summaryrefslogtreecommitdiff
path: root/gcc/ada/gnat_ug.texi
blob: be71814bd7e98d1ccbcdf6317dfec197d6b130ab (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
1012
1013
1014
1015
1016
1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
1031
1032
1033
1034
1035
1036
1037
1038
1039
1040
1041
1042
1043
1044
1045
1046
1047
1048
1049
1050
1051
1052
1053
1054
1055
1056
1057
1058
1059
1060
1061
1062
1063
1064
1065
1066
1067
1068
1069
1070
1071
1072
1073
1074
1075
1076
1077
1078
1079
1080
1081
1082
1083
1084
1085
1086
1087
1088
1089
1090
1091
1092
1093
1094
1095
1096
1097
1098
1099
1100
1101
1102
1103
1104
1105
1106
1107
1108
1109
1110
1111
1112
1113
1114
1115
1116
1117
1118
1119
1120
1121
1122
1123
1124
1125
1126
1127
1128
1129
1130
1131
1132
1133
1134
1135
1136
1137
1138
1139
1140
1141
1142
1143
1144
1145
1146
1147
1148
1149
1150
1151
1152
1153
1154
1155
1156
1157
1158
1159
1160
1161
1162
1163
1164
1165
1166
1167
1168
1169
1170
1171
1172
1173
1174
1175
1176
1177
1178
1179
1180
1181
1182
1183
1184
1185
1186
1187
1188
1189
1190
1191
1192
1193
1194
1195
1196
1197
1198
1199
1200
1201
1202
1203
1204
1205
1206
1207
1208
1209
1210
1211
1212
1213
1214
1215
1216
1217
1218
1219
1220
1221
1222
1223
1224
1225
1226
1227
1228
1229
1230
1231
1232
1233
1234
1235
1236
1237
1238
1239
1240
1241
1242
1243
1244
1245
1246
1247
1248
1249
1250
1251
1252
1253
1254
1255
1256
1257
1258
1259
1260
1261
1262
1263
1264
1265
1266
1267
1268
1269
1270
1271
1272
1273
1274
1275
1276
1277
1278
1279
1280
1281
1282
1283
1284
1285
1286
1287
1288
1289
1290
1291
1292
1293
1294
1295
1296
1297
1298
1299
1300
1301
1302
1303
1304
1305
1306
1307
1308
1309
1310
1311
1312
1313
1314
1315
1316
1317
1318
1319
1320
1321
1322
1323
1324
1325
1326
1327
1328
1329
1330
1331
1332
1333
1334
1335
1336
1337
1338
1339
1340
1341
1342
1343
1344
1345
1346
1347
1348
1349
1350
1351
1352
1353
1354
1355
1356
1357
1358
1359
1360
1361
1362
1363
1364
1365
1366
1367
1368
1369
1370
1371
1372
1373
1374
1375
1376
1377
1378
1379
1380
1381
1382
1383
1384
1385
1386
1387
1388
1389
1390
1391
1392
1393
1394
1395
1396
1397
1398
1399
1400
1401
1402
1403
1404
1405
1406
1407
1408
1409
1410
1411
1412
1413
1414
1415
1416
1417
1418
1419
1420
1421
1422
1423
1424
1425
1426
1427
1428
1429
1430
1431
1432
1433
1434
1435
1436
1437
1438
1439
1440
1441
1442
1443
1444
1445
1446
1447
1448
1449
1450
1451
1452
1453
1454
1455
1456
1457
1458
1459
1460
1461
1462
1463
1464
1465
1466
1467
1468
1469
1470
1471
1472
1473
1474
1475
1476
1477
1478
1479
1480
1481
1482
1483
1484
1485
1486
1487
1488
1489
1490
1491
1492
1493
1494
1495
1496
1497
1498
1499
1500
1501
1502
1503
1504
1505
1506
1507
1508
1509
1510
1511
1512
1513
1514
1515
1516
1517
1518
1519
1520
1521
1522
1523
1524
1525
1526
1527
1528
1529
1530
1531
1532
1533
1534
1535
1536
1537
1538
1539
1540
1541
1542
1543
1544
1545
1546
1547
1548
1549
1550
1551
1552
1553
1554
1555
1556
1557
1558
1559
1560
1561
1562
1563
1564
1565
1566
1567
1568
1569
1570
1571
1572
1573
1574
1575
1576
1577
1578
1579
1580
1581
1582
1583
1584
1585
1586
1587
1588
1589
1590
1591
1592
1593
1594
1595
1596
1597
1598
1599
1600
1601
1602
1603
1604
1605
1606
1607
1608
1609
1610
1611
1612
1613
1614
1615
1616
1617
1618
1619
1620
1621
1622
1623
1624
1625
1626
1627
1628
1629
1630
1631
1632
1633
1634
1635
1636
1637
1638
1639
1640
1641
1642
1643
1644
1645
1646
1647
1648
1649
1650
1651
1652
1653
1654
1655
1656
1657
1658
1659
1660
1661
1662
1663
1664
1665
1666
1667
1668
1669
1670
1671
1672
1673
1674
1675
1676
1677
1678
1679
1680
1681
1682
1683
1684
1685
1686
1687
1688
1689
1690
1691
1692
1693
1694
1695
1696
1697
1698
1699
1700
1701
1702
1703
1704
1705
1706
1707
1708
1709
1710
1711
1712
1713
1714
1715
1716
1717
1718
1719
1720
1721
1722
1723
1724
1725
1726
1727
1728
1729
1730
1731
1732
1733
1734
1735
1736
1737
1738
1739
1740
1741
1742
1743
1744
1745
1746
1747
1748
1749
1750
1751
1752
1753
1754
1755
1756
1757
1758
1759
1760
1761
1762
1763
1764
1765
1766
1767
1768
1769
1770
1771
1772
1773
1774
1775
1776
1777
1778
1779
1780
1781
1782
1783
1784
1785
1786
1787
1788
1789
1790
1791
1792
1793
1794
1795
1796
1797
1798
1799
1800
1801
1802
1803
1804
1805
1806
1807
1808
1809
1810
1811
1812
1813
1814
1815
1816
1817
1818
1819
1820
1821
1822
1823
1824
1825
1826
1827
1828
1829
1830
1831
1832
1833
1834
1835
1836
1837
1838
1839
1840
1841
1842
1843
1844
1845
1846
1847
1848
1849
1850
1851
1852
1853
1854
1855
1856
1857
1858
1859
1860
1861
1862
1863
1864
1865
1866
1867
1868
1869
1870
1871
1872
1873
1874
1875
1876
1877
1878
1879
1880
1881
1882
1883
1884
1885
1886
1887
1888
1889
1890
1891
1892
1893
1894
1895
1896
1897
1898
1899
1900
1901
1902
1903
1904
1905
1906
1907
1908
1909
1910
1911
1912
1913
1914
1915
1916
1917
1918
1919
1920
1921
1922
1923
1924
1925
1926
1927
1928
1929
1930
1931
1932
1933
1934
1935
1936
1937
1938
1939
1940
1941
1942
1943
1944
1945
1946
1947
1948
1949
1950
1951
1952
1953
1954
1955
1956
1957
1958
1959
1960
1961
1962
1963
1964
1965
1966
1967
1968
1969
1970
1971
1972
1973
1974
1975
1976
1977
1978
1979
1980
1981
1982
1983
1984
1985
1986
1987
1988
1989
1990
1991
1992
1993
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
2016
2017
2018
2019
2020
2021
2022
2023
2024
2025
2026
2027
2028
2029
2030
2031
2032
2033
2034
2035
2036
2037
2038
2039
2040
2041
2042
2043
2044
2045
2046
2047
2048
2049
2050
2051
2052
2053
2054
2055
2056
2057
2058
2059
2060
2061
2062
2063
2064
2065
2066
2067
2068
2069
2070
2071
2072
2073
2074
2075
2076
2077
2078
2079
2080
2081
2082
2083
2084
2085
2086
2087
2088
2089
2090
2091
2092
2093
2094
2095
2096
2097
2098
2099
2100
2101
2102
2103
2104
2105
2106
2107
2108
2109
2110
2111
2112
2113
2114
2115
2116
2117
2118
2119
2120
2121
2122
2123
2124
2125
2126
2127
2128
2129
2130
2131
2132
2133
2134
2135
2136
2137
2138
2139
2140
2141
2142
2143
2144
2145
2146
2147
2148
2149
2150
2151
2152
2153
2154
2155
2156
2157
2158
2159
2160
2161
2162
2163
2164
2165
2166
2167
2168
2169
2170
2171
2172
2173
2174
2175
2176
2177
2178
2179
2180
2181
2182
2183
2184
2185
2186
2187
2188
2189
2190
2191
2192
2193
2194
2195
2196
2197
2198
2199
2200
2201
2202
2203
2204
2205
2206
2207
2208
2209
2210
2211
2212
2213
2214
2215
2216
2217
2218
2219
2220
2221
2222
2223
2224
2225
2226
2227
2228
2229
2230
2231
2232
2233
2234
2235
2236
2237
2238
2239
2240
2241
2242
2243
2244
2245
2246
2247
2248
2249
2250
2251
2252
2253
2254
2255
2256
2257
2258
2259
2260
2261
2262
2263
2264
2265
2266
2267
2268
2269
2270
2271
2272
2273
2274
2275
2276
2277
2278
2279
2280
2281
2282
2283
2284
2285
2286
2287
2288
2289
2290
2291
2292
2293
2294
2295
2296
2297
2298
2299
2300
2301
2302
2303
2304
2305
2306
2307
2308
2309
2310
2311
2312
2313
2314
2315
2316
2317
2318
2319
2320
2321
2322
2323
2324
2325
2326
2327
2328
2329
2330
2331
2332
2333
2334
2335
2336
2337
2338
2339
2340
2341
2342
2343
2344
2345
2346
2347
2348
2349
2350
2351
2352
2353
2354
2355
2356
2357
2358
2359
2360
2361
2362
2363
2364
2365
2366
2367
2368
2369
2370
2371
2372
2373
2374
2375
2376
2377
2378
2379
2380
2381
2382
2383
2384
2385
2386
2387
2388
2389
2390
2391
2392
2393
2394
2395
2396
2397
2398
2399
2400
2401
2402
2403
2404
2405
2406
2407
2408
2409
2410
2411
2412
2413
2414
2415
2416
2417
2418
2419
2420
2421
2422
2423
2424
2425
2426
2427
2428
2429
2430
2431
2432
2433
2434
2435
2436
2437
2438
2439
2440
2441
2442
2443
2444
2445
2446
2447
2448
2449
2450
2451
2452
2453
2454
2455
2456
2457
2458
2459
2460
2461
2462
2463
2464
2465
2466
2467
2468
2469
2470
2471
2472
2473
2474
2475
2476
2477
2478
2479
2480
2481
2482
2483
2484
2485
2486
2487
2488
2489
2490
2491
2492
2493
2494
2495
2496
2497
2498
2499
2500
2501
2502
2503
2504
2505
2506
2507
2508
2509
2510
2511
2512
2513
2514
2515
2516
2517
2518
2519
2520
2521
2522
2523
2524
2525
2526
2527
2528
2529
2530
2531
2532
2533
2534
2535
2536
2537
2538
2539
2540
2541
2542
2543
2544
2545
2546
2547
2548
2549
2550
2551
2552
2553
2554
2555
2556
2557
2558
2559
2560
2561
2562
2563
2564
2565
2566
2567
2568
2569
2570
2571
2572
2573
2574
2575
2576
2577
2578
2579
2580
2581
2582
2583
2584
2585
2586
2587
2588
2589
2590
2591
2592
2593
2594
2595
2596
2597
2598
2599
2600
2601
2602
2603
2604
2605
2606
2607
2608
2609
2610
2611
2612
2613
2614
2615
2616
2617
2618
2619
2620
2621
2622
2623
2624
2625
2626
2627
2628
2629
2630
2631
2632
2633
2634
2635
2636
2637
2638
2639
2640
2641
2642
2643
2644
2645
2646
2647
2648
2649
2650
2651
2652
2653
2654
2655
2656
2657
2658
2659
2660
2661
2662
2663
2664
2665
2666
2667
2668
2669
2670
2671
2672
2673
2674
2675
2676
2677
2678
2679
2680
2681
2682
2683
2684
2685
2686
2687
2688
2689
2690
2691
2692
2693
2694
2695
2696
2697
2698
2699
2700
2701
2702
2703
2704
2705
2706
2707
2708
2709
2710
2711
2712
2713
2714
2715
2716
2717
2718
2719
2720
2721
2722
2723
2724
2725
2726
2727
2728
2729
2730
2731
2732
2733
2734
2735
2736
2737
2738
2739
2740
2741
2742
2743
2744
2745
2746
2747
2748
2749
2750
2751
2752
2753
2754
2755
2756
2757
2758
2759
2760
2761
2762
2763
2764
2765
2766
2767
2768
2769
2770
2771
2772
2773
2774
2775
2776
2777
2778
2779
2780
2781
2782
2783
2784
2785
2786
2787
2788
2789
2790
2791
2792
2793
2794
2795
2796
2797
2798
2799
2800
2801
2802
2803
2804
2805
2806
2807
2808
2809
2810
2811
2812
2813
2814
2815
2816
2817
2818
2819
2820
2821
2822
2823
2824
2825
2826
2827
2828
2829
2830
2831
2832
2833
2834
2835
2836
2837
2838
2839
2840
2841
2842
2843
2844
2845
2846
2847
2848
2849
2850
2851
2852
2853
2854
2855
2856
2857
2858
2859
2860
2861
2862
2863
2864
2865
2866
2867
2868
2869
2870
2871
2872
2873
2874
2875
2876
2877
2878
2879
2880
2881
2882
2883
2884
2885
2886
2887
2888
2889
2890
2891
2892
2893
2894
2895
2896
2897
2898
2899
2900
2901
2902
2903
2904
2905
2906
2907
2908
2909
2910
2911
2912
2913
2914
2915
2916
2917
2918
2919
2920
2921
2922
2923
2924
2925
2926
2927
2928
2929
2930
2931
2932
2933
2934
2935
2936
2937
2938
2939
2940
2941
2942
2943
2944
2945
2946
2947
2948
2949
2950
2951
2952
2953
2954
2955
2956
2957
2958
2959
2960
2961
2962
2963
2964
2965
2966
2967
2968
2969
2970
2971
2972
2973
2974
2975
2976
2977
2978
2979
2980
2981
2982
2983
2984
2985
2986
2987
2988
2989
2990
2991
2992
2993
2994
2995
2996
2997
2998
2999
3000
3001
3002
3003
3004
3005
3006
3007
3008
3009
3010
3011
3012
3013
3014
3015
3016
3017
3018
3019
3020
3021
3022
3023
3024
3025
3026
3027
3028
3029
3030
3031
3032
3033
3034
3035
3036
3037
3038
3039
3040
3041
3042
3043
3044
3045
3046
3047
3048
3049
3050
3051
3052
3053
3054
3055
3056
3057
3058
3059
3060
3061
3062
3063
3064
3065
3066
3067
3068
3069
3070
3071
3072
3073
3074
3075
3076
3077
3078
3079
3080
3081
3082
3083
3084
3085
3086
3087
3088
3089
3090
3091
3092
3093
3094
3095
3096
3097
3098
3099
3100
3101
3102
3103
3104
3105
3106
3107
3108
3109
3110
3111
3112
3113
3114
3115
3116
3117
3118
3119
3120
3121
3122
3123
3124
3125
3126
3127
3128
3129
3130
3131
3132
3133
3134
3135
3136
3137
3138
3139
3140
3141
3142
3143
3144
3145
3146
3147
3148
3149
3150
3151
3152
3153
3154
3155
3156
3157
3158
3159
3160
3161
3162
3163
3164
3165
3166
3167
3168
3169
3170
3171
3172
3173
3174
3175
3176
3177
3178
3179
3180
3181
3182
3183
3184
3185
3186
3187
3188
3189
3190
3191
3192
3193
3194
3195
3196
3197
3198
3199
3200
3201
3202
3203
3204
3205
3206
3207
3208
3209
3210
3211
3212
3213
3214
3215
3216
3217
3218
3219
3220
3221
3222
3223
3224
3225
3226
3227
3228
3229
3230
3231
3232
3233
3234
3235
3236
3237
3238
3239
3240
3241
3242
3243
3244
3245
3246
3247
3248
3249
3250
3251
3252
3253
3254
3255
3256
3257
3258
3259
3260
3261
3262
3263
3264
3265
3266
3267
3268
3269
3270
3271
3272
3273
3274
3275
3276
3277
3278
3279
3280
3281
3282
3283
3284
3285
3286
3287
3288
3289
3290
3291
3292
3293
3294
3295
3296
3297
3298
3299
3300
3301
3302
3303
3304
3305
3306
3307
3308
3309
3310
3311
3312
3313
3314
3315
3316
3317
3318
3319
3320
3321
3322
3323
3324
3325
3326
3327
3328
3329
3330
3331
3332
3333
3334
3335
3336
3337
3338
3339
3340
3341
3342
3343
3344
3345
3346
3347
3348
3349
3350
3351
3352
3353
3354
3355
3356
3357
3358
3359
3360
3361
3362
3363
3364
3365
3366
3367
3368
3369
3370
3371
3372
3373
3374
3375
3376
3377
3378
3379
3380
3381
3382
3383
3384
3385
3386
3387
3388
3389
3390
3391
3392
3393
3394
3395
3396
3397
3398
3399
3400
3401
3402
3403
3404
3405
3406
3407
3408
3409
3410
3411
3412
3413
3414
3415
3416
3417
3418
3419
3420
3421
3422
3423
3424
3425
3426
3427
3428
3429
3430
3431
3432
3433
3434
3435
3436
3437
3438
3439
3440
3441
3442
3443
3444
3445
3446
3447
3448
3449
3450
3451
3452
3453
3454
3455
3456
3457
3458
3459
3460
3461
3462
3463
3464
3465
3466
3467
3468
3469
3470
3471
3472
3473
3474
3475
3476
3477
3478
3479
3480
3481
3482
3483
3484
3485
3486
3487
3488
3489
3490
3491
3492
3493
3494
3495
3496
3497
3498
3499
3500
3501
3502
3503
3504
3505
3506
3507
3508
3509
3510
3511
3512
3513
3514
3515
3516
3517
3518
3519
3520
3521
3522
3523
3524
3525
3526
3527
3528
3529
3530
3531
3532
3533
3534
3535
3536
3537
3538
3539
3540
3541
3542
3543
3544
3545
3546
3547
3548
3549
3550
3551
3552
3553
3554
3555
3556
3557
3558
3559
3560
3561
3562
3563
3564
3565
3566
3567
3568
3569
3570
3571
3572
3573
3574
3575
3576
3577
3578
3579
3580
3581
3582
3583
3584
3585
3586
3587
3588
3589
3590
3591
3592
3593
3594
3595
3596
3597
3598
3599
3600
3601
3602
3603
3604
3605
3606
3607
3608
3609
3610
3611
3612
3613
3614
3615
3616
3617
3618
3619
3620
3621
3622
3623
3624
3625
3626
3627
3628
3629
3630
3631
3632
3633
3634
3635
3636
3637
3638
3639
3640
3641
3642
3643
3644
3645
3646
3647
3648
3649
3650
3651
3652
3653
3654
3655
3656
3657
3658
3659
3660
3661
3662
3663
3664
3665
3666
3667
3668
3669
3670
3671
3672
3673
3674
3675
3676
3677
3678
3679
3680
3681
3682
3683
3684
3685
3686
3687
3688
3689
3690
3691
3692
3693
3694
3695
3696
3697
3698
3699
3700
3701
3702
3703
3704
3705
3706
3707
3708
3709
3710
3711
3712
3713
3714
3715
3716
3717
3718
3719
3720
3721
3722
3723
3724
3725
3726
3727
3728
3729
3730
3731
3732
3733
3734
3735
3736
3737
3738
3739
3740
3741
3742
3743
3744
3745
3746
3747
3748
3749
3750
3751
3752
3753
3754
3755
3756
3757
3758
3759
3760
3761
3762
3763
3764
3765
3766
3767
3768
3769
3770
3771
3772
3773
3774
3775
3776
3777
3778
3779
3780
3781
3782
3783
3784
3785
3786
3787
3788
3789
3790
3791
3792
3793
3794
3795
3796
3797
3798
3799
3800
3801
3802
3803
3804
3805
3806
3807
3808
3809
3810
3811
3812
3813
3814
3815
3816
3817
3818
3819
3820
3821
3822
3823
3824
3825
3826
3827
3828
3829
3830
3831
3832
3833
3834
3835
3836
3837
3838
3839
3840
3841
3842
3843
3844
3845
3846
3847
3848
3849
3850
3851
3852
3853
3854
3855
3856
3857
3858
3859
3860
3861
3862
3863
3864
3865
3866
3867
3868
3869
3870
3871
3872
3873
3874
3875
3876
3877
3878
3879
3880
3881
3882
3883
3884
3885
3886
3887
3888
3889
3890
3891
3892
3893
3894
3895
3896
3897
3898
3899
3900
3901
3902
3903
3904
3905
3906
3907
3908
3909
3910
3911
3912
3913
3914
3915
3916
3917
3918
3919
3920
3921
3922
3923
3924
3925
3926
3927
3928
3929
3930
3931
3932
3933
3934
3935
3936
3937
3938
3939
3940
3941
3942
3943
3944
3945
3946
3947
3948
3949
3950
3951
3952
3953
3954
3955
3956
3957
3958
3959
3960
3961
3962
3963
3964
3965
3966
3967
3968
3969
3970
3971
3972
3973
3974
3975
3976
3977
3978
3979
3980
3981
3982
3983
3984
3985
3986
3987
3988
3989
3990
3991
3992
3993
3994
3995
3996
3997
3998
3999
4000
4001
4002
4003
4004
4005
4006
4007
4008
4009
4010
4011
4012
4013
4014
4015
4016
4017
4018
4019
4020
4021
4022
4023
4024
4025
4026
4027
4028
4029
4030
4031
4032
4033
4034
4035
4036
4037
4038
4039
4040
4041
4042
4043
4044
4045
4046
4047
4048
4049
4050
4051
4052
4053
4054
4055
4056
4057
4058
4059
4060
4061
4062
4063
4064
4065
4066
4067
4068
4069
4070
4071
4072
4073
4074
4075
4076
4077
4078
4079
4080
4081
4082
4083
4084
4085
4086
4087
4088
4089
4090
4091
4092
4093
4094
4095
4096
4097
4098
4099
4100
4101
4102
4103
4104
4105
4106
4107
4108
4109
4110
4111
4112
4113
4114
4115
4116
4117
4118
4119
4120
4121
4122
4123
4124
4125
4126
4127
4128
4129
4130
4131
4132
4133
4134
4135
4136
4137
4138
4139
4140
4141
4142
4143
4144
4145
4146
4147
4148
4149
4150
4151
4152
4153
4154
4155
4156
4157
4158
4159
4160
4161
4162
4163
4164
4165
4166
4167
4168
4169
4170
4171
4172
4173
4174
4175
4176
4177
4178
4179
4180
4181
4182
4183
4184
4185
4186
4187
4188
4189
4190
4191
4192
4193
4194
4195
4196
4197
4198
4199
4200
4201
4202
4203
4204
4205
4206
4207
4208
4209
4210
4211
4212
4213
4214
4215
4216
4217
4218
4219
4220
4221
4222
4223
4224
4225
4226
4227
4228
4229
4230
4231
4232
4233
4234
4235
4236
4237
4238
4239
4240
4241
4242
4243
4244
4245
4246
4247
4248
4249
4250
4251
4252
4253
4254
4255
4256
4257
4258
4259
4260
4261
4262
4263
4264
4265
4266
4267
4268
4269
4270
4271
4272
4273
4274
4275
4276
4277
4278
4279
4280
4281
4282
4283
4284
4285
4286
4287
4288
4289
4290
4291
4292
4293
4294
4295
4296
4297
4298
4299
4300
4301
4302
4303
4304
4305
4306
4307
4308
4309
4310
4311
4312
4313
4314
4315
4316
4317
4318
4319
4320
4321
4322
4323
4324
4325
4326
4327
4328
4329
4330
4331
4332
4333
4334
4335
4336
4337
4338
4339
4340
4341
4342
4343
4344
4345
4346
4347
4348
4349
4350
4351
4352
4353
4354
4355
4356
4357
4358
4359
4360
4361
4362
4363
4364
4365
4366
4367
4368
4369
4370
4371
4372
4373
4374
4375
4376
4377
4378
4379
4380
4381
4382
4383
4384
4385
4386
4387
4388
4389
4390
4391
4392
4393
4394
4395
4396
4397
4398
4399
4400
4401
4402
4403
4404
4405
4406
4407
4408
4409
4410
4411
4412
4413
4414
4415
4416
4417
4418
4419
4420
4421
4422
4423
4424
4425
4426
4427
4428
4429
4430
4431
4432
4433
4434
4435
4436
4437
4438
4439
4440
4441
4442
4443
4444
4445
4446
4447
4448
4449
4450
4451
4452
4453
4454
4455
4456
4457
4458
4459
4460
4461
4462
4463
4464
4465
4466
4467
4468
4469
4470
4471
4472
4473
4474
4475
4476
4477
4478
4479
4480
4481
4482
4483
4484
4485
4486
4487
4488
4489
4490
4491
4492
4493
4494
4495
4496
4497
4498
4499
4500
4501
4502
4503
4504
4505
4506
4507
4508
4509
4510
4511
4512
4513
4514
4515
4516
4517
4518
4519
4520
4521
4522
4523
4524
4525
4526
4527
4528
4529
4530
4531
4532
4533
4534
4535
4536
4537
4538
4539
4540
4541
4542
4543
4544
4545
4546
4547
4548
4549
4550
4551
4552
4553
4554
4555
4556
4557
4558
4559
4560
4561
4562
4563
4564
4565
4566
4567
4568
4569
4570
4571
4572
4573
4574
4575
4576
4577
4578
4579
4580
4581
4582
4583
4584
4585
4586
4587
4588
4589
4590
4591
4592
4593
4594
4595
4596
4597
4598
4599
4600
4601
4602
4603
4604
4605
4606
4607
4608
4609
4610
4611
4612
4613
4614
4615
4616
4617
4618
4619
4620
4621
4622
4623
4624
4625
4626
4627
4628
4629
4630
4631
4632
4633
4634
4635
4636
4637
4638
4639
4640
4641
4642
4643
4644
4645
4646
4647
4648
4649
4650
4651
4652
4653
4654
4655
4656
4657
4658
4659
4660
4661
4662
4663
4664
4665
4666
4667
4668
4669
4670
4671
4672
4673
4674
4675
4676
4677
4678
4679
4680
4681
4682
4683
4684
4685
4686
4687
4688
4689
4690
4691
4692
4693
4694
4695
4696
4697
4698
4699
4700
4701
4702
4703
4704
4705
4706
4707
4708
4709
4710
4711
4712
4713
4714
4715
4716
4717
4718
4719
4720
4721
4722
4723
4724
4725
4726
4727
4728
4729
4730
4731
4732
4733
4734
4735
4736
4737
4738
4739
4740
4741
4742
4743
4744
4745
4746
4747
4748
4749
4750
4751
4752
4753
4754
4755
4756
4757
4758
4759
4760
4761
4762
4763
4764
4765
4766
4767
4768
4769
4770
4771
4772
4773
4774
4775
4776
4777
4778
4779
4780
4781
4782
4783
4784
4785
4786
4787
4788
4789
4790
4791
4792
4793
4794
4795
4796
4797
4798
4799
4800
4801
4802
4803
4804
4805
4806
4807
4808
4809
4810
4811
4812
4813
4814
4815
4816
4817
4818
4819
4820
4821
4822
4823
4824
4825
4826
4827
4828
4829
4830
4831
4832
4833
4834
4835
4836
4837
4838
4839
4840
4841
4842
4843
4844
4845
4846
4847
4848
4849
4850
4851
4852
4853
4854
4855
4856
4857
4858
4859
4860
4861
4862
4863
4864
4865
4866
4867
4868
4869
4870
4871
4872
4873
4874
4875
4876
4877
4878
4879
4880
4881
4882
4883
4884
4885
4886
4887
4888
4889
4890
4891
4892
4893
4894
4895
4896
4897
4898
4899
4900
4901
4902
4903
4904
4905
4906
4907
4908
4909
4910
4911
4912
4913
4914
4915
4916
4917
4918
4919
4920
4921
4922
4923
4924
4925
4926
4927
4928
4929
4930
4931
4932
4933
4934
4935
4936
4937
4938
4939
4940
4941
4942
4943
4944
4945
4946
4947
4948
4949
4950
4951
4952
4953
4954
4955
4956
4957
4958
4959
4960
4961
4962
4963
4964
4965
4966
4967
4968
4969
4970
4971
4972
4973
4974
4975
4976
4977
4978
4979
4980
4981
4982
4983
4984
4985
4986
4987
4988
4989
4990
4991
4992
4993
4994
4995
4996
4997
4998
4999
5000
5001
5002
5003
5004
5005
5006
5007
5008
5009
5010
5011
5012
5013
5014
5015
5016
5017
5018
5019
5020
5021
5022
5023
5024
5025
5026
5027
5028
5029
5030
5031
5032
5033
5034
5035
5036
5037
5038
5039
5040
5041
5042
5043
5044
5045
5046
5047
5048
5049
5050
5051
5052
5053
5054
5055
5056
5057
5058
5059
5060
5061
5062
5063
5064
5065
5066
5067
5068
5069
5070
5071
5072
5073
5074
5075
5076
5077
5078
5079
5080
5081
5082
5083
5084
5085
5086
5087
5088
5089
5090
5091
5092
5093
5094
5095
5096
5097
5098
5099
5100
5101
5102
5103
5104
5105
5106
5107
5108
5109
5110
5111
5112
5113
5114
5115
5116
5117
5118
5119
5120
5121
5122
5123
5124
5125
5126
5127
5128
5129
5130
5131
5132
5133
5134
5135
5136
5137
5138
5139
5140
5141
5142
5143
5144
5145
5146
5147
5148
5149
5150
5151
5152
5153
5154
5155
5156
5157
5158
5159
5160
5161
5162
5163
5164
5165
5166
5167
5168
5169
5170
5171
5172
5173
5174
5175
5176
5177
5178
5179
5180
5181
5182
5183
5184
5185
5186
5187
5188
5189
5190
5191
5192
5193
5194
5195
5196
5197
5198
5199
5200
5201
5202
5203
5204
5205
5206
5207
5208
5209
5210
5211
5212
5213
5214
5215
5216
5217
5218
5219
5220
5221
5222
5223
5224
5225
5226
5227
5228
5229
5230
5231
5232
5233
5234
5235
5236
5237
5238
5239
5240
5241
5242
5243
5244
5245
5246
5247
5248
5249
5250
5251
5252
5253
5254
5255
5256
5257
5258
5259
5260
5261
5262
5263
5264
5265
5266
5267
5268
5269
5270
5271
5272
5273
5274
5275
5276
5277
5278
5279
5280
5281
5282
5283
5284
5285
5286
5287
5288
5289
5290
5291
5292
5293
5294
5295
5296
5297
5298
5299
5300
5301
5302
5303
5304
5305
5306
5307
5308
5309
5310
5311
5312
5313
5314
5315
5316
5317
5318
5319
5320
5321
5322
5323
5324
5325
5326
5327
5328
5329
5330
5331
5332
5333
5334
5335
5336
5337
5338
5339
5340
5341
5342
5343
5344
5345
5346
5347
5348
5349
5350
5351
5352
5353
5354
5355
5356
5357
5358
5359
5360
5361
5362
5363
5364
5365
5366
5367
5368
5369
5370
5371
5372
5373
5374
5375
5376
5377
5378
5379
5380
5381
5382
5383
5384
5385
5386
5387
5388
5389
5390
5391
5392
5393
5394
5395
5396
5397
5398
5399
5400
5401
5402
5403
5404
5405
5406
5407
5408
5409
5410
5411
5412
5413
5414
5415
5416
5417
5418
5419
5420
5421
5422
5423
5424
5425
5426
5427
5428
5429
5430
5431
5432
5433
5434
5435
5436
5437
5438
5439
5440
5441
5442
5443
5444
5445
5446
5447
5448
5449
5450
5451
5452
5453
5454
5455
5456
5457
5458
5459
5460
5461
5462
5463
5464
5465
5466
5467
5468
5469
5470
5471
5472
5473
5474
5475
5476
5477
5478
5479
5480
5481
5482
5483
5484
5485
5486
5487
5488
5489
5490
5491
5492
5493
5494
5495
5496
5497
5498
5499
5500
5501
5502
5503
5504
5505
5506
5507
5508
5509
5510
5511
5512
5513
5514
5515
5516
5517
5518
5519
5520
5521
5522
5523
5524
5525
5526
5527
5528
5529
5530
5531
5532
5533
5534
5535
5536
5537
5538
5539
5540
5541
5542
5543
5544
5545
5546
5547
5548
5549
5550
5551
5552
5553
5554
5555
5556
5557
5558
5559
5560
5561
5562
5563
5564
5565
5566
5567
5568
5569
5570
5571
5572
5573
5574
5575
5576
5577
5578
5579
5580
5581
5582
5583
5584
5585
5586
5587
5588
5589
5590
5591
5592
5593
5594
5595
5596
5597
5598
5599
5600
5601
5602
5603
5604
5605
5606
5607
5608
5609
5610
5611
5612
5613
5614
5615
5616
5617
5618
5619
5620
5621
5622
5623
5624
5625
5626
5627
5628
5629
5630
5631
5632
5633
5634
5635
5636
5637
5638
5639
5640
5641
5642
5643
5644
5645
5646
5647
5648
5649
5650
5651
5652
5653
5654
5655
5656
5657
5658
5659
5660
5661
5662
5663
5664
5665
5666
5667
5668
5669
5670
5671
5672
5673
5674
5675
5676
5677
5678
5679
5680
5681
5682
5683
5684
5685
5686
5687
5688
5689
5690
5691
5692
5693
5694
5695
5696
5697
5698
5699
5700
5701
5702
5703
5704
5705
5706
5707
5708
5709
5710
5711
5712
5713
5714
5715
5716
5717
5718
5719
5720
5721
5722
5723
5724
5725
5726
5727
5728
5729
5730
5731
5732
5733
5734
5735
5736
5737
5738
5739
5740
5741
5742
5743
5744
5745
5746
5747
5748
5749
5750
5751
5752
5753
5754
5755
5756
5757
5758
5759
5760
5761
5762
5763
5764
5765
5766
5767
5768
5769
5770
5771
5772
5773
5774
5775
5776
5777
5778
5779
5780
5781
5782
5783
5784
5785
5786
5787
5788
5789
5790
5791
5792
5793
5794
5795
5796
5797
5798
5799
5800
5801
5802
5803
5804
5805
5806
5807
5808
5809
5810
5811
5812
5813
5814
5815
5816
5817
5818
5819
5820
5821
5822
5823
5824
5825
5826
5827
5828
5829
5830
5831
5832
5833
5834
5835
5836
5837
5838
5839
5840
5841
5842
5843
5844
5845
5846
5847
5848
5849
5850
5851
5852
5853
5854
5855
5856
5857
5858
5859
5860
5861
5862
5863
5864
5865
5866
5867
5868
5869
5870
5871
5872
5873
5874
5875
5876
5877
5878
5879
5880
5881
5882
5883
5884
5885
5886
5887
5888
5889
5890
5891
5892
5893
5894
5895
5896
5897
5898
5899
5900
5901
5902
5903
5904
5905
5906
5907
5908
5909
5910
5911
5912
5913
5914
5915
5916
5917
5918
5919
5920
5921
5922
5923
5924
5925
5926
5927
5928
5929
5930
5931
5932
5933
5934
5935
5936
5937
5938
5939
5940
5941
5942
5943
5944
5945
5946
5947
5948
5949
5950
5951
5952
5953
5954
5955
5956
5957
5958
5959
5960
5961
5962
5963
5964
5965
5966
5967
5968
5969
5970
5971
5972
5973
5974
5975
5976
5977
5978
5979
5980
5981
5982
5983
5984
5985
5986
5987
5988
5989
5990
5991
5992
5993
5994
5995
5996
5997
5998
5999
6000
6001
6002
6003
6004
6005
6006
6007
6008
6009
6010
6011
6012
6013
6014
6015
6016
6017
6018
6019
6020
6021
6022
6023
6024
6025
6026
6027
6028
6029
6030
6031
6032
6033
6034
6035
6036
6037
6038
6039
6040
6041
6042
6043
6044
6045
6046
6047
6048
6049
6050
6051
6052
6053
6054
6055
6056
6057
6058
6059
6060
6061
6062
6063
6064
6065
6066
6067
6068
6069
6070
6071
6072
6073
6074
6075
6076
6077
6078
6079
6080
6081
6082
6083
6084
6085
6086
6087
6088
6089
6090
6091
6092
6093
6094
6095
6096
6097
6098
6099
6100
6101
6102
6103
6104
6105
6106
6107
6108
6109
6110
6111
6112
6113
6114
6115
6116
6117
6118
6119
6120
6121
6122
6123
6124
6125
6126
6127
6128
6129
6130
6131
6132
6133
6134
6135
6136
6137
6138
6139
6140
6141
6142
6143
6144
6145
6146
6147
6148
6149
6150
6151
6152
6153
6154
6155
6156
6157
6158
6159
6160
6161
6162
6163
6164
6165
6166
6167
6168
6169
6170
6171
6172
6173
6174
6175
6176
6177
6178
6179
6180
6181
6182
6183
6184
6185
6186
6187
6188
6189
6190
6191
6192
6193
6194
6195
6196
6197
6198
6199
6200
6201
6202
6203
6204
6205
6206
6207
6208
6209
6210
6211
6212
6213
6214
6215
6216
6217
6218
6219
6220
6221
6222
6223
6224
6225
6226
6227
6228
6229
6230
6231
6232
6233
6234
6235
6236
6237
6238
6239
6240
6241
6242
6243
6244
6245
6246
6247
6248
6249
6250
6251
6252
6253
6254
6255
6256
6257
6258
6259
6260
6261
6262
6263
6264
6265
6266
6267
6268
6269
6270
6271
6272
6273
6274
6275
6276
6277
6278
6279
6280
6281
6282
6283
6284
6285
6286
6287
6288
6289
6290
6291
6292
6293
6294
6295
6296
6297
6298
6299
6300
6301
6302
6303
6304
6305
6306
6307
6308
6309
6310
6311
6312
6313
6314
6315
6316
6317
6318
6319
6320
6321
6322
6323
6324
6325
6326
6327
6328
6329
6330
6331
6332
6333
6334
6335
6336
6337
6338
6339
6340
6341
6342
6343
6344
6345
6346
6347
6348
6349
6350
6351
6352
6353
6354
6355
6356
6357
6358
6359
6360
6361
6362
6363
6364
6365
6366
6367
6368
6369
6370
6371
6372
6373
6374
6375
6376
6377
6378
6379
6380
6381
6382
6383
6384
6385
6386
6387
6388
6389
6390
6391
6392
6393
6394
6395
6396
6397
6398
6399
6400
6401
6402
6403
6404
6405
6406
6407
6408
6409
6410
6411
6412
6413
6414
6415
6416
6417
6418
6419
6420
6421
6422
6423
6424
6425
6426
6427
6428
6429
6430
6431
6432
6433
6434
6435
6436
6437
6438
6439
6440
6441
6442
6443
6444
6445
6446
6447
6448
6449
6450
6451
6452
6453
6454
6455
6456
6457
6458
6459
6460
6461
6462
6463
6464
6465
6466
6467
6468
6469
6470
6471
6472
6473
6474
6475
6476
6477
6478
6479
6480
6481
6482
6483
6484
6485
6486
6487
6488
6489
6490
6491
6492
6493
6494
6495
6496
6497
6498
6499
6500
6501
6502
6503
6504
6505
6506
6507
6508
6509
6510
6511
6512
6513
6514
6515
6516
6517
6518
6519
6520
6521
6522
6523
6524
6525
6526
6527
6528
6529
6530
6531
6532
6533
6534
6535
6536
6537
6538
6539
6540
6541
6542
6543
6544
6545
6546
6547
6548
6549
6550
6551
6552
6553
6554
6555
6556
6557
6558
6559
6560
6561
6562
6563
6564
6565
6566
6567
6568
6569
6570
6571
6572
6573
6574
6575
6576
6577
6578
6579
6580
6581
6582
6583
6584
6585
6586
6587
6588
6589
6590
6591
6592
6593
6594
6595
6596
6597
6598
6599
6600
6601
6602
6603
6604
6605
6606
6607
6608
6609
6610
6611
6612
6613
6614
6615
6616
6617
6618
6619
6620
6621
6622
6623
6624
6625
6626
6627
6628
6629
6630
6631
6632
6633
6634
6635
6636
6637
6638
6639
6640
6641
6642
6643
6644
6645
6646
6647
6648
6649
6650
6651
6652
6653
6654
6655
6656
6657
6658
6659
6660
6661
6662
6663
6664
6665
6666
6667
6668
6669
6670
6671
6672
6673
6674
6675
6676
6677
6678
6679
6680
6681
6682
6683
6684
6685
6686
6687
6688
6689
6690
6691
6692
6693
6694
6695
6696
6697
6698
6699
6700
6701
6702
6703
6704
6705
6706
6707
6708
6709
6710
6711
6712
6713
6714
6715
6716
6717
6718
6719
6720
6721
6722
6723
6724
6725
6726
6727
6728
6729
6730
6731
6732
6733
6734
6735
6736
6737
6738
6739
6740
6741
6742
6743
6744
6745
6746
6747
6748
6749
6750
6751
6752
6753
6754
6755
6756
6757
6758
6759
6760
6761
6762
6763
6764
6765
6766
6767
6768
6769
6770
6771
6772
6773
6774
6775
6776
6777
6778
6779
6780
6781
6782
6783
6784
6785
6786
6787
6788
6789
6790
6791
6792
6793
6794
6795
6796
6797
6798
6799
6800
6801
6802
6803
6804
6805
6806
6807
6808
6809
6810
6811
6812
6813
6814
6815
6816
6817
6818
6819
6820
6821
6822
6823
6824
6825
6826
6827
6828
6829
6830
6831
6832
6833
6834
6835
6836
6837
6838
6839
6840
6841
6842
6843
6844
6845
6846
6847
6848
6849
6850
6851
6852
6853
6854
6855
6856
6857
6858
6859
6860
6861
6862
6863
6864
6865
6866
6867
6868
6869
6870
6871
6872
6873
6874
6875
6876
6877
6878
6879
6880
6881
6882
6883
6884
6885
6886
6887
6888
6889
6890
6891
6892
6893
6894
6895
6896
6897
6898
6899
6900
6901
6902
6903
6904
6905
6906
6907
6908
6909
6910
6911
6912
6913
6914
6915
6916
6917
6918
6919
6920
6921
6922
6923
6924
6925
6926
6927
6928
6929
6930
6931
6932
6933
6934
6935
6936
6937
6938
6939
6940
6941
6942
6943
6944
6945
6946
6947
6948
6949
6950
6951
6952
6953
6954
6955
6956
6957
6958
6959
6960
6961
6962
6963
6964
6965
6966
6967
6968
6969
6970
6971
6972
6973
6974
6975
6976
6977
6978
6979
6980
6981
6982
6983
6984
6985
6986
6987
6988
6989
6990
6991
6992
6993
6994
6995
6996
6997
6998
6999
7000
7001
7002
7003
7004
7005
7006
7007
7008
7009
7010
7011
7012
7013
7014
7015
7016
7017
7018
7019
7020
7021
7022
7023
7024
7025
7026
7027
7028
7029
7030
7031
7032
7033
7034
7035
7036
7037
7038
7039
7040
7041
7042
7043
7044
7045
7046
7047
7048
7049
7050
7051
7052
7053
7054
7055
7056
7057
7058
7059
7060
7061
7062
7063
7064
7065
7066
7067
7068
7069
7070
7071
7072
7073
7074
7075
7076
7077
7078
7079
7080
7081
7082
7083
7084
7085
7086
7087
7088
7089
7090
7091
7092
7093
7094
7095
7096
7097
7098
7099
7100
7101
7102
7103
7104
7105
7106
7107
7108
7109
7110
7111
7112
7113
7114
7115
7116
7117
7118
7119
7120
7121
7122
7123
7124
7125
7126
7127
7128
7129
7130
7131
7132
7133
7134
7135
7136
7137
7138
7139
7140
7141
7142
7143
7144
7145
7146
7147
7148
7149
7150
7151
7152
7153
7154
7155
7156
7157
7158
7159
7160
7161
7162
7163
7164
7165
7166
7167
7168
7169
7170
7171
7172
7173
7174
7175
7176
7177
7178
7179
7180
7181
7182
7183
7184
7185
7186
7187
7188
7189
7190
7191
7192
7193
7194
7195
7196
7197
7198
7199
7200
7201
7202
7203
7204
7205
7206
7207
7208
7209
7210
7211
7212
7213
7214
7215
7216
7217
7218
7219
7220
7221
7222
7223
7224
7225
7226
7227
7228
7229
7230
7231
7232
7233
7234
7235
7236
7237
7238
7239
7240
7241
7242
7243
7244
7245
7246
7247
7248
7249
7250
7251
7252
7253
7254
7255
7256
7257
7258
7259
7260
7261
7262
7263
7264
7265
7266
7267
7268
7269
7270
7271
7272
7273
7274
7275
7276
7277
7278
7279
7280
7281
7282
7283
7284
7285
7286
7287
7288
7289
7290
7291
7292
7293
7294
7295
7296
7297
7298
7299
7300
7301
7302
7303
7304
7305
7306
7307
7308
7309
7310
7311
7312
7313
7314
7315
7316
7317
7318
7319
7320
7321
7322
7323
7324
7325
7326
7327
7328
7329
7330
7331
7332
7333
7334
7335
7336
7337
7338
7339
7340
7341
7342
7343
7344
7345
7346
7347
7348
7349
7350
7351
7352
7353
7354
7355
7356
7357
7358
7359
7360
7361
7362
7363
7364
7365
7366
7367
7368
7369
7370
7371
7372
7373
7374
7375
7376
7377
7378
7379
7380
7381
7382
7383
7384
7385
7386
7387
7388
7389
7390
7391
7392
7393
7394
7395
7396
7397
7398
7399
7400
7401
7402
7403
7404
7405
7406
7407
7408
7409
7410
7411
7412
7413
7414
7415
7416
7417
7418
7419
7420
7421
7422
7423
7424
7425
7426
7427
7428
7429
7430
7431
7432
7433
7434
7435
7436
7437
7438
7439
7440
7441
7442
7443
7444
7445
7446
7447
7448
7449
7450
7451
7452
7453
7454
7455
7456
7457
7458
7459
7460
7461
7462
7463
7464
7465
7466
7467
7468
7469
7470
7471
7472
7473
7474
7475
7476
7477
7478
7479
7480
7481
7482
7483
7484
7485
7486
7487
7488
7489
7490
7491
7492
7493
7494
7495
7496
7497
7498
7499
7500
7501
7502
7503
7504
7505
7506
7507
7508
7509
7510
7511
7512
7513
7514
7515
7516
7517
7518
7519
7520
7521
7522
7523
7524
7525
7526
7527
7528
7529
7530
7531
7532
7533
7534
7535
7536
7537
7538
7539
7540
7541
7542
7543
7544
7545
7546
7547
7548
7549
7550
7551
7552
7553
7554
7555
7556
7557
7558
7559
7560
7561
7562
7563
7564
7565
7566
7567
7568
7569
7570
7571
7572
7573
7574
7575
7576
7577
7578
7579
7580
7581
7582
7583
7584
7585
7586
7587
7588
7589
7590
7591
7592
7593
7594
7595
7596
7597
7598
7599
7600
7601
7602
7603
7604
7605
7606
7607
7608
7609
7610
7611
7612
7613
7614
7615
7616
7617
7618
7619
7620
7621
7622
7623
7624
7625
7626
7627
7628
7629
7630
7631
7632
7633
7634
7635
7636
7637
7638
7639
7640
7641
7642
7643
7644
7645
7646
7647
7648
7649
7650
7651
7652
7653
7654
7655
7656
7657
7658
7659
7660
7661
7662
7663
7664
7665
7666
7667
7668
7669
7670
7671
7672
7673
7674
7675
7676
7677
7678
7679
7680
7681
7682
7683
7684
7685
7686
7687
7688
7689
7690
7691
7692
7693
7694
7695
7696
7697
7698
7699
7700
7701
7702
7703
7704
7705
7706
7707
7708
7709
7710
7711
7712
7713
7714
7715
7716
7717
7718
7719
7720
7721
7722
7723
7724
7725
7726
7727
7728
7729
7730
7731
7732
7733
7734
7735
7736
7737
7738
7739
7740
7741
7742
7743
7744
7745
7746
7747
7748
7749
7750
7751
7752
7753
7754
7755
7756
7757
7758
7759
7760
7761
7762
7763
7764
7765
7766
7767
7768
7769
7770
7771
7772
7773
7774
7775
7776
7777
7778
7779
7780
7781
7782
7783
7784
7785
7786
7787
7788
7789
7790
7791
7792
7793
7794
7795
7796
7797
7798
7799
7800
7801
7802
7803
7804
7805
7806
7807
7808
7809
7810
7811
7812
7813
7814
7815
7816
7817
7818
7819
7820
7821
7822
7823
7824
7825
7826
7827
7828
7829
7830
7831
7832
7833
7834
7835
7836
7837
7838
7839
7840
7841
7842
7843
7844
7845
7846
7847
7848
7849
7850
7851
7852
7853
7854
7855
7856
7857
7858
7859
7860
7861
7862
7863
7864
7865
7866
7867
7868
7869
7870
7871
7872
7873
7874
7875
7876
7877
7878
7879
7880
7881
7882
7883
7884
7885
7886
7887
7888
7889
7890
7891
7892
7893
7894
7895
7896
7897
7898
7899
7900
7901
7902
7903
7904
7905
7906
7907
7908
7909
7910
7911
7912
7913
7914
7915
7916
7917
7918
7919
7920
7921
7922
7923
7924
7925
7926
7927
7928
7929
7930
7931
7932
7933
7934
7935
7936
7937
7938
7939
7940
7941
7942
7943
7944
7945
7946
7947
7948
7949
7950
7951
7952
7953
7954
7955
7956
7957
7958
7959
7960
7961
7962
7963
7964
7965
7966
7967
7968
7969
7970
7971
7972
7973
7974
7975
7976
7977
7978
7979
7980
7981
7982
7983
7984
7985
7986
7987
7988
7989
7990
7991
7992
7993
7994
7995
7996
7997
7998
7999
8000
8001
8002
8003
8004
8005
8006
8007
8008
8009
8010
8011
8012
8013
8014
8015
8016
8017
8018
8019
8020
8021
8022
8023
8024
8025
8026
8027
8028
8029
8030
8031
8032
8033
8034
8035
8036
8037
8038
8039
8040
8041
8042
8043
8044
8045
8046
8047
8048
8049
8050
8051
8052
8053
8054
8055
8056
8057
8058
8059
8060
8061
8062
8063
8064
8065
8066
8067
8068
8069
8070
8071
8072
8073
8074
8075
8076
8077
8078
8079
8080
8081
8082
8083
8084
8085
8086
8087
8088
8089
8090
8091
8092
8093
8094
8095
8096
8097
8098
8099
8100
8101
8102
8103
8104
8105
8106
8107
8108
8109
8110
8111
8112
8113
8114
8115
8116
8117
8118
8119
8120
8121
8122
8123
8124
8125
8126
8127
8128
8129
8130
8131
8132
8133
8134
8135
8136
8137
8138
8139
8140
8141
8142
8143
8144
8145
8146
8147
8148
8149
8150
8151
8152
8153
8154
8155
8156
8157
8158
8159
8160
8161
8162
8163
8164
8165
8166
8167
8168
8169
8170
8171
8172
8173
8174
8175
8176
8177
8178
8179
8180
8181
8182
8183
8184
8185
8186
8187
8188
8189
8190
8191
8192
8193
8194
8195
8196
8197
8198
8199
8200
8201
8202
8203
8204
8205
8206
8207
8208
8209
8210
8211
8212
8213
8214
8215
8216
8217
8218
8219
8220
8221
8222
8223
8224
8225
8226
8227
8228
8229
8230
8231
8232
8233
8234
8235
8236
8237
8238
8239
8240
8241
8242
8243
8244
8245
8246
8247
8248
8249
8250
8251
8252
8253
8254
8255
8256
8257
8258
8259
8260
8261
8262
8263
8264
8265
8266
8267
8268
8269
8270
8271
8272
8273
8274
8275
8276
8277
8278
8279
8280
8281
8282
8283
8284
8285
8286
8287
8288
8289
8290
8291
8292
8293
8294
8295
8296
8297
8298
8299
8300
8301
8302
8303
8304
8305
8306
8307
8308
8309
8310
8311
8312
8313
8314
8315
8316
8317
8318
8319
8320
8321
8322
8323
8324
8325
8326
8327
8328
8329
8330
8331
8332
8333
8334
8335
8336
8337
8338
8339
8340
8341
8342
8343
8344
8345
8346
8347
8348
8349
8350
8351
8352
8353
8354
8355
8356
8357
8358
8359
8360
8361
8362
8363
8364
8365
8366
8367
8368
8369
8370
8371
8372
8373
8374
8375
8376
8377
8378
8379
8380
8381
8382
8383
8384
8385
8386
8387
8388
8389
8390
8391
8392
8393
8394
8395
8396
8397
8398
8399
8400
8401
8402
8403
8404
8405
8406
8407
8408
8409
8410
8411
8412
8413
8414
8415
8416
8417
8418
8419
8420
8421
8422
8423
8424
8425
8426
8427
8428
8429
8430
8431
8432
8433
8434
8435
8436
8437
8438
8439
8440
8441
8442
8443
8444
8445
8446
8447
8448
8449
8450
8451
8452
8453
8454
8455
8456
8457
8458
8459
8460
8461
8462
8463
8464
8465
8466
8467
8468
8469
8470
8471
8472
8473
8474
8475
8476
8477
8478
8479
8480
8481
8482
8483
8484
8485
8486
8487
8488
8489
8490
8491
8492
8493
8494
8495
8496
8497
8498
8499
8500
8501
8502
8503
8504
8505
8506
8507
8508
8509
8510
8511
8512
8513
8514
8515
8516
8517
8518
8519
8520
8521
8522
8523
8524
8525
8526
8527
8528
8529
8530
8531
8532
8533
8534
8535
8536
8537
8538
8539
8540
8541
8542
8543
8544
8545
8546
8547
8548
8549
8550
8551
8552
8553
8554
8555
8556
8557
8558
8559
8560
8561
8562
8563
8564
8565
8566
8567
8568
8569
8570
8571
8572
8573
8574
8575
8576
8577
8578
8579
8580
8581
8582
8583
8584
8585
8586
8587
8588
8589
8590
8591
8592
8593
8594
8595
8596
8597
8598
8599
8600
8601
8602
8603
8604
8605
8606
8607
8608
8609
8610
8611
8612
8613
8614
8615
8616
8617
8618
8619
8620
8621
8622
8623
8624
8625
8626
8627
8628
8629
8630
8631
8632
8633
8634
8635
8636
8637
8638
8639
8640
8641
8642
8643
8644
8645
8646
8647
8648
8649
8650
8651
8652
8653
8654
8655
8656
8657
8658
8659
8660
8661
8662
8663
8664
8665
8666
8667
8668
8669
8670
8671
8672
8673
8674
8675
8676
8677
8678
8679
8680
8681
8682
8683
8684
8685
8686
8687
8688
8689
8690
8691
8692
8693
8694
8695
8696
8697
8698
8699
8700
8701
8702
8703
8704
8705
8706
8707
8708
8709
8710
8711
8712
8713
8714
8715
8716
8717
8718
8719
8720
8721
8722
8723
8724
8725
8726
8727
8728
8729
8730
8731
8732
8733
8734
8735
8736
8737
8738
8739
8740
8741
8742
8743
8744
8745
8746
8747
8748
8749
8750
8751
8752
8753
8754
8755
8756
8757
8758
8759
8760
8761
8762
8763
8764
8765
8766
8767
8768
8769
8770
8771
8772
8773
8774
8775
8776
8777
8778
8779
8780
8781
8782
8783
8784
8785
8786
8787
8788
8789
8790
8791
8792
8793
8794
8795
8796
8797
8798
8799
8800
8801
8802
8803
8804
8805
8806
8807
8808
8809
8810
8811
8812
8813
8814
8815
8816
8817
8818
8819
8820
8821
8822
8823
8824
8825
8826
8827
8828
8829
8830
8831
8832
8833
8834
8835
8836
8837
8838
8839
8840
8841
8842
8843
8844
8845
8846
8847
8848
8849
8850
8851
8852
8853
8854
8855
8856
8857
8858
8859
8860
8861
8862
8863
8864
8865
8866
8867
8868
8869
8870
8871
8872
8873
8874
8875
8876
8877
8878
8879
8880
8881
8882
8883
8884
8885
8886
8887
8888
8889
8890
8891
8892
8893
8894
8895
8896
8897
8898
8899
8900
8901
8902
8903
8904
8905
8906
8907
8908
8909
8910
8911
8912
8913
8914
8915
8916
8917
8918
8919
8920
8921
8922
8923
8924
8925
8926
8927
8928
8929
8930
8931
8932
8933
8934
8935
8936
8937
8938
8939
8940
8941
8942
8943
8944
8945
8946
8947
8948
8949
8950
8951
8952
8953
8954
8955
8956
8957
8958
8959
8960
8961
8962
8963
8964
8965
8966
8967
8968
8969
8970
8971
8972
8973
8974
8975
8976
8977
8978
8979
8980
8981
8982
8983
8984
8985
8986
8987
8988
8989
8990
8991
8992
8993
8994
8995
8996
8997
8998
8999
9000
9001
9002
9003
9004
9005
9006
9007
9008
9009
9010
9011
9012
9013
9014
9015
9016
9017
9018
9019
9020
9021
9022
9023
9024
9025
9026
9027
9028
9029
9030
9031
9032
9033
9034
9035
9036
9037
9038
9039
9040
9041
9042
9043
9044
9045
9046
9047
9048
9049
9050
9051
9052
9053
9054
9055
9056
9057
9058
9059
9060
9061
9062
9063
9064
9065
9066
9067
9068
9069
9070
9071
9072
9073
9074
9075
9076
9077
9078
9079
9080
9081
9082
9083
9084
9085
9086
9087
9088
9089
9090
9091
9092
9093
9094
9095
9096
9097
9098
9099
9100
9101
9102
9103
9104
9105
9106
9107
9108
9109
9110
9111
9112
9113
9114
9115
9116
9117
9118
9119
9120
9121
9122
9123
9124
9125
9126
9127
9128
9129
9130
9131
9132
9133
9134
9135
9136
9137
9138
9139
9140
9141
9142
9143
9144
9145
9146
9147
9148
9149
9150
9151
9152
9153
9154
9155
9156
9157
9158
9159
9160
9161
9162
9163
9164
9165
9166
9167
9168
9169
9170
9171
9172
9173
9174
9175
9176
9177
9178
9179
9180
9181
9182
9183
9184
9185
9186
9187
9188
9189
9190
9191
9192
9193
9194
9195
9196
9197
9198
9199
9200
9201
9202
9203
9204
9205
9206
9207
9208
9209
9210
9211
9212
9213
9214
9215
9216
9217
9218
9219
9220
9221
9222
9223
9224
9225
9226
9227
9228
9229
9230
9231
9232
9233
9234
9235
9236
9237
9238
9239
9240
9241
9242
9243
9244
9245
9246
9247
9248
9249
9250
9251
9252
9253
9254
9255
9256
9257
9258
9259
9260
9261
9262
9263
9264
9265
9266
9267
9268
9269
9270
9271
9272
9273
9274
9275
9276
9277
9278
9279
9280
9281
9282
9283
9284
9285
9286
9287
9288
9289
9290
9291
9292
9293
9294
9295
9296
9297
9298
9299
9300
9301
9302
9303
9304
9305
9306
9307
9308
9309
9310
9311
9312
9313
9314
9315
9316
9317
9318
9319
9320
9321
9322
9323
9324
9325
9326
9327
9328
9329
9330
9331
9332
9333
9334
9335
9336
9337
9338
9339
9340
9341
9342
9343
9344
9345
9346
9347
9348
9349
9350
9351
9352
9353
9354
9355
9356
9357
9358
9359
9360
9361
9362
9363
9364
9365
9366
9367
9368
9369
9370
9371
9372
9373
9374
9375
9376
9377
9378
9379
9380
9381
9382
9383
9384
9385
9386
9387
9388
9389
9390
9391
9392
9393
9394
9395
9396
9397
9398
9399
9400
9401
9402
9403
9404
9405
9406
9407
9408
9409
9410
9411
9412
9413
9414
9415
9416
9417
9418
9419
9420
9421
9422
9423
9424
9425
9426
9427
9428
9429
9430
9431
9432
9433
9434
9435
9436
9437
9438
9439
9440
9441
9442
9443
9444
9445
9446
9447
9448
9449
9450
9451
9452
9453
9454
9455
9456
9457
9458
9459
9460
9461
9462
9463
9464
9465
9466
9467
9468
9469
9470
9471
9472
9473
9474
9475
9476
9477
9478
9479
9480
9481
9482
9483
9484
9485
9486
9487
9488
9489
9490
9491
9492
9493
9494
9495
9496
9497
9498
9499
9500
9501
9502
9503
9504
9505
9506
9507
9508
9509
9510
9511
9512
9513
9514
9515
9516
9517
9518
9519
9520
9521
9522
9523
9524
9525
9526
9527
9528
9529
9530
9531
9532
9533
9534
9535
9536
9537
9538
9539
9540
9541
9542
9543
9544
9545
9546
9547
9548
9549
9550
9551
9552
9553
9554
9555
9556
9557
9558
9559
9560
9561
9562
9563
9564
9565
9566
9567
9568
9569
9570
9571
9572
9573
9574
9575
9576
9577
9578
9579
9580
9581
9582
9583
9584
9585
9586
9587
9588
9589
9590
9591
9592
9593
9594
9595
9596
9597
9598
9599
9600
9601
9602
9603
9604
9605
9606
9607
9608
9609
9610
9611
9612
9613
9614
9615
9616
9617
9618
9619
9620
9621
9622
9623
9624
9625
9626
9627
9628
9629
9630
9631
9632
9633
9634
9635
9636
9637
9638
9639
9640
9641
9642
9643
9644
9645
9646
9647
9648
9649
9650
9651
9652
9653
9654
9655
9656
9657
9658
9659
9660
9661
9662
9663
9664
9665
9666
9667
9668
9669
9670
9671
9672
9673
9674
9675
9676
9677
9678
9679
9680
9681
9682
9683
9684
9685
9686
9687
9688
9689
9690
9691
9692
9693
9694
9695
9696
9697
9698
9699
9700
9701
9702
9703
9704
9705
9706
9707
9708
9709
9710
9711
9712
9713
9714
9715
9716
9717
9718
9719
9720
9721
9722
9723
9724
9725
9726
9727
9728
9729
9730
9731
9732
9733
9734
9735
9736
9737
9738
9739
9740
9741
9742
9743
9744
9745
9746
9747
9748
9749
9750
9751
9752
9753
9754
9755
9756
9757
9758
9759
9760
9761
9762
9763
9764
9765
9766
9767
9768
9769
9770
9771
9772
9773
9774
9775
9776
9777
9778
9779
9780
9781
9782
9783
9784
9785
9786
9787
9788
9789
9790
9791
9792
9793
9794
9795
9796
9797
9798
9799
9800
9801
9802
9803
9804
9805
9806
9807
9808
9809
9810
9811
9812
9813
9814
9815
9816
9817
9818
9819
9820
9821
9822
9823
9824
9825
9826
9827
9828
9829
9830
9831
9832
9833
9834
9835
9836
9837
9838
9839
9840
9841
9842
9843
9844
9845
9846
9847
9848
9849
9850
9851
9852
9853
9854
9855
9856
9857
9858
9859
9860
9861
9862
9863
9864
9865
9866
9867
9868
9869
9870
9871
9872
9873
9874
9875
9876
9877
9878
9879
9880
9881
9882
9883
9884
9885
9886
9887
9888
9889
9890
9891
9892
9893
9894
9895
9896
9897
9898
9899
9900
9901
9902
9903
9904
9905
9906
9907
9908
9909
9910
9911
9912
9913
9914
9915
9916
9917
9918
9919
9920
9921
9922
9923
9924
9925
9926
9927
9928
9929
9930
9931
9932
9933
9934
9935
9936
9937
9938
9939
9940
9941
9942
9943
9944
9945
9946
9947
9948
9949
9950
9951
9952
9953
9954
9955
9956
9957
9958
9959
9960
9961
9962
9963
9964
9965
9966
9967
9968
9969
9970
9971
9972
9973
9974
9975
9976
9977
9978
9979
9980
9981
9982
9983
9984
9985
9986
9987
9988
9989
9990
9991
9992
9993
9994
9995
9996
9997
9998
9999
10000
10001
10002
10003
10004
10005
10006
10007
10008
10009
10010
10011
10012
10013
10014
10015
10016
10017
10018
10019
10020
10021
10022
10023
10024
10025
10026
10027
10028
10029
10030
10031
10032
10033
10034
10035
10036
10037
10038
10039
10040
10041
10042
10043
10044
10045
10046
10047
10048
10049
10050
10051
10052
10053
10054
10055
10056
10057
10058
10059
10060
10061
10062
10063
10064
10065
10066
10067
10068
10069
10070
10071
10072
10073
10074
10075
10076
10077
10078
10079
10080
10081
10082
10083
10084
10085
10086
10087
10088
10089
10090
10091
10092
10093
10094
10095
10096
10097
10098
10099
10100
10101
10102
10103
10104
10105
10106
10107
10108
10109
10110
10111
10112
10113
10114
10115
10116
10117
10118
10119
10120
10121
10122
10123
10124
10125
10126
10127
10128
10129
10130
10131
10132
10133
10134
10135
10136
10137
10138
10139
10140
10141
10142
10143
10144
10145
10146
10147
10148
10149
10150
10151
10152
10153
10154
10155
10156
10157
10158
10159
10160
10161
10162
10163
10164
10165
10166
10167
10168
10169
10170
10171
10172
10173
10174
10175
10176
10177
10178
10179
10180
10181
10182
10183
10184
10185
10186
10187
10188
10189
10190
10191
10192
10193
10194
10195
10196
10197
10198
10199
10200
10201
10202
10203
10204
10205
10206
10207
10208
10209
10210
10211
10212
10213
10214
10215
10216
10217
10218
10219
10220
10221
10222
10223
10224
10225
10226
10227
10228
10229
10230
10231
10232
10233
10234
10235
10236
10237
10238
10239
10240
10241
10242
10243
10244
10245
10246
10247
10248
10249
10250
10251
10252
10253
10254
10255
10256
10257
10258
10259
10260
10261
10262
10263
10264
10265
10266
10267
10268
10269
10270
10271
10272
10273
10274
10275
10276
10277
10278
10279
10280
10281
10282
10283
10284
10285
10286
10287
10288
10289
10290
10291
10292
10293
10294
10295
10296
10297
10298
10299
10300
10301
10302
10303
10304
10305
10306
10307
10308
10309
10310
10311
10312
10313
10314
10315
10316
10317
10318
10319
10320
10321
10322
10323
10324
10325
10326
10327
10328
10329
10330
10331
10332
10333
10334
10335
10336
10337
10338
10339
10340
10341
10342
10343
10344
10345
10346
10347
10348
10349
10350
10351
10352
10353
10354
10355
10356
10357
10358
10359
10360
10361
10362
10363
10364
10365
10366
10367
10368
10369
10370
10371
10372
10373
10374
10375
10376
10377
10378
10379
10380
10381
10382
10383
10384
10385
10386
10387
10388
10389
10390
10391
10392
10393
10394
10395
10396
10397
10398
10399
10400
10401
10402
10403
10404
10405
10406
10407
10408
10409
10410
10411
10412
10413
10414
10415
10416
10417
10418
10419
10420
10421
10422
10423
10424
10425
10426
10427
10428
10429
10430
10431
10432
10433
10434
10435
10436
10437
10438
10439
10440
10441
10442
10443
10444
10445
10446
10447
10448
10449
10450
10451
10452
10453
10454
10455
10456
10457
10458
10459
10460
10461
10462
10463
10464
10465
10466
10467
10468
10469
10470
10471
10472
10473
10474
10475
10476
10477
10478
10479
10480
10481
10482
10483
10484
10485
10486
10487
10488
10489
10490
10491
10492
10493
10494
10495
10496
10497
10498
10499
10500
10501
10502
10503
10504
10505
10506
10507
10508
10509
10510
10511
10512
10513
10514
10515
10516
10517
10518
10519
10520
10521
10522
10523
10524
10525
10526
10527
10528
10529
10530
10531
10532
10533
10534
10535
10536
10537
10538
10539
10540
10541
10542
10543
10544
10545
10546
10547
10548
10549
10550
10551
10552
10553
10554
10555
10556
10557
10558
10559
10560
10561
10562
10563
10564
10565
10566
10567
10568
10569
10570
10571
10572
10573
10574
10575
10576
10577
10578
10579
10580
10581
10582
10583
10584
10585
10586
10587
10588
10589
10590
10591
10592
10593
10594
10595
10596
10597
10598
10599
10600
10601
10602
10603
10604
10605
10606
10607
10608
10609
10610
10611
10612
10613
10614
10615
10616
10617
10618
10619
10620
10621
10622
10623
10624
10625
10626
10627
10628
10629
10630
10631
10632
10633
10634
10635
10636
10637
10638
10639
10640
10641
10642
10643
10644
10645
10646
10647
10648
10649
10650
10651
10652
10653
10654
10655
10656
10657
10658
10659
10660
10661
10662
10663
10664
10665
10666
10667
10668
10669
10670
10671
10672
10673
10674
10675
10676
10677
10678
10679
10680
10681
10682
10683
10684
10685
10686
10687
10688
10689
10690
10691
10692
10693
10694
10695
10696
10697
10698
10699
10700
10701
10702
10703
10704
10705
10706
10707
10708
10709
10710
10711
10712
10713
10714
10715
10716
10717
10718
10719
10720
10721
10722
10723
10724
10725
10726
10727
10728
10729
10730
10731
10732
10733
10734
10735
10736
10737
10738
10739
10740
10741
10742
10743
10744
10745
10746
10747
10748
10749
10750
10751
10752
10753
10754
10755
10756
10757
10758
10759
10760
10761
10762
10763
10764
10765
10766
10767
10768
10769
10770
10771
10772
10773
10774
10775
10776
10777
10778
10779
10780
10781
10782
10783
10784
10785
10786
10787
10788
10789
10790
10791
10792
10793
10794
10795
10796
10797
10798
10799
10800
10801
10802
10803
10804
10805
10806
10807
10808
10809
10810
10811
10812
10813
10814
10815
10816
10817
10818
10819
10820
10821
10822
10823
10824
10825
10826
10827
10828
10829
10830
10831
10832
10833
10834
10835
10836
10837
10838
10839
10840
10841
10842
10843
10844
10845
10846
10847
10848
10849
10850
10851
10852
10853
10854
10855
10856
10857
10858
10859
10860
10861
10862
10863
10864
10865
10866
10867
10868
10869
10870
10871
10872
10873
10874
10875
10876
10877
10878
10879
10880
10881
10882
10883
10884
10885
10886
10887
10888
10889
10890
10891
10892
10893
10894
10895
10896
10897
10898
10899
10900
10901
10902
10903
10904
10905
10906
10907
10908
10909
10910
10911
10912
10913
10914
10915
10916
10917
10918
10919
10920
10921
10922
10923
10924
10925
10926
10927
10928
10929
10930
10931
10932
10933
10934
10935
10936
10937
10938
10939
10940
10941
10942
10943
10944
10945
10946
10947
10948
10949
10950
10951
10952
10953
10954
10955
10956
10957
10958
10959
10960
10961
10962
10963
10964
10965
10966
10967
10968
10969
10970
10971
10972
10973
10974
10975
10976
10977
10978
10979
10980
10981
10982
10983
10984
10985
10986
10987
10988
10989
10990
10991
10992
10993
10994
10995
10996
10997
10998
10999
11000
11001
11002
11003
11004
11005
11006
11007
11008
11009
11010
11011
11012
11013
11014
11015
11016
11017
11018
11019
11020
11021
11022
11023
11024
11025
11026
11027
11028
11029
11030
11031
11032
11033
11034
11035
11036
11037
11038
11039
11040
11041
11042
11043
11044
11045
11046
11047
11048
11049
11050
11051
11052
11053
11054
11055
11056
11057
11058
11059
11060
11061
11062
11063
11064
11065
11066
11067
11068
11069
11070
11071
11072
11073
11074
11075
11076
11077
11078
11079
11080
11081
11082
11083
11084
11085
11086
11087
11088
11089
11090
11091
11092
11093
11094
11095
11096
11097
11098
11099
11100
11101
11102
11103
11104
11105
11106
11107
11108
11109
11110
11111
11112
11113
11114
11115
11116
11117
11118
11119
11120
11121
11122
11123
11124
11125
11126
11127
11128
11129
11130
11131
11132
11133
11134
11135
11136
11137
11138
11139
11140
11141
11142
11143
11144
11145
11146
11147
11148
11149
11150
11151
11152
11153
11154
11155
11156
11157
11158
11159
11160
11161
11162
11163
11164
11165
11166
11167
11168
11169
11170
11171
11172
11173
11174
11175
11176
11177
11178
11179
11180
11181
11182
11183
11184
11185
11186
11187
11188
11189
11190
11191
11192
11193
11194
11195
11196
11197
11198
11199
11200
11201
11202
11203
11204
11205
11206
11207
11208
11209
11210
11211
11212
11213
11214
11215
11216
11217
11218
11219
11220
11221
11222
11223
11224
11225
11226
11227
11228
11229
11230
11231
11232
11233
11234
11235
11236
11237
11238
11239
11240
11241
11242
11243
11244
11245
11246
11247
11248
11249
11250
11251
11252
11253
11254
11255
11256
11257
11258
11259
11260
11261
11262
11263
11264
11265
11266
11267
11268
11269
11270
11271
11272
11273
11274
11275
11276
11277
11278
11279
11280
11281
11282
11283
11284
11285
11286
11287
11288
11289
11290
11291
11292
11293
11294
11295
11296
11297
11298
11299
11300
11301
11302
11303
11304
11305
11306
11307
11308
11309
11310
11311
11312
11313
11314
11315
11316
11317
11318
11319
11320
11321
11322
11323
11324
11325
11326
11327
11328
11329
11330
11331
11332
11333
11334
11335
11336
11337
11338
11339
11340
11341
11342
11343
11344
11345
11346
11347
11348
11349
11350
11351
11352
11353
11354
11355
11356
11357
11358
11359
11360
11361
11362
11363
11364
11365
11366
11367
11368
11369
11370
11371
11372
11373
11374
11375
11376
11377
11378
11379
11380
11381
11382
11383
11384
11385
11386
11387
11388
11389
11390
11391
11392
11393
11394
11395
11396
11397
11398
11399
11400
11401
11402
11403
11404
11405
11406
11407
11408
11409
11410
11411
11412
11413
11414
11415
11416
11417
11418
11419
11420
11421
11422
11423
11424
11425
11426
11427
11428
11429
11430
11431
11432
11433
11434
11435
11436
11437
11438
11439
11440
11441
11442
11443
11444
11445
11446
11447
11448
11449
11450
11451
11452
11453
11454
11455
11456
11457
11458
11459
11460
11461
11462
11463
11464
11465
11466
11467
11468
11469
11470
11471
11472
11473
11474
11475
11476
11477
11478
11479
11480
11481
11482
11483
11484
11485
11486
11487
11488
11489
11490
11491
11492
11493
11494
11495
11496
11497
11498
11499
11500
11501
11502
11503
11504
11505
11506
11507
11508
11509
11510
11511
11512
11513
11514
11515
11516
11517
11518
11519
11520
11521
11522
11523
11524
11525
11526
11527
11528
11529
11530
11531
11532
11533
11534
11535
11536
11537
11538
11539
11540
11541
11542
11543
11544
11545
11546
11547
11548
11549
11550
11551
11552
11553
11554
11555
11556
11557
11558
11559
11560
11561
11562
11563
11564
11565
11566
11567
11568
11569
11570
11571
11572
11573
11574
11575
11576
11577
11578
11579
11580
11581
11582
11583
11584
11585
11586
11587
11588
11589
11590
11591
11592
11593
11594
11595
11596
11597
11598
11599
11600
11601
11602
11603
11604
11605
11606
11607
11608
11609
11610
11611
11612
11613
11614
11615
11616
11617
11618
11619
11620
11621
11622
11623
11624
11625
11626
11627
11628
11629
11630
11631
11632
11633
11634
11635
11636
11637
11638
11639
11640
11641
11642
11643
11644
11645
11646
11647
11648
11649
11650
11651
11652
11653
11654
11655
11656
11657
11658
11659
11660
11661
11662
11663
11664
11665
11666
11667
11668
11669
11670
11671
11672
11673
11674
11675
11676
11677
11678
11679
11680
11681
11682
11683
11684
11685
11686
11687
11688
11689
11690
11691
11692
11693
11694
11695
11696
11697
11698
11699
11700
11701
11702
11703
11704
11705
11706
11707
11708
11709
11710
11711
11712
11713
11714
11715
11716
11717
11718
11719
11720
11721
11722
11723
11724
11725
11726
11727
11728
11729
11730
11731
11732
11733
11734
11735
11736
11737
11738
11739
11740
11741
11742
11743
11744
11745
11746
11747
11748
11749
11750
11751
11752
11753
11754
11755
11756
11757
11758
11759
11760
11761
11762
11763
11764
11765
11766
11767
11768
11769
11770
11771
11772
11773
11774
11775
11776
11777
11778
11779
11780
11781
11782
11783
11784
11785
11786
11787
11788
11789
11790
11791
11792
11793
11794
11795
11796
11797
11798
11799
11800
11801
11802
11803
11804
11805
11806
11807
11808
11809
11810
11811
11812
11813
11814
11815
11816
11817
11818
11819
11820
11821
11822
11823
11824
11825
11826
11827
11828
11829
11830
11831
11832
11833
11834
11835
11836
11837
11838
11839
11840
11841
11842
11843
11844
11845
11846
11847
11848
11849
11850
11851
11852
11853
11854
11855
11856
11857
11858
11859
11860
11861
11862
11863
11864
11865
11866
11867
11868
11869
11870
11871
11872
11873
11874
11875
11876
11877
11878
11879
11880
11881
11882
11883
11884
11885
11886
11887
11888
11889
11890
11891
11892
11893
11894
11895
11896
11897
11898
11899
11900
11901
11902
11903
11904
11905
11906
11907
11908
11909
11910
11911
11912
11913
11914
11915
11916
11917
11918
11919
11920
11921
11922
11923
11924
11925
11926
11927
11928
11929
11930
11931
11932
11933
11934
11935
11936
11937
11938
11939
11940
11941
11942
11943
11944
11945
11946
11947
11948
11949
11950
11951
11952
11953
11954
11955
11956
11957
11958
11959
11960
11961
11962
11963
11964
11965
11966
11967
11968
11969
11970
11971
11972
11973
11974
11975
11976
11977
11978
11979
11980
11981
11982
11983
11984
11985
11986
11987
11988
11989
11990
11991
11992
11993
11994
11995
11996
11997
11998
11999
12000
12001
12002
12003
12004
12005
12006
12007
12008
12009
12010
12011
12012
12013
12014
12015
12016
12017
12018
12019
12020
12021
12022
12023
12024
12025
12026
12027
12028
12029
12030
12031
12032
12033
12034
12035
12036
12037
12038
12039
12040
12041
12042
12043
12044
12045
12046
12047
12048
12049
12050
12051
12052
12053
12054
12055
12056
12057
12058
12059
12060
12061
12062
12063
12064
12065
12066
12067
12068
12069
12070
12071
12072
12073
12074
12075
12076
12077
12078
12079
12080
12081
12082
12083
12084
12085
12086
12087
12088
12089
12090
12091
12092
12093
12094
12095
12096
12097
12098
12099
12100
12101
12102
12103
12104
12105
12106
12107
12108
12109
12110
12111
12112
12113
12114
12115
12116
12117
12118
12119
12120
12121
12122
12123
12124
12125
12126
12127
12128
12129
12130
12131
12132
12133
12134
12135
12136
12137
12138
12139
12140
12141
12142
12143
12144
12145
12146
12147
12148
12149
12150
12151
12152
12153
12154
12155
12156
12157
12158
12159
12160
12161
12162
12163
12164
12165
12166
12167
12168
12169
12170
12171
12172
12173
12174
12175
12176
12177
12178
12179
12180
12181
12182
12183
12184
12185
12186
12187
12188
12189
12190
12191
12192
12193
12194
12195
12196
12197
12198
12199
12200
12201
12202
12203
12204
12205
12206
12207
12208
12209
12210
12211
12212
12213
12214
12215
12216
12217
12218
12219
12220
12221
12222
12223
12224
12225
12226
12227
12228
12229
12230
12231
12232
12233
12234
12235
12236
12237
12238
12239
12240
12241
12242
12243
12244
12245
12246
12247
12248
12249
12250
12251
12252
12253
12254
12255
12256
12257
12258
12259
12260
12261
12262
12263
12264
12265
12266
12267
12268
12269
12270
12271
12272
12273
12274
12275
12276
12277
12278
12279
12280
12281
12282
12283
12284
12285
12286
12287
12288
12289
12290
12291
12292
12293
12294
12295
12296
12297
12298
12299
12300
12301
12302
12303
12304
12305
12306
12307
12308
12309
12310
12311
12312
12313
12314
12315
12316
12317
12318
12319
12320
12321
12322
12323
12324
12325
12326
12327
12328
12329
12330
12331
12332
12333
12334
12335
12336
12337
12338
12339
12340
12341
12342
12343
12344
12345
12346
12347
12348
12349
12350
12351
12352
12353
12354
12355
12356
12357
12358
12359
12360
12361
12362
12363
12364
12365
12366
12367
12368
12369
12370
12371
12372
12373
12374
12375
12376
12377
12378
12379
12380
12381
12382
12383
12384
12385
12386
12387
12388
12389
12390
12391
12392
12393
12394
12395
12396
12397
12398
12399
12400
12401
12402
12403
12404
12405
12406
12407
12408
12409
12410
12411
12412
12413
12414
12415
12416
12417
12418
12419
12420
12421
12422
12423
12424
12425
12426
12427
12428
12429
12430
12431
12432
12433
12434
12435
12436
12437
12438
12439
12440
12441
12442
12443
12444
12445
12446
12447
12448
12449
12450
12451
12452
12453
12454
12455
12456
12457
12458
12459
12460
12461
12462
12463
12464
12465
12466
12467
12468
12469
12470
12471
12472
12473
12474
12475
12476
12477
12478
12479
12480
12481
12482
12483
12484
12485
12486
12487
12488
12489
12490
12491
12492
12493
12494
12495
12496
12497
12498
12499
12500
12501
12502
12503
12504
12505
12506
12507
12508
12509
12510
12511
12512
12513
12514
12515
12516
12517
12518
12519
12520
12521
12522
12523
12524
12525
12526
12527
12528
12529
12530
12531
12532
12533
12534
12535
12536
12537
12538
12539
12540
12541
12542
12543
12544
12545
12546
12547
12548
12549
12550
12551
12552
12553
12554
12555
12556
12557
12558
12559
12560
12561
12562
12563
12564
12565
12566
12567
12568
12569
12570
12571
12572
12573
12574
12575
12576
12577
12578
12579
12580
12581
12582
12583
12584
12585
12586
12587
12588
12589
12590
12591
12592
12593
12594
12595
12596
12597
12598
12599
12600
12601
12602
12603
12604
12605
12606
12607
12608
12609
12610
12611
12612
12613
12614
12615
12616
12617
12618
12619
12620
12621
12622
12623
12624
12625
12626
12627
12628
12629
12630
12631
12632
12633
12634
12635
12636
12637
12638
12639
12640
12641
12642
12643
12644
12645
12646
12647
12648
12649
12650
12651
12652
12653
12654
12655
12656
12657
12658
12659
12660
12661
12662
12663
12664
12665
12666
12667
12668
12669
12670
12671
12672
12673
12674
12675
12676
12677
12678
12679
12680
12681
12682
12683
12684
12685
12686
12687
12688
12689
12690
12691
12692
12693
12694
12695
12696
12697
12698
12699
12700
12701
12702
12703
12704
12705
12706
12707
12708
12709
12710
12711
12712
12713
12714
12715
12716
12717
12718
12719
12720
12721
12722
12723
12724
12725
12726
12727
12728
12729
12730
12731
12732
12733
12734
12735
12736
12737
12738
12739
12740
12741
12742
12743
12744
12745
12746
12747
12748
12749
12750
12751
12752
12753
12754
12755
12756
12757
12758
12759
12760
12761
12762
12763
12764
12765
12766
12767
12768
12769
12770
12771
12772
12773
12774
12775
12776
12777
12778
12779
12780
12781
12782
12783
12784
12785
12786
12787
12788
12789
12790
12791
12792
12793
12794
12795
12796
12797
12798
12799
12800
12801
12802
12803
12804
12805
12806
12807
12808
12809
12810
12811
12812
12813
12814
12815
12816
12817
12818
12819
12820
12821
12822
12823
12824
12825
12826
12827
12828
12829
12830
12831
12832
12833
12834
12835
12836
12837
12838
12839
12840
12841
12842
12843
12844
12845
12846
12847
12848
12849
12850
12851
12852
12853
12854
12855
12856
12857
12858
12859
12860
12861
12862
12863
12864
12865
12866
12867
12868
12869
12870
12871
12872
12873
12874
12875
12876
12877
12878
12879
12880
12881
12882
12883
12884
12885
12886
12887
12888
12889
12890
12891
12892
12893
12894
12895
12896
12897
12898
12899
12900
12901
12902
12903
12904
12905
12906
12907
12908
12909
12910
12911
12912
12913
12914
12915
12916
12917
12918
12919
12920
12921
12922
12923
12924
12925
12926
12927
12928
12929
12930
12931
12932
12933
12934
12935
12936
12937
12938
12939
12940
12941
12942
12943
12944
12945
12946
12947
12948
12949
12950
12951
12952
12953
12954
12955
12956
12957
12958
12959
12960
12961
12962
12963
12964
12965
12966
12967
12968
12969
12970
12971
12972
12973
12974
12975
12976
12977
12978
12979
12980
12981
12982
12983
12984
12985
12986
12987
12988
12989
12990
12991
12992
12993
12994
12995
12996
12997
12998
12999
13000
13001
13002
13003
13004
13005
13006
13007
13008
13009
13010
13011
13012
13013
13014
13015
13016
13017
13018
13019
13020
13021
13022
13023
13024
13025
13026
13027
13028
13029
13030
13031
13032
13033
13034
13035
13036
13037
13038
13039
13040
13041
13042
13043
13044
13045
13046
13047
13048
13049
13050
13051
13052
13053
13054
13055
13056
13057
13058
13059
13060
13061
13062
13063
13064
13065
13066
13067
13068
13069
13070
13071
13072
13073
13074
13075
13076
13077
13078
13079
13080
13081
13082
13083
13084
13085
13086
13087
13088
13089
13090
13091
13092
13093
13094
13095
13096
13097
13098
13099
13100
13101
13102
13103
13104
13105
13106
13107
13108
13109
13110
13111
13112
13113
13114
13115
13116
13117
13118
13119
13120
13121
13122
13123
13124
13125
13126
13127
13128
13129
13130
13131
13132
13133
13134
13135
13136
13137
13138
13139
13140
13141
13142
13143
13144
13145
13146
13147
13148
13149
13150
13151
13152
13153
13154
13155
13156
13157
13158
13159
13160
13161
13162
13163
13164
13165
13166
13167
13168
13169
13170
13171
13172
13173
13174
13175
13176
13177
13178
13179
13180
13181
13182
13183
13184
13185
13186
13187
13188
13189
13190
13191
13192
13193
13194
13195
13196
13197
13198
13199
13200
13201
13202
13203
13204
13205
13206
13207
13208
13209
13210
13211
13212
13213
13214
13215
13216
13217
13218
13219
13220
13221
13222
13223
13224
13225
13226
13227
13228
13229
13230
13231
13232
13233
13234
13235
13236
13237
13238
13239
13240
13241
13242
13243
13244
13245
13246
13247
13248
13249
13250
13251
13252
13253
13254
13255
13256
13257
13258
13259
13260
13261
13262
13263
13264
13265
13266
13267
13268
13269
13270
13271
13272
13273
13274
13275
13276
13277
13278
13279
13280
13281
13282
13283
13284
13285
13286
13287
13288
13289
13290
13291
13292
13293
13294
13295
13296
13297
13298
13299
13300
13301
13302
13303
13304
13305
13306
13307
13308
13309
13310
13311
13312
13313
13314
13315
13316
13317
13318
13319
13320
13321
13322
13323
13324
13325
13326
13327
13328
13329
13330
13331
13332
13333
13334
13335
13336
13337
13338
13339
13340
13341
13342
13343
13344
13345
13346
13347
13348
13349
13350
13351
13352
13353
13354
13355
13356
13357
13358
13359
13360
13361
13362
13363
13364
13365
13366
13367
13368
13369
13370
13371
13372
13373
13374
13375
13376
13377
13378
13379
13380
13381
13382
13383
13384
13385
13386
13387
13388
13389
13390
13391
13392
13393
13394
13395
13396
13397
13398
13399
13400
13401
13402
13403
13404
13405
13406
13407
13408
13409
13410
13411
13412
13413
13414
13415
13416
13417
13418
13419
13420
13421
13422
13423
13424
13425
13426
13427
13428
13429
13430
13431
13432
13433
13434
13435
13436
13437
13438
13439
13440
13441
13442
13443
13444
13445
13446
13447
13448
13449
13450
13451
13452
13453
13454
13455
13456
13457
13458
13459
13460
13461
13462
13463
13464
13465
13466
13467
13468
13469
13470
13471
13472
13473
13474
13475
13476
13477
13478
13479
13480
13481
13482
13483
13484
13485
13486
13487
13488
13489
13490
13491
13492
13493
13494
13495
13496
13497
13498
13499
13500
13501
13502
13503
13504
13505
13506
13507
13508
13509
13510
13511
13512
13513
13514
13515
13516
13517
13518
13519
13520
13521
13522
13523
13524
13525
13526
13527
13528
13529
13530
13531
13532
13533
13534
13535
13536
13537
13538
13539
13540
13541
13542
13543
13544
13545
13546
13547
13548
13549
13550
13551
13552
13553
13554
13555
13556
13557
13558
13559
13560
13561
13562
13563
13564
13565
13566
13567
13568
13569
13570
13571
13572
13573
13574
13575
13576
13577
13578
13579
13580
13581
13582
13583
13584
13585
13586
13587
13588
13589
13590
13591
13592
13593
13594
13595
13596
13597
13598
13599
13600
13601
13602
13603
13604
13605
13606
13607
13608
13609
13610
13611
13612
13613
13614
13615
13616
13617
13618
13619
13620
13621
13622
13623
13624
13625
13626
13627
13628
13629
13630
13631
13632
13633
13634
13635
13636
13637
13638
13639
13640
13641
13642
13643
13644
13645
13646
13647
13648
13649
13650
13651
13652
13653
13654
13655
13656
13657
13658
13659
13660
13661
13662
13663
13664
13665
13666
13667
13668
13669
13670
13671
13672
13673
13674
13675
13676
13677
13678
13679
13680
13681
13682
13683
13684
13685
13686
13687
13688
13689
13690
13691
13692
13693
13694
13695
13696
13697
13698
13699
13700
13701
13702
13703
13704
13705
13706
13707
13708
13709
13710
13711
13712
13713
13714
13715
13716
13717
13718
13719
13720
13721
13722
13723
13724
13725
13726
13727
13728
13729
13730
13731
13732
13733
13734
13735
13736
13737
13738
13739
13740
13741
13742
13743
13744
13745
13746
13747
13748
13749
13750
13751
13752
13753
13754
13755
13756
13757
13758
13759
13760
13761
13762
13763
13764
13765
13766
13767
13768
13769
13770
13771
13772
13773
13774
13775
13776
13777
13778
13779
13780
13781
13782
13783
13784
13785
13786
13787
13788
13789
13790
13791
13792
13793
13794
13795
13796
13797
13798
13799
13800
13801
13802
13803
13804
13805
13806
13807
13808
13809
13810
13811
13812
13813
13814
13815
13816
13817
13818
13819
13820
13821
13822
13823
13824
13825
13826
13827
13828
13829
13830
13831
13832
13833
13834
13835
13836
13837
13838
13839
13840
13841
13842
13843
13844
13845
13846
13847
13848
13849
13850
13851
13852
13853
13854
13855
13856
13857
13858
13859
13860
13861
13862
13863
13864
13865
13866
13867
13868
13869
13870
13871
13872
13873
13874
13875
13876
13877
13878
13879
13880
13881
13882
13883
13884
13885
13886
13887
13888
13889
13890
13891
13892
13893
13894
13895
13896
13897
13898
13899
13900
13901
13902
13903
13904
13905
13906
13907
13908
13909
13910
13911
13912
13913
13914
13915
13916
13917
13918
13919
13920
13921
13922
13923
13924
13925
13926
13927
13928
13929
13930
13931
13932
13933
13934
13935
13936
13937
13938
13939
13940
13941
13942
13943
13944
13945
13946
13947
13948
13949
13950
13951
13952
13953
13954
13955
13956
13957
13958
13959
13960
13961
13962
13963
13964
13965
13966
13967
13968
13969
13970
13971
13972
13973
13974
13975
13976
13977
13978
13979
13980
13981
13982
13983
13984
13985
13986
13987
13988
13989
13990
13991
13992
13993
13994
13995
13996
13997
13998
13999
14000
14001
14002
14003
14004
14005
14006
14007
14008
14009
14010
14011
14012
14013
14014
14015
14016
14017
14018
14019
14020
14021
14022
14023
14024
14025
14026
14027
14028
14029
14030
14031
14032
14033
14034
14035
14036
14037
14038
14039
14040
14041
14042
14043
14044
14045
14046
14047
14048
14049
14050
14051
14052
14053
14054
14055
14056
14057
14058
14059
14060
14061
14062
14063
14064
14065
14066
14067
14068
14069
14070
14071
14072
14073
14074
14075
14076
14077
14078
14079
14080
14081
14082
14083
14084
14085
14086
14087
14088
14089
14090
14091
14092
14093
14094
14095
14096
14097
14098
14099
14100
14101
14102
14103
14104
14105
14106
14107
14108
14109
14110
14111
14112
14113
14114
14115
14116
14117
14118
14119
14120
14121
14122
14123
14124
14125
14126
14127
14128
14129
14130
14131
14132
14133
14134
14135
14136
14137
14138
14139
14140
14141
14142
14143
14144
14145
14146
14147
14148
14149
14150
14151
14152
14153
14154
14155
14156
14157
14158
14159
14160
14161
14162
14163
14164
14165
14166
14167
14168
14169
14170
14171
14172
14173
14174
14175
14176
14177
14178
14179
14180
14181
14182
14183
14184
14185
14186
14187
14188
14189
14190
14191
14192
14193
14194
14195
14196
14197
14198
14199
14200
14201
14202
14203
14204
14205
14206
14207
14208
14209
14210
14211
14212
14213
14214
14215
14216
14217
14218
14219
14220
14221
14222
14223
14224
14225
14226
14227
14228
14229
14230
14231
14232
14233
14234
14235
14236
14237
14238
14239
14240
14241
14242
14243
14244
14245
14246
14247
14248
14249
14250
14251
14252
14253
14254
14255
14256
14257
14258
14259
14260
14261
14262
14263
14264
14265
14266
14267
14268
14269
14270
14271
14272
14273
14274
14275
14276
14277
14278
14279
14280
14281
14282
14283
14284
14285
14286
14287
14288
14289
14290
14291
14292
14293
14294
14295
14296
14297
14298
14299
14300
14301
14302
14303
14304
14305
14306
14307
14308
14309
14310
14311
14312
14313
14314
14315
14316
14317
14318
14319
14320
14321
14322
14323
14324
14325
14326
14327
14328
14329
14330
14331
14332
14333
14334
14335
14336
14337
14338
14339
14340
14341
14342
14343
14344
14345
14346
14347
14348
14349
14350
14351
14352
14353
14354
14355
14356
14357
14358
14359
14360
14361
14362
14363
14364
14365
14366
14367
14368
14369
14370
14371
14372
14373
14374
14375
14376
14377
14378
14379
14380
14381
14382
14383
14384
14385
14386
14387
14388
14389
14390
14391
14392
14393
14394
14395
14396
14397
14398
14399
14400
14401
14402
14403
14404
14405
14406
14407
14408
14409
14410
14411
14412
14413
14414
14415
14416
14417
14418
14419
14420
14421
14422
14423
14424
14425
14426
14427
14428
14429
14430
14431
14432
14433
14434
14435
14436
14437
14438
14439
14440
14441
14442
14443
14444
14445
14446
14447
14448
14449
14450
14451
14452
14453
14454
14455
14456
14457
14458
14459
14460
14461
14462
14463
14464
14465
14466
14467
14468
14469
14470
14471
14472
14473
14474
14475
14476
14477
14478
14479
14480
14481
14482
14483
14484
14485
14486
14487
14488
14489
14490
14491
14492
14493
14494
14495
14496
14497
14498
14499
14500
14501
14502
14503
14504
14505
14506
14507
14508
14509
14510
14511
14512
14513
14514
14515
14516
14517
14518
14519
14520
14521
14522
14523
14524
14525
14526
14527
14528
14529
14530
14531
14532
14533
14534
14535
14536
14537
14538
14539
14540
14541
14542
14543
14544
14545
14546
14547
14548
14549
14550
14551
14552
14553
14554
14555
14556
14557
14558
14559
14560
14561
14562
14563
14564
14565
14566
14567
14568
14569
14570
14571
14572
14573
14574
14575
14576
14577
14578
14579
14580
14581
14582
14583
14584
14585
14586
14587
14588
14589
14590
14591
14592
14593
14594
14595
14596
14597
14598
14599
14600
14601
14602
14603
14604
14605
14606
14607
14608
14609
14610
14611
14612
14613
14614
14615
14616
14617
14618
14619
14620
14621
14622
14623
14624
14625
14626
14627
14628
14629
14630
14631
14632
14633
14634
14635
14636
14637
14638
14639
14640
14641
14642
14643
14644
14645
14646
14647
14648
14649
14650
14651
14652
14653
14654
14655
14656
14657
14658
14659
14660
14661
14662
14663
14664
14665
14666
14667
14668
14669
14670
14671
14672
14673
14674
14675
14676
14677
14678
14679
14680
14681
14682
14683
14684
14685
14686
14687
14688
14689
14690
14691
14692
14693
14694
14695
14696
14697
14698
14699
14700
14701
14702
14703
14704
14705
14706
14707
14708
14709
14710
14711
14712
14713
14714
14715
14716
14717
14718
14719
14720
14721
14722
14723
14724
14725
14726
14727
14728
14729
14730
14731
14732
14733
14734
14735
14736
14737
14738
14739
14740
14741
14742
14743
14744
14745
14746
14747
14748
14749
14750
14751
14752
14753
14754
14755
14756
14757
14758
14759
14760
14761
14762
14763
14764
14765
14766
14767
14768
14769
14770
14771
14772
14773
14774
14775
14776
14777
14778
14779
14780
14781
14782
14783
14784
14785
14786
14787
14788
14789
14790
14791
14792
14793
14794
14795
14796
14797
14798
14799
14800
14801
14802
14803
14804
14805
14806
14807
14808
14809
14810
14811
14812
14813
14814
14815
14816
14817
14818
14819
14820
14821
14822
14823
14824
14825
14826
14827
14828
14829
14830
14831
14832
14833
14834
14835
14836
14837
14838
14839
14840
14841
14842
14843
14844
14845
14846
14847
14848
14849
14850
14851
14852
14853
14854
14855
14856
14857
14858
14859
14860
14861
14862
14863
14864
14865
14866
14867
14868
14869
14870
14871
14872
14873
14874
14875
14876
14877
14878
14879
14880
14881
14882
14883
14884
14885
14886
14887
14888
14889
14890
14891
14892
14893
14894
14895
14896
14897
14898
14899
14900
14901
14902
14903
14904
14905
14906
14907
14908
14909
14910
14911
14912
14913
14914
14915
14916
14917
14918
14919
14920
14921
14922
14923
14924
14925
14926
14927
14928
14929
14930
14931
14932
14933
14934
14935
14936
14937
14938
14939
14940
14941
14942
14943
14944
14945
14946
14947
14948
14949
14950
14951
14952
14953
14954
14955
14956
14957
14958
14959
14960
14961
14962
14963
14964
14965
14966
14967
14968
14969
14970
14971
14972
14973
14974
14975
14976
14977
14978
14979
14980
14981
14982
14983
14984
14985
14986
14987
14988
14989
14990
14991
14992
14993
14994
14995
14996
14997
14998
14999
15000
15001
15002
15003
15004
15005
15006
15007
15008
15009
15010
15011
15012
15013
15014
15015
15016
15017
15018
15019
15020
15021
15022
15023
15024
15025
15026
15027
15028
15029
15030
15031
15032
15033
15034
15035
15036
15037
15038
15039
15040
15041
15042
15043
15044
15045
15046
15047
15048
15049
15050
15051
15052
15053
15054
15055
15056
15057
15058
15059
15060
15061
15062
15063
15064
15065
15066
15067
15068
15069
15070
15071
15072
15073
15074
15075
15076
15077
15078
15079
15080
15081
15082
15083
15084
15085
15086
15087
15088
15089
15090
15091
15092
15093
15094
15095
15096
15097
15098
15099
15100
15101
15102
15103
15104
15105
15106
15107
15108
15109
15110
15111
15112
15113
15114
15115
15116
15117
15118
15119
15120
15121
15122
15123
15124
15125
15126
15127
15128
15129
15130
15131
15132
15133
15134
15135
15136
15137
15138
15139
15140
15141
15142
15143
15144
15145
15146
15147
15148
15149
15150
15151
15152
15153
15154
15155
15156
15157
15158
15159
15160
15161
15162
15163
15164
15165
15166
15167
15168
15169
15170
15171
15172
15173
15174
15175
15176
15177
15178
15179
15180
15181
15182
15183
15184
15185
15186
15187
15188
15189
15190
15191
15192
15193
15194
15195
15196
15197
15198
15199
15200
15201
15202
15203
15204
15205
15206
15207
15208
15209
15210
15211
15212
15213
15214
15215
15216
15217
15218
15219
15220
15221
15222
15223
15224
15225
15226
15227
15228
15229
15230
15231
15232
15233
15234
15235
15236
15237
15238
15239
15240
15241
15242
15243
15244
15245
15246
15247
15248
15249
15250
15251
15252
15253
15254
15255
15256
15257
15258
15259
15260
15261
15262
15263
15264
15265
15266
15267
15268
15269
15270
15271
15272
15273
15274
15275
15276
15277
15278
15279
15280
15281
15282
15283
15284
15285
15286
15287
15288
15289
15290
15291
15292
15293
15294
15295
15296
15297
15298
15299
15300
15301
15302
15303
15304
15305
15306
15307
15308
15309
15310
15311
15312
15313
15314
15315
15316
15317
15318
15319
15320
15321
15322
15323
15324
15325
15326
15327
15328
15329
15330
15331
15332
15333
15334
15335
15336
15337
15338
15339
15340
15341
15342
15343
15344
15345
15346
15347
15348
15349
15350
15351
15352
15353
15354
15355
15356
15357
15358
15359
15360
15361
15362
15363
15364
15365
15366
15367
15368
15369
15370
15371
15372
15373
15374
15375
15376
15377
15378
15379
15380
15381
15382
15383
15384
15385
15386
15387
15388
15389
15390
15391
15392
15393
15394
15395
15396
15397
15398
15399
15400
15401
15402
15403
15404
15405
15406
15407
15408
15409
15410
15411
15412
15413
15414
15415
15416
15417
15418
15419
15420
15421
15422
15423
15424
15425
15426
15427
15428
15429
15430
15431
15432
15433
15434
15435
15436
15437
15438
15439
15440
15441
15442
15443
15444
15445
15446
15447
15448
15449
15450
15451
15452
15453
15454
15455
15456
15457
15458
15459
15460
15461
15462
15463
15464
15465
15466
15467
15468
15469
15470
15471
15472
15473
15474
15475
15476
15477
15478
15479
15480
15481
15482
15483
15484
15485
15486
15487
15488
15489
15490
15491
15492
15493
15494
15495
15496
15497
15498
15499
15500
15501
15502
15503
15504
15505
15506
15507
15508
15509
15510
15511
15512
15513
15514
15515
15516
15517
15518
15519
15520
15521
15522
15523
15524
15525
15526
15527
15528
15529
15530
15531
15532
15533
15534
15535
15536
15537
15538
15539
15540
15541
15542
15543
15544
15545
15546
15547
15548
15549
15550
15551
15552
15553
15554
15555
15556
15557
15558
15559
15560
15561
15562
15563
15564
15565
15566
15567
15568
15569
15570
15571
15572
15573
15574
15575
15576
15577
15578
15579
15580
15581
15582
15583
15584
15585
15586
15587
15588
15589
15590
15591
15592
15593
15594
15595
15596
15597
15598
15599
15600
15601
15602
15603
15604
15605
15606
15607
15608
15609
15610
15611
15612
15613
15614
15615
15616
15617
15618
15619
15620
15621
15622
15623
15624
15625
15626
15627
15628
15629
15630
15631
15632
15633
15634
15635
15636
15637
15638
15639
15640
15641
15642
15643
15644
15645
15646
15647
15648
15649
15650
15651
15652
15653
15654
15655
15656
15657
15658
15659
15660
15661
15662
15663
15664
15665
15666
15667
15668
15669
15670
15671
15672
15673
15674
15675
15676
15677
15678
15679
15680
15681
15682
15683
15684
15685
15686
15687
15688
15689
15690
15691
15692
15693
15694
15695
15696
15697
15698
15699
15700
15701
15702
15703
15704
15705
15706
15707
15708
15709
15710
15711
15712
15713
15714
15715
15716
15717
15718
15719
15720
15721
15722
15723
15724
15725
15726
15727
15728
15729
15730
15731
15732
15733
15734
15735
15736
15737
15738
15739
15740
15741
15742
15743
15744
15745
15746
15747
15748
15749
15750
15751
15752
15753
15754
15755
15756
15757
15758
15759
15760
15761
15762
15763
15764
15765
15766
15767
15768
15769
15770
15771
15772
15773
15774
15775
15776
15777
15778
15779
15780
15781
15782
15783
15784
15785
15786
15787
15788
15789
15790
15791
15792
15793
15794
15795
15796
15797
15798
15799
15800
15801
15802
15803
15804
15805
15806
15807
15808
15809
15810
15811
15812
15813
15814
15815
15816
15817
15818
15819
15820
15821
15822
15823
15824
15825
15826
15827
15828
15829
15830
15831
15832
15833
15834
15835
15836
15837
15838
15839
15840
15841
15842
15843
15844
15845
15846
15847
15848
15849
15850
15851
15852
15853
15854
15855
15856
15857
15858
15859
15860
15861
15862
15863
15864
15865
15866
15867
15868
15869
15870
15871
15872
15873
15874
15875
15876
15877
15878
15879
15880
15881
15882
15883
15884
15885
15886
15887
15888
15889
15890
15891
15892
15893
15894
15895
15896
15897
15898
15899
15900
15901
15902
15903
15904
15905
15906
15907
15908
15909
15910
15911
15912
15913
15914
15915
15916
15917
15918
15919
15920
15921
15922
15923
15924
15925
15926
15927
15928
15929
15930
15931
15932
15933
15934
15935
15936
15937
15938
15939
15940
15941
15942
15943
15944
15945
15946
15947
15948
15949
15950
15951
15952
15953
15954
15955
15956
15957
15958
15959
15960
15961
15962
15963
15964
15965
15966
15967
15968
15969
15970
15971
15972
15973
15974
15975
15976
15977
15978
15979
15980
15981
15982
15983
15984
15985
15986
15987
15988
15989
15990
15991
15992
15993
15994
15995
15996
15997
15998
15999
16000
16001
16002
16003
16004
16005
16006
16007
16008
16009
16010
16011
16012
16013
16014
16015
16016
16017
16018
16019
16020
16021
16022
16023
16024
16025
16026
16027
16028
16029
16030
16031
16032
16033
16034
16035
16036
16037
16038
16039
16040
16041
16042
16043
16044
16045
16046
16047
16048
16049
16050
16051
16052
16053
16054
16055
16056
16057
16058
16059
16060
16061
16062
16063
16064
16065
16066
16067
16068
16069
16070
16071
16072
16073
16074
16075
16076
16077
16078
16079
16080
16081
16082
16083
16084
16085
16086
16087
16088
16089
16090
16091
16092
16093
16094
16095
16096
16097
16098
16099
16100
16101
16102
16103
16104
16105
16106
16107
16108
16109
16110
16111
16112
16113
16114
16115
16116
16117
16118
16119
16120
16121
16122
16123
16124
16125
16126
16127
16128
16129
16130
16131
16132
16133
16134
16135
16136
16137
16138
16139
16140
16141
16142
16143
16144
16145
16146
16147
16148
16149
16150
16151
16152
16153
16154
16155
16156
16157
16158
16159
16160
16161
16162
16163
16164
16165
16166
16167
16168
16169
16170
16171
16172
16173
16174
16175
16176
16177
16178
16179
16180
16181
16182
16183
16184
16185
16186
16187
16188
16189
16190
16191
16192
16193
16194
16195
16196
16197
16198
16199
16200
16201
16202
16203
16204
16205
16206
16207
16208
16209
16210
16211
16212
16213
16214
16215
16216
16217
16218
16219
16220
16221
16222
16223
16224
16225
16226
16227
16228
16229
16230
16231
16232
16233
16234
16235
16236
16237
16238
16239
16240
16241
16242
16243
16244
16245
16246
16247
16248
16249
16250
16251
16252
16253
16254
16255
16256
16257
16258
16259
16260
16261
16262
16263
16264
16265
16266
16267
16268
16269
16270
16271
16272
16273
16274
16275
16276
16277
16278
16279
16280
16281
16282
16283
16284
16285
16286
16287
16288
16289
16290
16291
16292
16293
16294
16295
16296
16297
16298
16299
16300
16301
16302
16303
16304
16305
16306
16307
16308
16309
16310
16311
16312
16313
16314
16315
16316
16317
16318
16319
16320
16321
16322
16323
16324
16325
16326
16327
16328
16329
16330
16331
16332
16333
16334
16335
16336
16337
16338
16339
16340
16341
16342
16343
16344
16345
16346
16347
16348
16349
16350
16351
16352
16353
16354
16355
16356
16357
16358
16359
16360
16361
16362
16363
16364
16365
16366
16367
16368
16369
16370
16371
16372
16373
16374
16375
16376
16377
16378
16379
16380
16381
16382
16383
16384
16385
16386
16387
16388
16389
16390
16391
16392
16393
16394
16395
16396
16397
16398
16399
16400
16401
16402
16403
16404
16405
16406
16407
16408
16409
16410
16411
16412
16413
16414
16415
16416
16417
16418
16419
16420
16421
16422
16423
16424
16425
16426
16427
16428
16429
16430
16431
16432
16433
16434
16435
16436
16437
16438
16439
16440
16441
16442
16443
16444
16445
16446
16447
16448
16449
16450
16451
16452
16453
16454
16455
16456
16457
16458
16459
16460
16461
16462
16463
16464
16465
16466
16467
16468
16469
16470
16471
16472
16473
16474
16475
16476
16477
16478
16479
16480
16481
16482
16483
16484
16485
16486
16487
16488
16489
16490
16491
16492
16493
16494
16495
16496
16497
16498
16499
16500
16501
16502
16503
16504
16505
16506
16507
16508
16509
16510
16511
16512
16513
16514
16515
16516
16517
16518
16519
16520
16521
16522
16523
16524
16525
16526
16527
16528
16529
16530
16531
16532
16533
16534
16535
16536
16537
16538
16539
16540
16541
16542
16543
16544
16545
16546
16547
16548
16549
16550
16551
16552
16553
16554
16555
16556
16557
16558
16559
16560
16561
16562
16563
16564
16565
16566
16567
16568
16569
16570
16571
16572
16573
16574
16575
16576
16577
16578
16579
16580
16581
16582
16583
16584
16585
16586
16587
16588
16589
16590
16591
16592
16593
16594
16595
16596
16597
16598
16599
16600
16601
16602
16603
16604
16605
16606
16607
16608
16609
16610
16611
16612
16613
16614
16615
16616
16617
16618
16619
16620
16621
16622
16623
16624
16625
16626
16627
16628
16629
16630
16631
16632
16633
16634
16635
16636
16637
16638
16639
16640
16641
16642
16643
16644
16645
16646
16647
16648
16649
16650
16651
16652
16653
16654
16655
16656
16657
16658
16659
16660
16661
16662
16663
16664
16665
16666
16667
16668
16669
16670
16671
16672
16673
16674
16675
16676
16677
16678
16679
16680
16681
16682
16683
16684
16685
16686
16687
16688
16689
16690
16691
16692
16693
16694
16695
16696
16697
16698
16699
16700
16701
16702
16703
16704
16705
16706
16707
16708
16709
16710
16711
16712
16713
16714
16715
16716
16717
16718
16719
16720
16721
16722
16723
16724
16725
16726
16727
16728
16729
16730
16731
16732
16733
16734
16735
16736
16737
16738
16739
16740
16741
16742
16743
16744
16745
16746
16747
16748
16749
16750
16751
16752
16753
16754
16755
16756
16757
16758
16759
16760
16761
16762
16763
16764
16765
16766
16767
16768
16769
16770
16771
16772
16773
16774
16775
16776
16777
16778
16779
16780
16781
16782
16783
16784
16785
16786
16787
16788
16789
16790
16791
16792
16793
16794
16795
16796
16797
16798
16799
16800
16801
16802
16803
16804
16805
16806
16807
16808
16809
16810
16811
16812
16813
16814
16815
16816
16817
16818
16819
16820
16821
16822
16823
16824
16825
16826
16827
16828
16829
16830
16831
16832
16833
16834
16835
16836
16837
16838
16839
16840
16841
16842
16843
16844
16845
16846
16847
16848
16849
16850
16851
16852
16853
16854
16855
16856
16857
16858
16859
16860
16861
16862
16863
16864
16865
16866
16867
16868
16869
16870
16871
16872
16873
16874
16875
16876
16877
16878
16879
16880
16881
16882
16883
16884
16885
16886
16887
16888
16889
16890
16891
16892
16893
16894
16895
16896
16897
16898
16899
16900
16901
16902
16903
16904
16905
16906
16907
16908
16909
16910
16911
16912
16913
16914
16915
16916
16917
16918
16919
16920
16921
16922
16923
16924
16925
16926
16927
16928
16929
16930
16931
16932
16933
16934
16935
16936
16937
16938
16939
16940
16941
16942
16943
16944
16945
16946
16947
16948
16949
16950
16951
16952
16953
16954
16955
16956
16957
16958
16959
16960
16961
16962
16963
16964
16965
16966
16967
16968
16969
16970
16971
16972
16973
16974
16975
16976
16977
16978
16979
16980
16981
16982
16983
16984
16985
16986
16987
16988
16989
16990
16991
16992
16993
16994
16995
16996
16997
16998
16999
17000
17001
17002
17003
17004
17005
17006
17007
17008
17009
17010
17011
17012
17013
17014
17015
17016
17017
17018
17019
17020
17021
17022
17023
17024
17025
17026
17027
17028
17029
17030
17031
17032
17033
17034
17035
17036
17037
17038
17039
17040
17041
17042
17043
17044
17045
17046
17047
17048
17049
17050
17051
17052
17053
17054
17055
17056
17057
17058
17059
17060
17061
17062
17063
17064
17065
17066
17067
17068
17069
17070
17071
17072
17073
17074
17075
17076
17077
17078
17079
17080
17081
17082
17083
17084
17085
17086
17087
17088
17089
17090
17091
17092
17093
17094
17095
17096
17097
17098
17099
17100
17101
17102
17103
17104
17105
17106
17107
17108
17109
17110
17111
17112
17113
17114
17115
17116
17117
17118
17119
17120
17121
17122
17123
17124
17125
17126
17127
17128
17129
17130
17131
17132
17133
17134
17135
17136
17137
17138
17139
17140
17141
17142
17143
17144
17145
17146
17147
17148
17149
17150
17151
17152
17153
17154
17155
17156
17157
17158
17159
17160
17161
17162
17163
17164
17165
17166
17167
17168
17169
17170
17171
17172
17173
17174
17175
17176
17177
17178
17179
17180
17181
17182
17183
17184
17185
17186
17187
17188
17189
17190
17191
17192
17193
17194
17195
17196
17197
17198
17199
17200
17201
17202
17203
17204
17205
17206
17207
17208
17209
17210
17211
17212
17213
17214
17215
17216
17217
17218
17219
17220
17221
17222
17223
17224
17225
17226
17227
17228
17229
17230
17231
17232
17233
17234
17235
17236
17237
17238
17239
17240
17241
17242
17243
17244
17245
17246
17247
17248
17249
17250
17251
17252
17253
17254
17255
17256
17257
17258
17259
17260
17261
17262
17263
17264
17265
17266
17267
17268
17269
17270
17271
17272
17273
17274
17275
17276
17277
17278
17279
17280
17281
17282
17283
17284
17285
17286
17287
17288
17289
17290
17291
17292
17293
17294
17295
17296
17297
17298
17299
17300
17301
17302
17303
17304
17305
17306
17307
17308
17309
17310
17311
17312
17313
17314
17315
17316
17317
17318
17319
17320
17321
17322
17323
17324
17325
17326
17327
17328
17329
17330
17331
17332
17333
17334
17335
17336
17337
17338
17339
17340
17341
17342
17343
17344
17345
17346
17347
17348
17349
17350
17351
17352
17353
17354
17355
17356
17357
17358
17359
17360
17361
17362
17363
17364
17365
17366
17367
17368
17369
17370
17371
17372
17373
17374
17375
17376
17377
17378
17379
17380
17381
17382
17383
17384
17385
17386
17387
17388
17389
17390
17391
17392
17393
17394
17395
17396
17397
17398
17399
17400
17401
17402
17403
17404
17405
17406
17407
17408
17409
17410
17411
17412
17413
17414
17415
17416
17417
17418
17419
17420
17421
17422
17423
17424
17425
17426
17427
17428
17429
17430
17431
17432
17433
17434
17435
17436
17437
17438
17439
17440
17441
17442
17443
17444
17445
17446
17447
17448
17449
17450
17451
17452
17453
17454
17455
17456
17457
17458
17459
17460
17461
17462
17463
17464
17465
17466
17467
17468
17469
17470
17471
17472
17473
17474
17475
17476
17477
17478
17479
17480
17481
17482
17483
17484
17485
17486
17487
17488
17489
17490
17491
17492
17493
17494
17495
17496
17497
17498
17499
17500
17501
17502
17503
17504
17505
17506
17507
17508
17509
17510
17511
17512
17513
17514
17515
17516
17517
17518
17519
17520
17521
17522
17523
17524
17525
17526
17527
17528
17529
17530
17531
17532
17533
17534
17535
17536
17537
17538
17539
17540
17541
17542
17543
17544
17545
17546
17547
17548
17549
17550
17551
17552
17553
17554
17555
17556
17557
17558
17559
17560
17561
17562
17563
17564
17565
17566
17567
17568
17569
17570
17571
17572
17573
17574
17575
17576
17577
17578
17579
17580
17581
17582
17583
17584
17585
17586
17587
17588
17589
17590
17591
17592
17593
17594
17595
17596
17597
17598
17599
17600
17601
17602
17603
17604
17605
17606
17607
17608
17609
17610
17611
17612
17613
17614
17615
17616
17617
17618
17619
17620
17621
17622
17623
17624
17625
17626
17627
17628
17629
17630
17631
17632
17633
17634
17635
17636
17637
17638
17639
17640
17641
17642
17643
17644
17645
17646
17647
17648
17649
17650
17651
17652
17653
17654
17655
17656
17657
17658
17659
17660
17661
17662
17663
17664
17665
17666
17667
17668
17669
17670
17671
17672
17673
17674
17675
17676
17677
17678
17679
17680
17681
17682
17683
17684
17685
17686
17687
17688
17689
17690
17691
17692
17693
17694
17695
17696
17697
17698
17699
17700
17701
17702
17703
17704
17705
17706
17707
17708
17709
17710
17711
17712
17713
17714
17715
17716
17717
17718
17719
17720
17721
17722
17723
17724
17725
17726
17727
17728
17729
17730
17731
17732
17733
17734
17735
17736
17737
17738
17739
17740
17741
17742
17743
17744
17745
17746
17747
17748
17749
17750
17751
17752
17753
17754
17755
17756
17757
17758
17759
17760
17761
17762
17763
17764
17765
17766
17767
17768
17769
17770
17771
17772
17773
17774
17775
17776
17777
17778
17779
17780
17781
17782
17783
17784
17785
17786
17787
17788
17789
17790
17791
17792
17793
17794
17795
17796
17797
17798
17799
17800
17801
17802
17803
17804
17805
17806
17807
17808
17809
17810
17811
17812
17813
17814
17815
17816
17817
17818
17819
17820
17821
17822
17823
17824
17825
17826
17827
17828
17829
17830
17831
17832
17833
17834
17835
17836
17837
17838
17839
17840
17841
17842
17843
17844
17845
17846
17847
17848
17849
17850
17851
17852
17853
17854
17855
17856
17857
17858
17859
17860
17861
17862
17863
17864
17865
17866
17867
17868
17869
17870
17871
17872
17873
17874
17875
17876
17877
17878
17879
17880
17881
17882
17883
17884
17885
17886
17887
17888
17889
17890
17891
17892
17893
17894
17895
17896
17897
17898
17899
17900
17901
17902
17903
17904
17905
17906
17907
17908
17909
17910
17911
17912
17913
17914
17915
17916
17917
17918
17919
17920
17921
17922
17923
17924
17925
17926
17927
17928
17929
17930
17931
17932
17933
17934
17935
17936
17937
17938
17939
17940
17941
17942
17943
17944
17945
17946
17947
17948
17949
17950
17951
17952
17953
17954
17955
17956
17957
17958
17959
17960
17961
17962
17963
17964
17965
17966
17967
17968
17969
17970
17971
17972
17973
17974
17975
17976
17977
17978
17979
17980
17981
17982
17983
17984
17985
17986
17987
17988
17989
17990
17991
17992
17993
17994
17995
17996
17997
17998
17999
18000
18001
18002
18003
18004
18005
18006
18007
18008
18009
18010
18011
18012
18013
18014
18015
18016
18017
18018
18019
18020
18021
18022
18023
18024
18025
18026
18027
18028
18029
18030
18031
18032
18033
18034
18035
18036
18037
18038
18039
18040
18041
18042
18043
18044
18045
18046
18047
18048
18049
18050
18051
18052
18053
18054
18055
18056
18057
18058
18059
18060
18061
18062
18063
18064
18065
18066
18067
18068
18069
18070
18071
18072
18073
18074
18075
18076
18077
18078
18079
18080
18081
18082
18083
18084
18085
18086
18087
18088
18089
18090
18091
18092
18093
18094
18095
18096
18097
18098
18099
18100
18101
18102
18103
18104
18105
18106
18107
18108
18109
18110
18111
18112
18113
18114
18115
18116
18117
18118
18119
18120
18121
18122
18123
18124
18125
18126
18127
18128
18129
18130
18131
18132
18133
18134
18135
18136
18137
18138
18139
18140
18141
18142
18143
18144
18145
18146
18147
18148
18149
18150
18151
18152
18153
18154
18155
18156
18157
18158
18159
18160
18161
18162
18163
18164
18165
18166
18167
18168
18169
18170
18171
18172
18173
18174
18175
18176
18177
18178
18179
18180
18181
18182
18183
18184
18185
18186
18187
18188
18189
18190
18191
18192
18193
18194
18195
18196
18197
18198
18199
18200
18201
18202
18203
18204
18205
18206
18207
18208
18209
18210
18211
18212
18213
18214
18215
18216
18217
18218
18219
18220
18221
18222
18223
18224
18225
18226
18227
18228
18229
18230
18231
18232
18233
18234
18235
18236
18237
18238
18239
18240
18241
18242
18243
18244
18245
18246
18247
18248
18249
18250
18251
18252
18253
18254
18255
18256
18257
18258
18259
18260
18261
18262
18263
18264
18265
18266
18267
18268
18269
18270
18271
18272
18273
18274
18275
18276
18277
18278
18279
18280
18281
18282
18283
18284
18285
18286
18287
18288
18289
18290
18291
18292
18293
18294
18295
18296
18297
18298
18299
18300
18301
18302
18303
18304
18305
18306
18307
18308
18309
18310
18311
18312
18313
18314
18315
18316
18317
18318
18319
18320
18321
18322
18323
18324
18325
18326
18327
18328
18329
18330
18331
18332
18333
18334
18335
18336
18337
18338
18339
18340
18341
18342
18343
18344
18345
18346
18347
18348
18349
18350
18351
18352
18353
18354
18355
18356
18357
18358
18359
18360
18361
18362
18363
18364
18365
18366
18367
18368
18369
18370
18371
18372
18373
18374
18375
18376
18377
18378
18379
18380
18381
18382
18383
18384
18385
18386
18387
18388
18389
18390
18391
18392
18393
18394
18395
18396
18397
18398
18399
18400
18401
18402
18403
18404
18405
18406
18407
18408
18409
18410
18411
18412
18413
18414
18415
18416
18417
18418
18419
18420
18421
18422
18423
18424
18425
18426
18427
18428
18429
18430
18431
18432
18433
18434
18435
18436
18437
18438
18439
18440
18441
18442
18443
18444
18445
18446
18447
18448
18449
18450
18451
18452
18453
18454
18455
18456
18457
18458
18459
18460
18461
18462
18463
18464
18465
18466
18467
18468
18469
18470
18471
18472
18473
18474
18475
18476
18477
18478
18479
18480
18481
18482
18483
18484
18485
18486
18487
18488
18489
18490
18491
18492
18493
18494
18495
18496
18497
18498
18499
18500
18501
18502
18503
18504
18505
18506
18507
18508
18509
18510
18511
18512
18513
18514
18515
18516
18517
18518
18519
18520
18521
18522
18523
18524
18525
18526
18527
18528
18529
18530
18531
18532
18533
18534
18535
18536
18537
18538
18539
18540
18541
18542
18543
18544
18545
18546
18547
18548
18549
18550
18551
18552
18553
18554
18555
18556
18557
18558
18559
18560
18561
18562
18563
18564
18565
18566
18567
18568
18569
18570
18571
18572
18573
18574
18575
18576
18577
18578
18579
18580
18581
18582
18583
18584
18585
18586
18587
18588
18589
18590
18591
18592
18593
18594
18595
18596
18597
18598
18599
18600
18601
18602
18603
18604
18605
18606
18607
18608
18609
18610
18611
18612
18613
18614
18615
18616
18617
18618
18619
18620
18621
18622
18623
18624
18625
18626
18627
18628
18629
18630
18631
18632
18633
18634
18635
18636
18637
18638
18639
18640
18641
18642
18643
18644
18645
18646
18647
18648
18649
18650
18651
18652
18653
18654
18655
18656
18657
18658
18659
18660
18661
18662
18663
18664
18665
18666
18667
18668
18669
18670
18671
18672
18673
18674
18675
18676
18677
18678
18679
18680
18681
18682
18683
18684
18685
18686
18687
18688
18689
18690
18691
18692
18693
18694
18695
18696
18697
18698
18699
18700
18701
18702
18703
18704
18705
18706
18707
18708
18709
18710
18711
18712
18713
18714
18715
18716
18717
18718
18719
18720
18721
18722
18723
18724
18725
18726
18727
18728
18729
18730
18731
18732
18733
18734
18735
18736
18737
18738
18739
18740
18741
18742
18743
18744
18745
18746
18747
18748
18749
18750
18751
18752
18753
18754
18755
18756
18757
18758
18759
18760
18761
18762
18763
18764
18765
18766
18767
18768
18769
18770
18771
18772
18773
18774
18775
18776
18777
18778
18779
18780
18781
18782
18783
18784
18785
18786
18787
18788
18789
18790
18791
18792
18793
18794
18795
18796
18797
18798
18799
18800
18801
18802
18803
18804
18805
18806
18807
18808
18809
18810
18811
18812
18813
18814
18815
18816
18817
18818
18819
18820
18821
18822
18823
18824
18825
18826
18827
18828
18829
18830
18831
18832
18833
18834
18835
18836
18837
18838
18839
18840
18841
18842
18843
18844
18845
18846
18847
18848
18849
18850
18851
18852
18853
18854
18855
18856
18857
18858
18859
18860
18861
18862
18863
18864
18865
18866
18867
18868
18869
18870
18871
18872
18873
18874
18875
18876
18877
18878
18879
18880
18881
18882
18883
18884
18885
18886
18887
18888
18889
18890
18891
18892
18893
18894
18895
18896
18897
18898
18899
18900
18901
18902
18903
18904
18905
18906
18907
18908
18909
18910
18911
18912
18913
18914
18915
18916
18917
18918
18919
18920
18921
18922
18923
18924
18925
18926
18927
18928
18929
18930
18931
18932
18933
18934
18935
18936
18937
18938
18939
18940
18941
18942
18943
18944
18945
18946
18947
18948
18949
18950
18951
18952
18953
18954
18955
18956
18957
18958
18959
18960
18961
18962
18963
18964
18965
18966
18967
18968
18969
18970
18971
18972
18973
18974
18975
18976
18977
18978
18979
18980
18981
18982
18983
18984
18985
18986
18987
18988
18989
18990
18991
18992
18993
18994
18995
18996
18997
18998
18999
19000
19001
19002
19003
19004
19005
19006
19007
19008
19009
19010
19011
19012
19013
19014
19015
19016
19017
19018
19019
19020
19021
19022
19023
19024
19025
19026
19027
19028
19029
19030
19031
19032
19033
19034
19035
19036
19037
19038
19039
19040
19041
19042
19043
19044
19045
19046
19047
19048
19049
19050
19051
19052
19053
19054
19055
19056
19057
19058
19059
19060
19061
19062
19063
19064
19065
19066
19067
19068
19069
19070
19071
19072
19073
19074
19075
19076
19077
19078
19079
19080
19081
19082
19083
19084
19085
19086
19087
19088
19089
19090
19091
19092
19093
19094
19095
19096
19097
19098
19099
19100
19101
19102
19103
19104
19105
19106
19107
19108
19109
19110
19111
19112
19113
19114
19115
19116
19117
19118
19119
19120
19121
19122
19123
19124
19125
19126
19127
19128
19129
19130
19131
19132
19133
19134
19135
19136
19137
19138
19139
19140
19141
19142
19143
19144
19145
19146
19147
19148
19149
19150
19151
19152
19153
19154
19155
19156
19157
19158
19159
19160
19161
19162
19163
19164
19165
19166
19167
19168
19169
19170
19171
19172
19173
19174
19175
19176
19177
19178
19179
19180
19181
19182
19183
19184
19185
19186
19187
19188
19189
19190
19191
19192
19193
19194
19195
19196
19197
19198
19199
19200
19201
19202
19203
19204
19205
19206
19207
19208
19209
19210
19211
19212
19213
19214
19215
19216
19217
19218
19219
19220
19221
19222
19223
19224
19225
19226
19227
19228
19229
19230
19231
19232
19233
19234
19235
19236
19237
19238
19239
19240
19241
19242
19243
19244
19245
19246
19247
19248
19249
19250
19251
19252
19253
19254
19255
19256
19257
19258
19259
19260
19261
19262
19263
19264
19265
19266
19267
19268
19269
19270
19271
19272
19273
19274
19275
19276
19277
19278
19279
19280
19281
19282
19283
19284
19285
19286
19287
19288
19289
19290
19291
19292
19293
19294
19295
19296
19297
19298
19299
19300
19301
19302
19303
19304
19305
19306
19307
19308
19309
19310
19311
19312
19313
19314
19315
19316
19317
19318
19319
19320
19321
19322
19323
19324
19325
19326
19327
19328
19329
19330
19331
19332
19333
19334
19335
19336
19337
19338
19339
19340
19341
19342
19343
19344
19345
19346
19347
19348
19349
19350
19351
19352
19353
19354
19355
19356
19357
19358
19359
19360
19361
19362
19363
19364
19365
19366
19367
19368
19369
19370
19371
19372
19373
19374
19375
19376
19377
19378
19379
19380
19381
19382
19383
19384
19385
19386
19387
19388
19389
19390
19391
19392
19393
19394
19395
19396
19397
19398
19399
19400
19401
19402
19403
19404
19405
19406
19407
19408
19409
19410
19411
19412
19413
19414
19415
19416
19417
19418
19419
19420
19421
19422
19423
19424
19425
19426
19427
19428
19429
19430
19431
19432
19433
19434
19435
19436
19437
19438
19439
19440
19441
19442
19443
19444
19445
19446
19447
19448
19449
19450
19451
19452
19453
19454
19455
19456
19457
19458
19459
19460
19461
19462
19463
19464
19465
19466
19467
19468
19469
19470
19471
19472
19473
19474
19475
19476
19477
19478
19479
19480
19481
19482
19483
19484
19485
19486
19487
19488
19489
19490
19491
19492
19493
19494
19495
19496
19497
19498
19499
19500
19501
19502
19503
19504
19505
19506
19507
19508
19509
19510
19511
19512
19513
19514
19515
19516
19517
19518
19519
19520
19521
19522
19523
19524
19525
19526
19527
19528
19529
19530
19531
19532
19533
19534
19535
19536
19537
19538
19539
19540
19541
19542
19543
19544
19545
19546
19547
19548
19549
19550
19551
19552
19553
19554
19555
19556
19557
19558
19559
19560
19561
19562
19563
19564
19565
19566
19567
19568
19569
19570
19571
19572
19573
19574
19575
19576
19577
19578
19579
19580
19581
19582
19583
19584
19585
19586
19587
19588
19589
19590
19591
19592
19593
19594
19595
19596
19597
19598
19599
19600
19601
19602
19603
19604
19605
19606
19607
19608
19609
19610
19611
19612
19613
19614
19615
19616
19617
19618
19619
19620
19621
19622
19623
19624
19625
19626
19627
19628
19629
19630
19631
19632
19633
19634
19635
19636
19637
19638
19639
19640
19641
19642
19643
19644
19645
19646
19647
19648
19649
19650
19651
19652
19653
19654
19655
19656
19657
19658
19659
19660
19661
19662
19663
19664
19665
19666
19667
19668
19669
19670
19671
19672
19673
19674
19675
19676
19677
19678
19679
19680
19681
19682
19683
19684
19685
19686
19687
19688
19689
19690
19691
19692
19693
19694
19695
19696
19697
19698
19699
19700
19701
19702
19703
19704
19705
19706
19707
19708
19709
19710
19711
19712
19713
19714
19715
19716
19717
19718
19719
19720
19721
19722
19723
19724
19725
19726
19727
19728
19729
19730
19731
19732
19733
19734
19735
19736
19737
19738
19739
19740
19741
19742
19743
19744
19745
19746
19747
19748
19749
19750
19751
19752
19753
19754
19755
19756
19757
19758
19759
19760
19761
19762
19763
19764
19765
19766
19767
19768
19769
19770
19771
19772
19773
19774
19775
19776
19777
19778
19779
19780
19781
19782
19783
19784
19785
19786
19787
19788
19789
19790
19791
19792
19793
19794
19795
19796
19797
19798
19799
19800
19801
19802
19803
19804
19805
19806
19807
19808
19809
19810
19811
19812
19813
19814
19815
19816
19817
19818
19819
19820
19821
19822
19823
19824
19825
19826
19827
19828
19829
19830
19831
19832
19833
19834
19835
19836
19837
19838
19839
19840
19841
19842
19843
19844
19845
19846
19847
19848
19849
19850
19851
19852
19853
19854
19855
19856
19857
19858
19859
19860
19861
19862
19863
19864
19865
19866
19867
19868
19869
19870
19871
19872
19873
19874
19875
19876
19877
19878
19879
19880
19881
19882
19883
19884
19885
19886
19887
19888
19889
19890
19891
19892
19893
19894
19895
19896
19897
19898
19899
19900
19901
19902
19903
19904
19905
19906
19907
19908
19909
19910
19911
19912
19913
19914
19915
19916
19917
19918
19919
19920
19921
19922
19923
19924
19925
19926
19927
19928
19929
19930
19931
19932
19933
19934
19935
19936
19937
19938
19939
19940
19941
19942
19943
19944
19945
19946
19947
19948
19949
19950
19951
19952
19953
19954
19955
19956
19957
19958
19959
19960
19961
19962
19963
19964
19965
19966
19967
19968
19969
19970
19971
19972
19973
19974
19975
19976
19977
19978
19979
19980
19981
19982
19983
19984
19985
19986
19987
19988
19989
19990
19991
19992
19993
19994
19995
19996
19997
19998
19999
20000
20001
20002
20003
20004
20005
20006
20007
20008
20009
20010
20011
20012
20013
20014
20015
20016
20017
20018
20019
20020
20021
20022
20023
20024
20025
20026
20027
20028
20029
20030
20031
20032
20033
20034
20035
20036
20037
20038
20039
20040
20041
20042
20043
20044
20045
20046
20047
20048
20049
20050
20051
20052
20053
20054
20055
20056
20057
20058
20059
20060
20061
20062
20063
20064
20065
20066
20067
20068
20069
20070
20071
20072
20073
20074
20075
20076
20077
20078
20079
20080
20081
20082
20083
20084
20085
20086
20087
20088
20089
20090
20091
20092
20093
20094
20095
20096
20097
20098
20099
20100
20101
20102
20103
20104
20105
20106
20107
20108
20109
20110
20111
20112
20113
20114
20115
20116
20117
20118
20119
20120
20121
20122
20123
20124
20125
20126
20127
20128
20129
20130
20131
20132
20133
20134
20135
20136
20137
20138
20139
20140
20141
20142
20143
20144
20145
20146
20147
20148
20149
20150
20151
20152
20153
20154
20155
20156
20157
20158
20159
20160
20161
20162
20163
20164
20165
20166
20167
20168
20169
20170
20171
20172
20173
20174
20175
20176
20177
20178
20179
20180
20181
20182
20183
20184
20185
20186
20187
20188
20189
20190
20191
20192
20193
20194
20195
20196
20197
20198
20199
20200
20201
20202
20203
20204
20205
20206
20207
20208
20209
20210
20211
20212
20213
20214
20215
20216
20217
20218
20219
20220
20221
20222
20223
20224
20225
20226
20227
20228
20229
20230
20231
20232
20233
20234
20235
20236
20237
20238
20239
20240
20241
20242
20243
20244
20245
20246
20247
20248
20249
20250
20251
20252
20253
20254
20255
20256
20257
20258
20259
20260
20261
20262
20263
20264
20265
20266
20267
20268
20269
20270
20271
20272
20273
20274
20275
20276
20277
20278
20279
20280
20281
20282
20283
20284
20285
20286
20287
20288
20289
20290
20291
20292
20293
20294
20295
20296
20297
20298
20299
20300
20301
20302
20303
20304
20305
20306
20307
20308
20309
20310
20311
20312
20313
20314
20315
20316
20317
20318
20319
20320
20321
20322
20323
20324
20325
20326
20327
20328
20329
20330
20331
20332
20333
20334
20335
20336
20337
20338
20339
20340
20341
20342
20343
20344
20345
20346
20347
20348
20349
20350
20351
20352
20353
20354
20355
20356
20357
20358
20359
20360
20361
20362
20363
20364
20365
20366
20367
20368
20369
20370
20371
20372
20373
20374
20375
20376
20377
20378
20379
20380
20381
20382
20383
20384
20385
20386
20387
20388
20389
20390
20391
20392
20393
20394
20395
20396
20397
20398
20399
20400
20401
20402
20403
20404
20405
20406
20407
20408
20409
20410
20411
20412
20413
20414
20415
20416
20417
20418
20419
20420
20421
20422
20423
20424
20425
20426
20427
20428
20429
20430
20431
20432
20433
20434
20435
20436
20437
20438
20439
20440
20441
20442
20443
20444
20445
20446
20447
20448
20449
20450
20451
20452
20453
20454
20455
20456
20457
20458
20459
20460
20461
20462
20463
20464
20465
20466
20467
20468
20469
20470
20471
20472
20473
20474
20475
20476
20477
20478
20479
20480
20481
20482
20483
20484
20485
20486
20487
20488
20489
20490
20491
20492
20493
20494
20495
20496
20497
20498
20499
20500
20501
20502
20503
20504
20505
20506
20507
20508
20509
20510
20511
20512
20513
20514
20515
20516
20517
20518
20519
20520
20521
20522
20523
20524
20525
20526
20527
20528
20529
20530
20531
20532
20533
20534
20535
20536
20537
20538
20539
20540
20541
20542
20543
20544
20545
20546
20547
20548
20549
20550
20551
20552
20553
20554
20555
20556
20557
20558
20559
20560
20561
20562
20563
20564
20565
20566
20567
20568
20569
20570
20571
20572
20573
20574
20575
20576
20577
20578
20579
20580
20581
20582
20583
20584
20585
20586
20587
20588
20589
20590
20591
20592
20593
20594
20595
20596
20597
20598
20599
20600
20601
20602
20603
20604
20605
20606
20607
20608
20609
20610
20611
20612
20613
20614
20615
20616
20617
20618
20619
20620
20621
20622
20623
20624
20625
20626
20627
20628
20629
20630
20631
20632
20633
20634
20635
20636
20637
20638
20639
20640
20641
20642
20643
20644
20645
20646
20647
20648
20649
20650
20651
20652
20653
20654
20655
20656
20657
20658
20659
20660
20661
20662
20663
20664
20665
20666
20667
20668
20669
20670
20671
20672
20673
20674
20675
20676
20677
20678
20679
20680
20681
20682
20683
20684
20685
20686
20687
20688
20689
20690
20691
20692
20693
20694
20695
20696
20697
20698
20699
20700
20701
20702
20703
20704
20705
20706
20707
20708
20709
20710
20711
20712
20713
20714
20715
20716
20717
20718
20719
20720
20721
20722
20723
20724
20725
20726
20727
20728
20729
20730
20731
20732
20733
20734
20735
20736
20737
20738
20739
20740
20741
20742
20743
20744
20745
20746
20747
20748
20749
20750
20751
20752
20753
20754
20755
20756
20757
20758
20759
20760
20761
20762
20763
20764
20765
20766
20767
20768
20769
20770
20771
20772
20773
20774
20775
20776
20777
20778
20779
20780
20781
20782
20783
20784
20785
20786
20787
20788
20789
20790
20791
20792
20793
20794
20795
20796
20797
20798
20799
20800
20801
20802
20803
20804
20805
20806
20807
20808
20809
20810
20811
20812
20813
20814
20815
20816
20817
20818
20819
20820
20821
20822
20823
20824
20825
20826
20827
20828
20829
20830
20831
20832
20833
20834
20835
20836
20837
20838
20839
20840
20841
20842
20843
20844
20845
20846
20847
20848
20849
20850
20851
20852
20853
20854
20855
20856
20857
20858
20859
20860
20861
20862
20863
20864
20865
20866
20867
20868
20869
20870
20871
20872
20873
20874
20875
20876
20877
20878
20879
20880
20881
20882
20883
20884
20885
20886
20887
20888
20889
20890
20891
20892
20893
20894
20895
20896
20897
20898
20899
20900
20901
20902
20903
20904
20905
20906
20907
20908
20909
20910
20911
20912
20913
20914
20915
20916
20917
20918
20919
20920
20921
20922
20923
20924
20925
20926
20927
20928
20929
20930
20931
20932
20933
20934
20935
20936
20937
20938
20939
20940
20941
20942
20943
20944
20945
20946
20947
20948
20949
20950
20951
20952
20953
20954
20955
20956
20957
20958
20959
20960
20961
20962
20963
20964
20965
20966
20967
20968
20969
20970
20971
20972
20973
20974
20975
20976
20977
20978
20979
20980
20981
20982
20983
20984
20985
20986
20987
20988
20989
20990
20991
20992
20993
20994
20995
20996
20997
20998
20999
21000
21001
21002
21003
21004
21005
21006
21007
21008
21009
21010
21011
21012
21013
21014
21015
21016
21017
21018
21019
21020
21021
21022
21023
21024
21025
21026
21027
21028
21029
21030
21031
21032
21033
21034
21035
21036
21037
21038
21039
21040
21041
21042
21043
21044
21045
21046
21047
21048
21049
21050
21051
21052
21053
21054
21055
21056
21057
21058
21059
21060
21061
21062
21063
21064
21065
21066
21067
21068
21069
21070
21071
21072
21073
21074
21075
21076
21077
21078
21079
21080
21081
21082
21083
21084
21085
21086
21087
21088
21089
21090
21091
21092
21093
21094
21095
21096
21097
21098
21099
21100
21101
21102
21103
21104
21105
21106
21107
21108
21109
21110
21111
21112
21113
21114
21115
21116
21117
21118
21119
21120
21121
21122
21123
21124
21125
21126
21127
21128
21129
21130
21131
21132
21133
21134
21135
21136
21137
21138
21139
21140
21141
21142
21143
21144
21145
21146
21147
21148
21149
21150
21151
21152
21153
21154
21155
21156
21157
21158
21159
21160
21161
21162
21163
21164
21165
21166
21167
21168
21169
21170
21171
21172
21173
21174
21175
21176
21177
21178
21179
21180
21181
21182
21183
21184
21185
21186
21187
21188
21189
21190
21191
21192
21193
21194
21195
21196
21197
21198
21199
21200
21201
21202
21203
21204
21205
21206
21207
21208
21209
21210
21211
21212
21213
21214
21215
21216
21217
21218
21219
21220
21221
21222
21223
21224
21225
21226
21227
21228
21229
21230
21231
21232
21233
21234
21235
21236
21237
21238
21239
21240
21241
21242
21243
21244
21245
21246
21247
21248
21249
21250
21251
21252
21253
21254
21255
21256
21257
21258
21259
21260
21261
21262
21263
21264
21265
21266
21267
21268
21269
21270
21271
21272
21273
21274
21275
21276
21277
21278
21279
21280
21281
21282
21283
21284
21285
21286
21287
21288
21289
21290
21291
21292
21293
21294
21295
21296
21297
21298
21299
21300
21301
21302
21303
21304
21305
21306
21307
21308
21309
21310
21311
21312
21313
21314
21315
21316
21317
21318
21319
21320
21321
21322
21323
21324
21325
21326
21327
21328
21329
21330
21331
21332
21333
21334
21335
21336
21337
21338
21339
21340
21341
21342
21343
21344
21345
21346
21347
21348
21349
21350
21351
21352
21353
21354
21355
21356
21357
21358
21359
21360
21361
21362
21363
21364
21365
21366
21367
21368
21369
21370
21371
21372
21373
21374
21375
21376
21377
21378
21379
21380
21381
21382
21383
21384
21385
21386
21387
21388
21389
21390
21391
21392
21393
21394
21395
21396
21397
21398
21399
21400
21401
21402
21403
21404
21405
21406
21407
21408
21409
21410
21411
21412
21413
21414
21415
21416
21417
21418
21419
21420
21421
21422
21423
21424
21425
21426
21427
21428
21429
21430
21431
21432
21433
21434
21435
21436
21437
21438
21439
21440
21441
21442
21443
21444
21445
21446
21447
21448
21449
21450
21451
21452
21453
21454
21455
21456
21457
21458
21459
21460
21461
21462
21463
21464
21465
21466
21467
21468
21469
21470
21471
21472
21473
21474
21475
21476
21477
21478
21479
21480
21481
21482
21483
21484
21485
21486
21487
21488
21489
21490
21491
21492
21493
21494
21495
21496
21497
21498
21499
21500
21501
21502
21503
21504
21505
21506
21507
21508
21509
21510
21511
21512
21513
21514
21515
21516
21517
21518
21519
21520
21521
21522
21523
21524
21525
21526
21527
21528
21529
21530
21531
21532
21533
21534
21535
21536
21537
21538
21539
21540
21541
21542
21543
21544
21545
21546
21547
21548
21549
21550
21551
21552
21553
21554
21555
21556
21557
21558
21559
21560
21561
21562
21563
21564
21565
21566
21567
21568
21569
21570
21571
21572
21573
21574
21575
21576
21577
21578
21579
21580
21581
21582
21583
21584
21585
21586
21587
21588
21589
21590
21591
21592
21593
21594
21595
21596
21597
21598
21599
21600
21601
21602
21603
21604
21605
21606
21607
21608
21609
21610
21611
21612
21613
21614
21615
21616
21617
21618
21619
21620
21621
21622
21623
21624
21625
21626
21627
21628
21629
21630
21631
21632
21633
21634
21635
21636
21637
21638
21639
21640
21641
21642
21643
21644
21645
21646
21647
21648
21649
21650
21651
21652
21653
21654
21655
21656
21657
21658
21659
21660
21661
21662
21663
21664
21665
21666
21667
21668
21669
21670
21671
21672
21673
21674
21675
21676
21677
21678
21679
21680
21681
21682
21683
21684
21685
21686
21687
21688
21689
21690
21691
21692
21693
21694
21695
21696
21697
21698
21699
21700
21701
21702
21703
21704
21705
21706
21707
21708
21709
21710
21711
21712
21713
21714
21715
21716
21717
21718
21719
21720
21721
21722
21723
21724
21725
21726
21727
21728
21729
21730
21731
21732
21733
21734
21735
21736
21737
21738
21739
21740
21741
21742
21743
21744
21745
21746
21747
21748
21749
21750
21751
21752
21753
21754
21755
21756
21757
21758
21759
21760
21761
21762
21763
21764
21765
21766
21767
21768
21769
21770
21771
21772
21773
21774
21775
21776
21777
21778
21779
21780
21781
21782
21783
21784
21785
21786
21787
21788
21789
21790
21791
21792
21793
21794
21795
21796
21797
21798
21799
21800
21801
21802
21803
21804
21805
21806
21807
21808
21809
21810
21811
21812
21813
21814
21815
21816
21817
21818
21819
21820
21821
21822
21823
21824
21825
21826
21827
21828
21829
21830
21831
21832
21833
21834
21835
21836
21837
21838
21839
21840
21841
21842
21843
21844
21845
21846
21847
21848
21849
21850
21851
21852
21853
21854
21855
21856
21857
21858
21859
21860
21861
21862
21863
21864
21865
21866
21867
21868
21869
21870
21871
21872
21873
21874
21875
21876
21877
21878
21879
21880
21881
21882
21883
21884
21885
21886
21887
21888
21889
21890
21891
21892
21893
21894
21895
21896
21897
21898
21899
21900
21901
21902
21903
21904
21905
21906
21907
21908
21909
21910
21911
21912
21913
21914
21915
21916
21917
21918
21919
21920
21921
21922
21923
21924
21925
21926
21927
21928
21929
21930
21931
21932
21933
21934
21935
21936
21937
21938
21939
21940
21941
21942
21943
21944
21945
21946
21947
21948
21949
21950
21951
21952
21953
21954
21955
21956
21957
21958
21959
21960
21961
21962
21963
21964
21965
21966
21967
21968
21969
21970
21971
21972
21973
21974
21975
21976
21977
21978
21979
21980
21981
21982
21983
21984
21985
21986
21987
21988
21989
21990
21991
21992
21993
21994
21995
21996
21997
21998
21999
22000
22001
22002
22003
22004
22005
22006
22007
22008
22009
22010
22011
22012
22013
22014
22015
22016
22017
22018
22019
22020
22021
22022
22023
22024
22025
22026
22027
22028
22029
22030
22031
22032
22033
22034
22035
22036
22037
22038
22039
22040
22041
22042
22043
22044
22045
22046
22047
22048
22049
22050
22051
22052
22053
22054
22055
22056
22057
22058
22059
22060
22061
22062
22063
22064
22065
22066
22067
22068
22069
22070
22071
22072
22073
22074
22075
22076
22077
22078
22079
22080
22081
22082
22083
22084
22085
22086
22087
22088
22089
22090
22091
22092
22093
22094
22095
22096
22097
22098
22099
22100
22101
22102
22103
22104
22105
22106
22107
22108
22109
22110
22111
22112
22113
22114
22115
22116
22117
22118
22119
22120
22121
22122
22123
22124
22125
22126
22127
22128
22129
22130
22131
22132
22133
22134
22135
22136
22137
22138
22139
22140
22141
22142
22143
22144
22145
22146
22147
22148
22149
22150
22151
22152
22153
22154
22155
22156
22157
22158
22159
22160
22161
22162
22163
22164
22165
22166
22167
22168
22169
22170
22171
22172
22173
22174
22175
22176
22177
22178
22179
22180
22181
22182
22183
22184
22185
22186
22187
22188
22189
22190
22191
22192
22193
22194
22195
22196
22197
22198
22199
22200
22201
22202
22203
22204
22205
22206
22207
22208
22209
22210
22211
22212
22213
22214
22215
22216
22217
22218
22219
22220
22221
22222
22223
22224
22225
22226
22227
22228
22229
22230
22231
22232
22233
22234
22235
22236
22237
22238
22239
22240
22241
22242
22243
22244
22245
22246
22247
22248
22249
22250
22251
22252
22253
22254
22255
22256
22257
22258
22259
22260
22261
22262
22263
22264
22265
22266
22267
22268
22269
22270
22271
22272
22273
22274
22275
22276
22277
22278
22279
22280
22281
22282
22283
22284
22285
22286
22287
22288
22289
22290
22291
22292
22293
22294
22295
22296
22297
22298
22299
22300
22301
22302
22303
22304
22305
22306
22307
22308
22309
22310
22311
22312
22313
22314
22315
22316
22317
22318
22319
22320
22321
22322
22323
22324
22325
22326
22327
22328
22329
22330
22331
22332
22333
22334
22335
22336
22337
22338
22339
22340
22341
22342
22343
22344
22345
22346
22347
22348
22349
22350
22351
22352
22353
22354
22355
22356
22357
22358
22359
22360
22361
22362
22363
22364
22365
22366
22367
22368
22369
22370
22371
22372
22373
22374
22375
22376
22377
22378
22379
22380
22381
22382
22383
22384
22385
22386
22387
22388
22389
22390
22391
22392
22393
22394
22395
22396
22397
22398
22399
22400
22401
22402
22403
22404
22405
22406
22407
22408
22409
22410
22411
22412
22413
22414
22415
22416
22417
22418
22419
22420
22421
22422
22423
22424
22425
22426
22427
22428
22429
22430
22431
22432
22433
22434
22435
22436
22437
22438
22439
22440
22441
22442
22443
22444
22445
22446
22447
22448
22449
22450
22451
22452
22453
22454
22455
22456
22457
22458
22459
22460
22461
22462
22463
22464
22465
22466
22467
22468
22469
22470
22471
22472
22473
22474
22475
22476
22477
22478
22479
22480
22481
22482
22483
22484
22485
22486
22487
22488
22489
22490
22491
22492
22493
22494
22495
22496
22497
22498
22499
22500
22501
22502
22503
22504
22505
22506
22507
22508
22509
22510
22511
22512
22513
22514
22515
22516
22517
22518
22519
22520
22521
22522
22523
22524
22525
22526
22527
22528
22529
22530
22531
22532
22533
22534
22535
22536
22537
22538
22539
22540
22541
22542
22543
22544
22545
22546
22547
22548
22549
22550
22551
22552
22553
22554
22555
22556
22557
22558
22559
22560
22561
22562
22563
22564
22565
22566
22567
22568
22569
22570
22571
22572
22573
22574
22575
22576
22577
22578
22579
22580
22581
22582
22583
22584
22585
22586
22587
22588
22589
22590
22591
22592
22593
22594
22595
22596
22597
22598
22599
22600
22601
22602
22603
22604
22605
22606
22607
22608
22609
22610
22611
22612
22613
22614
22615
22616
22617
22618
22619
22620
22621
22622
22623
22624
22625
22626
22627
22628
22629
22630
22631
22632
22633
22634
22635
22636
22637
22638
22639
22640
22641
22642
22643
22644
22645
22646
22647
22648
22649
22650
22651
22652
22653
22654
22655
22656
22657
22658
22659
22660
22661
22662
22663
22664
22665
22666
22667
22668
22669
22670
22671
22672
22673
22674
22675
22676
22677
22678
22679
22680
22681
22682
22683
22684
22685
22686
22687
22688
22689
22690
22691
22692
22693
22694
22695
22696
22697
22698
22699
22700
22701
22702
22703
22704
22705
22706
22707
22708
22709
22710
22711
22712
22713
22714
22715
22716
22717
22718
22719
22720
22721
22722
22723
22724
22725
22726
22727
22728
22729
22730
22731
22732
22733
22734
22735
22736
22737
22738
22739
22740
22741
22742
22743
22744
22745
22746
22747
22748
22749
22750
22751
22752
22753
22754
22755
22756
22757
22758
22759
22760
22761
22762
22763
22764
22765
22766
22767
22768
22769
22770
22771
22772
22773
22774
22775
22776
22777
22778
22779
22780
22781
22782
22783
22784
22785
22786
22787
22788
22789
22790
22791
22792
22793
22794
22795
22796
22797
22798
22799
22800
22801
22802
22803
22804
22805
22806
22807
22808
22809
22810
22811
22812
22813
22814
22815
22816
22817
22818
22819
22820
22821
22822
22823
22824
22825
22826
22827
22828
22829
22830
22831
22832
22833
22834
22835
22836
22837
22838
22839
22840
22841
22842
22843
22844
22845
22846
22847
22848
22849
22850
22851
22852
22853
22854
22855
22856
22857
22858
22859
22860
22861
22862
22863
22864
22865
22866
22867
22868
22869
22870
22871
22872
22873
22874
22875
22876
22877
22878
22879
22880
22881
22882
22883
22884
22885
22886
22887
22888
22889
22890
22891
22892
22893
22894
22895
22896
22897
22898
22899
22900
22901
22902
22903
22904
22905
22906
22907
22908
22909
22910
22911
22912
22913
22914
22915
22916
22917
22918
22919
22920
22921
22922
22923
22924
22925
22926
22927
22928
22929
22930
22931
22932
22933
22934
22935
22936
22937
22938
22939
22940
22941
22942
22943
22944
22945
22946
22947
22948
22949
22950
22951
22952
22953
22954
22955
22956
22957
22958
22959
22960
22961
22962
22963
22964
22965
22966
22967
22968
22969
22970
22971
22972
22973
22974
22975
22976
22977
22978
22979
22980
22981
22982
22983
22984
22985
22986
22987
22988
22989
22990
22991
22992
22993
22994
22995
22996
22997
22998
22999
23000
23001
23002
23003
23004
23005
23006
23007
23008
23009
23010
23011
23012
23013
23014
23015
23016
23017
23018
23019
23020
23021
23022
23023
23024
23025
23026
23027
23028
23029
23030
23031
23032
23033
23034
23035
23036
23037
23038
23039
23040
23041
23042
23043
23044
23045
23046
23047
23048
23049
23050
23051
23052
23053
23054
23055
23056
23057
23058
23059
23060
23061
23062
23063
23064
23065
23066
23067
23068
23069
23070
23071
23072
23073
23074
23075
23076
23077
23078
23079
23080
23081
23082
23083
23084
23085
23086
23087
23088
23089
23090
23091
23092
23093
23094
23095
23096
23097
23098
23099
23100
23101
23102
23103
23104
23105
23106
23107
23108
23109
23110
23111
23112
23113
23114
23115
23116
23117
23118
23119
23120
23121
23122
23123
23124
23125
23126
23127
23128
23129
23130
23131
23132
23133
23134
23135
23136
23137
23138
23139
23140
23141
23142
23143
23144
23145
23146
23147
23148
23149
23150
23151
23152
23153
23154
23155
23156
23157
23158
23159
23160
23161
23162
23163
23164
23165
23166
23167
23168
23169
23170
23171
23172
23173
23174
23175
23176
23177
23178
23179
23180
23181
23182
23183
23184
23185
23186
23187
23188
23189
23190
23191
23192
23193
23194
23195
23196
23197
23198
23199
23200
23201
23202
23203
23204
23205
23206
23207
23208
23209
23210
23211
23212
23213
23214
23215
23216
23217
23218
23219
23220
23221
23222
23223
23224
23225
23226
23227
23228
23229
23230
23231
23232
23233
23234
23235
23236
23237
23238
23239
23240
23241
23242
23243
23244
23245
23246
23247
23248
23249
23250
23251
23252
23253
23254
23255
23256
23257
23258
23259
23260
23261
23262
23263
23264
23265
23266
23267
23268
23269
23270
23271
23272
23273
23274
23275
23276
23277
23278
23279
23280
23281
23282
23283
23284
23285
23286
23287
23288
23289
23290
23291
23292
23293
23294
23295
23296
23297
23298
23299
23300
23301
23302
23303
23304
23305
23306
23307
23308
23309
23310
23311
23312
23313
23314
23315
23316
23317
23318
23319
23320
23321
23322
23323
23324
23325
23326
23327
23328
23329
23330
23331
23332
23333
23334
23335
23336
23337
23338
23339
23340
23341
23342
23343
23344
23345
23346
23347
23348
23349
23350
23351
23352
23353
23354
23355
23356
23357
23358
23359
23360
23361
23362
23363
23364
23365
23366
23367
23368
23369
23370
23371
23372
23373
23374
23375
23376
23377
23378
23379
23380
23381
23382
23383
23384
23385
23386
23387
23388
23389
23390
23391
23392
23393
23394
23395
23396
23397
23398
23399
23400
23401
23402
23403
23404
23405
23406
23407
23408
23409
23410
23411
23412
23413
23414
23415
23416
23417
23418
23419
23420
23421
23422
23423
23424
23425
23426
23427
23428
23429
23430
23431
23432
23433
23434
23435
23436
23437
23438
23439
23440
23441
23442
23443
23444
23445
23446
23447
23448
23449
23450
23451
23452
23453
23454
23455
23456
23457
23458
23459
23460
23461
23462
23463
23464
23465
23466
23467
23468
23469
23470
23471
23472
23473
23474
23475
23476
23477
23478
23479
23480
23481
23482
23483
23484
23485
23486
23487
23488
23489
23490
23491
23492
23493
23494
23495
23496
23497
23498
23499
23500
23501
23502
23503
23504
23505
23506
23507
23508
23509
23510
23511
23512
23513
23514
23515
23516
23517
23518
23519
23520
23521
23522
23523
23524
23525
23526
23527
23528
23529
23530
23531
23532
23533
23534
23535
23536
23537
23538
23539
23540
23541
23542
23543
23544
23545
23546
23547
23548
23549
23550
23551
23552
23553
23554
23555
23556
23557
23558
23559
23560
23561
23562
23563
23564
23565
23566
23567
23568
23569
23570
23571
23572
23573
23574
23575
23576
23577
23578
23579
23580
23581
23582
23583
23584
23585
23586
23587
23588
23589
23590
23591
23592
23593
23594
23595
23596
23597
23598
23599
23600
23601
23602
23603
23604
23605
23606
23607
23608
23609
23610
23611
23612
23613
23614
23615
23616
23617
23618
23619
23620
23621
23622
23623
23624
23625
23626
23627
23628
23629
23630
23631
23632
23633
23634
23635
23636
23637
23638
23639
23640
23641
23642
23643
23644
23645
23646
23647
23648
23649
23650
23651
23652
23653
23654
23655
23656
23657
23658
23659
23660
23661
23662
23663
23664
23665
23666
23667
23668
23669
23670
23671
23672
23673
23674
23675
23676
23677
23678
23679
23680
23681
23682
23683
23684
23685
23686
23687
23688
23689
23690
23691
23692
23693
23694
23695
23696
23697
23698
23699
23700
23701
23702
23703
23704
23705
23706
23707
23708
23709
23710
23711
23712
23713
23714
23715
23716
23717
23718
23719
23720
23721
23722
23723
23724
23725
23726
23727
23728
23729
23730
23731
23732
23733
23734
23735
23736
23737
23738
23739
23740
23741
23742
23743
23744
23745
23746
23747
23748
23749
23750
23751
23752
23753
23754
23755
23756
23757
23758
23759
23760
23761
23762
23763
23764
23765
23766
23767
23768
23769
23770
23771
23772
23773
23774
23775
23776
23777
23778
23779
23780
23781
23782
23783
23784
23785
23786
23787
23788
23789
23790
23791
23792
23793
23794
23795
23796
23797
23798
23799
23800
23801
23802
23803
23804
23805
23806
23807
23808
23809
23810
23811
23812
23813
23814
23815
23816
23817
23818
23819
23820
23821
23822
23823
23824
23825
23826
23827
23828
23829
23830
23831
23832
23833
23834
23835
23836
23837
23838
23839
23840
23841
23842
23843
23844
23845
23846
23847
23848
23849
23850
23851
23852
23853
23854
23855
23856
23857
23858
23859
23860
23861
23862
23863
23864
23865
23866
23867
23868
23869
23870
23871
23872
23873
23874
23875
23876
23877
23878
23879
23880
23881
23882
23883
23884
23885
23886
23887
23888
23889
23890
23891
23892
23893
23894
23895
23896
23897
23898
23899
23900
23901
23902
23903
23904
23905
23906
23907
23908
23909
23910
23911
23912
23913
23914
23915
23916
23917
23918
23919
23920
23921
23922
23923
23924
23925
23926
23927
23928
23929
23930
23931
23932
23933
23934
23935
23936
23937
23938
23939
23940
23941
23942
23943
23944
23945
23946
23947
23948
23949
23950
23951
23952
23953
23954
23955
23956
23957
23958
23959
23960
23961
23962
23963
23964
23965
23966
23967
23968
23969
23970
23971
23972
23973
23974
23975
23976
23977
23978
23979
23980
23981
23982
23983
23984
23985
23986
23987
23988
23989
23990
23991
23992
23993
23994
23995
23996
23997
23998
23999
24000
24001
24002
24003
24004
24005
24006
24007
24008
24009
24010
24011
24012
24013
24014
24015
24016
24017
24018
24019
24020
24021
24022
24023
24024
24025
24026
24027
24028
24029
24030
24031
24032
24033
24034
24035
24036
24037
24038
24039
24040
24041
24042
24043
24044
24045
24046
24047
24048
24049
24050
24051
24052
24053
24054
24055
24056
24057
24058
24059
24060
24061
24062
24063
24064
24065
24066
24067
24068
24069
24070
24071
24072
24073
24074
24075
24076
24077
24078
24079
24080
24081
24082
24083
24084
24085
24086
24087
24088
24089
24090
24091
24092
24093
24094
24095
24096
24097
24098
24099
24100
24101
24102
24103
24104
24105
24106
24107
24108
24109
24110
24111
24112
24113
24114
24115
24116
24117
24118
24119
24120
24121
24122
24123
24124
24125
24126
24127
24128
24129
24130
24131
24132
24133
24134
24135
24136
24137
24138
24139
24140
24141
24142
24143
24144
24145
24146
24147
24148
24149
24150
24151
24152
24153
24154
24155
24156
24157
24158
24159
24160
24161
24162
24163
24164
24165
24166
24167
24168
24169
24170
24171
24172
24173
24174
24175
24176
24177
24178
24179
24180
24181
24182
24183
24184
24185
24186
24187
24188
24189
24190
24191
24192
24193
24194
24195
24196
24197
24198
24199
24200
24201
24202
24203
24204
24205
24206
24207
24208
24209
24210
24211
24212
24213
24214
24215
24216
24217
24218
24219
24220
24221
24222
24223
24224
24225
24226
24227
24228
24229
24230
24231
24232
24233
24234
24235
24236
24237
24238
24239
24240
24241
24242
24243
24244
24245
24246
24247
24248
24249
24250
24251
24252
24253
24254
24255
24256
24257
24258
24259
24260
24261
24262
24263
24264
24265
24266
24267
24268
24269
24270
24271
24272
24273
24274
24275
24276
24277
24278
24279
24280
24281
24282
24283
24284
24285
24286
24287
24288
24289
24290
24291
24292
24293
24294
24295
24296
24297
24298
24299
24300
24301
24302
24303
24304
24305
24306
24307
24308
24309
24310
24311
24312
24313
24314
24315
24316
24317
24318
24319
24320
24321
24322
24323
24324
24325
24326
24327
24328
24329
24330
24331
24332
24333
24334
24335
24336
24337
24338
24339
24340
24341
24342
24343
24344
24345
24346
24347
24348
24349
24350
24351
24352
24353
24354
24355
24356
24357
24358
24359
24360
24361
24362
24363
24364
24365
24366
24367
24368
24369
24370
24371
24372
24373
24374
24375
24376
24377
24378
24379
24380
24381
24382
24383
24384
24385
24386
24387
24388
24389
24390
24391
24392
24393
24394
24395
24396
24397
24398
24399
24400
24401
24402
24403
24404
24405
24406
24407
24408
24409
24410
24411
24412
24413
24414
24415
24416
24417
24418
24419
24420
24421
24422
24423
24424
24425
24426
24427
24428
24429
24430
24431
24432
24433
24434
24435
24436
24437
24438
24439
24440
24441
24442
24443
24444
24445
24446
24447
24448
24449
24450
24451
24452
24453
24454
24455
24456
24457
24458
24459
24460
24461
24462
24463
24464
24465
24466
24467
24468
24469
24470
24471
24472
24473
24474
24475
24476
24477
24478
24479
24480
24481
24482
24483
24484
24485
24486
24487
24488
24489
24490
24491
24492
24493
24494
24495
24496
24497
24498
24499
24500
24501
24502
24503
24504
24505
24506
24507
24508
24509
24510
24511
24512
24513
24514
24515
24516
24517
24518
24519
24520
24521
24522
24523
24524
24525
24526
24527
24528
24529
24530
24531
24532
24533
24534
24535
24536
24537
24538
24539
24540
24541
24542
24543
24544
24545
24546
24547
24548
24549
24550
24551
24552
24553
24554
24555
24556
24557
24558
24559
24560
24561
24562
24563
24564
24565
24566
24567
24568
24569
24570
24571
24572
24573
24574
24575
24576
24577
24578
24579
24580
24581
24582
24583
24584
24585
24586
24587
24588
24589
24590
24591
24592
24593
24594
24595
24596
24597
24598
24599
24600
24601
24602
24603
24604
24605
24606
24607
24608
24609
24610
24611
24612
24613
24614
24615
24616
24617
24618
24619
24620
24621
24622
24623
24624
24625
24626
24627
24628
24629
24630
24631
24632
24633
24634
24635
24636
24637
24638
24639
24640
24641
24642
24643
24644
24645
24646
24647
24648
24649
24650
24651
24652
24653
24654
24655
24656
24657
24658
24659
24660
24661
24662
24663
24664
24665
24666
24667
24668
24669
24670
24671
24672
24673
24674
24675
24676
24677
24678
24679
24680
24681
24682
24683
24684
24685
24686
24687
24688
24689
24690
24691
24692
24693
24694
24695
24696
24697
24698
24699
24700
24701
24702
24703
24704
24705
24706
24707
24708
24709
24710
24711
24712
24713
24714
24715
24716
24717
24718
24719
24720
24721
24722
24723
24724
24725
24726
24727
24728
24729
24730
24731
24732
24733
24734
24735
24736
24737
24738
24739
24740
24741
24742
24743
24744
24745
24746
24747
24748
24749
24750
24751
24752
24753
24754
24755
24756
24757
24758
24759
24760
24761
24762
24763
24764
24765
24766
24767
24768
24769
24770
24771
24772
24773
24774
24775
24776
24777
24778
24779
24780
24781
24782
24783
24784
24785
24786
24787
24788
24789
24790
24791
24792
24793
24794
24795
24796
24797
24798
24799
24800
24801
24802
24803
24804
24805
24806
24807
24808
24809
24810
24811
24812
24813
24814
24815
24816
24817
24818
24819
24820
24821
24822
24823
24824
24825
24826
24827
24828
24829
24830
24831
24832
24833
24834
24835
24836
24837
24838
24839
24840
24841
24842
24843
24844
24845
24846
24847
24848
24849
24850
24851
24852
24853
24854
24855
24856
24857
24858
24859
24860
24861
24862
24863
24864
24865
24866
24867
24868
24869
24870
24871
\input texinfo   @c -*-texinfo-*-
@c %**start of header

@c oooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooo
@c                                                                            o
@c                            GNAT DOCUMENTATION                              o
@c                                                                            o
@c                              G N A T _ U G                                 o
@c                                                                            o
@c          Copyright (C) 1992-2002 Ada Core Technologies, Inc.               o
@c                                                                            o
@c  GNAT is free software;  you can  redistribute it  and/or modify it under  o
@c  terms of the  GNU General Public License as published  by the Free Soft-  o
@c  ware  Foundation;  either version 2,  or (at your option) any later ver-  o
@c  sion.  GNAT is distributed in the hope that it will be useful, but WITH-  o
@c  OUT ANY WARRANTY;  without even the  implied warranty of MERCHANTABILITY  o
@c  or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License  o
@c  for  more details.  You should have  received  a copy of the GNU General  o
@c  Public License  distributed with GNAT;  see file COPYING.  If not, write  o
@c  to  the Free Software Foundation,  59 Temple Place - Suite 330,  Boston,  o
@c  MA 02111-1307, USA.                                                       o
@c                                                                            o
@c oooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooo

@c oooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooo
@c
@c                           GNAT_UG Style Guide
@c
@c  1. Always put a @noindent on the line before the first paragraph
@c     after any of these commands:
@c
@c          @chapter
@c          @section
@c          @subsection
@c          @subsubsection
@c          @subsubsubsection
@c
@c          @end smallexample
@c          @end itemize
@c          @end enumerate
@c
@c  2. DO NOT use @example. Use @smallexample instead.
@c
@c  3. Each @chapter, @section, @subsection, @subsubsection, etc.
@c     command must be preceded by two empty lines
@c
@c  4. The @item command must be on a line of its own if it is in an
@c     @itemize or @enumerate command.
@c
@c  5. When talking about ALI files use "ALI" (all uppercase), not "Ali"
@c     or "ali".
@c
@c oooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooooo

@ifset vms
@setfilename gnat_ug_vms.info
@settitle GNAT User's Guide for OpenVMS Alpha
@end ifset

@ifset wnt
@setfilename gnat_ug_wnt.info
@settitle GNAT User's Guide for Windows NT
@end ifset

@ifset unx
@setfilename gnat_ug_unx.info
@settitle GNAT User's Guide for Unix Platforms
@end ifset

@ifset vxworks
@setfilename gnat_ug_vxw.info
@settitle GNAT User's Guide for Cross Platforms
@end ifset

@include gcc-common.texi

@setchapternewpage odd
@syncodeindex fn cp
@c %**end of header

@copying
Copyright @copyright{} 1995-2002, Free Software Foundation

Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.1
or any later version published by the Free Software Foundation;
with the Invariant Sections being ``GNU Free Documentation License'', with the
Front-Cover Texts being
@ifset vms
``GNAT User's Guide for OpenVMS Alpha'',
@end ifset
@ifset wnt
``GNAT User's Guide for Windows NT'',
@end ifset
@ifset unx
``GNAT User's Guide for Unix Platforms'',
@end ifset
@ifset vxworks
``GNAT User's Guide for Cross Platforms'',
@end ifset
and with no Back-Cover Texts.
A copy of the license is included in the section entitled ``GNU
Free Documentation License''.
@end copying

@titlepage

@ifset vms
@title GNAT User's Guide
@center @titlefont{for OpenVMS Alpha}
@end ifset

@ifset wnt
@title GNAT User's Guide
@center @titlefont{for Windows NT}
@end ifset

@ifset unx
@title GNAT User's Guide
@center @titlefont{for Unix Platforms}
@end ifset

@ifset vxworks
@title GNAT User's Guide
@center @titlefont{for Cross Platforms}
@end ifset

@subtitle GNAT, The GNU Ada 95 Compiler
@subtitle GNAT Version for GCC @value{version-GCC}

@author Ada Core Technologies, Inc.

@page
@vskip 0pt plus 1filll

@insertcopying

@end titlepage

@ifnottex
@node Top, About This Guide, (dir), (dir)
@top GNAT User's Guide

@ifset vms
GNAT User's Guide for OpenVMS Alpha
@end ifset

@ifset wnt
GNAT User's Guide for Windows NT
@end ifset

@ifset unx
GNAT User's Guide for Unix Platforms
@end ifset

@ifset vxworks
GNAT User's Guide for Cross Platforms
@end ifset

GNAT, The GNU Ada 95 Compiler

GNAT Version for GCC @value{version-GCC}

Ada Core Technologies, Inc.

@insertcopying

@menu
* About This Guide::
@ifset vxworks
* Preliminary Note for Cross Platform Users::
@end ifset
* Getting Started with GNAT::
* The GNAT Compilation Model::
* Compiling Using gcc::
* Binding Using gnatbind::
* Linking Using gnatlink::
* The GNAT Make Program gnatmake::
* Renaming Files Using gnatchop::
* Configuration Pragmas::
* Handling Arbitrary File Naming Conventions Using gnatname::
* GNAT Project Manager::
* Elaboration Order Handling in GNAT::
* The Cross-Referencing Tools gnatxref and gnatfind::
* File Name Krunching Using gnatkr::
* Preprocessing Using gnatprep::
@ifset vms
* The GNAT Run-Time Library Builder gnatlbr::
@end ifset
* The GNAT Library Browser gnatls::
@ifclear vms
* GNAT and Libraries::
* Using the GNU make Utility::
@ifclear vxworks
* Finding Memory Problems with gnatmem::
@end ifclear
@end ifclear
* Finding Memory Problems with GNAT Debug Pool::
* Creating Sample Bodies Using gnatstub::
* Reducing the Size of Ada Executables with gnatelim::
* Other Utility Programs::
@ifset vms
* Compatibility with DEC Ada::
@end ifset
* Running and Debugging Ada Programs::
* Inline Assembler::
@ifset wnt
* Microsoft Windows Topics::
@end ifset
@ifset vxworks
* VxWorks Topics::
* LynxOS Topics::
@end ifset
* Performance Considerations::
* GNU Free Documentation License::
* Index::

 --- The Detailed Node Listing ---

About This Guide

* What This Guide Contains::
* What You Should Know before Reading This Guide::
* Related Information::
* Conventions::

@ifset vxworks
Preliminary Note for Cross Platform Users::
@end ifset

Getting Started with GNAT

* Running GNAT::
@ifclear vxworks
* Running a Simple Ada Program::
@end ifclear
@ifset vxworks
* Building a Simple Ada Program::
* Executing a Program on VxWorks::
@end ifset
* Running a Program with Multiple Units::
* Using the gnatmake Utility::
@ifset vms
* Editing with Emacs::
@end ifset

The GNAT Compilation Model

* Source Representation::
* Foreign Language Representation::
* File Naming Rules::
* Using Other File Names::
* Alternative File Naming Schemes::
* Generating Object Files::
* Source Dependencies::
* The Ada Library Information Files::
* Binding an Ada Program::
* Mixed Language Programming::
* Building Mixed Ada & C++ Programs::
* Comparison between GNAT and C/C++ Compilation Models::
* Comparison between GNAT and Conventional Ada Library Models::

Foreign Language Representation

* Latin-1::
* Other 8-Bit Codes::
* Wide Character Encodings::

Compiling Ada Programs With gcc

* Compiling Programs::
* Switches for gcc::
* Search Paths and the Run-Time Library (RTL)::
* Order of Compilation Issues::
* Examples::

Switches for gcc

* Output and Error Message Control::
* Debugging and Assertion Control::
* Run-Time Checks::
* Stack Overflow Checking::
* Run-Time Control::
* Validity Checking::
* Style Checking::
* Using gcc for Syntax Checking::
* Using gcc for Semantic Checking::
* Compiling Ada 83 Programs::
* Character Set Control::
* File Naming Control::
* Subprogram Inlining Control::
* Auxiliary Output Control::
* Debugging Control::
* Units to Sources Mapping Files::

Binding Ada Programs With gnatbind

* Running gnatbind::
* Generating the Binder Program in C::
* Consistency-Checking Modes::
* Binder Error Message Control::
* Elaboration Control::
* Output Control::
* Binding with Non-Ada Main Programs::
* Binding Programs with No Main Subprogram::
* Summary of Binder Switches::
* Command-Line Access::
* Search Paths for gnatbind::
* Examples of gnatbind Usage::

Linking Using gnatlink

* Running gnatlink::
* Switches for gnatlink::
* Setting Stack Size from gnatlink::
* Setting Heap Size from gnatlink::

The GNAT Make Program gnatmake

* Running gnatmake::
* Switches for gnatmake::
* Mode Switches for gnatmake::
* Notes on the Command Line::
* How gnatmake Works::
* Examples of gnatmake Usage::

Renaming Files Using gnatchop

* Handling Files with Multiple Units::
* Operating gnatchop in Compilation Mode::
* Command Line for gnatchop::
* Switches for gnatchop::
* Examples of gnatchop Usage::

Configuration Pragmas

* Handling of Configuration Pragmas::
* The Configuration Pragmas Files::

Handling Arbitrary File Naming Conventions Using gnatname

* Arbitrary File Naming Conventions::
* Running gnatname::
* Switches for gnatname::
* Examples of gnatname Usage::

GNAT Project Manager

* Introduction::
* Examples of Project Files::
* Project File Syntax::
* Objects and Sources in Project Files::
* Importing Projects::
* Project Extension::
* External References in Project Files::
* Packages in Project Files::
* Variables from Imported Projects::
* Naming Schemes::
* Library Projects::
* Switches Related to Project Files::
* Tools Supporting Project Files::
* An Extended Example::
* Project File Complete Syntax::

Elaboration Order Handling in GNAT

* Elaboration Code in Ada 95::
* Checking the Elaboration Order in Ada 95::
* Controlling the Elaboration Order in Ada 95::
* Controlling Elaboration in GNAT - Internal Calls::
* Controlling Elaboration in GNAT - External Calls::
* Default Behavior in GNAT - Ensuring Safety::
* Elaboration Issues for Library Tasks::
* Mixing Elaboration Models::
* What to Do If the Default Elaboration Behavior Fails::
* Elaboration for Access-to-Subprogram Values::
* Summary of Procedures for Elaboration Control::
* Other Elaboration Order Considerations::

The Cross-Referencing Tools gnatxref and gnatfind

* gnatxref Switches::
* gnatfind Switches::
* Project Files for gnatxref and gnatfind::
* Regular Expressions in gnatfind and gnatxref::
* Examples of gnatxref Usage::
* Examples of gnatfind Usage::

File Name Krunching Using gnatkr

* About gnatkr::
* Using gnatkr::
* Krunching Method::
* Examples of gnatkr Usage::

Preprocessing Using gnatprep

* Using gnatprep::
* Switches for gnatprep::
* Form of Definitions File::
* Form of Input Text for gnatprep::

@ifset vms
The GNAT Run-Time Library Builder gnatlbr

* Running gnatlbr::
* Switches for gnatlbr::
* Examples of gnatlbr Usage::
@end ifset

The GNAT Library Browser gnatls

* Running gnatls::
* Switches for gnatls::
* Examples of gnatls Usage::

@ifclear vms

GNAT and Libraries

* Creating an Ada Library::
* Installing an Ada Library::
* Using an Ada Library::
* Creating an Ada Library to be Used in a Non-Ada Context::
* Rebuilding the GNAT Run-Time Library::

Using the GNU make Utility

* Using gnatmake in a Makefile::
* Automatically Creating a List of Directories::
* Generating the Command Line Switches::
* Overcoming Command Line Length Limits::

@ifclear vxworks
Finding Memory Problems with gnatmem

* Running gnatmem (GDB Mode)::
* Running gnatmem (GMEM Mode)::
* Switches for gnatmem::
* Examples of gnatmem Usage::
* GDB and GMEM Modes::
* Implementation Note::

@end ifclear
@end ifclear

Finding Memory Problems with GNAT Debug Pool

Creating Sample Bodies Using gnatstub

* Running gnatstub::
* Switches for gnatstub::

Reducing the Size of Ada Executables with gnatelim

* About gnatelim::
* Eliminate Pragma::
* Tree Files::
* Preparing Tree and Bind Files for gnatelim::
* Running gnatelim::
* Correcting the List of Eliminate Pragmas::
* Making Your Executables Smaller::
* Summary of the gnatelim Usage Cycle::

Other Utility Programs

* Using Other Utility Programs with GNAT::
* The gnatpsta Utility Program::
* The External Symbol Naming Scheme of GNAT::
* Ada Mode for Glide::
* Converting Ada Files to html with gnathtml::
@ifset vms
* LSE::
@end ifset

@ifset vms
Compatibility with DEC Ada

* Ada 95 Compatibility::
* Differences in the Definition of Package System::
* Language-Related Features::
* The Package STANDARD::
* The Package SYSTEM::
* Tasking and Task-Related Features::
* Implementation of Tasks in DEC Ada for OpenVMS Alpha Systems::
* Pragmas and Pragma-Related Features::
* Library of Predefined Units::
* Bindings::
* Main Program Definition::
* Implementation-Defined Attributes::
* Compiler and Run-Time Interfacing::
* Program Compilation and Library Management::
* Input-Output::
* Implementation Limits::
* Tools::

Language-Related Features

* Integer Types and Representations::
* Floating-Point Types and Representations::
* Pragmas Float_Representation and Long_Float::
* Fixed-Point Types and Representations::
* Record and Array Component Alignment::
* Address Clauses::
* Other Representation Clauses::

Implementation of Tasks in DEC Ada for OpenVMS Alpha Systems

* Assigning Task IDs::
* Task IDs and Delays::
* Task-Related Pragmas::
* Scheduling and Task Priority::
* The Task Stack::
* External Interrupts::

Pragmas and Pragma-Related Features

* Restrictions on the Pragma INLINE::
* Restrictions on the Pragma INTERFACE::
* Restrictions on the Pragma SYSTEM_NAME::

Library of Predefined Units

* Changes to DECLIB::

Bindings

* Shared Libraries and Options Files::
* Interfaces to C::
@end ifset

Running and Debugging Ada Programs

* The GNAT Debugger GDB::
* Running GDB::
* Introduction to GDB Commands::
* Using Ada Expressions::
* Calling User-Defined Subprograms::
* Using the Next Command in a Function::
* Ada Exceptions::
* Ada Tasks::
* Debugging Generic Units::
* GNAT Abnormal Termination or Failure to Terminate::
* Naming Conventions for GNAT Source Files::
* Getting Internal Debugging Information::
* Stack Traceback::

Inline Assembler

* Basic Assembler Syntax::
* A Simple Example of Inline Assembler::
* Output Variables in Inline Assembler::
* Input Variables in Inline Assembler::
* Inlining Inline Assembler Code::
* Other Asm Functionality::
* A Complete Example::

@ifset wnt
Microsoft Windows Topics

* Using GNAT on Windows::
* GNAT Setup Tool::
* CONSOLE and WINDOWS subsystems::
* Temporary Files::
* Mixed-Language Programming on Windows::
* Windows Calling Conventions::
* Introduction to Dynamic Link Libraries (DLLs)::
* Using DLLs with GNAT::
* Building DLLs with GNAT::
* GNAT and Windows Resources::
* GNAT and COM/DCOM Objects::
@end ifset

@ifset vxworks
VxWorks Topics

* Kernel Configuration for VxWorks::
* Kernel Compilation Issues for VxWorks::
* Handling Relocation Issues for PowerPc Targets::
* Support for Software Floating Point on PowerPC Processors::
* Interrupt Handling for VxWorks::
* Simulating Command Line Arguments for VxWorks::
* Debugging Issues for VxWorks::
* Using GNAT from the Tornado 2 Project Facility::
* Frequently Asked Questions for VxWorks::

LynxOS Topics

* Getting Started with GNAT on LynxOS::
* Kernel Configuration for LynxOS::
* Patch Level Issues for LynxOS::
* Debugging Issues for LynxOS::
* An Example Debugging Session for LynxOS::
@end ifset

Performance Considerations

* Controlling Run-Time Checks::
* Optimization Levels::
* Debugging Optimized Code::
* Inlining of Subprograms::
@ifset vms
* Coverage Analysis::
@end ifset

* Index::
@end menu
@end ifnottex

@node About This Guide
@unnumbered About This Guide

@noindent
@ifset vms
This guide describes the use of of GNAT, a full language compiler for the Ada
95 programming language, implemented on DIGITAL OpenVMS Alpha Systems.
@end ifset
@ifclear vms
This guide describes the use of GNAT, a compiler and software development
toolset for the full Ada 95 programming language.
@end ifclear
It describes the features of the compiler and tools, and details
how to use them to build Ada 95 applications.

@menu
* What This Guide Contains::
* What You Should Know before Reading This Guide::
* Related Information::
* Conventions::
@end menu

@node What This Guide Contains
@unnumberedsec What This Guide Contains

@noindent
This guide contains the following chapters:
@itemize @bullet
@ifset vxworks
@item
@ref{Preliminary Note for Cross Platform Users}, describes the basic
differences between the cross and native versions of GNAT.
@end ifset
@item
@ref{Getting Started with GNAT}, describes how to get started compiling
and running Ada programs with the GNAT Ada programming environment.
@item
@ref{The GNAT Compilation Model}, describes the compilation model used
by GNAT.
@item
@ref{Compiling Using gcc}, describes how to compile
Ada programs with @code{gcc}, the Ada compiler.
@item
@ref{Binding Using gnatbind}, describes how to
perform binding of Ada programs with @code{gnatbind}, the GNAT binding
utility.
@item
@ref{Linking Using gnatlink},
describes @code{gnatlink}, a
program that provides for linking using the GNAT run-time library to
construct a program. @code{gnatlink} can also incorporate foreign language
object units into the executable.
@item
@ref{The GNAT Make Program gnatmake}, describes @code{gnatmake}, a
utility that automatically determines the set of sources
needed by an Ada compilation unit, and executes the necessary compilations
binding and link.
@item
@ref{Renaming Files Using gnatchop}, describes
@code{gnatchop}, a utility that allows you to preprocess a file that
contains Ada source code, and split it into one or more new files, one
for each compilation unit.
@item
@ref{Configuration Pragmas}, describes the configuration pragmas handled by GNAT.
@item
@ref{Handling Arbitrary File Naming Conventions Using gnatname}, shows how to override
the default GNAT file naming conventions, either for an individual unit or globally.
@item
@ref{GNAT Project Manager}, describes how to use project files to organize large projects.
@item
@ref{Elaboration Order Handling in GNAT}, describes how GNAT helps you deal with
elaboration order issues.
@item
@ref{The Cross-Referencing Tools gnatxref and gnatfind}, discusses
@code{gnatxref} and @code{gnatfind}, two tools that provide an easy
way to navigate through sources.
@item
@ref{File Name Krunching Using gnatkr}, describes the @code{gnatkr}
file name krunching utility, used to handle shortened
file names on operating systems with a limit on the length of names.
@item
@ref{Preprocessing Using gnatprep}, describes @code{gnatprep}, a
preprocessor utility that allows a single source file to be used to
generate multiple or parameterized source files, by means of macro
substitution.
@item
@ref{The GNAT Library Browser gnatls}, describes @code{gnatls}, a
utility that displays information about compiled units, including dependences
on the corresponding sources files, and consistency of compilations.
@ifclear vms
@item
@ref{GNAT and Libraries}, describes the process of creating and using
Libraries with GNAT. It also describes how to recompile the GNAT run-time
library.

@item
@ref{Using the GNU make Utility}, describes some techniques for using
the GNAT toolset in Makefiles.

@ifclear vxworks
@item
@ref{Finding Memory Problems with gnatmem}, describes @code{gnatmem}, a
utility that monitors dynamic allocation and deallocation activity in a
program, and displays information about incorrect deallocations and sources
of possible memory leaks.
@end ifclear
@end ifclear
@item
@ref{Finding Memory Problems with GNAT Debug Pool}, describes how to
use the GNAT-specific Debug Pool in order to detect as early as possible
the use of incorrect memory references.

@item
@ref{Creating Sample Bodies Using gnatstub}, discusses @code{gnatstub},
a utility that generates empty but compilable bodies for library units.

@item
@ref{Reducing the Size of Ada Executables with gnatelim}, describes
@code{gnatelim}, a tool which detects unused subprograms and helps
the compiler to create a smaller executable for the program.

@item
@ref{Other Utility Programs}, discusses several other GNAT utilities,
including @code{gnatpsta}.

@item
@ref{Running and Debugging Ada Programs}, describes how to run and debug
Ada programs.

@item
@ref{Inline Assembler}, shows how to use the inline assembly facility in an Ada program.

@ifset vxworks
@item
@ref{VxWorks Topics}, presents information relevant to the VxWorks target for cross-compilation
configurations.

@item
@ref{LynxOS Topics}, presents information relevant to the LynxOS target for cross-compilation
configurations.
@end ifset

@item
@ref{Performance Considerations}, reviews the trade offs between using
defaults or options in program development.
@ifset vms
@item
@ref{Compatibility with DEC Ada}, details the compatibility of GNAT with
DEC Ada 83 for OpenVMS Alpha.
@end ifset
@end itemize

@node What You Should Know before Reading This Guide
@unnumberedsec What You Should Know before Reading This Guide

@cindex Ada 95 Language Reference Manual
@noindent
This user's guide assumes that you are familiar with Ada 95 language, as
described in the International Standard ANSI/ISO/IEC-8652:1995, Jan
1995.

@node Related Information
@unnumberedsec Related Information

@noindent
For further information about related tools, refer to the following
documents:

@itemize @bullet
@item
@cite{GNAT Reference Manual}, which contains all reference
material for the GNAT implementation of Ada 95.

@item
@cite{Ada 95 Language Reference Manual}, which contains all reference
material for the Ada 95 programming language.

@item
@cite{Debugging with GDB}
@ifset vms
, located in the GNU:[DOCS] directory,
@end ifset
contains all details on the use of the GNU source-level debugger.

@item
@cite{GNU Emacs Manual}
@ifset vms
, located in the GNU:[DOCS] directory if the EMACS kit is installed,
@end ifset
contains full information on the extensible editor and programming
environment Emacs.

@end itemize

@node Conventions
@unnumberedsec Conventions
@cindex Conventions
@cindex Typographical conventions

@noindent
Following are examples of the typographical and graphic conventions used
in this guide:

@itemize @bullet
@item
@code{Functions}, @code{utility program names}, @code{standard names},
and @code{classes}.

@item
@samp{Option flags}

@item
@file{File Names}, @file{button names}, and @file{field names}.

@item
@var{Variables}.

@item
@emph{Emphasis}.

@item
[optional information or parameters]

@item
Examples are described by text
@smallexample
and then shown this way.
@end smallexample
@end itemize

@noindent
Commands that are entered by the user are preceded in this manual by the
characters @w{"@code{$ }"} (dollar sign followed by space). If your system
uses this sequence as a prompt, then the commands will appear exactly as
you see them in the manual. If your system uses some other prompt, then
the command will appear with the @code{$} replaced by whatever prompt
character you are using.

@ifset vxworks
@node Preliminary Note for Cross Platform Users
@chapter Preliminary Note for Cross Platform Users

@noindent
The use of GNAT in a cross environment is very similar to its use in a
native environment. Most of the tools described in this manual have
similar functions and options in both modes. The major
difference is that the name of the cross tools includes the target for
which the cross compiler is configured. For instance, the cross @command{gnatmake}
tool is called @command{@i{target}-gnatmake} where @code{@i{target}} stands for the name of
the cross target. Thus, in an environment configured for the
target @code{powerpc-wrs-vxworks}, the @command{gnatmake} command is
@code{powerpc-wrs-vxworks-gnatmake}. This convention allows the
installation of a native and one or several cross development
environments at the same location.

The tools that are most relevant in a cross environment are:
@code{@i{target}-gcc}, @code{@i{target}-gnatmake},
@code{@i{target}-gnatbind}, @code{@i{target}-gnatlink} to build cross
applications and @code{@i{target}-gnatls} for cross library
browsing. @code{@i{target}-gdb} is also usually available for cross
debugging in text mode. The graphical debugger interface
@code{gvd} is always a native tool but it can be configured to drive
the above mentioned cross debugger, thus allowing graphical cross debugging
sessions. Some other tools such as  @code{@i{target}-gnatchop},
@code{@i{target}-gnatkr}, @code{@i{target}-gnatprep},
@code{@i{target}-gnatpsta}, @code{@i{target}-gnatxref}, @code{@i{target}-gnatfind}
and @code{@i{target}-gnatname} are also provided for completeness
even though they do not differ greatly from their native counterpart.

In the rest of this manual, the tools are sometimes designated with
their full cross name, and sometimes with their simplified native
name.

@end ifset

@node Getting Started with GNAT
@chapter Getting Started with GNAT

@ifclear vxworks
@noindent
This chapter describes some simple ways of using GNAT to build
executable Ada programs.
@end ifclear
@ifset vxworks
@noindent
This introduction is a starting point for using GNAT to develop
and execute Ada 95 programs in a cross environment.
It provides some specifics
about the GNAT toolchain targeted to the Wind River Sytems' VxWorks/Tornado platform;
for other targets please refer to the corresponding chapter later in this manual.

Basic familiarity with use of GNAT in a native environment is
presumed. For the VxWorks specific part, a knowledge of how to start
Tornado's @code{windsh} tool is also presumed.
@end ifset

@menu
* Running GNAT::
@ifclear vxworks
* Running a Simple Ada Program::
@end ifclear
@ifset vxworks
* Building a Simple Ada Program::
* Executing a Program on VxWorks::
@end ifset

* Running a Program with Multiple Units::

* Using the gnatmake Utility::
@ifset vms
* Editing with Emacs::
@end ifset
@ifclear vms
* Introduction to Glide and GVD::
@end ifclear
@end menu

@node Running GNAT
@section Running GNAT

@noindent
Three steps are needed to create an executable file from an Ada source
file:

@enumerate
@item
The source file(s) must be compiled.
@item
The file(s) must be bound using the GNAT binder.
@item
@ifclear vxworks
All appropriate object files must be linked to produce an executable.
@end ifclear
@ifset vxworks
All appropriate object files must be linked to produce a loadable module.
@end ifset
@end enumerate

@noindent
All three steps are most commonly handled by using the @code{gnatmake}
utility program that, given the name of the main program, automatically
performs the necessary compilation, binding and linking steps.

@ifclear vxworks
@node Running a Simple Ada Program
@section Running a Simple Ada Program
@end ifclear
@ifset vxworks
@node Building a Simple Ada Program
@section Building a Simple Ada Program
@end ifset

@noindent
Any text editor may be used to prepare an Ada program. If @code{Glide} is
used, the optional Ada mode may be helpful in laying out the program. The
program text is a normal text file. We will suppose in our initial
example that you have used your editor to prepare the following
standard format text file:

@smallexample
@group
@cartouche
@b{with} Ada.Text_IO; @b{use} Ada.Text_IO;
@b{procedure} Hello @b{is}
@b{begin}
   Put_Line ("Hello WORLD!");
@b{end} Hello;
@end cartouche
@end group
@end smallexample

@noindent
This file should be named @file{hello.adb}.
With the normal default file naming conventions, GNAT requires
that each file
contain a single compilation unit whose file name is the
unit name,
with periods replaced by hyphens; the
extension is @file{ads} for a
spec and @file{adb} for a body.
You can override this default file naming convention by use of the
special pragma @code{Source_File_Name} (@pxref{Using Other File Names}).
Alternatively, if you want to rename your files according to this default
convention, which is probably more convenient if you will be using GNAT
for all your compilations, then the @code{gnatchop} utility
can be used to generate correctly-named source files
(@pxref{Renaming Files Using gnatchop}).

You can compile the program using the following command (@code{$} is used
as the command prompt in the examples in this document):

@ifclear vxworks
@smallexample
$ gcc -c hello.adb
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gcc -c hello.adb
@end smallexample
@end ifset

@noindent
@code{gcc} is the command used to run the compiler. This compiler is
capable of compiling programs in several languages, including Ada 95 and
C. It assumes that you have given it an Ada program if the file extension is
either @file{.ads} or @file{.adb}, and it will then call the GNAT compiler to compile
the specified file.

@ifclear vms
The @option{-c} switch is required. It tells @command{gcc} to only do a
compilation. (For C programs, @command{gcc} can also do linking, but this
capability is not used directly for Ada programs, so the @option{-c}
switch must always be present.)
@end ifclear

This compile command generates a file
@file{hello.o}, which is the object
file corresponding to your Ada program. It also generates an "Ada Library Information" file
@file{hello.ali},
which contains additional information used to check
that an Ada program is consistent.
@ifclear vxworks
To build an executable file,
@end ifclear
@ifset vxworks
To build a downloadable module,
@end ifset
use @code{gnatbind} to bind the program
and @code{gnatlink} to link it. The
argument to both @code{gnatbind} and @code{gnatlink} is the name of the
@file{ali} file, but the default extension of @file{.ali} can
be omitted. This means that in the most common case, the argument
is simply the name of the main program:

@ifclear vxworks
@smallexample
$ gnatbind hello
$ gnatlink hello
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gnatbind hello
$ @i{target}-gnatlink hello
@end smallexample
@end ifset

@noindent
A simpler method of carrying out these steps is to use
@command{gnatmake},
a master program that invokes all the required
compilation, binding and linking tools in the correct order. In particular,
@command{gnatmake} automatically recompiles any sources that have been modified
since they were last compiled, or sources that depend
on such modified sources, so that "version skew" is avoided.
@cindex Version skew (avoided by @command{gnatmake})

@ifclear vxworks
@smallexample
$ gnatmake hello.adb
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gnatmake hello.adb
@end smallexample
@end ifset

@ifclear vxworks
@noindent
The result is an executable program called @file{hello}, which can be
run by entering:

@c The following should be removed (BMB 2001-01-23)
@c @smallexample
@c $ ^./hello^$ RUN HELLO^
@c @end smallexample

@smallexample
$ hello
@end smallexample

@noindent
assuming that the current directory is on the search path for executable programs.

@noindent
and, if all has gone well, you will see

@smallexample
Hello WORLD!
@end smallexample

@noindent
appear in response to this command.

@end ifclear

@ifset vxworks
@noindent
The result is a relocatable object called @file{hello}.

@emph{Technical note:} the result of the linking stage is a
relocatable partially-linked object containing all the relevant GNAT
run-time units, in contrast with the executable-format object file found in
native environments.


@node Executing a Program on VxWorks
@section Executing a Program on VxWorks

@noindent
Getting a program to execute involves loading it onto the target, running it, and then (if re-execution is needed) unloading it.

@menu
* Loading and Running the Program::
* Unloading the Program::
@end menu

@node Loading and Running the Program
@subsection Loading and Running the Program

@noindent
An Ada program is loaded and run in the same way as a C program.
Details may be found in the @cite{Tornado User's Guide}.

In order to load and run our simple "Hello World" example, we assume that
the target has access to the disk of the host containing this object and
that its working directory has been set to the directory containing this
object. The commands are typed in Tornado's Windshell. The @code{windsh} prompt
is the @code{->} sequence.

@smallexample
-> vf0=open("/vio/0",2,0)
new symbol "vf0" added to symbol table.
vf0 = 0x2cab48: value = 12 = 0xc
-> ioGlobalStdSet(1,vf0)
value = 1 = 0x1
-> ld < hello
value = 665408 = 0xa2740
-> hello
Hello World
value = 0 = 0x0
->
@end smallexample

@noindent
The first two commands redirect output to the shell window.
They are only needed if the target server was started without the
@code{-C} option.  The third command loads the module, which is the file
@file{hello} created previously by the @code{@i{target}-gnatmake} command.
Note that for Tornado AE, the @command{ml} command replaces @command{ld}."

The "Hello World" program comprises a procedure named @code{hello}, and this
is the name entered for the procedure in the target server's symbol table
when the module is loaded.  To execute the procedure, type the symbol name @code{hello}
into @code{windsh} as shown in the last command above.

Note that by default the entry point of an Ada program is the name of the main
Ada subprogram in a VxWorks environment. It is possible to use an alternative
name; see the description of @code{gnatbind} options for details.

@node Unloading the Program
@subsection Unloading the Program

@noindent
It is important to remember that
you must unload a program once you have run it. You
cannot load it once and run it several times. If you don't follow
this rule, your program's behavior can be unpredictable, and will most
probably crash.

This effect is due to the implementation of Ada 95's @emph{elaboration} semantics.
The unit elaboration phase comprises a @emph{static} elaboration and a
@emph{dynamic} elaboration. On a native platform they both take place
when the program is run. Thus rerunning the program will repeat the complete
elaboration phase, and the program will run correctly.

On VxWorks, the process is a bit different.
The static elaboration phase is handled by
the loader (typically when you type @code{ld < program_name} in
@code{windsh}). The dynamic phase takes place when the program is run. If the
program is run twice and has not been unloaded and then reloaded, the
second time it is run, the static elaboration phase is skipped.
Variables initialized during the static elaboration phase
may have been modified during the first execution of the program. Thus the
second execution isn't performed on a completely initialized environment.

Note that in C programs, elaboration isn't systematic. Multiple runs without reload
might work, but, even with C programs, if there is an elaboration
phase, you will have to unload your program before re-running it.
@end ifset


@node Running a Program with Multiple Units
@section Running a Program with Multiple Units

@noindent
Consider a slightly more complicated example that has three files: a
main program, and the spec and body of a package:

@smallexample
@cartouche
@group
@b{package} Greetings @b{is}
   @b{procedure} Hello;
   @b{procedure} Goodbye;
@b{end} Greetings;

@b{with} Ada.Text_IO; @b{use} Ada.Text_IO;
@b{package} @b{body} Greetings @b{is}
   @b{procedure} Hello @b{is}
   @b{begin}
      Put_Line ("Hello WORLD!");
   @b{end} Hello;

   @b{procedure} Goodbye @b{is}
   @b{begin}
      Put_Line ("Goodbye WORLD!");
   @b{end} Goodbye;
@b{end} Greetings;
@end group

@group
@b{with} Greetings;
@b{procedure} Gmain @b{is}
@b{begin}
   Greetings.Hello;
   Greetings.Goodbye;
@b{end} Gmain;
@end group
@end cartouche
@end smallexample

@noindent
Following the one-unit-per-file rule, place this program in the
following three separate files:

@table @file
@item greetings.ads
spec of package @code{Greetings}

@item greetings.adb
body of package @code{Greetings}

@item gmain.adb
body of main program
@end table

@noindent
To build an executable version of
this program, we could use four separate steps to compile, bind, and link
the program, as follows:

@ifclear vxworks
@smallexample
$ gcc -c gmain.adb
$ gcc -c greetings.adb
$ gnatbind gmain
$ gnatlink gmain
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gcc -c gmain.adb
$ @i{target}-gcc -c greetings.adb
$ @i{target}-gnatbind gmain
$ @i{target}-gnatlink gmain
@end smallexample
@end ifset

@noindent
Note that there is no required order of compilation when using GNAT.
In particular it is perfectly fine to compile the main program first.
Also, it is not necessary to compile package specs in the case where
there is an accompanying body; you only need to compile the body. If you want
to submit these files to the compiler for semantic checking and not code generation,
then use the
@option{-gnatc} switch:

@ifclear vxworks
@smallexample
   $ gcc -c greetings.ads -gnatc
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gcc -c greetings.ads -gnatc
@end smallexample
@end ifset

@noindent
Although the compilation can be done in separate steps as in the
above example, in practice it is almost always more convenient
to use the @code{gnatmake} tool. All you need to know in this case
is the name of the main program's source file. The effect of the above four
commands can be achieved with a single one:

@ifclear vxworks
@smallexample
$ gnatmake gmain.adb
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gnatmake gmain.adb
@end smallexample
@end ifset

@noindent
In the next section we discuss the advantages of using @code{gnatmake} in
more detail.

@node Using the gnatmake Utility
@section Using the @command{gnatmake} Utility

@noindent
If you work on a program by compiling single components at a time using
@code{gcc}, you typically keep track of the units you modify. In order to
build a consistent system, you compile not only these units, but also any
units that depend on the units you have modified.
For example, in the preceding case,
if you edit @file{gmain.adb}, you only need to recompile that file. But if
you edit @file{greetings.ads}, you must recompile both
@file{greetings.adb} and @file{gmain.adb}, because both files contain
units that depend on @file{greetings.ads}.

@code{gnatbind} will warn you if you forget one of these compilation
steps, so that it is impossible to generate an inconsistent program as a
result of forgetting to do a compilation. Nevertheless it is tedious and
error-prone to keep track of dependencies among units.
One approach to handle the dependency-bookkeeping is to use a
makefile. However, makefiles present maintenance problems of their own:
if the dependencies change as you change the program, you must make
sure that the makefile is kept up-to-date manually, which is also an
error-prone process.

The @code{gnatmake} utility takes care of these details automatically.
Invoke it using either one of the following forms:

@ifclear vxworks
@smallexample
$ gnatmake gmain.adb
$ gnatmake ^gmain^GMAIN^
@end smallexample
@end ifclear

@ifset vxworks
@smallexample
$ @i{target}-gnatmake gmain.adb
$ @i{target}-gnatmake gmain
@end smallexample
@end ifset

@noindent
The argument is the name of the file containing the main program;
you may omit the extension. @code{gnatmake}
examines the environment, automatically recompiles any files that need
recompiling, and binds and links the resulting set of object files,
generating the executable file, @file{^gmain^GMAIN.EXE^}.
In a large program, it
can be extremely helpful to use @code{gnatmake}, because working out by hand
what needs to be recompiled can be difficult.

Note that @code{gnatmake}
takes into account all the Ada 95 rules that
establish dependencies among units. These include dependencies that result
from inlining subprogram bodies, and from
generic instantiation. Unlike some other
Ada make tools, @code{gnatmake} does not rely on the dependencies that were
found by the compiler on a previous compilation, which may possibly
be wrong when sources change. @code{gnatmake} determines the exact set of
dependencies from scratch each time it is run.

@ifset vms
@node Editing with Emacs
@section Editing with Emacs
@cindex Emacs

@noindent
Emacs is an extensible self-documenting text editor that is available in a
separate VMSINSTAL kit.

Invoke Emacs by typing "Emacs" at the command prompt. To get started,
click on the Emacs Help menu and run the Emacs Tutorial.
In a character cell terminal, Emacs help is invoked with "Ctrl-h" (also written
as "C-h"), and the tutorial by "C-h t".

Documentation on Emacs and other tools is available in Emacs under the
pull-down menu button: Help - Info. After selecting Info, use the middle
mouse button to select a topic (e.g. Emacs).

In a character cell terminal, do "C-h i" to invoke info, and then "m"
(stands for menu) followed by the menu item desired, as in "m Emacs", to get
to the Emacs manual.
Help on Emacs is also available by typing "HELP EMACS" at the DCL command
prompt.

The tutorial is highly recommended in order to learn the intricacies of Emacs,
which is sufficiently extensible to provide for a complete programming
environment and shell for the sophisticated user.
@end ifset

@ifclear vms
@node Introduction to Glide and GVD
@section Introduction to Glide and GVD
@cindex Glide
@cindex GVD
@noindent
Although it is possible to develop programs using only the command line interface (@command{gnatmake}, etc.) a graphical Interactive Development Environment can make it easier for you to compose, navigate, and debug programs.  This section describes the main features of Glide, the GNAT graphical IDE, and also shows how to use the basic commands in GVD, the GNU Visual Debugger.  Additional information may be found in the on-line help for these tools.

@menu
* Building a New Program with Glide::
* Simple Debugging with GVD::
* Other Glide Features::
@end menu

@node Building a New Program with Glide
@subsection Building a New Program with Glide
@noindent
The simplest way to invoke Glide is to enter @command{glide} at the command prompt.  It will generally be useful to issue this as a background command, thus allowing you to continue using your command window for other purposes while Glide is running:

@smallexample
$ glide&
@end smallexample

@noindent
Glide will start up with an initial screen displaying the top-level menu items as well as some other information.  The menu selections are as follows
@itemize @bullet
@item @code{Buffers}
@item @code{Files}
@item @code{Tools}
@item @code{Edit}
@item @code{Search}
@item @code{Mule}
@item @code{Glide}
@item @code{Help}
@end itemize

@noindent
For this introductory example, you will need to create a new Ada source file.  First, select the @code{Files} menu.  This will pop open a menu with around a dozen or so items.  To create a file, select the @code{Open file...} choice.  Depending on the platform, you may see a pop-up window where you can browse to an appropriate directory and then enter the file name, or else simply see a line at the bottom of the Glide window where you can likewise enter the file name.  Note that in Glide, when you attempt to open a non-existent file, the effect is to create a file with that name.  For this example enter @file{hello.adb} as the name of the file.

A new buffer will now appear, occupying the entire Glide window, with the file name at the top.  The menu selections are slightly different from the ones you saw on the opening screen; there is an @code{Entities} item, and in place of @code{Glide} there is now an @code{Ada} item.  Glide uses the file extension to identify the source language, so @file{adb} indicates an Ada source file.

You will enter some of the source program lines explicitly, and use the syntax-oriented template mechanism to enter other lines.  First, type the following text:
@smallexample
with Ada.Text_IO; use Ada.Text_IO;
procedure Hello is
begin
@end smallexample

@noindent
Observe that Glide uses different colors to distinguish reserved words from identifiers.  Also, after the @code{procedure Hello is} line, the cursor is automatically indented in anticipation of declarations.  When you enter @code{begin}, Glide recognizes that there are no declarations and thus places @code{begin} flush left.  But after the @code{begin} line the cursor is again indented, where the statement(s) will be placed.

The main part of the program will be a @code{for} loop.  Instead of entering the text explicitly, however, use a statement template.  Select the @code{Ada} item on the top menu bar, move the mouse to the @code{Statements} item, and you will see a large selection of alternatives.  Choose @code{for loop}.  You will be prompted (at the bottom of the buffer) for a loop name; simply press the @key{Enter} key since a loop name is not needed.  You should see the beginning of a @code{for} loop appear in the source program window.  You will now be prompted for the name of the loop variable; enter a line with the identifier @code{ind} (lower case).  Note that, by default, Glide capitalizes the name (you can override such behavior if you wish, although this is outside the scope of this introduction).  Next, Glide prompts you for the loop range; enter a line containing @code{1..5} and you will see this also appear in the source program, together with the remaining elements of the @code{for} loop syntax.

Next enter the statement (with an intentional error, a missing semicolon) that will form the body of the loop:
@smallexample
Put_Line("Hello, World" & Integer'Image(I))
@end smallexample

@noindent
Finally, type @code{end Hello;} as the last line in the program.  Now save the file: choose the @code{File} menu item, and then the @code{Save buffer} selection.  You will see a message at the bottom of the buffer confirming that the file has been saved.

You are now ready to attempt to build the program.  Select the @code{Ada} item from the top menu bar.  Although we could choose simply to compile the file, we will instead attempt to do a build (which invokes @command{gnatmake}) since, if the compile is successful, we want to build an executable.  Thus select @code{Ada build}.  This will fail because of the compilation error, and you will notice that the Glide window has been split: the top window contains the source file, and the bottom window contains the output from the GNAT tools.  Glide allows you to navigate from a compilation error to the source file position corresponding to the error: click the middle mouse button (or simultaneously press the left and right buttons, on a two-button mouse) on the diagnostic line in the tool window.  The focus will shift to the source window, and the cursor will be positioned on the character at which the error was detected.

Correct the error: type in a semicolon to terminate the statement.  Although you can again save the file explicitly, you can also simply invoke @code{Ada} @result{} @code{Build} and you will be prompted to save the file.  This time the build will succeed; the tool output window shows you the options that are supplied by default.  The GNAT tools' output (e.g., object and ALI files, executable) will go in the directory from which Glide was launched.

To execute the program, choose @code{Ada} and then @code{Run}.  You should see the program's output displayed in the bottom window:

@smallexample
Hello, world 1
Hello, world 2
Hello, world 3
Hello, world 4
Hello, world 5
@end smallexample

@node Simple Debugging with GVD
@subsection Simple Debugging with GVD

@noindent
This section describes how to set breakpoints, examine/modify variables, and step through execution.

In order to enable debugging, you need to pass the @option{-g} switch to both the compiler and to @command{gnatlink}.  If you are using the command line, passing @option{-g} to @command{gnatmake} will have this effect.  You can then launch GVD, e.g. on the @code{hello} program, by issuing the command:

@smallexample
$ gvd hello
@end smallexample

@noindent
If you are using Glide, then @option{-g} is passed to the relevant tools by default when you do a build.  Start the debugger by selecting the @code{Ada} menu item, and then @code{Debug}.

GVD comes up in a multi-part window.  One pane shows the names of files comprising your executable; another pane shows the source code of the current unit (initially your main subprogram), another pane shows the debugger output and user interactions, and the fourth pane (the data canvas at the top of the window) displays data objects that you have selected.

To the left of the source file pane, you will notice green dots adjacent to some lines.  These are lines for which object code exists and where breakpoints can thus be set.  You set/reset a breakpoint by clicking the green dot.  When a breakpoint is set, the dot is replaced by an @code{X} in a red circle.  Clicking the circle toggles the breakpoint off, and the red circle is replaced by the green dot.

For this example, set a breakpoint at the statement where @code{Put_Line} is invoked.

Start program execution by selecting the @code{Run} button on the top menu bar.  (The @code{Start} button will also start your program, but it will cause program execution to break at the entry to your main subprogram.)  Evidence of reaching the breakpoint will appear: the source file line will be highlighted, and the debugger interactions pane will display a relevant message.

You can examine the values of variables in several ways.  Move the mouse over an occurrence of @code{Ind} in the @code{for} loop, and you will see the value (now @code{1}) displayed.  Alternatively, right-click on @code{Ind} and select @code{Display Ind}; a box showing the variable's name and value will appear in the data canvas.

Although a loop index is a constant with respect to Ada semantics, you can change its value in the debugger.  Right-click in the box for @code{Ind}, and select the @code{Set Value of Ind} item.  Enter @code{2} as the new value, and press @command{OK}.  The box for @code{Ind} shows the update.

Press the @code{Step} button on the top menu bar; this will step through one line of program text (the invocation of @code{Put_Line}), and you can observe the effect of having modified @code{Ind} since the value displayed is @code{2}.

Remove the breakpoint, and resume execution by selecting the @code{Cont} button.  You will see the remaining output lines displayed in the debugger interaction window, along with a message confirming normal program termination.


@node Other Glide Features
@subsection Other Glide Features

@noindent
You may have observed that some of the menu selections contain abbreviations; e.g., @code{(C-x C-f)} for @code{Open file...} in the @code{Files} menu.  These are @emph{shortcut keys} that you can use instead of selecting menu items.  The @key{C} stands for @key{Ctrl}; thus @code{(C-x C-f)} means @key{Ctrl-x} followed by @key{Ctrl-f}, and this sequence can be used instead of selecting @code{Files} and then @code{Open file...}.

To abort a Glide command, type @key{Ctrl-g}.

If you want Glide to start with an existing source file, you can either launch Glide as above and then open the file via @code{Files} @result{} @code{Open file...}, or else simply pass the name of the source file on the command line:

@smallexample
$ glide hello.adb&
@end smallexample

@noindent
While you are using Glide, a number of @emph{buffers} exist.  You create some explicitly; e.g., when you open/create a file.  Others arise as an effect of the commands that you issue; e.g., the buffer containing the output of the tools invoked during a build.  If a buffer is hidden, you can bring it into a visible window by first opening the @code{Buffers} menu and then selecting the desired entry.

If a buffer occupies only part of the Glide screen and you want to expand it to fill the entire screen, then click in the buffer and then select @code{Files} @result{} @code{One Window}.

If a window is occupied by one buffer and you want to split the window to bring up a second buffer, perform the following steps:
@itemize @bullet
@item Select @code{Files} @result{} @code{Split Window}; this will produce two windows each of which holds the original buffer (these are not copies, but rather different views of the same buffer contents)
@item With the focus in one of the windows, select the desired buffer from the @code{Buffers} menu
@end itemize

@noindent
To exit from Glide, choose @code{Files} @result{} @code{Exit}.
@end ifclear

@node The GNAT Compilation Model
@chapter The GNAT Compilation Model
@cindex GNAT compilation model
@cindex Compilation model

@menu
* Source Representation::
* Foreign Language Representation::
* File Naming Rules::
* Using Other File Names::
* Alternative File Naming Schemes::
* Generating Object Files::
* Source Dependencies::
* The Ada Library Information Files::
* Binding an Ada Program::
* Mixed Language Programming::
* Building Mixed Ada & C++ Programs::
* Comparison between GNAT and C/C++ Compilation Models::
* Comparison between GNAT and Conventional Ada Library Models::
@end menu

@noindent
This chapter describes the compilation model used by GNAT. Although
similar to that used by other languages, such as C and C++, this model
is substantially different from the traditional Ada compilation models,
which are based on a library. The model is initially described without
reference to the library-based model. If you have not previously used an
Ada compiler, you need only read the first part of this chapter. The
last section describes and discusses the differences between the GNAT
model and the traditional Ada compiler models. If you have used other
Ada compilers, this section will help you to understand those
differences, and the advantages of the GNAT model.

@node Source Representation
@section Source Representation
@cindex Latin-1

@noindent
Ada source programs are represented in standard text files, using
Latin-1 coding. Latin-1 is an 8-bit code that includes the familiar
7-bit ASCII set, plus additional characters used for
representing foreign languages (@pxref{Foreign Language Representation}
for support of non-USA character sets). The format effector characters
are represented using their standard ASCII encodings, as follows:

@table @code
@item VT
@findex VT
Vertical tab, @code{16#0B#}

@item HT
@findex HT
Horizontal tab, @code{16#09#}

@item CR
@findex CR
Carriage return, @code{16#0D#}

@item LF
@findex LF
Line feed, @code{16#0A#}

@item FF
@findex FF
Form feed, @code{16#0C#}
@end table

@noindent
Source files are in standard text file format. In addition, GNAT will
recognize a wide variety of stream formats, in which the end of physical
physical lines is marked by any of the following sequences:
@code{LF}, @code{CR}, @code{CR-LF}, or @code{LF-CR}. This is useful
in accommodating files that are imported from other operating systems.

@cindex End of source file
@cindex Source file, end
@findex SUB
The end of a source file is normally represented by the physical end of
file. However, the control character @code{16#1A#} (@code{SUB}) is also
recognized as signalling the end of the source file. Again, this is
provided for compatibility with other operating systems where this
code is used to represent the end of file.

Each file contains a single Ada compilation unit, including any pragmas
associated with the unit. For example, this means you must place a
package declaration (a package @dfn{spec}) and the corresponding body in
separate files. An Ada @dfn{compilation} (which is a sequence of
compilation units) is represented using a sequence of files. Similarly,
you will place each subunit or child unit in a separate file.

@node Foreign Language Representation
@section Foreign Language Representation

@noindent
GNAT supports the standard character sets defined in Ada 95 as well as
several other non-standard character sets for use in localized versions
of the compiler (@pxref{Character Set Control}).
@menu
* Latin-1::
* Other 8-Bit Codes::
* Wide Character Encodings::
@end menu

@node Latin-1
@subsection Latin-1
@cindex Latin-1

@noindent
The basic character set is Latin-1. This character set is defined by ISO
standard 8859, part 1. The lower half (character codes @code{16#00#}
... @code{16#7F#)} is identical to standard ASCII coding, but the upper half is
used to represent additional characters. These include extended letters
used by European languages, such as French accents, the vowels with umlauts
used in German, and the extra letter A-ring used in Swedish.

@findex Ada.Characters.Latin_1
For a complete list of Latin-1 codes and their encodings, see the source
file of library unit @code{Ada.Characters.Latin_1} in file
@file{a-chlat1.ads}.
You may use any of these extended characters freely in character or
string literals. In addition, the extended characters that represent
letters can be used in identifiers.

@node Other 8-Bit Codes
@subsection Other 8-Bit Codes

@noindent
GNAT also supports several other 8-bit coding schemes:

@table @asis
@cindex Latin-2
@item Latin-2
Latin-2 letters allowed in identifiers, with uppercase and lowercase
equivalence.

@item Latin-3
@cindex Latin-3
Latin-3 letters allowed in identifiers, with uppercase and lowercase
equivalence.

@item Latin-4
@cindex Latin-4
Latin-4 letters allowed in identifiers, with uppercase and lowercase
equivalence.

@item Latin-5
@cindex Latin-5
@cindex Cyrillic
Latin-4 letters (Cyrillic) allowed in identifiers, with uppercase and lowercase
equivalence.

@item IBM PC (code page 437)
@cindex code page 437
This code page is the normal default for PCs in the U.S. It corresponds
to the original IBM PC character set. This set has some, but not all, of
the extended Latin-1 letters, but these letters do not have the same
encoding as Latin-1. In this mode, these letters are allowed in
identifiers with uppercase and lowercase equivalence.

@item IBM PC (code page 850)
@cindex code page 850
This code page is a modification of 437 extended to include all the
Latin-1 letters, but still not with the usual Latin-1 encoding. In this
mode, all these letters are allowed in identifiers with uppercase and
lowercase equivalence.

@item Full Upper 8-bit
Any character in the range 80-FF allowed in identifiers, and all are
considered distinct. In other words, there are no uppercase and lowercase
equivalences in this range. This is useful in conjunction with
certain encoding schemes used for some foreign character sets (e.g.
the typical method of representing Chinese characters on the PC).

@item No Upper-Half
No upper-half characters in the range 80-FF are allowed in identifiers.
This gives Ada 83 compatibility for identifier names.
@end table

@noindent
For precise data on the encodings permitted, and the uppercase and lowercase
equivalences that are recognized, see the file @file{csets.adb} in
the GNAT compiler sources. You will need to obtain a full source release
of GNAT to obtain this file.

@node Wide Character Encodings
@subsection Wide Character Encodings

@noindent
GNAT allows wide character codes to appear in character and string
literals, and also optionally in identifiers, by means of the following
possible encoding schemes:

@table @asis

@item Hex Coding
In this encoding, a wide character is represented by the following five
character sequence:

@smallexample
ESC a b c d
@end smallexample

@noindent
Where @code{a}, @code{b}, @code{c}, @code{d} are the four hexadecimal
characters (using uppercase letters) of the wide character code. For
example, ESC A345 is used to represent the wide character with code
@code{16#A345#}.
This scheme is compatible with use of the full Wide_Character set.

@item Upper-Half Coding
@cindex Upper-Half Coding
The wide character with encoding @code{16#abcd#} where the upper bit is on (in
other words, "a" is in the range 8-F) is represented as two bytes,
@code{16#ab#} and @code{16#cd#}. The second byte cannot be a format control
character, but is not required to be in the upper half. This method can
be also used for shift-JIS or EUC, where the internal coding matches the
external coding.

@item Shift JIS Coding
@cindex Shift JIS Coding
A wide character is represented by a two-character sequence,
@code{16#ab#} and
@code{16#cd#}, with the restrictions described for upper-half encoding as
described above. The internal character code is the corresponding JIS
character according to the standard algorithm for Shift-JIS
conversion. Only characters defined in the JIS code set table can be
used with this encoding method.

@item EUC Coding
@cindex EUC Coding
A wide character is represented by a two-character sequence
@code{16#ab#} and
@code{16#cd#}, with both characters being in the upper half. The internal
character code is the corresponding JIS character according to the EUC
encoding algorithm. Only characters defined in the JIS code set table
can be used with this encoding method.

@item UTF-8 Coding
A wide character is represented using
UCS Transformation Format 8 (UTF-8) as defined in Annex R of ISO
10646-1/Am.2. Depending on the character value, the representation
is a one, two, or three byte sequence:
@smallexample
@iftex
@leftskip=.7cm
@end iftex
16#0000#-16#007f#: 2#0xxxxxxx#
16#0080#-16#07ff#: 2#110xxxxx# 2#10xxxxxx#
16#0800#-16#ffff#: 2#1110xxxx# 2#10xxxxxx# 2#10xxxxxx#

@end smallexample

@noindent
where the xxx bits correspond to the left-padded bits of the
16-bit character value. Note that all lower half ASCII characters
are represented as ASCII bytes and all upper half characters and
other wide characters are represented as sequences of upper-half
(The full UTF-8 scheme allows for encoding 31-bit characters as
6-byte sequences, but in this implementation, all UTF-8 sequences
of four or more bytes length will be treated as illegal).
@item Brackets Coding
In this encoding, a wide character is represented by the following eight
character sequence:

@smallexample
[ " a b c d " ]
@end smallexample

@noindent
Where @code{a}, @code{b}, @code{c}, @code{d} are the four hexadecimal
characters (using uppercase letters) of the wide character code. For
example, ["A345"] is used to represent the wide character with code
@code{16#A345#}. It is also possible (though not required) to use the
Brackets coding for upper half characters. For example, the code
@code{16#A3#} can be represented as @code{["A3"]}.

This scheme is compatible with use of the full Wide_Character set,
and is also the method used for wide character encoding in the standard
ACVC (Ada Compiler Validation Capability) test suite distributions.

@end table

@noindent
Note: Some of these coding schemes do not permit the full use of the
Ada 95 character set. For example, neither Shift JIS, nor EUC allow the
use of the upper half of the Latin-1 set.

@node File Naming Rules
@section File Naming Rules

@noindent
The default file name is determined by the name of the unit that the
file contains. The name is formed by taking the full expanded name of
the unit and replacing the separating dots with hyphens and using
^lowercase^uppercase^ for all letters.

An exception arises if the file name generated by the above rules starts
with one of the characters
@ifset vms
A,G,I, or S,
@end ifset
@ifclear vms
a,g,i, or s,
@end ifclear
and the second character is a
minus. In this case, the character ^tilde^dollar sign^ is used in place
of the minus. The reason for this special rule is to avoid clashes with
the standard names for child units of the packages System, Ada,
Interfaces, and GNAT, which use the prefixes
@ifset vms
S- A- I- and G-
@end ifset
@ifclear vms
s- a- i- and g-
@end ifclear
respectively.

The file extension is @file{.ads} for a spec and
@file{.adb} for a body. The following list shows some
examples of these rules.

@table @file
@item main.ads
Main (spec)
@item main.adb
Main (body)
@item arith_functions.ads
Arith_Functions (package spec)
@item arith_functions.adb
Arith_Functions (package body)
@item func-spec.ads
Func.Spec (child package spec)
@item func-spec.adb
Func.Spec (child package body)
@item main-sub.adb
Sub (subunit of Main)
@item ^a~bad.adb^A$BAD.ADB^
A.Bad (child package body)
@end table

@noindent
Following these rules can result in excessively long
file names if corresponding
unit names are long (for example, if child units or subunits are
heavily nested). An option is available to shorten such long file names
(called file name "krunching"). This may be particularly useful when
programs being developed with GNAT are to be used on operating systems
with limited file name lengths. @xref{Using gnatkr}.

Of course, no file shortening algorithm can guarantee uniqueness over
all possible unit names; if file name krunching is used, it is your
responsibility to ensure no name clashes occur. Alternatively you
can specify the exact file names that you want used, as described
in the next section. Finally, if your Ada programs are migrating from a
compiler with a different naming convention, you can use the gnatchop
utility to produce source files that follow the GNAT naming conventions.
(For details @pxref{Renaming Files Using gnatchop}.)

@node Using Other File Names
@section Using Other File Names
@cindex File names

@noindent
In the previous section, we have described the default rules used by
GNAT to determine the file name in which a given unit resides. It is
often convenient to follow these default rules, and if you follow them,
the compiler knows without being explicitly told where to find all
the files it needs.

However, in some cases, particularly when a program is imported from
another Ada compiler environment, it may be more convenient for the
programmer to specify which file names contain which units. GNAT allows
arbitrary file names to be used by means of the Source_File_Name pragma.
The form of this pragma is as shown in the following examples:
@cindex Source_File_Name pragma

@smallexample
@group
@cartouche
@b{pragma} Source_File_Name (My_Utilities.Stacks,
  Spec_File_Name => "myutilst_a.ada");
@b{pragma} Source_File_name (My_Utilities.Stacks,
  Body_File_Name => "myutilst.ada");
@end cartouche
@end group
@end smallexample

@noindent
As shown in this example, the first argument for the pragma is the unit
name (in this example a child unit). The second argument has the form
of a named association. The identifier
indicates whether the file name is for a spec or a body;
the file name itself is given by a string literal.

The source file name pragma is a configuration pragma, which means that
normally it will be placed in the @file{gnat.adc}
file used to hold configuration
pragmas that apply to a complete compilation environment.
For more details on how the @file{gnat.adc} file is created and used
@pxref{Handling of Configuration Pragmas}
@cindex @file{gnat.adc}

@ifclear vms
GNAT allows completely arbitrary file names to be specified using the
source file name pragma. However, if the file name specified has an
extension other than @file{.ads} or @file{.adb} it is necessary to use a special
syntax when compiling the file. The name in this case must be preceded
by the special sequence @code{-x} followed by a space and the name of the
language, here @code{ada}, as in:

@smallexample
$ gcc -c -x ada peculiar_file_name.sim
@end smallexample
@end ifclear

@noindent
@code{gnatmake} handles non-standard file names in the usual manner (the
non-standard file name for the main program is simply used as the
argument to gnatmake). Note that if the extension is also non-standard,
then it must be included in the gnatmake command, it may not be omitted.

@node Alternative File Naming Schemes
@section Alternative File Naming Schemes
@cindex File naming schemes, alternative
@cindex File names

In the previous section, we described the use of the @code{Source_File_Name}
pragma to allow arbitrary names to be assigned to individual source files.
However, this approach requires one pragma for each file, and especially in
large systems can result in very long @file{gnat.adc} files, and also create
a maintenance problem.

GNAT also provides a facility for specifying systematic file naming schemes
other than the standard default naming scheme previously described. An
alternative scheme for naming is specified by the use of
@code{Source_File_Name} pragmas having the following format:
@cindex Source_File_Name pragma

@smallexample
pragma Source_File_Name (
   Spec_File_Name  => FILE_NAME_PATTERN
 [,Casing          => CASING_SPEC]
 [,Dot_Replacement => STRING_LITERAL]);

pragma Source_File_Name (
   Body_File_Name  => FILE_NAME_PATTERN
 [,Casing          => CASING_SPEC]
 [,Dot_Replacement => STRING_LITERAL]);

pragma Source_File_Name (
   Subunit_File_Name  => FILE_NAME_PATTERN
 [,Casing             => CASING_SPEC]
 [,Dot_Replacement    => STRING_LITERAL]);

FILE_NAME_PATTERN ::= STRING_LITERAL
CASING_SPEC ::= Lowercase | Uppercase | Mixedcase

@end smallexample

@noindent
The @code{FILE_NAME_PATTERN} string shows how the file name is constructed.
It contains a single asterisk character, and the unit name is substituted
systematically for this asterisk. The optional parameter
@code{Casing} indicates
whether the unit name is to be all upper-case letters, all lower-case letters,
or mixed-case. If no
@code{Casing} parameter is used, then the default is all
^lower-case^upper-case^.

The optional @code{Dot_Replacement} string is used to replace any periods
that occur in subunit or child unit names. If no @code{Dot_Replacement}
argument is used then separating dots appear unchanged in the resulting
file name.
Although the above syntax indicates that the
@code{Casing} argument must appear
before the @code{Dot_Replacement} argument, but it
is also permissible to write these arguments in the opposite order.

As indicated, it is possible to specify different naming schemes for
bodies, specs, and subunits. Quite often the rule for subunits is the
same as the rule for bodies, in which case, there is no need to give
a separate @code{Subunit_File_Name} rule, and in this case the
@code{Body_File_name} rule is used for subunits as well.

The separate rule for subunits can also be used to implement the rather
unusual case of a compilation environment (e.g. a single directory) which
contains a subunit and a child unit with the same unit name. Although
both units cannot appear in the same partition, the Ada Reference Manual
allows (but does not require) the possibility of the two units coexisting
in the same environment.

The file name translation works in the following steps:

@itemize @bullet

@item
If there is a specific @code{Source_File_Name} pragma for the given unit,
then this is always used, and any general pattern rules are ignored.

@item
If there is a pattern type @code{Source_File_Name} pragma that applies to
the unit, then the resulting file name will be used if the file exists. If
more than one pattern matches, the latest one will be tried first, and the
first attempt resulting in a reference to a file that exists will be used.

@item
If no pattern type @code{Source_File_Name} pragma that applies to the unit
for which the corresponding file exists, then the standard GNAT default
naming rules are used.

@end itemize

@noindent
As an example of the use of this mechanism, consider a commonly used scheme
in which file names are all lower case, with separating periods copied
unchanged to the resulting file name, and specs end with ".1.ada", and
bodies end with ".2.ada". GNAT will follow this scheme if the following
two pragmas appear:

@smallexample
pragma Source_File_Name
  (Spec_File_Name => "*.1.ada");
pragma Source_File_Name
  (Body_File_Name => "*.2.ada");
@end smallexample

@noindent
The default GNAT scheme is actually implemented by providing the following
default pragmas internally:

@smallexample
pragma Source_File_Name
  (Spec_File_Name => "*.ads", Dot_Replacement => "-");
pragma Source_File_Name
  (Body_File_Name => "*.adb", Dot_Replacement => "-");
@end smallexample

@noindent
Our final example implements a scheme typically used with one of the
Ada 83 compilers, where the separator character for subunits was "__"
(two underscores), specs were identified by adding @file{_.ADA}, bodies
by adding @file{.ADA}, and subunits by
adding @file{.SEP}. All file names were
upper case. Child units were not present of course since this was an
Ada 83 compiler, but it seems reasonable to extend this scheme to use
the same double underscore separator for child units.

@smallexample
pragma Source_File_Name
  (Spec_File_Name => "*_.ADA",
   Dot_Replacement => "__",
   Casing = Uppercase);
pragma Source_File_Name
  (Body_File_Name => "*.ADA",
   Dot_Replacement => "__",
   Casing = Uppercase);
pragma Source_File_Name
  (Subunit_File_Name => "*.SEP",
   Dot_Replacement => "__",
   Casing = Uppercase);
@end smallexample

@node Generating Object Files
@section Generating Object Files

@noindent
An Ada program consists of a set of source files, and the first step in
compiling the program is to generate the corresponding object files.
These are generated by compiling a subset of these source files.
The files you need to compile are the following:

@itemize @bullet
@item
If a package spec has no body, compile the package spec to produce the
object file for the package.

@item
If a package has both a spec and a body, compile the body to produce the
object file for the package. The source file for the package spec need
not be compiled in this case because there is only one object file, which
contains the code for both the spec and body of the package.

@item
For a subprogram, compile the subprogram body to produce the object file
for the subprogram. The spec, if one is present, is as usual in a
separate file, and need not be compiled.

@item
@cindex Subunits
In the case of subunits, only compile the parent unit. A single object
file is generated for the entire subunit tree, which includes all the
subunits.

@item
Compile child units independently of their parent units
(though, of course, the spec of all the ancestor unit must be present in order
to compile a child unit).

@item
@cindex Generics
Compile generic units in the same manner as any other units. The object
files in this case are small dummy files that contain at most the
flag used for elaboration checking. This is because GNAT always handles generic
instantiation by means of macro expansion. However, it is still necessary to
compile generic units, for dependency checking and elaboration purposes.
@end itemize

@noindent
The preceding rules describe the set of files that must be compiled to
generate the object files for a program. Each object file has the same
name as the corresponding source file, except that the extension is
@file{.o} as usual.

You may wish to compile other files for the purpose of checking their
syntactic and semantic correctness. For example, in the case where a
package has a separate spec and body, you would not normally compile the
spec. However, it is convenient in practice to compile the spec to make
sure it is error-free before compiling clients of this spec, because such
compilations will fail if there is an error in the spec.

GNAT provides an option for compiling such files purely for the
purposes of checking correctness; such compilations are not required as
part of the process of building a program. To compile a file in this
checking mode, use the @option{-gnatc} switch.

@node Source Dependencies
@section Source Dependencies

@noindent
A given object file clearly depends on the source file which is compiled
to produce it. Here we are using @dfn{depends} in the sense of a typical
@code{make} utility; in other words, an object file depends on a source
file if changes to the source file require the object file to be
recompiled.
In addition to this basic dependency, a given object may depend on
additional source files as follows:

@itemize @bullet
@item
If a file being compiled @code{with}'s a unit @var{X}, the object file
depends on the file containing the spec of unit @var{X}. This includes
files that are @code{with}'ed implicitly either because they are parents
of @code{with}'ed child units or they are run-time units required by the
language constructs used in a particular unit.

@item
If a file being compiled instantiates a library level generic unit, the
object file depends on both the spec and body files for this generic
unit.

@item
If a file being compiled instantiates a generic unit defined within a
package, the object file depends on the body file for the package as
well as the spec file.

@item
@findex Inline
@cindex @option{-gnatn} switch
If a file being compiled contains a call to a subprogram for which
pragma @code{Inline} applies and inlining is activated with the
@option{-gnatn} switch, the object file depends on the file containing the
body of this subprogram as well as on the file containing the spec. Note
that for inlining to actually occur as a result of the use of this switch,
it is necessary to compile in optimizing mode.

@cindex @option{-gnatN} switch
The use of @option{-gnatN} activates a more extensive inlining optimization
that is performed by the front end of the compiler. This inlining does
not require that the code generation be optimized. Like @option{-gnatn},
the use of this switch generates additional dependencies.

@item
If an object file O  depends on the proper body of a subunit through inlining
or instantiation, it depends on the parent unit of the subunit. This means that
any modification of the parent unit or one of its subunits affects the
compilation of O.

@item
The object file for a parent unit depends on all its subunit body files.

@item
The previous two rules meant that for purposes of computing dependencies and
recompilation, a body and all its subunits are treated as an indivisible whole.

@noindent
These rules are applied transitively: if unit @code{A} @code{with}'s
unit @code{B}, whose elaboration calls an inlined procedure in package
@code{C}, the object file for unit @code{A} will depend on the body of
@code{C}, in file @file{c.adb}.

The set of dependent files described by these rules includes all the
files on which the unit is semantically dependent, as described in the
Ada 95 Language Reference Manual. However, it is a superset of what the
ARM describes, because it includes generic, inline, and subunit dependencies.

An object file must be recreated by recompiling the corresponding source
file if any of the source files on which it depends are modified. For
example, if the @code{make} utility is used to control compilation,
the rule for an Ada object file must mention all the source files on
which the object file depends, according to the above definition.
The determination of the necessary
recompilations is done automatically when one uses @code{gnatmake}.
@end itemize

@node The Ada Library Information Files
@section The Ada Library Information Files
@cindex Ada Library Information files
@cindex @file{ali} files

@noindent
Each compilation actually generates two output files. The first of these
is the normal object file that has a @file{.o} extension. The second is a
text file containing full dependency information. It has the same
name as the source file, but an @file{.ali} extension.
This file is known as the Ada Library Information (@file{ali}) file.
The following information is contained in the @file{ali} file.

@itemize @bullet
@item
Version information (indicates which version of GNAT was used to compile
the unit(s) in question)

@item
Main program information (including priority and time slice settings,
as well as the wide character encoding used during compilation).

@item
List of arguments used in the @code{gcc} command for the compilation

@item
Attributes of the unit, including configuration pragmas used, an indication
of whether the compilation was successful, exception model used etc.

@item
A list of relevant restrictions applying to the unit (used for consistency)
checking.

@item
Categorization information (e.g. use of pragma @code{Pure}).

@item
Information on all @code{with}'ed units, including presence of
@code{Elaborate} or @code{Elaborate_All} pragmas.

@item
Information from any @code{Linker_Options} pragmas used in the unit

@item
Information on the use of @code{Body_Version} or @code{Version}
attributes in the unit.

@item
Dependency information. This is a list of files, together with
time stamp and checksum information. These are files on which
the unit depends in the sense that recompilation is required
if any of these units are modified.

@item
Cross-reference data. Contains information on all entities referenced
in the unit. Used by tools like @code{gnatxref} and @code{gnatfind} to
provide cross-reference information.

@end itemize

@noindent
For a full detailed description of the format of the @file{ali} file,
see the source of the body of unit @code{Lib.Writ}, contained in file
@file{lib-writ.adb} in the GNAT compiler sources.

@node Binding an Ada Program
@section Binding an Ada Program

@noindent
When using languages such as C and C++, once the source files have been
compiled the only remaining step in building an executable program
is linking the object modules together. This means that it is possible to
link an inconsistent version of a program, in which two units have
included different versions of the same header.

The rules of Ada do not permit such an inconsistent program to be built.
For example, if two clients have different versions of the same package,
it is illegal to build a program containing these two clients.
These rules are enforced by the GNAT binder, which also determines an
elaboration order consistent with the Ada rules.

The GNAT binder is run after all the object files for a program have
been created. It is given the name of the main program unit, and from
this it determines the set of units required by the program, by reading the
corresponding ALI files. It generates error messages if the program is
inconsistent or if no valid order of elaboration exists.

If no errors are detected, the binder produces a main program, in Ada by
default, that contains calls to the elaboration procedures of those
compilation unit that require them, followed by
a call to the main program. This Ada program is compiled to generate the
object file for the main program. The name of
the Ada file is @file{b~@var{xxx}.adb} (with the corresponding spec
@file{b~@var{xxx}.ads}) where @var{xxx} is the name of the
main program unit.

Finally, the linker is used to build the resulting executable program,
using the object from the main program from the bind step as well as the
object files for the Ada units of the program.

@node Mixed Language Programming
@section Mixed Language Programming
@cindex Mixed Language Programming

@menu
* Interfacing to C::
* Calling Conventions::
@end menu

@node Interfacing to C
@subsection Interfacing to C
@noindent
There are two ways to
build a program that contains some Ada files and some other language
files depending on whether the main program is in Ada or not.
If the main program is in Ada, you should proceed as follows:

@enumerate
@item
Compile the other language files to generate object files. For instance:
@smallexample
gcc -c file1.c
gcc -c file2.c
@end smallexample

@item
Compile the Ada units to produce a set of object files and ALI
files. For instance:
@smallexample
gnatmake ^-c^/ACTIONS=COMPILE^ my_main.adb
@end smallexample

@item
Run the Ada binder on the Ada main program. For instance:
@smallexample
gnatbind my_main.ali
@end smallexample

@item
Link the Ada main program, the Ada objects and the other language
objects. For instance:
@smallexample
gnatlink my_main.ali file1.o file2.o
@end smallexample
@end enumerate

The three last steps can be grouped in a single command:
@smallexample
gnatmake my_main.adb -largs file1.o file2.o
@end smallexample

@cindex Binder output file
@noindent
If the main program is in some language other than Ada, Then you may
have more than one entry point in the Ada subsystem. You must use a
special option of the binder to generate callable routines to initialize
and finalize the Ada units (@pxref{Binding with Non-Ada Main Programs}).
Calls to the initialization and finalization routines must be inserted in
the main program, or some other appropriate point in the code. The call to
initialize the Ada units must occur before the first Ada subprogram is
called, and the call to finalize the Ada units must occur after the last
Ada subprogram returns. You use the same procedure for building the
program as described previously. In this case, however, the binder
only places the initialization and finalization subprograms into file
@file{b~@var{xxx}.adb} instead of the main program.
So, if the main program is not in Ada, you should proceed as follows:

@enumerate
@item
Compile the other language files to generate object files. For instance:
@smallexample
gcc -c file1.c
gcc -c file2.c
@end smallexample

@item
Compile the Ada units to produce a set of object files and ALI
files. For instance:
@smallexample
gnatmake ^-c^/ACTIONS=COMPILE^ entry_point1.adb
gnatmake ^-c^/ACTIONS=COMPILE^ entry_point2.adb
@end smallexample

@item
Run the Ada binder on the Ada main program. For instance:
@smallexample
gnatbind ^-n^/NOMAIN^ entry_point1.ali entry_point2.ali
@end smallexample

@item
Link the Ada main program, the Ada objects and the other language
objects. You only need to give the last entry point here. For instance:
@smallexample
gnatlink entry_point2.ali file1.o file2.o
@end smallexample
@end enumerate

@node Calling Conventions
@subsection Calling Conventions
@cindex Foreign Languages
@cindex Calling Conventions
GNAT follows standard calling sequence conventions and will thus interface
to any other language that also follows these conventions. The following
Convention identifiers are recognized by GNAT:

@itemize @bullet
@cindex Interfacing to Ada
@cindex Other Ada compilers
@cindex Convention Ada
@item
Ada. This indicates that the standard Ada calling sequence will be
used and all Ada data items may be passed without any limitations in the
case where GNAT is used to generate both the caller and callee. It is also
possible to mix GNAT generated code and code generated by another Ada
compiler. In this case, the data types should be restricted to simple
cases, including primitive types. Whether complex data types can be passed
depends on the situation. Probably it is safe to pass simple arrays, such
as arrays of integers or floats. Records may or may not work, depending
on whether both compilers lay them out identically. Complex structures
involving variant records, access parameters, tasks, or protected types,
are unlikely to be able to be passed.

Note that in the case of GNAT running
on a platform that supports DEC Ada 83, a higher degree of compatibility
can be guaranteed, and in particular records are layed out in an identical
manner in the two compilers. Note also that if output from two different
compilers is mixed, the program is responsible for dealing with elaboration
issues. Probably the safest approach is to write the main program in the
version of Ada other than GNAT, so that it takes care of its own elaboration
requirements, and then call the GNAT-generated adainit procedure to ensure
elaboration of the GNAT components. Consult the documentation of the other
Ada compiler for further details on elaboration.

However, it is not possible to mix the tasking run time of GNAT and
DEC Ada 83, All the tasking operations must either be entirely within
GNAT compiled sections of the program, or entirely within DEC Ada 83
compiled sections of the program.

@cindex Interfacing to Assembly
@cindex Convention Assembler
@item
Assembler. Specifies assembler as the convention. In practice this has the
same effect as convention Ada (but is not equivalent in the sense of being
considered the same convention).

@cindex Convention Asm
@findex Asm
@item
Asm. Equivalent to Assembler.

@cindex Convention Asm
@findex Asm
@item
Asm. Equivalent to Assembly.

@cindex Interfacing to COBOL
@cindex Convention COBOL
@findex COBOL
@item
COBOL. Data will be passed according to the conventions described
in section B.4 of the Ada 95 Reference Manual.

@findex C
@cindex Interfacing to C
@cindex Convention C
@item
C. Data will be passed according to the conventions described
in section B.3 of the Ada 95 Reference Manual.

@cindex Convention Default
@findex Default
@item
Default. Equivalent to C.

@cindex Convention External
@findex External
@item
External. Equivalent to C.

@findex C++
@cindex Interfacing to C++
@cindex Convention C++
@item
CPP. This stands for C++. For most purposes this is identical to C.
See the separate description of the specialized GNAT pragmas relating to
C++ interfacing for further details.

@findex Fortran
@cindex Interfacing to Fortran
@cindex Convention Fortran
@item
Fortran. Data will be passed according to the conventions described
in section B.5 of the Ada 95 Reference Manual.

@item
Intrinsic. This applies to an intrinsic operation, as defined in the Ada 95
Reference Manual. If a a pragma Import (Intrinsic) applies to a subprogram,
this means that the body of the subprogram is provided by the compiler itself,
usually by means of an efficient code sequence, and that the user does not
supply an explicit body for it. In an application program, the pragma can only
be applied to the following two sets of names, which the GNAT compiler
recognizes.
@itemize @bullet
@item
Rotate_Left, Rotate_Right, Shift_Left, Shift_Right, Shift_Right_-
Arithmetic.  The corresponding subprogram declaration must have
two formal parameters. The
first one must be a signed integer type or a modular type with a binary
modulus, and the second parameter must be of type Natural.
The return type must be the same as the type of the first argument. The size
of this type can only be 8, 16, 32, or 64.
@item binary arithmetic operators: "+", "-", "*", "/"
The corresponding operator declaration must have parameters and result type
that have the same root numeric type (for example, all three are long_float
types). This simplifies the definition of operations that use type checking
to perform dimensional checks:
@smallexample
type Distance is new Long_Float;
type Time     is new Long_Float;
type Velocity is new Long_Float;
function "/" (D : Distance; T : Time)
  return Velocity;
pragma Import (Intrinsic, "/");
@end smallexample
@noindent
This common idiom is often programmed with a generic definition and an explicit
body. The pragma makes it simpler to introduce such declarations. It incurs
no overhead in compilation time or code size, because it is implemented as a
single machine instruction.
@end itemize
@noindent

@findex Stdcall
@cindex Convention Stdcall
@item
Stdcall. This is relevant only to NT/Win95 implementations of GNAT,
and specifies that the Stdcall calling sequence will be used, as defined
by the NT API.

@findex DLL
@cindex Convention DLL
@item
DLL. This is equivalent to Stdcall.

@findex Win32
@cindex Convention Win32
@item
Win32. This is equivalent to Stdcall.

@findex Stubbed
@cindex Convention Stubbed
@item
Stubbed. This is a special convention that indicates that the compiler
should provide a stub body that raises @code{Program_Error}.
@end itemize

@noindent
GNAT additionally provides a useful pragma @code{Convention_Identifier}
that can be used to parametrize conventions and allow additional synonyms
to be specified. For example if you have legacy code in which the convention
identifier Fortran77 was used for Fortran, you can use the configuration
pragma:

@smallexample
   pragma Convention_Identifier (Fortran77, Fortran);
@end smallexample

@noindent
And from now on the identifier Fortran77 may be used as a convention
identifier (for example in an @code{Import} pragma) with the same
meaning as Fortran.

@node Building Mixed Ada & C++ Programs
@section Building Mixed Ada & C++ Programs

@noindent
Building a mixed application containing both Ada and C++ code may be a
challenge for the unaware programmer. As a matter of fact, this
interfacing has not been standardized in the Ada 95 reference manual due
to the immaturity and lack of standard of C++ at the time. This
section gives a few hints that should make this task easier. In
particular the first section addresses the differences with
interfacing with C. The second section looks into the delicate problem
of linking the complete application from its Ada and C++ parts. The last
section give some hints on how the GNAT run time can be adapted in order
to allow inter-language dispatching with a new C++ compiler.

@menu
* Interfacing to C++::
* Linking a Mixed C++ & Ada Program::
* A Simple Example::
* Adapting the Run Time to a New C++ Compiler::
@end menu

@node Interfacing to C++
@subsection Interfacing to C++

@noindent
GNAT supports interfacing with C++ compilers generating code that is
compatible with the standard Application Binary Interface of the given
platform.

@noindent
Interfacing can be done at 3 levels: simple data, subprograms and
classes. In the first 2 cases, GNAT offer a specific @var{Convention
CPP} that behaves exactly like @var{Convention C}. Usually C++ mangle
names of subprograms and currently GNAT does not provide any help to
solve the demangling problem. This problem can be addressed in 2 ways:
@itemize @bullet
@item
by modifying the C++ code in order to force a C convention using
the @var{extern "C"} syntax.

@item
by figuring out the mangled name and use it as the Link_Name argument of
the pragma import.
@end itemize

@noindent
Interfacing at the class level can be achieved by using the GNAT specific
pragmas such as @code{CPP_Class} and @code{CPP_Virtual}. See the GNAT
Reference Manual for additional information.

@node Linking a Mixed C++ & Ada Program
@subsection Linking a Mixed C++ & Ada Program

@noindent
Usually the linker of the C++ development system must be used to link
mixed applications because most C++ systems will resolve elaboration
issues (such as calling constructors on global class instances)
transparently during the link phase. GNAT has been adapted to ease the
use of a foreign linker for the last phase. Three cases can be
considered:
@enumerate

@item
Using GNAT and G++ (GNU C++ compiler) from the same GCC
installation. The c++ linker can simply be called by using the c++
specific driver called @code{c++}. Note that this setup is not
very common because it may request recompiling the whole GCC
tree from sources and it does not allow to upgrade easily to a new
version of one compiler for one of the two languages without taking the
risk of destabilizing the other.

@smallexample
$ c++ -c file1.C
$ c++ -c file2.C
$ gnatmake ada_unit -largs file1.o file2.o --LINK=c++
@end smallexample

@item
Using GNAT and G++ from 2 different GCC installations. If both compilers
are on the PATH, the same method can be used. It is important to be
aware that environment variables such as C_INCLUDE_PATH,
GCC_EXEC_PREFIX, BINUTILS_ROOT or GCC_ROOT will affect both compilers at
the same time and thus may make one of the 2 compilers operate
improperly if they are set for the other. In particular it is important
that the link command has access to the proper gcc library @file{libgcc.a},
that is to say the one that is part of the C++ compiler
installation. The implicit link command as suggested in the gnatmake
command from the former example can be replaced by an explicit link
command with full verbosity in order to verify which library is used:
@smallexample
$ gnatbind ada_unit
$ gnatlink -v -v ada_unit file1.o file2.o --LINK=c++
@end smallexample
If there is a problem due to interfering environment variables, it can
be workaround by using an intermediate script. The following example
shows the proper script to use when GNAT has not been installed at its
default location and g++ has been installed at its default location:

@smallexample
$ gnatlink -v -v ada_unit file1.o file2.o --LINK=./my_script
$ cat ./my_script
#!/bin/sh
unset BINUTILS_ROOT
unset GCC_ROOT
c++ $*
@end smallexample

@item
Using a non GNU C++ compiler. The same set of command as previously
described can be used to insure that the c++ linker is
used. Nonetheless, you need to add the path to libgcc explicitely, since some
libraries needed by GNAT are located in this directory:

@smallexample

$ gnatlink ada_unit file1.o file2.o --LINK=./my_script
$ cat ./my_script
#!/bin/sh
CC $* `gcc -print-libgcc-file-name`

@end smallexample

Where CC is the name of the non GNU C++ compiler.

@end enumerate

@node A Simple Example
@subsection  A Simple Example
@noindent
The following example, provided as part of the GNAT examples, show how
to achieve procedural interfacing between Ada and C++ in both
directions. The C++ class A has 2 methods. The first method is exported
to Ada by the means of an extern C wrapper function. The second method
calls an Ada subprogram. On the Ada side, The C++ calls is modelized by
a limited record with a layout comparable to the C++ class. The Ada
subprogram, in turn, calls the c++ method. So from the C++ main program
the code goes back and forth between the 2 languages.

@noindent
Here are the compilation commands
@ifclear vxworks
for native configurations:
@smallexample
$ gnatmake -c simple_cpp_interface
$ c++ -c cpp_main.C
$ c++ -c ex7.C
$ gnatbind -n simple_cpp_interface
$ gnatlink simple_cpp_interface -o cpp_main --LINK=$(CPLUSPLUS)
      -lstdc++ ex7.o cpp_main.o
@end smallexample
@end ifclear
@ifset vxworks
for a GNAT VxWorks/PowerPC  configuration:
@smallexample
$ powerpc-wrs-vxworks-gnatmake -c simple_cpp_interface
$ powerpc-wrs-vxworks-gnatbind -n simple_cpp_interface
$ gnatlink simple_cpp_interface -o ada_part
$ c++ppc -c -DCPU=PPC604  -I/usr/windppc/target/h  cpp_main.C
$ c++ppc -c -DCPU=PPC604  -I/usr/windppc/target/h  ex7.C
$ ldppc -r -o my_main my_main.o ex7.o ada_part
@end smallexample
@end ifset
@noindent
Here are the corresponding sources:
@smallexample

//cpp_main.C

#include "ex7.h"

extern "C" @{
  void adainit (void);
  void adafinal (void);
  void method1 (A *t);
@}

void method1 (A *t)
@{
  t->method1 ();
@}

int main ()
@{
  A obj;
  adainit ();
  obj.method2 (3030);
  adafinal ();
@}

//ex7.h

class Origin @{
 public:
  int o_value;
@};
class A : public Origin @{
 public:
  void method1 (void);
  virtual void method2 (int v);
  A();
  int   a_value;
@};

//ex7.C

#include "ex7.h"
#include <stdio.h>

extern "C" @{ void ada_method2 (A *t, int v);@}

void A::method1 (void)
@{
  a_value = 2020;
  printf ("in A::method1, a_value = %d \n",a_value);

@}

void A::method2 (int v)
@{
   ada_method2 (this, v);
   printf ("in A::method2, a_value = %d \n",a_value);

@}

A::A(void)
@{
   a_value = 1010;
  printf ("in A::A, a_value = %d \n",a_value);
@}

-- Ada sources
@b{package} @b{body} Simple_Cpp_Interface @b{is}

   @b{procedure} Ada_Method2 (This : @b{in} @b{out} A; V : Integer) @b{is}
   @b{begin}
      Method1 (This);
      This.A_Value := V;
   @b{end} Ada_Method2;

@b{end} Simple_Cpp_Interface;

@b{package} Simple_Cpp_Interface @b{is}
   @b{type} A @b{is} @b{limited}
      @b{record}
         O_Value : Integer;
         A_Value : Integer;
      @b{end} @b{record};
   @b{pragma} Convention (C, A);

   @b{procedure} Method1 (This : @b{in} @b{out} A);
   @b{pragma} Import (C, Method1);

   @b{procedure} Ada_Method2 (This : @b{in} @b{out} A; V : Integer);
   @b{pragma} Export (C, Ada_Method2);

@b{end} Simple_Cpp_Interface;
@end smallexample

@node Adapting the Run Time to a New C++ Compiler
@subsection Adapting the Run Time to a New C++ Compiler
@noindent
GNAT offers the capability to derive Ada 95 tagged types directly from
preexisting C++ classes and . See "Interfacing with C++" in the GNAT
reference manual. The mechanism used by GNAT for achieving such a goal
has been made user configurable through a GNAT library unit
@code{Interfaces.CPP}. The default version of this file is adapted to
the GNU c++ compiler. Internal knowledge of the virtual
table layout used by the new C++ compiler is needed to configure
properly this unit. The Interface of this unit is known by the compiler
and cannot be changed except for the value of the constants defining the
characteristics of the virtual table: CPP_DT_Prologue_Size, CPP_DT_Entry_Size,
CPP_TSD_Prologue_Size, CPP_TSD_Entry_Size. Read comments in the source
of this unit for more details.

@node Comparison between GNAT and C/C++ Compilation Models
@section Comparison between GNAT and C/C++ Compilation Models

@noindent
The GNAT model of compilation is close to the C and C++ models. You can
think of Ada specs as corresponding to header files in C. As in C, you
don't need to compile specs; they are compiled when they are used. The
Ada @code{with} is similar in effect to the @code{#include} of a C
header.

One notable difference is that, in Ada, you may compile specs separately
to check them for semantic and syntactic accuracy. This is not always
possible with C headers because they are fragments of programs that have
less specific syntactic or semantic rules.

The other major difference is the requirement for running the binder,
which performs two important functions. First, it checks for
consistency. In C or C++, the only defense against assembling
inconsistent programs lies outside the compiler, in a makefile, for
example. The binder satisfies the Ada requirement that it be impossible
to construct an inconsistent program when the compiler is used in normal
mode.

@cindex Elaboration order control
The other important function of the binder is to deal with elaboration
issues. There are also elaboration issues in C++ that are handled
automatically. This automatic handling has the advantage of being
simpler to use, but the C++ programmer has no control over elaboration.
Where @code{gnatbind} might complain there was no valid order of
elaboration, a C++ compiler would simply construct a program that
malfunctioned at run time.

@node Comparison between GNAT and Conventional Ada Library Models
@section Comparison between GNAT and Conventional Ada Library Models

@noindent
This section is intended to be useful to Ada programmers who have
previously used an Ada compiler implementing the traditional Ada library
model, as described in the Ada 95 Language Reference Manual. If you
have not used such a system, please go on to the next section.

@cindex GNAT library
In GNAT, there is no @dfn{library} in the normal sense. Instead, the set of
source files themselves acts as the library. Compiling Ada programs does
not generate any centralized information, but rather an object file and
a ALI file, which are of interest only to the binder and linker.
In a traditional system, the compiler reads information not only from
the source file being compiled, but also from the centralized library.
This means that the effect of a compilation depends on what has been
previously compiled. In particular:

@itemize @bullet
@item
When a unit is @code{with}'ed, the unit seen by the compiler corresponds
to the version of the unit most recently compiled into the library.

@item
Inlining is effective only if the necessary body has already been
compiled into the library.

@item
Compiling a unit may obsolete other units in the library.
@end itemize

@noindent
In GNAT, compiling one unit never affects the compilation of any other
units because the compiler reads only source files. Only changes to source
files can affect the results of a compilation. In particular:

@itemize @bullet
@item
When a unit is @code{with}'ed, the unit seen by the compiler corresponds
to the source version of the unit that is currently accessible to the
compiler.

@item
@cindex Inlining
Inlining requires the appropriate source files for the package or
subprogram bodies to be available to the compiler. Inlining is always
effective, independent of the order in which units are complied.

@item
Compiling a unit never affects any other compilations. The editing of
sources may cause previous compilations to be out of date if they
depended on the source file being modified.
@end itemize

@noindent
The most important result of these differences is that order of compilation
is never significant in GNAT. There is no situation in which one is
required to do one compilation before another. What shows up as order of
compilation requirements in the traditional Ada library becomes, in
GNAT, simple source dependencies; in other words, there is only a set
of rules saying what source files must be present when a file is
compiled.

@node Compiling Using gcc
@chapter Compiling Using @code{gcc}

@noindent
This chapter discusses how to compile Ada programs using the @code{gcc}
command. It also describes the set of switches
that can be used to control the behavior of the compiler.
@menu
* Compiling Programs::
* Switches for gcc::
* Search Paths and the Run-Time Library (RTL)::
* Order of Compilation Issues::
* Examples::
@end menu

@node Compiling Programs
@section Compiling Programs

@noindent
The first step in creating an executable program is to compile the units
of the program using the @code{gcc} command. You must compile the
following files:

@itemize @bullet
@item
the body file (@file{.adb}) for a library level subprogram or generic
subprogram

@item
the spec file (@file{.ads}) for a library level package or generic
package that has no body

@item
the body file (@file{.adb}) for a library level package
or generic package that has a body

@end itemize

@noindent
You need @emph{not} compile the following files

@itemize @bullet

@item
the spec of a library unit which has a body

@item
subunits
@end itemize

@noindent
because they are compiled as part of compiling related units. GNAT
package specs
when the corresponding body is compiled, and subunits when the parent is
compiled.
@cindex No code generated
If you attempt to compile any of these files, you will get one of the
following error messages (where fff is the name of the file you compiled):

@smallexample
No code generated for file @var{fff} (@var{package spec})
No code generated for file @var{fff} (@var{subunit})
@end smallexample

@noindent
The basic command for compiling a file containing an Ada unit is

@smallexample
$ gcc -c [@var{switches}] @file{file name}
@end smallexample

@noindent
where @var{file name} is the name of the Ada file (usually
having an extension
@file{.ads} for a spec or @file{.adb} for a body).
@ifclear vms
You specify the
@code{-c} switch to tell @code{gcc} to compile, but not link, the file.
@end ifclear
The result of a successful compilation is an object file, which has the
same name as the source file but an extension of @file{.o} and an Ada
Library Information (ALI) file, which also has the same name as the
source file, but with @file{.ali} as the extension. GNAT creates these
two output files in the current directory, but you may specify a source
file in any directory using an absolute or relative path specification
containing the directory information.

@findex gnat1
@code{gcc} is actually a driver program that looks at the extensions of
the file arguments and loads the appropriate compiler. For example, the
GNU C compiler is @file{cc1}, and the Ada compiler is @file{gnat1}.
These programs are in directories known to the driver program (in some
configurations via environment variables you set), but need not be in
your path. The @code{gcc} driver also calls the assembler and any other
utilities needed to complete the generation of the required object
files.

It is possible to supply several file names on the same @code{gcc}
command. This causes @code{gcc} to call the appropriate compiler for
each file. For example, the following command lists three separate
files to be compiled:

@smallexample
$ gcc -c x.adb y.adb z.c
@end smallexample

@noindent
calls @code{gnat1} (the Ada compiler) twice to compile @file{x.adb} and
@file{y.adb}, and @code{cc1} (the C compiler) once to compile @file{z.c}.
The compiler generates three object files @file{x.o}, @file{y.o} and
@file{z.o} and the two ALI files @file{x.ali} and @file{y.ali} from the
Ada compilations. Any switches apply to all the files ^listed,^listed.^
@ifclear vms
except for
@option{-gnat@var{x}} switches, which apply only to Ada compilations.
@end ifclear

@node Switches for gcc
@section Switches for @code{gcc}

@noindent
The @code{gcc} command accepts switches that control the
compilation process. These switches are fully described in this section.
First we briefly list all the switches, in alphabetical order, then we
describe the switches in more detail in functionally grouped sections.

@menu
* Output and Error Message Control::
* Debugging and Assertion Control::
* Run-Time Checks::
* Stack Overflow Checking::
* Run-Time Control::
* Validity Checking::
* Style Checking::
* Using gcc for Syntax Checking::
* Using gcc for Semantic Checking::
* Compiling Ada 83 Programs::
* Character Set Control::
* File Naming Control::
* Subprogram Inlining Control::
* Auxiliary Output Control::
* Debugging Control::
* Units to Sources Mapping Files::
@end menu

@table @code
@ifclear vms
@cindex @code{-b} (@code{gcc})
@item -b @var{target}
Compile your program to run on @var{target}, which is the name of a
system configuration. You must have a GNAT cross-compiler built if
@var{target} is not the same as your host system.

@item -B@var{dir}
@cindex @code{-B} (@code{gcc})
Load compiler executables (for example, @code{gnat1}, the Ada compiler)
from @var{dir} instead of the default location. Only use this switch
when multiple versions of the GNAT compiler are available. See the
@code{gcc} manual page for further details. You would normally use the
@code{-b} or @code{-V} switch instead.

@item -c
@cindex @code{-c} (@code{gcc})
Compile. Always use this switch when compiling Ada programs.

Note: for some other languages when using @code{gcc}, notably in
the case of C and C++, it is possible to use
use @code{gcc} without a @code{-c} switch to
compile and link in one step. In the case of GNAT, you
cannot use this approach, because the binder must be run
and @code{gcc} cannot be used to run the GNAT binder.
@end ifclear

@item ^-g^/DEBUG^
@cindex @code{^-g^/DEBUG^} (@code{gcc})
Generate debugging information. This information is stored in the object
file and copied from there to the final executable file by the linker,
where it can be read by the debugger. You must use the
@code{^-g^/DEBUG^} switch if you plan on using the debugger.

@item ^-I^/SEARCH=^@var{dir}
@cindex @code{^-I^/SEARCH^} (@code{gcc})
@cindex RTL
Direct GNAT to search the @var{dir} directory for source files needed by
the current compilation
(@pxref{Search Paths and the Run-Time Library (RTL)}).

@item ^-I-^/NOCURRENT_DIRECTORY^
@cindex @code{^-I-^/NOCURRENT_DIRECTORY^} (@code{gcc})
@cindex RTL
Except for the source file named in the command line, do not look for source files
in the directory containing the source file named in the command line
(@pxref{Search Paths and the Run-Time Library (RTL)}).

@ifclear vms
@item -o @var{file}
@cindex @code{-o} (@code{gcc})
This switch is used in @code{gcc} to redirect the generated object file
and its associated ALI file. Beware of this switch with GNAT, because it may
cause the object file and ALI file to have different names which in turn
may confuse the binder and the linker.
@end ifclear

@ifclear vms
@item -O[@var{n}]
@cindex @code{-O} (@code{gcc})
@var{n} controls the optimization level.

@table @asis
@item n = 0
No optimization, the default setting if no @code{-O} appears

@item n = 1
Normal optimization, the default if you specify @code{-O} without
an operand.

@item n = 2
Extensive optimization

@item n = 3
Extensive optimization with automatic inlining. This applies only to
inlining within a unit. For details on control of inter-unit inlining
see @xref{Subprogram Inlining Control}.
@end table
@end ifclear

@ifset vms
@item  /NOOPTIMIZE (default)
@itemx /OPTIMIZE[=(keyword[,...])]
Selects the level of optimization for your program. The supported
keywords are as follows:
@table @code
@item   ALL (default)
Perform most optimizations, including those that
be expensive.

@item   NONE
Do not do any optimizations. Same as @code{/NOOPTIMIZE}.

@item SOME
Perform some optimizations, but omit ones that are costly.

@item   DEVELOPMENT
Same as @code{SOME}.

@item   INLINING
Full optimization, and also attempt automatic inlining of small
subprograms within a unit (@pxref{Inlining of Subprograms}).

@item   UNROLL_LOOPS
Try to unroll loops. This keyword may be specified together with
any keyword above other than @code{NONE}. Loop unrolling
usually, but not always, improves the performance of programs.
@end table
@end ifset

@item --RTS=@var{rts-path}
@cindex @code{--RTS} (@code{gcc})
Specifies the default location of the runtime library. Same meaning as the
equivalent @code{gnatmake} flag (see @ref{Switches for gnatmake}).

@item ^-S^/ASM^
@cindex @code{^-S^/ASM^} (@code{gcc})
^Used in place of @code{-c} to^Used to^
cause the assembler source file to be
generated, using @file{^.s^.S^} as the extension,
instead of the object file.
This may be useful if you need to examine the generated assembly code.

@item ^-v^/VERBOSE^
@cindex @code{^-v^/VERBOSE^} (@code{gcc})
Show commands generated by the @code{gcc} driver. Normally used only for
debugging purposes or if you need to be sure what version of the
compiler you are executing.

@ifclear vms
@item -V @var{ver}
@cindex @code{-V} (@code{gcc})
Execute @var{ver} version of the compiler. This is the @code{gcc}
version, not the GNAT version.
@end ifclear

@item -gnata
Assertions enabled. @code{Pragma Assert} and @code{pragma Debug} to be
activated.

@item -gnatA
Avoid processing @file{gnat.adc}. If a gnat.adc file is present, it will be ignored.

@item -gnatb
Generate brief messages to @file{stderr} even if verbose mode set.

@item -gnatc
Check syntax and semantics only (no code generation attempted).

@item -gnatC
Compress debug information and external symbol name table entries.

@item -gnatD
Output expanded source files for source level debugging. This switch
also suppress generation of cross-reference information (see -gnatx).

@item -gnatec@var{path}
Specify a configuration pragma file. (see @ref{The Configuration Pragmas Files})

@item -gnatem@var{path}
Specify a mapping file. (see @ref{Units to Sources Mapping Files})

@item -gnatE
Full dynamic elaboration checks.

@item -gnatf
Full errors. Multiple errors per line, all undefined references.

@item -gnatF
Externals names are folded to all uppercase.

@item -gnatg
Internal GNAT implementation mode. This should not be used for
applications programs, it is intended only for use by the compiler
and its run-time library. For documentation, see the GNAT sources.

@item -gnatG
List generated expanded code in source form.

@item ^-gnati^/IDENTIFIER_CHARACTER_SET=^@var{c}
Identifier character set
@ifclear vms
(@var{c}=1/2/3/4/8/9/p/f/n/w).
@end ifclear
@ifset vms
For details of the possible selections for @var{c},
see @xref{Character Set Control}.
@end ifset

@item ^-gnath^/HELP^
Output usage information. The output is written to @file{stdout}.

@item ^-gnatk^/FILE_NAME_MAX_LENGTH=^@var{n}
Limit file names to @var{n} (1-999) characters ^(@code{k} = krunch)^^.

@item -gnatl
Output full source listing with embedded error messages.

@item -gnatm^^=^@var{n}
Limit number of detected errors to @var{n} (1-999).

@item -gnatn
Activate inlining across unit boundaries for subprograms for which
pragma @code{inline} is specified.

@item -gnatN
Activate front end inlining.

@item ^-fno-inline^/INLINE=SUPPRESS^
Suppresses all inlining, even if other optimization or inlining switches
are set.

@ifclear vms
@item -fstack-check
Activates stack checking. See separate section on stack checking for
details of the use of this option.
@end ifclear

@item -gnato
Enable numeric overflow checking (which is not normally enabled by
default). Not that division by zero is a separate check that is not
controlled by this switch (division by zero checking is on by default).

@item -gnatp
Suppress all checks.

@item -gnatq
Don't quit; try semantics, even if parse errors.

@item -gnatQ
Don't quit; generate @file{ali} and tree files even if illegalities.

@item -gnatP
Enable polling. This is required on some systems (notably Windows NT) to
obtain asynchronous abort and asynchronous transfer of control capability.
See the description of pragma Polling in the GNAT Reference Manual for
full details.

@item -gnatR[0/1/2/3][s]
Output representation information for declared types and objects.

@item -gnats
Syntax check only.

@item -gnatt
Tree output file to be generated.

@item -gnatT nnn
Set time slice to specified number of microseconds

@item -gnatu
List units for this compilation.

@item -gnatU
Tag all error messages with the unique string "error:"

@item -gnatv
Verbose mode. Full error output with source lines to @file{stdout}.

@item -gnatV
Control level of validity checking. See separate section describing
this feature.

@item ^-gnatwxxx^/WARNINGS=^@var{xxx}
Warning mode where
@var{xxx} is a string of options describing the exact warnings that
are enabled or disabled. See separate section on warning control.

@item ^-gnatW^/WIDE_CHARACTER_ENCODING=^@var{e}
Wide character encoding method
@ifclear vms
(@var{e}=n/h/u/s/e/8).
@end ifclear
@ifset vms
(@var{e}=@code{BRACKETS, NONE, HEX, UPPER, SHIFT_JIS, EUC, UTF8})
@end ifset

@item -gnatx
Suppress generation of cross-reference information.

@item ^-gnaty^/STYLE_CHECKS=(option,option..)^
Enable built-in style checks. See separate section describing this feature.

@item ^-gnatz^/DISTRIBUTION_STUBS=^@var{m}
Distribution stub generation and compilation
@ifclear vms
(@var{m}=r/c for receiver/caller stubs).
@end ifclear
@ifset vms
(@var{m}=@code{RECEIVER} or @code{CALLER} to specify the type of stubs
to be generated and compiled).
@end ifset

@item -gnat83
Enforce Ada 83 restrictions.

@ifclear vms
@item -pass-exit-codes
Catch exit codes from the compiler and use the most meaningful as
exit status.
@end ifclear
@end table

@ifclear vms
You may combine a sequence of GNAT switches into a single switch. For
example, the combined switch

@cindex Combining GNAT switches
@smallexample
-gnatofi3
@end smallexample

@noindent
is equivalent to specifying the following sequence of switches:

@smallexample
-gnato -gnatf -gnati3
@end smallexample
@end ifclear

@noindent
The following restrictions apply to the combination of switches
in this manner:

@itemize @bullet
@item
The switch @option{-gnatc} if combined with other switches must come
first in the string.

@item
The switch @option{-gnats} if combined with other switches must come
first in the string.

@item
Once a "y" appears in the string (that is a use of the @option{-gnaty}
switch), then all further characters in the switch are interpreted
as style modifiers (see description of @option{-gnaty}).

@item
Once a "d" appears in the string (that is a use of the @option{-gnatd}
switch), then all further characters in the switch are interpreted
as debug flags (see description of @option{-gnatd}).

@item
Once a "w" appears in the string (that is a use of the @option{-gnatw}
switch), then all further characters in the switch are interpreted
as warning mode modifiers (see description of @option{-gnatw}).

@item
Once a "V" appears in the string (that is a use of the @option{-gnatV}
switch), then all further characters in the switch are interpreted
as validity checking options (see description of @option{-gnatV}).

@end itemize

@node Output and Error Message Control
@subsection Output and Error Message Control
@findex stderr

@noindent
The standard default format for error messages is called "brief format."
Brief format messages are written to @file{stderr} (the standard error
file) and have the following form:

@smallexample
@iftex
@leftskip=.7cm
@end iftex
e.adb:3:04: Incorrect spelling of keyword "function"
e.adb:4:20: ";" should be "is"
@end smallexample

@noindent
The first integer after the file name is the line number in the file,
and the second integer is the column number within the line.
@code{glide} can parse the error messages
and point to the referenced character.
The following switches provide control over the error message
format:

@table @code
@item -gnatv
@cindex @option{-gnatv} (@code{gcc})
@findex stdout
@ifclear vms
The v stands for verbose.
@end ifclear
The effect of this setting is to write long-format error
messages to @file{stdout} (the standard output file.
The same program compiled with the
@option{-gnatv} switch would generate:

@smallexample
@group
@cartouche
3. funcion X (Q : Integer)
   |
>>> Incorrect spelling of keyword "function"
4. return Integer;
                 |
>>> ";" should be "is"
@end cartouche
@end group
@end smallexample

@noindent
The vertical bar indicates the location of the error, and the @samp{>>>}
prefix can be used to search for error messages. When this switch is
used the only source lines output are those with errors.

@item -gnatl
@cindex @option{-gnatl} (@code{gcc})
@ifclear vms
The @code{l} stands for list.
@end ifclear
This switch causes a full listing of
the file to be generated. The output might look as follows:

@smallexample
@group
@cartouche
 1. procedure E is
 2.    V : Integer;
 3.    funcion X (Q : Integer)
       |
    >>> Incorrect spelling of keyword "function"
 4.     return Integer;
                      |
    >>> ";" should be "is"
 5.    begin
 6.       return Q + Q;
 7.    end;
 8. begin
 9.    V := X + X;
10.end E;
@end cartouche
@end group
@end smallexample

@noindent
@findex stderr
When you specify the @option{-gnatv} or @option{-gnatl} switches and
standard output is redirected, a brief summary is written to
@file{stderr} (standard error) giving the number of error messages and
warning messages generated.

@item -gnatU
@cindex @option{-gnatU} (@code{gcc})
This switch forces all error messages to be preceded by the unique
string "error:". This means that error messages take a few more
characters in space, but allows easy searching for and identification
of error messages.

@item -gnatb
@cindex @option{-gnatb} (@code{gcc})
@ifclear vms
The @code{b} stands for brief.
@end ifclear
This switch causes GNAT to generate the
brief format error messages to @file{stderr} (the standard error
file) as well as the verbose
format message or full listing (which as usual is written to
@file{stdout} (the standard output file).

@item -gnatm^^=^@var{n}
@cindex @option{-gnatm} (@code{gcc})
@ifclear vms
The @code{m} stands for maximum.
@end ifclear
@var{n} is a decimal integer in the
range of 1 to 999 and limits the number of error messages to be
generated. For example, using @option{-gnatm2} might yield

@smallexample
@iftex
@leftskip=.7cm
@end iftex
e.adb:3:04: Incorrect spelling of keyword "function"
e.adb:5:35: missing ".."
fatal error: maximum errors reached
compilation abandoned
@end smallexample

@item -gnatf
@cindex @option{-gnatf} (@code{gcc})
@cindex Error messages, suppressing
@ifclear vms
The @code{f} stands for full.
@end ifclear
Normally, the compiler suppresses error messages that are likely to be
redundant. This switch causes all error
messages to be generated. In particular, in the case of
references to undefined variables. If a given variable is referenced
several times, the normal format of messages is
@smallexample
@iftex
@leftskip=.7cm
@end iftex
e.adb:7:07: "V" is undefined (more references follow)
@end smallexample

@noindent
where the parenthetical comment warns that there are additional
references to the variable @code{V}. Compiling the same program with the
@option{-gnatf} switch yields

@smallexample
e.adb:7:07: "V" is undefined
e.adb:8:07: "V" is undefined
e.adb:8:12: "V" is undefined
e.adb:8:16: "V" is undefined
e.adb:9:07: "V" is undefined
e.adb:9:12: "V" is undefined
@end smallexample

@item -gnatq
@cindex @option{-gnatq} (@code{gcc})
@ifclear vms
The @code{q} stands for quit (really "don't quit").
@end ifclear
In normal operation mode, the compiler first parses the program and
determines if there are any syntax errors. If there are, appropriate
error messages are generated and compilation is immediately terminated.
This switch tells
GNAT to continue with semantic analysis even if syntax errors have been
found. This may enable the detection of more errors in a single run. On
the other hand, the semantic analyzer is more likely to encounter some
internal fatal error when given a syntactically invalid tree.

@item -gnatQ
In normal operation mode, the @file{ali} file is not generated if any
illegalities are detected in the program. The use of @option{-gnatQ} forces
generation of the @file{ali} file. This file is marked as being in
error, so it cannot be used for binding purposes, but it does contain
reasonably complete cross-reference information, and thus may be useful
for use by tools (e.g. semantic browsing tools or integrated development
environments) that are driven from the @file{ali} file.

In addition, if @option{-gnatt} is also specified, then the tree file is
generated even if there are illegalities. It may be useful in this case
to also specify @option{-gnatq} to ensure that full semantic processing
occurs. The resulting tree file can be processed by ASIS, for the purpose
of providing partial information about illegal units, but if the error
causes the tree to be badly malformed, then ASIS may crash during the
analysis.

@end table

@noindent
In addition to error messages, which correspond to illegalities as defined
in the Ada 95 Reference Manual, the compiler detects two kinds of warning
situations.

@cindex Warning messages
First, the compiler considers some constructs suspicious and generates a
warning message to alert you to a possible error. Second, if the
compiler detects a situation that is sure to raise an exception at
run time, it generates a warning message. The following shows an example
of warning messages:
@smallexample
@iftex
@leftskip=.2cm
@end iftex
e.adb:4:24: warning: creation of object may raise Storage_Error
e.adb:10:17: warning: static value out of range
e.adb:10:17: warning: "Constraint_Error" will be raised at run time

@end smallexample

@noindent
GNAT considers a large number of situations as appropriate
for the generation of warning messages. As always, warnings are not
definite indications of errors. For example, if you do an out-of-range
assignment with the deliberate intention of raising a
@code{Constraint_Error} exception, then the warning that may be
issued does not indicate an error. Some of the situations for which GNAT
issues warnings (at least some of the time) are given in the following
list, which is not necessarily complete.

@itemize @bullet
@item
Possible infinitely recursive calls

@item
Out-of-range values being assigned

@item
Possible order of elaboration problems

@item
Unreachable code

@item
Fixed-point type declarations with a null range

@item
Variables that are never assigned a value

@item
Variables that are referenced before being initialized

@item
Task entries with no corresponding accept statement

@item
Duplicate accepts for the same task entry in a select

@item
Objects that take too much storage

@item
Unchecked conversion between types of differing sizes

@item
Missing return statements along some execution paths in a function

@item
Incorrect (unrecognized) pragmas

@item
Incorrect external names

@item
Allocation from empty storage pool

@item
Potentially blocking operations in protected types

@item
Suspicious parenthesization of expressions

@item
Mismatching bounds in an aggregate

@item
Attempt to return local value by reference

@item
Unrecognized pragmas

@item
Premature instantiation of a generic body

@item
Attempt to pack aliased components

@item
Out of bounds array subscripts

@item
Wrong length on string assignment

@item
Violations of style rules if style checking is enabled

@item
Unused with clauses

@item
Bit_Order usage that does not have any effect

@item
Compile time biased rounding of floating-point constant

@item
Standard.Duration used to resolve universal fixed expression

@item
Dereference of possibly null value

@item
Declaration that is likely to cause storage error

@item
Internal GNAT unit with'ed by application unit

@item
Values known to be out of range at compile time

@item
Unreferenced labels and variables

@item
Address overlays that could clobber memory

@item
Unexpected initialization when address clause present

@item
Bad alignment for address clause

@item
Useless type conversions

@item
Redundant assignment statements

@item
Accidental hiding of name by child unit

@item
Unreachable code

@item
Access before elaboration detected at compile time

@item
A range in a @code{for} loop that is known to be null or might be null

@end itemize

@noindent
The following switches are available to control the handling of
warning messages:

@table @code
@item -gnatwa (activate all optional errors)
@cindex @option{-gnatwa} (@code{gcc})
This switch activates most optional warning messages, see remaining list
in this section for details on optional warning messages that can be
individually controlled. The warnings that are not turned on by this
switch are @option{-gnatwb} (biased rounding),
@option{-gnatwd} (implicit dereferencing),
and @option{-gnatwh} (hiding). All other optional warnings are
turned on.

@item -gnatwA (suppress all optional errors)
@cindex @option{-gnatwA} (@code{gcc})
This switch suppresses all optional warning messages, see remaining list
in this section for details on optional warning messages that can be
individually controlled.

@item -gnatwb (activate warnings on biased rounding)
@cindex @option{-gnatwb} (@code{gcc})
@cindex Rounding, biased
@cindex Biased rounding
If a static floating-point expression has a value that is exactly half
way between two adjacent machine numbers, then the rules of Ada
(Ada Reference Manual, section 4.9(38)) require that this rounding
be done away from zero, even if the normal unbiased rounding rules
at run time would require rounding towards zero. This warning message
alerts you to such instances where compile-time rounding and run-time
rounding are not equivalent. If it is important to get proper run-time
rounding, then you can force this by making one of the operands into
a variable. The default is that such warnings are not generated.
Note that @option{-gnatwa} does not affect the setting of
this warning option.

@item -gnatwB (suppress warnings on biased rounding)
@cindex @option{-gnatwB} (@code{gcc})
This switch disables warnings on biased rounding.

@item -gnatwc (activate warnings on conditionals)
@cindex @option{-gnatwc} (@code{gcc})
@cindex Conditionals, constant
This switch activates warnings for conditional expressions used in
tests that are known to be True or False at compile time. The default
is that such warnings are not generated.
This warning can also be turned on using @option{-gnatwa}.

@item -gnatwC (suppress warnings on conditionals)
@cindex @option{-gnatwC} (@code{gcc})
This switch suppresses warnings for conditional expressions used in
tests that are known to be True or False at compile time.

@item -gnatwd (activate warnings on implicit dereferencing)
@cindex @option{-gnatwd} (@code{gcc})
If this switch is set, then the use of a prefix of an access type
in an indexed component, slice, or selected component without an
explicit @code{.all} will generate a warning. With this warning
enabled, access checks occur only at points where an explicit
@code{.all} appears in the source code (assuming no warnings are
generated as a result of this switch). The default is that such
warnings are not generated.
Note that @option{-gnatwa} does not affect the setting of
this warning option.

@item -gnatwD (suppress warnings on implicit dereferencing)
@cindex @option{-gnatwD} (@code{gcc})
@cindex Implicit dereferencing
@cindex Dereferencing, implicit
This switch suppresses warnings for implicit deferences in
indexed components, slices, and selected components.

@item -gnatwe (treat warnings as errors)
@cindex @option{-gnatwe} (@code{gcc})
@cindex Warnings, treat as error
This switch causes warning messages to be treated as errors.
The warning string still appears, but the warning messages are counted
as errors, and prevent the generation of an object file.

@item -gnatwf (activate warnings on unreferenced formals)
@cindex @option{-gnatwf} (@code{gcc})
@cindex Formals, unreferenced
This switch causes a warning to be generated if a formal parameter
is not referenced in the body of the subprogram. This warning can
also be turned on using @option{-gnatwa} or @option{-gnatwu}.

@item -gnatwF (suppress warnings on unreferenced formals)
@cindex @option{-gnatwF} (@code{gcc})
This switch suppresses warnings for unreferenced formal
parameters. Note that the
combination @option{-gnatwu} followed by @option{-gnatwF} has the
effect of warning on unreferenced entities other than subprogram
formals.

@item -gnatwh (activate warnings on hiding)
@cindex @option{-gnatwh} (@code{gcc})
@cindex Hiding of Declarations
This switch activates warnings on hiding declarations.
A declaration is considered hiding
if it is for a non-overloadable entity, and it declares an entity with the
same name as some other entity that is directly or use-visible. The default
is that such warnings are not generated.
Note that @option{-gnatwa} does not affect the setting of this warning option.

@item -gnatwH (suppress warnings on hiding)
@cindex @option{-gnatwH} (@code{gcc})
This switch suppresses warnings on hiding declarations.

@item -gnatwi (activate warnings on implementation units).
@cindex @option{-gnatwi} (@code{gcc})
This switch activates warnings for a @code{with} of an internal GNAT
implementation unit, defined as any unit from the @code{Ada},
@code{Interfaces}, @code{GNAT},
^^@code{DEC},^ or @code{System}
hierarchies that is not
documented in either the Ada Reference Manual or the GNAT
Programmer's Reference Manual. Such units are intended only
for internal implementation purposes and should not be @code{with}'ed
by user programs. The default is that such warnings are generated
This warning can also be turned on using @option{-gnatwa}.

@item -gnatwI (disable warnings on implementation units).
@cindex @option{-gnatwI} (@code{gcc})
This switch disables warnings for a @code{with} of an internal GNAT
implementation unit.

@item -gnatwl (activate warnings on elaboration pragmas)
@cindex @option{-gnatwl} (@code{gcc})
@cindex Elaboration, warnings
This switch activates warnings on missing pragma Elaborate_All statements.
See the section in this guide on elaboration checking for details on
when such pragma should be used. The default is that such warnings
are not generated.
This warning can also be turned on using @option{-gnatwa}.

@item -gnatwL (suppress warnings on elaboration pragmas)
@cindex @option{-gnatwL} (@code{gcc})
This switch suppresses warnings on missing pragma Elaborate_All statements.
See the section in this guide on elaboration checking for details on
when such pragma should be used.

@item -gnatwo (activate warnings on address clause overlays)
@cindex @option{-gnatwo} (@code{gcc})
@cindex Address Clauses, warnings
This switch activates warnings for possibly unintended initialization
effects of defining address clauses that cause one variable to overlap
another. The default is that such warnings are generated.
This warning can also be turned on using @option{-gnatwa}.

@item -gnatwO (suppress warnings on address clause overlays)
@cindex @option{-gnatwO} (@code{gcc})
This switch suppresses warnings on possibly unintended initialization
effects of defining address clauses that cause one variable to overlap
another.

@item -gnatwp (activate warnings on ineffective pragma Inlines)
@cindex @option{-gnatwp} (@code{gcc})
@cindex Inlining, warnings
This switch activates warnings for failure of front end inlining
(activated by @option{-gnatN}) to inline a particular call. There are
many reasons for not being able to inline a call, including most
commonly that the call is too complex to inline.
This warning can also be turned on using @option{-gnatwa}.

@item -gnatwP (suppress warnings on ineffective pragma Inlines)
@cindex @option{-gnatwP} (@code{gcc})
This switch suppresses warnings on ineffective pragma Inlines. If the
inlining mechanism cannot inline a call, it will simply ignore the
request silently.

@item -gnatwr (activate warnings on redundant constructs)
@cindex @option{-gnatwr} (@code{gcc})
This switch activates warnings for redundant constructs. The following
is the current list of constructs regarded as redundant:
This warning can also be turned on using @option{-gnatwa}.

@itemize @bullet
@item
Assignment of an item to itself.
@item
Type conversion that converts an expression to its own type.
@item
Use of the attribute @code{Base} where @code{typ'Base} is the same
as @code{typ}.
@item
Use of pragma @code{Pack} when all components are placed by a record
representation clause.
@end itemize

@item -gnatwR (suppress warnings on redundant constructs)
@cindex @option{-gnatwR} (@code{gcc})
This switch suppresses warnings for redundant constructs.

@item -gnatws (suppress all warnings)
@cindex @option{-gnatws} (@code{gcc})
This switch completely suppresses the
output of all warning messages from the GNAT front end.
Note that it does not suppress warnings from the @code{gcc} back end.
To suppress these back end warnings as well, use the switch @code{-w}
in addition to @option{-gnatws}.

@item -gnatwu (activate warnings on unused entities)
@cindex @option{-gnatwu} (@code{gcc})
This switch activates warnings to be generated for entities that
are defined but not referenced, and for units that are @code{with}'ed
and not
referenced. In the case of packages, a warning is also generated if
no entities in the package are referenced. This means that if the package
is referenced but the only references are in @code{use}
clauses or @code{renames}
declarations, a warning is still generated. A warning is also generated
for a generic package that is @code{with}'ed but never instantiated.
In the case where a package or subprogram body is compiled, and there
is a @code{with} on the corresponding spec
that is only referenced in the body,
a warning is also generated, noting that the
@code{with} can be moved to the body. The default is that
such warnings are not generated.
This switch also activates warnings on unreferenced formals
(it is includes the effect of @option{-gnatwf}).
This warning can also be turned on using @option{-gnatwa}.

@item -gnatwU (suppress warnings on unused entities)
@cindex @option{-gnatwU} (@code{gcc})
This switch suppresses warnings for unused entities and packages.
It also turns off warnings on unreferenced formals (and thus includes
the effect of @option{-gnatwF}).

@noindent
A string of warning parameters can be used in the same parameter. For example:

@smallexample
-gnatwaLe
@end smallexample

@noindent
Would turn on all optional warnings except for elaboration pragma warnings,
and also specify that warnings should be treated as errors.

@item -w
@cindex @code{-w}
This switch suppresses warnings from the @code{gcc} backend. It may be
used in conjunction with @option{-gnatws} to ensure that all warnings
are suppressed during the entire compilation process.

@end table

@node Debugging and Assertion Control
@subsection Debugging and Assertion Control

@table @code
@item -gnata
@cindex @option{-gnata} (@code{gcc})
@findex Assert
@findex Debug
@cindex Assertions

@noindent
The pragmas @code{Assert} and @code{Debug} normally have no effect and
are ignored. This switch, where @samp{a} stands for assert, causes
@code{Assert} and @code{Debug} pragmas to be activated.

The pragmas have the form:

@smallexample
@group
@cartouche
   @b{pragma} Assert (@var{Boolean-expression} [,
                      @var{static-string-expression}])
   @b{pragma} Debug (@var{procedure call})
@end cartouche
@end group
@end smallexample

@noindent
The @code{Assert} pragma causes @var{Boolean-expression} to be tested.
If the result is @code{True}, the pragma has no effect (other than
possible side effects from evaluating the expression). If the result is
@code{False}, the exception @code{Assert_Failure} declared in the package
@code{System.Assertions} is
raised (passing @var{static-string-expression}, if present, as the
message associated with the exception). If no string expression is
given the default is a string giving the file name and line number
of the pragma.

The @code{Debug} pragma causes @var{procedure} to be called. Note that
@code{pragma Debug} may appear within a declaration sequence, allowing
debugging procedures to be called between declarations.

@ifset vms
@item /DEBUG[=debug-level]
@itemx  /NODEBUG
Specifies how much debugging information is to be included in
the resulting object file where 'debug-level' is one of the following:
@table @code
@item   TRACEBACK (default)
Include both debugger symbol records and traceback
the object file.
@item   ALL
Include both debugger symbol records and traceback in
object file.
@item   NONE
Excludes both debugger symbol records and traceback
the object file. Same as /NODEBUG.
@item   SYMBOLS
Includes only debugger symbol records in the object
file. Note that this doesn't include traceback information.
@end table
@end ifset
@end table

@node Validity Checking
@subsection Validity Checking
@findex Validity Checking

@noindent
The Ada 95 Reference Manual has specific requirements for checking
for invalid values. In particular, RM 13.9.1 requires that the
evaluation of invalid values (for example from unchecked conversions),
not result in erroneous execution. In GNAT, the result of such an
evaluation in normal default mode is to either use the value
unmodified, or to raise Constraint_Error in those cases where use
of the unmodified value would cause erroneous execution. The cases
where unmodified values might lead to erroneous execution are case
statements (where a wild jump might result from an invalid value),
and subscripts on the left hand side (where memory corruption could
occur as a result of an invalid value).

The @option{-gnatVx} switch allows more control over the validity checking
mode. The @code{x} argument here is a string of letters which control which
validity checks are performed in addition to the default checks described
above.

@itemize @bullet
@item
@option{-gnatVc} Validity checks for copies

The right hand side of assignments, and the initializing values of
object declarations are validity checked.

@item
@option{-gnatVd} Default (RM) validity checks

Some validity checks are done by default following normal Ada semantics
(RM 13.9.1 (9-11)).
A check is done in case statements that the expression is within the range
of the subtype. If it is not, Constraint_Error is raised.
For assignments to array components, a check is done that the expression used
as index is within the range. If it is not, Constraint_Error is raised.
Both these validity checks may be turned off using switch @option{-gnatVD}.
They are turned on by default. If @option{-gnatVD} is specified, a subsequent
switch @option{-gnatVd} will leave the checks turned on.
Switch @option{-gnatVD} should be used only if you are sure that all such
expressions have valid values. If you use this switch and invalid values
are present, then the program is erroneous, and wild jumps or memory
overwriting may occur.

@item
@option{-gnatVi} Validity checks for @code{in} mode parameters

Arguments for parameters of mode @code{in} are validity checked in function
and procedure calls at the point of call.

@item
@option{-gnatVm} Validity checks for @code{in out} mode parameters

Arguments for parameters of mode @code{in out} are validity checked in
procedure calls at the point of call. The @code{'m'} here stands for
modify, since this concerns parameters that can be modified by the call.
Note that there is no specific option to test @code{out} parameters,
but any reference within the subprogram will be tested in the usual
manner, and if an invalid value is copied back, any reference to it
will be subject to validity checking.

@item
@option{-gnatVo} Validity checks for operator and attribute operands

Arguments for predefined operators and attributes are validity checked.
This includes all operators in package @code{Standard},
the shift operators defined as intrinsic in package @code{Interfaces}
and operands for attributes such as @code{Pos}.

@item
@option{-gnatVr} Validity checks for function returns

The expression in @code{return} statements in functions is validity
checked.

@item
@option{-gnatVs} Validity checks for subscripts

All subscripts expressions are checked for validity, whether they appear
on the right side or left side (in default mode only left side subscripts
are validity checked).

@item
@option{-gnatVt} Validity checks for tests

Expressions used as conditions in @code{if}, @code{while} or @code{exit}
statements are checked, as well as guard expressions in entry calls.

@item
@option{-gnatVf} Validity checks for floating-point values

In the absence of this switch, validity checking occurs only for discrete
values. If @option{-gnatVf} is specified, then validity checking also applies
for floating-point values, and NaN's and infinities are considered invalid,
as well as out of range values for constrained types. Note that this means
that standard @code{IEEE} infinity mode is not allowed. The exact contexts
in which floating-point values are checked depends on the setting of other
options. For example @option{-gnatVif} or @option{-gnatVfi} (the order does
not matter) specifies that floating-point parameters of mode @code{in} should
be validity checked.

@item
@option{-gnatVa} All validity checks

All the above validity checks are turned on. That is @option{-gnatVa} is
equivalent to @code{gnatVcdfimorst}.

@item
@option{-gnatVn} No validity checks

This switch turns off all validity checking, including the default checking
for case statements and left hand side subscripts. Note that the use of
the switch @option{-gnatp} supresses all run-time checks, including
validity checks, and thus implies @option{-gnatVn}.

@end itemize

The @option{-gnatV} switch may be followed by a string of letters to turn on
a series of validity checking options. For example, @option{-gnatVcr} specifies
that in addition to the default validity checking, copies and function
return expressions be validity checked. In order to make it easier to specify
a set of options, the upper case letters @code{CDFIMORST} may be used to turn
off the corresponding lower case option, so for example @option{-gnatVaM} turns
on all validity checking options except for checking of @code{in out}
procedure arguments.

The specification of additional validity checking generates extra code (and
in the case of @option{-gnatva} the code expansion can be substantial. However,
these additional checks can be very useful in smoking out cases of
uninitialized variables, incorrect use of unchecked conversion, and other
errors leading to invalid values. The use of pragma @code{Initialize_Scalars}
is useful in conjunction with the extra validity checking, since this
ensures that wherever possible uninitialized variables have invalid values.

See also the pragma @code{Validity_Checks} which allows modification of
the validity checking mode at the program source level, and also allows for
temporary disabling of validity checks.

@node Style Checking
@subsection Style Checking
@findex Style checking

@noindent
The -gnaty@var{^x^(option,option,..)^} switch causes the compiler to
enforce specified style rules. A limited set of style rules has been used
in writing the GNAT sources themselves. This switch allows user programs
to activate all or some of these checks. If the source program fails a
specified style check, an appropriate warning message is given, preceded by
the character sequence "(style)".
@ifset vms
(OPTION,OPTION,..) is a sequence of keywords
@end ifset
@ifclear vms
The string @var{x} is a sequence of letters or digits
@end ifclear
indicating the particular style
checks to be performed. The following checks are defined:

@table @code
@item 1-9 (specify indentation level)
If a digit from 1-9 appears in the string after @option{-gnaty} then proper
indentation is checked, with the digit indicating the indentation level
required. The general style of required indentation is as specified by
the examples in the Ada Reference Manual. Full line comments must be
aligned with the @code{--} starting on a column that is a multiple of
the alignment level.

@item ^a^ATTRIBUTE^ (check attribute casing)
If the ^letter a^word ATTRIBUTE^ appears in the string after @option{-gnaty} then
attribute names, including the case of keywords such as @code{digits}
used as attributes names, must be written in mixed case, that is, the
initial letter and any letter following an underscore must be uppercase.
All other letters must be lowercase.

@item ^b^BLANKS^ (blanks not allowed at statement end)
If the ^letter b^word BLANKS^ appears in the string after @option{-gnaty} then
trailing blanks are not allowed at the end of statements. The purpose of this
rule, together with h (no horizontal tabs), is to enforce a canonical format
for the use of blanks to separate source tokens.

@item ^c^COMMENTS^ (check comments)
If the ^letter c^word COMMENTS^ appears in the string after @option{-gnaty} then
comments must meet the following set of rules:

@itemize @bullet

@item
The "--" that starts the column must either start in column one, or else
at least one blank must precede this sequence.

@item
Comments that follow other tokens on a line must have at least one blank
following the "--" at the start of the comment.

@item
Full line comments must have two blanks following the "--" that starts
the comment, with the following exceptions.

@item
A line consisting only of the "--" characters, possibly preceded by blanks
is permitted.

@item
A comment starting with "--x" where x is a special character is permitted.
This alows proper processing of the output generated by specialized tools
including @code{gnatprep} (where --! is used) and the SPARK annnotation
language (where --# is used). For the purposes of this rule, a special
character is defined as being in one of the ASCII ranges
16#21#..16#2F# or 16#3A#..16#3F#.

@item
A line consisting entirely of minus signs, possibly preceded by blanks, is
permitted. This allows the construction of box comments where lines of minus
signs are used to form the top and bottom of the box.

@item
If a comment starts and ends with "--" is permitted as long as at least
one blank follows the initial "--". Together with the preceding rule,
this allows the construction of box comments, as shown in the following
example:
@smallexample
---------------------------
-- This is a box comment --
-- with two text lines.  --
---------------------------
@end smallexample
@end itemize

@item ^e^END^ (check end/exit labels)
If the ^letter e^word END^ appears in the string after @option{-gnaty} then
optional labels on @code{end} statements ending subprograms and on
@code{exit} statements exiting named loops, are required to be present.

@item ^f^VTABS^ (no form feeds or vertical tabs)
If the ^letter f^word VTABS^ appears in the string after @option{-gnaty} then
neither form feeds nor vertical tab characters are not permitted
in the source text.

@item ^h^HTABS^ (no horizontal tabs)
If the ^letter h^word HTABS^ appears in the string after @option{-gnaty} then
horizontal tab characters are not permitted in the source text.
Together with the b (no blanks at end of line) check, this
enforces a canonical form for the use of blanks to separate
source tokens.

@item ^i^IF_THEN^ (check if-then layout)
If the ^letter i^word IF_THEN^ appears in the string after @option{-gnaty},
then the keyword @code{then} must appear either on the same
line as corresponding @code{if}, or on a line on its own, lined
up under the @code{if} with at least one non-blank line in between
containing all or part of the condition to be tested.

@item ^k^KEYWORD^ (check keyword casing)
If the ^letter k^word KEYWORD^ appears in the string after @option{-gnaty} then
all keywords must be in lower case (with the exception of keywords
such as @code{digits} used as attribute names to which this check
does not apply).

@item ^l^LAYOUT^ (check layout)
If the ^letter l^word LAYOUT^ appears in the string after @option{-gnaty} then
layout of statement and declaration constructs must follow the
recommendations in the Ada Reference Manual, as indicated by the
form of the syntax rules. For example an @code{else} keyword must
be lined up with the corresponding @code{if} keyword.

There are two respects in which the style rule enforced by this check
option are more liberal than those in the Ada Reference Manual. First
in the case of record declarations, it is permissible to put the
@code{record} keyword on the same line as the @code{type} keyword, and
then the @code{end} in @code{end record} must line up under @code{type}.
For example, either of the following two layouts is acceptable:

@smallexample
@group
@cartouche
@b{type} q @b{is record}
   a : integer;
   b : integer;
@b{end record};

@b{type} q @b{is}
   @b{record}
      a : integer;
      b : integer;
   @b{end record};
@end cartouche
@end group
@end smallexample

@noindent
Second, in the case of a block statement, a permitted alternative
is to put the block label on the same line as the @code{declare} or
@code{begin} keyword, and then line the @code{end} keyword up under
the block label. For example both the following are permitted:

@smallexample
@group
@cartouche
Block : @b{declare}
   A : Integer := 3;
@b{begin}
   Proc (A, A);
@b{end} Block;

Block :
   @b{declare}
      A : Integer := 3;
   @b{begin}
      Proc (A, A);
   @b{end} Block;
@end cartouche
@end group
@end smallexample

@noindent
The same alternative format is allowed for loops. For example, both of
the following are permitted:

@smallexample
@group
@cartouche
Clear : @b{while} J < 10 @b{loop}
   A (J) := 0;
@b{end loop} Clear;

Clear :
   @b{while} J < 10 @b{loop}
      A (J) := 0;
   @b{end loop} Clear;
@end cartouche
@end group
@end smallexample

@item ^m^LINE_LENGTH^ (check maximum line length)
If the ^letter m^word LINE_LENGTH^ appears in the string after @option{-gnaty}
then the length of source lines must not exceed 79 characters, including
any trailing blanks. The value of 79 allows convenient display on an
80 character wide device or window, allowing for possible special
treatment of 80 character lines.

@item ^Mnnn^MAX_LENGTH=nnn^ (set maximum line length)
If the sequence ^M^MAX_LENGTH=^nnn, where nnn is a decimal number, appears in
the string after @option{-gnaty} then the length of lines must not exceed the
given value.

@item ^n^STANDARD_CASING^ (check casing of entities in Standard)
If the ^letter n^word STANDARD_CASING^ appears in the string
after @option{-gnaty} then any identifier from Standard must be cased
to match the presentation in the Ada Reference Manual (for example,
@code{Integer} and @code{ASCII.NUL}).

@item ^o^ORDERED_SUBPROGRAMS^ (check order of subprogram bodies)
If the ^letter o^word ORDERED_SUBPROGRAMS^ appears in the string
after @option{-gnaty} then all subprogram bodies in a given scope
(e.g. a package body) must be in alphabetical order. The ordering
rule uses normal Ada rules for comparing strings, ignoring casing
of letters, except that if there is a trailing numeric suffix, then
the value of this suffix is used in the ordering (e.g. Junk2 comes
before Junk10).

@item ^p^PRAGMA^ (check pragma casing)
If the ^letter p^word PRAGMA^ appears in the string after @option{-gnaty} then
pragma names must be written in mixed case, that is, the
initial letter and any letter following an underscore must be uppercase.
All other letters must be lowercase.

@item ^r^REFERENCES^ (check references)
If the ^letter r^word REFERENCES^ appears in the string after @option{-gnaty}
then all identifier references must be cased in the same way as the
corresponding declaration. No specific casing style is imposed on
identifiers. The only requirement is for consistency of references
with declarations.

@item ^s^SPECS^ (check separate specs)
If the ^letter s^word SPECS^ appears in the string after @option{-gnaty} then
separate declarations ("specs") are required for subprograms (a
body is not allowed to serve as its own declaration). The only
exception is that parameterless library level procedures are
not required to have a separate declaration. This exception covers
the most frequent form of main program procedures.

@item ^t^TOKEN^ (check token spacing)
If the ^letter t^word TOKEN^ appears in the string after @option{-gnaty} then
the following token spacing rules are enforced:

@itemize @bullet

@item
The keywords @code{abs} and @code{not} must be followed by a space.

@item
The token @code{=>} must be surrounded by spaces.

@item
The token @code{<>} must be preceded by a space or a left parenthesis.

@item
Binary operators other than @code{**} must be surrounded by spaces.
There is no restriction on the layout of the @code{**} binary operator.

@item
Colon must be surrounded by spaces.

@item
Colon-equal (assignment) must be surrounded by spaces.

@item
Comma must be the first non-blank character on the line, or be
immediately preceded by a non-blank character, and must be followed
by a space.

@item
If the token preceding a left paren ends with a letter or digit, then
a space must separate the two tokens.

@item
A right parenthesis must either be the first non-blank character on
a line, or it must be preceded by a non-blank character.

@item
A semicolon must not be preceded by a space, and must not be followed by
a non-blank character.

@item
A unary plus or minus may not be followed by a space.

@item
A vertical bar must be surrounded by spaces.
@end itemize

@noindent
In the above rules, appearing in column one is always permitted, that is,
counts as meeting either a requirement for a required preceding space,
or as meeting a requirement for no preceding space.

Appearing at the end of a line is also always permitted, that is, counts
as meeting either a requirement for a following space, or as meeting
a requirement for no following space.

@end table

@noindent
If any of these style rules is violated, a message is generated giving
details on the violation. The initial characters of such messages are
always "(style)". Note that these messages are treated as warning
messages, so they normally do not prevent the generation of an object
file. The @option{-gnatwe} switch can be used to treat warning messages,
including style messages, as fatal errors.

@noindent
The switch
^@option{-gnaty} on its own (that is not followed by any letters or digits),^/STYLE_CHECKS=ALL_BUILTIN^
is equivalent to ^@code{gnaty3abcefhiklmprst}, that is^^ all checking
options ^are^^ enabled with
the exception of ^-gnatyo^ORDERED_SUBPROGRAMS^,
with an indentation level of 3. This is the standard
checking option that is used for the GNAT sources.

@node Run-Time Checks
@subsection Run-Time Checks
@cindex Division by zero
@cindex Access before elaboration
@cindex Checks, division by zero
@cindex Checks, access before elaboration

@noindent
If you compile with the default options, GNAT will insert many run-time
checks into the compiled code, including code that performs range
checking against constraints, but not arithmetic overflow checking for
integer operations (including division by zero) or checks for access
before elaboration on subprogram calls. All other run-time checks, as
required by the Ada 95 Reference Manual, are generated by default.
The following @code{gcc} switches refine this default behavior:

@table @code
@item -gnatp
@cindex @option{-gnatp} (@code{gcc})
@cindex Suppressing checks
@cindex Checks, suppressing
@findex Suppress
Suppress all run-time checks as though @code{pragma Suppress (all_checks})
had been present in the source. Validity checks are also suppressed (in
other words @option{-gnatp} also implies @option{-gnatVn}.
Use this switch to improve the performance
of the code at the expense of safety in the presence of invalid data or
program bugs.

@item -gnato
@cindex @option{-gnato} (@code{gcc})
@cindex Overflow checks
@cindex Check, overflow
Enables overflow checking for integer operations.
This causes GNAT to generate slower and larger executable
programs by adding code to check for overflow (resulting in raising
@code{Constraint_Error} as required by standard Ada
semantics). These overflow checks correspond to situations in which
the true value of the result of an operation may be outside the base
range of the result type. The following example shows the distinction:

@smallexample
X1 : Integer := Integer'Last;
X2 : Integer range 1 .. 5 := 5;
...
X1 := X1 + 1;   -- @option{-gnato} required to catch the Constraint_Error
X2 := X2 + 1;   -- range check, @option{-gnato} has no effect here
@end smallexample

@noindent
Here the first addition results in a value that is outside the base range
of Integer, and hence requires an overflow check for detection of the
constraint error. The second increment operation results in a violation
of the explicit range constraint, and such range checks are always
performed. Basically the compiler can assume that in the absence of
the @option{-gnato} switch that any value of type @code{xxx} is
in range of the base type of @code{xxx}.

@findex Machine_Overflows
Note that the @option{-gnato} switch does not affect the code generated
for any floating-point operations; it applies only to integer
semantics).
For floating-point, GNAT has the @code{Machine_Overflows}
attribute set to @code{False} and the normal mode of operation is to
generate IEEE NaN and infinite values on overflow or invalid operations
(such as dividing 0.0 by 0.0).

The reason that we distinguish overflow checking from other kinds of
range constraint checking is that a failure of an overflow check can
generate an incorrect value, but cannot cause erroneous behavior. This
is unlike the situation with a constraint check on an array subscript,
where failure to perform the check can result in random memory description,
or the range check on a case statement, where failure to perform the check
can cause a wild jump.

Note again that @option{-gnato} is off by default, so overflow checking is
not performed in default mode. This means that out of the box, with the
default settings, GNAT does not do all the checks expected from the
language description in the Ada Reference Manual. If you want all constraint
checks to be performed, as described in this Manual, then you must
explicitly use the -gnato switch either on the @code{gnatmake} or
@code{gcc} command.

@item -gnatE
@cindex @option{-gnatE} (@code{gcc})
@cindex Elaboration checks
@cindex Check, elaboration
Enables dynamic checks for access-before-elaboration
on subprogram calls and generic instantiations.
For full details of the effect and use of this switch,
@xref{Compiling Using gcc}.
@end table

@findex Unsuppress
@noindent
The setting of these switches only controls the default setting of the
checks. You may modify them using either @code{Suppress} (to remove
checks) or @code{Unsuppress} (to add back suppressed checks) pragmas in
the program source.

@node Stack Overflow Checking
@subsection Stack Overflow Checking
@cindex Stack Overflow Checking
@cindex -fstack-check

@noindent
For most operating systems, @code{gcc} does not perform stack overflow
checking by default. This means that if the main environment task or
some other task exceeds the available stack space, then unpredictable
behavior will occur.

To activate stack checking, compile all units with the gcc option
@code{-fstack-check}. For example:

@smallexample
gcc -c -fstack-check package1.adb
@end smallexample

@noindent
Units compiled with this option will generate extra instructions to check
that any use of the stack (for procedure calls or for declaring local
variables in declare blocks) do not exceed the available stack space.
If the space is exceeded, then a @code{Storage_Error} exception is raised.

For declared tasks, the stack size is always controlled by the size
given in an applicable @code{Storage_Size} pragma (or is set to
the default size if no pragma is used.

For the environment task, the stack size depends on
system defaults and is unknown to the compiler. The stack
may even dynamically grow on some systems, precluding the
normal Ada semantics for stack overflow. In the worst case,
unbounded stack usage, causes unbounded stack expansion
resulting in the system running out of virtual memory.

The stack checking may still work correctly if a fixed
size stack is allocated, but this cannot be guaranteed.
To ensure that a clean exception is signalled for stack
overflow, set the environment variable
@code{GNAT_STACK_LIMIT} to indicate the maximum
stack area that can be used, as in:
@cindex GNAT_STACK_LIMIT

@smallexample
SET GNAT_STACK_LIMIT 1600
@end smallexample

@noindent
The limit is given in kilobytes, so the above declaration would
set the stack limit of the environment task to 1.6 megabytes.
Note that the only purpose of this usage is to limit the amount
of stack used by the environment task. If it is necessary to
increase the amount of stack for the environment task, then this
is an operating systems issue, and must be addressed with the
appropriate operating systems commands.

@node Run-Time Control
@subsection Run-Time Control

@table @code
@item -gnatT nnn
@cindex @option{-gnatT} (@code{gcc})
@cindex Time Slicing

@noindent
The @code{gnatT} switch can be used to specify the time-slicing value
to be used for task switching between equal priority tasks. The value
@code{nnn} is given in microseconds as a decimal integer.

Setting the time-slicing value is only effective if the underlying thread
control system can accommodate time slicing. Check the documentation of
your operating system for details. Note that the time-slicing value can
also be set by use of pragma @code{Time_Slice} or by use of the
@code{t} switch in the gnatbind step. The pragma overrides a command
line argument if both are present, and the @code{t} switch for gnatbind
overrides both the pragma and the @code{gcc} command line switch.
@end table

@node Using gcc for Syntax Checking
@subsection Using @code{gcc} for Syntax Checking
@table @code
@item -gnats
@cindex @option{-gnats} (@code{gcc})
@ifclear vms

@noindent
The @code{s} stands for syntax.
@end ifclear

Run GNAT in syntax checking only mode. For
example, the command

@smallexample
$ gcc -c -gnats x.adb
@end smallexample

@noindent
compiles file @file{x.adb} in syntax-check-only mode. You can check a
series of files in a single command
@ifclear vms
, and can use wild cards to specify such a group of files.
Note that you must specify the @code{-c} (compile
only) flag in addition to the @option{-gnats} flag.
@end ifclear
.

You may use other switches in conjunction with @option{-gnats}. In
particular, @option{-gnatl} and @option{-gnatv} are useful to control the
format of any generated error messages.

The output is simply the error messages, if any. No object file or ALI
file is generated by a syntax-only compilation. Also, no units other
than the one specified are accessed. For example, if a unit @code{X}
@code{with}'s a unit @code{Y}, compiling unit @code{X} in syntax
check only mode does not access the source file containing unit
@code{Y}.

@cindex Multiple units, syntax checking
Normally, GNAT allows only a single unit in a source file. However, this
restriction does not apply in syntax-check-only mode, and it is possible
to check a file containing multiple compilation units concatenated
together. This is primarily used by the @code{gnatchop} utility
(@pxref{Renaming Files Using gnatchop}).
@end table

@node Using gcc for Semantic Checking
@subsection Using @code{gcc} for Semantic Checking
@table @code
@item -gnatc
@cindex @option{-gnatc} (@code{gcc})

@ifclear vms
@noindent
The @code{c} stands for check.
@end ifclear
Causes the compiler to operate in semantic check mode,
with full checking for all illegalities specified in the
Ada 95 Reference Manual, but without generation of any object code
(no object file is generated).

Because dependent files must be accessed, you must follow the GNAT
semantic restrictions on file structuring to operate in this mode:

@itemize @bullet
@item
The needed source files must be accessible
(@pxref{Search Paths and the Run-Time Library (RTL)}).

@item
Each file must contain only one compilation unit.

@item
The file name and unit name must match (@pxref{File Naming Rules}).
@end itemize

The output consists of error messages as appropriate. No object file is
generated. An @file{ALI} file is generated for use in the context of
cross-reference tools, but this file is marked as not being suitable
for binding (since no object file is generated).
The checking corresponds exactly to the notion of
legality in the Ada 95 Reference Manual.

Any unit can be compiled in semantics-checking-only mode, including
units that would not normally be compiled (subunits,
and specifications where a separate body is present).
@end table

@node Compiling Ada 83 Programs
@subsection Compiling Ada 83 Programs
@table @code
@cindex Ada 83 compatibility
@item -gnat83
@cindex @option{-gnat83} (@code{gcc})
@cindex ACVC, Ada 83 tests

@noindent
Although GNAT is primarily an Ada 95 compiler, it accepts this switch to
specify that an Ada 83 program is to be compiled in Ada83 mode. If you specify
this switch, GNAT rejects most Ada 95 extensions and applies Ada 83 semantics
where this can be done easily.
It is not possible to guarantee this switch does a perfect
job; for example, some subtle tests, such as are
found in earlier ACVC tests (that have been removed from the ACVC suite for Ada
95), may not compile correctly. However, for most purposes, using
this switch should help to ensure that programs that compile correctly
under the @option{-gnat83} switch can be ported easily to an Ada 83
compiler. This is the main use of the switch.

With few exceptions (most notably the need to use @code{<>} on
@cindex Generic formal parameters
unconstrained generic formal parameters, the use of the new Ada 95
keywords, and the use of packages
with optional bodies), it is not necessary to use the
@option{-gnat83} switch when compiling Ada 83 programs, because, with rare
exceptions, Ada 95 is upwardly compatible with Ada 83. This
means that a correct Ada 83 program is usually also a correct Ada 95
program.

@end table

@node Character Set Control
@subsection Character Set Control
@table @code
@item ^-gnati^/IDENTIFIER_CHARACTER_SET=^@var{c}
@cindex @code{^-gnati^/IDENTIFIER_CHARACTER_SET^} (@code{gcc})

@noindent
Normally GNAT recognizes the Latin-1 character set in source program
identifiers, as described in the Ada 95 Reference Manual.
This switch causes
GNAT to recognize alternate character sets in identifiers. @var{c} is a
single character ^^or word^ indicating the character set, as follows:

@table @code
@item 1
Latin-1 identifiers

@item 2
Latin-2 letters allowed in identifiers

@item 3
Latin-3 letters allowed in identifiers

@item 4
Latin-4 letters allowed in identifiers

@item 5
Latin-5 (Cyrillic) letters allowed in identifiers

@item 9
Latin-9 letters allowed in identifiers

@item ^p^PC^
IBM PC letters (code page 437) allowed in identifiers

@item ^8^PC850^
IBM PC letters (code page 850) allowed in identifiers

@item ^f^FULL_UPPER^
Full upper-half codes allowed in identifiers

@item ^n^NO_UPPER^
No upper-half codes allowed in identifiers

@item ^w^WIDE^
Wide-character codes (that is, codes greater than 255)
allowed in identifiers
@end table

@xref{Foreign Language Representation}, for full details on the
implementation of these character sets.

@item ^-gnatW^/WIDE_CHARACTER_ENCODING=^@var{e}
@cindex @code{^-gnatW^/WIDE_CHARACTER_ENCODING^} (@code{gcc})
Specify the method of encoding for wide characters.
@var{e} is one of the following:

@table @code

@item ^h^HEX^
Hex encoding (brackets coding also recognized)

@item ^u^UPPER^
Upper half encoding (brackets encoding also recognized)

@item ^s^SHIFT_JIS^
Shift/JIS encoding (brackets encoding also recognized)

@item ^e^EUC^
EUC encoding (brackets encoding also recognized)

@item ^8^UTF8^
UTF-8 encoding (brackets encoding also recognized)

@item ^b^BRACKETS^
Brackets encoding only (default value)
@end table
For full details on the these encoding
methods see @xref{Wide Character Encodings}.
Note that brackets coding is always accepted, even if one of the other
options is specified, so for example @option{-gnatW8} specifies that both
brackets and @code{UTF-8} encodings will be recognized. The units that are
with'ed directly or indirectly will be scanned using the specified
representation scheme, and so if one of the non-brackets scheme is
used, it must be used consistently throughout the program. However,
since brackets encoding is always recognized, it may be conveniently
used in standard libraries, allowing these libraries to be used with
any of the available coding schemes.
scheme. If no @option{-gnatW?} parameter is present, then the default
representation is Brackets encoding only.

Note that the wide character representation that is specified (explicitly
or by default) for the main program also acts as the default encoding used
for Wide_Text_IO files if not specifically overridden by a WCEM form
parameter.

@end table
@node File Naming Control
@subsection File Naming Control

@table @code
@item ^-gnatk^/FILE_NAME_MAX_LENGTH=^@var{n}
@cindex @option{-gnatk} (@code{gcc})
Activates file name "krunching". @var{n}, a decimal integer in the range
1-999, indicates the maximum allowable length of a file name (not
including the @file{.ads} or @file{.adb} extension). The default is not
to enable file name krunching.

For the source file naming rules, @xref{File Naming Rules}.
@end table

@node Subprogram Inlining Control
@subsection Subprogram Inlining Control

@table @code
@item -gnatn
@cindex @option{-gnatn} (@code{gcc})
@ifclear vms
The @code{n} here is intended to suggest the first syllable of the
word "inline".
@end ifclear
GNAT recognizes and processes @code{Inline} pragmas. However, for the
inlining to actually occur, optimization must be enabled. To enable
inlining across unit boundaries, this is, inlining a call in one unit of
a subprogram declared in a @code{with}'ed unit, you must also specify
this switch.
In the absence of this switch, GNAT does not attempt
inlining across units and does not need to access the bodies of
subprograms for which @code{pragma Inline} is specified if they are not
in the current unit.

If you specify this switch the compiler will access these bodies,
creating an extra source dependency for the resulting object file, and
where possible, the call will be inlined.
For further details on when inlining is possible
see @xref{Inlining of Subprograms}.

@item -gnatN
@cindex @option{-gnatN} (@code{gcc})
The front end inlining activated by this switch is generally more extensive,
and quite often more effective than the standard @option{-gnatn} inlining mode.
It will also generate additional dependencies.

@end table

@node Auxiliary Output Control
@subsection Auxiliary Output Control

@table @code
@item -gnatt
@cindex @option{-gnatt} (@code{gcc})
@cindex Writing internal trees
@cindex Internal trees, writing to file
Causes GNAT to write the internal tree for a unit to a file (with the
extension @file{.adt}.
This not normally required, but is used by separate analysis tools.
Typically
these tools do the necessary compilations automatically, so you should
not have to specify this switch in normal operation.

@item -gnatu
@cindex @option{-gnatu} (@code{gcc})
Print a list of units required by this compilation on @file{stdout}.
The listing includes all units on which the unit being compiled depends
either directly or indirectly.

@ifclear vms
@item -pass-exit-codes
@cindex @code{-pass-exit-codes} (@code{gcc})
If this switch is not used, the exit code returned by @code{gcc} when
compiling multiple files indicates whether all source files have
been successfully used to generate object files or not.

When @code{-pass-exit-codes} is used, @code{gcc} exits with an extended
exit status and allows an integrated development environment to better
react to a compilation failure. Those exit status are:

@table @asis
@item 5
There was an error in at least one source file.
@item 3
At least one source file did not generate an object file.
@item 2
The compiler died unexpectedly (internal error for example).
@item 0
An object file has been generated for every source file.
@end table
@end ifclear
@end table

@node Debugging Control
@subsection Debugging Control

@table @code
@cindex Debugging options
@ifclear vms
@item -gnatd@var{x}
Activate internal debugging switches. @var{x} is a letter or digit, or
string of letters or digits, which specifies the type of debugging
outputs desired. Normally these are used only for internal development
or system debugging purposes. You can find full documentation for these
switches in the body of the @code{Debug} unit in the compiler source
file @file{debug.adb}.
@end ifclear

@item -gnatG
@cindex @option{-gnatG} (@code{gcc})
This switch causes the compiler to generate auxiliary output containing
a pseudo-source listing of the generated expanded code. Like most Ada
compilers, GNAT works by first transforming the high level Ada code into
lower level constructs. For example, tasking operations are transformed
into calls to the tasking run-time routines. A unique capability of GNAT
is to list this expanded code in a form very close to normal Ada source.
This is very useful in understanding the implications of various Ada
usage on the efficiency of the generated code. There are many cases in
Ada (e.g. the use of controlled types), where simple Ada statements can
generate a lot of run-time code. By using @option{-gnatG} you can identify
these cases, and consider whether it may be desirable to modify the coding
approach to improve efficiency.

The format of the output is very similar to standard Ada source, and is
easily understood by an Ada programmer. The following special syntactic
additions correspond to low level features used in the generated code that
do not have any exact analogies in pure Ada source form. The following
is a partial list of these special constructions. See the specification
of package @code{Sprint} in file @file{sprint.ads} for a full list.

@table @code
@item new @var{xxx} [storage_pool = @var{yyy}]
Shows the storage pool being used for an allocator.

@item at end @var{procedure-name};
Shows the finalization (cleanup) procedure for a scope.

@item (if @var{expr} then @var{expr} else @var{expr})
Conditional expression equivalent to the @code{x?y:z} construction in C.

@item @var{target}^^^(@var{source})
A conversion with floating-point truncation instead of rounding.

@item @var{target}?(@var{source})
A conversion that bypasses normal Ada semantic checking. In particular
enumeration types and fixed-point types are treated simply as integers.

@item @var{target}?^^^(@var{source})
Combines the above two cases.

@item @var{x} #/ @var{y}
@itemx @var{x} #mod @var{y}
@itemx @var{x} #* @var{y}
@itemx @var{x} #rem @var{y}
A division or multiplication of fixed-point values which are treated as
integers without any kind of scaling.

@item free @var{expr} [storage_pool = @var{xxx}]
Shows the storage pool associated with a @code{free} statement.

@item freeze @var{typename} [@var{actions}]
Shows the point at which @var{typename} is frozen, with possible
associated actions to be performed at the freeze point.

@item reference @var{itype}
Reference (and hence definition) to internal type @var{itype}.

@item @var{function-name}! (@var{arg}, @var{arg}, @var{arg})
Intrinsic function call.

@item @var{labelname} : label
Declaration of label @var{labelname}.

@item @var{expr} && @var{expr} && @var{expr} ... && @var{expr}
A multiple concatenation (same effect as @var{expr} & @var{expr} &
@var{expr}, but handled more efficiently).

@item [constraint_error]
Raise the @code{Constraint_Error} exception.

@item @var{expression}'reference
A pointer to the result of evaluating @var{expression}.

@item @var{target-type}!(@var{source-expression})
An unchecked conversion of @var{source-expression} to @var{target-type}.

@item [@var{numerator}/@var{denominator}]
Used to represent internal real literals (that) have no exact
representation in base 2-16 (for example, the result of compile time
evaluation of the expression 1.0/27.0).

@item -gnatD
@cindex @option{-gnatD} (@code{gcc})
This switch is used in conjunction with @option{-gnatG} to cause the expanded
source, as described above to be written to files with names
@file{^xxx.dg^XXX_DG^}, where @file{xxx} is the normal file name,
for example, if the source file name is @file{hello.adb},
then a file @file{^hello.adb.dg^HELLO.ADB_DG^} will be written.
The debugging information generated
by the @code{gcc} @code{^-g^/DEBUG^} switch will refer to the generated
@file{^xxx.dg^XXX_DG^} file. This allows you to do source level debugging using
the generated code which is sometimes useful for complex code, for example
to find out exactly which part of a complex construction raised an
exception. This switch also suppress generation of cross-reference
information (see -gnatx).

@item -gnatC
@cindex @option{-gnatE} (@code{gcc})
In the generated debugging information, and also in the case of long external
names, the compiler uses a compression mechanism if the name is very long.
This compression method uses a checksum, and avoids trouble on some operating
systems which have difficulty with very long names. The @option{-gnatC} switch
forces this compression approach to be used on all external names and names
in the debugging information tables. This reduces the size of the generated
executable, at the expense of making the naming scheme more complex. The
compression only affects the qualification of the name. Thus a name in
the source:

@smallexample
Very_Long_Package.Very_Long_Inner_Package.Var
@end smallexample

@noindent
would normally appear in these tables as:

@smallexample
very_long_package__very_long_inner_package__var
@end smallexample

@noindent
but if the @option{-gnatC} switch is used, then the name appears as

@smallexample
XCb7e0c705__var
@end smallexample

@noindent
Here b7e0c705 is a compressed encoding of the qualification prefix.
The GNAT Ada aware version of GDB understands these encoded prefixes, so if this
debugger is used, the encoding is largely hidden from the user of the compiler.

@end table

@item -gnatR[0|1|2|3][s]
@cindex @option{-gnatR} (@code{gcc})
This switch controls output from the compiler of a listing showing
representation information for declared types and objects. For
@option{-gnatR0}, no information is output (equivalent to omitting
the @option{-gnatR} switch). For @option{-gnatR1} (which is the default,
so @option{-gnatR} with no parameter has the same effect), size and alignment
information is listed for declared array and record types. For
@option{-gnatR2}, size and alignment information is listed for all
expression information for values that are computed at run time for
variant records. These symbolic expressions have a mostly obvious
format with #n being used to represent the value of the n'th
discriminant. See source files @file{repinfo.ads/adb} in the
@code{GNAT} sources for full detalis on the format of @option{-gnatR3}
output. If the switch is followed by an s (e.g. @option{-gnatR2s}), then
the output is to a file with the name @file{^file.rep^file_REP^} where
file is the name of the corresponding source file.

@item -gnatx
@cindex @option{-gnatx} (@code{gcc})
Normally the compiler generates full cross-referencing information in
the @file{ALI} file. This information is used by a number of tools,
including @code{gnatfind} and @code{gnatxref}. The -gnatx switch
suppresses this information. This saves some space and may slightly
speed up compilation, but means that these tools cannot be used.
@end table

@node Units to Sources Mapping Files
@subsection Units to Sources Mapping Files

@table @code

@item -gnatem@var{path}
@cindex @option{-gnatem} (@code{gcc})
A mapping file is a way to communicate to the compiler two mappings:
from unit names to file names (without any directory information) and from
file names to path names (with full directory information). These mappings
are used by the compiler to short-circuit the path search.

A mapping file is a sequence of sets of three lines. In each set,
the first line is the unit name, in lower case, with "%s" appended for
specifications and "%b" appended for bodies; the second line is the file
name; and the third line is the path name.

Example:
@smallexample
   main%b
   main.2.ada
   /gnat/project1/sources/main.2.ada
@end smallexample

When the switch @option{-gnatem} is specified, the compiler will create
in memory the two mappings from the specified file. If there is any problem
(non existent file, truncated file or duplicate entries), no mapping
will be created.

Several @option{-gnatem} switches may be specified; however, only the last
one on the command line will be taken into account.

When using a project file, @code{gnatmake} create a temporary mapping file
and communicates it to the compiler using this switch.

@end table

@node Search Paths and the Run-Time Library (RTL)
@section Search Paths and the Run-Time Library (RTL)

@noindent
With the GNAT source-based library system, the compiler must be able to
find source files for units that are needed by the unit being compiled.
Search paths are used to guide this process.

The compiler compiles one source file whose name must be given
explicitly on the command line. In other words, no searching is done
for this file. To find all other source files that are needed (the most
common being the specs of units), the compiler examines the following
directories, in the following order:

@enumerate
@item
The directory containing the source file of the main unit being compiled
(the file name on the command line).

@item
Each directory named by an @code{^-I^/SOURCE_SEARCH^} switch given on the @code{gcc}
command line, in the order given.

@item
@findex ADA_INCLUDE_PATH
Each of the directories listed in the value of the
@code{ADA_INCLUDE_PATH} ^environment variable^logical name^.
@ifclear vms
Construct this value
exactly as the @code{PATH} environment variable: a list of directory
names separated by colons (semicolons when working with the NT version).
@end ifclear
@ifset vms
Normally, define this value as a logical name containing a comma separated
list of directory names.

This variable can also be defined by means of an environment string
(an argument to the DEC C exec* set of functions).

Logical Name:
@smallexample
DEFINE ANOTHER_PATH FOO:[BAG]
DEFINE ADA_INCLUDE_PATH ANOTHER_PATH,FOO:[BAM],FOO:[BAR]
@end smallexample

By default, the path includes GNU:[LIB.OPENVMS7_x.2_8_x.DECLIB]
first, followed by the standard Ada 95
libraries in GNU:[LIB.OPENVMS7_x.2_8_x.ADAINCLUDE].
If this is not redefined, the user will obtain the DEC Ada83 IO packages
(Text_IO, Sequential_IO, etc)
instead of the Ada95 packages. Thus, in order to get the Ada 95
packages by default, ADA_INCLUDE_PATH must be redefined.
@end ifset
@item
The content of the "ada_source_path" file which is part of the GNAT
installation tree and is used to store standard libraries such as the
GNAT Run Time Library (RTL) source files.
@ifclear vms
@ref{Installing an Ada Library}
@end ifclear
@end enumerate

@noindent
Specifying the switch @code{^-I-^/NOCURRENT_DIRECTORY^}
inhibits the use of the directory
containing the source file named in the command line. You can still
have this directory on your search path, but in this case it must be
explicitly requested with a @code{^-I^/SOURCE_SEARCH^} switch.

Specifying the switch @code{-nostdinc}
inhibits the search of the default location for the GNAT Run Time
Library (RTL) source files.

The compiler outputs its object files and ALI files in the current
working directory.
@ifclear vms
Caution: The object file can be redirected with the @code{-o} switch;
however, @code{gcc} and @code{gnat1} have not been coordinated on this
so the ALI file will not go to the right place. Therefore, you should
avoid using the @code{-o} switch.
@end ifclear

@findex System.IO
The packages @code{Ada}, @code{System}, and @code{Interfaces} and their
children make up the GNAT RTL, together with the simple @code{System.IO}
package used in the "Hello World" example. The sources for these units
are needed by the compiler and are kept together in one directory. Not
all of the bodies are needed, but all of the sources are kept together
anyway. In a normal installation, you need not specify these directory
names when compiling or binding. Either the environment variables or
the built-in defaults cause these files to be found.

In addition to the language-defined hierarchies (System, Ada and
Interfaces), the GNAT distribution provides a fourth hierarchy,
consisting of child units of GNAT. This is a collection of generally
useful routines. See the GNAT Reference Manual for further details.

Besides simplifying access to the RTL, a major use of search paths is
in compiling sources from multiple directories. This can make
development environments much more flexible.

@node Order of Compilation Issues
@section Order of Compilation Issues

@noindent
If, in our earlier example, there was a spec for the @code{hello}
procedure, it would be contained in the file @file{hello.ads}; yet this
file would not have to be explicitly compiled. This is the result of the
model we chose to implement library management. Some of the consequences
of this model are as follows:

@itemize @bullet
@item
There is no point in compiling specs (except for package
specs with no bodies) because these are compiled as needed by clients. If
you attempt a useless compilation, you will receive an error message.
It is also useless to compile subunits because they are compiled as needed
by the parent.

@item
There are no order of compilation requirements: performing a
compilation never obsoletes anything. The only way you can obsolete
something and require recompilations is to modify one of the
source files on which it depends.

@item
There is no library as such, apart from the ALI files
(@pxref{The Ada Library Information Files}, for information on the format of these
files). For now we find it convenient to create separate ALI files, but
eventually the information therein may be incorporated into the object
file directly.

@item
When you compile a unit, the source files for the specs of all units
that it @code{with}'s, all its subunits, and the bodies of any generics it
instantiates must be available (reachable by the search-paths mechanism
described above), or you will receive a fatal error message.
@end itemize

@node Examples
@section Examples

@noindent
The following are some typical Ada compilation command line examples:

@table @code
@item $ gcc -c xyz.adb
Compile body in file @file{xyz.adb} with all default options.

@ifclear vms
@item $ gcc -c -O2 -gnata xyz-def.adb
@end ifclear
@ifset vms
@item $ GNAT COMPILE /OPTIMIZE=ALL -gnata xyz-def.adb
@end ifset

Compile the child unit package in file @file{xyz-def.adb} with extensive
optimizations, and pragma @code{Assert}/@code{Debug} statements
enabled.

@item $ gcc -c -gnatc abc-def.adb
Compile the subunit in file @file{abc-def.adb} in semantic-checking-only
mode.
@end table

@node Binding Using gnatbind
@chapter Binding Using @code{gnatbind}
@findex gnatbind

@menu
* Running gnatbind::
* Generating the Binder Program in C::
* Consistency-Checking Modes::
* Binder Error Message Control::
* Elaboration Control::
* Output Control::
* Binding with Non-Ada Main Programs::
* Binding Programs with No Main Subprogram::
* Summary of Binder Switches::
* Command-Line Access::
* Search Paths for gnatbind::
* Examples of gnatbind Usage::
@end menu

@noindent
This chapter describes the GNAT binder, @code{gnatbind}, which is used
to bind compiled GNAT objects. The @code{gnatbind} program performs
four separate functions:

@enumerate
@item
Checks that a program is consistent, in accordance with the rules in
Chapter 10 of the Ada 95 Reference Manual. In particular, error
messages are generated if a program uses inconsistent versions of a
given unit.

@item
Checks that an acceptable order of elaboration exists for the program
and issues an error message if it cannot find an order of elaboration
that satisfies the rules in Chapter 10 of the Ada 95 Language Manual.

@item
Generates a main program incorporating the given elaboration order.
This program is a small Ada package (body and spec) that
must be subsequently compiled
using the GNAT compiler. The necessary compilation step is usually
performed automatically by @code{gnatlink}. The two most important
functions of this program
are to call the elaboration routines of units in an appropriate order
and to call the main program.

@item
Determines the set of object files required by the given main program.
This information is output in the forms of comments in the generated program,
to be read by the @code{gnatlink} utility used to link the Ada application.
@end enumerate

@node Running gnatbind
@section Running @code{gnatbind}

@noindent
The form of the @code{gnatbind} command is

@smallexample
$ gnatbind [@var{switches}] @var{mainprog}[.ali] [@var{switches}]
@end smallexample

@noindent
where @var{mainprog}.adb is the Ada file containing the main program
unit body. If no switches are specified, @code{gnatbind} constructs an Ada
package in two files which names are
@file{b~@var{ada_main}.ads}, and @file{b~@var{ada_main}.adb}.
For example, if given the
parameter @samp{hello.ali}, for a main program contained in file
@file{hello.adb}, the binder output files would be @file{b~hello.ads}
and @file{b~hello.adb}.

When doing consistency checking, the binder takes into consideration
any source files it can locate. For example, if the binder determines
that the given main program requires the package @code{Pack}, whose
@file{.ali}
file is @file{pack.ali} and whose corresponding source spec file is
@file{pack.ads}, it attempts to locate the source file @file{pack.ads}
(using the same search path conventions as previously described for the
@code{gcc} command). If it can locate this source file, it checks that
the time stamps
or source checksums of the source and its references to in @file{ali} files
match. In other words, any @file{ali} files that mentions this spec must have
resulted from compiling this version of the source file (or in the case
where the source checksums match, a version close enough that the
difference does not matter).

@cindex Source files, use by binder
The effect of this consistency checking, which includes source files, is
that the binder ensures that the program is consistent with the latest
version of the source files that can be located at bind time. Editing a
source file without compiling files that depend on the source file cause
error messages to be generated by the binder.

For example, suppose you have a main program @file{hello.adb} and a
package @code{P}, from file @file{p.ads} and you perform the following
steps:

@enumerate
@item
Enter @code{gcc -c hello.adb} to compile the main program.

@item
Enter @code{gcc -c p.ads} to compile package @code{P}.

@item
Edit file @file{p.ads}.

@item
Enter @code{gnatbind hello}.
@end enumerate

At this point, the file @file{p.ali} contains an out-of-date time stamp
because the file @file{p.ads} has been edited. The attempt at binding
fails, and the binder generates the following error messages:

@smallexample
error: "hello.adb" must be recompiled ("p.ads" has been modified)
error: "p.ads" has been modified and must be recompiled
@end smallexample

@noindent
Now both files must be recompiled as indicated, and then the bind can
succeed, generating a main program. You need not normally be concerned
with the contents of this file, but it is similar to the following which
is the binder file generated for a simple "hello world" program.

@smallexample
@iftex
@leftskip=0cm
@end iftex
--  The package is called Ada_Main unless this name is actually used
--  as a unit name in the partition, in which case some other unique
--  name is used.

with System;
package ada_main is

   Elab_Final_Code : Integer;
   pragma Import (C, Elab_Final_Code, "__gnat_inside_elab_final_code");

   --  The main program saves the parameters (argument count,
   --  argument values, environment pointer) in global variables
   --  for later access by other units including
   --  Ada.Command_Line.

   gnat_argc : Integer;
   gnat_argv : System.Address;
   gnat_envp : System.Address;

   --  The actual variables are stored in a library routine. This
   --  is useful for some shared library situations, where there
   --  are problems if variables are not in the library.

   pragma Import (C, gnat_argc);
   pragma Import (C, gnat_argv);
   pragma Import (C, gnat_envp);

   --  The exit status is similarly an external location

   gnat_exit_status : Integer;
   pragma Import (C, gnat_exit_status);

   GNAT_Version : constant String :=
                    "GNAT Version: 3.15w (20010315)";
   pragma Export (C, GNAT_Version, "__gnat_version");

   --  This is the generated adafinal routine that performs
   --  finalization at the end of execution. In the case where
   --  Ada is the main program, this main program makes a call
   --  to adafinal at program termination.

   procedure adafinal;
   pragma Export (C, adafinal, "adafinal");

   --  This is the generated adainit routine that performs
   --  initialization at the start of execution. In the case
   --  where Ada is the main program, this main program makes
   --  a call to adainit at program startup.

   procedure adainit;
   pragma Export (C, adainit, "adainit");

   --  This routine is called at the start of execution. It is
   --  a dummy routine that is used by the debugger to breakpoint
   --  at the start of execution.

   procedure Break_Start;
   pragma Import (C, Break_Start, "__gnat_break_start");

   --  This is the actual generated main program (it would be
   --  suppressed if the no main program switch were used). As
   --  required by standard system conventions, this program has
   --  the external name main.

   function main
     (argc : Integer;
      argv : System.Address;
      envp : System.Address)
      return Integer;
   pragma Export (C, main, "main");

   --  The following set of constants give the version
   --  identification values for every unit in the bound
   --  partition. This identification is computed from all
   --  dependent semantic units, and corresponds to the
   --  string that would be returned by use of the
   --  Body_Version or Version attributes.

   type Version_32 is mod 2 ** 32;
   u00001 : constant Version_32 := 16#7880BEB3#;
   u00002 : constant Version_32 := 16#0D24CBD0#;
   u00003 : constant Version_32 := 16#3283DBEB#;
   u00004 : constant Version_32 := 16#2359F9ED#;
   u00005 : constant Version_32 := 16#664FB847#;
   u00006 : constant Version_32 := 16#68E803DF#;
   u00007 : constant Version_32 := 16#5572E604#;
   u00008 : constant Version_32 := 16#46B173D8#;
   u00009 : constant Version_32 := 16#156A40CF#;
   u00010 : constant Version_32 := 16#033DABE0#;
   u00011 : constant Version_32 := 16#6AB38FEA#;
   u00012 : constant Version_32 := 16#22B6217D#;
   u00013 : constant Version_32 := 16#68A22947#;
   u00014 : constant Version_32 := 16#18CC4A56#;
   u00015 : constant Version_32 := 16#08258E1B#;
   u00016 : constant Version_32 := 16#367D5222#;
   u00017 : constant Version_32 := 16#20C9ECA4#;
   u00018 : constant Version_32 := 16#50D32CB6#;
   u00019 : constant Version_32 := 16#39A8BB77#;
   u00020 : constant Version_32 := 16#5CF8FA2B#;
   u00021 : constant Version_32 := 16#2F1EB794#;
   u00022 : constant Version_32 := 16#31AB6444#;
   u00023 : constant Version_32 := 16#1574B6E9#;
   u00024 : constant Version_32 := 16#5109C189#;
   u00025 : constant Version_32 := 16#56D770CD#;
   u00026 : constant Version_32 := 16#02F9DE3D#;
   u00027 : constant Version_32 := 16#08AB6B2C#;
   u00028 : constant Version_32 := 16#3FA37670#;
   u00029 : constant Version_32 := 16#476457A0#;
   u00030 : constant Version_32 := 16#731E1B6E#;
   u00031 : constant Version_32 := 16#23C2E789#;
   u00032 : constant Version_32 := 16#0F1BD6A1#;
   u00033 : constant Version_32 := 16#7C25DE96#;
   u00034 : constant Version_32 := 16#39ADFFA2#;
   u00035 : constant Version_32 := 16#571DE3E7#;
   u00036 : constant Version_32 := 16#5EB646AB#;
   u00037 : constant Version_32 := 16#4249379B#;
   u00038 : constant Version_32 := 16#0357E00A#;
   u00039 : constant Version_32 := 16#3784FB72#;
   u00040 : constant Version_32 := 16#2E723019#;
   u00041 : constant Version_32 := 16#623358EA#;
   u00042 : constant Version_32 := 16#107F9465#;
   u00043 : constant Version_32 := 16#6843F68A#;
   u00044 : constant Version_32 := 16#63305874#;
   u00045 : constant Version_32 := 16#31E56CE1#;
   u00046 : constant Version_32 := 16#02917970#;
   u00047 : constant Version_32 := 16#6CCBA70E#;
   u00048 : constant Version_32 := 16#41CD4204#;
   u00049 : constant Version_32 := 16#572E3F58#;
   u00050 : constant Version_32 := 16#20729FF5#;
   u00051 : constant Version_32 := 16#1D4F93E8#;
   u00052 : constant Version_32 := 16#30B2EC3D#;
   u00053 : constant Version_32 := 16#34054F96#;
   u00054 : constant Version_32 := 16#5A199860#;
   u00055 : constant Version_32 := 16#0E7F912B#;
   u00056 : constant Version_32 := 16#5760634A#;
   u00057 : constant Version_32 := 16#5D851835#;

   --  The following Export pragmas export the version numbers
   --  with symbolic names ending in B (for body) or S
   --  (for spec) so that they can be located in a link. The
   --  information provided here is sufficient to track down
   --  the exact versions of units used in a given build.

   pragma Export (C, u00001, "helloB");
   pragma Export (C, u00002, "system__standard_libraryB");
   pragma Export (C, u00003, "system__standard_libraryS");
   pragma Export (C, u00004, "adaS");
   pragma Export (C, u00005, "ada__text_ioB");
   pragma Export (C, u00006, "ada__text_ioS");
   pragma Export (C, u00007, "ada__exceptionsB");
   pragma Export (C, u00008, "ada__exceptionsS");
   pragma Export (C, u00009, "gnatS");
   pragma Export (C, u00010, "gnat__heap_sort_aB");
   pragma Export (C, u00011, "gnat__heap_sort_aS");
   pragma Export (C, u00012, "systemS");
   pragma Export (C, u00013, "system__exception_tableB");
   pragma Export (C, u00014, "system__exception_tableS");
   pragma Export (C, u00015, "gnat__htableB");
   pragma Export (C, u00016, "gnat__htableS");
   pragma Export (C, u00017, "system__exceptionsS");
   pragma Export (C, u00018, "system__machine_state_operationsB");
   pragma Export (C, u00019, "system__machine_state_operationsS");
   pragma Export (C, u00020, "system__machine_codeS");
   pragma Export (C, u00021, "system__storage_elementsB");
   pragma Export (C, u00022, "system__storage_elementsS");
   pragma Export (C, u00023, "system__secondary_stackB");
   pragma Export (C, u00024, "system__secondary_stackS");
   pragma Export (C, u00025, "system__parametersB");
   pragma Export (C, u00026, "system__parametersS");
   pragma Export (C, u00027, "system__soft_linksB");
   pragma Export (C, u00028, "system__soft_linksS");
   pragma Export (C, u00029, "system__stack_checkingB");
   pragma Export (C, u00030, "system__stack_checkingS");
   pragma Export (C, u00031, "system__tracebackB");
   pragma Export (C, u00032, "system__tracebackS");
   pragma Export (C, u00033, "ada__streamsS");
   pragma Export (C, u00034, "ada__tagsB");
   pragma Export (C, u00035, "ada__tagsS");
   pragma Export (C, u00036, "system__string_opsB");
   pragma Export (C, u00037, "system__string_opsS");
   pragma Export (C, u00038, "interfacesS");
   pragma Export (C, u00039, "interfaces__c_streamsB");
   pragma Export (C, u00040, "interfaces__c_streamsS");
   pragma Export (C, u00041, "system__file_ioB");
   pragma Export (C, u00042, "system__file_ioS");
   pragma Export (C, u00043, "ada__finalizationB");
   pragma Export (C, u00044, "ada__finalizationS");
   pragma Export (C, u00045, "system__finalization_rootB");
   pragma Export (C, u00046, "system__finalization_rootS");
   pragma Export (C, u00047, "system__finalization_implementationB");
   pragma Export (C, u00048, "system__finalization_implementationS");
   pragma Export (C, u00049, "system__string_ops_concat_3B");
   pragma Export (C, u00050, "system__string_ops_concat_3S");
   pragma Export (C, u00051, "system__stream_attributesB");
   pragma Export (C, u00052, "system__stream_attributesS");
   pragma Export (C, u00053, "ada__io_exceptionsS");
   pragma Export (C, u00054, "system__unsigned_typesS");
   pragma Export (C, u00055, "system__file_control_blockS");
   pragma Export (C, u00056, "ada__finalization__list_controllerB");
   pragma Export (C, u00057, "ada__finalization__list_controllerS");

   -- BEGIN ELABORATION ORDER
   -- ada (spec)
   -- gnat (spec)
   -- gnat.heap_sort_a (spec)
   -- gnat.heap_sort_a (body)
   -- gnat.htable (spec)
   -- gnat.htable (body)
   -- interfaces (spec)
   -- system (spec)
   -- system.machine_code (spec)
   -- system.parameters (spec)
   -- system.parameters (body)
   -- interfaces.c_streams (spec)
   -- interfaces.c_streams (body)
   -- system.standard_library (spec)
   -- ada.exceptions (spec)
   -- system.exception_table (spec)
   -- system.exception_table (body)
   -- ada.io_exceptions (spec)
   -- system.exceptions (spec)
   -- system.storage_elements (spec)
   -- system.storage_elements (body)
   -- system.machine_state_operations (spec)
   -- system.machine_state_operations (body)
   -- system.secondary_stack (spec)
   -- system.stack_checking (spec)
   -- system.soft_links (spec)
   -- system.soft_links (body)
   -- system.stack_checking (body)
   -- system.secondary_stack (body)
   -- system.standard_library (body)
   -- system.string_ops (spec)
   -- system.string_ops (body)
   -- ada.tags (spec)
   -- ada.tags (body)
   -- ada.streams (spec)
   -- system.finalization_root (spec)
   -- system.finalization_root (body)
   -- system.string_ops_concat_3 (spec)
   -- system.string_ops_concat_3 (body)
   -- system.traceback (spec)
   -- system.traceback (body)
   -- ada.exceptions (body)
   -- system.unsigned_types (spec)
   -- system.stream_attributes (spec)
   -- system.stream_attributes (body)
   -- system.finalization_implementation (spec)
   -- system.finalization_implementation (body)
   -- ada.finalization (spec)
   -- ada.finalization (body)
   -- ada.finalization.list_controller (spec)
   -- ada.finalization.list_controller (body)
   -- system.file_control_block (spec)
   -- system.file_io (spec)
   -- system.file_io (body)
   -- ada.text_io (spec)
   -- ada.text_io (body)
   -- hello (body)
   -- END ELABORATION ORDER

end ada_main;

--  The following source file name pragmas allow the generated file
--  names to be unique for different main programs. They are needed
--  since the package name will always be Ada_Main.

pragma Source_File_Name (ada_main, Spec_File_Name => "b~hello.ads");
pragma Source_File_Name (ada_main, Body_File_Name => "b~hello.adb");

--  Generated package body for Ada_Main starts here

package body ada_main is

   --  The actual finalization is performed by calling the
   --  library routine in System.Standard_Library.Adafinal

   procedure Do_Finalize;
   pragma Import (C, Do_Finalize, "system__standard_library__adafinal");

   -------------
   -- adainit --
   -------------

@findex adainit
   procedure adainit is

      --  These booleans are set to True once the associated unit has
      --  been elaborated. It is also used to avoid elaborating the
      --  same unit twice.

      E040 : Boolean; pragma Import (Ada, E040, "interfaces__c_streams_E");
      E008 : Boolean; pragma Import (Ada, E008, "ada__exceptions_E");
      E014 : Boolean; pragma Import (Ada, E014, "system__exception_table_E");
      E053 : Boolean; pragma Import (Ada, E053, "ada__io_exceptions_E");
      E017 : Boolean; pragma Import (Ada, E017, "system__exceptions_E");
      E024 : Boolean; pragma Import (Ada, E024, "system__secondary_stack_E");
      E030 : Boolean; pragma Import (Ada, E030, "system__stack_checking_E");
      E028 : Boolean; pragma Import (Ada, E028, "system__soft_links_E");
      E035 : Boolean; pragma Import (Ada, E035, "ada__tags_E");
      E033 : Boolean; pragma Import (Ada, E033, "ada__streams_E");
      E046 : Boolean; pragma Import (Ada, E046, "system__finalization_root_E");
      E048 : Boolean; pragma Import (Ada, E048, "system__finalization_implementation_E");
      E044 : Boolean; pragma Import (Ada, E044, "ada__finalization_E");
      E057 : Boolean; pragma Import (Ada, E057, "ada__finalization__list_controller_E");
      E055 : Boolean; pragma Import (Ada, E055, "system__file_control_block_E");
      E042 : Boolean; pragma Import (Ada, E042, "system__file_io_E");
      E006 : Boolean; pragma Import (Ada, E006, "ada__text_io_E");

      --  Set_Globals is a library routine that stores away the
      --  value of the indicated set of global values in global
      --  variables within the library.

      procedure Set_Globals
        (Main_Priority            : Integer;
         Time_Slice_Value         : Integer;
         WC_Encoding              : Character;
         Locking_Policy           : Character;
         Queuing_Policy           : Character;
         Task_Dispatching_Policy  : Character;
         Adafinal                 : System.Address;
         Unreserve_All_Interrupts : Integer;
         Exception_Tracebacks     : Integer);
@findex __gnat_set_globals
      pragma Import (C, Set_Globals, "__gnat_set_globals");

      --  SDP_Table_Build is a library routine used to build the
      --  exception tables. See unit Ada.Exceptions in files
      --  a-except.ads/adb for full details of how zero cost
      --  exception handling works. This procedure, the call to
      --  it, and the two following tables are all omitted if the
      --  build is in longjmp/setjump exception mode.

@findex SDP_Table_Build
@findex Zero Cost Exceptions
      procedure SDP_Table_Build
        (SDP_Addresses   : System.Address;
         SDP_Count       : Natural;
         Elab_Addresses  : System.Address;
         Elab_Addr_Count : Natural);
      pragma Import (C, SDP_Table_Build, "__gnat_SDP_Table_Build");

      --  Table of Unit_Exception_Table addresses. Used for zero
      --  cost exception handling to build the top level table.

      ST : aliased constant array (1 .. 23) of System.Address := (
        Hello'UET_Address,
        Ada.Text_Io'UET_Address,
        Ada.Exceptions'UET_Address,
        Gnat.Heap_Sort_A'UET_Address,
        System.Exception_Table'UET_Address,
        System.Machine_State_Operations'UET_Address,
        System.Secondary_Stack'UET_Address,
        System.Parameters'UET_Address,
        System.Soft_Links'UET_Address,
        System.Stack_Checking'UET_Address,
        System.Traceback'UET_Address,
        Ada.Streams'UET_Address,
        Ada.Tags'UET_Address,
        System.String_Ops'UET_Address,
        Interfaces.C_Streams'UET_Address,
        System.File_Io'UET_Address,
        Ada.Finalization'UET_Address,
        System.Finalization_Root'UET_Address,
        System.Finalization_Implementation'UET_Address,
        System.String_Ops_Concat_3'UET_Address,
        System.Stream_Attributes'UET_Address,
        System.File_Control_Block'UET_Address,
        Ada.Finalization.List_Controller'UET_Address);

      --  Table of addresses of elaboration routines. Used for
      --  zero cost exception handling to make sure these
      --  addresses are included in the top level procedure
      --  address table.

      EA : aliased constant array (1 .. 23) of System.Address := (
        adainit'Code_Address,
        Do_Finalize'Code_Address,
        Ada.Exceptions'Elab_Spec'Address,
        System.Exceptions'Elab_Spec'Address,
        Interfaces.C_Streams'Elab_Spec'Address,
        System.Exception_Table'Elab_Body'Address,
        Ada.Io_Exceptions'Elab_Spec'Address,
        System.Stack_Checking'Elab_Spec'Address,
        System.Soft_Links'Elab_Body'Address,
        System.Secondary_Stack'Elab_Body'Address,
        Ada.Tags'Elab_Spec'Address,
        Ada.Tags'Elab_Body'Address,
        Ada.Streams'Elab_Spec'Address,
        System.Finalization_Root'Elab_Spec'Address,
        Ada.Exceptions'Elab_Body'Address,
        System.Finalization_Implementation'Elab_Spec'Address,
        System.Finalization_Implementation'Elab_Body'Address,
        Ada.Finalization'Elab_Spec'Address,
        Ada.Finalization.List_Controller'Elab_Spec'Address,
        System.File_Control_Block'Elab_Spec'Address,
        System.File_Io'Elab_Body'Address,
        Ada.Text_Io'Elab_Spec'Address,
        Ada.Text_Io'Elab_Body'Address);

   --  Start of processing for adainit

   begin

      --  Call SDP_Table_Build to build the top level procedure
      --  table for zero cost exception handling (omitted in
      --  longjmp/setjump mode).

      SDP_Table_Build (ST'Address, 23, EA'Address, 23);

      --  Call Set_Globals to record various information for
      --  this partition.  The values are derived by the binder
      --  from information stored in the ali files by the compiler.

@findex __gnat_set_globals
      Set_Globals
        (Main_Priority            => -1,
         --  Priority of main program, -1 if no pragma Priority used

         Time_Slice_Value         => -1,
         --  Time slice from Time_Slice pragma, -1 if none used

         WC_Encoding              => 'b',
         --  Wide_Character encoding used, default is brackets

         Locking_Policy           => ' ',
         --  Locking_Policy used, default of space means not
         --  specified, otherwise it is the first character of
         --  the policy name.

         Queuing_Policy           => ' ',
         --  Queuing_Policy used, default of space means not
         --  specified, otherwise it is the first character of
         --  the policy name.

         Task_Dispatching_Policy  => ' ',
         --  Task_Dispatching_Policy used, default of space means
         --  not specified, otherwise first character of the
         --  policy name.

         Adafinal                 => System.Null_Address,
         --  Address of Adafinal routine, not used anymore

         Unreserve_All_Interrupts => 0,
         --  Set true if pragma Unreserve_All_Interrupts was used

         Exception_Tracebacks     => 0);
         --  Indicates if exception tracebacks are enabled

      Elab_Final_Code := 1;

      --  Now we have the elaboration calls for all units in the partition.
      --  The Elab_Spec and Elab_Body attributes generate references to the
      --  implicit elaboration procedures generated by the compiler for
      --  each unit that requires elaboration.

      if not E040 then
         Interfaces.C_Streams'Elab_Spec;
      end if;
      E040 := True;
      if not E008 then
         Ada.Exceptions'Elab_Spec;
      end if;
      if not E014 then
         System.Exception_Table'Elab_Body;
         E014 := True;
      end if;
      if not E053 then
         Ada.Io_Exceptions'Elab_Spec;
         E053 := True;
      end if;
      if not E017 then
         System.Exceptions'Elab_Spec;
         E017 := True;
      end if;
      if not E030 then
         System.Stack_Checking'Elab_Spec;
      end if;
      if not E028 then
         System.Soft_Links'Elab_Body;
         E028 := True;
      end if;
      E030 := True;
      if not E024 then
         System.Secondary_Stack'Elab_Body;
         E024 := True;
      end if;
      if not E035 then
         Ada.Tags'Elab_Spec;
      end if;
      if not E035 then
         Ada.Tags'Elab_Body;
         E035 := True;
      end if;
      if not E033 then
         Ada.Streams'Elab_Spec;
         E033 := True;
      end if;
      if not E046 then
         System.Finalization_Root'Elab_Spec;
      end if;
      E046 := True;
      if not E008 then
         Ada.Exceptions'Elab_Body;
         E008 := True;
      end if;
      if not E048 then
         System.Finalization_Implementation'Elab_Spec;
      end if;
      if not E048 then
         System.Finalization_Implementation'Elab_Body;
         E048 := True;
      end if;
      if not E044 then
         Ada.Finalization'Elab_Spec;
      end if;
      E044 := True;
      if not E057 then
         Ada.Finalization.List_Controller'Elab_Spec;
      end if;
      E057 := True;
      if not E055 then
         System.File_Control_Block'Elab_Spec;
         E055 := True;
      end if;
      if not E042 then
         System.File_Io'Elab_Body;
         E042 := True;
      end if;
      if not E006 then
         Ada.Text_Io'Elab_Spec;
      end if;
      if not E006 then
         Ada.Text_Io'Elab_Body;
         E006 := True;
      end if;

      Elab_Final_Code := 0;
   end adainit;

   --------------
   -- adafinal --
   --------------

@findex adafinal
   procedure adafinal is
   begin
      Do_Finalize;
   end adafinal;

   ----------
   -- main --
   ----------

   --  main is actually a function, as in the ANSI C standard,
   --  defined to return the exit status. The three parameters
   --  are the argument count, argument values and environment
   --  pointer.

@findex Main Program
   function main
     (argc : Integer;
      argv : System.Address;
      envp : System.Address)
      return Integer
   is
      --  The initialize routine performs low level system
      --  initialization using a standard library routine which
      --  sets up signal handling and performs any other
      --  required setup. The routine can be found in file
      --  a-init.c.

@findex __gnat_initialize
      procedure initialize;
      pragma Import (C, initialize, "__gnat_initialize");

      --  The finalize routine performs low level system
      --  finalization using a standard library routine. The
      --  routine is found in file a-final.c and in the standard
      --  distribution is a dummy routine that does nothing, so
      --  really this is a hook for special user finalization.

@findex __gnat_finalize
      procedure finalize;
      pragma Import (C, finalize, "__gnat_finalize");

      --  We get to the main program of the partition by using
      --  pragma Import because if we try to with the unit and
      --  call it Ada style, then not only do we waste time
      --  recompiling it, but also, we don't really know the right
      --  switches (e.g. identifier character set) to be used
      --  to compile it.

      procedure Ada_Main_Program;
      pragma Import (Ada, Ada_Main_Program, "_ada_hello");

   --  Start of processing for main

   begin
      --  Save global variables

      gnat_argc := argc;
      gnat_argv := argv;
      gnat_envp := envp;

      --  Call low level system initialization

      Initialize;

      --  Call our generated Ada initialization routine

      adainit;

      --  This is the point at which we want the debugger to get
      --  control

      Break_Start;

      --  Now we call the main program of the partition

      Ada_Main_Program;

      --  Perform Ada finalization

      adafinal;

      --  Perform low level system finalization

      Finalize;

      --  Return the proper exit status
      return (gnat_exit_status);
   end;

--  This section is entirely comments, so it has no effect on the
--  compilation of the Ada_Main package. It provides the list of
--  object files and linker options, as well as some standard
--  libraries needed for the link. The gnatlink utility parses
--  this b~hello.adb file to read these comment lines to generate
--  the appropriate command line arguments for the call to the
--  system linker. The BEGIN/END lines are used for sentinels for
--  this parsing operation.

--  The exact file names will of course depend on the environment,
--  host/target and location of files on the host system.

@findex Object file list
-- BEGIN Object file/option list
   --   ./hello.o
   --   -L./
   --   -L/usr/local/gnat/lib/gcc-lib/i686-pc-linux-gnu/2.8.1/adalib/
   --   /usr/local/gnat/lib/gcc-lib/i686-pc-linux-gnu/2.8.1/adalib/libgnat.a
-- END Object file/option list

end ada_main;

@end smallexample

@noindent
The Ada code in the above example is exactly what is generated by the
binder. We have added comments to more clearly indicate the function
of each part of the generated @code{Ada_Main} package.

The code is standard Ada in all respects, and can be processed by any
tools that handle Ada. In particular, it is possible to use the debugger
in Ada mode to debug the generated Ada_Main package. For example, suppose
that for reasons that you do not understand, your program is blowing up
during elaboration of the body of @code{Ada.Text_IO}. To chase this bug
down, you can place a breakpoint on the call:

@smallexample
Ada.Text_Io'Elab_Body;
@end smallexample

@noindent
and trace the elaboration routine for this package to find out where
the problem might be (more usually of course you would be debugging
elaboration code in your own application).

@node Generating the Binder Program in C
@section Generating the Binder Program in C
@noindent
In most normal usage, the default mode of @code{gnatbind} which is to
generate the main package in Ada, as described in the previous section.
In particular, this means that any Ada programmer can read and understand
the generated main program. It can also be debugged just like any other
Ada code provided the @code{-g} switch is used for @code{gnatbind}
and @code{gnatlink}.

However for some purposes it may be convenient to generate the main
program in C rather than Ada. This may for example be helpful when you
are generating a mixed language program with the main program in C. The
GNAT compiler itself is an example. The use of the @code{-C} switch
for both @code{gnatbind} and @code{gnatlink} will cause the program to
be generated in C (and compiled using the gnu C compiler). The
following shows the C code generated for the same "Hello World"
program:

@smallexample

#ifdef __STDC__
#define PARAMS(paramlist) paramlist
#else
#define PARAMS(paramlist) ()
#endif

extern void __gnat_set_globals
 PARAMS ((int, int, int, int, int, int,
          void (*) PARAMS ((void)), int, int));
extern void adafinal PARAMS ((void));
extern void adainit PARAMS ((void));
extern void system__standard_library__adafinal PARAMS ((void));
extern int main PARAMS ((int, char **, char **));
extern void exit PARAMS ((int));
extern void __gnat_break_start PARAMS ((void));
extern void _ada_hello PARAMS ((void));
extern void __gnat_initialize PARAMS ((void));
extern void __gnat_finalize PARAMS ((void));

extern void ada__exceptions___elabs PARAMS ((void));
extern void system__exceptions___elabs PARAMS ((void));
extern void interfaces__c_streams___elabs PARAMS ((void));
extern void system__exception_table___elabb PARAMS ((void));
extern void ada__io_exceptions___elabs PARAMS ((void));
extern void system__stack_checking___elabs PARAMS ((void));
extern void system__soft_links___elabb PARAMS ((void));
extern void system__secondary_stack___elabb PARAMS ((void));
extern void ada__tags___elabs PARAMS ((void));
extern void ada__tags___elabb PARAMS ((void));
extern void ada__streams___elabs PARAMS ((void));
extern void system__finalization_root___elabs PARAMS ((void));
extern void ada__exceptions___elabb PARAMS ((void));
extern void system__finalization_implementation___elabs PARAMS ((void));
extern void system__finalization_implementation___elabb PARAMS ((void));
extern void ada__finalization___elabs PARAMS ((void));
extern void ada__finalization__list_controller___elabs PARAMS ((void));
extern void system__file_control_block___elabs PARAMS ((void));
extern void system__file_io___elabb PARAMS ((void));
extern void ada__text_io___elabs PARAMS ((void));
extern void ada__text_io___elabb PARAMS ((void));

extern int __gnat_inside_elab_final_code;

extern int gnat_argc;
extern char **gnat_argv;
extern char **gnat_envp;
extern int gnat_exit_status;

char __gnat_version[] = "GNAT Version: 3.15w (20010315)";
void adafinal () @{
   system__standard_library__adafinal ();
@}

void adainit ()
@{
   extern char ada__exceptions_E;
   extern char system__exceptions_E;
   extern char interfaces__c_streams_E;
   extern char system__exception_table_E;
   extern char ada__io_exceptions_E;
   extern char system__secondary_stack_E;
   extern char system__stack_checking_E;
   extern char system__soft_links_E;
   extern char ada__tags_E;
   extern char ada__streams_E;
   extern char system__finalization_root_E;
   extern char system__finalization_implementation_E;
   extern char ada__finalization_E;
   extern char ada__finalization__list_controller_E;
   extern char system__file_control_block_E;
   extern char system__file_io_E;
   extern char ada__text_io_E;

   extern void *__gnat_hello__SDP;
   extern void *__gnat_ada__text_io__SDP;
   extern void *__gnat_ada__exceptions__SDP;
   extern void *__gnat_gnat__heap_sort_a__SDP;
   extern void *__gnat_system__exception_table__SDP;
   extern void *__gnat_system__machine_state_operations__SDP;
   extern void *__gnat_system__secondary_stack__SDP;
   extern void *__gnat_system__parameters__SDP;
   extern void *__gnat_system__soft_links__SDP;
   extern void *__gnat_system__stack_checking__SDP;
   extern void *__gnat_system__traceback__SDP;
   extern void *__gnat_ada__streams__SDP;
   extern void *__gnat_ada__tags__SDP;
   extern void *__gnat_system__string_ops__SDP;
   extern void *__gnat_interfaces__c_streams__SDP;
   extern void *__gnat_system__file_io__SDP;
   extern void *__gnat_ada__finalization__SDP;
   extern void *__gnat_system__finalization_root__SDP;
   extern void *__gnat_system__finalization_implementation__SDP;
   extern void *__gnat_system__string_ops_concat_3__SDP;
   extern void *__gnat_system__stream_attributes__SDP;
   extern void *__gnat_system__file_control_block__SDP;
   extern void *__gnat_ada__finalization__list_controller__SDP;

   void **st[23] = @{
     &__gnat_hello__SDP,
     &__gnat_ada__text_io__SDP,
     &__gnat_ada__exceptions__SDP,
     &__gnat_gnat__heap_sort_a__SDP,
     &__gnat_system__exception_table__SDP,
     &__gnat_system__machine_state_operations__SDP,
     &__gnat_system__secondary_stack__SDP,
     &__gnat_system__parameters__SDP,
     &__gnat_system__soft_links__SDP,
     &__gnat_system__stack_checking__SDP,
     &__gnat_system__traceback__SDP,
     &__gnat_ada__streams__SDP,
     &__gnat_ada__tags__SDP,
     &__gnat_system__string_ops__SDP,
     &__gnat_interfaces__c_streams__SDP,
     &__gnat_system__file_io__SDP,
     &__gnat_ada__finalization__SDP,
     &__gnat_system__finalization_root__SDP,
     &__gnat_system__finalization_implementation__SDP,
     &__gnat_system__string_ops_concat_3__SDP,
     &__gnat_system__stream_attributes__SDP,
     &__gnat_system__file_control_block__SDP,
     &__gnat_ada__finalization__list_controller__SDP@};

   extern void ada__exceptions___elabs ();
   extern void system__exceptions___elabs ();
   extern void interfaces__c_streams___elabs ();
   extern void system__exception_table___elabb ();
   extern void ada__io_exceptions___elabs ();
   extern void system__stack_checking___elabs ();
   extern void system__soft_links___elabb ();
   extern void system__secondary_stack___elabb ();
   extern void ada__tags___elabs ();
   extern void ada__tags___elabb ();
   extern void ada__streams___elabs ();
   extern void system__finalization_root___elabs ();
   extern void ada__exceptions___elabb ();
   extern void system__finalization_implementation___elabs ();
   extern void system__finalization_implementation___elabb ();
   extern void ada__finalization___elabs ();
   extern void ada__finalization__list_controller___elabs ();
   extern void system__file_control_block___elabs ();
   extern void system__file_io___elabb ();
   extern void ada__text_io___elabs ();
   extern void ada__text_io___elabb ();

   void (*ea[23]) () = @{
     adainit,
     system__standard_library__adafinal,
     ada__exceptions___elabs,
     system__exceptions___elabs,
     interfaces__c_streams___elabs,
     system__exception_table___elabb,
     ada__io_exceptions___elabs,
     system__stack_checking___elabs,
     system__soft_links___elabb,
     system__secondary_stack___elabb,
     ada__tags___elabs,
     ada__tags___elabb,
     ada__streams___elabs,
     system__finalization_root___elabs,
     ada__exceptions___elabb,
     system__finalization_implementation___elabs,
     system__finalization_implementation___elabb,
     ada__finalization___elabs,
     ada__finalization__list_controller___elabs,
     system__file_control_block___elabs,
     system__file_io___elabb,
     ada__text_io___elabs,
     ada__text_io___elabb@};

   __gnat_SDP_Table_Build (&st, 23, ea, 23);
   __gnat_set_globals (
      -1,      /* Main_Priority              */
      -1,      /* Time_Slice_Value           */
      'b',     /* WC_Encoding                */
      ' ',     /* Locking_Policy             */
      ' ',     /* Queuing_Policy             */
      ' ',     /* Tasking_Dispatching_Policy */
      0,       /* Finalization routine address, not used anymore */
      0,       /* Unreserve_All_Interrupts */
      0);      /* Exception_Tracebacks */

   __gnat_inside_elab_final_code = 1;

   if (ada__exceptions_E == 0) @{
      ada__exceptions___elabs ();
   @}
   if (system__exceptions_E == 0) @{
      system__exceptions___elabs ();
      system__exceptions_E++;
   @}
   if (interfaces__c_streams_E == 0) @{
      interfaces__c_streams___elabs ();
   @}
   interfaces__c_streams_E = 1;
   if (system__exception_table_E == 0) @{
      system__exception_table___elabb ();
      system__exception_table_E++;
   @}
   if (ada__io_exceptions_E == 0) @{
      ada__io_exceptions___elabs ();
      ada__io_exceptions_E++;
   @}
   if (system__stack_checking_E == 0) @{
      system__stack_checking___elabs ();
   @}
   if (system__soft_links_E == 0) @{
      system__soft_links___elabb ();
      system__soft_links_E++;
   @}
   system__stack_checking_E = 1;
   if (system__secondary_stack_E == 0) @{
      system__secondary_stack___elabb ();
      system__secondary_stack_E++;
   @}
   if (ada__tags_E == 0) @{
      ada__tags___elabs ();
   @}
   if (ada__tags_E == 0) @{
      ada__tags___elabb ();
      ada__tags_E++;
   @}
   if (ada__streams_E == 0) @{
      ada__streams___elabs ();
      ada__streams_E++;
   @}
   if (system__finalization_root_E == 0) @{
      system__finalization_root___elabs ();
   @}
   system__finalization_root_E = 1;
   if (ada__exceptions_E == 0) @{
      ada__exceptions___elabb ();
      ada__exceptions_E++;
   @}
   if (system__finalization_implementation_E == 0) @{
      system__finalization_implementation___elabs ();
   @}
   if (system__finalization_implementation_E == 0) @{
      system__finalization_implementation___elabb ();
      system__finalization_implementation_E++;
   @}
   if (ada__finalization_E == 0) @{
      ada__finalization___elabs ();
   @}
   ada__finalization_E = 1;
   if (ada__finalization__list_controller_E == 0) @{
      ada__finalization__list_controller___elabs ();
   @}
   ada__finalization__list_controller_E = 1;
   if (system__file_control_block_E == 0) @{
      system__file_control_block___elabs ();
      system__file_control_block_E++;
   @}
   if (system__file_io_E == 0) @{
      system__file_io___elabb ();
      system__file_io_E++;
   @}
   if (ada__text_io_E == 0) @{
      ada__text_io___elabs ();
   @}
   if (ada__text_io_E == 0) @{
      ada__text_io___elabb ();
      ada__text_io_E++;
   @}

   __gnat_inside_elab_final_code = 0;
@}
int main (argc, argv, envp)
    int argc;
    char **argv;
    char **envp;
@{
   gnat_argc = argc;
   gnat_argv = argv;
   gnat_envp = envp;

   __gnat_initialize ();
   adainit ();
   __gnat_break_start ();

   _ada_hello ();

   system__standard_library__adafinal ();
   __gnat_finalize ();
   exit (gnat_exit_status);
@}
unsigned helloB = 0x7880BEB3;
unsigned system__standard_libraryB = 0x0D24CBD0;
unsigned system__standard_libraryS = 0x3283DBEB;
unsigned adaS = 0x2359F9ED;
unsigned ada__text_ioB = 0x47C85FC4;
unsigned ada__text_ioS = 0x496FE45C;
unsigned ada__exceptionsB = 0x74F50187;
unsigned ada__exceptionsS = 0x6736945B;
unsigned gnatS = 0x156A40CF;
unsigned gnat__heap_sort_aB = 0x033DABE0;
unsigned gnat__heap_sort_aS = 0x6AB38FEA;
unsigned systemS = 0x0331C6FE;
unsigned system__exceptionsS = 0x20C9ECA4;
unsigned system__exception_tableB = 0x68A22947;
unsigned system__exception_tableS = 0x394BADD5;
unsigned gnat__htableB = 0x08258E1B;
unsigned gnat__htableS = 0x367D5222;
unsigned system__machine_state_operationsB = 0x4F3B7492;
unsigned system__machine_state_operationsS = 0x182F5CF4;
unsigned system__storage_elementsB = 0x2F1EB794;
unsigned system__storage_elementsS = 0x102C83C7;
unsigned system__secondary_stackB = 0x1574B6E9;
unsigned system__secondary_stackS = 0x708E260A;
unsigned system__parametersB = 0x56D770CD;
unsigned system__parametersS = 0x237E39BE;
unsigned system__soft_linksB = 0x08AB6B2C;
unsigned system__soft_linksS = 0x1E2491F3;
unsigned system__stack_checkingB = 0x476457A0;
unsigned system__stack_checkingS = 0x5299FCED;
unsigned system__tracebackB = 0x2971EBDE;
unsigned system__tracebackS = 0x2E9C3122;
unsigned ada__streamsS = 0x7C25DE96;
unsigned ada__tagsB = 0x39ADFFA2;
unsigned ada__tagsS = 0x769A0464;
unsigned system__string_opsB = 0x5EB646AB;
unsigned system__string_opsS = 0x63CED018;
unsigned interfacesS = 0x0357E00A;
unsigned interfaces__c_streamsB = 0x3784FB72;
unsigned interfaces__c_streamsS = 0x2E723019;
unsigned system__file_ioB = 0x623358EA;
unsigned system__file_ioS = 0x31F873E6;
unsigned ada__finalizationB = 0x6843F68A;
unsigned ada__finalizationS = 0x63305874;
unsigned system__finalization_rootB = 0x31E56CE1;
unsigned system__finalization_rootS = 0x23169EF3;
unsigned system__finalization_implementationB = 0x6CCBA70E;
unsigned system__finalization_implementationS = 0x604AA587;
unsigned system__string_ops_concat_3B = 0x572E3F58;
unsigned system__string_ops_concat_3S = 0x01F57876;
unsigned system__stream_attributesB = 0x1D4F93E8;
unsigned system__stream_attributesS = 0x30B2EC3D;
unsigned ada__io_exceptionsS = 0x34054F96;
unsigned system__unsigned_typesS = 0x7B9E7FE3;
unsigned system__file_control_blockS = 0x2FF876A8;
unsigned ada__finalization__list_controllerB = 0x5760634A;
unsigned ada__finalization__list_controllerS = 0x5D851835;

/* BEGIN ELABORATION ORDER
ada (spec)
gnat (spec)
gnat.heap_sort_a (spec)
gnat.htable (spec)
gnat.htable (body)
interfaces (spec)
system (spec)
system.parameters (spec)
system.standard_library (spec)
ada.exceptions (spec)
system.exceptions (spec)
system.parameters (body)
gnat.heap_sort_a (body)
interfaces.c_streams (spec)
interfaces.c_streams (body)
system.exception_table (spec)
system.exception_table (body)
ada.io_exceptions (spec)
system.storage_elements (spec)
system.storage_elements (body)
system.machine_state_operations (spec)
system.machine_state_operations (body)
system.secondary_stack (spec)
system.stack_checking (spec)
system.soft_links (spec)
system.soft_links (body)
system.stack_checking (body)
system.secondary_stack (body)
system.standard_library (body)
system.string_ops (spec)
system.string_ops (body)
ada.tags (spec)
ada.tags (body)
ada.streams (spec)
system.finalization_root (spec)
system.finalization_root (body)
system.string_ops_concat_3 (spec)
system.string_ops_concat_3 (body)
system.traceback (spec)
system.traceback (body)
ada.exceptions (body)
system.unsigned_types (spec)
system.stream_attributes (spec)
system.stream_attributes (body)
system.finalization_implementation (spec)
system.finalization_implementation (body)
ada.finalization (spec)
ada.finalization (body)
ada.finalization.list_controller (spec)
ada.finalization.list_controller (body)
system.file_control_block (spec)
system.file_io (spec)
system.file_io (body)
ada.text_io (spec)
ada.text_io (body)
hello (body)
   END ELABORATION ORDER */

/* BEGIN Object file/option list
./hello.o
-L./
-L/usr/local/gnat/lib/gcc-lib/alpha-dec-osf5.1/2.8.1/adalib/
/usr/local/gnat/lib/gcc-lib/alpha-dec-osf5.1/2.8.1/adalib/libgnat.a
-lexc
   END Object file/option list */

@end smallexample

@noindent
Here again, the C code is exactly what is generated by the binder. The
functions of the various parts of this code correspond in an obvious
manner with the commented Ada code shown in the example in the previous
section.

@node Consistency-Checking Modes
@section Consistency-Checking Modes

@noindent
As described in the previous section, by default @code{gnatbind} checks
that object files are consistent with one another and are consistent
with any source files it can locate. The following switches control binder
access to sources.

@table @code
@item ^-s^/READ_SOURCES=ALL^
@cindex @code{^-s^/READ_SOURCES=ALL^} (@code{gnatbind})
Require source files to be present. In this mode, the binder must be
able to locate all source files that are referenced, in order to check
their consistency. In normal mode, if a source file cannot be located it
is simply ignored. If you specify this switch, a missing source
file is an error.

@item ^-x^/READ_SOURCES=NONE^
@cindex @code{^-x^/READ_SOURCES=NONE^} (@code{gnatbind})
Exclude source files. In this mode, the binder only checks that ALI
files are consistent with one another. Source files are not accessed.
The binder runs faster in this mode, and there is still a guarantee that
the resulting program is self-consistent.
If a source file has been edited since it was last compiled, and you
specify this switch, the binder will not detect that the object
file is out of date with respect to the source file. Note that this is the
mode that is automatically used by @code{gnatmake} because in this
case the checking against sources has already been performed by
@code{gnatmake} in the course of compilation (i.e. before binding).

@ifset vms
@item /READ_SOURCES=AVAILABLE
This is the default mode in which source files are checked if they are
available, and ignored if they are not available.
@end ifset
@end table

@node Binder Error Message Control
@section Binder Error Message Control

@noindent
The following switches provide control over the generation of error
messages from the binder:

@table @code
@item ^-v^/REPORT_ERRORS=VERBOSE^
@cindex @code{^-v^/REPORT_ERRORS=VERBOSE^} (@code{gnatbind})
Verbose mode. In the normal mode, brief error messages are generated to
@file{stderr}. If this switch is present, a header is written
to @file{stdout} and any error messages are directed to @file{stdout}.
All that is written to @file{stderr} is a brief summary message.

@item ^-b^/REPORT_ERRORS=BRIEF^
@cindex @code{^-b^/REPORT_ERRORS=BRIEF^} (@code{gnatbind})
Generate brief error messages to @file{stderr} even if verbose mode is
specified. This is relevant only when used with the
@code{^-v^/REPORT_ERRORS=VERBOSE^} switch.

@ifclear vms
@item -m@var{n}
@cindex @code{-m} (@code{gnatbind})
Limits the number of error messages to @var{n}, a decimal integer in the
range 1-999. The binder terminates immediately if this limit is reached.

@item -M@var{xxx}
@cindex @code{-M} (@code{gnatbind})
Renames the generated main program from @code{main} to @code{xxx}.
This is useful in the case of some cross-building environments, where
the actual main program is separate from the one generated
by @code{gnatbind}.
@end ifclear

@item ^-ws^/WARNINGS=SUPPRESS^
@cindex @code{^-ws^/WARNINGS=SUPPRESS^} (@code{gnatbind})
@cindex Warnings
Suppress all warning messages.

@item ^-we^/WARNINGS=ERROR^
@cindex @code{^-we^/WARNINGS=ERROR^} (@code{gnatbind})
Treat any warning messages as fatal errors.

@ifset vms
@item /WARNINGS=NORMAL
Standard mode with warnings generated, but warnings do not get treated
as errors.
@end ifset

@item ^-t^/NOTIME_STAMP_CHECK^
@cindex @code{^-t^/NOTIME_STAMP_CHECK^} (@code{gnatbind})
@cindex Time stamp checks, in binder
@cindex Binder consistency checks
@cindex Consistency checks, in binder
The binder performs a number of consistency checks including:

@itemize @bullet
@item
Check that time stamps of a given source unit are consistent
@item
Check that checksums of a given source unit are consistent
@item
Check that consistent versions of @code{GNAT} were used for compilation
@item
Check consistency of configuration pragmas as required
@end itemize

@noindent
Normally failure of such checks, in accordance with the consistency
requirements of the Ada Reference Manual, causes error messages to be
generated which abort the binder and prevent the output of a binder
file and subsequent link to obtain an executable.

The @code{^-t^/NOTIME_STAMP_CHECK^} switch converts these error messages
into warnings, so that
binding and linking can continue to completion even in the presence of such
errors. The result may be a failed link (due to missing symbols), or a
non-functional executable which has undefined semantics.
@emph{This means that
@code{^-t^/NOTIME_STAMP_CHECK^} should be used only in unusual situations,
with extreme care.}
@end table

@node Elaboration Control
@section Elaboration Control

@noindent
The following switches provide additional control over the elaboration
order. For full details see @xref{Elaboration Order Handling in GNAT}.

@table @code
@item ^-p^/PESSIMISTIC_ELABORATION^
@cindex @code{^-h^/PESSIMISTIC_ELABORATION^} (@code{gnatbind})
Normally the binder attempts to choose an elaboration order that is
likely to minimize the likelihood of an elaboration order error resulting
in raising a @code{Program_Error} exception. This switch reverses the
action of the binder, and requests that it deliberately choose an order
that is likely to maximize the likelihood of an elaboration error.
This is useful in ensuring portability and avoiding dependence on
accidental fortuitous elaboration ordering.

Normally it only makes sense to use the @code{-p} switch if dynamic
elaboration checking is used (@option{-gnatE} switch used for compilation).
This is because in the default static elaboration mode, all necessary
@code{Elaborate_All} pragmas are implicitly inserted. These implicit
pragmas are still respected by the binder in @code{-p} mode, so a
safe elaboration order is assured.
@end table

@node Output Control
@section Output Control

@noindent
The following switches allow additional control over the output
generated by the binder.

@table @code

@item ^-A^/BIND_FILE=ADA^
@cindex @code{^-A^/BIND_FILE=ADA^} (@code{gnatbind})
Generate binder program in Ada (default). The binder program is named
@file{b~@var{mainprog}.adb} by default. This can be changed with
@code{-o} @code{gnatbind} option.

@item ^-c^/NOOUTPUT^
@cindex @code{^-c^/NOOUTPUT^} (@code{gnatbind})
Check only. Do not generate the binder output file. In this mode the
binder performs all error checks but does not generate an output file.

@item ^-C^/BIND_FILE=C^
@cindex @code{^-C^/BIND_FILE=C^} (@code{gnatbind})
Generate binder program in C. The binder program is named
@file{b_@var{mainprog}.c}. This can be changed with @code{-o} @code{gnatbind}
option.

@item ^-e^/ELABORATION_DEPENDENCIES^
@cindex @code{^-e^/ELABORATION_DEPENDENCIES^} (@code{gnatbind})
Output complete list of elaboration-order dependencies, showing the
reason for each dependency. This output can be rather extensive but may
be useful in diagnosing problems with elaboration order. The output is
written to @file{stdout}.

@item ^-h^/HELP^
@cindex @code{^-h^/HELP^} (@code{gnatbind})
Output usage information. The output is written to @file{stdout}.

@item ^-K^/LINKER_OPTION_LIST^
@cindex @code{^-K^/LINKER_OPTION_LIST^} (@code{gnatbind})
Output linker options to @file{stdout}. Includes library search paths,
contents of pragmas Ident and Linker_Options, and libraries added
by @code{gnatbind}.

@item ^-l^/ORDER_OF_ELABORATION^
@cindex @code{^-l^/ORDER_OF_ELABORATION^} (@code{gnatbind})
Output chosen elaboration order. The output is written to @file{stdout}.

@item ^-O^/OBJECT_LIST^
@cindex @code{^-O^/OBJECT_LIST^} (@code{gnatbind})
Output full names of all the object files that must be linked to provide
the Ada component of the program. The output is written to @file{stdout}.
This list includes the files explicitly supplied and referenced by the user
as well as implicitly referenced run-time unit files. The latter are
omitted if the corresponding units reside in shared libraries. The
directory names for the run-time units depend on the system configuration.

@item ^-o ^/OUTPUT=^@var{file}
@cindex @code{^-o^/OUTPUT^} (@code{gnatbind})
Set name of output file to @var{file} instead of the normal
@file{b~@var{mainprog}.adb} default. Note that @var{file} denote the Ada
binder generated body filename. In C mode you would normally give
@var{file} an extension of @file{.c} because it will be a C source program.
Note that if this option is used, then linking must be done manually.
It is not possible to use gnatlink in this case, since it cannot locate
the binder file.

@item ^-r^/RESTRICTION_LIST^
@cindex @code{^-r^/RESTRICTION_LIST^} (@code{gnatbind})
Generate list of @code{pragma Rerstrictions} that could be applied to
the current unit. This is useful for code audit purposes, and also may
be used to improve code generation in some cases.

@end table

@node Binding with Non-Ada Main Programs
@section Binding with Non-Ada Main Programs

@noindent
In our description so far we have assumed that the main
program is in Ada, and that the task of the binder is to generate a
corresponding function @code{main} that invokes this Ada main
program. GNAT also supports the building of executable programs where
the main program is not in Ada, but some of the called routines are
written in Ada and compiled using GNAT (@pxref{Mixed Language Programming}).
The following switch is used in this situation:

@table @code
@item ^-n^/NOMAIN^
@cindex @code{^-n^/NOMAIN^} (@code{gnatbind})
No main program. The main program is not in Ada.
@end table

@noindent
In this case, most of the functions of the binder are still required,
but instead of generating a main program, the binder generates a file
containing the following callable routines:

@table @code
@item adainit
@findex adainit
You must call this routine to initialize the Ada part of the program by
calling the necessary elaboration routines. A call to @code{adainit} is
required before the first call to an Ada subprogram.

Note that it is assumed that the basic execution environment must be setup
to be appropriate for Ada execution at the point where the first Ada
subprogram is called. In particular, if the Ada code will do any
floating-point operations, then the FPU must be setup in an appropriate
manner. For the case of the x86, for example, full precision mode is
required. The procedure GNAT.Float_Control.Reset may be used to ensure
that the FPU is in the right state.

@item adafinal
@findex adafinal
You must call this routine to perform any library-level finalization
required by the Ada subprograms. A call to @code{adafinal} is required
after the last call to an Ada subprogram, and before the program
terminates.
@end table

@noindent
If the @code{^-n^/NOMAIN^} switch
@cindex Binder, multiple input files
is given, more than one ALI file may appear on
the command line for @code{gnatbind}. The normal @dfn{closure}
calculation is performed for each of the specified units. Calculating
the closure means finding out the set of units involved by tracing
@code{with} references. The reason it is necessary to be able to
specify more than one ALI file is that a given program may invoke two or
more quite separate groups of Ada units.

The binder takes the name of its output file from the last specified ALI
file, unless overridden by the use of the @code{^-o file^/OUTPUT=file^}.
The output is an Ada unit in source form that can
be compiled with GNAT unless the -C switch is used in which case the
output is a C source file, which must be compiled using the C compiler.
This compilation occurs automatically as part of the @code{gnatlink}
processing.

Currently the GNAT run time requires a FPU using 80 bits mode
precision. Under targets where this is not the default it is required to
call GNAT.Float_Control.Reset before using floating point numbers (this
include float computation, float input and output) in the Ada code. A
side effect is that this could be the wrong mode for the foreign code
where floating point computation could be broken after this call.

@node Binding Programs with No Main Subprogram
@section Binding Programs with No Main Subprogram

@noindent
It is possible to have an Ada program which does not have a main
subprogram. This program will call the elaboration routines of all the
packages, then the finalization routines.

The following switch is used to bind programs organized in this manner:

@table @code
@item ^-z^/ZERO_MAIN^
@cindex @code{^-z^/ZERO_MAIN^} (@code{gnatbind})
Normally the binder checks that the unit name given on the command line
corresponds to a suitable main subprogram. When this switch is used,
a list of ALI files can be given, and the execution of the program
consists of elaboration of these units in an appropriate order.
@end table

@node Summary of Binder Switches
@section Summary of Binder Switches

@noindent
The following are the switches available with @code{gnatbind}:

@table @code
@item ^-aO^/OBJECT_SEARCH^
Specify directory to be searched for ALI files.

@item ^-aI^/SOURCE_SEARCH^
Specify directory to be searched for source file.

@item ^-A^/BIND_FILE=ADA^
Generate binder program in Ada (default)

@item ^-b^/REPORT_ERRORS=BRIEF^
Generate brief messages to @file{stderr} even if verbose mode set.

@item ^-c^/NOOUTPUT^
Check only, no generation of binder output file.

@item ^-C^/BIND_FILE=C^
Generate binder program in C

@item ^-e^/ELABORATION_DEPENDENCIES^
Output complete list of elaboration-order dependencies.

@item -E
Store tracebacks in exception occurrences when the target supports it.
This is the default with the zero cost exception mechanism.
This option is currently supported on the following targets:
all x86 ports, Solaris, Windows, HP-UX, AIX, PowerPC VxWorks and Alpha VxWorks.
See also the packages @code{GNAT.Traceback} and
@code{GNAT.Traceback.Symbolic} for more information.
Note that on x86 ports, you must not use @code{-fomit-frame-pointer}
@code{gcc} option.

@item -h
Output usage (help) information

@item ^-I^/SEARCH^
Specify directory to be searched for source and ALI files.

@item ^-I-^/NOCURRENT_DIRECTORY^
Do not look for sources in the current directory where @code{gnatbind} was
invoked, and do not look for ALI files in the directory containing the
ALI file named in the @code{gnatbind} command line.

@item ^-l^/ORDER_OF_ELABORATION^
Output chosen elaboration order.

@item -Lxxx
Binds the units for library building. In this case the adainit and
adafinal procedures (See @pxref{Binding with Non-Ada Main Programs})
are renamed to xxxinit and xxxfinal. Implies -n.
@ifclear vms
See @pxref{GNAT and Libraries} for more details.
@end ifclear

@item -Mxyz
Rename generated main program from main to xyz

@item ^-m^/ERROR_LIMIT=^@var{n}
Limit number of detected errors to @var{n} (1-999).
@ifset wnt
Furthermore, under Windows, the sources pointed to by the libraries path
set in the registry are not searched for.
@end ifset

@item ^-n^/NOMAIN^
No main program.

@item -nostdinc
Do not look for sources in the system default directory.

@item -nostdlib
Do not look for library files in the system default directory.

@item --RTS=@var{rts-path}
@cindex @code{--RTS} (@code{gnatbind})
Specifies the default location of the runtime library. Same meaning as the
equivalent @code{gnatmake} flag (see @ref{Switches for gnatmake}).

@item ^-o ^/OUTPUT=^@var{file}
Name the output file @var{file} (default is @file{b~@var{xxx}.adb}).
Note that if this option is used, then linking must be done manually,
gnatlink cannot be used.

@item ^-O^/OBJECT_LIST^
Output object list.

@item -p
Pessimistic (worst-case) elaboration order

@item ^-s^/READ_SOURCES=ALL^
Require all source files to be present.

@ifclear vms
@item -static
Link against a static GNAT run time.

@item -shared
Link against a shared GNAT run time when available.
@end ifclear

@item ^-t^/NOTIME_STAMP_CHECK^
Tolerate time stamp and other consistency errors

@item -T@var{n}
Set the time slice value to n microseconds. A value of zero means no time
slicing and also indicates to the tasking run time to match as close as
possible to the annex D requirements of the RM.

@item ^-v^/REPORT_ERRORS=VERBOSE^
Verbose mode. Write error messages, header, summary output to
@file{stdout}.

@ifclear vms
@item -w@var{x}
Warning mode (@var{x}=s/e for suppress/treat as error)
@end ifclear

@ifset vms
@item /WARNINGS=NORMAL
Normal warnings mode. Warnings are issued but ignored

@item /WARNINGS=SUPPRESS
All warning messages are suppressed

@item /WARNINGS=ERROR
Warning messages are treated as fatal errors
@end ifset

@item ^-x^/READ_SOURCES=NONE^
Exclude source files (check object consistency only).

@ifset vms
@item /READ_SOURCES=AVAILABLE
Default mode, in which sources are checked for consistency only if
they are available.
@end ifset

@item ^-z^/ZERO_MAIN^
No main subprogram.

@end table

@ifclear vms
You may obtain this listing by running the program @code{gnatbind} with
no arguments.
@end ifclear

@node Command-Line Access
@section Command-Line Access

@noindent
The package @code{Ada.Command_Line} provides access to the command-line
arguments and program name. In order for this interface to operate
correctly, the two variables

@smallexample
@group
@cartouche
int gnat_argc;
char **gnat_argv;
@end cartouche
@end group
@end smallexample

@noindent
@findex gnat_argv
@findex gnat_argc
are declared in one of the GNAT library routines. These variables must
be set from the actual @code{argc} and @code{argv} values passed to the
main program. With no @code{^n^/NOMAIN^} present, @code{gnatbind}
generates the C main program to automatically set these variables.
If the @code{^n^/NOMAIN^} switch is used, there is no automatic way to
set these variables. If they are not set, the procedures in
@code{Ada.Command_Line} will not be available, and any attempt to use
them will raise @code{Constraint_Error}. If command line access is
required, your main program must set @code{gnat_argc} and
@code{gnat_argv} from the @code{argc} and @code{argv} values passed to
it.

@node Search Paths for gnatbind
@section Search Paths for @code{gnatbind}

@noindent
The binder takes the name of an ALI file as its argument and needs to
locate source files as well as other ALI files to verify object consistency.

For source files, it follows exactly the same search rules as @code{gcc}
(@pxref{Search Paths and the Run-Time Library (RTL)}). For ALI files the
directories searched are:

@enumerate
@item
The directory containing the ALI file named in the command line, unless
the switch @code{^-I-^/NOCURRENT_DIRECTORY^} is specified.

@item
All directories specified by @code{^-I^/SEARCH^}
switches on the @code{gnatbind}
command line, in the order given.

@item
@findex ADA_OBJECTS_PATH
Each of the directories listed in the value of the
@code{ADA_OBJECTS_PATH} ^environment variable^logical name^.
@ifclear vms
Construct this value
exactly as the @code{PATH} environment variable: a list of directory
names separated by colons (semicolons when working with the NT version
of GNAT).
@end ifclear
@ifset vms
Normally, define this value as a logical name containing a comma separated
list of directory names.

This variable can also be defined by means of an environment string
(an argument to the DEC C exec* set of functions).

Logical Name:
@smallexample
DEFINE ANOTHER_PATH FOO:[BAG]
DEFINE ADA_OBJECTS_PATH ANOTHER_PATH,FOO:[BAM],FOO:[BAR]
@end smallexample

By default, the path includes GNU:[LIB.OPENVMS7_x.2_8_x.DECLIB]
first, followed by the standard Ada 95
libraries in GNU:[LIB.OPENVMS7_x.2_8_x.ADALIB].
If this is not redefined, the user will obtain the DEC Ada83 IO packages
(Text_IO, Sequential_IO, etc)
instead of the Ada95 packages. Thus, in order to get the Ada 95
packages by default, ADA_OBJECTS_PATH must be redefined.
@end ifset

@item
The content of the "ada_object_path" file which is part of the GNAT
installation tree and is used to store standard libraries such as the
GNAT Run Time Library (RTL) unless the switch @code{-nostdlib} is
specified.
@ifclear vms
@ref{Installing an Ada Library}
@end ifclear
@end enumerate

@noindent
In the binder the switch @code{^-I^/SEARCH^}
is used to specify both source and
library file paths. Use @code{^-aI^/SOURCE_SEARCH^}
instead if you want to specify
source paths only, and @code{^-aO^/LIBRARY_SEARCH^}
if you want to specify library paths
only. This means that for the binder
@code{^-I^/SEARCH=^}@var{dir} is equivalent to
@code{^-aI^/SOURCE_SEARCH=^}@var{dir}
@code{^-aO^/OBJECT_SEARCH=^}@var{dir}.
The binder generates the bind file (a C language source file) in the
current working directory.

@findex Ada
@findex System
@findex Interfaces
@findex GNAT
The packages @code{Ada}, @code{System}, and @code{Interfaces} and their
children make up the GNAT Run-Time Library, together with the package
GNAT and its children, which contain a set of useful additional
library functions provided by GNAT. The sources for these units are
needed by the compiler and are kept together in one directory. The ALI
files and object files generated by compiling the RTL are needed by the
binder and the linker and are kept together in one directory, typically
different from the directory containing the sources. In a normal
installation, you need not specify these directory names when compiling
or binding. Either the environment variables or the built-in defaults
cause these files to be found.

Besides simplifying access to the RTL, a major use of search paths is
in compiling sources from multiple directories. This can make
development environments much more flexible.

@node Examples of gnatbind Usage
@section Examples of @code{gnatbind} Usage

@noindent
This section contains a number of examples of using the GNAT binding
utility @code{gnatbind}.

@table @code
@item gnatbind hello
The main program @code{Hello} (source program in @file{hello.adb}) is
bound using the standard switch settings. The generated main program is
@file{b~hello.adb}. This is the normal, default use of the binder.

@ifclear vms
@item gnatbind hello -o mainprog.adb
@end ifclear
@ifset vms
@item gnatbind HELLO.ALI /OUTPUT=Mainprog.ADB
@end ifset
The main program @code{Hello} (source program in @file{hello.adb}) is
bound using the standard switch settings. The generated main program is
@file{mainprog.adb} with the associated spec in
@file{mainprog.ads}. Note that you must specify the body here not the
spec, in the case where the output is in Ada. Note that if this option
is used, then linking must be done manually, since gnatlink will not
be able to find the generated file.

@ifclear vms
@item gnatbind main -C -o mainprog.c -x
@end ifclear
@ifset vms
@item gnatbind MAIN.ALI /BIND_FILE=C /OUTPUT=Mainprog.C /READ_SOURCES=NONE
@end ifset
The main program @code{Main} (source program in
@file{main.adb}) is bound, excluding source files from the
consistency checking, generating
the file @file{mainprog.c}.

@ifclear vms
@item gnatbind -x main_program -C -o mainprog.c
This command is exactly the same as the previous example. Switches may
appear anywhere in the command line, and single letter switches may be
combined into a single switch.
@end ifclear

@ifclear vms
@item gnatbind -n math dbase -C -o ada-control.c
@end ifclear
@ifset vms
@item gnatbind /NOMAIN math dbase /BIND_FILE=C /OUTPUT=ada-control.c
@end ifset
The main program is in a language other than Ada, but calls to
subprograms in packages @code{Math} and @code{Dbase} appear. This call
to @code{gnatbind} generates the file @file{ada-control.c} containing
the @code{adainit} and @code{adafinal} routines to be called before and
after accessing the Ada units.
@end table

@node Linking Using gnatlink
@chapter Linking Using @code{gnatlink}
@findex gnatlink

@noindent
This chapter discusses @code{gnatlink}, a utility program used to link
Ada programs and build an executable file. This is a simple program
that invokes the Unix linker (via the @code{gcc}
command) with a correct list of object files and library references.
@code{gnatlink} automatically determines the list of files and
references for the Ada part of a program. It uses the binder file
generated by the binder to determine this list.

@menu
* Running gnatlink::
* Switches for gnatlink::
* Setting Stack Size from gnatlink::
* Setting Heap Size from gnatlink::
@end menu

@node Running gnatlink
@section Running @code{gnatlink}

@noindent
The form of the @code{gnatlink} command is

@smallexample
$ gnatlink [@var{switches}] @var{mainprog}[.ali] [@var{non-Ada objects}]
      [@var{linker options}]
@end smallexample

@noindent
@file{@var{mainprog}.ali} references the ALI file of the main program.
The @file{.ali} extension of this file can be omitted. From this
reference, @code{gnatlink} locates the corresponding binder file
@file{b~@var{mainprog}.adb} and, using the information in this file along
with the list of non-Ada objects and linker options, constructs a Unix
linker command file to create the executable.

The arguments following @file{@var{mainprog}.ali} are passed to the
linker uninterpreted. They typically include the names of object files
for units written in other languages than Ada and any library references
required to resolve references in any of these foreign language units,
or in @code{pragma Import} statements in any Ada units.

@var{linker options} is an optional list of linker specific
switches. The default linker called by gnatlink is @var{gcc} which in
turn calls the appropriate system linker usually called
@var{ld}. Standard options for the linker such as @code{-lmy_lib} or
@code{-Ldir} can be added as is. For options that are not recognized by
@var{gcc} as linker options, the @var{gcc} switches @code{-Xlinker} or
@code{-Wl,} shall be used. Refer to the GCC documentation for
details. Here is an example showing how to generate a linker map
assuming that the underlying linker is GNU ld:

@smallexample
$ gnatlink my_prog -Wl,-Map,MAPFILE
@end smallexample

Using @var{linker options} it is possible to set the program stack and
heap size. See @pxref{Setting Stack Size from gnatlink} and
@pxref{Setting Heap Size from gnatlink}.

@code{gnatlink} determines the list of objects required by the Ada
program and prepends them to the list of objects passed to the linker.
@code{gnatlink} also gathers any arguments set by the use of
@code{pragma Linker_Options} and adds them to the list of arguments
presented to the linker.

@ifset vms
@code{gnatlink} accepts the following types of extra files on the command
line: objects (.OBJ), libraries (.OLB), shareable images (.EXE), and
options files (.OPT). These are recognized and handled according to their
extension.
@end ifset

@node Switches for gnatlink
@section Switches for @code{gnatlink}

@noindent
The following switches are available with the @code{gnatlink} utility:

@table @code

@item ^-A^/BIND_FILE=ADA^
@cindex @code{^-A^/BIND_FILE=ADA^} (@code{gnatlink})
The binder has generated code in Ada. This is the default.

@item ^-C^/BIND_FILE=C^
@cindex @code{^-C^/BIND_FILE=C^} (@code{gnatlink})
If instead of generating a file in Ada, the binder has generated one in
C, then the linker needs to know about it. Use this switch to signal
to @code{gnatlink} that the binder has generated C code rather than
Ada code.

@item -f
@cindex Command line length
@cindex @code{-f} (@code{gnatlink})
On some targets, the command line length is limited, and @code{gnatlink}
will generate a separate file for the linker if the list of object files
is too long. The @code{-f} flag forces this file to be generated even if
the limit is not exceeded. This is useful in some cases to deal with
special situations where the command line length is exceeded.

@item ^-g^/DEBUG^
@cindex Debugging information, including
@cindex @code{^-g^/DEBUG^} (@code{gnatlink})
The option to include debugging information causes the Ada bind file (in
other words, @file{b~@var{mainprog}.adb}) to be compiled with
@code{^-g^/DEBUG^}.
In addition, the binder does not delete the @file{b~@var{mainprog}.adb},
@file{b~@var{mainprog}.o} and @file{b~@var{mainprog}.ali} files.
Without @code{^-g^/DEBUG^}, the binder removes these files by
default. The same procedure apply if a C bind file was generated using
@code{^-C^/BIND_FILE=C^} @code{gnatbind} option, in this case the filenames are
@file{b_@var{mainprog}.c} and @file{b_@var{mainprog}.o}.

@ifclear vms
@item -n
@cindex @code{-n} (@code{gnatlink})
Do not compile the file generated by the binder. This may be used when
a link is rerun with different options, but there is no need to recompile
the binder file.
@end ifclear

@item ^-v^/VERBOSE^
@cindex @code{^-v^/VERBOSE^} (@code{gnatlink})
Causes additional information to be output, including a full list of the
included object files. This switch option is most useful when you want
to see what set of object files are being used in the link step.

@ifclear vms
@item -v -v
@cindex @code{-v -v} (@code{gnatlink})
Very verbose mode. Requests that the compiler operate in verbose mode when
it compiles the binder file, and that the system linker run in verbose mode.
@end ifclear

@item ^-o ^/EXECUTABLE=^@var{exec-name}
@cindex @code{^-o^/EXECUTABLE^} (@code{gnatlink})
@var{exec-name} specifies an alternate name for the generated
executable program. If this switch is omitted, the executable has the same
name as the main unit. For example, @code{gnatlink try.ali} creates
an executable called @file{^try^TRY.EXE^}.

@ifclear vms
@item -b @var{target}
@cindex @code{-b} (@code{gnatlink})
Compile your program to run on @var{target}, which is the name of a
system configuration. You must have a GNAT cross-compiler built if
@var{target} is not the same as your host system.

@item -B@var{dir}
@cindex @code{-B} (@code{gnatlink})
Load compiler executables (for example, @code{gnat1}, the Ada compiler)
from @var{dir} instead of the default location. Only use this switch
when multiple versions of the GNAT compiler are available. See the
@code{gcc} manual page for further details. You would normally use the
@code{-b} or @code{-V} switch instead.

@item --GCC=@var{compiler_name}
@cindex @code{--GCC=compiler_name} (@code{gnatlink})
Program used for compiling the binder file. The default is
`@code{gcc}'. You need to use quotes around @var{compiler_name} if
@code{compiler_name} contains spaces or other separator characters. As
an example @code{--GCC="foo -x -y"} will instruct @code{gnatlink} to use
@code{foo -x -y} as your compiler. Note that switch @code{-c} is always
inserted after your command name. Thus in the above example the compiler
command that will be used by @code{gnatlink} will be @code{foo -c -x -y}.
If several @code{--GCC=compiler_name} are used, only the last
@var{compiler_name} is taken into account. However, all the additional
switches are also taken into account. Thus,
@code{--GCC="foo -x -y" --GCC="bar -z -t"} is equivalent to
@code{--GCC="bar -x -y -z -t"}.

@item --LINK=@var{name}
@cindex @code{--LINK=} (@code{gnatlink})
@var{name} is the name of the linker to be invoked. This is especially
useful in mixed language programs since languages such as c++ require
their own linker to be used. When this switch is omitted, the default
name for the linker is (@file{gcc}). When this switch is used, the
specified linker is called instead of (@file{gcc}) with exactly the same
parameters that would have been passed to (@file{gcc}) so if the desired
linker requires different parameters it is necessary to use a wrapper
script that massages the parameters before invoking the real linker. It
may be useful to control the exact invocation by using the verbose
switch.

@end ifclear

@ifset vms
@item /DEBUG=TRACEBACK
@cindex @code{/DEBUG=TRACEBACK} (@code{gnatlink})
This qualifier causes sufficient information to be included in the
executable file to allow a traceback, but does not include the full
symbol information needed by the debugger.

@item /IDENTIFICATION="<string>"
"<string>" specifies the string to be stored in the image file identification
field in the image header. It overrides any pragma Ident specified string.

@item /NOINHIBIT-EXEC
Generate the executable file even if there are linker warnings.

@item /NOSTART_FILES
Don't link in the object file containing the "main" transfer address.
Used when linking with a foreign language main program compiled with a
Digital compiler.

@item /STATIC
Prefer linking with object libraries over shareable images, even without
/DEBUG.
@end ifset

@end table

@node Setting Stack Size from gnatlink
@section Setting Stack Size from @code{gnatlink}

@noindent
It is possible to specify the program stack size from @code{gnatlink}.
Assuming that the underlying linker is GNU ld there is two ways to do so:

@itemize @bullet

@item using @code{-Xlinker} linker option

@smallexample
$ gnatlink hello -Xlinker --stack=0x10000,0x1000
@end smallexample

This set the stack reserve size to 0x10000 bytes and the stack commit
size to 0x1000 bytes.

@item using @code{-Wl} linker option

@smallexample
$ gnatlink hello -Wl,--stack=0x1000000
@end smallexample

This set the stack reserve size to 0x1000000 bytes. Note that with
@code{-Wl} option it is not possible to set the stack commit size
because the coma is a separator for this option.

@end itemize

@node Setting Heap Size from gnatlink
@section Setting Heap Size from @code{gnatlink}

@noindent
It is possible to specify the program heap size from @code{gnatlink}.
Assuming that the underlying linker is GNU ld there is two ways to do so:

@itemize @bullet

@item using @code{-Xlinker} linker option

@smallexample
$ gnatlink hello -Xlinker --heap=0x10000,0x1000
@end smallexample

This set the heap reserve size to 0x10000 bytes and the heap commit
size to 0x1000 bytes.

@item using @code{-Wl} linker option

@smallexample
$ gnatlink hello -Wl,--heap=0x1000000
@end smallexample

This set the heap reserve size to 0x1000000 bytes. Note that with
@code{-Wl} option it is not possible to set the heap commit size
because the coma is a separator for this option.

@end itemize

@node The GNAT Make Program gnatmake
@chapter The GNAT Make Program @code{gnatmake}
@findex gnatmake

@menu
* Running gnatmake::
* Switches for gnatmake::
* Mode Switches for gnatmake::
* Notes on the Command Line::
* How gnatmake Works::
* Examples of gnatmake Usage::
@end menu
@noindent
A typical development cycle when working on an Ada program consists of
the following steps:

@enumerate
@item
Edit some sources to fix bugs.

@item
Add enhancements.

@item
Compile all sources affected.

@item
Rebind and relink.

@item
Test.
@end enumerate

@noindent
The third step can be tricky, because not only do the modified files
@cindex Dependency rules
have to be compiled, but any files depending on these files must also be
recompiled. The dependency rules in Ada can be quite complex, especially
in the presence of overloading, @code{use} clauses, generics and inlined
subprograms.

@code{gnatmake} automatically takes care of the third and fourth steps
of this process. It determines which sources need to be compiled,
compiles them, and binds and links the resulting object files.

Unlike some other Ada make programs, the dependencies are always
accurately recomputed from the new sources. The source based approach of
the GNAT compilation model makes this possible. This means that if
changes to the source program cause corresponding changes in
dependencies, they will always be tracked exactly correctly by
@code{gnatmake}.

@node Running gnatmake
@section Running @code{gnatmake}

@noindent
The usual form of the @code{gnatmake} command is

@smallexample
$ gnatmake [@var{switches}] @var{file_name} [@var{file_names}] [@var{mode_switches}]
@end smallexample

@noindent
The only required argument is one @var{file_name}, which specifies
a compilation unit that is a main program. Several @var{file_names} can be
specified: this will result in several executables being built.
If @code{switches} are present, they can be placed before the first
@var{file_name}, between @var{file_names} or after the last @var{file_name}.
If @var{mode_switches} are present, they must always be placed after
the last @var{file_name} and all @code{switches}.

If you are using standard file extensions (.adb and .ads), then the
extension may be omitted from the @var{file_name} arguments. However, if
you are using non-standard extensions, then it is required that the
extension be given. A relative or absolute directory path can be
specified in a @var{file_name}, in which case, the input source file will
be searched for in the specified directory only. Otherwise, the input
source file will first be searched in the directory where
@code{gnatmake} was invoked and if it is not found, it will be search on
the source path of the compiler as described in
@ref{Search Paths and the Run-Time Library (RTL)}.

When several @var{file_names} are specified, if an executable needs to be
rebuilt and relinked, all subsequent executables will be rebuilt and
relinked, even if this would not be absolutely necessary.

All @code{gnatmake} output (except when you specify
@code{^-M^/DEPENDENCIES_LIST^}) is to
@file{stderr}. The output produced by the
@code{^-M^/DEPENDENCIES_LIST^} switch is send to
@file{stdout}.

@node Switches for gnatmake
@section Switches for @code{gnatmake}

@noindent
You may specify any of the following switches to @code{gnatmake}:

@table @code
@ifclear vms
@item --GCC=@var{compiler_name}
@cindex @code{--GCC=compiler_name} (@code{gnatmake})
Program used for compiling. The default is `@code{gcc}'. You need to use
quotes around @var{compiler_name} if @code{compiler_name} contains
spaces or other separator characters. As an example @code{--GCC="foo -x
-y"} will instruct @code{gnatmake} to use @code{foo -x -y} as your
compiler. Note that switch @code{-c} is always inserted after your
command name. Thus in the above example the compiler command that will
be used by @code{gnatmake} will be @code{foo -c -x -y}.
If several @code{--GCC=compiler_name} are used, only the last
@var{compiler_name} is taken into account. However, all the additional
switches are also taken into account. Thus,
@code{--GCC="foo -x -y" --GCC="bar -z -t"} is equivalent to
@code{--GCC="bar -x -y -z -t"}.

@item --GNATBIND=@var{binder_name}
@cindex @code{--GNATBIND=binder_name} (@code{gnatmake})
Program used for binding. The default is `@code{gnatbind}'. You need to
use quotes around @var{binder_name} if @var{binder_name} contains spaces
or other separator characters. As an example @code{--GNATBIND="bar -x
-y"} will instruct @code{gnatmake} to use @code{bar -x -y} as your
binder. Binder switches that are normally appended by @code{gnatmake} to
`@code{gnatbind}' are now appended to the end of @code{bar -x -y}.

@item --GNATLINK=@var{linker_name}
@cindex @code{--GNATLINK=linker_name} (@code{gnatmake})
Program used for linking. The default is `@code{gnatlink}'. You need to
use quotes around @var{linker_name} if @var{linker_name} contains spaces
or other separator characters. As an example @code{--GNATLINK="lan -x
-y"} will instruct @code{gnatmake} to use @code{lan -x -y} as your
linker. Linker switches that are normally appended by @code{gnatmake} to
`@code{gnatlink}' are now appended to the end of @code{lan -x -y}.

@end ifclear

@item ^-a^/ALL_FILES^
@cindex @code{^-a^/ALL_FILES^} (@code{gnatmake})
Consider all files in the make process, even the GNAT internal system
files (for example, the predefined Ada library files), as well as any
locked files. Locked files are files whose ALI file is write-protected.
By default,
@code{gnatmake} does not check these files,
because the assumption is that the GNAT internal files are properly up
to date, and also that any write protected ALI files have been properly
installed. Note that if there is an installation problem, such that one
of these files is not up to date, it will be properly caught by the
binder.
You may have to specify this switch if you are working on GNAT
itself. @code{^-a^/ALL_FILES^} is also useful in conjunction with
@code{^-f^/FORCE_COMPILE^}
if you need to recompile an entire application,
including run-time files, using special configuration pragma settings,
such as a non-standard @code{Float_Representation} pragma.
By default
@code{gnatmake ^-a^/ALL_FILES^} compiles all GNAT
internal files with
@ifclear vms
@code{gcc -c -gnatpg} rather than @code{gcc -c}.
@end ifclear
@ifset vms
the @code{/CHECKS=SUPPRESS_ALL /STYLE_CHECKS=GNAT} switch.
@end ifset

@item ^-b^/ACTIONS=BIND^
@cindex @code{^-b^/ACTIONS=BIND^} (@code{gnatmake})
Bind only. Can be combined with @code{^-c^/ACTIONS=COMPILE^} to do compilation
and binding, but no link. Can be combined with @code{^-l^/ACTIONS=LINK^}
to do binding and linking. When not combined with @code{^-c^/ACTIONS=COMPILE^}
all the units in the closure of the main program must have been previously
compiled and must be up to date. The root unit specified by @var{file_name}
may be given without extension, with the source extension or, if no GNAT
Project File is specified, with the ALI file extension.

@item ^-c^/ACTIONS=COMPILE^
@cindex @code{^-c^/ACTIONS=COMPILE^} (@code{gnatmake})
Compile only. Do not perform binding, except when @code{^-b^/ACTIONS=BIND^}
is also specified. Do not perform linking, except if both
@code{^-b^/ACTIONS=BIND^} and
 @code{^-l^/ACTIONS=LINK^} are also specified.
If the root unit specified by @var{file_name} is not a main unit, this is the
default. Otherwise @code{gnatmake} will attempt binding and linking
unless all objects are up to date and the executable is more recent than
the objects.

@item ^-C^/MAPPING^
@cindex @code{^-C^/MAPPING^} (@code{gnatmake})
Use a mapping file. A mapping file is a way to communicate to the compiler
two mappings: from unit names to file names (without any directory information)
and from file names to path names (with full directory information).
These mappings are used by the compiler to short-circuit the path search.
When @code{gnatmake} is invoked with this switch, it will create a mapping
file, initially populated by the project manager, if @code{-P} is used,
otherwise initially empty. Each invocation of the compiler will add the newly
accessed sources to the mapping file. This will improve the source search
during the next invocation of the compiler.

@item ^-f^/FORCE_COMPILE^
@cindex @code{^-f^/FORCE_COMPILE^} (@code{gnatmake})
Force recompilations. Recompile all sources, even though some object
files may be up to date, but don't recompile predefined or GNAT internal
files or locked files (files with a write-protected ALI file),
unless the @code{^-a^/ALL_FILES^} switch is also specified.

@item
@item ^-i^/IN_PLACE^
@cindex @code{^-i^/IN_PLACE^} (@code{gnatmake})
In normal mode, @code{gnatmake} compiles all object files and ALI files
into the current directory. If the @code{^-i^/IN_PLACE^} switch is used,
then instead object files and ALI files that already exist are overwritten
in place. This means that once a large project is organized into separate
directories in the desired manner, then @code{gnatmake} will automatically
maintain and update this organization. If no ALI files are found on the
Ada object path (@ref{Search Paths and the Run-Time Library (RTL)}),
the new object and ALI files are created in the
directory containing the source being compiled. If another organization
is desired, where objects and sources are kept in different directories,
a useful technique is to create dummy ALI files in the desired directories.
When detecting such a dummy file, @code{gnatmake} will be forced to recompile
the corresponding source file, and it will be put the resulting object
and ALI files in the directory where it found the dummy file.

@item ^-j^/PROCESSES=^@var{n}
@cindex @code{^-j^/PROCESSES^} (@code{gnatmake})
@cindex Parallel make
Use @var{n} processes to carry out the (re)compilations. On a
multiprocessor machine compilations will occur in parallel. In the
event of compilation errors, messages from various compilations might
get interspersed (but @code{gnatmake} will give you the full ordered
list of failing compiles at the end). If this is problematic, rerun
the make process with n set to 1 to get a clean list of messages.

@item ^-k^/CONTINUE_ON_ERROR^
@cindex @code{^-k^/CONTINUE_ON_ERROR^} (@code{gnatmake})
Keep going. Continue as much as possible after a compilation error. To
ease the programmer's task in case of compilation errors, the list of
sources for which the compile fails is given when @code{gnatmake}
terminates.

If @code{gnatmake} is invoked with several @file{file_names} and with this
switch, if there are compilation errors when building an executable,
@code{gnatmake} will not attempt to build the following executables.

@item ^-l^/ACTIONS=LINK^
@cindex @code{^-l^/ACTIONS=LINK^} (@code{gnatmake})
Link only. Can be combined with @code{^-b^/ACTIONS=BIND^} to binding
and linking. Linking will not be performed if combined with
@code{^-c^/ACTIONS=COMPILE^}
but not with @code{^-b^/ACTIONS=BIND^}.
When not combined with @code{^-b^/ACTIONS=BIND^}
all the units in the closure of the main program must have been previously
compiled and must be up to date, and the main program need to have been bound.
The root unit specified by @var{file_name}
may be given without extension, with the source extension or, if no GNAT
Project File is specified, with the ALI file extension.

@item ^-m^/MINIMAL_RECOMPILATION^
@cindex @code{^-m^/MINIMAL_RECOMPILATION^} (@code{gnatmake})
Specifies that the minimum necessary amount of recompilations
be performed. In this mode @code{gnatmake} ignores time
stamp differences when the only
modifications to a source file consist in adding/removing comments,
empty lines, spaces or tabs. This means that if you have changed the
comments in a source file or have simply reformatted it, using this
switch will tell gnatmake not to recompile files that depend on it
(provided other sources on which these files depend have undergone no
semantic modifications). Note that the debugging information may be
out of date with respect to the sources if the @code{-m} switch causes
a compilation to be switched, so the use of this switch represents a
trade-off between compilation time and accurate debugging information.

@item ^-M^/DEPENDENCIES_LIST^
@cindex Dependencies, producing list
@cindex @code{^-M^/DEPENDENCIES_LIST^} (@code{gnatmake})
Check if all objects are up to date. If they are, output the object
dependences to @file{stdout} in a form that can be directly exploited in
a @file{Makefile}. By default, each source file is prefixed with its
(relative or absolute) directory name. This name is whatever you
specified in the various @code{^-aI^/SOURCE_SEARCH^}
and @code{^-I^/SEARCH^} switches. If you use
@code{gnatmake ^-M^/DEPENDENCIES_LIST^}
@code{^-q^/QUIET^}
(see below), only the source file names,
without relative paths, are output. If you just specify the
@code{^-M^/DEPENDENCIES_LIST^}
switch, dependencies of the GNAT internal system files are omitted. This
is typically what you want. If you also specify
the @code{^-a^/ALL_FILES^} switch,
dependencies of the GNAT internal files are also listed. Note that
dependencies of the objects in external Ada libraries (see switch
@code{^-aL^/SKIP_MISSING=^}@var{dir} in the following list) are never reported.

@item ^-n^/DO_OBJECT_CHECK^
@cindex @code{^-n^/DO_OBJECT_CHECK^} (@code{gnatmake})
Don't compile, bind, or link. Checks if all objects are up to date.
If they are not, the full name of the first file that needs to be
recompiled is printed.
Repeated use of this option, followed by compiling the indicated source
file, will eventually result in recompiling all required units.

@item ^-o ^/EXECUTABLE=^@var{exec_name}
@cindex @code{^-o^/EXECUTABLE^} (@code{gnatmake})
Output executable name. The name of the final executable program will be
@var{exec_name}. If the @code{^-o^/EXECUTABLE^} switch is omitted the default
name for the executable will be the name of the input file in appropriate form
for an executable file on the host system.

This switch cannot be used when invoking @code{gnatmake} with several
@file{file_names}.

@item ^-q^/QUIET^
@cindex @code{^-q^/QUIET^} (@code{gnatmake})
Quiet. When this flag is not set, the commands carried out by
@code{gnatmake} are displayed.

@item ^-s^/SWITCH_CHECK/^
@cindex @code{^-s^/SWITCH_CHECK^} (@code{gnatmake})
Recompile if compiler switches have changed since last compilation.
All compiler switches but -I and -o are taken into account in the
following way:
orders between different ``first letter'' switches are ignored, but
orders between same switches are taken into account. For example,
@code{-O -O2} is different than @code{-O2 -O}, but @code{-g -O} is equivalent
to @code{-O -g}.

@item ^-u^/UNIQUE^
@cindex @code{^-u^/UNIQUE^} (@code{gnatmake})
Unique. Recompile at most the main file. It implies -c. Combined with
-f, it is equivalent to calling the compiler directly.

@item ^-v^/REASONS^
@cindex @code{^-v^/REASONS^} (@code{gnatmake})
Verbose. Displays the reason for all recompilations @code{gnatmake}
decides are necessary.

@item ^-z^/NOMAIN^
@cindex @code{^-z^/NOMAIN^} (@code{gnatmake})
No main subprogram. Bind and link the program even if the unit name
given on the command line is a package name. The resulting executable
will execute the elaboration routines of the package and its closure,
then the finalization routines.

@item @code{gcc} @asis{switches}
@ifclear vms
The switch @code{-g} or any uppercase switch (other than @code{-A},
@code{-L} or
@code{-S}) or any switch that is more than one character is passed to
@code{gcc} (e.g. @code{-O}, @option{-gnato,} etc.)
@end ifclear
@ifset vms
Any qualifier that cannot be recognized as a qualifier for @code{GNAT MAKE}
but is recognizable as a valid qualifier for @code{GNAT COMPILE} is
automatically treated as a compiler switch, and passed on to all
compilations that are carried out.
@end ifset
@end table

@noindent
Source and library search path switches:

@table @code
@item ^-aI^/SOURCE_SEARCH=^@var{dir}
@cindex @code{^-aI^/SOURCE_SEARCH^} (@code{gnatmake})
When looking for source files also look in directory @var{dir}.
The order in which source files search is undertaken is
described in @ref{Search Paths and the Run-Time Library (RTL)}.

@item ^-aL^/SKIP_MISSING=^@var{dir}
@cindex @code{^-aL^/SKIP_MISSING^} (@code{gnatmake})
Consider @var{dir} as being an externally provided Ada library.
Instructs @code{gnatmake} to skip compilation units whose @file{.ali}
files have been located in directory @var{dir}. This allows you to have
missing bodies for the units in @var{dir} and to ignore out of date bodies
for the same units. You still need to specify
the location of the specs for these units by using the switches
@code{^-aI^/SOURCE_SEARCH=^@var{dir}}
or @code{^-I^/SEARCH=^@var{dir}}.
Note: this switch is provided for compatibility with previous versions
of @code{gnatmake}. The easier method of causing standard libraries
to be excluded from consideration is to write-protect the corresponding
ALI files.

@item ^-aO^/OBJECT_SEARCH=^@var{dir}
@cindex @code{^-aO^/OBJECT_SEARCH^} (@code{gnatmake})
When searching for library and object files, look in directory
@var{dir}. The order in which library files are searched is described in
@ref{Search Paths for gnatbind}.

@item ^-A^/CONDITIONAL_SOURCE_SEARCH=^@var{dir}
@cindex Search paths, for @code{gnatmake}
@cindex @code{^-A^/CONDITIONAL_SOURCE_SEARCH^} (@code{gnatmake})
Equivalent to @code{^-aL^/SKIP_MISSING=^@var{dir}
^-aI^/SOURCE_SEARCH=^@var{dir}}.

@item ^-I^/SEARCH=^@var{dir}
@cindex @code{^-I^/SEARCH^} (@code{gnatmake})
Equivalent to @code{^-aO^/OBJECT_SEARCH=^@var{dir}
^-aI^/SOURCE_SEARCH=^@var{dir}}.

@item ^-I-^/NOCURRENT_DIRECTORY^
@cindex @code{^-I-^/NOCURRENT_DIRECTORY^} (@code{gnatmake})
@cindex Source files, suppressing search
Do not look for source files in the directory containing the source
file named in the command line.
Do not look for ALI or object files in the directory
where @code{gnatmake} was invoked.

@item ^-L^/LIBRARY_SEARCH=^@var{dir}
@cindex @code{^-L^/LIBRARY_SEARCH^} (@code{gnatmake})
@cindex Linker libraries
Add directory @var{dir} to the list of directories in which the linker
@ifset wnt
Furthermore, under Windows, the sources pointed to by the libraries path
set in the registry are not searched for.
@end ifset
will search for libraries. This is equivalent to
@code{-largs ^-L^/LIBRARY_SEARCH=^}@var{dir}.

@item -nostdinc
@cindex @code{-nostdinc} (@code{gnatmake})
Do not look for source files in the system default directory.

@item -nostdlib
@cindex @code{-nostdlib} (@code{gnatmake})
Do not look for library files in the system default directory.

@item --RTS=@var{rts-path}
@cindex @code{--RTS} (@code{gnatmake})
Specifies the default location of the runtime library. We look for the runtime
in the following directories, and stop as soon as a valid runtime is found
("adainclude" or "ada_source_path", and "adalib" or "ada_object_path" present):

@itemize @bullet
@item <current directory>/$rts_path

@item <default-search-dir>/$rts_path

@item <default-search-dir>/rts-$rts_path
@end itemize

@noindent
The selected path is handled like a normal RTS path.

@end table

@node Mode Switches for gnatmake
@section Mode Switches for @code{gnatmake}

@noindent
The mode switches (referred to as @code{mode_switches}) allow the
inclusion of switches that are to be passed to the compiler itself, the
binder or the linker. The effect of a mode switch is to cause all
subsequent switches up to the end of the switch list, or up to the next
mode switch, to be interpreted as switches to be passed on to the
designated component of GNAT.

@table @code
@item -cargs @var{switches}
@cindex @code{-cargs} (@code{gnatmake})
Compiler switches. Here @var{switches} is a list of switches
that are valid switches for @code{gcc}. They will be passed on to
all compile steps performed by @code{gnatmake}.

@item -bargs @var{switches}
@cindex @code{-bargs} (@code{gnatmake})
Binder switches. Here @var{switches} is a list of switches
that are valid switches for @code{gcc}. They will be passed on to
all bind steps performed by @code{gnatmake}.

@item -largs @var{switches}
@cindex @code{-largs} (@code{gnatmake})
Linker switches. Here @var{switches} is a list of switches
that are valid switches for @code{gcc}. They will be passed on to
all link steps performed by @code{gnatmake}.
@end table

@node Notes on the Command Line
@section Notes on the Command Line

@noindent
This section contains some additional useful notes on the operation
of the @code{gnatmake} command.

@itemize @bullet
@item
@cindex Recompilation, by @code{gnatmake}
If @code{gnatmake} finds no ALI files, it recompiles the main program
and all other units required by the main program.
This means that @code{gnatmake}
can be used for the initial compile, as well as during subsequent steps of
the development cycle.

@item
If you enter @code{gnatmake @var{file}.adb}, where @file{@var{file}.adb}
is a subunit or body of a generic unit, @code{gnatmake} recompiles
@file{@var{file}.adb} (because it finds no ALI) and stops, issuing a
warning.

@item
In @code{gnatmake} the switch @code{^-I^/SEARCH^}
is used to specify both source and
library file paths. Use @code{^-aI^/SOURCE_SEARCH^}
instead if you just want to specify
source paths only and @code{^-aO^/OBJECT_SEARCH^}
if you want to specify library paths
only.

@item
@code{gnatmake} examines both an ALI file and its corresponding object file
for consistency. If an ALI is more recent than its corresponding object,
or if the object file is missing, the corresponding source will be recompiled.
Note that @code{gnatmake} expects an ALI and the corresponding object file
to be in the same directory.

@item
@code{gnatmake} will ignore any files whose ALI file is write-protected.
This may conveniently be used to exclude standard libraries from
consideration and in particular it means that the use of the
@code{^-f^/FORCE_COMPILE^} switch will not recompile these files
unless @code{^-a^/ALL_FILES^} is also specified.

@item
@code{gnatmake} has been designed to make the use of Ada libraries
particularly convenient. Assume you have an Ada library organized
as follows: @var{^obj-dir^[OBJ_DIR]^} contains the objects and ALI files for
of your Ada compilation units,
whereas @var{^include-dir^[INCLUDE_DIR]^} contains the
specs of these units, but no bodies. Then to compile a unit
stored in @code{main.adb}, which uses this Ada library you would just type

@smallexample
@ifclear vms
$ gnatmake -aI@var{include-dir}  -aL@var{obj-dir}  main
@end ifclear
@ifset vms
$ gnatmake /SOURCE_SEARCH=@var{[INCLUDE_DIR]}
           /SKIP_MISSING=@var{[OBJ_DIR]} main
@end ifset
@end smallexample

@item
Using @code{gnatmake} along with the
@code{^-m (minimal recompilation)^/MINIMAL_RECOMPILATION^}
switch provides a mechanism for avoiding unnecessary rcompilations. Using
this switch,
you can update the comments/format of your
source files without having to recompile everything. Note, however, that
adding or deleting lines in a source files may render its debugging
info obsolete. If the file in question is a spec, the impact is rather
limited, as that debugging info will only be useful during the
elaboration phase of your program. For bodies the impact can be more
significant. In all events, your debugger will warn you if a source file
is more recent than the corresponding object, and alert you to the fact
that the debugging information may be out of date.
@end itemize

@node How gnatmake Works
@section How @code{gnatmake} Works

@noindent
Generally @code{gnatmake} automatically performs all necessary
recompilations and you don't need to worry about how it works. However,
it may be useful to have some basic understanding of the @code{gnatmake}
approach and in particular to understand how it uses the results of
previous compilations without incorrectly depending on them.

First a definition: an object file is considered @dfn{up to date} if the
corresponding ALI file exists and its time stamp predates that of the
object file and if all the source files listed in the
dependency section of this ALI file have time stamps matching those in
the ALI file. This means that neither the source file itself nor any
files that it depends on have been modified, and hence there is no need
to recompile this file.

@code{gnatmake} works by first checking if the specified main unit is up
to date. If so, no compilations are required for the main unit. If not,
@code{gnatmake} compiles the main program to build a new ALI file that
reflects the latest sources. Then the ALI file of the main unit is
examined to find all the source files on which the main program depends,
and @code{gnatmake} recursively applies the above procedure on all these files.

This process ensures that @code{gnatmake} only trusts the dependencies
in an existing ALI file if they are known to be correct. Otherwise it
always recompiles to determine a new, guaranteed accurate set of
dependencies. As a result the program is compiled "upside down" from what may
be more familiar as the required order of compilation in some other Ada
systems. In particular, clients are compiled before the units on which
they depend. The ability of GNAT to compile in any order is critical in
allowing an order of compilation to be chosen that guarantees that
@code{gnatmake} will recompute a correct set of new dependencies if
necessary.

When invoking @code{gnatmake} with several @var{file_names}, if a unit is
imported by several of the executables, it will be recompiled at most once.

@node Examples of gnatmake Usage
@section Examples of @code{gnatmake} Usage

@table @code
@item gnatmake hello.adb
Compile all files necessary to bind and link the main program
@file{hello.adb} (containing unit @code{Hello}) and bind and link the
resulting object files to generate an executable file @file{^hello^HELLO.EXE^}.

@item gnatmake main1 main2 main3
Compile all files necessary to bind and link the main programs
@file{main1.adb} (containing unit @code{Main1}), @file{main2.adb}
(containing unit @code{Main2}) and @file{main3.adb}
(containing unit @code{Main3}) and bind and link the resulting object files
to generate three executable files @file{^main1^MAIN1.EXE^},
@file{^main2^MAIN2.EXE^}
and @file{^main3^MAIN3.EXE^}.

@ifclear vms
@item gnatmake -q Main_Unit -cargs -O2 -bargs -l
@end ifclear

@ifset vms
@item gnatmake Main_Unit /QUIET /COMPILER_QUALIFIERS /OPTIMIZE=ALL /BINDER_QUALIFIERS /ORDER_OF_ELABORATION
@end ifset
Compile all files necessary to bind and link the main program unit
@code{Main_Unit} (from file @file{main_unit.adb}). All compilations will
be done with optimization level 2 and the order of elaboration will be
listed by the binder. @code{gnatmake} will operate in quiet mode, not
displaying commands it is executing.
@end table

@node Renaming Files Using gnatchop
@chapter Renaming Files Using @code{gnatchop}
@findex gnatchop

@noindent
This chapter discusses how to handle files with multiple units by using
the @code{gnatchop} utility. This utility is also useful in renaming
files to meet the standard GNAT default file naming conventions.

@menu
* Handling Files with Multiple Units::
* Operating gnatchop in Compilation Mode::
* Command Line for gnatchop::
* Switches for gnatchop::
* Examples of gnatchop Usage::
@end menu

@node Handling Files with Multiple Units
@section Handling Files with Multiple Units

@noindent
The basic compilation model of GNAT requires that a file submitted to the
compiler have only one unit and there be a strict correspondence
between the file name and the unit name.

The @code{gnatchop} utility allows both of these rules to be relaxed,
allowing GNAT to process files which contain multiple compilation units
and files with arbitrary file names. @code{gnatchop}
reads the specified file and generates one or more output files,
containing one unit per file. The unit and the file name correspond,
as required by GNAT.

If you want to permanently restructure a set of "foreign" files so that
they match the GNAT rules, and do the remaining development using the
GNAT structure, you can simply use @code{gnatchop} once, generate the
new set of files and work with them from that point on.

Alternatively, if you want to keep your files in the "foreign" format,
perhaps to maintain compatibility with some other Ada compilation
system, you can set up a procedure where you use @code{gnatchop} each
time you compile, regarding the source files that it writes as temporary
files that you throw away.

@node Operating gnatchop in Compilation Mode
@section Operating gnatchop in Compilation Mode

@noindent
The basic function of @code{gnatchop} is to take a file with multiple units
and split it into separate files. The boundary between files is reasonably
clear, except for the issue of comments and pragmas. In default mode, the
rule is that any pragmas between units belong to the previous unit, except
that configuration pragmas always belong to the following unit. Any comments
belong to the following unit. These rules
almost always result in the right choice of
the split point without needing to mark it explicitly and most users will
find this default to be what they want. In this default mode it is incorrect to
submit a file containing only configuration pragmas, or one that ends in
configuration pragmas, to @code{gnatchop}.

However, using a special option to activate "compilation mode",
@code{gnatchop}
can perform another function, which is to provide exactly the semantics
required by the RM for handling of configuration pragmas in a compilation.
In the absence of configuration pragmas (at the main file level), this
option has no effect, but it causes such configuration pragmas to be handled
in a quite different manner.

First, in compilation mode, if @code{gnatchop} is given a file that consists of
only configuration pragmas, then this file is appended to the
@file{gnat.adc} file in the current directory. This behavior provides
the required behavior described in the RM for the actions to be taken
on submitting such a file to the compiler, namely that these pragmas
should apply to all subsequent compilations in the same compilation
environment. Using GNAT, the current directory, possibly containing a
@file{gnat.adc} file is the representation
of a compilation environment. For more information on the
@file{gnat.adc} file, see the section on handling of configuration
pragmas @pxref{Handling of Configuration Pragmas}.

Second, in compilation mode, if @code{gnatchop}
is given a file that starts with
configuration pragmas, and contains one or more units, then these
configuration pragmas are prepended to each of the chopped files. This
behavior provides the required behavior described in the RM for the
actions to be taken on compiling such a file, namely that the pragmas
apply to all units in the compilation, but not to subsequently compiled
units.

Finally, if configuration pragmas appear between units, they are appended
to the previous unit. This results in the previous unit being illegal,
since the compiler does not accept configuration pragmas that follow
a unit. This provides the required RM behavior that forbids configuration
pragmas other than those preceding the first compilation unit of a
compilation.

For most purposes, @code{gnatchop} will be used in default mode. The
compilation mode described above is used only if you need exactly
accurate behavior with respect to compilations, and you have files
that contain multiple units and configuration pragmas. In this
circumstance the use of @code{gnatchop} with the compilation mode
switch provides the required behavior, and is for example the mode
in which GNAT processes the ACVC tests.

@node Command Line for gnatchop
@section Command Line for @code{gnatchop}

@noindent
The @code{gnatchop} command has the form:

@smallexample
$ gnatchop switches @var{file name} [@var{file name} @var{file name} ...]
      [@var{directory}]
@end smallexample

@noindent
The only required argument is the file name of the file to be chopped.
There are no restrictions on the form of this file name. The file itself
contains one or more Ada units, in normal GNAT format, concatenated
together. As shown, more than one file may be presented to be chopped.

When run in default mode, @code{gnatchop} generates one output file in
the current directory for each unit in each of the files.

@var{directory}, if specified, gives the name of the directory to which
the output files will be written. If it is not specified, all files are
written to the current directory.

For example, given a
file called @file{hellofiles} containing

@smallexample
@group
@cartouche
@b{procedure} hello;

@b{with} Text_IO; @b{use} Text_IO;
@b{procedure} hello @b{is}
@b{begin}
   Put_Line ("Hello");
@b{end} hello;
@end cartouche
@end group
@end smallexample

@noindent
the command

@smallexample
$ gnatchop ^hellofiles^HELLOFILES.^
@end smallexample

@noindent
generates two files in the current directory, one called
@file{hello.ads} containing the single line that is the procedure spec,
and the other called @file{hello.adb} containing the remaining text. The
original file is not affected. The generated files can be compiled in
the normal manner.

@node Switches for gnatchop
@section Switches for @code{gnatchop}

@noindent
@code{gnatchop} recognizes the following switches:

@table @code

@item ^-c^/COMPILATION^
@cindex @code{^-c^/COMPILATION^} (@code{gnatchop})
Causes @code{gnatchop} to operate in compilation mode, in which
configuration pragmas are handled according to strict RM rules. See
previous section for a full description of this mode.

@ifclear vms
@item -gnatxxx
This passes the given @option{-gnatxxx} switch to @code{gnat} which is
used to parse the given file. Not all @code{xxx} options make sense,
but for example, the use of @option{-gnati2} allows @code{gnatchop} to
process a source file that uses Latin-2 coding for identifiers.
@end ifclear

@item ^-h^/HELP^
Causes @code{gnatchop} to generate a brief help summary to the standard
output file showing usage information.

@item ^-k@var{mm}^/FILE_NAME_MAX_LENGTH=@var{mm}^
@cindex @code{^-k^/FILE_NAME_MAX_LENGTH^} (@code{gnatchop})
Limit generated file names to the specified number @code{mm}
of characters.
This is useful if the
resulting set of files is required to be interoperable with systems
which limit the length of file names.
@ifset vms
If no value is given, or
if no @code{/FILE_NAME_MAX_LENGTH} qualifier is given,
a default of 39, suitable for OpenVMS Alpha
Systems, is assumed
@end ifset
@ifclear vms
No space is allowed between the @code{-k} and the numeric value. The numeric
value may be omitted in which case a default of @code{-k8},
suitable for use
with DOS-like file systems, is used. If no @code{-k} switch
is present then
there is no limit on the length of file names.
@end ifclear

@item ^-p^/PRESERVE^
@cindex @code{^-p^/PRESERVE^} (@code{gnatchop})
Causes the file ^modification^creation^ time stamp of the input file to be
preserved and used for the time stamp of the output file(s). This may be
useful for preserving coherency of time stamps in an enviroment where
@code{gnatchop} is used as part of a standard build process.

@item ^-q^/QUIET^
@cindex @code{^-q^/QUIET^} (@code{gnatchop})
Causes output of informational messages indicating the set of generated
files to be suppressed. Warnings and error messages are unaffected.

@item ^-r^/REFERENCE^
@cindex @code{^-r^/REFERENCE^} (@code{gnatchop})
@findex Source_Reference
Generate @code{Source_Reference} pragmas. Use this switch if the output
files are regarded as temporary and development is to be done in terms
of the original unchopped file. This switch causes
@code{Source_Reference} pragmas to be inserted into each of the
generated files to refers back to the original file name and line number.
The result is that all error messages refer back to the original
unchopped file.
In addition, the debugging information placed into the object file (when
the @code{^-g^/DEBUG^} switch of @code{gcc} or @code{gnatmake} is specified) also
refers back to this original file so that tools like profilers and
debuggers will give information in terms of the original unchopped file.

If the original file to be chopped itself contains
a @code{Source_Reference}
pragma referencing a third file, then gnatchop respects
this pragma, and the generated @code{Source_Reference} pragmas
in the chopped file refer to the original file, with appropriate
line numbers. This is particularly useful when @code{gnatchop}
is used in conjunction with @code{gnatprep} to compile files that
contain preprocessing statements and multiple units.

@item ^-v^/VERBOSE^
@cindex @code{^-v^/VERBOSE^} (@code{gnatchop})
Causes @code{gnatchop} to operate in verbose mode. The version
number and copyright notice are output, as well as exact copies of
the gnat1 commands spawned to obtain the chop control information.

@item ^-w^/OVERWRITE^
@cindex @code{^-w^/OVERWRITE^} (@code{gnatchop})
Overwrite existing file names. Normally @code{gnatchop} regards it as a
fatal error if there is already a file with the same name as a
file it would otherwise output, in other words if the files to be
chopped contain duplicated units. This switch bypasses this
check, and causes all but the last instance of such duplicated
units to be skipped.

@ifclear vms
@item --GCC=xxxx
@cindex @code{--GCC=} (@code{gnatchop})
Specify the path of the GNAT parser to be used. When this switch is used,
no attempt is made to add the prefix to the GNAT parser executable.
@end ifclear
@end table

@node Examples of gnatchop Usage
@section Examples of @code{gnatchop} Usage

@table @code
@ifset vms
@item gnatchop /OVERWRITE HELLO_S.ADA [ICHBIAH.FILES]
@end ifset
@ifclear vms
@item gnatchop -w hello_s.ada ichbiah/files
@end ifclear

Chops the source file @file{hello_s.ada}. The output files will be
placed in the directory @file{^ichbiah/files^[ICHBIAH.FILES]^},
overwriting any
files with matching names in that directory (no files in the current
directory are modified).

@item gnatchop ^archive^ARCHIVE.^
Chops the source file @file{^archive^ARCHIVE.^}
into the current directory. One
useful application of @code{gnatchop} is in sending sets of sources
around, for example in email messages. The required sources are simply
concatenated (for example, using a ^Unix @code{cat}^VMS @code{APPEND/NEW}^
command), and then
@code{gnatchop} is used at the other end to reconstitute the original
file names.

@item gnatchop file1 file2 file3 direc
Chops all units in files @file{file1}, @file{file2}, @file{file3}, placing
the resulting files in the directory @file{direc}. Note that if any units
occur more than once anywhere within this set of files, an error message
is generated, and no files are written. To override this check, use the
@code{^-w^/OVERWRITE^} switch,
in which case the last occurrence in the last file will
be the one that is output, and earlier duplicate occurrences for a given
unit will be skipped.
@end table

@node Configuration Pragmas
@chapter Configuration Pragmas
@cindex Configuration pragmas
@cindex Pragmas, configuration

@noindent
In Ada 95, configuration pragmas include those pragmas described as
such in the Ada 95 Reference Manual, as well as
implementation-dependent pragmas that are configuration pragmas. See the
individual descriptions of pragmas in the GNAT Reference Manual for
details on these additional GNAT-specific configuration pragmas. Most
notably, the pragma @code{Source_File_Name}, which allows
specifying non-default names for source files, is a configuration
pragma. The following is a complete list of configuration pragmas
recognized by @code{GNAT}:

@smallexample
   Ada_83
   Ada_95
   C_Pass_By_Copy
   Component_Alignment
   Discard_Names
   Elaboration_Checks
   Eliminate
   Extend_System
   Extensions_Allowed
   External_Name_Casing
   Float_Representation
   Initialize_Scalars
   License
   Locking_Policy
   Long_Float
   No_Run_Time
   Normalize_Scalars
   Polling
   Propagate_Exceptions
   Queuing_Policy
   Ravenscar
   Restricted_Run_Time
   Restrictions
   Reviewable
   Source_File_Name
   Style_Checks
   Suppress
   Task_Dispatching_Policy
   Unsuppress
   Use_VADS_Size
   Warnings
   Validity_Checks
@end smallexample

@menu
* Handling of Configuration Pragmas::
* The Configuration Pragmas Files::
@end menu

@node Handling of Configuration Pragmas
@section Handling of Configuration Pragmas

Configuration pragmas may either appear at the start of a compilation
unit, in which case they apply only to that unit, or they may apply to
all compilations performed in a given compilation environment.

GNAT also provides the @code{gnatchop} utility to provide an automatic
way to handle configuration pragmas following the semantics for
compilations (that is, files with multiple units), described in the RM.
See section @pxref{Operating gnatchop in Compilation Mode} for details.
However, for most purposes, it will be more convenient to edit the
@file{gnat.adc} file that contains configuration pragmas directly,
as described in the following section.

@node The Configuration Pragmas Files
@section The Configuration Pragmas Files
@cindex @file{gnat.adc}

@noindent
In GNAT a compilation environment is defined by the current
directory at the time that a compile command is given. This current
directory is searched for a file whose name is @file{gnat.adc}. If
this file is present, it is expected to contain one or more
configuration pragmas that will be applied to the current compilation.
However, if the switch @option{-gnatA} is used, @file{gnat.adc} is not
considered.

Configuration pragmas may be entered into the @file{gnat.adc} file
either by running @code{gnatchop} on a source file that consists only of
configuration pragmas, or more conveniently  by
direct editing of the @file{gnat.adc} file, which is a standard format
source file.

In addition to @file{gnat.adc}, one additional file containing configuration
pragmas may be applied to the current compilation using the switch
@option{-gnatec}@var{path}. @var{path} must designate an existing file that
contains only configuration pragmas. These configuration pragmas are
in addition to those found in @file{gnat.adc} (provided @file{gnat.adc}
is present and switch @option{-gnatA} is not used).

It is allowed to specify several switches @option{-gnatec}, however only
the last one on the command line will be taken into account.

@ifset vms
Of special interest to GNAT OpenVMS Alpha is the following configuration pragma:

@smallexample
@cartouche
@b{pragma} Extend_System (Aux_DEC);
@end cartouche
@end smallexample

@noindent
In the presence of this pragma, GNAT adds to the definition of the
predefined package SYSTEM all the additional types and subprograms that are
defined in DEC Ada. See @pxref{Compatibility with DEC Ada} for details.
@end ifset

@node Handling Arbitrary File Naming Conventions Using gnatname
@chapter Handling Arbitrary File Naming Conventions Using @code{gnatname}
@cindex Arbitrary File Naming Conventions

@menu
* Arbitrary File Naming Conventions::
* Running gnatname::
* Switches for gnatname::
* Examples of gnatname Usage::
@end menu

@node Arbitrary File Naming Conventions
@section Arbitrary File Naming Conventions

@noindent
The GNAT compiler must be able to know the source file name of a compilation unit.
When using the standard GNAT default file naming conventions (@code{.ads} for specs,
@code{.adb} for bodies), the GNAT compiler does not need additional information.

@noindent
When the source file names do not follow the standard GNAT default file naming
conventions, the GNAT compiler must be given additional information through
a configuration pragmas file (see @ref{Configuration Pragmas}) or a project file.
When the non standard file naming conventions are well-defined, a small number of
pragmas @code{Source_File_Name} specifying a naming pattern
(see @ref{Alternative File Naming Schemes}) may be sufficient. However,
if the file naming conventions are irregular or arbitrary, a number
of pragma @code{Source_File_Name} for individual compilation units must be defined.
To help maintain the correspondence between compilation unit names and
source file names within the compiler,
GNAT provides a tool @code{gnatname} to generate the required pragmas for a
set of files.

@node Running gnatname
@section Running @code{gnatname}

@noindent
The usual form of the @code{gnatname} command is

@smallexample
$ gnatname [@var{switches}] @var{naming_pattern} [@var{naming_patterns}]
@end smallexample

@noindent
All of the arguments are optional. If invoked without any argument,
@code{gnatname} will display its usage.

@noindent
When used with at least one naming pattern, @code{gnatname} will attempt to
find all the compilation units in files that follow at least one of the
naming patterns. To find these compilation units,
@code{gnatname} will use the GNAT compiler in syntax-check-only mode on all
regular files.

@noindent
One or several Naming Patterns may be given as arguments to @code{gnatname}.
Each Naming Pattern is enclosed between double quotes.
A Naming Pattern is a regular expression similar to the wildcard patterns
used in file names by the Unix shells or the DOS prompt.

@noindent
Examples of Naming Patterns are

@smallexample
   "*.[12].ada"
   "*.ad[sb]*"
   "body_*"    "spec_*"
@end smallexample

@noindent
For a more complete description of the syntax of Naming Patterns, see the second kind
of regular expressions described in @file{g-regexp.ads} (the "Glob" regular
expressions).

@noindent
When invoked with no switches, @code{gnatname} will create a configuration
pragmas file @file{gnat.adc} in the current working directory, with pragmas
@code{Source_File_Name} for each file that contains a valid Ada unit.

@node Switches for gnatname
@section Switches for @code{gnatname}

@noindent
Switches for @code{gnatname} must precede any specified Naming Pattern.

@noindent
You may specify any of the following switches to @code{gnatname}:

@table @code

@item -c@file{file}
@cindex @code{-c} (@code{gnatname})
Create a configuration pragmas file @file{file} (instead of the default
@file{gnat.adc}). There may be zero, one or more space between @code{-c} and
@file{file}. @file{file} may include directory information. @file{file} must be
writeable. There may be only one switch @code{-c}. When a switch @code{-c} is
specified, no switch @code{-P} may be specified (see below).

@item -d@file{dir}
@cindex @code{-d} (@code{gnatname})
Look for source files in directory @file{dir}. There may be zero, one or more spaces
between @code{-d} and @file{dir}. When a switch @code{-d} is specified,
the current working directory will not be searched for source files, unless it
is explictly
specified with a @code{-d} or @code{-D} switch. Several switches @code{-d} may be
specified. If @file{dir} is a relative path, it is relative to the directory of
the configuration pragmas file specified with switch @code{-c}, or to the directory
of the project file specified with switch @code{-P} or, if neither switch @code{-c}
nor switch @code{-P} are specified, it is relative to the current working
directory. The directory
specified with switch @code{-c} must exist and be readable.

@item -D@file{file}
@cindex @code{-D} (@code{gnatname})
Look for source files in all directories listed in text file @file{file}. There may be
zero, one or more spaces between @code{-d} and @file{dir}. @file{file}
must be an existing, readable text file. Each non empty line in @file{file} must be
a directory. Specifying switch @code{-D} is equivalent to specifying as many switches
@code{-d} as there are non empty lines in @file{file}.

@item -h
@cindex @code{-h} (@code{gnatname})
Output usage (help) information. The output is written to @file{stdout}.

@item -P@file{proj}
@cindex @code{-P} (@code{gnatname})
Create or update project file @file{proj}. There may be zero, one or more space
between @code{-P} and @file{proj}. @file{proj} may include directory information.
@file{proj} must be writeable. There may be only one switch @code{-P}.
When a switch @code{-P} is specified, no switch @code{-c} may be specified.

@item -v
@cindex @code{-v} (@code{gnatname})
Verbose mode. Output detailed explanation of behavior to @file{stdout}. This includes
name of the file written, the name of the directories to search and, for each file
in those directories whose name matches at least one of the Naming Patterns, an
indication of whether the file contains a unit, and if so the name of the unit.

@item -v -v
Very Verbose mode. In addition to the output produced in verbose mode, for each file
in the searched directories whose name matches none of the Naming Patterns, an
indication is given that there is no match.

@item -x@file{pattern}
Excluded patterns. Using this switch, it is possible to exclude some files
that would match the name patterns. For example,
@code{"gnatname -x "*_nt.ada" "*.ada"} will look for Ada units in all files
with the @file{.ada} extension, except those whose names end with
@file{_nt.ada}.

@end table

@node Examples of gnatname Usage
@section Examples of @code{gnatname} Usage

@smallexample
$ gnatname -c /home/me/names.adc -d sources "[a-z]*.ada*"
@end smallexample

In this example, the directory @file{/home/me} must already exist and be
writeable. In addition, the directory @file{/home/me/sources} (specified by
@code{-d sources}) must exist and be readable. Note the optional spaces after
@code{-c} and @code{-d}.

@smallexample
$ gnatname -P/home/me/proj -x "*_nt_body.ada" -dsources -dsources/plus -Dcommon_dirs.txt "body_*" "spec_*"
@end smallexample

Note that several switches @code{-d} may be used, even in conjunction with one
or several switches @code{-D}. Several Naming Patterns and one excluded pattern
are used in this example.


@c *****************************************
@c * G N A T  P r o j e c t  M a n a g e r *
@c *****************************************
@node GNAT Project Manager
@chapter GNAT Project Manager

@menu
* Introduction::
* Examples of Project Files::
* Project File Syntax::
* Objects and Sources in Project Files::
* Importing Projects::
* Project Extension::
* External References in Project Files::
* Packages in Project Files::
* Variables from Imported Projects::
* Naming Schemes::
* Library Projects::
* Switches Related to Project Files::
* Tools Supporting Project Files::
* An Extended Example::
* Project File Complete Syntax::
@end menu


@c ****************
@c * Introduction *
@c ****************

@node Introduction
@section Introduction

@noindent
This chapter describes GNAT's @emph{Project Manager}, a facility that
lets you configure various properties for a collection of source files.  In
particular, you can specify:
@itemize @bullet
@item
The directory or set of directories containing the source files, and/or the
names of the specific source files themselves
@item
The directory in which the compiler's output
(@file{ALI} files, object files, tree files) will be placed
@item
The directory in which the executable programs will be placed
@item
Switch settings for any of the project-enabled tools (@command{gnatmake},
compiler, binder, linker, @code{gnatls}, @code{gnatxref}, @code{gnatfind});
you can apply these settings either globally or to individual units
@item
The source files containing the main subprogram(s) to be built
@item
The source programming language(s) (currently Ada and/or C)
@item
Source file naming conventions; you can specify these either globally or for
individual units
@end itemize

@menu
* Project Files::
@end menu

@node Project Files
@subsection Project Files

@noindent
A @dfn{project} is a specific set of values for these properties.  You can
define a project's settings in a @dfn{project file}, a text file with an
Ada-like syntax; a property value is either a string or a list of strings.
Properties that are not explicitly set receive default values.  A project
file may interrogate the values of @dfn{external variables} (user-defined
command-line switches or environment variables), and it may specify property
settings conditionally, based on the value of such variables.

In simple cases, a project's source files depend only on other source files
in the same project, or on the predefined libraries.  ("Dependence" is in
the technical sense; for example, one Ada unit "with"ing another.)  However,
the Project Manager also allows much more sophisticated arrangements,
with the source files in one project depending on source files in other
projects:
@itemize @bullet
@item
One project can @emph{import} other projects containing needed source files.
@item
You can organize GNAT projects in a hierarchy: a @emph{child} project
can extend a @emph{parent} project, inheriting the parent's source files and
optionally overriding any of them with alternative versions
@end itemize

@noindent
More generally, the Project Manager lets you structure large development
efforts into hierarchical subsystems, with build decisions deferred to the
subsystem level and thus different compilation environments (switch settings)
used for different subsystems.

The Project Manager is invoked through the @option{-P@emph{projectfile}}
switch to @command{gnatmake} or to the @command{gnat} front driver.
If you want to define (on the command line) an external variable that is
queried by the project file, additionally use the
@option{-X@emph{vbl}=@emph{value}} switch.
The Project Manager parses and interprets the project file, and drives the
invoked tool based on the project settings.

The Project Manager supports a wide range of development strategies,
for systems of all sizes.  Some typical practices that are easily handled:
@itemize @bullet
@item
Using a common set of source files, but generating object files in different
directories via different switch settings
@item
Using a mostly-shared set of source files, but with different versions of
some unit or units
@end itemize

@noindent
The destination of an executable can be controlled inside a project file
using the @option{-o} switch. In the absence of such a switch either inside
the project file or on the command line, any executable files generated by
@command{gnatmake} will be placed in the directory @code{Exec_Dir} specified
in the project file. If no @code{Exec_Dir} is specified, they will be placed
in the object directory of the project.

You can use project files to achieve some of the effects of a source
versioning system (for example, defining separate projects for
the different sets of sources that comprise different releases) but the
Project Manager is independent of any source configuration management tools
that might be used by the developers.

The next section introduces the main features of GNAT's project facility
through a sequence of examples; subsequent sections will present the syntax
and semantics in more detail.


@c *****************************
@c * Examples of Project Files *
@c *****************************

@node Examples of Project Files
@section Examples of Project Files
@noindent
This section illustrates some of the typical uses of project files and
explains their basic structure and behavior.

@menu
* Common Sources with Different Switches and Different Output Directories::
* Using External Variables::
* Importing Other Projects::
* Extending a Project::
@end menu

@node Common Sources with Different Switches and Different Output Directories
@subsection Common Sources with Different Switches and Different Output Directories

@menu
* Source Files::
* Specifying the Object Directory::
* Specifying the Exec Directory::
* Project File Packages::
* Specifying Switch Settings::
* Main Subprograms::
* Source File Naming Conventions::
* Source Language(s)::
@end menu

@noindent
Assume that the Ada source files @file{pack.ads}, @file{pack.adb}, and
@file{proc.adb} are in the @file{/common} directory.  The file
@file{proc.adb} contains an Ada main subprogram @code{Proc} that "with"s
package @code{Pack}.  We want to compile these source files under two sets
of switches:
@itemize @bullet
@item
When debugging, we want to pass the @option{-g} switch to @command{gnatmake},
and the @option{-gnata}, @option{-gnato}, and @option{-gnatE} switches to the
compiler; the compiler's output is to appear in @file{/common/debug}
@item
When preparing a release version, we want to pass the @option{-O2} switch to
the compiler; the compiler's output is to appear in @file{/common/release}
@end itemize

@noindent
The GNAT project files shown below, respectively @file{debug.gpr} and
@file{release.gpr} in the @file{/common} directory, achieve these effects.

Diagrammatically:
@smallexample
@group
/common
  debug.gpr
  release.gpr
  pack.ads
  pack.adb
  proc.adb
@end group
@group
/common/debug @{-g, -gnata, -gnato, -gnatE@}
  proc.ali, proc.o
  pack.ali, pack.o
@end group
@group
/common/release @{-O2@}
  proc.ali, proc.o
  pack.ali, pack.o
@end group
@end smallexample
Here are the project files:
@smallexample
@group
project Debug is
  for Object_Dir use "debug";
  for Main use ("proc");

  package Builder is
    for Default_Switches ("Ada") use ("-g");
  end Builder;
@end group

@group
  package Compiler is
    for Default_Switches ("Ada")
       use ("-fstack-check", "-gnata", "-gnato", "-gnatE");
  end Compiler;
end Debug;
@end group
@end smallexample

@smallexample
@group
project Release is
  for Object_Dir use "release";
  for Exec_Dir use ".";
  for Main use ("proc");

  package Compiler is
    for Default_Switches ("Ada") use ("-O2");
  end Compiler;
end Release;
@end group
@end smallexample

@noindent
The name of the project defined by @file{debug.gpr} is @code{"Debug"} (case
insensitive), and analogously the project defined by @file{release.gpr} is
@code{"Release"}.  For consistency the file should have the same name as the
project, and the project file's extension should be @code{"gpr"}. These
conventions are not required, but a warning is issued if they are not followed.

If the current directory is @file{/temp}, then the command
@smallexample
gnatmake -P/common/debug.gpr
@end smallexample

@noindent
generates object and ALI files in @file{/common/debug}, and the @code{proc}
executable also in @file{/common/debug}, using the switch settings defined in
the project file.

Likewise, the command
@smallexample
gnatmake -P/common/release.gpr
@end smallexample

@noindent
generates object and ALI files in @file{/common/release}, and the @code{proc}
executable in @file{/common}, using the switch settings from the project file.

@node Source Files
@unnumberedsubsubsec Source Files

@noindent
If a project file does not explicitly specify a set of source directories or
a set of source files, then by default the project's source files are the
Ada source files in the project file directory.  Thus @file{pack.ads},
@file{pack.adb}, and @file{proc.adb} are the source files for both projects.

@node Specifying the Object Directory
@unnumberedsubsubsec Specifying the Object Directory

@noindent
Several project properties are modeled by Ada-style @emph{attributes};
you define the property by supplying the equivalent of an Ada attribute
definition clause in the project file.
A project's object directory is such a property; the corresponding
attribute is @code{Object_Dir}, and its value is a string expression.  A
directory may be specified either as absolute or as relative; in the latter
case, it is relative to the project file directory.  Thus the compiler's
output is directed to @file{/common/debug} (for the @code{Debug} project)
and to @file{/common/release} (for the @code{Release} project).  If
@code{Object_Dir} is not specified, then the default is the project file
directory.

@node Specifying the Exec Directory
@unnumberedsubsubsec Specifying the Exec Directory

@noindent
A project's exec directory is another property; the corresponding
attribute is @code{Exec_Dir}, and its value is also a string expression,
either specified as relative or absolute. If @code{Exec_Dir} is not specified,
then the default is the object directory (which may also be the project file
directory if attribute @code{Object_Dir} is not specified). Thus the executable
is placed in @file{/common/debug} for the @code{Debug} project (attribute
@code{Exec_Dir} not specified) and in @file{/common} for the @code{Release}
project.

@node Project File Packages
@unnumberedsubsubsec Project File Packages

@noindent
A GNAT tool integrated with the Project Manager is modeled by a
corresponding package in the project file.
The @code{Debug} project defines the packages @code{Builder}
(for @command{gnatmake}) and @code{Compiler};
the @code{Release} project defines only the @code{Compiler} package.

The Ada package syntax is not to be taken literally.  Although packages in
project files bear a surface resemblance to packages in Ada source code, the
notation is simply a way to convey a grouping of properties for a named
entity.  Indeed, the package names permitted in project files are restricted
to a predefined set, corresponding to the project-aware tools, and the contents
of packages are limited to a small set of constructs.
The packages in the example above contain attribute definitions.


@node Specifying Switch Settings
@unnumberedsubsubsec Specifying Switch Settings

@noindent
Switch settings for a project-aware tool can be specified through attributes
in the package corresponding to the tool.
The example above illustrates one of the relevant attributes,
@code{Default_Switches}, defined in the packages in both project files.
Unlike simple attributes like @code{Source_Dirs}, @code{Default_Switches} is
known as an @emph{associative array}.  When you define this attribute, you must
supply an "index" (a literal string), and the effect of the attribute
definition is to set the value of the "array" at the specified "index".
For the @code{Default_Switches} attribute, the index is a programming
language (in our case, Ada) , and the value specified (after @code{use})
must be a list of string expressions.

The attributes permitted in project files are restricted to a predefined set.
Some may appear at project level, others in packages.
For any attribute that is an associate array, the index must always be a
literal string, but the restrictions on this string (e.g., a file name or a
language name) depend on the individual attribute.
Also depending on the attribute, its specified value will need to be either a
string or a string list.

In the @code{Debug} project, we set the switches for two tools,
@command{gnatmake} and the compiler, and thus we include corresponding
packages, with each package defining the @code{Default_Switches} attribute
with index @code{"Ada"}.
Note that the package corresponding to
@command{gnatmake} is named @code{Builder}.  The @code{Release} project is
similar, but with just the @code{Compiler} package.

In project @code{Debug} above the switches starting with @option{-gnat} that
are specified in package @code{Compiler} could have been placed in package
@code{Builder}, since @command{gnatmake} transmits all such switches to the
compiler.

@node Main Subprograms
@unnumberedsubsubsec Main Subprograms

@noindent
One of the properties of a project is its list of main subprograms (actually
a list of names of source files containing main subprograms, with the file
extension optional.  This property is captured in the @code{Main} attribute,
whose value is a list of strings.  If a project defines the @code{Main}
attribute, then you do not need to identify the main subprogram(s) when
invoking @command{gnatmake} (see @ref{gnatmake and Project Files}).

@node Source File Naming Conventions
@unnumberedsubsubsec Source File Naming Conventions

@noindent
Since the project files do not specify any source file naming conventions,
the GNAT defaults are used.  The mechanism for defining source file naming
conventions -- a package named @code{Naming} -- will be described below
(@pxref{Naming Schemes}).

@node Source Language(s)
@unnumberedsubsubsec Source Language(s)

@noindent
Since the project files do not specify a @code{Languages} attribute, by
default the GNAT tools assume that the language of the project file is Ada.
More generally, a project can comprise source files
in Ada, C, and/or other languages.

@node Using External Variables
@subsection Using External Variables

@noindent
Instead of supplying different project files for debug and release, we can
define a single project file that queries an external variable (set either
on the command line or via an environment variable) in order to
conditionally define the appropriate settings.  Again, assume that the
source files @file{pack.ads}, @file{pack.adb}, and @file{proc.adb} are
located in directory @file{/common}.  The following project file,
@file{build.gpr}, queries the external variable named @code{STYLE} and
defines an object directory and switch settings based on whether the value
is @code{"deb"} (debug) or @code{"rel"} (release), where the default is
@code{"deb"}.

@smallexample
@group
project Build is
  for Main use ("proc");

  type Style_Type is ("deb", "rel");
  Style : Style_Type := external ("STYLE", "deb");

  case Style is
    when "deb" =>
      for Object_Dir use "debug";

    when "rel" =>
      for Object_Dir use "release";
      for Exec_Dir use ".";
  end case;
@end group

@group
  package Builder is

    case Style is
      when "deb" =>
        for Default_Switches ("Ada") use ("-g");
    end case;

  end Builder;
@end group

@group
  package Compiler is

    case Style is
      when "deb" =>
        for Default_Switches ("Ada") use ("-gnata", "-gnato", "-gnatE");

      when "rel" =>
        for Default_Switches ("Ada") use ("-O2");
    end case;

  end Compiler;

end Build;
@end group
@end smallexample

@noindent
@code{Style_Type} is an example of a @emph{string type}, which is the project
file analog of an Ada enumeration type but containing string literals rather
than identifiers.  @code{Style} is declared as a variable of this type.

The form @code{external("STYLE", "deb")} is known as an
@emph{external reference}; its first argument is the name of an
@emph{external variable}, and the second argument is a default value to be
used if the external variable doesn't exist.  You can define an external
variable on the command line via the @option{-X} switch, or you can use an
environment variable as an external variable.

Each @code{case} construct is expanded by the Project Manager based on the
value of @code{Style}. Thus the command
@smallexample
gnatmake -P/common/build.gpr -XSTYLE=deb
@end smallexample

@noindent
is equivalent to the @command{gnatmake} invocation using the project file
@file{debug.gpr} in the earlier example.  So is the command
@smallexample
gnatmake -P/common/build.gpr
@end smallexample

@noindent
since @code{"deb"} is the default for @code{STYLE}.

Analogously,
@smallexample
gnatmake -P/common/build.gpr -XSTYLE=rel
@end smallexample

@noindent
is equivalent to the @command{gnatmake} invocation using the project file
@file{release.gpr} in the earlier example.


@node Importing Other Projects
@subsection Importing Other Projects

@noindent
A compilation unit in a source file in one project may depend on compilation
units in source files in other projects.  To obtain this behavior, the
dependent project must @emph{import} the projects containing the needed source
files.  This effect is embodied in syntax similar to an Ada @code{with} clause,
but the "with"ed entities are strings denoting project files.

As an example, suppose that the two projects @code{GUI_Proj} and
@code{Comm_Proj} are defined in the project files @file{gui_proj.gpr} and
@file{comm_proj.gpr} in directories @file{/gui} and @file{/comm},
respectively.  Assume that the source files for @code{GUI_Proj} are
@file{gui.ads} and @file{gui.adb}, and that the source files for
@code{Comm_Proj} are @file{comm.ads} and @file{comm.adb}, with each set of
files located in its respective project file directory.  Diagrammatically:

@smallexample
@group
/gui
  gui_proj.gpr
  gui.ads
  gui.adb
@end group

@group
/comm
  comm_proj.gpr
  comm.ads
  comm.adb
@end group
@end smallexample

@noindent
We want to develop an application in directory @file{/app} that "with"s the
packages @code{GUI} and @code{Comm}, using the properties of the
corresponding project files (e.g. the switch settings and object directory).
Skeletal code for a main procedure might be something like the following:

@smallexample
@group
with GUI, Comm;
procedure App_Main is
   ...
begin
   ...
end App_Main;
@end group
@end smallexample

@noindent
Here is a project file, @file{app_proj.gpr}, that achieves the desired
effect:

@smallexample
@group
with "/gui/gui_proj", "/comm/comm_proj";
project App_Proj is
   for Main use ("app_main");
end App_Proj;
@end group
@end smallexample

@noindent
Building an executable is achieved through the command:
@smallexample
gnatmake -P/app/app_proj
@end smallexample
@noindent
which will generate the @code{app_main} executable in the directory where
@file{app_proj.gpr} resides.

If an imported project file uses the standard extension (@code{gpr}) then
(as illustrated above) the @code{with} clause can omit the extension.

Our example specified an absolute path for each imported project file.
Alternatively, you can omit the directory if either
@itemize @bullet
@item
The imported project file is in the same directory as the importing project
file, or
@item
You have defined an environment variable @code{ADA_PROJECT_PATH} that
includes the directory containing the needed project file.
@end itemize

@noindent
Thus, if we define @code{ADA_PROJECT_PATH} to include @file{/gui} and
@file{/comm}, then our project file @file{app_proj.gpr} could be written as
follows:

@smallexample
@group
with "gui_proj", "comm_proj";
project App_Proj is
   for Main use ("app_main");
end App_Proj;
@end group
@end smallexample

@noindent
Importing other projects raises the possibility of ambiguities.  For
example, the same unit might be present in different imported projects, or
it might be present in both the importing project and an imported project.
Both of these conditions are errors.  Note that in the current version of
the Project Manager, it is illegal to have an ambiguous unit even if the
unit is never referenced by the importing project.  This restriction may be
relaxed in a future release.

@node Extending a Project
@subsection Extending a Project

@noindent
A common situation in large software systems is to have multiple
implementations for a common interface; in Ada terms, multiple versions of a
package body for the same specification.  For example, one implementation
might be safe for use in tasking programs, while another might only be used
in sequential applications.  This can be modeled in GNAT using the concept
of @emph{project extension}.  If one project (the "child") @emph{extends}
another project (the "parent") then by default all source files of the
parent project are inherited by the child, but the child project can
override any of the parent's source files with new versions, and can also
add new files.  This facility is the project analog of extension in
Object-Oriented Programming.  Project hierarchies are permitted (a child
project may be the parent of yet another project), and a project that
inherits one project can also import other projects.

As an example, suppose that directory @file{/seq} contains the project file
@file{seq_proj.gpr} and the source files @file{pack.ads}, @file{pack.adb},
and @file{proc.adb}:

@smallexample
@group
/seq
  pack.ads
  pack.adb
  proc.adb
  seq_proj.gpr
@end group
@end smallexample

@noindent
Note that the project file can simply be empty (that is, no attribute or
package is defined):

@smallexample
@group
project Seq_Proj is
end Seq_Proj;
@end group
@end smallexample

@noindent
implying that its source files are all the Ada source files in the project
directory.

Suppose we want to supply an alternate version of @file{pack.adb}, in
directory @file{/tasking}, but use the existing versions of @file{pack.ads}
and @file{proc.adb}.  We can define a project @code{Tasking_Proj} that
inherits @code{Seq_Proj}:

@smallexample
@group
/tasking
  pack.adb
  tasking_proj.gpr
@end group

@group
project Tasking_Proj extends "/seq/seq_proj" is
end Tasking_Proj;
@end group
@end smallexample

@noindent
The version of @file{pack.adb} used in a build depends on which project file
is specified.

Note that we could have designed this using project import rather than
project inheritance; a @code{base} project would contain the sources for
@file{pack.ads} and @file{proc.adb}, a sequential project would import
@code{base} and add @file{pack.adb}, and likewise a tasking project would
import @code{base} and add a different version of @file{pack.adb}.  The
choice depends on whether other sources in the original project need to be
overridden.  If they do, then project extension is necessary, otherwise,
importing is sufficient.


@c ***********************
@c * Project File Syntax *
@c ***********************

@node Project File Syntax
@section Project File Syntax

@menu
* Basic Syntax::
* Packages::
* Expressions::
* String Types::
* Variables::
* Attributes::
* Associative Array Attributes::
* case Constructions::
@end menu

@noindent
This section describes the structure of project files.

A project may be an @emph{independent project}, entirely defined by a single
project file. Any Ada source file in an independent project depends only
on the predefined library and other Ada source files in the same project.

@noindent
A project may also @dfn{depend on} other projects, in either or both of the following ways:
@itemize @bullet
@item It may import any number of projects
@item It may extend at most one other project
@end itemize

@noindent
The dependence relation is a directed acyclic graph (the subgraph reflecting
the "extends" relation is a tree).

A project's @dfn{immediate sources} are the source files directly defined by
that project, either implicitly by residing in the project file's directory,
or explicitly through any of the source-related attributes described below.
More generally, a project @var{proj}'s @dfn{sources} are the immediate sources
of @var{proj} together with the immediate sources (unless overridden) of any
project on which @var{proj} depends (either directly or indirectly).

@node Basic Syntax
@subsection Basic Syntax

@noindent
As seen in the earlier examples, project files have an Ada-like syntax.
The minimal project file is:
@smallexample
@group
project Empty is

end Empty;
@end group
@end smallexample

@noindent
The identifier @code{Empty} is the name of the project.
This project name must be present after the reserved
word @code{end} at the end of the project file, followed by a semi-colon.

Any name in a project file, such as the project name or a variable name,
has the same syntax as an Ada identifier.

The reserved words of project files are the Ada reserved words plus
@code{extends}, @code{external}, and @code{project}.  Note that the only Ada
reserved words currently used in project file syntax are:

@itemize @bullet
@item
@code{case}
@item
@code{end}
@item
@code{for}
@item
@code{is}
@item
@code{others}
@item
@code{package}
@item
@code{renames}
@item
@code{type}
@item
@code{use}
@item
@code{when}
@item
@code{with}
@end itemize

@noindent
Comments in project files have the same syntax as in Ada, two consecutives
hyphens through the end of the line.

@node Packages
@subsection Packages

@noindent
A project file may contain @emph{packages}. The name of a package must be one
of the identifiers (case insensitive) from a predefined list, and a package
with a given name may only appear once in a project file. The predefined list
includes the following packages:

@itemize @bullet
@item
@code{Naming}
@item
@code{Builder}
@item
@code{Compiler}
@item
@code{Binder}
@item
@code{Linker}
@item
@code{Finder}
@item
@code{Cross_Reference}
@item
@code{gnatls}
@end itemize

@noindent
(The complete list of the package names and their attributes can be found
in file @file{prj-attr.adb}).

@noindent
In its simplest form, a package may be empty:

@smallexample
@group
project Simple is
  package Builder is
  end Builder;
end Simple;
@end group
@end smallexample

@noindent
A package may contain @emph{attribute declarations},
@emph{variable declarations} and @emph{case constructions}, as will be
described below.

When there is ambiguity between a project name and a package name,
the name always designates the project. To avoid possible confusion, it is
always a good idea to avoid naming a project with one of the
names allowed for packages or any name that starts with @code{gnat}.


@node Expressions
@subsection Expressions

@noindent
An @emph{expression} is either a @emph{string expression} or a
@emph{string list expression}.

A @emph{string expression} is either a @emph{simple string expression} or a
@emph{compound string expression}.

A @emph{simple string expression} is one of the following:
@itemize @bullet
@item A literal string; e.g.@code{"comm/my_proj.gpr"}
@item A string-valued variable reference (see @ref{Variables})
@item A string-valued attribute reference (see @ref{Attributes})
@item An external reference (see @ref{External References in Project Files})
@end itemize

@noindent
A @emph{compound string expression} is a concatenation of string expressions,
using @code{"&"}
@smallexample
       Path & "/" & File_Name & ".ads"
@end smallexample

@noindent
A @emph{string list expression} is either a
@emph{simple string list expression} or a
@emph{compound string list expression}.

A @emph{simple string list expression} is one of the following:
@itemize @bullet
@item A parenthesized list of zero or more string expressions, separated by commas
@smallexample
   File_Names := (File_Name, "gnat.adc", File_Name & ".orig");
   Empty_List := ();
@end smallexample
@item A string list-valued variable reference
@item A string list-valued attribute reference
@end itemize

@noindent
A @emph{compound string list expression} is the concatenation (using
@code{"&"}) of a simple string list expression and an expression.  Note that
each term in a compound string list expression, except the first, may be
either a string expression or a string list expression.

@smallexample
@group
   File_Name_List := () & File_Name; --  One string in this list
   Extended_File_Name_List := File_Name_List & (File_Name & ".orig");
   --  Two strings
   Big_List := File_Name_List & Extended_File_Name_List;
   --  Concatenation of two string lists: three strings
   Illegal_List := "gnat.adc" & Extended_File_Name_List;
   --  Illegal: must start with a string list
@end group
@end smallexample


@node String Types
@subsection String Types

@noindent
The value of a variable may be restricted to a list of string literals.
The restricted list of string literals is given in a
@emph{string type declaration}.

Here is an example of a string type declaration:

@smallexample
   type OS is ("NT, "nt", "Unix", "Linux", "other OS");
@end smallexample

@noindent
Variables of a string type are called @emph{typed variables}; all other
variables are called @emph{untyped variables}. Typed variables are
particularly useful in @code{case} constructions
(see @ref{case Constructions}).

A string type declaration starts with the reserved word @code{type}, followed
by the name of the string type (case-insensitive), followed by the reserved
word @code{is}, followed by a parenthesized list of one or more string literals
separated by commas, followed by a semicolon.

The string literals in the list are case sensitive and must all be different.
They may include any graphic characters allowed in Ada, including spaces.

A string type may only be declared at the project level, not inside a package.

A string type may be referenced by its name if it has been declared in the same
project file, or by its project name, followed by a dot,
followed by the string type name.


@node Variables
@subsection Variables

@noindent
A variable may be declared at the project file level, or in a package.
Here are some examples of variable declarations:

@smallexample
@group
   This_OS : OS := external ("OS"); --  a typed variable declaration
   That_OS := "Linux";              --  an untyped variable declaration
@end group
@end smallexample

@noindent
A @emph{typed variable declaration} includes the variable name, followed by a colon,
followed by the name of a string type, followed by @code{:=}, followed by
a simple string expression.

An @emph{untyped variable declaration} includes the variable name,
followed by @code{:=}, followed by an expression.  Note that, despite the
terminology, this form of "declaration" resembles more an assignment
than a declaration in Ada.  It is a declaration in several senses:
@itemize @bullet
@item
The variable name does not need to be defined previously
@item
The declaration establishes the @emph{kind} (string versus string list) of the
variable, and later declarations of the same variable need to be consistent
with this
@end itemize

@noindent
A string variable declaration (typed or untyped) declares a variable
whose value is a string. This variable may be used as a string expression.
@smallexample
   File_Name       := "readme.txt";
   Saved_File_Name := File_Name & ".saved";
@end smallexample

@noindent
A string list variable declaration declares a variable whose value is a list
of strings. The list may contain any number (zero or more) of strings.

@smallexample
   Empty_List := ();
   List_With_One_Element := ("-gnaty");
   List_With_Two_Elements := List_With_One_Element & "-gnatg";
   Long_List := ("main.ada", "pack1_.ada", "pack1.ada", "pack2_.ada"
                 "pack2.ada", "util_.ada", "util.ada");
@end smallexample

@noindent
The same typed variable may not be declared more than once at project level, and it may not be declared more than once in any package; it is in effect a constant or a readonly variable.

The same untyped variable may be declared several times.
In this case, the new value replaces the old one,
and any subsequent reference to the variable uses the new value.
However, as noted above, if a variable has been declared as a string, all subsequent
declarations must give it a string value. Similarly, if a variable has
been declared as a string list, all subsequent declarations
must give it a string list value.

A @emph{variable reference} may take several forms:

@itemize @bullet
@item The simple variable name, for a variable in the current package (if any) or in the current project
@item A context name, followed by a dot, followed by the variable name.
@end itemize

@noindent
A @emph{context} may be one of the following:

@itemize @bullet
@item The name of an existing package in the current project
@item The name of an imported project of the current project
@item The name of an ancestor project (i.e., a project extended by the current project, either directly or indirectly)
@item An imported/parent project name, followed by a dot, followed by a package name
@end itemize

@noindent
A variable reference may be used in an expression.


@node Attributes
@subsection Attributes

@noindent
A project (and its packages) may have @emph{attributes} that define the project's properties.
Some attributes have values that are strings;
others have values that are string lists.

There are two categories of attributes: @emph{simple attributes} and @emph{associative arrays}
(see @ref{Associative Array Attributes}).

The names of the attributes are restricted; there is a list of project
attributes, and a list of package attributes for each package.
The names are not case sensitive.

The project attributes are as follows (all are simple attributes):

@multitable @columnfractions .4 .3
@item @emph{Attribute Name}
@tab @emph{Value}
@item @code{Source_Files}
@tab string list
@item @code{Source_Dirs}
@tab string list
@item @code{Source_List_File}
@tab string
@item @code{Object_Dir}
@tab string
@item @code{Exec_Dir}
@tab string
@item @code{Main}
@tab string list
@item @code{Languages}
@tab string list
@item @code{Library_Dir}
@tab string
@item @code{Library_Name}
@tab string
@item @code{Library_Kind}
@tab string
@item @code{Library_Elaboration}
@tab string
@item @code{Library_Version}
@tab string
@end multitable

@noindent
The attributes for package @code{Naming} are as follows
(see @ref{Naming Schemes}):

@multitable @columnfractions .4 .2 .2 .2
@item Attribute Name @tab Category @tab Index @tab Value
@item @code{Specification_Suffix}
@tab associative array
@tab language name
@tab string
@item @code{Implementation_Suffix}
@tab associative array
@tab language name
@tab string
@item @code{Separate_Suffix}
@tab simple attribute
@tab n/a
@tab string
@item @code{Casing}
@tab simple attribute
@tab n/a
@tab string
@item @code{Dot_Replacement}
@tab simple attribute
@tab n/a
@tab string
@item @code{Specification}
@tab associative array
@tab Ada unit name
@tab string
@item @code{Implementation}
@tab associative array
@tab Ada unit name
@tab string
@item @code{Specification_Exceptions}
@tab associative array
@tab language name
@tab string list
@item @code{Implementation_Exceptions}
@tab associative array
@tab language name
@tab string list
@end multitable

@noindent
The attributes for package @code{Builder}, @code{Compiler}, @code{Binder},
@code{Linker}, @code{Cross_Reference}, and @code{Finder}
are as follows (see @ref{Switches and Project Files}).

@multitable @columnfractions .4 .2 .2 .2
@item Attribute Name @tab Category @tab Index @tab Value
@item @code{Default_Switches}
@tab associative array
@tab language name
@tab string list
@item @code{Switches}
@tab associative array
@tab file name
@tab string list
@end multitable

@noindent
In addition, package @code{Builder} has a single string attribute
@code{Local_Configuration_Pragmas} and package @code{Builder} has a single
string attribute @code{Global_Configuration_Pragmas}.

@noindent
The attribute for package @code{Glide} are not documented: they are for
internal use only.

@noindent
Each simple attribute has a default value: the empty string (for string-valued
attributes) and the empty list (for string list-valued attributes).

Similar to variable declarations, an attribute declaration defines a new value
for an attribute.

Examples of simple attribute declarations:

@smallexample
   for Object_Dir use "objects";
   for Source_Dirs use ("units", "test/drivers");
@end smallexample

@noindent
A @dfn{simple attribute declaration} starts with the reserved word @code{for},
followed by the name of the attribute, followed by the reserved word
@code{use}, followed by an expression (whose kind depends on the attribute),
followed by a semicolon.

Attributes may be referenced in expressions.
The general form for such a reference is @code{<entity>'<attribute>}:
the entity for which the attribute is defined,
followed by an apostrophe, followed by the name of the attribute.
For associative array attributes, a litteral string between parentheses
need to be supplied as index.

Examples are:

@smallexample
  project'Object_Dir
  Naming'Dot_Replacement
  Imported_Project'Source_Dirs
  Imported_Project.Naming'Casing
  Builder'Default_Switches("Ada")
@end smallexample

@noindent
The entity may be:
@itemize @bullet
@item @code{project} for an attribute of the current project
@item The name of an existing package of the current project
@item The name of an imported project
@item The name of a parent project (extended by the current project)
@item An imported/parent project name, followed by a dot,
      followed by a package name
@end itemize

@noindent
Example:
@smallexample
@group
   project Prj is
     for Source_Dirs use project'Source_Dirs & "units";
     for Source_Dirs use project'Source_Dirs & "test/drivers"
   end Prj;
@end group
@end smallexample

@noindent
In the first attribute declaration, initially the attribute @code{Source_Dirs}
has the default value: an empty string list. After this declaration,
@code{Source_Dirs} is a string list of one element: "units".
After the second attribute declaration @code{Source_Dirs} is a string list of
two elements: "units" and "test/drivers".

Note: this example is for illustration only. In practice,
the project file would contain only one attribute declaration:

@smallexample
   for Source_Dirs use ("units", "test/drivers");
@end smallexample


@node Associative Array Attributes
@subsection Associative Array Attributes

@noindent
Some attributes are defined as @emph{associative arrays}. An associative
array may be regarded as a function that takes a string as a parameter
and delivers a string or string list value as its result.

Here are some examples of associative array attribute declarations:

@smallexample
   for Implementation ("main") use "Main.ada";
   for Switches ("main.ada") use ("-v", "-gnatv");
   for Switches ("main.ada") use Builder'Switches ("main.ada") & "-g";
@end smallexample

@noindent
Like untyped variables and simple attributes, associative array attributes may be declared several times. Each declaration supplies a new value for the
attribute, replacing the previous setting.


@node case Constructions
@subsection @code{case} Constructions

@noindent
A @code{case} construction is used in a project file to effect conditional
behavior.
Here is a typical example:

@smallexample
@group
project MyProj is
   type OS_Type is ("Linux", "Unix", "NT", "VMS");

   OS : OS_Type := external ("OS", "Linux");
@end group

@group
   package Compiler is
     case OS is
       when "Linux" | "Unix" =>
         for Default_Switches ("Ada") use ("-gnath");
       when "NT" =>
         for Default_Switches ("Ada") use ("-gnatP");
       when others =>
     end case;
   end Compiler;
end MyProj;
@end group
@end smallexample

@noindent
The syntax of a @code{case} construction is based on the Ada case statement
(although there is no @code{null} construction for empty alternatives).

Following the reserved word @code{case} there is the case variable (a typed
string variable), the reserved word @code{is}, and then a sequence of one or
more alternatives.
Each alternative comprises the reserved word @code{when}, either a list of
literal strings separated by the @code{"|"} character or the reserved word
@code{others},  and the @code{"=>"} token.
Each literal string must belong to the string type that is the type of the
case variable.
An @code{others} alternative, if present, must occur last.
The @code{end case;} sequence terminates the case construction.

After each @code{=>}, there are zero or more constructions.  The only
constructions allowed in a case construction are other case constructions and
attribute declarations. String type declarations, variable declarations and
package declarations are not allowed.

The value of the case variable is often given by an external reference
(see @ref{External References in Project Files}).


@c ****************************************
@c * Objects and Sources in Project Files *
@c ****************************************

@node Objects and Sources in Project Files
@section Objects and Sources in Project Files

@menu
* Object Directory::
* Exec Directory::
* Source Directories::
* Source File Names::
@end menu

@noindent
Each project has exactly one object directory and one or more source
directories. The source directories must contain at least one source file,
unless  the project file explicitly specifies that no source files are present
(see @ref{Source File Names}).


@node Object Directory
@subsection Object Directory

@noindent
The object directory for a project is the directory containing the compiler's
output (such as @file{ALI} files and object files) for the project's immediate
sources. Note that for inherited sources (when extending a parent project) the
parent project's object directory is used.

The object directory is given by the value of the attribute @code{Object_Dir}
in the project file.

@smallexample
   for Object_Dir use "objects";
@end smallexample

@noindent
The attribute @var{Object_Dir} has a string value, the path name of the object
directory. The path name may be absolute or relative to the directory of the
project file. This directory must already exist, and be readable and writable.

By default, when the attribute @code{Object_Dir} is not given an explicit value
or when its value is the empty string, the object directory is the same as the
directory containing the project file.


@node Exec Directory
@subsection Exec Directory

@noindent
The exec directory for a project is the directory containing the executables
for the project's main subprograms.

The exec directory is given by the value of the attribute @code{Exec_Dir}
in the project file.

@smallexample
   for Exec_Dir use "executables";
@end smallexample

@noindent
The attribute @var{Exec_Dir} has a string value, the path name of the exec
directory. The path name may be absolute or relative to the directory of the
project file. This directory must already exist, and be writable.

By default, when the attribute @code{Exec_Dir} is not given an explicit value
or when its value is the empty string, the exec directory is the same as the
object directory of the project file.


@node Source Directories
@subsection Source Directories

@noindent
The source directories of a project are specified by the project file
attribute @code{Source_Dirs}.

This attribute's value is a string list. If the attribute is not given an
explicit value, then there is only one source directory, the one where the
project file resides.

A @code{Source_Dirs} attribute that is explicitly defined to be the empty list,
as in

@smallexample
    for Source_Dirs use ();
@end smallexample

@noindent
indicates that the project contains no source files.

Otherwise, each string in the string list designates one or more
source directories.

@smallexample
   for Source_Dirs use ("sources", "test/drivers");
@end smallexample

@noindent
If a string in the list ends with @code{"/**"},  then the directory whose path
name precedes the two asterisks, as well as all its subdirectories
(recursively), are source directories.

@smallexample
   for Source_Dirs use ("/system/sources/**");
@end smallexample

@noindent
Here the directory @code{/system/sources} and all of its subdirectories
(recursively) are source directories.

To specify that the source directories are the directory of the project file
and all of its subdirectories, you can declare @code{Source_Dirs} as follows:
@smallexample
   for Source_Dirs use ("./**");
@end smallexample

@noindent
Each of the source directories must exist and be readable.


@node Source File Names
@subsection Source File Names

@noindent
In a project that contains source files, their names may be specified by the
attributes @code{Source_Files} (a string list) or @code{Source_List_File}
(a string). Source file names never include any directory information.

If the attribute @code{Source_Files} is given an explicit value, then each
element of the list is a source file name.

@smallexample
   for Source_Files use ("main.adb");
   for Source_Files use ("main.adb", "pack1.ads", "pack2.adb");
@end smallexample

@noindent
If the attribute @code{Source_Files} is not given an explicit value,
but the attribute @code{Source_List_File} is given a string value,
then the source file names are contained in the text file whose path name
(absolute or relative to the directory of the project file) is the
value of the attribute @code{Source_List_File}.

Each line in the file that is not empty or is not a comment
contains a source file name. A comment line starts with two hyphens.

@smallexample
   for Source_List_File use "source_list.txt";
@end smallexample

@noindent
By default, if neither the attribute @code{Source_Files} nor the attribute
@code{Source_List_File} is given an explicit value, then each file in the
source directories that conforms to the project's naming scheme
(see @ref{Naming Schemes}) is an immediate source of the project.

A warning is issued if both attributes @code{Source_Files} and
@code{Source_List_File} are given explicit values. In this case, the attribute
@code{Source_Files} prevails.

Each source file name must be the name of one and only one existing source file
in one of the source directories.

A @code{Source_Files} attribute defined with an empty list as its value
indicates that there are no source files in the project.

Except for projects that are clearly specified as containing no Ada source
files (@code{Source_Dirs} or @code{Source_Files} specified as an empty list,
or @code{Languages} specified without @code{"Ada"} in the list)
@smallexample
   for Source_Dirs use ();
   for Source_Files use ();
   for Languages use ("C", "C++");
@end smallexample

@noindent
a project must contain at least one immediate source.

Projects with no source files are useful as template packages
(see @ref{Packages in Project Files}) for other projects; in particular to
define a package @code{Naming} (see @ref{Naming Schemes}).


@c ****************************
@c * Importing Projects *
@c ****************************

@node  Importing Projects
@section Importing Projects

@noindent
An immediate source of a project P may depend on source files that
are neither immediate sources of P nor in the predefined library.
To get this effect, P must @emph{import} the projects that contain the needed
source files.

@smallexample
@group
  with "project1", "utilities.gpr";
  with "/namings/apex.gpr";
  project Main is
    ...
@end group
@end smallexample

@noindent
As can be seen in this example, the syntax for importing projects is similar
to the syntax for importing compilation units in Ada. However, project files
use literal strings instead of names, and the @code{with} clause identifies
project files rather than packages.

Each literal string is the file name or path name (absolute or relative) of a
project file. If a string is simply a file name, with no path, then its
location is determined by the @emph{project path}:

@itemize @bullet
@item
If the environment variable @env{ADA_PROJECT_PATH} exists, then the project
path includes all the directories in this environment variable, plus the
directory of the project file.

@item
If the environment variable @env{ADA_PROJECT_PATH} does not exist,
then the project path contains only one directory, namely the one where
the project file is located.
@end itemize

@noindent
If a relative pathname is used as in

@smallexample
  with "tests/proj";
@end smallexample

@noindent
then the path is relative to the directory where the importing project file is
located. Any symbolic link will be fully resolved in the directory
of the importing project file before the imported project file is looked up.

When the @code{with}'ed project file name does not have an extension,
the default is @file{.gpr}. If a file with this extension is not found, then
the file name as specified in the @code{with} clause (no extension) will be
used. In the above example, if a file @code{project1.gpr} is found, then it
will be used; otherwise, if a file @code{project1} exists then it will be used;
if neither file exists, this is an error.

A warning is issued if the name of the project file does not match the
name of the project; this check is case insensitive.

Any source file that is an immediate source of the imported project can be
used by the immediate sources of the importing project, and recursively. Thus
if @code{A} imports @code{B}, and @code{B} imports @code{C}, the immediate
sources of @code{A} may depend on the immediate sources of @code{C}, even if
@code{A} does not import @code{C} explicitly. However, this is not recommended,
because if and when @code{B} ceases to import @code{C}, some sources in
@code{A} will no longer compile.

A side effect of this capability is that cyclic dependences are not permitted:
if @code{A} imports @code{B} (directly or indirectly) then @code{B} is not
allowed to import @code{A}.


@c *********************
@c * Project Extension *
@c *********************

@node Project Extension
@section Project Extension

@noindent
During development of a large system, it is sometimes necessary to use
modified versions of some of the source files without changing the original
sources. This can be achieved through a facility known as
@emph{project extension}.

@smallexample
   project Modified_Utilities extends "/baseline/utilities.gpr" is ...
@end smallexample

@noindent
The project file for the project being extended (the @emph{parent}) is
identified by the literal string that follows the reserved word @code{extends},
which itself follows the name of the extending project (the @emph{child}).

By default, a child project inherits all the sources of its parent.
However, inherited sources can be overridden: a unit with the same name as one
in the parent will hide the original unit.
Inherited sources are considered to be sources (but not immediate sources)
of the child project; see @ref{Project File Syntax}.

An inherited source file retains any switches specified in the parent project.

For example if the project @code{Utilities} contains the specification and the
body of an Ada package @code{Util_IO}, then the project
@code{Modified_Utilities} can contain a new body for package @code{Util_IO}.
The original body of @code{Util_IO} will not be considered in program builds.
However, the package specification will still be found in the project
@code{Utilities}.

A child project can have only one parent but it may import any number of other
projects.

A project is not allowed to import directly or indirectly at the same time a
child project and any of its ancestors.


@c ****************************************
@c * External References in Project Files *
@c ****************************************

@node  External References in Project Files
@section External References in Project Files

@noindent
A project file may contain references to external variables; such references
are called @emph{external references}.

An external variable is either defined as part of the environment (an
environment variable in Unix, for example) or else specified on the command
line via the @option{-X@emph{vbl}=@emph{value}} switch. If both, then the
command line value is used.

An external reference is denoted by the built-in function
@code{external}, which returns a string value.  This function has two forms:
@itemize @bullet
@item @code{external (external_variable_name)}
@item @code{external (external_variable_name, default_value)}
@end itemize

@noindent
Each parameter must be a string literal.  For example:

@smallexample
   external ("USER")
   external ("OS", "Linux")
@end smallexample

@noindent
In the form with one parameter, the function returns the value of
the external variable given as parameter. If this name is not present in the
environment, then the returned value is an empty string.

In the form with two string parameters, the second parameter is
the value returned when the variable given as the first parameter is not
present in the environment. In the example above, if @code{"OS"} is not
the name of an environment variable and is not passed on the command line,
then the returned value will be @code{"Linux"}.

An external reference may be part of a string expression or of a string
list expression, to define variables or attributes.

@smallexample
@group
   type Mode_Type is ("Debug", "Release");
   Mode : Mode_Type := external ("MODE");
   case Mode is
     when "Debug" =>
        ...
@end group
@end smallexample


@c *****************************
@c * Packages in Project Files *
@c *****************************

@node  Packages in Project Files
@section Packages in Project Files

@noindent
The @emph{package} is the project file feature that defines the settings for
project-aware tools.
For each such tool you can declare a corresponding package; the names for these
packages are preset (see @ref{Packages}) but are not case sensitive.
A package may contain variable declarations, attribute declarations, and case
constructions.

@smallexample
@group
   project Proj is
      package Builder is  -- used by gnatmake
         for Default_Switches ("Ada") use ("-v", "-g");
      end Builder;
   end Proj;
@end group
@end smallexample

@noindent
A package declaration starts with the reserved word @code{package},
followed by the package name (case insensitive), followed by the reserved word
@code{is}. It ends with the reserved word @code{end}, followed by the package
name, finally followed by a semi-colon.

Most of the packages have an attribute @code{Default_Switches}.
This attribute is an associative array, and its value is a string list.
The index of the associative array is the name of a programming language (case
insensitive). This attribute indicates the switch or switches to be used
with the corresponding tool.

Some packages also have another attribute, @code{Switches}, an associative
array whose value is a string list. The index is the name of a source file.
This attribute indicates the switch or switches to be used by the corresponding
tool when dealing with this specific file.

Further information on these switch-related attributes is found in
@ref{Switches and Project Files}.

A package may be declared as a @emph{renaming} of another package; e.g., from
the project file for an imported project.

@smallexample
@group
  with "/global/apex.gpr";
  project Example is
    package Naming renames Apex.Naming;
    ...
  end Example;
@end group
@end smallexample

@noindent
Packages that are renamed in other project files often come from project files
that have no sources: they are just used as templates. Any modification in the
template will be reflected automatically in all the project files that rename
a package from the template.

In addition to the tool-oriented packages, you can also declare a package
named @code{Naming} to establish specialized source file naming conventions
(see @ref{Naming Schemes}).


@c ************************************
@c * Variables from Imported Projects *
@c ************************************

@node Variables from Imported Projects
@section Variables from Imported Projects

@noindent
An attribute or variable defined in an imported or parent project can
be used in expressions in the importing / extending project.
Such an attribute or variable is prefixed with the name of the project
and (if relevant) the name of package where it is defined.

@smallexample
@group
  with "imported";
  project Main extends "base" is
     Var1 := Imported.Var;
     Var2 := Base.Var & ".new";
@end group

@group
     package Builder is
        for Default_Switches ("Ada") use Imported.Builder.Ada_Switches &
                         "-gnatg" & "-v";
     end Builder;
@end group

@group
     package Compiler is
        for Default_Switches ("Ada") use Base.Compiler.Ada_Switches;
     end Compiler;
  end Main;
@end group
@end smallexample

@noindent
In this example:

@itemize @bullet
@item
@code{Var1} is a copy of the variable @code{Var} defined in the project file
@file{"imported.gpr"}
@item
the value of @code{Var2} is a copy of the value of variable @code{Var}
defined in the project file @file{base.gpr}, concatenated with @code{".new"}
@item
attribute @code{Default_Switches ("Ada")} in package @code{Builder}
is a string list that includes in its value a copy of variable
@code{Ada_Switches} defined in the @code{Builder} package in project file
@file{imported.gpr} plus two new elements: @option{"-gnatg"} and @option{"-v"};
@item
attribute @code{Default_Switches ("Ada")} in package @code{Compiler}
is a copy of the variable @code{Ada_Switches} defined in the @code{Compiler}
package in project file @file{base.gpr}, the project being extended.
@end itemize


@c ******************
@c * Naming Schemes *
@c ******************

@node  Naming Schemes
@section Naming Schemes

@noindent
Sometimes an Ada software system is ported from a foreign compilation
environment to GNAT, with file names that do not use the default GNAT
conventions. Instead of changing all the file names (which for a variety of
reasons might not be possible), you can define the relevant file naming scheme
in the @code{Naming} package in your project file.  For example, the following
package models the Apex file naming rules:

@smallexample
@group
  package Naming is
    for Casing                        use "lowercase";
    for Dot_Replacement               use ".";
    for Specification_Suffix ("Ada")  use ".1.ada";
    for Implementation_Suffix ("Ada") use ".2.ada";
  end Naming;
@end group
@end smallexample

@noindent
You can define the following attributes in package @code{Naming}:

@table @code

@item @var{Casing}
This must be a string with one of the three values @code{"lowercase"},
@code{"uppercase"} or @code{"mixedcase"}; these strings are case insensitive.

@noindent
If @var{Casing} is not specified, then the default is @code{"lowercase"}.

@item @var{Dot_Replacement}
This must be a string whose value satisfies the following conditions:

@itemize @bullet
@item It must not be empty
@item It cannot start or end with an alphanumeric character
@item It cannot be a single underscore
@item It cannot start with an underscore followed by an alphanumeric
@item It cannot contain a dot @code{'.'} except if it the entire string is @code{"."}
@end itemize

@noindent
If @code{Dot_Replacement} is not specified, then the default is @code{"-"}.

@item @var{Specification_Suffix}
This is an associative array (indexed by the programming language name, case
insensitive) whose value is a string that must satisfy the following
conditions:

@itemize @bullet
@item It must not be empty
@item It cannot start with an alphanumeric character
@item It cannot start with an underscore followed by an alphanumeric character
@end itemize
@noindent
If @code{Specification_Suffix ("Ada")} is not specified, then the default is
@code{".ads"}.

@item @var{Implementation_Suffix}
This is an associative array (indexed by the programming language name, case
insensitive) whose value is a string that must satisfy the following
conditions:

@itemize @bullet
@item It must not be empty
@item It cannot start with an alphanumeric character
@item It cannot start with an underscore followed by an alphanumeric character
@item It cannot be a suffix of @code{Specification_Suffix}
@end itemize
@noindent
If @code{Implementation_Suffix ("Ada")} is not specified, then the default is
@code{".adb"}.

@item @var{Separate_Suffix}
This must be a string whose value satisfies the same conditions as
@code{Implementation_Suffix}.

@noindent
If @code{Separate_Suffix ("Ada")} is not specified, then it defaults to same
value as @code{Implementation_Suffix ("Ada")}.

@item @var{Specification}
@noindent
You can use the @code{Specification} attribute, an associative array, to define
the source file name for an individual Ada compilation unit's spec. The array
index must be a string literal that identifies the Ada unit (case insensitive).
The value of this attribute must be a string that identifies the file that
contains this unit's spec (case sensitive or insensitive depending on the
operating system).

@smallexample
   for Specification ("MyPack.MyChild") use "mypack.mychild.spec";
@end smallexample

@item @var{Implementation}

You can use the @code{Implementation} attribute, an associative array, to
define the source file name for an individual Ada compilation unit's body
(possibly a subunit).  The array index must be a string literal that identifies
the Ada unit (case insensitive).  The value of this attribute must be a string
that identifies the file that contains this unit's body or subunit (case
sensitive or insensitive depending on the operating system).

@smallexample
   for Implementation ("MyPack.MyChild") use "mypack.mychild.body";
@end smallexample
@end table


@c ********************
@c * Library Projects *
@c ********************

@node Library Projects
@section Library Projects

@noindent
@emph{Library projects} are projects whose object code is placed in a library.
(Note that this facility is not yet supported on all platforms)

To create a library project, you need to define in its project file
two project-level attributes: @code{Library_Name} and @code{Library_Dir}.
Additionally, you may define the library-related attributes
@code{Library_Kind}, @code{Library_Version} and @code{Library_Elaboration}.

The @code{Library_Name} attribute has a string value that must start with a
letter and include only letters and digits.

The @code{Library_Dir} attribute has a string value that designates the path
(absolute or relative) of the directory where the library will reside.
It must designate an existing directory, and this directory needs to be
different from the project's object directory. It also needs to be writable.

If both @code{Library_Name} and @code{Library_Dir} are specified and
are legal, then the project file defines a library project.  The optional
library-related attributes are checked only for such project files.

The @code{Library_Kind} attribute has a string value that must be one of the
following (case insensitive): @code{"static"}, @code{"dynamic"} or
@code{"relocatable"}. If this attribute is not specified, the library is a
static library. Otherwise, the library may be dynamic or relocatable.
Depending on the operating system, there may or may not be a distinction
between dynamic and relocatable libraries. For example, on Unix there is no
such distinction.

The @code{Library_Version} attribute has a string value whose interpretation
is platform dependent. On Unix, it is used only for dynamic/relocatable
libraries as the internal name of the library (the @code{"soname"}). If the
library file name (built from the @code{Library_Name}) is different from the
@code{Library_Version}, then the library file will be a symbolic link to the
actual file whose name will be @code{Library_Version}.

Example (on Unix):

@smallexample
@group
project Plib is

   Version := "1";

   for Library_Dir use "lib_dir";
   for Library_Name use "dummy";
   for Library_Kind use "relocatable";
   for Library_Version use "libdummy.so." & Version;

end Plib;
@end group
@end smallexample

@noindent
Directory @file{lib_dir} will contain the internal library file whose name
will be @file{libdummy.so.1}, and @file{libdummy.so} will be a symbolic link to
@file{libdummy.so.1}.

When @command{gnatmake} detects that a project file (not the main project file)
is a library project file, it will check all immediate sources of the project
and rebuild the library if any of the sources have been recompiled.
All @file{ALI} files will also be copied from the object directory to the
library directory. To build executables, @command{gnatmake} will use the
library rather than the individual object files.


@c *************************************
@c * Switches Related to Project Files *
@c *************************************
@node Switches Related to Project Files
@section Switches Related to Project Files

@noindent
The following switches are used by GNAT tools that support project files:

@table @code

@item @option{-P@var{project}}
Indicates the name of a project file. This project file will be parsed with
the verbosity indicated by @option{-vP@emph{x}}, if any, and using the external
references indicated by @option{-X} switches, if any.

@noindent
There must be only one @option{-P} switch on the command line.

@noindent
Since the Project Manager parses the project file only after all the switches
on the command line are checked, the order of the switches @option{-P},
@option{-Vp@emph{x}} or @option{-X} is not significant.

@item @option{-X@var{name=value}}
Indicates that external variable @var{name} has the value @var{value}.
The Project Manager will use this value for occurrences of
@code{external(name)} when parsing the project file.

@noindent
If @var{name} or @var{value} includes a space, then @var{name=value} should be
put between quotes.
@smallexample
  -XOS=NT
  -X"user=John Doe"
@end smallexample

@noindent
Several @option{-X} switches can be used simultaneously.
If several @option{-X} switches specify the same @var{name}, only the last one
is used.

@noindent
An external variable specified with a @option{-X} switch takes precedence
over the value of the same name in the environment.

@item @option{-vP@emph{x}}
Indicates the verbosity of the parsing of GNAT project files.
@option{-vP0} means Default (no output for syntactically correct project
files);
@option{-vP1} means Medium;
@option{-vP2} means High.
@noindent
The default is Default.
@noindent
If several @option{-vP@emph{x}} switches are present, only the last one is
used.

@end table


@c **********************************
@c * Tools Supporting Project Files *
@c **********************************

@node  Tools Supporting Project Files
@section Tools Supporting Project Files

@menu
* gnatmake and Project Files::
* The GNAT Driver and Project Files::
@ifclear vms
* Glide and Project Files::
@end ifclear
@end menu

@node gnatmake and Project Files
@subsection gnatmake and Project Files

@noindent
This section covers two topics related to @command{gnatmake} and project files:
defining switches for @command{gnatmake} and for the tools that it invokes;
and the use of the @code{Main} attribute.

@menu
* Switches and Project Files::
* Project Files and Main Subprograms::
@end menu

@node Switches and Project Files
@subsubsection Switches and Project Files

@noindent
For each of the packages @code{Builder}, @code{Compiler}, @code{Binder}, and
@code{Linker}, you can specify a @code{Default_Switches} attribute, a
@code{Switches} attribute, or both; as their names imply, these switch-related
attributes affect which switches are used for which files when
@command{gnatmake} is invoked.  As will be explained below, these
package-contributed switches precede the switches passed on the
@command{gnatmake} command line.

The @code{Default_Switches} attribute is an associative array indexed by
language name (case insensitive) and returning a string list.  For example:

@smallexample
@group
package Compiler is
  for Default_Switches ("Ada") use ("-gnaty", "-v");
end Compiler;
@end group
@end smallexample

@noindent
The @code{Switches} attribute is also an associative array, indexed by a file
name (which may or may not be case sensitive, depending on the operating
system) and returning a string list.  For example:

@smallexample
@group
package Builder is
   for Switches ("main1.adb") use ("-O2");
   for Switches ("main2.adb") use ("-g");
end Builder;
@end group
@end smallexample

@noindent
For the @code{Builder} package, the file names should designate source files
for main subprograms.  For the @code{Binder} and @code{Linker} packages, the
file names should designate @file{ALI} or source files for main subprograms.
In each case just the file name (without explicit extension) is acceptable.

For each tool used in a program build (@command{gnatmake}, the compiler, the
binder, and the linker), its corresponding package @dfn{contributes} a set of
switches for each file on which the tool is invoked, based on the
switch-related attributes defined in the package. In particular, the switches
that each of these packages contributes for a given file @var{f} comprise:

@itemize @bullet
@item
the value of attribute @code{Switches (@var{f})}, if it is specified in the
package for the given file,
@item
otherwise, the value of @code{Default_Switches ("Ada")}, if it is specified in
the package.
@end itemize

@noindent
If neither of these attributes is defined in the package, then the package does
not contribute any switches for the given file.

When @command{gnatmake} is invoked on a file, the switches comprise two sets,
in the following order: those contributed for the file by the @code{Builder}
package; and the switches passed on the command line.

When @command{gnatmake} invokes a tool (compiler, binder, linker) on a file,
the switches passed to the tool comprise three sets, in the following order:

@enumerate
@item
the applicable switches contributed for the file by the @code{Builder} package
in the project file supplied on the command line;

@item
those contributed for the file by the package (in the relevant project file --
see below) corresponding to the tool; and

@item
the applicable switches passed on the command line.
@end enumerate

@noindent
The term @emph{applicable switches} reflects the fact that @command{gnatmake}
switches may or may not be passed to individual tools, depending on the
individual switch.

@command{gnatmake} may invoke the compiler on source files from different
projects. The Project Manager will use the appropriate project file to
determine the @code{Compiler} package for each source file being compiled.
Likewise for the @code{Binder} and @code{Linker} packages.

As an example, consider the following package in a project file:

@smallexample
@group
project Proj1 is
   package Compiler is
      for Default_Switches ("Ada") use ("-g");
      for Switches ("a.adb") use ("-O1");
      for Switches ("b.adb") use ("-O2", "-gnaty");
   end Compiler;
end Proj1;
@end group
@end smallexample

@noindent
If @command{gnatmake} is invoked with this project file, and it needs to
compile, say, the files @file{a.adb}, @file{b.adb}, and @file{c.adb}, then
@file{a.adb} will be compiled with the switch @option{-O1}, @file{b.adb}
with switches @option{-O2} and @option{-gnaty}, and @file{c.adb} with
@option{-g}.

Another example illustrates the ordering of the switches contributed by
different packages:

@smallexample
@group
project Proj2 is
   package Builder is
      for Switches ("main.adb") use ("-g", "-O1", "-f");
   end Builder;
@end group

@group
   package Compiler is
      for Switches ("main.adb") use ("-O2");
   end Compiler;
end Proj2;
@end group
@end smallexample

@noindent
If you issue the command:

@smallexample
    gnatmake -PProj2 -O0 main
@end smallexample

@noindent
then the compiler will be invoked on @file{main.adb} with the following sequence of switches

@smallexample
   -g -O1 -O2 -O0
@end smallexample

with the last @option{-O} switch having precedence over the earlier ones;
several other switches (such as @option{-c}) are added implicitly.

The switches @option{-g} and @option{-O1} are contributed by package
@code{Builder},  @option{-O2} is contributed by the package @code{Compiler}
and @option{-O0} comes from the command line.

The @option{-g} switch will also be passed in the invocation of
@command{gnatlink.}

A final example illustrates switch contributions from packages in different
project files:

@smallexample
@group
project Proj3 is
   for Source_Files use ("pack.ads", "pack.adb");
   package Compiler is
      for Default_Switches ("Ada") use ("-gnata");
   end Compiler;
end Proj3;
@end group

@group
with "Proj3";
project Proj4 is
   for Source_Files use ("foo_main.adb", "bar_main.adb");
   package Builder is
      for Switches ("foo_main.adb") use ("-s", "-g");
   end Builder;
end Proj4;
@end group

@group
-- Ada source file:
with Pack;
procedure Foo_Main is
   ...
end Foo_Main;
@end group
@end smallexample

If the command is
@smallexample
gnatmake -PProj4 foo_main.adb -cargs -gnato
@end smallexample

@noindent
then the switches passed to the compiler for @file{foo_main.adb} are
@option{-g} (contributed by the package @code{Proj4.Builder}) and
@option{-gnato} (passed on the command line).
When the imported package @code{Pack} is compiled, the switches used are
@option{-g} from @code{Proj4.Builder}, @option{-gnata} (contributed from
package @code{Proj3.Compiler}, and @option{-gnato} from the command line.


@node Project Files and Main Subprograms
@subsubsection Project Files and Main Subprograms

@noindent
When using a project file, you can invoke @command{gnatmake}
with several main subprograms, by specifying their source files on the command
line.  Each of these needs to be an immediate source file of the project.

@smallexample
    gnatmake -Pprj main1 main2 main3
@end smallexample

@noindent
When using a project file, you can also invoke @command{gnatmake} without
explicitly specifying any main, and the effect depends on whether you have
defined the @code{Main} attribute.  This attribute has a string list value,
where each element in the list is the name of a source file (the file
extension is optional) containing a main subprogram.

If the @code{Main} attribute is defined in a project file as a non-empty
string list and the switch @option{-u} is not used on the command line, then
invoking @command{gnatmake} with this project file but without any main on the
command line is equivalent to invoking @command{gnatmake} with all the file
names in the @code{Main} attribute on the command line.

Example:
@smallexample
@group
   project Prj is
      for Main use ("main1", "main2", "main3");
   end Prj;
@end group
@end smallexample

@noindent
With this project file, @code{"gnatmake -Pprj"} is equivalent to
@code{"gnatmake -Pprj main1 main2 main3"}.

When the project attribute @code{Main} is not specified, or is specified
as an empty string list, or when the switch @option{-u} is used on the command
line, then invoking @command{gnatmake} with no main on the command line will
result in all immediate sources of the project file being checked, and
potentially recompiled. Depending on the presence of the switch @option{-u},
sources from other project files on which the immediate sources of the main
project file depend are also checked and potentially recompiled. In other
words, the @option{-u} switch is applied to all of the immediate sources of themain project file.


@node The GNAT Driver and Project Files
@subsection The GNAT Driver and Project Files

@noindent
A number of GNAT tools, other than @command{gnatmake} are project-aware:
@command{gnatbind}, @command{gnatfind}, @command{gnatlink}, @command{gnatls}
and @command{gnatxref}. However, none of these tools can be invoked directly
with a project file switch (@code{-P}). They need to be invoke through the
@command{gnat} driver.

The @command{gnat} driver is a front-end that accepts a number of commands and
call the corresponding tool. It has been designed initially for VMS to convert
VMS style qualifiers to Unix style switches, but it is now available to all
the GNAT supported platforms.

On non VMS platforms, the @command{gnat} driver accepts the following commands
(case insensitive):

@itemize @bullet
@item
BIND to invoke @command{gnatbind}
@item
CHOP to invoke @command{gnatchop}
@item
COMP or COMPILE to invoke the compiler
@item
ELIM to invoke @command{gnatelim}
@item
FIND to invoke @command{gnatfind}
@item
KR or KRUNCH to invoke @command{gnatkr}
@item
LINK to invoke @command{gnatlink}
@item
LS or LIST to invoke @command{gnatls}
@item
MAKE to invoke @command{gnatmake}
@item
NAME to invoke @command{gnatname}
@item
PREP or PREPROCESS to invoke @command{gnatprep}
@item
PSTA or STANDARD to invoke @command{gnatpsta}
@item
STUB to invoke @command{gnatstub}
@item
XREF to invoke @command{gnatxref}
@end itemize

@noindent
Note that the compiler is invoked using the command @command{gnatmake -f -u}.

@noindent
Following the command, you may put switches and arguments for the invoked
tool.

@smallexample
  gnat bind -C main.ali
  gnat ls -a main
  gnat chop foo.txt
@end smallexample

@noindent
In addition, for command BIND, FIND, LS or LIST, LINK and XREF, the project
file related switches (@code{-P}, @code{-X} and @code{-vPx}) may be used in
addition to the switches of the invoking tool.

@noindent
For each of these command, there is possibly a package in the main project that
corresponds to the invoked tool.

@itemize @bullet
@item
package @code{Binder} for command BIND (invoking @code{gnatbind})

@item
package @code{Finder} for command FIND (invoking @code{gnatfind})

@item
package @code{Gnatls} for command LS or LIST (invoking @code{gnatls})

@item
package @code{Linker} for command LINK (invoking @code{gnatlink})

@item
package @code{Cross_Reference} for command XREF (invoking @code{gnatlink})

@end itemize

@noindent
Package @code{Gnatls} has a unique attribute @code{Switches}, a simple variable
with a string list value. It contains switches for the invocation of
@code{gnatls}.

@smallexample
@group
project Proj1 is
   package gnatls is
      for Switches use ("-a", "-v");
   end gnatls;
end Proj1;
@end group
@end smallexample

@noindent
All other packages contains a switch @code{Default_Switches}, an associative
array, indexed by the programming language (case insensitive) and having a
string list value. @code{Default_Switches ("Ada")} contains the switches for
the invocation of the tool corresponding to the package.

@smallexample
@group
project Proj is

   for Source_Dirs use ("./**");

   package gnatls is
      for Switches use ("-a", "-v");
   end gnatls;
@end group
@group

   package Binder is
      for Default_Switches ("Ada") use ("-C", "-e");
   end Binder;
@end group
@group

   package Linker is
      for Default_Switches ("Ada") use ("-C");
   end Linker;
@end group
@group

   package Finder is
      for Default_Switches ("Ada") use ("-a", "-f");
   end Finder;
@end group
@group

   package Cross_Reference is
      for Default_Switches ("Ada") use ("-a", "-f", "-d", "-u");
   end Cross_Reference;
end Proj;
@end group
@end smallexample

@noindent
With the above project file, commands such as

@smallexample
   gnat ls -Pproj main
   gnat xref -Pproj main
   gnat bind -Pproj main.ali
@end smallexample

@noindent
will set up the environment properly and invoke the tool with the switches
found in the package corresponding to the tool.


@ifclear vms
@node Glide and Project Files
@subsection Glide and Project Files

@noindent
Glide will automatically recognize the @file{.gpr} extension for
project files, and will
convert them to its own internal format automatically. However, it
doesn't provide a syntax-oriented editor for modifying these
files.
The project file will be loaded as text when you select the menu item
@code{Ada} @result{} @code{Project} @result{} @code{Edit}.
You can edit this text and save the @file{gpr} file;
when you next select this project file in Glide it
will be automatically reloaded.

@ifset vxworks
Glide uses the @code{gnatlist} attribute in the @code{Ide} package, whose value
is something like @code{powerpc-wrs-vxworks-gnatls}, to compute the
cross-prefix.  From this information the correct location for the
GNAT runtime, and thus also the correct cross-references, can be
determined.
@end ifset
@end ifclear


@node An Extended Example
@section An Extended Example

@noindent
Suppose that we have two programs, @var{prog1} and @var{prog2}, with the sources
in the respective directories. We would like to build them with a single
@command{gnatmake} command, and we would like to place their object files into
@file{.build} subdirectories of the source directories. Furthermore, we would
like to have to have two separate subdirectories in @file{.build}  --
@file{release} and @file{debug} -- which will contain the object files compiled with
different set of compilation flags.

In other words, we have the following structure:

@smallexample
@group
   main
     |- prog1
     |    |- .build
     |         | debug
     |         | release
     |- prog2
          |- .build
               | debug
               | release
@end group
@end smallexample

@noindent
Here are the project files that we need to create in a directory @file{main}
to maintain this structure:

@enumerate

@item We create a @code{Common} project with a package @code{Compiler} that
specifies the compilation switches:

@smallexample
File "common.gpr":
@group
@b{project} Common @b{is}

   @b{for} Source_Dirs @b{use} (); -- No source files
@end group

@group
   @b{type} Build_Type @b{is} ("release", "debug");
   Build : Build_Type := External ("BUILD", "debug");
@end group
@group
   @b{package} Compiler @b{is}
      @b{case} Build @b{is}
         @b{when} "release" =>
           @b{for} Default_Switches ("Ada") @b{use} ("-O2");
         @b{when} "debug"   =>
           @b{for} Default_Switches ("Ada") @b{use} ("-g");
      @b{end case};
   @b{end} Compiler;

@b{end} Common;
@end group
@end smallexample

@item We create separate projects for the two programs:

@smallexample
@group
File "prog1.gpr":

@b{with} "common";
@b{project} Prog1 @b{is}

    @b{for} Source_Dirs @b{use} ("prog1");
    @b{for} Object_Dir  @b{use} "prog1/.build/" & Common.Build;

    @b{package} Compiler @b{renames} Common.Compiler;

@b{end} Prog1;
@end group
@end smallexample

@smallexample
@group
File "prog2.gpr":

@b{with} "common";
@b{project} Prog2 @b{is}

    @b{for} Source_Dirs @b{use} ("prog2");
    @b{for} Object_Dir  @b{use} "prog2/.build/" & Common.Build;

    @b{package} Compiler @b{renames} Common.Compiler;

@end group
@b{end} Prog2;
@end smallexample

@item We create a wrapping project @var{Main}:

@smallexample
@group
File "main.gpr":

@b{with} "common";
@b{with} "prog1";
@b{with} "prog2";
@b{project} Main @b{is}

   @b{package} Compiler @b{renames} Common.Compiler;

@b{end} Main;
@end group
@end smallexample

@item Finally we need to create a dummy procedure that @code{with}s (either
explicitly or implicitly) all the sources of our two programs.

@end enumerate

@noindent
Now we can build the programs using the command

@smallexample
   gnatmake -Pmain dummy
@end smallexample

@noindent
for the Debug mode, or

@smallexample
   gnatmake -Pmain -XBUILD=release
@end smallexample

@noindent
for the Release mode.


@c ********************************
@c * Project File Complete Syntax *
@c ********************************

@node Project File Complete Syntax
@section Project File Complete Syntax

@smallexample
project ::=
  context_clause project_declaration

context_clause ::=
  @{with_clause@}

with_clause ::=
  @b{with} literal_string @{ , literal_string @} ;

project_declaration ::=
  @b{project} <project_>simple_name [ @b{extends} literal_string ] @b{is}
    @{declarative_item@}
  @b{end} <project_>simple_name;

declarative_item ::=
  package_declaration |
  typed_string_declaration |
  other_declarative_item

package_declaration ::=
  @b{package} <package_>simple_name package_completion

package_completion ::=
  package_body | package_renaming

package body ::=
  @b{is}
    @{other_declarative_item@}
  @b{end} <package_>simple_name ;

package_renaming ::==
  @b{renames} <project_>simple_name.<package_>simple_name ;

typed_string_declaration ::=
  @b{type} <typed_string_>_simple_name @b{is}
   ( literal_string @{, literal_string@} );

other_declarative_item ::=
  attribute_declaration |
  typed_variable_declaration |
  variable_declaration |
  case_construction

attribute_declaration ::=
  @b{for} attribute @b{use} expression ;

attribute ::=
  <simple_attribute_>simple_name |
  <associative_array_attribute_>simple_name ( literal_string )

typed_variable_declaration ::=
  <typed_variable_>simple_name : <typed_string_>name :=  string_expression ;

variable_declaration ::=
  <variable_>simple_name := expression;

expression ::=
  term @{& term@}

term ::=
  literal_string |
  string_list |
  <variable_>name |
  external_value |
  attribute_reference

literal_string ::=
  (same as Ada)

string_list ::=
  ( <string_>expression @{ , <string_>expression @} )

external_value ::=
  @b{external} ( literal_string [, literal_string] )

attribute_reference ::=
  attribute_parent ' <simple_attribute_>simple_name [ ( literal_string ) ]

attribute_parent ::=
  @b{project} |
  <project_or_package>simple_name |
  <project_>simple_name . <package_>simple_name

case_construction ::=
  @b{case} <typed_variable_>name @b{is}
    @{case_item@}
  @b{end case} ;

case_item ::=
  @b{when} discrete_choice_list => @{case_construction | attribute_declaration@}

discrete_choice_list ::=
  literal_string @{| literal_string@}

name ::=
  simple_name @{. simple_name@}

simple_name ::=
  identifier (same as Ada)

@end smallexample


@node Elaboration Order Handling in GNAT
@chapter Elaboration Order Handling in GNAT
@cindex Order of elaboration
@cindex Elaboration control

@menu
* Elaboration Code in Ada 95::
* Checking the Elaboration Order in Ada 95::
* Controlling the Elaboration Order in Ada 95::
* Controlling Elaboration in GNAT - Internal Calls::
* Controlling Elaboration in GNAT - External Calls::
* Default Behavior in GNAT - Ensuring Safety::
* Elaboration Issues for Library Tasks::
* Mixing Elaboration Models::
* What to Do If the Default Elaboration Behavior Fails::
* Elaboration for Access-to-Subprogram Values::
* Summary of Procedures for Elaboration Control::
* Other Elaboration Order Considerations::
@end menu

@noindent
This chapter describes the handling of elaboration code in Ada 95 and
in GNAT, and discusses how the order of elaboration of program units can
be controlled in GNAT, either automatically or with explicit programming
features.

@node Elaboration Code in Ada 95
@section Elaboration Code in Ada 95

@noindent
Ada 95 provides rather general mechanisms for executing code at elaboration
time, that is to say before the main program starts executing. Such code arises
in three contexts:

@table @asis
@item Initializers for variables.
Variables declared at the library level, in package specs or bodies, can
require initialization that is performed at elaboration time, as in:
@smallexample
@cartouche
Sqrt_Half : Float := Sqrt (0.5);
@end cartouche
@end smallexample

@item Package initialization code
Code in a @code{BEGIN-END} section at the outer level of a package body is
executed as part of the package body elaboration code.

@item Library level task allocators
Tasks that are declared using task allocators at the library level
start executing immediately and hence can execute at elaboration time.
@end table

@noindent
Subprogram calls are possible in any of these contexts, which means that
any arbitrary part of the program may be executed as part of the elaboration
code. It is even possible to write a program which does all its work at
elaboration time, with a null main program, although stylistically this
would usually be considered an inappropriate way to structure
a program.

An important concern arises in the context of elaboration code:
we have to be sure that it is executed in an appropriate order. What we
have is a series of elaboration code sections, potentially one section
for each unit in the program. It is important that these execute
in the correct order. Correctness here means that, taking the above
example of the declaration of @code{Sqrt_Half},
if some other piece of
elaboration code references @code{Sqrt_Half},
then it must run after the
section of elaboration code that contains the declaration of
@code{Sqrt_Half}.

There would never be any order of elaboration problem if we made a rule
that whenever you @code{with} a unit, you must elaborate both the spec and body
of that unit before elaborating the unit doing the @code{with}'ing:

@smallexample
@group
@cartouche
@b{with} Unit_1;
@b{package} Unit_2 @b{is} ...
@end cartouche
@end group
@end smallexample

@noindent
would require that both the body and spec of @code{Unit_1} be elaborated
before the spec of @code{Unit_2}. However, a rule like that would be far too
restrictive. In particular, it would make it impossible to have routines
in separate packages that were mutually recursive.

You might think that a clever enough compiler could look at the actual
elaboration code and determine an appropriate correct order of elaboration,
but in the general case, this is not possible. Consider the following
example.

In the body of @code{Unit_1}, we have a procedure @code{Func_1}
that references
the variable @code{Sqrt_1}, which is declared in the elaboration code
of the body of @code{Unit_1}:

@smallexample
@cartouche
Sqrt_1 : Float := Sqrt (0.1);
@end cartouche
@end smallexample

@noindent
The elaboration code of the body of @code{Unit_1} also contains:

@smallexample
@group
@cartouche
@b{if} expression_1 = 1 @b{then}
   Q := Unit_2.Func_2;
@b{end if};
@end cartouche
@end group
@end smallexample

@noindent
@code{Unit_2} is exactly parallel,
it has a procedure @code{Func_2} that references
the variable @code{Sqrt_2}, which is declared in the elaboration code of
the body @code{Unit_2}:

@smallexample
@cartouche
Sqrt_2 : Float := Sqrt (0.1);
@end cartouche
@end smallexample

@noindent
The elaboration code of the body of @code{Unit_2} also contains:

@smallexample
@group
@cartouche
@b{if} expression_2 = 2 @b{then}
   Q := Unit_1.Func_1;
@b{end if};
@end cartouche
@end group
@end smallexample

@noindent
Now the question is, which of the following orders of elaboration is
acceptable:

@smallexample
@group
Spec of Unit_1
Spec of Unit_2
Body of Unit_1
Body of Unit_2
@end group
@end smallexample

@noindent
or

@smallexample
@group
Spec of Unit_2
Spec of Unit_1
Body of Unit_2
Body of Unit_1
@end group
@end smallexample

@noindent
If you carefully analyze the flow here, you will see that you cannot tell
at compile time the answer to this question.
If @code{expression_1} is not equal to 1,
and @code{expression_2} is not equal to 2,
then either order is acceptable, because neither of the function calls is
executed. If both tests evaluate to true, then neither order is acceptable
and in fact there is no correct order.

If one of the two expressions is true, and the other is false, then one
of the above orders is correct, and the other is incorrect. For example,
if @code{expression_1} = 1 and @code{expression_2} /= 2,
then the call to @code{Func_2}
will occur, but not the call to @code{Func_1.}
This means that it is essential
to elaborate the body of @code{Unit_1} before
the body of @code{Unit_2}, so the first
order of elaboration is correct and the second is wrong.

By making @code{expression_1} and @code{expression_2}
depend on input data, or perhaps
the time of day, we can make it impossible for the compiler or binder
to figure out which of these expressions will be true, and hence it
is impossible to guarantee a safe order of elaboration at run time.

@node Checking the Elaboration Order in Ada 95
@section Checking the Elaboration Order in Ada 95

@noindent
In some languages that involve the same kind of elaboration problems,
e.g. Java and C++, the programmer is expected to worry about these
ordering problems himself, and it is common to
write a program in which an incorrect elaboration order  gives
surprising results, because it references variables before they
are initialized.
Ada 95 is designed to be a safe language, and a programmer-beware approach is
clearly not sufficient. Consequently, the language provides three lines
of defense:

@table @asis
@item Standard rules
Some standard rules restrict the possible choice of elaboration
order. In particular, if you @code{with} a unit, then its spec is always
elaborated before the unit doing the @code{with}. Similarly, a parent
spec is always elaborated before the child spec, and finally
a spec is always elaborated before its corresponding body.

@item Dynamic elaboration checks
@cindex Elaboration checks
@cindex Checks, elaboration
Dynamic checks are made at run time, so that if some entity is accessed
before it is elaborated (typically  by means of a subprogram call)
then the exception (@code{Program_Error}) is raised.

@item Elaboration control
Facilities are provided for the programmer to specify the desired order
of elaboration.
@end table

Let's look at these facilities in more detail. First, the rules for
dynamic checking. One possible rule would be simply to say that the
exception is raised if you access a variable which has not yet been
elaborated. The trouble with this approach is that it could require
expensive checks on every variable reference. Instead Ada 95 has two
rules which are a little more restrictive, but easier to check, and
easier to state:

@table @asis
@item Restrictions on calls
A subprogram can only be called at elaboration time if its body
has been elaborated. The rules for elaboration given above guarantee
that the spec of the subprogram has been elaborated before the
call, but not the body. If this rule is violated, then the
exception @code{Program_Error} is raised.

@item Restrictions on instantiations
A generic unit can only be instantiated if the body of the generic
unit has been elaborated. Again, the rules for elaboration given above
guarantee that the spec of the generic unit has been elaborated
before the instantiation, but not the body. If this rule is
violated, then the exception @code{Program_Error} is raised.
@end table

@noindent
The idea is that if the body has been elaborated, then any variables
it references must have been elaborated; by checking for the body being
elaborated we guarantee that none of its references causes any
trouble. As we noted above, this is a little too restrictive, because a
subprogram that has no non-local references in its body may in fact be safe
to call. However, it really would be unsafe to rely on this, because
it would mean that the caller was aware of details of the implementation
in the body. This goes against the basic tenets of Ada.

A plausible implementation can be described as follows.
A Boolean variable is associated with each subprogram
and each generic unit. This variable is initialized to False, and is set to
True at the point body is elaborated. Every call or instantiation checks the
variable, and raises @code{Program_Error} if the variable is False.

Note that one might think that it would be good enough to have one Boolean
variable for each package, but that would not deal with cases of trying
to call a body in the same package as the call
that has not been elaborated yet.
Of course a compiler may be able to do enough analysis to optimize away
some of the Boolean variables as unnecessary, and @code{GNAT} indeed
does such optimizations, but still the easiest conceptual model is to
think of there being one variable per subprogram.

@node Controlling the Elaboration Order in Ada 95
@section Controlling the Elaboration Order in Ada 95

@noindent
In the previous section we discussed the rules in Ada 95 which ensure
that @code{Program_Error} is raised if an incorrect elaboration order is
chosen. This prevents erroneous executions, but we need mechanisms to
specify a correct execution and avoid the exception altogether.
To achieve this, Ada 95 provides a number of features for controlling
the order of elaboration. We discuss these features in this section.

First, there are several ways of indicating to the compiler that a given
unit has no elaboration problems:

@table @asis
@item packages that do not require a body
In Ada 95, a library package that does not require a body does not permit
a body. This means that if we have a such a package, as in:

@smallexample
@group
@cartouche
@b{package} Definitions @b{is}
   @b{generic}
      @b{type} m @b{is new} integer;
   @b{package} Subp @b{is}
      @b{type} a @b{is array} (1 .. 10) @b{of} m;
      @b{type} b @b{is array} (1 .. 20) @b{of} m;
   @b{end} Subp;
@b{end} Definitions;
@end cartouche
@end group
@end smallexample

@noindent
A package that @code{with}'s @code{Definitions} may safely instantiate
@code{Definitions.Subp} because the compiler can determine that there
definitely is no package body to worry about in this case

@item pragma Pure
@cindex pragma Pure
@findex Pure
Places sufficient restrictions on a unit to guarantee that
no call to any subprogram in the unit can result in an
elaboration problem. This means that the compiler does not need
to worry about the point of elaboration of such units, and in
particular, does not need to check any calls to any subprograms
in this unit.

@item pragma Preelaborate
@findex Preelaborate
@cindex pragma Preelaborate
This pragma places slightly less stringent restrictions on a unit than
does pragma Pure,
but these restrictions are still sufficient to ensure that there
are no elaboration problems with any calls to the unit.

@item pragma Elaborate_Body
@findex Elaborate_Body
@cindex pragma Elaborate_Body
This pragma requires that the body of a unit be elaborated immediately
after its spec. Suppose a unit @code{A} has such a pragma,
and unit @code{B} does
a @code{with} of unit @code{A}. Recall that the standard rules require
the spec of unit @code{A}
to be elaborated before the @code{with}'ing unit; given the pragma in
@code{A}, we also know that the body of @code{A}
will be elaborated before @code{B}, so
that calls to @code{A} are safe and do not need a check.
@end table

@noindent
Note that,
unlike pragma @code{Pure} and pragma @code{Preelaborate},
the use of
@code{Elaborate_Body} does not guarantee that the program is
free of elaboration problems, because it may not be possible
to satisfy the requested elaboration order.
Let's go back to the example with @code{Unit_1} and @code{Unit_2}.
If a programmer
marks @code{Unit_1} as @code{Elaborate_Body},
and not @code{Unit_2,} then the order of
elaboration will be:

@smallexample
@group
Spec of Unit_2
Spec of Unit_1
Body of Unit_1
Body of Unit_2
@end group
@end smallexample

@noindent
Now that means that the call to @code{Func_1} in @code{Unit_2}
need not be checked,
it must be safe. But the call to @code{Func_2} in
@code{Unit_1} may still fail if
@code{Expression_1} is equal to 1,
and the programmer must still take
responsibility for this not being the case.

If all units carry a pragma @code{Elaborate_Body}, then all problems are
eliminated, except for calls entirely within a body, which are
in any case fully under programmer control. However, using the pragma
everywhere is not always possible.
In particular, for our @code{Unit_1}/@code{Unit_2} example, if
we marked both of them as having pragma @code{Elaborate_Body}, then
clearly there would be no possible elaboration order.

The above pragmas allow a server to guarantee safe use by clients, and
clearly this is the preferable approach. Consequently a good rule in
Ada 95 is to mark units as @code{Pure} or @code{Preelaborate} if possible,
and if this is not possible,
mark them as @code{Elaborate_Body} if possible.
As we have seen, there are situations where neither of these
three pragmas can be used.
So we also provide methods for clients to control the
order of elaboration of the servers on which they depend:

@table @asis
@item pragma Elaborate (unit)
@findex Elaborate
@cindex pragma Elaborate
This pragma is placed in the context clause, after a @code{with} clause,
and it requires that the body of the named unit be elaborated before
the unit in which the pragma occurs. The idea is to use this pragma
if the current unit calls at elaboration time, directly or indirectly,
some subprogram in the named unit.

@item pragma Elaborate_All (unit)
@findex Elaborate_All
@cindex pragma Elaborate_All
This is a stronger version of the Elaborate pragma. Consider the
following example:

@smallexample
Unit A @code{with}'s unit B and calls B.Func in elab code
Unit B @code{with}'s unit C, and B.Func calls C.Func
@end smallexample

@noindent
Now if we put a pragma @code{Elaborate (B)}
in unit @code{A}, this ensures that the
body of @code{B} is elaborated before the call, but not the
body of @code{C}, so
the call to @code{C.Func} could still cause @code{Program_Error} to
be raised.

The effect of a pragma @code{Elaborate_All} is stronger, it requires
not only that the body of the named unit be elaborated before the
unit doing the @code{with}, but also the bodies of all units that the
named unit uses, following @code{with} links transitively. For example,
if we put a pragma @code{Elaborate_All (B)} in unit @code{A},
then it requires
not only that the body of @code{B} be elaborated before @code{A},
but also the
body of @code{C}, because @code{B} @code{with}'s @code{C}.
@end table

@noindent
We are now in a position to give a usage rule in Ada 95 for avoiding
elaboration problems, at least if dynamic dispatching and access to
subprogram values are not used. We will handle these cases separately
later.

The rule is simple. If a unit has elaboration code that can directly or
indirectly make a call to a subprogram in a @code{with}'ed unit, or instantiate
a generic unit in a @code{with}'ed unit,
then if the @code{with}'ed unit does not have
pragma @code{Pure} or @code{Preelaborate}, then the client should have
a pragma @code{Elaborate_All}
for the @code{with}'ed unit. By following this rule a client is
assured that calls can be made without risk of an exception.
If this rule is not followed, then a program may be in one of four
states:

@table @asis
@item No order exists
No order of elaboration exists which follows the rules, taking into
account any @code{Elaborate}, @code{Elaborate_All},
or @code{Elaborate_Body} pragmas. In
this case, an Ada 95 compiler must diagnose the situation at bind
time, and refuse to build an executable program.

@item One or more orders exist, all incorrect
One or more acceptable elaboration orders exists, and all of them
generate an elaboration order problem. In this case, the binder
can build an executable program, but @code{Program_Error} will be raised
when the program is run.

@item Several orders exist, some right, some incorrect
One or more acceptable elaboration orders exists, and some of them
work, and some do not. The programmer has not controlled
the order of elaboration, so the binder may or may not pick one of
the correct orders, and the program may or may not raise an
exception when it is run. This is the worst case, because it means
that the program may fail when moved to another compiler, or even
another version of the same compiler.

@item One or more orders exists, all correct
One ore more acceptable elaboration orders exist, and all of them
work. In this case the program runs successfully. This state of
affairs can be guaranteed by following the rule we gave above, but
may be true even if the rule is not followed.
@end table

@noindent
Note that one additional advantage of following our Elaborate_All rule
is that the program continues to stay in the ideal (all orders OK) state
even if maintenance
changes some bodies of some subprograms. Conversely, if a program that does
not follow this rule happens to be safe at some point, this state of affairs
may deteriorate silently as a result of maintenance changes.

You may have noticed that the above discussion did not mention
the use of @code{Elaborate_Body}. This was a deliberate omission. If you
@code{with} an @code{Elaborate_Body} unit, it still may be the case that
code in the body makes calls to some other unit, so it is still necessary
to use @code{Elaborate_All} on such units.

@node Controlling Elaboration in GNAT - Internal Calls
@section Controlling Elaboration in GNAT - Internal Calls

@noindent
In the case of internal calls, i.e. calls within a single package, the
programmer has full control over the order of elaboration, and it is up
to the programmer to elaborate declarations in an appropriate order. For
example writing:

@smallexample
@group
@cartouche
@b{function} One @b{return} Float;

Q : Float := One;

@b{function} One @b{return} Float @b{is}
@b{begin}
     return 1.0;
@b{end} One;
@end cartouche
@end group
@end smallexample

@noindent
will obviously raise @code{Program_Error} at run time, because function
One will be called before its body is elaborated. In this case GNAT will
generate a warning that the call will raise @code{Program_Error}:

@smallexample
@group
@cartouche
 1. procedure y is
 2.    function One return Float;
 3.
 4.    Q : Float := One;
                    |
    >>> warning: cannot call "One" before body is elaborated
    >>> warning: Program_Error will be raised at run time

 5.
 6.    function One return Float is
 7.    begin
 8.         return 1.0;
 9.    end One;
10.
11. begin
12.    null;
13. end;
@end cartouche
@end group
@end smallexample

@noindent
Note that in this particular case, it is likely that the call is safe, because
the function @code{One} does not access any global variables.
Nevertheless in Ada 95, we do not want the validity of the check to depend on
the contents of the body (think about the separate compilation case), so this
is still wrong, as we discussed in the previous sections.

The error is easily corrected by rearranging the declarations so that the
body of One appears before the declaration containing the call
(note that in Ada 95,
declarations can appear in any order, so there is no restriction that
would prevent this reordering, and if we write:

@smallexample
@group
@cartouche
@b{function} One @b{return} Float;

@b{function} One @b{return} Float @b{is}
@b{begin}
     return 1.0;
@b{end} One;

Q : Float := One;
@end cartouche
@end group
@end smallexample

@noindent
then all is well, no warning is generated, and no
@code{Program_Error} exception
will be raised.
Things are more complicated when a chain of subprograms is executed:

@smallexample
@group
@cartouche
@b{function} A @b{return} Integer;
@b{function} B @b{return} Integer;
@b{function} C @b{return} Integer;

@b{function} B @b{return} Integer @b{is begin return} A; @b{end};
@b{function} C @b{return} Integer @b{is begin return} B; @b{end};

X : Integer := C;

@b{function} A @b{return} Integer @b{is begin return} 1; @b{end};
@end cartouche
@end group
@end smallexample

@noindent
Now the call to @code{C}
at elaboration time in the declaration of @code{X} is correct, because
the body of @code{C} is already elaborated,
and the call to @code{B} within the body of
@code{C} is correct, but the call
to @code{A} within the body of @code{B} is incorrect, because the body
of @code{A} has not been elaborated, so @code{Program_Error}
will be raised on the call to @code{A}.
In this case GNAT will generate a
warning that @code{Program_Error} may be
raised at the point of the call. Let's look at the warning:

@smallexample
@group
@cartouche
 1. procedure x is
 2.    function A return Integer;
 3.    function B return Integer;
 4.    function C return Integer;
 5.
 6.    function B return Integer is begin return A; end;
                                                    |
    >>> warning: call to "A" before body is elaborated may
                 raise Program_Error
    >>> warning: "B" called at line 7
    >>> warning: "C" called at line 9

 7.    function C return Integer is begin return B; end;
 8.
 9.    X : Integer := C;
10.
11.    function A return Integer is begin return 1; end;
12.
13. begin
14.    null;
15. end;
@end cartouche
@end group
@end smallexample

@noindent
Note that the message here says "may raise", instead of the direct case,
where the message says "will be raised". That's because whether
@code{A} is
actually called depends in general on run-time flow of control.
For example, if the body of @code{B} said

@smallexample
@group
@cartouche
@b{function} B @b{return} Integer @b{is}
@b{begin}
   @b{if} some-condition-depending-on-input-data @b{then}
      @b{return} A;
   @b{else}
      @b{return} 1;
   @b{end if};
@b{end} B;
@end cartouche
@end group
@end smallexample

@noindent
then we could not know until run time whether the incorrect call to A would
actually occur, so @code{Program_Error} might
or might not be raised. It is possible for a compiler to
do a better job of analyzing bodies, to
determine whether or not @code{Program_Error}
might be raised, but it certainly
couldn't do a perfect job (that would require solving the halting problem
and is provably impossible), and because this is a warning anyway, it does
not seem worth the effort to do the analysis. Cases in which it
would be relevant are rare.

In practice, warnings of either of the forms given
above will usually correspond to
real errors, and should be examined carefully and eliminated.
In the rare case where a warning is bogus, it can be suppressed by any of
the following methods:

@itemize @bullet
@item
Compile with the @option{-gnatws} switch set

@item
Suppress @code{Elaboration_Checks} for the called subprogram

@item
Use pragma @code{Warnings_Off} to turn warnings off for the call
@end itemize

@noindent
For the internal elaboration check case,
GNAT by default generates the
necessary run-time checks to ensure
that @code{Program_Error} is raised if any
call fails an elaboration check. Of course this can only happen if a
warning has been issued as described above. The use of pragma
@code{Suppress (Elaboration_Checks)} may (but is not guaranteed to) suppress
some of these checks, meaning that it may be possible (but is not
guaranteed) for a program to be able to call a subprogram whose body
is not yet elaborated, without raising a @code{Program_Error} exception.

@node Controlling Elaboration in GNAT - External Calls
@section Controlling Elaboration in GNAT - External Calls

@noindent
The previous section discussed the case in which the execution of a
particular thread of elaboration code occurred entirely within a
single unit. This is the easy case to handle, because a programmer
has direct and total control over the order of elaboration, and
furthermore, checks need only be generated in cases which are rare
and which the compiler can easily detect.
The situation is more complex when separate compilation is taken into account.
Consider the following:

@smallexample
@cartouche
@group
@b{package} Math @b{is}
   @b{function} Sqrt (Arg : Float) @b{return} Float;
@b{end} Math;

@b{package body} Math @b{is}
   @b{function} Sqrt (Arg : Float) @b{return} Float @b{is}
   @b{begin}
         ...
   @b{end} Sqrt;
@b{end} Math;
@end group
@group
@b{with} Math;
@b{package} Stuff @b{is}
   X : Float := Math.Sqrt (0.5);
@b{end} Stuff;

@b{with} Stuff;
@b{procedure} Main @b{is}
@b{begin}
   ...
@b{end} Main;
@end group
@end cartouche
@end smallexample

@noindent
where @code{Main} is the main program. When this program is executed, the
elaboration code must first be executed, and one of the jobs of the
binder is to determine the order in which the units of a program are
to be elaborated. In this case we have four units: the spec and body
of @code{Math},
the spec of @code{Stuff} and the body of @code{Main}).
In what order should the four separate sections of elaboration code
be executed?

There are some restrictions in the order of elaboration that the binder
can choose. In particular, if unit U has a @code{with}
for a package @code{X}, then you
are assured that the spec of @code{X}
is elaborated before U , but you are
not assured that the body of @code{X}
is elaborated before U.
This means that in the above case, the binder is allowed to choose the
order:

@smallexample
spec of Math
spec of Stuff
body of Math
body of Main
@end smallexample

@noindent
but that's not good, because now the call to @code{Math.Sqrt}
that happens during
the elaboration of the @code{Stuff}
spec happens before the body of @code{Math.Sqrt} is
elaborated, and hence causes @code{Program_Error} exception to be raised.
At first glance, one might say that the binder is misbehaving, because
obviously you want to elaborate the body of something you @code{with}
first, but
that is not a general rule that can be followed in all cases. Consider

@smallexample
@group
@cartouche
@b{package} X @b{is} ...

@b{package} Y @b{is} ...

@b{with} X;
@b{package body} Y @b{is} ...

@b{with} Y;
@b{package body} X @b{is} ...
@end cartouche
@end group
@end smallexample

@noindent
This is a common arrangement, and, apart from the order of elaboration
problems that might arise in connection with elaboration code, this works fine.
A rule that says that you must first elaborate the body of anything you
@code{with} cannot work in this case:
the body of @code{X} @code{with}'s @code{Y},
which means you would have to
elaborate the body of @code{Y} first, but that @code{with}'s @code{X},
which means
you have to elaborate the body of @code{X} first, but ... and we have a
loop that cannot be broken.

It is true that the binder can in many cases guess an order of elaboration
that is unlikely to cause a @code{Program_Error}
exception to be raised, and it tries to do so (in the
above example of @code{Math/Stuff/Spec}, the GNAT binder will
by default
elaborate the body of @code{Math} right after its spec, so all will be well).

However, a program that blindly relies on the binder to be helpful can
get into trouble, as we discussed in the previous sections, so
GNAT
provides a number of facilities for assisting the programmer in
developing programs that are robust with respect to elaboration order.

@node Default Behavior in GNAT - Ensuring Safety
@section Default Behavior in GNAT - Ensuring Safety

@noindent
The default behavior in GNAT ensures elaboration safety. In its
default mode GNAT implements the
rule we previously described as the right approach. Let's restate it:

@itemize
@item
@emph{If a unit has elaboration code that can directly or indirectly make a
call to a subprogram in a @code{with}'ed unit, or instantiate a generic unit
in a @code{with}'ed unit, then if the @code{with}'ed unit
does not have pragma @code{Pure} or
@code{Preelaborate}, then the client should have an
@code{Elaborate_All} for the @code{with}'ed unit.}
@end itemize

@noindent
By following this rule a client
is assured that calls and instantiations can be made without risk of an exception.

In this mode GNAT traces all calls that are potentially made from
elaboration code, and puts in any missing implicit @code{Elaborate_All}
pragmas.
The advantage of this approach is that no elaboration problems
are possible if the binder can find an elaboration order that is
consistent with these implicit @code{Elaborate_All} pragmas. The
disadvantage of this approach is that no such order may exist.

If the binder does not generate any diagnostics, then it means that it
has found an elaboration order that is guaranteed to be safe. However,
the binder may still be relying on implicitly generated
@code{Elaborate_All} pragmas so portability to other compilers than
GNAT is not guaranteed.

If it is important to guarantee portability, then the compilations should
use the
@option{-gnatwl}
(warn on elaboration problems) switch. This will cause warning messages
to be generated indicating the missing @code{Elaborate_All} pragmas.
Consider the following source program:

@smallexample
@group
@cartouche
@b{with} k;
@b{package} j @b{is}
  m : integer := k.r;
@b{end};
@end cartouche
@end group
@end smallexample

@noindent
where it is clear that there
should be a pragma @code{Elaborate_All}
for unit @code{k}. An implicit pragma will be generated, and it is
likely that the binder will be able to honor it. However,
it is safer to include the pragma explicitly in the source. If this
unit is compiled with the
@option{-gnatwl}
switch, then the compiler outputs a warning:

@smallexample
@group
@cartouche
1. with k;
2. package j is
3.   m : integer := k.r;
                     |
   >>> warning: call to "r" may raise Program_Error
   >>> warning: missing pragma Elaborate_All for "k"

4. end;
@end cartouche
@end group
@end smallexample

@noindent
and these warnings can be used as a guide for supplying manually
the missing pragmas.

This default mode is more restrictive than the Ada Reference
Manual, and it is possible to construct programs which will compile
using the dynamic model described there, but will run into a
circularity using the safer static model we have described.

Of course any Ada compiler must be able to operate in a mode
consistent with the requirements of the Ada Reference Manual,
and in particular must have the capability of implementing the
standard dynamic model of elaboration with run-time checks.

In GNAT, this standard mode can be achieved either by the use of
the @option{-gnatE} switch on the compiler (@code{gcc} or @code{gnatmake})
command, or by the use of the configuration pragma:

@smallexample
pragma Elaboration_Checks (RM);
@end smallexample

@noindent
Either approach will cause the unit affected to be compiled using the
standard dynamic run-time elaboration checks described in the Ada
Reference Manual. The static model is generally preferable, since it
is clearly safer to rely on compile and link time checks rather than
run-time checks. However, in the case of legacy code, it may be
difficult to meet the requirements of the static model. This
issue is further discussed in
@ref{What to Do If the Default Elaboration Behavior Fails}.

Note that the static model provides a strict subset of the allowed
behavior and programs of the Ada Reference Manual, so if you do
adhere to the static model and no circularities exist,
then you are assured that your program will
work using the dynamic model.

@node Elaboration Issues for Library Tasks
@section Elaboration Issues for Library Tasks
@cindex Library tasks, elaboration issues
@cindex Elaboration of library tasks

@noindent
In this section we examine special elaboration issues that arise for
programs that declare library level tasks.

Generally the model of execution of an Ada program is that all units are
elaborated, and then execution of the program starts. However, the
declaration of library tasks definitely does not fit this model. The
reason for this is that library tasks start as soon as they are declared
(more precisely, as soon as the statement part of the enclosing package
body is reached), that is to say before elaboration
of the program is complete. This means that if such a task calls a
subprogram, or an entry in another task, the callee may or may not be
elaborated yet, and in the standard
Reference Manual model of dynamic elaboration checks, you can even
get timing dependent Program_Error exceptions, since there can be
a race between the elaboration code and the task code.

The static model of elaboration in GNAT seeks to avoid all such
dynamic behavior, by being conservative, and the conservative
approach in this particular case is to assume that all the code
in a task body is potentially executed at elaboration time if
a task is declared at the library level.

This can definitely result in unexpected circularities. Consider
the following example

@smallexample
package Decls is
  task Lib_Task is
     entry Start;
  end Lib_Task;

  type My_Int is new Integer;

  function Ident (M : My_Int) return My_Int;
end Decls;

with Utils;
package body Decls is
  task body Lib_Task is
  begin
     accept Start;
     Utils.Put_Val (2);
  end Lib_Task;

  function Ident (M : My_Int) return My_Int is
  begin
     return M;
  end Ident;
end Decls;

with Decls;
package Utils is
  procedure Put_Val (Arg : Decls.My_Int);
end Utils;

with Text_IO;
package body Utils is
  procedure Put_Val (Arg : Decls.My_Int) is
  begin
     Text_IO.Put_Line (Decls.My_Int'Image (Decls.Ident (Arg)));
  end Put_Val;
end Utils;

with Decls;
procedure Main is
begin
   Decls.Lib_Task.Start;
end;
@end smallexample

@noindent
If the above example is compiled in the default static elaboration
mode, then a circularity occurs. The circularity comes from the call
@code{Utils.Put_Val} in the task body of @code{Decls.Lib_Task}. Since
this call occurs in elaboration code, we need an implicit pragma
@code{Elaborate_All} for @code{Utils}. This means that not only must
the spec and body of @code{Utils} be elaborated before the body
of @code{Decls}, but also the spec and body of any unit that is
@code{with'ed} by the body of @code{Utils} must also be elaborated before
the body of @code{Decls}. This is the transitive implication of
pragma @code{Elaborate_All} and it makes sense, because in general
the body of @code{Put_Val} might have a call to something in a
@code{with'ed} unit.

In this case, the body of Utils (actually its spec) @code{with's}
@code{Decls}. Unfortunately this means that the body of @code{Decls}
must be elaborated before itself, in case there is a call from the
body of @code{Utils}.

Here is the exact chain of events we are worrying about:

@enumerate
@item
In the body of @code{Decls} a call is made from within the body of a library
task to a subprogram in the package @code{Utils}. Since this call may
occur at elaboration time (given that the task is activated at elaboration
time), we have to assume the worst, i.e. that the
call does happen at elaboration time.

@item
This means that the body and spec of @code{Util} must be elaborated before
the body of @code{Decls} so that this call does not cause an access before
elaboration.

@item
Within the body of @code{Util}, specifically within the body of
@code{Util.Put_Val} there may be calls to any unit @code{with}'ed
by this package.

@item
One such @code{with}'ed package is package @code{Decls}, so there
might be a call to a subprogram in @code{Decls} in @code{Put_Val}.
In fact there is such a call in this example, but we would have to
assume that there was such a call even if it were not there, since
we are not supposed to write the body of @code{Decls} knowing what
is in the body of @code{Utils}; certainly in the case of the
static elaboration model, the compiler does not know what is in
other bodies and must assume the worst.

@item
This means that the spec and body of @code{Decls} must also be
elaborated before we elaborate the unit containing the call, but
that unit is @code{Decls}! This means that the body of @code{Decls}
must be elaborated before itself, and that's a circularity.
@end enumerate

@noindent
Indeed, if you add an explicit pragma Elaborate_All for @code{Utils} in
the body of @code{Decls} you will get a true Ada Reference Manual
circularity that makes the program illegal.

In practice, we have found that problems with the static model of
elaboration in existing code often arise from library tasks, so
we must address this particular situation.

Note that if we compile and run the program above, using the dynamic model of
elaboration (that is to say use the @option{-gnatE} switch),
then it compiles, binds,
links, and runs, printing the expected result of 2. Therefore in some sense
the circularity here is only apparent, and we need to capture
the properties of this program that  distinguish it from other library-level
tasks that have real elaboration problems.

We have four possible answers to this question:

@itemize @bullet

@item
Use the dynamic model of elaboration.

If we use the @option{-gnatE} switch, then as noted above, the program works.
Why is this? If we examine the task body, it is apparent that the task cannot
proceed past the
@code{accept} statement until after elaboration has been completed, because
the corresponding entry call comes from the main program, not earlier.
This is why the dynamic model works here. But that's really giving
up on a precise analysis, and we prefer to take this approach only if we cannot
solve the
problem in any other manner. So let us examine two ways to reorganize
the program to avoid the potential elaboration problem.

@item
Split library tasks into separate packages.

Write separate packages, so that library tasks are isolated from
other declarations as much as possible. Let us look at a variation on
the above program.

@smallexample
package Decls1 is
  task Lib_Task is
     entry Start;
  end Lib_Task;
end Decls1;

with Utils;
package body Decls1 is
  task body Lib_Task is
  begin
     accept Start;
     Utils.Put_Val (2);
  end Lib_Task;
end Decls1;

package Decls2 is
  type My_Int is new Integer;
  function Ident (M : My_Int) return My_Int;
end Decls2;

with Utils;
package body Decls2 is
  function Ident (M : My_Int) return My_Int is
  begin
     return M;
  end Ident;
end Decls2;

with Decls2;
package Utils is
  procedure Put_Val (Arg : Decls2.My_Int);
end Utils;

with Text_IO;
package body Utils is
  procedure Put_Val (Arg : Decls2.My_Int) is
  begin
     Text_IO.Put_Line (Decls2.My_Int'Image (Decls2.Ident (Arg)));
  end Put_Val;
end Utils;

with Decls1;
procedure Main is
begin
   Decls1.Lib_Task.Start;
end;
@end smallexample

@noindent
All we have done is to split @code{Decls} into two packages, one
containing the library task, and one containing everything else. Now
there is no cycle, and the program compiles, binds, links and executes
using the default static model of elaboration.

@item
Declare separate task types.

A significant part of the problem arises because of the use of the
single task declaration form. This means that the elaboration of
the task type, and the elaboration of the task itself (i.e. the
creation of the task) happen at the same time. A good rule
of style in Ada 95 is to always create explicit task types. By
following the additional step of placing task objects in separate
packages from the task type declaration, many elaboration problems
are avoided. Here is another modified example of the example program:

@smallexample
package Decls is
  task type Lib_Task_Type is
     entry Start;
  end Lib_Task_Type;

  type My_Int is new Integer;

  function Ident (M : My_Int) return My_Int;
end Decls;

with Utils;
package body Decls is
  task body Lib_Task_Type is
  begin
     accept Start;
     Utils.Put_Val (2);
  end Lib_Task_Type;

  function Ident (M : My_Int) return My_Int is
  begin
     return M;
  end Ident;
end Decls;

with Decls;
package Utils is
  procedure Put_Val (Arg : Decls.My_Int);
end Utils;

with Text_IO;
package body Utils is
  procedure Put_Val (Arg : Decls.My_Int) is
  begin
     Text_IO.Put_Line (Decls.My_Int'Image (Decls.Ident (Arg)));
  end Put_Val;
end Utils;

with Decls;
package Declst is
   Lib_Task : Decls.Lib_Task_Type;
end Declst;

with Declst;
procedure Main is
begin
   Declst.Lib_Task.Start;
end;
@end smallexample

@noindent
What we have done here is to replace the @code{task} declaration in
package @code{Decls} with a @code{task type} declaration. Then we
introduce a separate package @code{Declst} to contain the actual
task object. This separates the elaboration issues for
the @code{task type}
declaration, which causes no trouble, from the elaboration issues
of the task object, which is also unproblematic, since it is now independent
of the elaboration of  @code{Utils}.
This separation of concerns also corresponds to
a generally sound engineering principle of separating declarations
from instances. This version of the program also compiles, binds, links,
and executes, generating the expected output.

@item
Use No_Entry_Calls_In_Elaboration_Code restriction.
@cindex No_Entry_Calls_In_Elaboration_Code

The previous two approaches described how a program can be restructured
to avoid the special problems caused by library task bodies. in practice,
however, such restructuring may be difficult to apply to existing legacy code,
so we must consider solutions that do not require massive rewriting.

Let us consider more carefully why our original sample program works
under the dynamic model of elaboration. The reason is that the code
in the task body blocks immediately on the @code{accept}
statement. Now of course there is nothing to prohibit elaboration
code from making entry calls (for example from another library level task),
so we cannot tell in isolation that
the task will not execute the accept statement  during elaboration.

However, in practice it is very unusual to see elaboration code
make any entry calls, and the pattern of tasks starting
at elaboration time and then immediately blocking on @code{accept} or
@code{select} statements is very common. What this means is that
the compiler is being too pessimistic when it analyzes the
whole package body as though it might be executed at elaboration
time.

If we know that the elaboration code contains no entry calls, (a very safe
assumption most of the time, that could almost be made the default
behavior), then we can compile all units of the program under control
of the following configuration pragma:

@smallexample
pragma Restrictions (No_Entry_Calls_In_Elaboration_Code);
@end smallexample

@noindent
This pragma can be placed in the @file{gnat.adc} file in the usual
manner. If we take our original unmodified program and compile it
in the presence of a @file{gnat.adc} containing the above pragma,
then once again, we can compile, bind, link, and execute, obtaining
the expected result. In the presence of this pragma, the compiler does
not trace calls in a task body, that appear after the first @code{accept}
or @code{select} statement, and therefore does not report a potential
circularity in the original program.

The compiler will check to the extent it can that the above
restriction is not violated, but it is not always possible to do a
complete check at compile time, so it is important to use this
pragma only if the stated restriction is in fact met, that is to say
no task receives an entry call before elaboration of all units is completed.

@end itemize

@node Mixing Elaboration Models
@section Mixing Elaboration Models
@noindent
So far, we have assumed that the entire program is either compiled
using the dynamic model or static model, ensuring consistency. It
is possible to mix the two models, but rules have to be followed
if this mixing is done to ensure that elaboration checks are not
omitted.

The basic rule is that @emph{a unit compiled with the static model cannot
be @code{with'ed} by a unit compiled with the dynamic model}. The
reason for this is that in the static model, a unit assumes that
its clients guarantee to use (the equivalent of) pragma
@code{Elaborate_All} so that no elaboration checks are required
in inner subprograms, and this assumption is violated if the
client is compiled with dynamic checks.

The precise rule is as follows. A unit that is compiled with dynamic
checks can only @code{with} a unit that meets at least one of the
following criteria:

@itemize @bullet

@item
The @code{with'ed} unit is itself compiled with dynamic elaboration
checks (that is with the @option{-gnatE} switch.

@item
The @code{with'ed} unit is an internal GNAT implementation unit from
the System, Interfaces, Ada, or GNAT hierarchies.

@item
The @code{with'ed} unit has pragma Preelaborate or pragma Pure.

@item
The @code{with'ing} unit (that is the client) has an explicit pragma
@code{Elaborate_All} for the @code{with'ed} unit.

@end itemize

@noindent
If this rule is violated, that is if a unit with dynamic elaboration
checks @code{with's} a unit that does not meet one of the above four
criteria, then the binder (@code{gnatbind}) will issue a warning
similar to that in the following example:

@smallexample
warning: "x.ads" has dynamic elaboration checks and with's
warning:   "y.ads" which has static elaboration checks
@end smallexample

@noindent
These warnings indicate that the rule has been violated, and that as a result
elaboration checks may be missed in the resulting executable file.
This warning may be suppressed using the @code{-ws} binder switch
in the usual manner.

One useful application of this mixing rule is in the case of a subsystem
which does not itself @code{with} units from the remainder of the
application. In this case, the entire subsystem can be compiled with
dynamic checks to resolve a circularity in the subsystem, while
allowing the main application that uses this subsystem to be compiled
using the more reliable default static model.

@node What to Do If the Default Elaboration Behavior Fails
@section What to Do If the Default Elaboration Behavior Fails

@noindent
If the binder cannot find an acceptable order, it outputs detailed
diagnostics. For example:
@smallexample
@group
@iftex
@leftskip=0cm
@end iftex
error: elaboration circularity detected
info:   "proc (body)" must be elaborated before "pack (body)"
info:     reason: Elaborate_All probably needed in unit "pack (body)"
info:     recompile "pack (body)" with -gnatwl
info:                             for full details
info:       "proc (body)"
info:         is needed by its spec:
info:       "proc (spec)"
info:         which is withed by:
info:       "pack (body)"
info:  "pack (body)" must be elaborated before "proc (body)"
info:     reason: pragma Elaborate in unit "proc (body)"
@end group

@end smallexample

@noindent
In this case we have a cycle that the binder cannot break. On the one
hand, there is an explicit pragma Elaborate in @code{proc} for
@code{pack}. This means that the body of @code{pack} must be elaborated
before the body of @code{proc}. On the other hand, there is elaboration
code in @code{pack} that calls a subprogram in @code{proc}. This means
that for maximum safety, there should really be a pragma
Elaborate_All in @code{pack} for @code{proc} which would require that
the body of @code{proc} be elaborated before the body of
@code{pack}. Clearly both requirements cannot be satisfied.
Faced with a circularity of this kind, you have three different options.

@table @asis
@item Fix the program
The most desirable option from the point of view of long-term maintenance
is to rearrange the program so that the elaboration problems are avoided.
One useful technique is to place the elaboration code into separate
child packages. Another is to move some of the initialization code to
explicitly called subprograms, where the program controls the order
of initialization explicitly. Although this is the most desirable option,
it may be impractical and involve too much modification, especially in
the case of complex legacy code.

@item Perform dynamic checks
If the compilations are done using the
@option{-gnatE}
(dynamic elaboration check) switch, then GNAT behaves in
a quite different manner. Dynamic checks are generated for all calls
that could possibly result in raising an exception. With this switch,
the compiler does not generate implicit @code{Elaborate_All} pragmas.
The behavior then is exactly as specified in the Ada 95 Reference Manual.
The binder will generate an executable program that may or may not
raise @code{Program_Error}, and then it is the programmer's job to ensure
that it does not raise an exception. Note that it is important to
compile all units with the switch, it cannot be used selectively.

@item Suppress checks
The drawback of dynamic checks is that they generate a
significant overhead at run time, both in space and time. If you
are absolutely sure that your program cannot raise any elaboration
exceptions, and you still want to use the dynamic elaboration model,
then you can use the configuration pragma
@code{Suppress (Elaboration_Checks)} to suppress all such checks. For
example this pragma could be placed in the @file{gnat.adc} file.

@item Suppress checks selectively
When you know that certain calls in elaboration code cannot possibly
lead to an elaboration error, and the binder nevertheless generates warnings
on those calls and inserts Elaborate_All pragmas that lead to elaboration
circularities, it is possible to remove those warnings locally and obtain
a program that will bind. Clearly this can be unsafe, and it is the
responsibility of the programmer to make sure that the resulting program has
no elaboration anomalies. The pragma @code{Suppress (Elaboration_Check)} can
be used with different granularity to suppress warnings and break
elaboration circularities:

@itemize @bullet
@item
Place the pragma that names the called subprogram in the declarative part
that contains the call.

@item
Place the pragma in the declarative part, without naming an entity. This
disables warnings on all calls in the corresponding  declarative region.

@item
Place the pragma in the package spec that declares the called subprogram,
and name the subprogram. This disables warnings on all elaboration calls to
that subprogram.

@item
Place the pragma in the package spec that declares the called subprogram,
without naming any entity. This disables warnings on all elaboration calls to
all subprograms declared in this spec.
@end itemize

@noindent
These four cases are listed in order of decreasing safety, and therefore
require increasing programmer care in their application. Consider the
following program:
@smallexample

package Pack1 is
  function F1 return Integer;
  X1 : Integer;
end Pack1;

package Pack2 is
  function F2 return Integer;
  function Pure (x : integer) return integer;
  --  pragma Suppress (Elaboration_Check, On => Pure);  -- (3)
  --  pragma Suppress (Elaboration_Check);              -- (4)
end Pack2;

with Pack2;
package body Pack1 is
  function F1 return Integer is
  begin
    return 100;
  end F1;
  Val : integer := Pack2.Pure (11);    --  Elab. call (1)
begin
  declare
    --  pragma Suppress(Elaboration_Check, Pack2.F2);   -- (1)
    --  pragma Suppress(Elaboration_Check);             -- (2)
  begin
    X1 := Pack2.F2 + 1;                --  Elab. call (2)
  end;
end Pack1;

with Pack1;
package body Pack2 is
  function F2 return Integer is
  begin
     return Pack1.F1;
  end F2;
  function Pure (x : integer) return integer is
  begin
     return x ** 3 - 3 * x;
  end;
end Pack2;

with Pack1, Ada.Text_IO;
procedure Proc3 is
begin
  Ada.Text_IO.Put_Line(Pack1.X1'Img); -- 101
end Proc3;
@end smallexample
In the absence of any pragmas, an attempt to bind this program produces
the following diagnostics:
@smallexample
@group
@iftex
@leftskip=.5cm
@end iftex
error: elaboration circularity detected
info:    "pack1 (body)" must be elaborated before "pack1 (body)"
info:       reason: Elaborate_All probably needed in unit "pack1 (body)"
info:       recompile "pack1 (body)" with -gnatwl for full details
info:          "pack1 (body)"
info:             must be elaborated along with its spec:
info:          "pack1 (spec)"
info:             which is withed by:
info:          "pack2 (body)"
info:             which must be elaborated along with its spec:
info:          "pack2 (spec)"
info:             which is withed by:
info:          "pack1 (body)"
@end group
@end smallexample
The sources of the circularity are the two calls to @code{Pack2.Pure} and
@code{Pack2.F2} in the body of @code{Pack1}. We can see that the call to
F2 is safe, even though F2 calls F1, because the call appears after the
elaboration of the body of F1. Therefore the pragma (1) is safe, and will
remove the warning on the call. It is also possible to use pragma (2)
because there are no other potentially unsafe calls in the block.

@noindent
The call to @code{Pure} is safe because this function does not depend on the
state of @code{Pack2}. Therefore any call to this function is safe, and it
is correct to place pragma (3) in the corresponding package spec.

@noindent
Finally, we could place pragma (4) in the spec of @code{Pack2} to disable
warnings on all calls to functions declared therein. Note that this is not
necessarily safe, and requires more detailed examination of the subprogram
bodies involved. In particular, a call to @code{F2} requires that @code{F1}
be already elaborated.
@end table

@noindent
It is hard to generalize on which of these four approaches should be
taken. Obviously if it is possible to fix the program so that the default
treatment works, this is preferable, but this may not always be practical.
It is certainly simple enough to use
@option{-gnatE}
but the danger in this case is that, even if the GNAT binder
finds a correct elaboration order, it may not always do so,
and certainly a binder from another Ada compiler might not. A
combination of testing and analysis (for which the warnings generated
with the
@option{-gnatwl}
switch can be useful) must be used to ensure that the program is free
of errors. One switch that is useful in this testing is the
@code{^-p (pessimistic elaboration order)^/PESSIMISTIC_ELABORATION_ORDER^}
switch for
@code{gnatbind}.
Normally the binder tries to find an order that has the best chance of
of avoiding elaboration problems. With this switch, the binder
plays a devil's advocate role, and tries to choose the order that
has the best chance of failing. If your program works even with this
switch, then it has a better chance of being error free, but this is still
not a guarantee.

For an example of this approach in action, consider the C-tests (executable
tests) from the ACVC suite. If these are compiled and run with the default
treatment, then all but one of them succeed without generating any error
diagnostics from the binder. However, there is one test that fails, and
this is not surprising, because the whole point of this test is to ensure
that the compiler can handle cases where it is impossible to determine
a correct order statically, and it checks that an exception is indeed
raised at run time.

This one test must be compiled and run using the
@option{-gnatE}
switch, and then it passes. Alternatively, the entire suite can
be run using this switch. It is never wrong to run with the dynamic
elaboration switch if your code is correct, and we assume that the
C-tests are indeed correct (it is less efficient, but efficiency is
not a factor in running the ACVC tests.)

@node Elaboration for Access-to-Subprogram Values
@section Elaboration for Access-to-Subprogram Values
@cindex Access-to-subprogram

@noindent
The introduction of access-to-subprogram types in Ada 95 complicates
the handling of elaboration. The trouble is that it becomes
impossible to tell at compile time which procedure
is being called. This means that it is not possible for the binder
to analyze the elaboration requirements in this case.

If at the point at which the access value is created
(i.e., the evaluation of @code{P'Access} for a subprogram @code{P}),
the body of the subprogram is
known to have been elaborated, then the access value is safe, and its use
does not require a check. This may be achieved by appropriate arrangement
of the order of declarations if the subprogram is in the current unit,
or, if the subprogram is in another unit, by using pragma
@code{Pure}, @code{Preelaborate}, or @code{Elaborate_Body}
on the referenced unit.

If the referenced body is not known to have been elaborated at the point
the access value is created, then any use of the access value must do a
dynamic check, and this dynamic check will fail and raise a
@code{Program_Error} exception if the body has not been elaborated yet.
GNAT will generate the necessary checks, and in addition, if the
@option{-gnatwl}
switch is set, will generate warnings that such checks are required.

The use of dynamic dispatching for tagged types similarly generates
a requirement for dynamic checks, and premature calls to any primitive
operation of a tagged type before the body of the operation has been elaborated,
will result in the raising of @code{Program_Error}.

@node Summary of Procedures for Elaboration Control
@section Summary of Procedures for Elaboration Control
@cindex Elaboration control

@noindent
First, compile your program with the default options, using none of
the special elaboration control switches. If the binder successfully
binds your program, then you can be confident that, apart from issues
raised by the use of access-to-subprogram types and dynamic dispatching,
the program is free of elaboration errors. If it is important that the
program be portable, then use the
@option{-gnatwl}
switch to generate warnings about missing @code{Elaborate_All}
pragmas, and supply the missing pragmas.

If the program fails to bind using the default static elaboration
handling, then you can fix the program to eliminate the binder
message, or recompile the entire program with the
@option{-gnatE} switch to generate dynamic elaboration checks,
and, if you are sure there really are no elaboration problems,
use a global pragma @code{Suppress (Elaboration_Checks)}.

@node Other Elaboration Order Considerations
@section Other Elaboration Order Considerations
@noindent
This section has been entirely concerned with the issue of finding a valid
elaboration order, as defined by the Ada Reference Manual. In a case
where several elaboration orders are valid, the task is to find one
of the possible valid elaboration orders (and the static model in GNAT
will ensure that this is achieved).

The purpose of the elaboration rules in the Ada Reference Manual is to
make sure that no entity is accessed before it has been elaborated. For
a subprogram, this means that the spec and body must have been elaborated
before the subprogram is called. For an object, this means that the object
must have been elaborated before its value is read or written. A violation
of either of these two requirements is an access before elaboration order,
and this section has been all about avoiding such errors.

In the case where more than one order of elaboration is possible, in the
sense that access before elaboration errors are avoided, then any one of
the orders is "correct" in the sense that it meets the requirements of
the Ada Reference Manual, and no such error occurs.

However, it may be the case for a given program, that there are
constraints on the order of elaboration that come not from consideration
of avoiding elaboration errors, but rather from extra-lingual logic
requirements. Consider this example:

@smallexample
with Init_Constants;
package Constants is
   X : Integer := 0;
   Y : Integer := 0;
end Constants;

package Init_Constants is
   procedure Calc;
end Init_Constants;

with Constants;
package body Init_Constants is
   procedure Calc is begin null; end;
begin
   Constants.X := 3;
   Constants.Y := 4;
end Init_Constants;

with Constants;
package Calc is
   Z : Integer := Constants.X + Constants.Y;
end Calc;

with Calc;
with Text_IO; use Text_IO;
procedure Main is
begin
   Put_Line (Calc.Z'Img);
end Main;
@end smallexample

@noindent
In this example, there is more than one valid order of elaboration. For
example both the following are correct orders:

@smallexample
Init_Constants spec
Constants spec
Calc spec
Main body
Init_Constants body

  and

Init_Constants spec
Init_Constants body
Constants spec
Calc spec
Main body
@end smallexample

@noindent
There is no language rule to prefer one or the other, both are correct
from an order of elaboration point of view. But the programmatic effects
of the two orders are very different. In the first, the elaboration routine
of @code{Calc} initializes @code{Z} to zero, and then the main program
runs with this value of zero. But in the second order, the elaboration
routine of @code{Calc} runs after the body of Init_Constants has set
@code{X} and @code{Y} and thus @code{Z} is set to 7 before @code{Main}
runs.

One could perhaps by applying pretty clever non-artificial intelligence
to the situation guess that it is more likely that the second order of
elaboration is the one desired, but there is no formal linguistic reason
to prefer one over the other. In fact in this particular case, GNAT will
prefer the second order, because of the rule that bodies are elaborated
as soon as possible, but it's just luck that this is what was wanted
(if indeed the second order was preferred).

If the program cares about the order of elaboration routines in a case like
this, it is important to specify the order required. In this particular
case, that could have been achieved by adding to the spec of Calc:

@smallexample
pragma Elaborate_All (Constants);
@end smallexample

@noindent
which requires that the body (if any) and spec of @code{Constants},
as well as the body and spec of any unit @code{with}'ed by
@code{Constants} be elaborated before @code{Calc} is elaborated.

Clearly no automatic method can always guess which alternative you require,
and if you are working with legacy code that had constraints of this kind
which were not properly specified by adding @code{Elaborate} or
@code{Elaborate_All} pragmas, then indeed it is possible that two different
compilers can choose different orders.

The @code{gnatbind}
@code{^-p^/PESSIMISTIC_ELABORATION^} switch may be useful in smoking
out problems. This switch causes bodies to be elaborated as late as possible
instead of as early as possible. In the example above, it would have forced
the choice of the first elaboration order. If you get different results
when using this switch, and particularly if one set of results is right,
and one is wrong as far as you are concerned, it shows that you have some
missing @code{Elaborate} pragmas. For the example above, we have the
following output:

@smallexample
gnatmake -f -q main
main
 7
gnatmake -f -q main -bargs -p
main
 0
@end smallexample

@noindent
It is of course quite unlikely that both these results are correct, so
it is up to you in a case like this to investigate the source of the
difference, by looking at the two elaboration orders that are chosen,
and figuring out which is correct, and then adding the necessary
@code{Elaborate_All} pragmas to ensure the desired order.

@node The Cross-Referencing Tools gnatxref and gnatfind
@chapter  The Cross-Referencing Tools @code{gnatxref} and @code{gnatfind}
@findex gnatxref
@findex gnatfind

@noindent
The compiler generates cross-referencing information (unless
you set the @samp{-gnatx} switch), which are saved in the @file{.ali} files.
This information indicates where in the source each entity is declared and
referenced. Note that entities in package Standard are not included, but
entities in all other predefined units are included in the output.

Before using any of these two tools, you need to compile successfully your
application, so that GNAT gets a chance to generate the cross-referencing
information.

The two tools @code{gnatxref} and @code{gnatfind} take advantage of this
information to provide the user with the capability to easily locate the
declaration and references to an entity. These tools are quite similar,
the difference being that @code{gnatfind} is intended for locating
definitions and/or references to a specified entity or entities, whereas
@code{gnatxref} is oriented to generating a full report of all
cross-references.

To use these tools, you must not compile your application using the
@option{-gnatx} switch on the @file{gnatmake} command line (@inforef{The
GNAT Make Program gnatmake,,gnat_ug}). Otherwise, cross-referencing
information will not be generated.

@menu
* gnatxref Switches::
* gnatfind Switches::
* Project Files for gnatxref and gnatfind::
* Regular Expressions in gnatfind and gnatxref::
* Examples of gnatxref Usage::
* Examples of gnatfind Usage::
@end menu

@node gnatxref Switches
@section @code{gnatxref} Switches

@noindent
The command lines for @code{gnatxref} is:
@smallexample
$ gnatxref [switches] sourcefile1 [sourcefile2 ...]
@end smallexample

@noindent
where

@table @code
@item sourcefile1, sourcefile2
identifies the source files for which a report is to be generated. The
'with'ed units will be processed too. You must provide at least one file.

These file names are considered to be regular expressions, so for instance
specifying 'source*.adb' is the same as giving every file in the current
directory whose name starts with 'source' and whose extension is 'adb'.

@end table

@noindent
The switches can be :
@table @code
@item ^-a^/ALL_FILES^
If this switch is present, @code{gnatfind} and @code{gnatxref} will parse
the read-only files found in the library search path. Otherwise, these files
will be ignored. This option can be used to protect Gnat sources or your own
libraries from being parsed, thus making @code{gnatfind} and @code{gnatxref}
much faster, and their output much smaller.

@item -aIDIR
When looking for source files also look in directory DIR. The order in which
source file search is undertaken is the same as for @file{gnatmake}.

@item -aODIR
When searching for library and object files, look in directory
DIR. The order in which library files are searched is the same as for
@file{gnatmake}.

@item -nostdinc
Do not look for sources in the system default directory.

@item -nostdlib
Do not look for library files in the system default directory.

@item --RTS=@var{rts-path}
@cindex @code{--RTS} (@code{gnatxref})
Specifies the default location of the runtime library. Same meaning as the
equivalent @code{gnatmake} flag (see @ref{Switches for gnatmake}).

@item -d
If this switch is set @code{gnatxref} will output the parent type
reference for each matching derived types.

@item ^-f^/FULL_PATHNAME^
If this switch is set, the output file names will be preceded by their
directory (if the file was found in the search path). If this switch is
not set, the directory will not be printed.

@item ^-g^/IGNORE_LOCALS^
If this switch is set, information is output only for library-level
entities, ignoring local entities. The use of this switch may accelerate
@code{gnatfind} and @code{gnatxref}.

@item -IDIR
Equivalent to @samp{-aODIR -aIDIR}.

@item -pFILE
Specify a project file to use @xref{Project Files}.
By default, @code{gnatxref} and @code{gnatfind} will try to locate a
project file in the current directory.

If a project file is either specified or found by the tools, then the content
of the source directory and object directory lines are added as if they
had been specified respectively by @samp{^-aI^/SOURCE_SEARCH^}
and @samp{^-aO^OBJECT_SEARCH^}.
@item ^-u^/UNUSED^
Output only unused symbols. This may be really useful if you give your
main compilation unit on the command line, as @code{gnatxref} will then
display every unused entity and 'with'ed package.

@ifclear vms
@item -v
Instead of producing the default output, @code{gnatxref} will generate a
@file{tags} file that can be used by vi. For examples how to use this
feature, see @xref{Examples of gnatxref Usage}. The tags file is output
to the standard output, thus you will have to redirect it to a file.
@end ifclear

@end table

All these switches may be in any order on the command line, and may even
appear after the file names. They need not be separated by spaces, thus
you can say @samp{gnatxref ^-ag^/ALL_FILES/IGNORE_LOCALS^} instead of
@samp{gnatxref ^-a -g^/ALL_FILES /IGNORE_LOCALS^}.

@node gnatfind Switches
@section @code{gnatfind} Switches

@noindent
The command line for @code{gnatfind} is:

@smallexample
$ gnatfind [switches] pattern[:sourcefile[:line[:column]]]
      [file1 file2 ...]
@end smallexample

@noindent
where

@table @code
@item pattern
An entity will be output only if it matches the regular expression found
in @samp{pattern}, see @xref{Regular Expressions in gnatfind and gnatxref}.

Omitting the pattern is equivalent to specifying @samp{*}, which
will match any entity. Note that if you do not provide a pattern, you
have to provide both a sourcefile and a line.

Entity names are given in Latin-1, with uppercase/lowercase equivalence
for matching purposes. At the current time there is no support for
8-bit codes other than Latin-1, or for wide characters in identifiers.

@item sourcefile
@code{gnatfind} will look for references, bodies or declarations
of symbols referenced in @file{sourcefile}, at line @samp{line}
and column @samp{column}. See @pxref{Examples of gnatfind Usage}
for syntax examples.

@item line
is a decimal integer identifying the line number containing
the reference to the entity (or entities) to be located.

@item column
is a decimal integer identifying the exact location on the
line of the first character of the identifier for the
entity reference. Columns are numbered from 1.

@item file1 file2 ...
The search will be restricted to these files. If none are given, then
the search will be done for every library file in the search path.
These file must appear only after the pattern or sourcefile.

These file names are considered to be regular expressions, so for instance
specifying 'source*.adb' is the same as giving every file in the current
directory whose name starts with 'source' and whose extension is 'adb'.

Not that if you specify at least one file in this part, @code{gnatfind} may
sometimes not be able to find the body of the subprograms...

@end table

At least one of 'sourcefile' or 'pattern' has to be present on
the command line.

The following switches are available:
@table @code

@item ^-a^/ALL_FILES^
If this switch is present, @code{gnatfind} and @code{gnatxref} will parse
the read-only files found in the library search path. Otherwise, these files
will be ignored. This option can be used to protect Gnat sources or your own
libraries from being parsed, thus making @code{gnatfind} and @code{gnatxref}
much faster, and their output much smaller.

@item -aIDIR
When looking for source files also look in directory DIR. The order in which
source file search is undertaken is the same as for @file{gnatmake}.

@item -aODIR
When searching for library and object files, look in directory
DIR. The order in which library files are searched is the same as for
@file{gnatmake}.

@item -nostdinc
Do not look for sources in the system default directory.

@item -nostdlib
Do not look for library files in the system default directory.

@item --RTS=@var{rts-path}
@cindex @code{--RTS} (@code{gnatfind})
Specifies the default location of the runtime library. Same meaning as the
equivalent @code{gnatmake} flag (see @ref{Switches for gnatmake}).

@item -d
If this switch is set, then @code{gnatfind} will output the parent type
reference for each matching derived types.

@item ^-e^/EXPRESSIONS^
By default, @code{gnatfind} accept the simple regular expression set for
@samp{pattern}. If this switch is set, then the pattern will be
considered as full Unix-style regular expression.

@item ^-f^/FULL_PATHNAME^
If this switch is set, the output file names will be preceded by their
directory (if the file was found in the search path). If this switch is
not set, the directory will not be printed.

@item ^-g^/IGNORE_LOCALS^
If this switch is set, information is output only for library-level
entities, ignoring local entities. The use of this switch may accelerate
@code{gnatfind} and @code{gnatxref}.

@item -IDIR
Equivalent to @samp{-aODIR -aIDIR}.

@item -pFILE
Specify a project file (@pxref{Project Files}) to use.
By default, @code{gnatxref} and @code{gnatfind} will try to locate a
project file in the current directory.

If a project file is either specified or found by the tools, then the content
of the source directory and object directory lines are added as if they
had been specified respectively by @samp{^-aI^/SOURCE_SEARCH^} and
@samp{^-aO^/OBJECT_SEARCH^}.

@item ^-r^/REFERENCES^
By default, @code{gnatfind} will output only the information about the
declaration, body or type completion of the entities. If this switch is
set, the @code{gnatfind} will locate every reference to the entities in
the files specified on the command line (or in every file in the search
path if no file is given on the command line).

@item ^-s^/PRINT_LINES^
If this switch is set, then @code{gnatfind} will output the content
of the Ada source file lines were the entity was found.

@item -t
If this switch is set, then @code{gnatfind} will output the type hierarchy for
the specified type. It act like -d option but recursively from parent
type to parent type. When this switch is set it is not possible to
specify more than one file.

@end table

All these switches may be in any order on the command line, and may even
appear after the file names. They need not be separated by spaces, thus
you can say @samp{gnatxref ^-ag^/ALL_FILES/IGNORE_LOCALS^} instead of
@samp{gnatxref ^-a -g^/ALL_FILES /IGNORE_LOCALS^}.

As stated previously, gnatfind will search in every directory in the
search path. You can force it to look only in the current directory if
you specify @code{*} at the end of the command line.


@node Project Files for gnatxref and gnatfind
@section Project Files for @command{gnatxref} and @command{gnatfind}

@noindent
Project files allow a programmer to specify how to compile its
application, where to find sources,... These files are used primarily by
the Glide Ada mode, but they can also be used by the two tools
@code{gnatxref} and @code{gnatfind}.

A project file name must end with @file{.adp}. If a single one is
present in the current directory, then @code{gnatxref} and @code{gnatfind} will
extract the information from it. If multiple project files are found, none of
them is read, and you have to use the @samp{-p} switch to specify the one
you want to use.

The following lines can be included, even though most of them have default
values which can be used in most cases.
The lines can be entered in any order in the file.
Except for @samp{src_dir} and @samp{obj_dir}, you can only have one instance of
each line. If you have multiple instances, only the last one is taken into
account.

@table @code
@item src_dir=DIR         [default: "^./^[]^"]
specifies a directory where to look for source files. Multiple src_dir lines
can be specified and they will be searched in the order they
are specified.

@item obj_dir=DIR         [default: "^./^[]^"]
specifies a directory where to look for object and library files. Multiple
obj_dir lines can be specified and they will be searched in the order they
are specified

@item comp_opt=SWITCHES   [default: ""]
creates a variable which can be referred to subsequently by using
the @samp{$@{comp_opt@}} notation. This is intended to store the default
switches given to @file{gnatmake} and @file{gcc}.

@item bind_opt=SWITCHES   [default: ""]
creates a variable which can be referred to subsequently by using
the @samp{$@{bind_opt@}} notation. This is intended to store the default
switches given to @file{gnatbind}.

@item link_opt=SWITCHES   [default: ""]
creates a variable which can be referred to subsequently by using
the @samp{$@{link_opt@}} notation. This is intended to store the default
switches given to @file{gnatlink}.

@item main=EXECUTABLE     [default: ""]
specifies the name of the executable for the application. This variable can
be referred to in the following lines by using the @samp{$@{main@}} notation.

@ifset vms
@item comp_cmd=COMMAND    [default: "GNAT COMPILE /SEARCH=$@{src_dir@} /DEBUG /TRY_SEMANTICS"]
@end ifset
@ifclear vms
@item comp_cmd=COMMAND    [default: "gcc -c -I$@{src_dir@} -g -gnatq"]
@end ifclear
specifies the command used to compile a single file in the application.

@ifset vms
@item make_cmd=COMMAND    [default: "GNAT MAKE $@{main@} /SOURCE_SEARCH=$@{src_dir@} /OBJECT_SEARCH=$@{obj_dir@} /DEBUG /TRY_SEMANTICS /COMPILER_QUALIFIERS $@{comp_opt@} /BINDER_QUALIFIERS $@{bind_opt@} /LINKER_QUALIFIERS $@{link_opt@}"]
@end ifset
@ifclear vms
@item make_cmd=COMMAND    [default: "gnatmake $@{main@} -aI$@{src_dir@} -aO$@{obj_dir@} -g -gnatq -cargs $@{comp_opt@} -bargs $@{bind_opt@} -largs $@{link_opt@}"]
@end ifclear
specifies the command used to recompile the whole application.

@item run_cmd=COMMAND     [default: "$@{main@}"]
specifies the command used to run the application.

@item debug_cmd=COMMAND   [default: "gdb $@{main@}"]
specifies the command used to debug the application

@end table

@code{gnatxref} and @code{gnatfind} only take into account the @samp{src_dir}
and @samp{obj_dir} lines, and ignore the others.

@node Regular Expressions in gnatfind and gnatxref
@section  Regular Expressions in @code{gnatfind} and @code{gnatxref}

@noindent
As specified in the section about @code{gnatfind}, the pattern can be a
regular expression. Actually, there are to set of regular expressions
which are recognized by the program :

@table @code
@item globbing patterns
These are the most usual regular expression. They are the same that you
generally used in a Unix shell command line, or in a DOS session.

Here is a more formal grammar :
@smallexample
@group
@iftex
@leftskip=.5cm
@end iftex
regexp ::= term
term   ::= elmt            -- matches elmt
term   ::= elmt elmt       -- concatenation (elmt then elmt)
term   ::= *               -- any string of 0 or more characters
term   ::= ?               -- matches any character
term   ::= [char @{char@}] -- matches any character listed
term   ::= [char - char]   -- matches any character in range
@end group
@end smallexample

@item full regular expression
The second set of regular expressions is much more powerful. This is the
type of regular expressions recognized by utilities such a @file{grep}.

The following is the form of a regular expression, expressed in Ada
reference manual style BNF is as follows

@smallexample
@iftex
@leftskip=.5cm
@end iftex
@group
regexp ::= term @{| term@} -- alternation (term or term ...)

term ::= item @{item@}     -- concatenation (item then item)

item ::= elmt              -- match elmt
item ::= elmt *            -- zero or more elmt's
item ::= elmt +            -- one or more elmt's
item ::= elmt ?            -- matches elmt or nothing
@end group
@group
elmt ::= nschar            -- matches given character
elmt ::= [nschar @{nschar@}]   -- matches any character listed
elmt ::= [^^^ nschar @{nschar@}] -- matches any character not listed
elmt ::= [char - char]     -- matches chars in given range
elmt ::= \ char            -- matches given character
elmt ::= .                 -- matches any single character
elmt ::= ( regexp )        -- parens used for grouping

char ::= any character, including special characters
nschar ::= any character except ()[].*+?^^^
@end group
@end smallexample

Following are a few examples :

@table @samp
@item abcde|fghi
will match any of the two strings 'abcde' and 'fghi'.

@item abc*d
will match any string like 'abd', 'abcd', 'abccd', 'abcccd', and so on

@item [a-z]+
will match any string which has only lowercase characters in it (and at
least one character

@end table
@end table

@node Examples of gnatxref Usage
@section Examples of @code{gnatxref} Usage

@subsection General Usage

@noindent
For the following examples, we will consider the following units :

@smallexample
@group
@cartouche
main.ads:
1: @b{with} Bar;
2: @b{package} Main @b{is}
3:     @b{procedure} Foo (B : @b{in} Integer);
4:     C : Integer;
5: @b{private}
6:     D : Integer;
7: @b{end} Main;

main.adb:
1: @b{package body} Main @b{is}
2:     @b{procedure} Foo (B : @b{in} Integer) @b{is}
3:     @b{begin}
4:        C := B;
5:        D := B;
6:        Bar.Print (B);
7:        Bar.Print (C);
8:     @b{end} Foo;
9: @b{end} Main;

bar.ads:
1: @b{package} Bar @b{is}
2:     @b{procedure} Print (B : Integer);
3: @b{end} bar;
@end cartouche
@end group
@end smallexample

@table @code

@noindent
The first thing to do is to recompile your application (for instance, in
that case just by doing a @samp{gnatmake main}, so that GNAT generates
the cross-referencing information.
You can then issue any of the following commands:

@item gnatxref main.adb
@code{gnatxref} generates cross-reference information for main.adb
and every unit 'with'ed by main.adb.

The output would be:
@smallexample
@iftex
@leftskip=0cm
@end iftex
B                                                      Type: Integer
  Decl: bar.ads           2:22
B                                                      Type: Integer
  Decl: main.ads          3:20
  Body: main.adb          2:20
  Ref:  main.adb          4:13     5:13     6:19
Bar                                                    Type: Unit
  Decl: bar.ads           1:9
  Ref:  main.adb          6:8      7:8
       main.ads           1:6
C                                                      Type: Integer
  Decl: main.ads          4:5
  Modi: main.adb          4:8
  Ref:  main.adb          7:19
D                                                      Type: Integer
  Decl: main.ads          6:5
  Modi: main.adb          5:8
Foo                                                    Type: Unit
  Decl: main.ads          3:15
  Body: main.adb          2:15
Main                                                    Type: Unit
  Decl: main.ads          2:9
  Body: main.adb          1:14
Print                                                   Type: Unit
  Decl: bar.ads           2:15
  Ref:  main.adb          6:12     7:12
@end smallexample

@noindent
that is the entity @code{Main} is declared in main.ads, line 2, column 9,
its body is in main.adb, line 1, column 14 and is not referenced any where.

The entity @code{Print} is declared in bar.ads, line 2, column 15 and it
it referenced in main.adb, line 6 column 12 and line 7 column 12.

@item gnatxref package1.adb package2.ads
@code{gnatxref} will generates cross-reference information for
package1.adb, package2.ads and any other package 'with'ed by any
of these.

@end table

@ifclear vms
@subsection Using gnatxref with vi

@code{gnatxref} can generate a tags file output, which can be used
directly from @file{vi}. Note that the standard version of @file{vi}
will not work properly with overloaded symbols. Consider using another
free implementation of @file{vi}, such as @file{vim}.

@smallexample
$ gnatxref -v gnatfind.adb > tags
@end smallexample

@noindent
will generate the tags file for @code{gnatfind} itself (if the sources
are in the search path!).

From @file{vi}, you can then use the command @samp{:tag @i{entity}}
(replacing @i{entity} by whatever you are looking for), and vi will
display a new file with the corresponding declaration of entity.
@end ifclear

@node Examples of gnatfind Usage
@section Examples of @code{gnatfind} Usage

@table @code

@item gnatfind ^-f^/FULL_PATHNAME^ xyz:main.adb
Find declarations for all entities xyz referenced at least once in
main.adb. The references are search in every library file in the search
path.

The directories will be printed as well (as the @samp{^-f^/FULL_PATHNAME^}
switch is set)

The output will look like:
@smallexample
^directory/^[directory]^main.ads:106:14: xyz <= declaration
^directory/^[directory]^main.adb:24:10: xyz <= body
^directory/^[directory]^foo.ads:45:23: xyz <= declaration
@end smallexample

@noindent
that is to say, one of the entities xyz found in main.adb is declared at
line 12 of main.ads (and its body is in main.adb), and another one is
declared at line 45 of foo.ads

@item gnatfind ^-fs^/FULL_PATHNAME/SOURCE_LINE^ xyz:main.adb
This is the same command as the previous one, instead @code{gnatfind} will
display the content of the Ada source file lines.

The output will look like:

@smallexample
^directory/^[directory]^main.ads:106:14: xyz <= declaration
   procedure xyz;
^directory/^[directory]^main.adb:24:10: xyz <= body
   procedure xyz is
^directory/^[directory]^foo.ads:45:23: xyz <= declaration
   xyz : Integer;
@end smallexample

@noindent
This can make it easier to find exactly the location your are looking
for.

@item gnatfind ^-r^/REFERENCES^ "*x*":main.ads:123 foo.adb
Find references to all entities containing an x that are
referenced on line 123 of main.ads.
The references will be searched only in main.adb and foo.adb.

@item gnatfind main.ads:123
Find declarations and bodies for all entities that are referenced on
line 123 of main.ads.

This is the same as @code{gnatfind "*":main.adb:123}.

@item gnatfind ^mydir/^[mydir]^main.adb:123:45
Find the declaration for the entity referenced at column 45 in
line 123 of file main.adb in directory mydir. Note that it
is usual to omit the identifier name when the column is given,
since the column position identifies a unique reference.

The column has to be the beginning of the identifier, and should not
point to any character in the middle of the identifier.

@end table

@node File Name Krunching Using gnatkr
@chapter File Name Krunching Using @code{gnatkr}
@findex gnatkr

@noindent
This chapter discusses the method used by the compiler to shorten
the default file names chosen for Ada units so that they do not
exceed the maximum length permitted. It also describes the
@code{gnatkr} utility that can be used to determine the result of
applying this shortening.
@menu
* About gnatkr::
* Using gnatkr::
* Krunching Method::
* Examples of gnatkr Usage::
@end menu

@node About gnatkr
@section About @code{gnatkr}

@noindent
The default file naming rule in GNAT
is that the file name must be derived from
the unit name. The exact default rule is as follows:
@itemize @bullet
@item
Take the unit name and replace all dots by hyphens.
@item
If such a replacement occurs in the
second character position of a name, and the first character is
^a, g, s, or i^A, G, S, or I^ then replace the dot by the character
^~ (tilde)^$ (dollar sign)^
instead of a minus.
@end itemize
The reason for this exception is to avoid clashes
with the standard names for children of System, Ada, Interfaces,
and GNAT, which use the prefixes ^s- a- i- and g-^S- A- I- and G-^
respectively.

The @code{^-gnatk^/FILE_NAME_MAX_LENGTH=^@var{nn}}
switch of the compiler activates a "krunching"
circuit that limits file names to nn characters (where nn is a decimal
integer). For example, using OpenVMS,
where the maximum file name length is
39, the value of nn is usually set to 39, but if you want to generate
a set of files that would be usable if ported to a system with some
different maximum file length, then a different value can be specified.
The default value of 39 for OpenVMS need not be specified.

The @code{gnatkr} utility can be used to determine the krunched name for
a given file, when krunched to a specified maximum length.

@node Using gnatkr
@section Using @code{gnatkr}

@noindent
The @code{gnatkr} command has the form

@ifclear vms
@smallexample
$ gnatkr @var{name} [@var{length}]
@end smallexample
@end ifclear

@ifset vms
@smallexample
$ gnatkr @var{name} /COUNT=nn
@end smallexample
@end ifset

@noindent
@var{name} can be an Ada name with dots or the GNAT name of the unit,
where the dots representing child units or subunit are replaced by
hyphens. The only confusion arises if a name ends in @code{.ads} or
@code{.adb}. @code{gnatkr} takes this to be an extension if there are
no other dots in the name^ and the whole name is in lowercase^^.

@var{length} represents the length of the krunched name. The default
when no argument is given is ^8^39^ characters. A length of zero stands for
unlimited, in other words do not chop except for system files which are
always ^8^39^.

@noindent
The output is the krunched name. The output has an extension only if the
original argument was a file name with an extension.

@node Krunching Method
@section Krunching Method

@noindent
The initial file name is determined by the name of the unit that the file
contains. The name is formed by taking the full expanded name of the
unit and replacing the separating dots with hyphens and
using ^lowercase^uppercase^
for all letters, except that a hyphen in the second character position is
replaced by a ^tilde^dollar sign^ if the first character is
^a, i, g, or s^A, I, G, or S^.
The extension is @code{.ads} for a
specification and @code{.adb} for a body.
Krunching does not affect the extension, but the file name is shortened to
the specified length by following these rules:

@itemize @bullet
@item
The name is divided into segments separated by hyphens, tildes or
underscores and all hyphens, tildes, and underscores are
eliminated. If this leaves the name short enough, we are done.

@item
If the name is too long, the longest segment is located (left-most if there are two
of equal length), and shortened by dropping its last character. This is
repeated until the name is short enough.

As an example, consider the krunching of @*@file{our-strings-wide_fixed.adb}
to fit the name into 8 characters as required by some operating systems.

@smallexample
our-strings-wide_fixed 22
our strings wide fixed 19
our string  wide fixed 18
our strin   wide fixed 17
our stri    wide fixed 16
our stri    wide fixe  15
our str     wide fixe  14
our str     wid  fixe  13
our str     wid  fix   12
ou  str     wid  fix   11
ou  st      wid  fix   10
ou  st      wi   fix   9
ou  st      wi   fi    8
Final file name: oustwifi.adb
@end smallexample

@item
The file names for all predefined units are always krunched to eight
characters. The krunching of these predefined units uses the following
special prefix replacements:

@table @file
@item ada-
replaced by @file{^a^A^-}

@item gnat-
replaced by @file{^g^G^-}

@item interfaces-
replaced by @file{^i^I^-}

@item system-
replaced by @file{^s^S^-}
@end table

These system files have a hyphen in the second character position. That
is why normal user files replace such a character with a
^tilde^dollar sign^, to
avoid confusion with system file names.

As an example of this special rule, consider
@*@file{ada-strings-wide_fixed.adb}, which gets krunched as follows:

@smallexample
ada-strings-wide_fixed 22
a-  strings wide fixed 18
a-  string  wide fixed 17
a-  strin   wide fixed 16
a-  stri    wide fixed 15
a-  stri    wide fixe  14
a-  str     wide fixe  13
a-  str     wid  fixe  12
a-  str     wid  fix   11
a-  st      wid  fix   10
a-  st      wi   fix   9
a-  st      wi   fi    8
Final file name: a-stwifi.adb
@end smallexample
@end itemize

Of course no file shortening algorithm can guarantee uniqueness over all
possible unit names, and if file name krunching is used then it is your
responsibility to ensure that no name clashes occur. The utility
program @code{gnatkr} is supplied for conveniently determining the
krunched name of a file.

@node Examples of gnatkr Usage
@section Examples of @code{gnatkr} Usage

@smallexample
@iftex
@leftskip=0cm
@end iftex
@ifclear vms
$ gnatkr very_long_unit_name.ads      --> velounna.ads
$ gnatkr grandparent-parent-child.ads --> grparchi.ads
$ gnatkr Grandparent.Parent.Child     --> grparchi
@end ifclear
$ gnatkr very_long_unit_name.ads/count=6 --> vlunna.ads
$ gnatkr very_long_unit_name.ads/count=0 --> very_long_unit_name.ads
@end smallexample

@node Preprocessing Using gnatprep
@chapter Preprocessing Using @code{gnatprep}
@findex gnatprep

@noindent
The @code{gnatprep} utility provides
a simple preprocessing capability for Ada programs.
It is designed for use with GNAT, but is not dependent on any special
features of GNAT.

@menu
* Using gnatprep::
* Switches for gnatprep::
* Form of Definitions File::
* Form of Input Text for gnatprep::
@end menu

@node Using gnatprep
@section Using @code{gnatprep}

@noindent
To call @code{gnatprep} use

@smallexample
$ gnatprep [-bcrsu] [-Dsymbol=value] infile outfile [deffile]
@end smallexample

@noindent
where
@table @code
@item infile
is the full name of the input file, which is an Ada source
file containing preprocessor directives.

@item outfile
is the full name of the output file, which is an Ada source
in standard Ada form. When used with GNAT, this file name will
normally have an ads or adb suffix.

@item deffile
is the full name of a text file containing definitions of
symbols to be referenced by the preprocessor. This argument is
optional, and can be replaced by the use of the @code{-D} switch.

@item switches
is an optional sequence of switches as described in the next section.
@end table

@node Switches for gnatprep
@section Switches for @code{gnatprep}

@table @code

@item ^-b^/BLANK_LINES^
Causes both preprocessor lines and the lines deleted by
preprocessing to be replaced by blank lines in the output source file,
preserving line numbers in the output file.

@item ^-c^/COMMENTS^
Causes both preprocessor lines and the lines deleted
by preprocessing to be retained in the output source as comments marked
with the special string "--! ". This option will result in line numbers
being preserved in the output file.

@item -Dsymbol=value
Defines a new symbol, associated with value. If no value is given on the
command line, then symbol is considered to be @code{True}. This switch
can be used in place of a definition file.

@ifset vms
@item /REMOVE (default)
This is the default setting which causes lines deleted by preprocessing
to be entirely removed from the output file.
@end ifset

@item ^-r^/REFERENCE^
Causes a @code{Source_Reference} pragma to be generated that
references the original input file, so that error messages will use
the file name of this original file. The use of this switch implies
that preprocessor lines are not to be removed from the file, so its
use will force @code{^-b^/BLANK_LINES^} mode if
@code{^-c^/COMMENTS^}
has not been specified explicitly.

Note that if the file to be preprocessed contains multiple units, then
it will be necessary to @code{gnatchop} the output file from
@code{gnatprep}. If a @code{Source_Reference} pragma is present
in the preprocessed file, it will be respected by
@code{gnatchop ^-r^/REFERENCE^}
so that the final chopped files will correctly refer to the original
input source file for @code{gnatprep}.

@item ^-s^/SYMBOLS^
Causes a sorted list of symbol names and values to be
listed on the standard output file.

@item ^-u^/UNDEFINED^
Causes undefined symbols to be treated as having the value FALSE in the context
of a preprocessor test. In the absence of this option, an undefined symbol in
a @code{#if} or @code{#elsif} test will be treated as an error.

@end table

@ifclear vms
@noindent
Note: if neither @code{-b} nor @code{-c} is present,
then preprocessor lines and
deleted lines are completely removed from the output, unless -r is
specified, in which case -b is assumed.
@end ifclear

@node Form of Definitions File
@section Form of Definitions File

@noindent
The definitions file contains lines of the form

@smallexample
symbol := value
@end smallexample

@noindent
where symbol is an identifier, following normal Ada (case-insensitive)
rules for its syntax, and value is one of the following:

@itemize @bullet
@item
Empty, corresponding to a null substitution
@item
A string literal using normal Ada syntax
@item
Any sequence of characters from the set
(letters, digits, period, underline).
@end itemize

@noindent
Comment lines may also appear in the definitions file, starting with
the usual @code{--},
and comments may be added to the definitions lines.

@node Form of Input Text for gnatprep
@section Form of Input Text for @code{gnatprep}

@noindent
The input text may contain preprocessor conditional inclusion lines,
as well as general symbol substitution sequences.

The preprocessor conditional inclusion commands have the form

@smallexample
@group
@cartouche
#if @i{expression} [then]
   lines
#elsif @i{expression} [then]
   lines
#elsif @i{expression} [then]
   lines
...
#else
   lines
#end if;
@end cartouche
@end group
@end smallexample

@noindent
In this example, @i{expression} is defined by the following grammar:
@smallexample
@i{expression} ::=  <symbol>
@i{expression} ::=  <symbol> = "<value>"
@i{expression} ::=  <symbol> = <symbol>
@i{expression} ::=  <symbol> 'Defined
@i{expression} ::=  not @i{expression}
@i{expression} ::=  @i{expression} and @i{expression}
@i{expression} ::=  @i{expression} or @i{expression}
@i{expression} ::=  @i{expression} and then @i{expression}
@i{expression} ::=  @i{expression} or else @i{expression}
@i{expression} ::=  ( @i{expression} )
@end smallexample

@noindent
For the first test (@i{expression} ::= <symbol>) the symbol must have
either the value true or false, that is to say the right-hand of the
symbol definition must be one of the (case-insensitive) literals
@code{True} or @code{False}. If the value is true, then the
corresponding lines are included, and if the value is false, they are
excluded.

The test (@i{expression} ::= <symbol> @code{'Defined}) is true only if
the symbol has been defined in the definition file or by a @code{-D}
switch on the command line. Otherwise, the test is false.

The equality tests are case insensitive, as are all the preprocessor lines.

If the symbol referenced is not defined in the symbol definitions file,
then the effect depends on whether or not switch @code{-u}
is specified. If so, then the symbol is treated as if it had the value
false and the test fails. If this switch is not specified, then
it is an error to reference an undefined symbol. It is also an error to
reference a symbol that is defined with a value other than @code{True}
or @code{False}.

The use of the @code{not} operator inverts the sense of this logical test, so
that the lines are included only if the symbol is not defined.
The @code{then} keyword is optional as shown

The @code{#} must be the first non-blank character on a line, but
otherwise the format is free form. Spaces or tabs may appear between
the @code{#} and the keyword. The keywords and the symbols are case
insensitive as in normal Ada code. Comments may be used on a
preprocessor line, but other than that, no other tokens may appear on a
preprocessor line. Any number of @code{elsif} clauses can be present,
including none at all. The @code{else} is optional, as in Ada.

The @code{#} marking the start of a preprocessor line must be the first
non-blank character on the line, i.e. it must be preceded only by
spaces or horizontal tabs.

Symbol substitution outside of preprocessor lines is obtained by using
the sequence

@smallexample
$symbol
@end smallexample

@noindent
anywhere within a source line, except in a comment or within a
string literal. The identifier
following the @code{$} must match one of the symbols defined in the symbol
definition file, and the result is to substitute the value of the
symbol in place of @code{$symbol} in the output file.

Note that although the substitution of strings within a string literal
is not possible, it is possible to have a symbol whose defined value is
a string literal. So instead of setting XYZ to @code{hello} and writing:

@smallexample
Header : String := "$XYZ";
@end smallexample

@noindent
you should set XYZ to @code{"hello"} and write:

@smallexample
Header : String := $XYZ;
@end smallexample

@noindent
and then the substitution will occur as desired.

@ifset vms
@node The GNAT Run-Time Library Builder gnatlbr
@chapter The GNAT Run-Time Library Builder @code{gnatlbr}
@findex gnatlbr
@cindex Library builder

@noindent
@code{gnatlbr} is a tool for rebuilding the GNAT run time with user
supplied configuration pragmas.

@menu
* Running gnatlbr::
* Switches for gnatlbr::
* Examples of gnatlbr Usage::
@end menu

@node Running gnatlbr
@section Running @code{gnatlbr}

@noindent
The @code{gnatlbr} command has the form

@smallexample
@ifclear vms
$ gnatlbr --[create | set | delete]=directory --config=file
@end ifclear
@ifset vms
$ GNAT LIBRARY /[CREATE | SET | DELETE]=directory [/CONFIG=file]
@end ifset
@end smallexample

@node Switches for gnatlbr
@section Switches for @code{gnatlbr}

@noindent
@code{gnatlbr} recognizes the following switches:

@table @code
@item ^--create^/CREATE^=directory
@cindex @code{^--create^/CREATE^=directory} (@code{gnatlbr})
     Create the new run-time library in the specified directory.

@item ^--set^/SET^=directory
@cindex @code{^--set^/SET^=directory} (@code{gnatlbr})
     Make the library in the specified directory the current run-time
     library.

@item ^--delete^/DELETE^=directory
@cindex @code{^--delete^/DELETE^=directory} (@code{gnatlbr})
     Delete the run-time library in the specified directory.

@item ^--config^/CONFIG^=file
@cindex @code{^--config^/CONFIG^=file} (@code{gnatlbr})
     With ^--create^/CREATE^:
     Use the configuration pragmas in the specified file when building
     the library.

     With ^--set^/SET^:
     Use the configuration pragmas in the specified file when compiling.

@end table

@node Examples of gnatlbr Usage
@section Example of @code{gnatlbr} Usage

@smallexample
Contents of VAXFLOAT.ADC:
pragma Float_Representation (VAX_Float);

$ GNAT LIBRARY /CREATE=[.VAXFLOAT] /CONFIG=VAXFLOAT.ADC

GNAT LIBRARY rebuilds the run-time library in directory [.VAXFLOAT]

@end smallexample
@end ifset

@node The GNAT Library Browser gnatls
@chapter The GNAT Library Browser @code{gnatls}
@findex gnatls
@cindex Library browser

@noindent
@code{gnatls} is a tool that outputs information about compiled
units. It gives the relationship between objects, unit names and source
files. It can also be used to check the source dependencies of a unit
as well as various characteristics.

@menu
* Running gnatls::
* Switches for gnatls::
* Examples of gnatls Usage::
@end menu

@node Running gnatls
@section Running @code{gnatls}

@noindent
The @code{gnatls} command has the form

@smallexample
$ gnatls switches @var{object_or_ali_file}
@end smallexample

@noindent
The main argument is the list of object or @file{ali} files
(@pxref{The Ada Library Information Files})
for which information is requested.

In normal mode, without additional option, @code{gnatls} produces a
four-column listing. Each line represents information for a specific
object. The first column gives the full path of the object, the second
column gives the name of the principal unit in this object, the third
column gives the status of the source and the fourth column gives the
full path of the source representing this unit.
Here is a simple example of use:

@smallexample
$ gnatls *.o
^./^[]^demo1.o            demo1            DIF demo1.adb
^./^[]^demo2.o            demo2             OK demo2.adb
^./^[]^hello.o            h1                OK hello.adb
^./^[]^instr-child.o      instr.child      MOK instr-child.adb
^./^[]^instr.o            instr             OK instr.adb
^./^[]^tef.o              tef              DIF tef.adb
^./^[]^text_io_example.o  text_io_example   OK text_io_example.adb
^./^[]^tgef.o             tgef             DIF tgef.adb
@end smallexample

@noindent
The first line can be interpreted as follows: the main unit which is
contained in
object file @file{demo1.o} is demo1, whose main source is in
@file{demo1.adb}. Furthermore, the version of the source used for the
compilation of demo1 has been modified (DIF). Each source file has a status
qualifier which can be:

@table @code
@item OK (unchanged)
The version of the source file used for the compilation of the
specified unit corresponds exactly to the actual source file.

@item MOK (slightly modified)
The version of the source file used for the compilation of the
specified unit differs from the actual source file but not enough to
require recompilation. If you use gnatmake with the qualifier
@code{^-m (minimal recompilation)^/MINIMAL_RECOMPILATION^}, a file marked
MOK will not be recompiled.

@item DIF (modified)
No version of the source found on the path corresponds to the source
used to build this object.

@item ??? (file not found)
No source file was found for this unit.

@item HID (hidden,  unchanged version not first on PATH)
The version of the source that corresponds exactly to the source used
for compilation has been found on the path but it is hidden by another
version of the same source that has been modified.

@end table

@node Switches for gnatls
@section Switches for @code{gnatls}

@noindent
@code{gnatls} recognizes the following switches:

@table @code
@item ^-a^/ALL_UNITS^
@cindex @code{^-a^/ALL_UNITS^} (@code{gnatls})
Consider all units, including those of the predefined Ada library.
Especially useful with @code{^-d^/DEPENDENCIES^}.

@item ^-d^/DEPENDENCIES^
@cindex @code{^-d^/DEPENDENCIES^} (@code{gnatls})
List sources from which specified units depend on.

@item ^-h^/OUTPUT=OPTIONS^
@cindex @code{^-h^/OUTPUT=OPTIONS^} (@code{gnatls})
Output the list of options.

@item ^-o^/OUTPUT=OBJECTS^
@cindex @code{^-o^/OUTPUT=OBJECTS^} (@code{gnatls})
Only output information about object files.

@item ^-s^/OUTPUT=SOURCES^
@cindex @code{^-s^/OUTPUT=SOURCES^} (@code{gnatls})
Only output information about source files.

@item ^-u^/OUTPUT=UNITS^
@cindex @code{^-u^/OUTPUT=UNITS^} (@code{gnatls})
Only output information about compilation units.

@item ^-aO^/OBJECT_SEARCH=^@var{dir}
@itemx ^-aI^/SOURCE_SEARCH=^@var{dir}
@itemx ^-I^/SEARCH=^@var{dir}
@itemx  ^-I-^/NOCURRENT_DIRECTORY^
@itemx -nostdinc
Source path manipulation. Same meaning as the equivalent @code{gnatmake} flags
(see @ref{Switches for gnatmake}).

@item --RTS=@var{rts-path}
@cindex @code{--RTS} (@code{gnatls})
Specifies the default location of the runtime library. Same meaning as the
equivalent @code{gnatmake} flag (see @ref{Switches for gnatmake}).

@item ^-v^/OUTPUT=VERBOSE^
@cindex @code{^-s^/OUTPUT=VERBOSE^} (@code{gnatls})
Verbose mode. Output the complete source and object paths. Do not use
the default column layout but instead use long format giving as much as
information possible on each requested units, including special
characteristics such as:

@table @code
@item  Preelaborable
The unit is preelaborable in the Ada 95 sense.

@item No_Elab_Code
No elaboration code has been produced by the compiler for this unit.

@item Pure
The unit is pure in the Ada 95 sense.

@item Elaborate_Body
The unit contains a pragma Elaborate_Body.

@item Remote_Types
The unit contains a pragma Remote_Types.

@item Shared_Passive
The unit contains a pragma Shared_Passive.

@item Predefined
This unit is part of the predefined environment and cannot be modified
by the user.

@item Remote_Call_Interface
The unit contains a pragma Remote_Call_Interface.

@end table

@end table

@node Examples of gnatls Usage
@section Example of @code{gnatls} Usage
@ifclear vms

@noindent
Example of using the verbose switch. Note how the source and
object paths are affected by the ^-I^/SEARCH^ switch.

@smallexample
$ gnatls -v -I.. demo1.o

GNATLS 3.10w (970212) Copyright 1999 Free Software Foundation, Inc.

Source Search Path:
   <Current_Directory>
   ../
   /home/comar/local/adainclude/

Object Search Path:
   <Current_Directory>
   ../
   /home/comar/local/lib/gcc-lib/mips-sni-sysv4/2.7.2/adalib/

./demo1.o
   Unit =>
     Name   => demo1
     Kind   => subprogram body
     Flags  => No_Elab_Code
     Source => demo1.adb    modified
@end smallexample

@noindent
The following is an example of use of the dependency list.
Note the use of the -s switch
which gives a straight list of source files. This can be useful for
building specialized scripts.

@smallexample
$ gnatls -d demo2.o
./demo2.o   demo2        OK demo2.adb
                         OK gen_list.ads
                         OK gen_list.adb
                         OK instr.ads
                         OK instr-child.ads

$ gnatls -d -s -a demo1.o
demo1.adb
/home/comar/local/adainclude/ada.ads
/home/comar/local/adainclude/a-finali.ads
/home/comar/local/adainclude/a-filico.ads
/home/comar/local/adainclude/a-stream.ads
/home/comar/local/adainclude/a-tags.ads
gen_list.ads
gen_list.adb
/home/comar/local/adainclude/gnat.ads
/home/comar/local/adainclude/g-io.ads
instr.ads
/home/comar/local/adainclude/system.ads
/home/comar/local/adainclude/s-exctab.ads
/home/comar/local/adainclude/s-finimp.ads
/home/comar/local/adainclude/s-finroo.ads
/home/comar/local/adainclude/s-secsta.ads
/home/comar/local/adainclude/s-stalib.ads
/home/comar/local/adainclude/s-stoele.ads
/home/comar/local/adainclude/s-stratt.ads
/home/comar/local/adainclude/s-tasoli.ads
/home/comar/local/adainclude/s-unstyp.ads
/home/comar/local/adainclude/unchconv.ads
@end smallexample
@end ifclear

@ifset vms
@smallexample
GNAT LIST /DEPENDENCIES /OUTPUT=SOURCES /ALL_UNITS DEMO1.ADB

GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]ada.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]a-finali.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]a-filico.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]a-stream.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]a-tags.ads
demo1.adb
gen_list.ads
gen_list.adb
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]gnat.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]g-io.ads
instr.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]system.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-exctab.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-finimp.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-finroo.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-secsta.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-stalib.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-stoele.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-stratt.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-tasoli.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]s-unstyp.ads
GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB]unchconv.ads
@end smallexample
@end ifset

@ifclear vms
@node GNAT and Libraries
@chapter GNAT and Libraries
@cindex Library, building, installing

@noindent
This chapter addresses some of the issues related to building and using
a library with GNAT. It also shows how the GNAT run-time library can be
recompiled.

@menu
* Creating an Ada Library::
* Installing an Ada Library::
* Using an Ada Library::
* Creating an Ada Library to be Used in a Non-Ada Context::
* Rebuilding the GNAT Run-Time Library::
@end menu

@node Creating an Ada Library
@section Creating an Ada Library

@noindent
In the GNAT environment, a library has two components:
@itemize @bullet
@item
Source files.
@item
Compiled code and Ali files. See @ref{The Ada Library Information Files}.
@end itemize

@noindent
In order to use other packages @ref{The GNAT Compilation Model}
requires a certain number of sources to be available to the compiler.
The minimal set of
sources required includes the specs of all the packages that make up the
visible part of the library as well as all the sources upon which they
depend. The bodies of all visible generic units must also be provided.
@noindent
Although it is not strictly mandatory, it is recommended that all sources
needed to recompile the library be provided, so that the user can make
full use of inter-unit inlining and source-level debugging. This can also
make the situation easier for users that need to upgrade their compilation
toolchain and thus need to recompile the library from sources.

@noindent
The compiled code can be provided in different ways. The simplest way is
to provide directly the set of objects produced by the compiler during
the compilation of the library. It is also possible to group the objects
into an archive using whatever commands are provided by the operating
system. Finally, it is also possible to create a shared library (see
option -shared in the GCC manual).

@noindent
There are various possibilities for compiling the units that make up the
library: for example with a Makefile @ref{Using the GNU make Utility},
or with a conventional script.
For simple libraries, it is also possible to create a
dummy main program which depends upon all the packages that comprise the
interface of the library. This dummy main program can then be given to
gnatmake, in order to build all the necessary objects. Here is an example
of such a dummy program and the generic commands used to build an
archive or a shared library.

@smallexample
@iftex
@leftskip=.7cm
@end iftex
@b{with} My_Lib.Service1;
@b{with} My_Lib.Service2;
@b{with} My_Lib.Service3;
@b{procedure} My_Lib_Dummy @b{is}
@b{begin}
   @b{null};
@b{end};

# compiling the library
$ gnatmake -c my_lib_dummy.adb

# we don't need the dummy object itself
$ rm my_lib_dummy.o my_lib_dummy.ali

# create an archive with the remaining objects
$ ar rc libmy_lib.a *.o
# some systems may require "ranlib" to be run as well

# or create a shared library
$ gcc -shared -o libmy_lib.so *.o
# some systems may require the code to have been compiled with -fPIC
@end smallexample

@noindent
When the objects are grouped in an archive or a shared library, the user
needs to specify the desired library at link time, unless a pragma
linker_options has been used in one of the sources:
@smallexample
@b{pragma} Linker_Options ("-lmy_lib");
@end smallexample

@node Installing an Ada Library
@section Installing an Ada Library

@noindent
In the GNAT model, installing a library consists in copying into a specific
location the files that make up this library. It is possible to install
the sources in a different directory from the other files (ALI, objects,
archives) since the source path and the object path can easily be
specified separately.

@noindent
For general purpose libraries, it is possible for the system
administrator to put those libraries in the default compiler paths. To
achieve this, he must specify their location in the configuration files
"ada_source_path" and "ada_object_path" that must be located in the GNAT
installation tree at the same place as the gcc spec file. The location of
the gcc spec file can be determined as follows:
@smallexample
$ gcc -v
@end smallexample

@noindent
The configuration files mentioned above have simple format: each line in them
must contain one unique
directory name. Those names are added to the corresponding path
in their order of appearance in the file. The names can be either absolute
or relative, in the latter case, they are relative to where theses files
are located.

@noindent
"ada_source_path" and "ada_object_path" might actually not be present in a
GNAT installation, in which case, GNAT will look for its run-time library in
the directories "adainclude" for the sources and "adalib" for the
objects and ALI files. When the files exist, the compiler does not
look in "adainclude" and "adalib" at all, and thus the "ada_source_path" file
must contain the location for the GNAT run-time sources (which can simply
be "adainclude"). In the same way, the "ada_object_path" file must contain
the location for the GNAT run-time objects (which can simply
be "adalib").

@noindent
You can also specify a new default path to the runtime library at compilation
time with the switch "--RTS=@var{rts-path}". You can easily choose and change
the runtime you want your program to be compiled with. This switch is
recognized by gcc, gnatmake, gnatbind, gnatls, gnatfind and gnatxref.

@noindent
It is possible to install a library before or after the standard GNAT
library, by reordering the lines in the configuration files. In general, a
library must be installed before the GNAT library if it redefines any part of it.

@node Using an Ada Library
@section Using an Ada Library

@noindent
In order to use a Ada library, you need to make sure that this
library is on both your source and object path
@ref{Search Paths and the Run-Time Library (RTL)}
and @ref{Search Paths for gnatbind}. For
instance, you can use the library "mylib" installed in "/dir/my_lib_src"
and "/dir/my_lib_obj" with the following commands:

@smallexample
$ gnatmake -aI/dir/my_lib_src -aO/dir/my_lib_obj my_appl \
  -largs -lmy_lib
@end smallexample

@noindent
This can be simplified down to the following:
@smallexample
$ gnatmake my_appl
@end smallexample
when the following conditions are met:
@itemize @bullet
@item
"/dir/my_lib_src" has been added by the user to the environment
variable "ADA_INCLUDE_PATH", or by the administrator to the file
"ada_source_path"
@item
"/dir/my_lib_obj" has been added by the user to the environment
variable "ADA_OBJECTS_PATH", or by the administrator to the file
"ada_object_path"
@item
a pragma linker_options, as mentioned in @ref{Creating an Ada Library}
as been added to the sources.
@end itemize
@noindent

@node Creating an Ada Library to be Used in a Non-Ada Context
@section Creating an Ada Library to be Used in a Non-Ada Context

@noindent
The previous sections detailed how to create and install a library that
was usable from an Ada main program. Using this library in a non-Ada
context is not possible, because the elaboration of the library is
automatically done as part of the main program elaboration.

GNAT also provides the ability to build libraries that can be used both
in an Ada and non-Ada context.  This section describes how to build such
a library, and then how to use it from a C program. The method for
interfacing with the library from other languages such as Fortran for
instance remains the same.

@subsection Creating the Library

@itemize @bullet
@item Identify the units representing the interface of the library.

Here is an example of simple library interface:

@smallexample
package Interface is

   procedure Do_Something;

   procedure Do_Something_Else;

end Interface;
@end smallexample

@item Use @code{pragma Export} or @code{pragma Convention} for the
exported entities.

Our package @code{Interface} is then updated as follow:
@smallexample
package Interface is

   procedure Do_Something;
   pragma Export (C, Do_Something, "do_something");

   procedure Do_Something_Else;
   pragma Export (C, Do_Something_Else, "do_something_else");

end Interface;
@end smallexample

@item Compile all the units composing the library.

@item Bind the library objects.

This step is performed by invoking gnatbind with the @code{-L<prefix>}
switch. @code{gnatbind} will then generate the library elaboration
procedure (named @code{<prefix>init}) and the run-time finalization
procedure (named @code{<prefix>final}).

@smallexample
# generate the binder file in Ada
$ gnatbind -Lmylib interface

# generate the binder file in C
$ gnatbind -C -Lmylib interface
@end smallexample

@item Compile the files generated by the binder

@smallexample
$ gcc -c b~interface.adb
@end smallexample

@item Create the library;

The procedure is identical to the procedure explained in
@ref{Creating an Ada Library},
except that @file{b~interface.o} needs to be added to
the list of objects.

@smallexample
# create an archive file
$ ar cr libmylib.a b~interface.o <other object files>

# create a shared library
$ gcc -shared -o libmylib.so b~interface.o <other object files>
@end smallexample

@item Provide a "foreign" view of the library interface;

The example below shows the content of @code{mylib_interface.h} (note
that there is no rule for the naming of this file, any name can be used)
@smallexample
/* the library elaboration procedure */
extern void mylibinit (void);

/* the library finalization procedure */
extern void mylibfinal (void);

/* the interface exported by the library */
extern void do_something (void);
extern void do_something_else (void);
@end smallexample
@end itemize

@subsection Using the Library

@noindent
Libraries built as explained above can be used from any program, provided
that the elaboration procedures (named @code{mylibinit} in the previous
example) are called before the library services are used. Any number of
libraries can be used simultaneously, as long as the elaboration
procedure of each library is called.

Below is an example of C program that uses our @code{mylib} library.

@smallexample
#include "mylib_interface.h"

int
main (void)
@{
   /* First, elaborate the library before using it */
   mylibinit ();

   /* Main program, using the library exported entities */
   do_something ();
   do_something_else ();

   /* Library finalization at the end of the program */
   mylibfinal ();
   return 0;
@}
@end smallexample

@noindent
Note that this same library can be used from an equivalent Ada main
program. In addition, if the libraries are installed as detailed in
@ref{Installing an Ada Library}, it is not necessary to invoke the
library elaboration and finalization routines. The binder will ensure
that this is done as part of the main program elaboration and
finalization phases.

@subsection The Finalization Phase

@noindent
Invoking any library finalization procedure generated by @code{gnatbind}
shuts down the Ada run time permanently. Consequently, the finalization
of all Ada libraries must be performed at the end of the program. No
call to these libraries nor the Ada run time should be made past the
finalization phase.

@subsection Restrictions in Libraries

@noindent
The pragmas listed below should be used with caution inside libraries,
as they can create incompatibilities with other Ada libraries:
@itemize @bullet
@item pragma @code{Locking_Policy}
@item pragma @code{Queuing_Policy}
@item pragma @code{Task_Dispatching_Policy}
@item pragma @code{Unreserve_All_Interrupts}
@end itemize
When using a library that contains such pragmas, the user must make sure
that all libraries use the same pragmas with the same values. Otherwise,
a @code{Program_Error} will
be raised during the elaboration of the conflicting
libraries. The usage of these pragmas and its consequences for the user
should therefore be well documented.

Similarly, the traceback in exception occurrences mechanism should be
enabled or disabled in a consistent manner across all libraries.
Otherwise, a Program_Error will be raised during the elaboration of the
conflicting libraries.

If the @code{'Version} and @code{'Body_Version}
attributes are used inside a library, then it is necessary to
perform a @code{gnatbind} step that mentions all ali files in all
libraries, so that version identifiers can be properly computed.
In practice these attributes are rarely used, so this is unlikely
to be a consideration.

@node  Rebuilding the GNAT Run-Time Library
@section Rebuilding the GNAT Run-Time Library

@noindent
It may be useful to recompile the GNAT library in various contexts, the
most important one being the use of partition-wide configuration pragmas
such as Normalize_Scalar. A special Makefile called
@code{Makefile.adalib} is provided to that effect and can be found in
the directory containing the GNAT library. The location of this
directory depends on the way the GNAT environment has been installed and can
be determined by means of the command:

@smallexample
$ gnatls -v
@end smallexample

@noindent
The last entry in the object search path usually contains the
gnat library. This Makefile contains its own documentation and in
particular the set of instructions needed to rebuild a new library and
to use it.

@node Using the GNU make Utility
@chapter Using the GNU @code{make} Utility
@findex make

@noindent
This chapter offers some examples of makefiles that solve specific
problems. It does not explain how to write a makefile (see the GNU make
documentation), nor does it try to replace the @code{gnatmake} utility
(@pxref{The GNAT Make Program gnatmake}).

All the examples in this section are specific to the GNU version of
make. Although @code{make} is a standard utility, and the basic language
is the same, these examples use some advanced features found only in
@code{GNU make}.

@menu
* Using gnatmake in a Makefile::
* Automatically Creating a List of Directories::
* Generating the Command Line Switches::
* Overcoming Command Line Length Limits::
@end menu

@node Using gnatmake in a Makefile
@section Using gnatmake in a Makefile
@findex makefile
@cindex GNU make

@noindent
Complex project organizations can be handled in a very powerful way by
using GNU make combined with gnatmake. For instance, here is a Makefile
which allows you to build each subsystem of a big project into a separate
shared library. Such a makefile allows you to significantly reduce the link
time of very big applications while maintaining full coherence at
each step of the build process.

The list of dependencies are handled automatically by
@code{gnatmake}. The Makefile is simply used to call gnatmake in each of
the appropriate directories.

Note that you should also read the example on how to automatically
create the list of directories (@pxref{Automatically Creating a List of Directories})
which might help you in case your project has a lot of
subdirectories.

@smallexample
@iftex
@leftskip=0cm
@font@heightrm=cmr8
@heightrm
@end iftex
## This Makefile is intended to be used with the following directory
## configuration:
##  - The sources are split into a series of csc (computer software components)
##    Each of these csc is put in its own directory.
##    Their name are referenced by the directory names.
##    They will be compiled into shared library (although this would also work
##    with static libraries
##  - The main program (and possibly other packages that do not belong to any
##    csc is put in the top level directory (where the Makefile is).
##       toplevel_dir __ first_csc  (sources) __ lib (will contain the library)
##                    \_ second_csc (sources) __ lib (will contain the library)
##                    \_ ...
## Although this Makefile is build for shared library, it is easy to modify
## to build partial link objects instead (modify the lines with -shared and
## gnatlink below)
##
## With this makefile, you can change any file in the system or add any new
## file, and everything will be recompiled correctly (only the relevant shared
## objects will be recompiled, and the main program will be re-linked).

# The list of computer software component for your project. This might be
# generated automatically.
CSC_LIST=aa bb cc

# Name of the main program (no extension)
MAIN=main

# If we need to build objects with -fPIC, uncomment the following line
#NEED_FPIC=-fPIC

# The following variable should give the directory containing libgnat.so
# You can get this directory through 'gnatls -v'. This is usually the last
# directory in the Object_Path.
GLIB=...

# The directories for the libraries
# (This macro expands the list of CSC to the list of shared libraries, you
# could simply use the expanded form :
# LIB_DIR=aa/lib/libaa.so bb/lib/libbb.so cc/lib/libcc.so
LIB_DIR=$@{foreach dir,$@{CSC_LIST@},$@{dir@}/lib/lib$@{dir@}.so@}

$@{MAIN@}: objects $@{LIB_DIR@}
    gnatbind $@{MAIN@} $@{CSC_LIST:%=-aO%/lib@} -shared
    gnatlink $@{MAIN@} $@{CSC_LIST:%=-l%@}

objects::
    # recompile the sources
    gnatmake -c -i $@{MAIN@}.adb $@{NEED_FPIC@} $@{CSC_LIST:%=-I%@}

# Note: In a future version of GNAT, the following commands will be simplified
# by a new tool, gnatmlib
$@{LIB_DIR@}:
    mkdir -p $@{dir $@@ @}
    cd $@{dir $@@ @}; gcc -shared -o $@{notdir $@@ @} ../*.o -L$@{GLIB@} -lgnat
    cd $@{dir $@@ @}; cp -f ../*.ali .

# The dependencies for the modules
# Note that we have to force the expansion of *.o, since in some cases make won't
# be able to do it itself.
aa/lib/libaa.so: $@{wildcard aa/*.o@}
bb/lib/libbb.so: $@{wildcard bb/*.o@}
cc/lib/libcc.so: $@{wildcard cc/*.o@}

# Make sure all of the shared libraries are in the path before starting the
# program
run::
    LD_LIBRARY_PATH=`pwd`/aa/lib:`pwd`/bb/lib:`pwd`/cc/lib ./$@{MAIN@}

clean::
    $@{RM@} -rf $@{CSC_LIST:%=%/lib@}
    $@{RM@} $@{CSC_LIST:%=%/*.ali@}
    $@{RM@} $@{CSC_LIST:%=%/*.o@}
    $@{RM@} *.o *.ali $@{MAIN@}
@end smallexample

@node Automatically Creating a List of Directories
@section Automatically Creating a List of Directories

@noindent
In most makefiles, you will have to specify a list of directories, and
store it in a variable. For small projects, it is often easier to
specify each of them by hand, since you then have full control over what
is the proper order for these directories, which ones should be
included...

However, in larger projects, which might involve hundreds of
subdirectories, it might be more convenient to generate this list
automatically.

The example below presents two methods. The first one, although less
general, gives you more control over the list. It involves wildcard
characters, that are automatically expanded by @code{make}. Its
shortcoming is that you need to explicitly specify some of the
organization of your project, such as for instance the directory tree
depth, whether some directories are found in a separate tree,...

The second method is the most general one. It requires an external
program, called @code{find}, which is standard on all Unix systems. All
the directories found under a given root directory will be added to the
list.

@smallexample
@iftex
@leftskip=0cm
@font@heightrm=cmr8
@heightrm
@end iftex
# The examples below are based on the following directory hierarchy:
# All the directories can contain any number of files
# ROOT_DIRECTORY ->  a  ->  aa  ->  aaa
#                       ->  ab
#                       ->  ac
#                ->  b  ->  ba  ->  baa
#                       ->  bb
#                       ->  bc
# This Makefile creates a variable called DIRS, that can be reused any time
# you need this list (see the other examples in this section)

# The root of your project's directory hierarchy
ROOT_DIRECTORY=.

####
# First method: specify explicitly the list of directories
# This allows you to specify any subset of all the directories you need.
####

DIRS := a/aa/ a/ab/ b/ba/

####
# Second method: use wildcards
# Note that the argument(s) to wildcard below should end with a '/'.
# Since wildcards also return file names, we have to filter them out
# to avoid duplicate directory names.
# We thus use make's @code{dir} and @code{sort} functions.
# It sets DIRs to the following value (note that the directories aaa and baa
# are not given, unless you change the arguments to wildcard).
# DIRS= ./a/a/ ./b/ ./a/aa/ ./a/ab/ ./a/ac/ ./b/ba/ ./b/bb/ ./b/bc/
####

DIRS := $@{sort $@{dir $@{wildcard $@{ROOT_DIRECTORY@}/*/ $@{ROOT_DIRECTORY@}/*/*/@}@}@}

####
# Third method: use an external program
# This command is much faster if run on local disks, avoiding NFS slowdowns.
# This is the most complete command: it sets DIRs to the following value:
# DIRS= ./a ./a/aa ./a/aa/aaa ./a/ab ./a/ac ./b ./b/ba ./b/ba/baa ./b/bb ./b/bc
####

DIRS := $@{shell find $@{ROOT_DIRECTORY@} -type d -print@}

@end smallexample

@node Generating the Command Line Switches
@section Generating the Command Line Switches

@noindent
Once you have created the list of directories as explained in the
previous section (@pxref{Automatically Creating a List of Directories}),
you can easily generate the command line arguments to pass to gnatmake.

For the sake of completeness, this example assumes that the source path
is not the same as the object path, and that you have two separate lists
of directories.

@smallexample
# see "Automatically creating a list of directories" to create
# these variables
SOURCE_DIRS=
OBJECT_DIRS=

GNATMAKE_SWITCHES := $@{patsubst %,-aI%,$@{SOURCE_DIRS@}@}
GNATMAKE_SWITCHES += $@{patsubst %,-aO%,$@{OBJECT_DIRS@}@}

all:
        gnatmake $@{GNATMAKE_SWITCHES@} main_unit
@end smallexample

@node Overcoming Command Line Length Limits
@section Overcoming Command Line Length Limits

@noindent
One problem that might be encountered on big projects is that many
operating systems limit the length of the command line. It is thus hard to give
gnatmake the list of source and object directories.

This example shows how you can set up environment variables, which will
make @code{gnatmake} behave exactly as if the directories had been
specified on the command line, but have a much higher length limit (or
even none on most systems).

It assumes that you have created a list of directories in your Makefile,
using one of the methods presented in
@ref{Automatically Creating a List of Directories}.
For the sake of completeness, we assume that the object
path (where the ALI files are found) is different from the sources patch.

Note a small trick in the Makefile below: for efficiency reasons, we
create two temporary variables (SOURCE_LIST and OBJECT_LIST), that are
expanded immediately by @code{make}. This way we overcome the standard
make behavior which is to expand the variables only when they are
actually used.

@smallexample
@iftex
@leftskip=0cm
@font@heightrm=cmr8
@heightrm
@end iftex
# In this example, we create both ADA_INCLUDE_PATH and ADA_OBJECT_PATH.
# This is the same thing as putting the -I arguments on the command line.
# (the equivalent of using -aI on the command line would be to define
#  only ADA_INCLUDE_PATH, the equivalent of -aO is ADA_OBJECT_PATH).
# You can of course have different values for these variables.
#
# Note also that we need to keep the previous values of these variables, since
# they might have been set before running 'make' to specify where the GNAT
# library is installed.

# see "Automatically creating a list of directories" to create these
# variables
SOURCE_DIRS=
OBJECT_DIRS=

empty:=
space:=$@{empty@} $@{empty@}
SOURCE_LIST := $@{subst $@{space@},:,$@{SOURCE_DIRS@}@}
OBJECT_LIST := $@{subst $@{space@},:,$@{OBJECT_DIRS@}@}
ADA_INCLUDE_PATH += $@{SOURCE_LIST@}
ADA_OBJECT_PATH += $@{OBJECT_LIST@}
export ADA_INCLUDE_PATH
export ADA_OBJECT_PATH

all:
        gnatmake main_unit
@end smallexample

@ifclear vxworks
@node Finding Memory Problems with gnatmem
@chapter Finding Memory Problems with @code{gnatmem}
@findex gnatmem

@noindent
@code{gnatmem}, is a tool that monitors dynamic allocation and
deallocation activity in a program, and displays information about
incorrect deallocations and possible sources of memory leaks. Gnatmem
provides three type of information:
@itemize @bullet
@item
General information concerning memory management, such as the total
number of allocations and deallocations, the amount of allocated
memory and the high water mark, i.e. the largest amount of allocated
memory in the course of program execution.

@item
Backtraces for all incorrect deallocations, that is to say deallocations
which do not correspond to a valid allocation.

@item
Information on each allocation that is potentially the origin of a memory
leak.
@end itemize

The @code{gnatmem} command has two modes. It can be used with @code{gdb}
or with instrumented allocation and deallocation routines. The later
mode is called the @code{GMEM} mode. Both modes produce the very same
output.

@menu
* Running gnatmem (GDB Mode)::
* Running gnatmem (GMEM Mode)::
* Switches for gnatmem::
* Examples of gnatmem Usage::
* GDB and GMEM Modes::
* Implementation Note::
@end menu

@node Running gnatmem (GDB Mode)
@section Running @code{gnatmem} (GDB Mode)

@noindent
The @code{gnatmem} command has the form

@smallexample
   $ gnatmem [-q] [n] [-o file] user_program [program_arg]*
or
   $ gnatmem [-q] [n] -i file
@end smallexample

@noindent
Gnatmem must be supplied with the executable to examine, followed by its
run-time inputs. For example, if a program is executed with the command:
@smallexample
$ my_program arg1 arg2
@end smallexample
then it can be run under @code{gnatmem} control using the command:
@smallexample
$ gnatmem my_program arg1 arg2
@end smallexample

The program is transparently executed under the control of the debugger
@ref{The GNAT Debugger GDB}. This does not affect the behavior
of the program, except for sensitive real-time programs. When the program
has completed execution, @code{gnatmem} outputs a report containing general
allocation/deallocation information and potential memory leak.
For better results, the user program should be compiled with
debugging options @ref{Switches for gcc}.

Here is a simple example of use:

*************** debut cc
@smallexample
$ gnatmem test_gm

Global information
------------------
   Total number of allocations        :  45
   Total number of deallocations      :   6
   Final Water Mark (non freed mem)   :  11.29 Kilobytes
   High Water Mark                    :  11.40 Kilobytes

.
.
.
Allocation Root # 2
-------------------
 Number of non freed allocations    :  11
 Final Water Mark (non freed mem)   :   1.16 Kilobytes
 High Water Mark                    :   1.27 Kilobytes
 Backtrace                          :
   test_gm.adb:23 test_gm.alloc
.
.
.
@end smallexample

The first block of output give general information. In this case, the
Ada construct "@b{new}" was executed 45 times, and only 6 calls to an
unchecked deallocation routine occurred.

Subsequent paragraphs display  information on all allocation roots.
An allocation root is a specific point in the execution of the program
that generates some dynamic allocation, such as a "@b{new}" construct. This
root is represented by an execution backtrace (or subprogram call
stack). By default the backtrace depth for allocations roots is 1, so
that a root corresponds exactly to a source location. The backtrace can
be made deeper, to make the root more specific.

@node Running gnatmem (GMEM Mode)
@section Running @code{gnatmem} (GMEM Mode)
@cindex @code{GMEM} (@code{gnatmem})

@noindent
The @code{gnatmem} command has the form

@smallexample
   $ gnatmem [-q] [n] -i gmem.out user_program [program_arg]*
@end smallexample

The program must have been linked with the instrumented version of the
allocation and deallocation routines. This is done with linking with the
@file{libgmem.a} library. For better results, the user program should be
compiled with debugging options @ref{Switches for gcc}. For example to
build @file{my_program}:

@smallexample
$ gnatmake -g my_program -largs -lgmem
@end smallexample

@noindent
When running @file{my_program} the file @file{gmem.out} is produced. This file
contains information about all allocations and deallocations done by the
program. It is produced by the instrumented allocations and
deallocations routines and will be used by @code{gnatmem}.

@noindent
Gnatmem must be supplied with the @file{gmem.out} file and the executable to
examine followed by its run-time inputs. For example, if a program is
executed with the command:
@smallexample
$ my_program arg1 arg2
@end smallexample
then @file{gmem.out} can be analysed by @code{gnatmem} using the command:
@smallexample
$ gnatmem -i gmem.out my_program arg1 arg2
@end smallexample

@node Switches for gnatmem
@section Switches for @code{gnatmem}

@noindent
@code{gnatmem} recognizes the following switches:

@table @code

@item @code{-q}
@cindex @code{-q} (@code{gnatmem})
Quiet. Gives the minimum output needed to identify the origin of the
memory leaks. Omit statistical information.

@item @code{n}
@cindex @code{n} (@code{gnatmem})
N is an integer literal (usually between 1 and 10) which controls the
depth of the backtraces defining allocation root. The default value for
N is 1. The deeper the backtrace, the more precise the localization of
the root. Note that the total number of roots can depend on this
parameter.

@item @code{-o file}
@cindex @code{-o} (@code{gnatmem})
Direct the gdb output to the specified file. The @code{gdb} script used
to generate this output is also saved in the file @file{gnatmem.tmp}.

@item @code{-i file}
@cindex @code{-i} (@code{gnatmem})
Do the @code{gnatmem} processing starting from @file{file} which has
been generated by a previous call to @code{gnatmem} with the -o
switch or @file{gmem.out} produced by @code{GMEM} mode. This is useful
for post mortem processing.

@end table

@node Examples of gnatmem Usage
@section Example of @code{gnatmem} Usage

@noindent
This section is based on the @code{GDB} mode of @code{gnatmem}. The same
results can be achieved using @code{GMEM} mode. See section
@ref{Running gnatmem (GMEM Mode)}.

@noindent
The first example shows the use of @code{gnatmem}
on a simple leaking program.
Suppose that we have the following Ada program:

@smallexample
@group
@cartouche
@b{with} Unchecked_Deallocation;
@b{procedure} Test_Gm @b{is}

   @b{type} T @b{is array} (1..1000) @b{of} Integer;
   @b{type} Ptr @b{is access} T;
   @b{procedure} Free @b{is new} Unchecked_Deallocation (T, Ptr);
   A : Ptr;

   @b{procedure} My_Alloc @b{is}
   @b{begin}
      A := @b{new} T;
   @b{end} My_Alloc;

   @b{procedure} My_DeAlloc @b{is}
      B : Ptr := A;
   @b{begin}
      Free (B);
   @b{end} My_DeAlloc;

@b{begin}
   My_Alloc;
   @b{for} I @b{in} 1 .. 5 @b{loop}
      @b{for} J @b{in} I .. 5 @b{loop}
         My_Alloc;
      @b{end loop};
      My_Dealloc;
   @b{end loop};
@b{end};
@end cartouche
@end group
@end smallexample

@noindent
The program needs to be compiled with debugging option:

@smallexample
$ gnatmake -g test_gm
@end smallexample

@code{gnatmem} is invoked simply with
@smallexample
$ gnatmem test_gm
@end smallexample

@noindent
which produces the following output:

@smallexample
Global information
------------------
   Total number of allocations        :  18
   Total number of deallocations      :   5
   Final Water Mark (non freed mem)   :  53.00 Kilobytes
   High Water Mark                    :  56.90 Kilobytes

Allocation Root # 1
-------------------
 Number of non freed allocations    :  11
 Final Water Mark (non freed mem)   :  42.97 Kilobytes
 High Water Mark                    :  46.88 Kilobytes
 Backtrace                          :
   test_gm.adb:11 test_gm.my_alloc

Allocation Root # 2
-------------------
 Number of non freed allocations    :   1
 Final Water Mark (non freed mem)   :  10.02 Kilobytes
 High Water Mark                    :  10.02 Kilobytes
 Backtrace                          :
   s-secsta.adb:81 system.secondary_stack.ss_init

Allocation Root # 3
-------------------
 Number of non freed allocations    :   1
 Final Water Mark (non freed mem)   :  12 Bytes
 High Water Mark                    :  12 Bytes
 Backtrace                          :
   s-secsta.adb:181 system.secondary_stack.ss_init
@end smallexample

@noindent
Note that the GNAT run time contains itself a certain number of
allocations that have no  corresponding deallocation,
as shown here for root #2 and root
#1. This is a normal behavior when the number of non freed allocations
is one, it locates dynamic data structures that the run time needs for
the complete lifetime of the program. Note also that there is only one
allocation root in the user program with a single line back trace:
test_gm.adb:11 test_gm.my_alloc, whereas a careful analysis of the
program shows that 'My_Alloc' is called at 2 different points in the
source (line 21 and line 24). If those two allocation roots need to be
distinguished, the backtrace depth parameter can be used:

@smallexample
$ gnatmem 3 test_gm
@end smallexample

@noindent
which will give the following output:

@smallexample
Global information
------------------
   Total number of allocations        :  18
   Total number of deallocations      :   5
   Final Water Mark (non freed mem)   :  53.00 Kilobytes
   High Water Mark                    :  56.90 Kilobytes

Allocation Root # 1
-------------------
 Number of non freed allocations    :  10
 Final Water Mark (non freed mem)   :  39.06 Kilobytes
 High Water Mark                    :  42.97 Kilobytes
 Backtrace                          :
   test_gm.adb:11 test_gm.my_alloc
   test_gm.adb:24 test_gm
   b_test_gm.c:52 main

Allocation Root # 2
-------------------
 Number of non freed allocations    :   1
 Final Water Mark (non freed mem)   :  10.02 Kilobytes
 High Water Mark                    :  10.02 Kilobytes
 Backtrace                          :
   s-secsta.adb:81  system.secondary_stack.ss_init
   s-secsta.adb:283 <system__secondary_stack___elabb>
   b_test_gm.c:33   adainit

Allocation Root # 3
-------------------
 Number of non freed allocations    :   1
 Final Water Mark (non freed mem)   :   3.91 Kilobytes
 High Water Mark                    :   3.91 Kilobytes
 Backtrace                          :
   test_gm.adb:11 test_gm.my_alloc
   test_gm.adb:21 test_gm
   b_test_gm.c:52 main

Allocation Root # 4
-------------------
 Number of non freed allocations    :   1
 Final Water Mark (non freed mem)   :  12 Bytes
 High Water Mark                    :  12 Bytes
 Backtrace                          :
   s-secsta.adb:181 system.secondary_stack.ss_init
   s-secsta.adb:283 <system__secondary_stack___elabb>
   b_test_gm.c:33   adainit
@end smallexample

@noindent
The allocation root #1 of the first example has been split in 2 roots #1
and #3 thanks to the more precise associated backtrace.

@node GDB and GMEM Modes
@section GDB and GMEM Modes

@noindent
The main advantage of the @code{GMEM} mode is that it is a lot faster than the
@code{GDB} mode where the application must be monitored by a @code{GDB} script.
But the @code{GMEM} mode is available only for DEC Unix, Linux x86,
Solaris (sparc and x86) and Windows 95/98/NT/2000 (x86).

@noindent
The main advantage of the @code{GDB} mode is that it is available on all
supported platforms. But it can be very slow if the application does a
lot of allocations and deallocations.

@node Implementation Note
@section Implementation Note

@menu
* gnatmem Using GDB Mode::
* gnatmem Using GMEM Mode::
@end menu

@node gnatmem Using GDB Mode
@subsection @code{gnatmem} Using @code{GDB} Mode

@noindent
@code{gnatmem} executes the user program under the control of @code{GDB} using
a script that sets breakpoints and gathers information on each dynamic
allocation and deallocation. The output of the script is then analyzed
by @code{gnatmem}
in order to locate memory leaks and their origin in the
program. Gnatmem works by recording each address returned by the
allocation procedure (@code{__gnat_malloc})
along with the backtrace at the
allocation point. On each deallocation, the deallocated address is
matched with the corresponding allocation. At the end of the processing,
the unmatched allocations are considered potential leaks. All the
allocations associated with the same backtrace are grouped together and
form an allocation root. The allocation roots are then sorted so that
those with the biggest number of unmatched allocation are printed
first. A delicate aspect of this technique is to distinguish between the
data produced by the user program and the data produced by the gdb
script. Currently, on systems that allow probing the terminal, the gdb
command "tty" is used to force the program output to be redirected to the
current terminal while the @code{gdb} output is directed to a file or to a
pipe in order to be processed subsequently by @code{gnatmem}.

@node gnatmem Using GMEM Mode
@subsection @code{gnatmem} Using @code{GMEM} Mode

@noindent
This mode use the same algorithm to detect memory leak as the @code{GDB}
mode of @code{gnatmem}, the only difference is in the way data are
gathered. In @code{GMEM} mode the program is linked with instrumented
version of @code{__gnat_malloc} and @code{__gnat_free}
routines. Information needed to find memory leak are recorded by these
routines in file @file{gmem.out}. This mode also require that the stack
traceback be available, this is only implemented on some platforms
@ref{GDB and GMEM Modes}.

@end ifclear
@end ifclear

@node Finding Memory Problems with GNAT Debug Pool
@chapter Finding Memory Problems with GNAT Debug Pool
@findex Debug Pool
@cindex storage, pool, memory corruption

@noindent
The use of unchecked deallocation and unchecked conversion can easily
lead to incorrect memory references. The problems generated by such
references are usually difficult to tackle because the symptoms can be
very remote from the origin of the problem. In such cases, it is
very helpful to detect the problem as early as possible. This is the
purpose of the Storage Pool provided by @code{GNAT.Debug_Pools}.

@noindent
In order to use the GNAT specific debugging pool, the user must
associate a debug pool object with each of the access types that may be
related to suspected memory problems. See Ada Reference Manual
13.11.
@smallexample
@b{type} Ptr @b{is} @b{access} Some_Type;
Pool : GNAT.Debug_Pools.Debug_Pool;
@b{for} Ptr'Storage_Pool @b{use} Pool;
@end smallexample

@code{GNAT.Debug_Pools} is derived from of a GNAT-specific kind of
pool: the Checked_Pool. Such pools, like standard Ada storage pools,
allow the user to redefine allocation and deallocation strategies. They
also provide a checkpoint for each dereference, through the use of
the primitive operation @code{Dereference} which is implicitly called at
each dereference of an access value.

Once an access type has been associated with a debug pool, operations on
values of the type may raise four distinct exceptions,
which correspond to four potential kinds of memory corruption:
@itemize @bullet
@item
@code{GNAT.Debug_Pools.Accessing_Not_Allocated_Storage}
@item
@code{GNAT.Debug_Pools.Accessing_Deallocated_Storage}
@item
@code{GNAT.Debug_Pools.Freeing_Not_Allocated_Storage}
@item
@code{GNAT.Debug_Pools.Freeing_Deallocated_Storage }
@end itemize

@noindent
For types associated with a Debug_Pool, dynamic allocation is performed using
the standard
GNAT allocation routine. References to all allocated chunks of memory
are kept in an internal dictionary. The deallocation strategy consists
in not releasing the memory to the underlying system but rather to fill
it with a memory pattern easily recognizable during debugging sessions:
The memory pattern is the old IBM hexadecimal convention: 16#DEADBEEF#.
Upon each dereference, a check is made that the access value denotes a properly
allocated memory location. Here is a complete example of use of
@code{Debug_Pools}, that includes typical instances of  memory corruption:
@smallexample
@iftex
@leftskip=0cm
@end iftex
@b{with} Gnat.Io; @b{use} Gnat.Io;
@b{with} Unchecked_Deallocation;
@b{with} Unchecked_Conversion;
@b{with} GNAT.Debug_Pools;
@b{with} System.Storage_Elements;
@b{with} Ada.Exceptions; @b{use} Ada.Exceptions;
@b{procedure} Debug_Pool_Test @b{is}

   @b{type} T @b{is} @b{access} Integer;
   @b{type} U @b{is} @b{access} @b{all} T;

   P : GNAT.Debug_Pools.Debug_Pool;
   @b{for} T'Storage_Pool @b{use} P;

   @b{procedure} Free @b{is} @b{new} Unchecked_Deallocation (Integer, T);
   @b{function} UC @b{is} @b{new} Unchecked_Conversion (U, T);
   A, B : @b{aliased} T;

   @b{procedure} Info @b{is} @b{new} GNAT.Debug_Pools.Print_Info(Put_Line);

@b{begin}
   Info (P);
   A := @b{new} Integer;
   B := @b{new} Integer;
   B := A;
   Info (P);
   Free (A);
   @b{begin}
      Put_Line (Integer'Image(B.@b{all}));
   @b{exception}
      @b{when} E : @b{others} => Put_Line ("raised: " & Exception_Name (E));
   @b{end};
   @b{begin}
      Free (B);
   @b{exception}
      @b{when} E : @b{others} => Put_Line ("raised: " & Exception_Name (E));
   @b{end};
   B := UC(A'Access);
   @b{begin}
      Put_Line (Integer'Image(B.@b{all}));
   @b{exception}
      @b{when} E : @b{others} => Put_Line ("raised: " & Exception_Name (E));
   @b{end};
   @b{begin}
      Free (B);
   @b{exception}
      @b{when} E : @b{others} => Put_Line ("raised: " & Exception_Name (E));
   @b{end};
   Info (P);
@b{end} Debug_Pool_Test;
@end smallexample
@noindent
The debug pool mechanism provides the following precise diagnostics on the
execution of this erroneous program:
@smallexample
Debug Pool info:
  Total allocated bytes :  0
  Total deallocated bytes :  0
  Current Water Mark:  0
  High Water Mark:  0

Debug Pool info:
  Total allocated bytes :  8
  Total deallocated bytes :  0
  Current Water Mark:  8
  High Water Mark:  8

raised: GNAT.DEBUG_POOLS.ACCESSING_DEALLOCATED_STORAGE
raised: GNAT.DEBUG_POOLS.FREEING_DEALLOCATED_STORAGE
raised: GNAT.DEBUG_POOLS.ACCESSING_NOT_ALLOCATED_STORAGE
raised: GNAT.DEBUG_POOLS.FREEING_NOT_ALLOCATED_STORAGE
Debug Pool info:
  Total allocated bytes :  8
  Total deallocated bytes :  4
  Current Water Mark:  4
  High Water Mark:  8

@end smallexample

@node Creating Sample Bodies Using gnatstub
@chapter Creating Sample Bodies Using @code{gnatstub}
@findex gnatstub

@noindent
@code{gnatstub} creates body stubs, that is, empty but compilable bodies
for library unit declarations.

To create a body stub, @code{gnatstub} has to compile the library
unit declaration. Therefore, bodies can be created only for legal
library units. Moreover, if a library unit depends semantically upon
units located outside the current directory, you have to provide
the source search path when calling @code{gnatstub}, see the description
of @code{gnatstub} switches below.

@menu
* Running gnatstub::
* Switches for gnatstub::
@end menu

@node Running gnatstub
@section Running @code{gnatstub}

@noindent
@code{gnatstub} has the command-line interface of the form

@smallexample
$ gnatstub [switches] filename [directory]
@end smallexample

@noindent
where
@table @code
@item filename
is the name of the source file that contains a library unit declaration
for which a body must be created. This name should follow the GNAT file name
conventions. No crunching is allowed for this file name. The file
name may contain the path information.

@item directory
indicates the directory to place a body stub (default is the
current directory)

@item switches
is an optional sequence of switches as described in the next section
@end table

@node Switches for gnatstub
@section Switches for @code{gnatstub}

@table @code

@item ^-f^/FULL^
If the destination directory already contains a file with a name of the body file
for the argument spec file, replace it with the generated body stub.

@item ^-hs^/HEADER=SPEC^
Put the comment header (i.e. all the comments preceding the
compilation unit) from the source of the library unit declaration
into the body stub.

@item ^-hg^/HEADER=GENERAL^
Put a sample comment header into the body stub.

@item -IDIR
@itemx ^-I-^/NOCURRENT_DIRECTORY^
These switches have the same meaning as in calls to gcc.
They define the source search path in the call to gcc issued
by @code{gnatstub} to compile an argument source file.

@item ^-i^/INDENTATION=^@var{n}
(@var{n} is a decimal natural number). Set the indentation level in the
generated body sample to n, '^-i0^/INDENTATION=0^' means "no indentation",
the default indentation is 3.

@item ^-k^/TREE_FILE=SAVE^
Do not remove the tree file (i.e. the snapshot of the compiler internal
structures used by @code{gnatstub}) after creating the body stub.

@item ^-l^/LINE_LENGTH=^@var{n}
(@var{n} is a decimal positive number) Set the maximum line length in the
body stub to n, the default is 78.

@item ^-q^/QUIET^
Quiet mode: do not generate a confirmation when a body is
successfully created or a message when a body is not required for an
argument unit.

@item ^-r^/TREE_FILE=REUSE^
Reuse the tree file (if it exists) instead of creating it: instead of
creating the tree file for the library unit declaration, gnatstub
tries to find it in the current directory and use it for creating
a body. If the tree file is not found, no body is created. @code{^-r^/REUSE^}
also implies @code{^-k^/SAVE^}, whether or not
@code{^-k^/SAVE^} is set explicitly.

@item ^-t^/TREE_FILE=OVERWRITE^
Overwrite the existing tree file: if the current directory already
contains the file which, according to the GNAT file name rules should
be considered as a tree file for the argument source file, gnatstub
will refuse to create the tree file needed to create a body sampler,
unless @code{-t} option is set

@item ^-v^/VERBOSE^
Verbose mode: generate version information.

@end table

@node Reducing the Size of Ada Executables with gnatelim
@chapter Reducing the Size of Ada Executables with @code{gnatelim}
@findex gnatelim

@menu
* About gnatelim::
* Eliminate Pragma::
* Tree Files::
* Preparing Tree and Bind Files for gnatelim::
* Running gnatelim::
* Correcting the List of Eliminate Pragmas::
* Making Your Executables Smaller::
* Summary of the gnatelim Usage Cycle::
@end menu

@node About gnatelim
@section About @code{gnatelim}

@noindent
When a program shares a set of Ada
packages with other programs, it may happen that this program uses
only a fraction of the subprograms defined in these packages. The code
created for these unused subprograms increases the size of the executable.

@code{gnatelim} tracks unused subprograms in an Ada program and
outputs a list of GNAT-specific @code{Eliminate} pragmas (see next
section) marking all the subprograms that are declared but never called.
By placing the list of @code{Eliminate} pragmas in the GNAT configuration
file @file{gnat.adc} and recompiling your program, you may decrease the
size of its executable, because the compiler will not generate the code
for 'eliminated' subprograms.

@code{gnatelim} needs as its input data a set of tree files
(see @ref{Tree Files}) representing all the components of a program to
process and a bind file for a main subprogram (see
@ref{Preparing Tree and Bind Files for gnatelim}).

@node Eliminate Pragma
@section @code{Eliminate} Pragma
@findex Eliminate

@noindent
The simplified syntax of the Eliminate pragma used by @code{gnatelim} is:

@smallexample
@cartouche
@b{pragma} Eliminate (Library_Unit_Name, Subprogram_Name);
@end cartouche
@end smallexample

@noindent
where
@table @code
@item Library_Unit_Name
full expanded Ada name of a library unit

@item Subprogram_Name
a simple or expanded name of a subprogram declared within this
compilation unit

@end table

@noindent
The effect of an @code{Eliminate} pragma placed in the GNAT configuration
file @file{gnat.adc} is:

@itemize @bullet

@item
If the subprogram @code{Subprogram_Name} is declared within
the library unit @code{Library_Unit_Name}, the compiler will not generate
code for this subprogram. This applies to all overloaded subprograms denoted
by @code{Subprogram_Name}.

@item
If a subprogram marked by the pragma @code{Eliminate} is used (called)
in a program, the compiler will produce an error message in the place where
it is called.
@end itemize

@node Tree Files
@section Tree Files
@cindex Tree file

@noindent
A tree file stores a snapshot of the compiler internal data
structures at the very end of a successful compilation. It contains all the
syntactic and semantic information for the compiled unit and all the
units upon which it depends semantically.
To use tools that make use of tree files, you
need to first produce the right set of tree files.

GNAT produces correct tree files when -gnatt -gnatc options are set
in a gcc call. The tree files have an .adt extension.
Therefore, to produce a tree file for the compilation unit contained in a file
named @file{foo.adb}, you must use the command

@smallexample
$ gcc -c -gnatc -gnatt foo.adb
@end smallexample

@noindent
and you will get the tree file @file{foo.adt}.
compilation.

@node Preparing Tree and Bind Files for gnatelim
@section Preparing Tree and Bind Files for @code{gnatelim}

@noindent
A set of tree files covering the program to be analyzed with
@code{gnatelim} and
the bind file for the main subprogram does not have to
be in the current directory.
'-T' gnatelim option may be used to provide
the search path for tree files, and '-b'
option may be used to point to the bind
file to process (see @ref{Running gnatelim})

If you do not have the appropriate set of tree
files and the right bind file, you
may create them in the current directory using the following procedure.

Let @code{Main_Prog} be the name of a main subprogram, and suppose
this subprogram is in a file named @file{main_prog.adb}.

To create a bind file for @code{gnatelim}, run @code{gnatbind} for
the main subprogram. @code{gnatelim} can work with both Ada and C
bind files; when both are present, it uses the Ada bind file.
The following commands will build the program and create the bind file:

@smallexample
$ gnatmake ^-c Main_Prog^/ACTIONS=COMPILE MAIN_PROG^
$ gnatbind main_prog
@end smallexample

@noindent
To create a minimal set of tree files covering the whole program, call
@code{gnatmake} for this program as follows:

@smallexample
@ifset vms
$ GNAT MAKE /FORCE_COMPILE /ACTIONS=COMPILE /NOLOAD /TREE_OUTPUT MAIN_PROG
@end ifset
@ifclear vms
$ gnatmake -f -c -gnatc -gnatt Main_Prog
@end ifclear
@end smallexample

@noindent
The @code{^-c^/ACTIONS=COMPILE^} gnatmake option turns off the bind and link
steps, that are useless anyway because the sources are compiled with
@option{-gnatc} option which turns off code generation.

The @code{^-f^/FORCE_COMPILE^} gnatmake option forces
recompilation of all the needed sources.

This sequence of actions will create all the data needed by @code{gnatelim}
from scratch and therefore guarantee its consistency. If you would like to
use some existing set of files as @code{gnatelim} output, you must make
sure that the set of files is complete and consistent. You can use the
@code{-m} switch to check if there are missed tree files

Note, that @code{gnatelim} needs neither object nor ALI files.

@node Running gnatelim
@section Running @code{gnatelim}

@noindent
@code{gnatelim} has the following command-line interface:

@smallexample
$ gnatelim [options] name
@end smallexample

@noindent
@code{name} should be a full expanded Ada name of a main subprogram
of a program (partition).

@code{gnatelim} options:

@table @code
@item ^-q^/QUIET^
Quiet mode: by default @code{gnatelim} generates to the standard error
stream a trace of the source file names of the compilation units being
processed. This option turns this trace off.

@item ^-v^/VERBOSE^
Verbose mode: @code{gnatelim} version information is printed as Ada
comments to the standard output stream.

@item ^-a^/ALL^
Also look for subprograms from the GNAT run time that can be eliminated.

@item ^-m^/MISSED^
Check if any tree files are missing for an accurate result.

@item ^-T^/TREE_DIRS=^@var{dir}
When looking for tree files also look in directory @var{dir}

@item ^-b^/BIND_FILE=^@var{bind_file}
Specifies @var{bind_file} as the bind file to process. If not set, the name
of the bind file is computed from the full expanded Ada name of a main subprogram.

@item -d@var{x}
Activate internal debugging switches. @var{x} is a letter or digit, or
string of letters or digits, which specifies the type of debugging
mode desired.  Normally these are used only for internal development
or system debugging purposes. You can find full documentation for these
switches in the body of the @code{Gnatelim.Options} unit in the compiler
source file @file{gnatelim-options.adb}.
@end table

@noindent
@code{gnatelim} sends its output to the standard output stream, and all the
tracing and debug information is sent to the standard error stream.
In order to produce a proper GNAT configuration file
@file{gnat.adc}, redirection must be used:

@smallexample
@ifset vms
$ PIPE GNAT ELIM MAIN_PROG > GNAT.ADC
@end ifset
@ifclear vms
$ gnatelim Main_Prog > gnat.adc
@end ifclear
@end smallexample

@ifclear vms
@noindent
or

@smallexample
$ gnatelim Main_Prog >> gnat.adc
@end smallexample
@end ifclear

@noindent
In order to append the @code{gnatelim} output to the existing contents of
@file{gnat.adc}.

@node Correcting the List of Eliminate Pragmas
@section Correcting the List of Eliminate Pragmas

@noindent
In some rare cases it may happen that @code{gnatelim} will try to eliminate
subprograms which are actually called in the program. In this case, the
compiler will generate an error message of the form:

@smallexample
file.adb:106:07: cannot call eliminated subprogram "My_Prog"
@end smallexample

@noindent
You will need to manually remove the wrong @code{Eliminate} pragmas from
the @file{gnat.adc} file. It is advised that you recompile your program
from scratch after that because you need a consistent @file{gnat.adc} file
during the entire compilation.

@node Making Your Executables Smaller
@section Making Your Executables Smaller

@noindent
In order to get a smaller executable for your program you now have to
recompile the program completely with the new @file{gnat.adc} file
created by @code{gnatelim} in your current directory:

@smallexample
$ gnatmake ^-f Main_Prog^/FORCE_COMPILE MAIN_PROG^
@end smallexample

@noindent
(you will need @code{^-f^/FORCE_COMPILE^} option for gnatmake to
recompile everything
with the set of pragmas @code{Eliminate} you have obtained with
@code{gnatelim}).

Be aware that the set of @code{Eliminate} pragmas is specific to each
program. It is not recommended to merge sets of @code{Eliminate}
pragmas created for different programs in one @file{gnat.adc} file.

@node Summary of the gnatelim Usage Cycle
@section Summary of the gnatelim Usage Cycle

@noindent
Here is a quick summary of the steps to be taken in order to reduce
the size of your executables with @code{gnatelim}. You may use
other GNAT options to control the optimization level,
to produce the debugging information, to set search path, etc.

@enumerate
@item
Produce a bind file and a set of tree files

@smallexample
$ gnatmake ^-c Main_Prog^/ACTIONS=COMPILE MAIN_PROG^
$ gnatbind main_prog
@ifset vms
$ GNAT MAKE /FORCE_COMPILE /NO_LINK /NOLOAD /TREE_OUTPUT MAIN_PROG
@end ifset
@ifclear vms
$ gnatmake -f -c -gnatc -gnatt Main_Prog
@end ifclear
@end smallexample

@item
Generate a list of @code{Eliminate} pragmas
@smallexample
@ifset vms
$ PIPE GNAT ELIM MAIN_PROG > GNAT.ADC
@end ifset
@ifclear vms
$ gnatelim Main_Prog >[>] gnat.adc
@end ifclear
@end smallexample

@item
Recompile the application

@smallexample
$ gnatmake ^-f Main_Prog^/FORCE_COMPILE MAIN_PROG^
@end smallexample

@end enumerate

@node Other Utility Programs
@chapter Other Utility Programs

@noindent
This chapter discusses some other utility programs available in the Ada
environment.

@menu
* Using Other Utility Programs with GNAT::
* The gnatpsta Utility Program::
* The External Symbol Naming Scheme of GNAT::
* Ada Mode for Glide::
* Converting Ada Files to html with gnathtml::
* Installing gnathtml::
@ifset vms
* LSE::
* Profiling::
@end ifset
@end menu

@node Using Other Utility Programs with GNAT
@section Using Other Utility Programs with GNAT

@noindent
The object files generated by GNAT are in standard system format and in
particular the debugging information uses this format. This means
programs generated by GNAT can be used with existing utilities that
depend on these formats.

@ifclear vms
In general, any utility program that works with C will also often work with
Ada programs generated by GNAT. This includes software utilities such as
gprof (a profiling program), @code{gdb} (the FSF debugger), and utilities such
as Purify.
@end ifclear

@node The gnatpsta Utility Program
@section The @code{gnatpsta} Utility Program

@noindent
Many of the definitions in package Standard are implementation-dependent.
However, the source of this package does not exist as an Ada source
file, so these values cannot be determined by inspecting the source.
They can be determined by examining in detail the coding of
@file{cstand.adb} which creates the image of Standard in the compiler,
but this is awkward and requires a great deal of internal knowledge
about the system.

The @code{gnatpsta} utility is designed to deal with this situation.
It is an Ada program that dynamically determines the
values of all the relevant parameters in Standard, and prints them
out in the form of an Ada source listing for Standard, displaying all
the values of interest. This output is generated to
@file{stdout}.

To determine the value of any parameter in package Standard, simply
run @code{gnatpsta} with no qualifiers or arguments, and examine
the output. This is preferable to consulting documentation, because
you know that the values you are getting are the actual ones provided
by the executing system.

@node The External Symbol Naming Scheme of GNAT
@section The External Symbol Naming Scheme of GNAT

@noindent
In order to interpret the output from GNAT, when using tools that are
originally intended for use with other languages, it is useful to
understand the conventions used to generate link names from the Ada
entity names.

All link names are in all lowercase letters. With the exception of library
procedure names, the mechanism used is simply to use the full expanded
Ada name with dots replaced by double underscores. For example, suppose
we have the following package spec:

@smallexample
@group
@cartouche
@b{package} QRS @b{is}
   MN : Integer;
@b{end} QRS;
@end cartouche
@end group
@end smallexample

@noindent
The variable @code{MN} has a full expanded Ada name of @code{QRS.MN}, so
the corresponding link name is @code{qrs__mn}.
@findex Export
Of course if a @code{pragma Export} is used this may be overridden:

@smallexample
@group
@cartouche
@b{package} Exports @b{is}
   Var1 : Integer;
   @b{pragma} Export (Var1, C, External_Name => "var1_name");
   Var2 : Integer;
   @b{pragma} Export (Var2, C, Link_Name => "var2_link_name");
@b{end} Exports;
@end cartouche
@end group
@end smallexample

@noindent
In this case, the link name for @var{Var1} is whatever link name the
C compiler would assign for the C function @var{var1_name}. This typically
would be either @var{var1_name} or @var{_var1_name}, depending on operating
system conventions, but other possibilities exist. The link name for
@var{Var2} is @var{var2_link_name}, and this is not operating system
dependent.

@findex _main
One exception occurs for library level procedures. A potential ambiguity
arises between the required name @code{_main} for the C main program,
and the name we would otherwise assign to an Ada library level procedure
called @code{Main} (which might well not be the main program).

To avoid this ambiguity, we attach the prefix @code{_ada_} to such
names. So if we have a library level procedure such as

@smallexample
@group
@cartouche
@b{procedure} Hello (S : String);
@end cartouche
@end group
@end smallexample

@noindent
the external name of this procedure will be @var{_ada_hello}.

@node Ada Mode for Glide
@section Ada Mode for @code{Glide}

@noindent
The Glide mode for programming in Ada (both, Ada83 and Ada95) helps the
user in understanding existing code and facilitates writing new code. It
furthermore provides some utility functions for easier integration of
standard Emacs features when programming in Ada.

@subsection General Features:

@itemize @bullet
@item
Full Integrated Development Environment :

@itemize @bullet
@item
support of 'project files' for the configuration (directories,
compilation options,...)

@item
compiling and stepping through error messages.

@item
running and debugging your applications within Glide.
@end itemize

@item
easy to use for beginners by pull-down menus,

@item
user configurable by many user-option variables.
@end itemize

@subsection Ada Mode Features That Help Understanding Code:

@itemize @bullet
@item
functions for easy and quick stepping through Ada code,

@item
getting cross reference information for identifiers (e.g. find the
defining place by a keystroke),

@item
displaying an index menu of types and subprograms and move point to
the chosen one,

@item
automatic color highlighting of the various entities in Ada code.
@end itemize

@subsection Glide Support for Writing Ada Code:

@itemize @bullet
@item
switching between spec and body files with possible
autogeneration of body files,

@item
automatic formating of subprograms parameter lists.

@item
automatic smart indentation according to Ada syntax,

@item
automatic completion of identifiers,

@item
automatic casing of identifiers, keywords, and attributes,

@item
insertion of statement templates,

@item
filling comment paragraphs like filling normal text,
@end itemize

For more information, please refer to the online Glide documentation
available in the Glide --> Help Menu.

@node Converting Ada Files to html with gnathtml
@section Converting Ada Files to html with @code{gnathtml}

@noindent
This @code{Perl} script allows Ada source files to be browsed using
standard Web browsers. For installation procedure, see the section
@xref{Installing gnathtml}.

Ada reserved keywords are highlighted in a bold font and Ada comments in
a blue font. Unless your program was compiled with the gcc @option{-gnatx}
switch to suppress the generation of cross-referencing information, user
defined variables and types will appear in a different color; you will
be able to click on any identifier and go to its declaration.

The command line is as follow:
@smallexample
$ perl gnathtml.pl [switches] ada-files
@end smallexample

You can pass it as many Ada files as you want. @code{gnathtml} will generate
an html file for every ada file, and a global file called @file{index.htm}.
This file is an index of every identifier defined in the files.

The available switches are the following ones :

@table @code
@item -83
@cindex @code{-83} (@code{gnathtml})
Only the subset on the Ada 83 keywords will be highlighted, not the full
Ada 95 keywords set.

@item -cc @var{color}
This option allows you to change the color used for comments. The default
value is green. The color argument can be any name accepted by html.

@item -d
@cindex @code{-d} (@code{gnathtml})
If the ada files depend on some other files (using for instance the
@code{with} command, the latter will also be converted to html.
Only the files in the user project will be converted to html, not the files
in the run-time library itself.

@item -D
This command is the same as -d above, but @code{gnathtml} will also look
for files in the run-time library, and generate html files for them.

@item -f
@cindex @code{-f} (@code{gnathtml})
By default, gnathtml will generate html links only for global entities
('with'ed units, global variables and types,...). If you specify the
@code{-f} on the command line, then links will be generated for local
entities too.

@item -l @var{number}
@cindex @code{-l} (@code{gnathtml})
If this switch is provided and @var{number} is not 0, then @code{gnathtml}
will number the html files every @var{number} line.

@item -I @var{dir}
@cindex @code{-I} (@code{gnathtml})
Specify a directory to search for library files (@file{.ali} files) and
source files. You can provide several -I switches on the command line,
and the directories will be parsed in the order of the command line.

@item -o @var{dir}
@cindex @code{-o} (@code{gnathtml})
Specify the output directory for html files. By default, gnathtml will
saved the generated html files in a subdirectory named @file{html/}.

@item -p @var{file}
@cindex @code{-p} (@code{gnathtml})
If you are using Emacs and the most recent Emacs Ada mode, which provides
a full Integrated Development Environment for compiling, checking,
running and debugging applications, you may be using @file{.adp} files
to give the directories where Emacs can find sources and object files.

Using this switch, you can tell gnathtml to use these files. This allows
you to get an html version of your application, even if it is spread
over multiple directories.

@item -sc @var{color}
@cindex @code{-sc} (@code{gnathtml})
This option allows you to change the color used for symbol definitions.
The default value is red. The color argument can be any name accepted by html.

@item -t @var{file}
@cindex @code{-t} (@code{gnathtml})
This switch provides the name of a file. This file contains a list of
file names to be converted, and the effect is exactly as though they had
appeared explicitly on the command line. This
is the recommended way to work around the command line length limit on some
systems.

@end table

@node Installing gnathtml
@section Installing @code{gnathtml}

@noindent
@code{Perl} needs to be installed on your machine to run this script.
@code{Perl} is freely available for almost every architecture and
Operating System via the Internet.

On Unix systems, you  may want to modify  the  first line of  the script
@code{gnathtml},  to explicitly  tell  the Operating  system  where Perl
is. The syntax of this line is :
@smallexample
#!full_path_name_to_perl
@end smallexample

@noindent
Alternatively, you may run the script using the following command line:

@smallexample
$ perl gnathtml.pl [switches] files
@end smallexample

@ifset vms
@node LSE
@section LSE
@findex LSE

@noindent
The GNAT distribution provides an Ada 95 template for the Digital Language
Sensitive Editor (LSE), a component of DECset. In order to
access it, invoke LSE with the qualifier /ENVIRONMENT=GNU:[LIB]ADA95.ENV.

@node Profiling
@section Profiling
@findex PCA

@noindent
GNAT supports The Digital Performance Coverage Analyzer (PCA), a component
of DECset. To use it proceed as outlined under "HELP PCA", except for running
the collection phase with the /DEBUG qualifier.

@smallexample
$ GNAT MAKE /DEBUG <PROGRAM_NAME>
$ DEFINE LIB$DEBUG PCA$COLLECTOR
$ RUN/DEBUG <PROGRAM_NAME>
@end smallexample
@noindent
@end ifset

@node Running and Debugging Ada Programs
@chapter Running and Debugging Ada Programs
@cindex Debugging

@noindent
This chapter discusses how to debug Ada programs. An incorrect Ada program
may be handled in three ways by the GNAT compiler:

@enumerate
@item
The illegality may be a violation of the static semantics of Ada. In
that case GNAT diagnoses the constructs in the program that are illegal.
It is then a straightforward matter for the user to modify those parts of
the program.

@item
The illegality may be a violation of the dynamic semantics of Ada. In
that case the program compiles and executes, but may generate incorrect
results, or may terminate abnormally with some exception.

@item
When presented with a program that contains convoluted errors, GNAT
itself may terminate abnormally without providing full diagnostics on
the incorrect user program.
@end enumerate

@menu
* The GNAT Debugger GDB::
* Running GDB::
* Introduction to GDB Commands::
* Using Ada Expressions::
* Calling User-Defined Subprograms::
* Using the Next Command in a Function::
* Ada Exceptions::
* Ada Tasks::
* Debugging Generic Units::
* GNAT Abnormal Termination or Failure to Terminate::
* Naming Conventions for GNAT Source Files::
* Getting Internal Debugging Information::
* Stack Traceback::
@end menu

@cindex Debugger
@findex gdb

@node The GNAT Debugger GDB
@section The GNAT Debugger GDB

@noindent
@code{GDB} is a general purpose, platform-independent debugger that
can be used to debug mixed-language programs compiled with @code{GCC},
and in particular is capable of debugging Ada programs compiled with
GNAT. The latest versions of @code{GDB} are Ada-aware and can handle
complex Ada data structures.

The manual @cite{Debugging with GDB}
@ifset vms
, located in the GNU:[DOCS] directory,
@end ifset
contains full details on the usage of @code{GDB}, including a section on
its usage on programs. This manual should be consulted for full
details. The section that follows is a brief introduction to the
philosophy and use of @code{GDB}.

When GNAT programs are compiled, the compiler optionally writes debugging
information into the generated object file, including information on
line numbers, and on declared types and variables. This information is
separate from the generated code. It makes the object files considerably
larger, but it does not add to the size of the actual executable that
will be loaded into memory, and has no impact on run-time performance. The
generation of debug information is triggered by the use of the
^-g^/DEBUG^ switch in the gcc or gnatmake command used to carry out
the compilations. It is important to emphasize that the use of these
options does not change the generated code.

The debugging information is written in standard system formats that
are used by many tools, including debuggers and profilers. The format
of the information is typically designed to describe C types and
semantics, but GNAT implements a translation scheme which allows full
details about Ada types and variables to be encoded into these
standard C formats. Details of this encoding scheme may be found in
the file exp_dbug.ads in the GNAT source distribution. However, the
details of this encoding are, in general, of no interest to a user,
since @code{GDB} automatically performs the necessary decoding.

When a program is bound and linked, the debugging information is
collected from the object files, and stored in the executable image of
the program. Again, this process significantly increases the size of
the generated executable file, but it does not increase the size of
the executable program itself. Furthermore, if this program is run in
the normal manner, it runs exactly as if the debug information were
not present, and takes no more actual memory.

However, if the program is run under control of @code{GDB}, the
debugger is activated.  The image of the program is loaded, at which
point it is ready to run.  If a run command is given, then the program
will run exactly as it would have if @code{GDB} were not present. This
is a crucial part of the @code{GDB} design philosophy.  @code{GDB} is
entirely non-intrusive until a breakpoint is encountered.  If no
breakpoint is ever hit, the program will run exactly as it would if no
debugger were present. When a breakpoint is hit, @code{GDB} accesses
the debugging information and can respond to user commands to inspect
variables, and more generally to report on the state of execution.

@node Running GDB
@section Running GDB

@ifclear vxworks
@noindent
The debugger can be launched directly and simply from @code{glide} or
through its graphical interface: @code{gvd}. It can also be used
directly in text mode. Here is described the basic use of @code{GDB}
in text mode. All the commands described below can be used in the
@code{gvd} console window eventhough there is usually other more
graphical ways to achieve the same goals.

@ifclear vms
@noindent
The command to run de graphical interface of the debugger is
@smallexample
$ gvd program
@end smallexample
@end ifclear

@noindent
The command to run @code{GDB} in text mode is

@smallexample
$ ^gdb program^$ GDB PROGRAM^
@end smallexample

@noindent
where @code{^program^PROGRAM^} is the name of the executable file. This
activates the debugger and results in a prompt for debugger commands.
The simplest command is simply @code{run}, which causes the program to run
exactly as if the debugger were not present. The following section
describes some of the additional commands that can be given to @code{GDB}.
@end ifclear

@ifset vxworks
Please refer to the debugging section of the chapter specific to your
cross environment at the end of this manual.
@end ifset

@node Introduction to GDB Commands
@section Introduction to GDB Commands

@noindent
@code{GDB} contains a large repertoire of commands. The manual
@cite{Debugging with GDB}
@ifset vms
, located in the GNU:[DOCS] directory,
@end ifset
includes extensive documentation on the use
of these commands, together with examples of their use. Furthermore,
the command @var{help} invoked from within @code{GDB} activates a simple help
facility which summarizes the available commands and their options.
In this section we summarize a few of the most commonly
used commands to give an idea of what @code{GDB} is about. You should create
a simple program with debugging information and experiment with the use of
these @code{GDB} commands on the program as you read through the
following section.

@table @code
@item set args @var{arguments}
The @var{arguments} list above is a list of arguments to be passed to
the program on a subsequent run command, just as though the arguments
had been entered on a normal invocation of the program. The @code{set args}
command is not needed if the program does not require arguments.

@item run
The @code{run} command causes execution of the program to start from
the beginning. If the program is already running, that is to say if
you are currently positioned at a breakpoint, then a prompt will ask
for confirmation that you want to abandon the current execution and
restart.

@item breakpoint @var{location}
The breakpoint command sets a breakpoint, that is to say a point at which
execution will halt and @code{GDB} will await further
commands. @var{location} is
either a line number within a file, given in the format @code{file:linenumber},
or it is the name of a subprogram. If you request that a breakpoint be set on
a subprogram that is overloaded, a prompt will ask you to specify on which of
those subprograms you want to breakpoint. You can also
specify that all of them should be breakpointed. If the program is run
and execution encounters the breakpoint, then the program
stops and @code{GDB} signals that the breakpoint was encountered by
printing the line of code before which the program is halted.

@item breakpoint exception @var{name}
A special form of the breakpoint command which breakpoints whenever
exception @var{name} is raised.
If @var{name} is omitted,
then a breakpoint will occur when any exception is raised.

@item print @var{expression}
This will print the value of the given expression. Most simple
Ada expression formats are properly handled by @code{GDB}, so the expression
can contain function calls, variables, operators, and attribute references.

@item continue
Continues execution following a breakpoint, until the next breakpoint or the
termination of the program.

@item step
Executes a single line after a breakpoint. If the next statement is a subprogram
call, execution continues into (the first statement of) the
called subprogram.

@item next
Executes a single line. If this line is a subprogram call, executes and
returns from the call.

@item list
Lists a few lines around the current source location. In practice, it
is usually more convenient to have a separate edit window open with the
relevant source file displayed. Successive applications of this command
print subsequent lines. The command can be given an argument which is a
line number, in which case it displays a few lines around the specified one.

@item backtrace
Displays a backtrace of the call chain. This command is typically
used after a breakpoint has occurred, to examine the sequence of calls that
leads to the current breakpoint. The display includes one line for each
activation record (frame) corresponding to an active subprogram.

@item up
At a breakpoint, @code{GDB} can display the values of variables local
to the current frame. The command @code{up} can be used to
examine the contents of other active frames, by moving the focus up
the stack, that is to say from callee to caller, one frame at a time.

@item down
Moves the focus of @code{GDB} down from the frame currently being
examined to the frame of its callee (the reverse of the previous command),

@item frame @var{n}
Inspect the frame with the given number. The value 0 denotes the frame
of the current breakpoint, that is to say the top of the call stack.

@end table

The above list is a very short introduction to the commands that
@code{GDB} provides. Important additional capabilities, including conditional
breakpoints, the ability to execute command sequences on a breakpoint,
the ability to debug at the machine instruction level and many other
features are described in detail in @cite{Debugging with GDB}.
Note that most commands can be abbreviated
(for example, c for continue, bt for backtrace).

@node Using Ada Expressions
@section Using Ada Expressions
@cindex Ada expressions

@noindent
@code{GDB} supports a fairly large subset of Ada expression syntax, with some
extensions. The philosophy behind the design of this subset is

@itemize @bullet
@item
That @code{GDB} should provide basic literals and access to operations for
arithmetic, dereferencing, field selection, indexing, and subprogram calls,
leaving more sophisticated computations to subprograms written into the
program (which therefore may be called from @code{GDB}).

@item
That type safety and strict adherence to Ada language restrictions
are not particularly important to the @code{GDB} user.

@item
That brevity is important to the @code{GDB} user.
@end itemize

Thus, for brevity, the debugger acts as if there were
implicit @code{with} and @code{use} clauses in effect for all user-written
packages, thus making it unnecessary to fully qualify most names with
their packages, regardless of context. Where this causes ambiguity,
@code{GDB} asks the user's intent.

For details on the supported Ada syntax, see @cite{Debugging with GDB}.

@node Calling User-Defined Subprograms
@section Calling User-Defined Subprograms

@noindent
An important capability of @code{GDB} is the ability to call user-defined
subprograms while debugging. This is achieved simply by entering
a subprogram call statement in the form:

@smallexample
call subprogram-name (parameters)
@end smallexample

@noindent
The keyword @code{call} can be omitted in the normal case where the
@code{subprogram-name} does not coincide with any of the predefined
@code{GDB} commands.

The effect is to invoke the given subprogram, passing it the
list of parameters that is supplied. The parameters can be expressions and
can include variables from the program being debugged. The
subprogram must be defined
at the library level within your program, and @code{GDB} will call the
subprogram within the environment of your program execution (which
means that the subprogram is free to access or even modify variables
within your program).

The most important use of this facility is in allowing the inclusion of
debugging routines that are tailored to particular data structures
in your program. Such debugging routines can be written to provide a suitably
high-level description of an abstract type, rather than a low-level dump
of its physical layout. After all, the standard
@code{GDB print} command only knows the physical layout of your
types, not their abstract meaning. Debugging routines can provide information
at the desired semantic level and are thus enormously useful.

For example, when debugging GNAT itself, it is crucial to have access to
the contents of the tree nodes used to represent the program internally.
But tree nodes are represented simply by an integer value (which in turn
is an index into a table of nodes).
Using the @code{print} command on a tree node would simply print this integer
value, which is not very useful. But the PN routine (defined in file
treepr.adb in the GNAT sources) takes a tree node as input, and displays
a useful high level representation of the tree node, which includes the
syntactic category of the node, its position in the source, the integers
that denote descendant nodes and parent node, as well as varied
semantic information. To study this example in more detail, you might want to
look at the body of the PN procedure in the stated file.

@node Using the Next Command in a Function
@section Using the Next Command in a Function

@noindent
When you use the @code{next} command in a function, the current source
location will advance to the next statement as usual. A special case
arises in the case of a @code{return} statement.

Part of the code for a return statement is the "epilog" of the function.
This is the code that returns to the caller. There is only one copy of
this epilog code, and it is typically associated with the last return
statement in the function if there is more than one return. In some
implementations, this epilog is associated with the first statement
of the function.

The result is that if you use the @code{next} command from a return
statement that is not the last return statement of the function you
may see a strange apparent jump to the last return statement or to
the start of the function. You should simply ignore this odd jump.
The value returned is always that from the first return statement
that was stepped through.

@node Ada Exceptions
@section Breaking on Ada Exceptions
@cindex Exceptions

@noindent
You can set breakpoints that trip when your program raises
selected exceptions.

@table @code
@item break exception
Set a breakpoint that trips whenever (any task in the) program raises
any exception.

@item break exception @var{name}
Set a breakpoint that trips whenever (any task in the) program raises
the exception @var{name}.

@item break exception unhandled
Set a breakpoint that trips whenever (any task in the) program raises an
exception for which there is no handler.

@item info exceptions
@itemx info exceptions @var{regexp}
The @code{info exceptions} command permits the user to examine all defined
exceptions within Ada programs. With a regular expression, @var{regexp}, as
argument, prints out only those exceptions whose name matches @var{regexp}.
@end table

@node Ada Tasks
@section Ada Tasks
@cindex Tasks

@noindent
@code{GDB} allows the following task-related commands:

@table @code
@item info tasks
This command shows a list of current Ada tasks, as in the following example:

@smallexample
@iftex
@leftskip=0cm
@end iftex
(gdb) info tasks
  ID       TID P-ID   Thread Pri State                 Name
   1   8088000   0   807e000  15 Child Activation Wait main_task
   2   80a4000   1   80ae000  15 Accept/Select Wait    b
   3   809a800   1   80a4800  15 Child Activation Wait a
*  4   80ae800   3   80b8000  15 Running               c
@end smallexample

@noindent
In this listing, the asterisk before the first task indicates it to be the
currently running task. The first column lists the task ID that is used
to refer to tasks in the following commands.

@item break @var{linespec} task @var{taskid}
@itemx break @var{linespec} task @var{taskid} if @dots{}
@cindex Breakpoints and tasks
These commands are like the @code{break @dots{} thread @dots{}}.
@var{linespec} specifies source lines.

Use the qualifier @samp{task @var{taskid}} with a breakpoint command
to specify that you only want @code{GDB} to stop the program when a
particular Ada task reaches this breakpoint. @var{taskid} is one of the
numeric task identifiers assigned by @code{GDB}, shown in the first
column of the @samp{info tasks} display.

If you do not specify @samp{task @var{taskid}} when you set a
breakpoint, the breakpoint applies to @emph{all} tasks of your
program.

You can use the @code{task} qualifier on conditional breakpoints as
well; in this case, place @samp{task @var{taskid}} before the
breakpoint condition (before the @code{if}).

@item task @var{taskno}
@cindex Task switching

This command allows to switch to the task referred by @var{taskno}. In
particular, This allows to browse the backtrace of the specified
task. It is advised to switch back to the original task before
continuing execution otherwise the scheduling of the program may be
perturbated.
@end table

@noindent
For more detailed information on the tasking support, see @cite{Debugging with GDB}.

@node Debugging Generic Units
@section Debugging Generic Units
@cindex Debugging Generic Units
@cindex Generics

@noindent
GNAT always uses code expansion for generic instantiation. This means that
each time an instantiation occurs, a complete copy of the original code is
made, with appropriate substitutions of formals by actuals.

It is not possible to refer to the original generic entities in
@code{GDB}, but it is always possible to debug a particular instance of
a generic, by using the appropriate expanded names. For example, if we have

@smallexample
@group
@cartouche
@b{procedure} g @b{is}

   @b{generic package} k @b{is}
      @b{procedure} kp (v1 : @b{in out} integer);
   @b{end} k;

   @b{package body} k @b{is}
      @b{procedure} kp (v1 : @b{in out} integer) @b{is}
      @b{begin}
         v1 := v1 + 1;
      @b{end} kp;
   @b{end} k;

   @b{package} k1 @b{is new} k;
   @b{package} k2 @b{is new} k;

   var : integer := 1;

@b{begin}
   k1.kp (var);
   k2.kp (var);
   k1.kp (var);
   k2.kp (var);
@b{end};
@end cartouche
@end group
@end smallexample

@noindent
Then to break on a call to procedure kp in the k2 instance, simply
use the command:

@smallexample
(gdb) break g.k2.kp
@end smallexample

@noindent
When the breakpoint occurs, you can step through the code of the
instance in the normal manner and examine the values of local variables, as for
other units.

@node GNAT Abnormal Termination or Failure to Terminate
@section GNAT Abnormal Termination or Failure to Terminate
@cindex GNAT Abnormal Termination or Failure to Terminate

@noindent
When presented with programs that contain serious errors in syntax
or semantics,
GNAT may on rare occasions  experience problems in operation, such
as aborting with a
segmentation fault or illegal memory access, raising an internal
exception, terminating abnormally, or failing to terminate at all.
In such cases, you can activate
various features of GNAT that can help you pinpoint the construct in your
program that is the likely source of the problem.

The following strategies are presented in increasing order of
difficulty, corresponding to your experience in using GNAT and your
familiarity with compiler internals.

@enumerate
@item
Run @code{gcc} with the @option{-gnatf}. This first
switch causes all errors on a given line to be reported. In its absence,
only the first error on a line is displayed.

The @option{-gnatdO} switch causes errors to be displayed as soon as they
are encountered, rather than after compilation is terminated. If GNAT
terminates prematurely or goes into an infinite loop, the last error
message displayed may help to pinpoint the culprit.

@item
Run @code{gcc} with the @code{^-v (verbose)^/VERBOSE^} switch. In this mode,
@code{gcc} produces ongoing information about the progress of the
compilation and provides the name of each procedure as code is
generated. This switch allows you to find which Ada procedure was being
compiled when it encountered a code generation problem.

@item
@cindex @option{-gnatdc} switch
Run @code{gcc} with the @option{-gnatdc} switch. This is a GNAT specific
switch that does for the front-end what @code{^-v^VERBOSE^} does for the back end.
The system prints the name of each unit, either a compilation unit or
nested unit, as it is being analyzed.
@item
Finally, you can start
@code{gdb} directly on the @code{gnat1} executable. @code{gnat1} is the
front-end of GNAT, and can be run independently (normally it is just
called from @code{gcc}). You can use @code{gdb} on @code{gnat1} as you
would on a C program (but @pxref{The GNAT Debugger GDB} for caveats). The
@code{where} command is the first line of attack; the variable
@code{lineno} (seen by @code{print lineno}), used by the second phase of
@code{gnat1} and by the @code{gcc} backend, indicates the source line at
which the execution stopped, and @code{input_file name} indicates the name of
the source file.
@end enumerate

@node Naming Conventions for GNAT Source Files
@section Naming Conventions for GNAT Source Files

@noindent
In order to examine the workings of the GNAT system, the following
brief description of its organization may be helpful:

@itemize @bullet
@item
Files with prefix @file{^sc^SC^} contain the lexical scanner.

@item
All files prefixed with @file{^par^PAR^} are components of the parser. The
numbers correspond to chapters of the Ada 95 Reference Manual. For example,
parsing of select statements can be found in @file{par-ch9.adb}.

@item
All files prefixed with @file{^sem^SEM^} perform semantic analysis. The
numbers correspond to chapters of the Ada standard. For example, all
issues involving context clauses can be found in @file{sem_ch10.adb}. In
addition, some features of the language require sufficient special processing
to justify their own semantic files: sem_aggr for aggregates, sem_disp for
dynamic dispatching, etc.

@item
All files prefixed with @file{^exp^EXP^} perform normalization and
expansion of the intermediate representation (abstract syntax tree, or AST).
these files use the same numbering scheme as the parser and semantics files.
For example, the construction of record initialization procedures is done in
@file{exp_ch3.adb}.

@item
The files prefixed with @file{^bind^BIND^} implement the binder, which
verifies the consistency of the compilation, determines an order of
elaboration, and generates the bind file.

@item
The files @file{atree.ads} and @file{atree.adb} detail the low-level
data structures used by the front-end.

@item
The files @file{sinfo.ads} and @file{sinfo.adb} detail the structure of
the abstract syntax tree as produced by the parser.

@item
The files @file{einfo.ads} and @file{einfo.adb} detail the attributes of
all entities, computed during semantic analysis.

@item
Library management issues are dealt with in files with prefix
@file{^lib^LIB^}.

@item
@findex Ada
@cindex Annex A
Ada files with the prefix @file{^a-^A-^} are children of @code{Ada}, as
defined in Annex A.

@item
@findex Interfaces
@cindex Annex B
Files with prefix @file{^i-^I-^} are children of @code{Interfaces}, as
defined in Annex B.

@item
@findex System
Files with prefix @file{^s-^S-^} are children of @code{System}. This includes
both language-defined children and GNAT run-time routines.

@item
@findex GNAT
Files with prefix @file{^g-^G-^} are children of @code{GNAT}. These are useful
general-purpose packages, fully documented in their specifications. All
the other @file{.c} files are modifications of common @code{gcc} files.
@end itemize

@node Getting Internal Debugging Information
@section Getting Internal Debugging Information

@noindent
Most compilers have internal debugging switches and modes. GNAT
does also, except GNAT internal debugging switches and modes are not
secret. A summary and full description of all the compiler and binder
debug flags are in the file @file{debug.adb}. You must obtain the
sources of the compiler to see the full detailed effects of these flags.

The switches that print the source of the program (reconstructed from
the internal tree) are of general interest for user programs, as are the
options to print
the full internal tree, and the entity table (the symbol table
information). The reconstructed source provides a readable version of the
program after the front-end has completed analysis and  expansion, and is useful
when studying the performance of specific constructs. For example, constraint
checks are indicated, complex aggregates are replaced with loops and
assignments, and tasking primitives are replaced with run-time calls.

@node Stack Traceback
@section Stack Traceback
@cindex traceback
@cindex stack traceback
@cindex stack unwinding

@noindent
Traceback is a mechanism to display the sequence of subprogram calls that
leads to a specified execution point in a program. Often (but not always)
the execution point is an instruction at which an exception has been raised.
This mechanism is also known as @i{stack unwinding} because it obtains
its information by scanning the run-time stack and recovering the activation
records of all active subprograms. Stack unwinding is one of the most
important tools for program debugging.

@noindent
The first entry stored in traceback corresponds to the deepest calling level,
that is to say the subprogram currently executing the instruction
from which we want to obtain the traceback.

@noindent
Note that there is no runtime performance penalty when stack traceback
is enabled and no exception are raised during program execution.

@menu
* Non-Symbolic Traceback::
* Symbolic Traceback::
@end menu

@node Non-Symbolic Traceback
@subsection Non-Symbolic Traceback
@cindex traceback, non-symbolic

@noindent
Note: this feature is not supported on all platforms. See
@file{GNAT.Traceback spec in g-traceb.ads} for a complete list of supported
platforms.

@menu
* Tracebacks From an Unhandled Exception::
* Tracebacks From Exception Occurrences (non-symbolic)::
* Tracebacks From Anywhere in a Program (non-symbolic)::
@end menu

@node Tracebacks From an Unhandled Exception
@subsubsection Tracebacks From an Unhandled Exception

@noindent
A runtime non-symbolic traceback is a list of addresses of call instructions.
To enable this feature you must use the @code{-E}
@code{gnatbind}'s option. With this option a stack traceback is stored as part
of exception information. It is possible to retrieve this information using the
standard @code{Ada.Exception.Exception_Information} routine.

@noindent
Let's have a look at a simple example:

@smallexample
@cartouche
@group
procedure STB is

   procedure P1 is
   begin
      raise Constraint_Error;
   end P1;

   procedure P2 is
   begin
      P1;
   end P2;

begin
   P2;
end STB;
@end group
@end cartouche
@end smallexample

@smallexample
$ gnatmake stb -bargs -E
$ stb

Execution terminated by unhandled exception
Exception name: CONSTRAINT_ERROR
Message: stb.adb:5
Call stack traceback locations:
0x401373 0x40138b 0x40139c 0x401335 0x4011c4 0x4011f1 0x77e892a4
@end smallexample

@noindent
As we see the traceback lists a sequence of addresses for the unhandled
exception @code{CONSTAINT_ERROR} raised in procedure P1. It is easy to
guess that this exception come from procedure P1. To translate these
addresses into the source lines where the calls appear, the
@code{addr2line} tool, described below, is invaluable. The use of this tool
requires the program to be compiled with debug information.

@smallexample
$ gnatmake -g stb -bargs -E
$ stb

Execution terminated by unhandled exception
Exception name: CONSTRAINT_ERROR
Message: stb.adb:5
Call stack traceback locations:
0x401373 0x40138b 0x40139c 0x401335 0x4011c4 0x4011f1 0x77e892a4

$ addr2line --exe=stb 0x401373 0x40138b 0x40139c 0x401335 0x4011c4
   0x4011f1 0x77e892a4

00401373 at d:/stb/stb.adb:5
0040138B at d:/stb/stb.adb:10
0040139C at d:/stb/stb.adb:14
00401335 at d:/stb/b~stb.adb:104
004011C4 at /build/.../crt1.c:200
004011F1 at /build/.../crt1.c:222
77E892A4 in ?? at ??:0
@end smallexample

@noindent
@code{addr2line} has a number of other useful options:

@table @code
@item --functions
to get the function name corresponding to any location

@item --demangle=gnat
to use the @b{gnat} decoding mode for the function names. Note that
for binutils version 2.9.x the option is simply @code{--demangle}.
@end table

@smallexample
$ addr2line --exe=stb --functions --demangle=gnat 0x401373 0x40138b
   0x40139c 0x401335 0x4011c4 0x4011f1

00401373 in stb.p1 at d:/stb/stb.adb:5
0040138B in stb.p2 at d:/stb/stb.adb:10
0040139C in stb at d:/stb/stb.adb:14
00401335 in main at d:/stb/b~stb.adb:104
004011C4 in <__mingw_CRTStartup> at /build/.../crt1.c:200
004011F1 in <mainCRTStartup> at /build/.../crt1.c:222
@end smallexample

@noindent
From this traceback we can see that the exception was raised in
@file{stb.adb} at line 5, which was reached from a procedure call in
@file{stb.adb} at line 10, and so on. The @file{b~std.adb} is the binder file,
which contains the call to the main program.
@pxref{Running gnatbind}. The remaining entries are assorted runtime routines,
and the output will vary from platform to platform.

@noindent
It is also possible to use @code{GDB} with these traceback addresses to debug
the program. For example, we can break at a given code location, as reported
in the stack traceback:

@smallexample
$ gdb -nw stb
@ifset wnt
@noindent
Furthermore, this feature is not implemented inside Windows DLL. Only
the non-symbolic traceback is reported in this case.
@end ifset

(gdb) break *0x401373
Breakpoint 1 at 0x401373: file stb.adb, line 5.
@end smallexample

@noindent
It is important to note that the stack traceback addresses
do not change when debug information is included. This is particularly useful
because it makes it possible to release software without debug information (to
minimize object size), get a field report that includes a stack traceback
whenever an internal bug occurs, and then be able to retrieve the sequence
of calls with the same program compiled with debug information.

@node Tracebacks From Exception Occurrences (non-symbolic)
@subsubsection Tracebacks From Exception Occurrences

@noindent
Non-symbolic tracebacks are obtained by using the @code{-E} binder argument.
The stack traceback is attached to the exception information string, and can
be retrieved in an exception handler within the Ada program, by means of the
Ada95 facilities defined in @code{Ada.Exceptions}. Here is a simple example:

@smallexample
@cartouche
@group
with Ada.Text_IO;
with Ada.Exceptions;

procedure STB is

   use Ada;
   use Ada.Exceptions;

   procedure P1 is
      K : Positive := 1;
   begin
      K := K - 1;
   exception
      when E : others =>
         Text_IO.Put_Line (Exception_Information (E));
   end P1;

   procedure P2 is
   begin
      P1;
   end P2;

begin
   P2;
end STB;
@end group
@end cartouche
@end smallexample

@noindent
This program will output:

@smallexample
$ stb

Exception name: CONSTRAINT_ERROR
Message: stb.adb:12
Call stack traceback locations:
0x4015e4 0x401633 0x401644 0x401461 0x4011c4 0x4011f1 0x77e892a4
@end smallexample

@node Tracebacks From Anywhere in a Program (non-symbolic)
@subsubsection Tracebacks From Anywhere in a Program

@noindent
It is also possible to retrieve a stack traceback from anywhere in a
program. For this you need to
use the @code{GNAT.Traceback} API. This package includes a procedure called
@code{Call_Chain} that computes a complete stack traceback, as well as useful
display procedures described below. It is not necessary to use the
@code{-E gnatbind} option in this case, because the stack traceback mechanism
is invoked explicitly.

@noindent
In the following example we compute a traceback at a specific location in
the program, and we display it using @code{GNAT.Debug_Utilities.Image} to
convert addresses to strings:

@smallexample
@cartouche
@group
with Ada.Text_IO;
with GNAT.Traceback;
with GNAT.Debug_Utilities;

procedure STB is

   use Ada;
   use GNAT;
   use GNAT.Traceback;

   procedure P1 is
      TB  : Tracebacks_Array (1 .. 10);
      --  We are asking for a maximum of 10 stack frames.
      Len : Natural;
      --  Len will receive the actual number of stack frames returned.
   begin
      Call_Chain (TB, Len);

      Text_IO.Put ("In STB.P1 : ");

      for K in 1 .. Len loop
         Text_IO.Put (Debug_Utilities.Image (TB (K)));
         Text_IO.Put (' ');
      end loop;

      Text_IO.New_Line;
   end P1;

   procedure P2 is
   begin
      P1;
   end P2;

begin
   P2;
end STB;
@end group
@end cartouche
@end smallexample

@smallexample
$ gnatmake stb
$ stb

In STB.P1 : 16#0040_F1E4# 16#0040_14F2# 16#0040_170B# 16#0040_171C#
16#0040_1461# 16#0040_11C4# 16#0040_11F1# 16#77E8_92A4#
@end smallexample

@node Symbolic Traceback
@subsection Symbolic Traceback
@cindex traceback, symbolic

@noindent
A symbolic traceback is a stack traceback in which procedure names are
associated with each code location.

@noindent
Note that this feature is not supported on all platforms. See
@file{GNAT.Traceback.Symbolic spec in g-trasym.ads} for a complete
list of currently supported platforms.

@noindent
Note that the symbolic traceback requires that the program be compiled
with debug information. If it is not compiled with debug information
only the non-symbolic information will be valid.

@menu
* Tracebacks From Exception Occurrences (symbolic)::
* Tracebacks From Anywhere in a Program (symbolic)::
@end menu

@node Tracebacks From Exception Occurrences (symbolic)
@subsubsection Tracebacks From Exception Occurrences

@smallexample
@cartouche
@group
with Ada.Text_IO;
with GNAT.Traceback.Symbolic;

procedure STB is

   procedure P1 is
   begin
      raise Constraint_Error;
   end P1;

   procedure P2 is
   begin
      P1;
   end P2;

   procedure P3 is
   begin
      P2;
   end P3;

begin
   P3;
exception
   when E : others =>
      Ada.Text_IO.Put_Line (GNAT.Traceback.Symbolic.Symbolic_Traceback (E));
end STB;
@end group
@end cartouche
@end smallexample

@smallexample
$ gnatmake -g stb -bargs -E -largs -lgnat -laddr2line -lintl
$ stb

0040149F in stb.p1 at stb.adb:8
004014B7 in stb.p2 at stb.adb:13
004014CF in stb.p3 at stb.adb:18
004015DD in ada.stb at stb.adb:22
00401461 in main at b~stb.adb:168
004011C4 in __mingw_CRTStartup at crt1.c:200
004011F1 in mainCRTStartup at crt1.c:222
77E892A4 in ?? at ??:0
@end smallexample

@noindent
The exact sequence of linker options may vary from platform to platform.
The above @code{-largs} section is for Windows platforms. By contrast,
under Unix there is no need for the @code{-largs} section.
Differences across platforms are due to details of linker implementation.

@node Tracebacks From Anywhere in a Program (symbolic)
@subsubsection Tracebacks From Anywhere in a Program

@noindent
It is possible to get a symbolic stack traceback
from anywhere in a program, just as for non-symbolic tracebacks.
The first step is to obtain a non-symbolic
traceback, and then call @code{Symbolic_Traceback} to compute the symbolic
information. Here is an example:

@smallexample
@cartouche
@group
with Ada.Text_IO;
with GNAT.Traceback;
with GNAT.Traceback.Symbolic;

procedure STB is

   use Ada;
   use GNAT.Traceback;
   use GNAT.Traceback.Symbolic;

   procedure P1 is
      TB  : Tracebacks_Array (1 .. 10);
      --  We are asking for a maximum of 10 stack frames.
      Len : Natural;
      --  Len will receive the actual number of stack frames returned.
   begin
      Call_Chain (TB, Len);
      Text_IO.Put_Line (Symbolic_Traceback (TB (1 .. Len)));
   end P1;

   procedure P2 is
   begin
      P1;
   end P2;

begin
   P2;
end STB;
@end group
@end cartouche
@end smallexample

@ifset vms
@node Compatibility with DEC Ada
@chapter Compatibility with DEC Ada
@cindex Compatibility

@noindent
This section of the manual compares DEC Ada for OpenVMS Alpha and GNAT
OpenVMS Alpha. GNAT achieves a high level of compatibility
with DEC Ada, and it should generally be straightforward to port code
from the DEC Ada environment to GNAT. However, there are a few language
and implementation differences of which the user must be aware. These
differences are discussed in this section. In
addition, the operating environment and command structure for the
compiler are different, and these differences are also discussed.

Note that this discussion addresses specifically the implementation
of Ada 83 for DIGITAL OpenVMS Alpha Systems. In cases where the implementation
of DEC Ada differs between OpenVMS Alpha Systems and OpenVMS VAX Systems, GNAT
always follows the Alpha implementation.

@menu
* Ada 95 Compatibility::
* Differences in the Definition of Package System::
* Language-Related Features::
* The Package STANDARD::
* The Package SYSTEM::
* Tasking and Task-Related Features::
* Implementation of Tasks in DEC Ada for OpenVMS Alpha Systems::
* Pragmas and Pragma-Related Features::
* Library of Predefined Units::
* Bindings::
* Main Program Definition::
* Implementation-Defined Attributes::
* Compiler and Run-Time Interfacing::
* Program Compilation and Library Management::
* Input-Output::
* Implementation Limits::
* Tools::
@end menu

@node Ada 95 Compatibility
@section Ada 95 Compatibility

@noindent
GNAT is an Ada 95 compiler, and DEC Ada is an Ada 83
compiler. Ada 95 is almost completely upwards compatible
with Ada 83, and therefore Ada 83 programs will compile
and run under GNAT with
no changes or only minor changes. The Ada 95 Reference
Manual (ANSI/ISO/IEC-8652:1995) provides details on specific
incompatibilities.

GNAT provides the switch /83 on the GNAT COMPILE command,
as well as the pragma ADA_83, to force the compiler to
operate in Ada 83 mode. This mode does not guarantee complete
conformance to Ada 83, but in practice is sufficient to
eliminate most sources of incompatibilities.
In particular, it eliminates the recognition of the
additional Ada 95 keywords, so that their use as identifiers
in Ada83 program is legal, and handles the cases of packages
with optional bodies, and generics that instantiate unconstrained
types without the use of @code{(<>)}.

@node Differences in the Definition of Package System
@section Differences in the Definition of Package System

@noindent
Both the Ada 95 and Ada 83 reference manuals permit a compiler to add
implementation-dependent declarations to package System. In normal mode,
GNAT does not take advantage of this permission, and the version of System
provided by GNAT exactly matches that in the Ada 95 Reference Manual.

However, DEC Ada adds an extensive set of declarations to package System,
as fully documented in the DEC Ada manuals. To minimize changes required
for programs that make use of these extensions, GNAT provides the pragma
Extend_System for extending the definition of package System. By using:

@smallexample
@group
@cartouche
@b{pragma} Extend_System (Aux_DEC);
@end cartouche
@end group
@end smallexample

@noindent
The set of definitions in System is extended to include those in package
@code{System.Aux_DEC}.
These definitions are incorporated directly into package
System, as though they had been declared there in the first place. For a
list of the declarations added, see the specification of this package,
which can be found in the file @code{s-auxdec.ads} in the GNAT library.
The pragma Extend_System is a configuration pragma, which means that
it can be placed in the file @file{gnat.adc}, so that it will automatically
apply to all subsequent compilations. See the section on Configuration
Pragmas for further details.

An alternative approach that avoids the use of the non-standard
Extend_System pragma is to add a context clause to the unit that
references these facilities:

@smallexample
@group
@cartouche
@b{with} System.Aux_DEC;
@b{use}  System.Aux_DEC;
@end cartouche
@end group
@end smallexample

@noindent
The effect is not quite semantically identical to incorporating the declarations
directly into package @code{System},
but most programs will not notice a difference
unless they use prefix notation (e.g. @code{System.Integer_8})
to reference the
entities directly in package @code{System}.
For units containing such references,
the prefixes must either be removed, or the pragma @code{Extend_System}
must be used.

@node Language-Related Features
@section Language-Related Features

@noindent
The following sections highlight differences in types,
representations of types, operations, alignment, and
related topics.

@menu
* Integer Types and Representations::
* Floating-Point Types and Representations::
* Pragmas Float_Representation and Long_Float::
* Fixed-Point Types and Representations::
* Record and Array Component Alignment::
* Address Clauses::
* Other Representation Clauses::
@end menu

@node Integer Types and Representations
@subsection Integer Types and Representations

@noindent
The set of predefined integer types is identical in DEC Ada and GNAT.
Furthermore the representation of these integer types is also identical,
including the capability of size clauses forcing biased representation.

In addition,
DEC Ada for OpenVMS Alpha systems has defined the
following additional integer types in package System:

@itemize @bullet

@item
INTEGER_8

@item
INTEGER_16

@item
INTEGER_32

@item
INTEGER_64

@item
LARGEST_INTEGER
@end itemize

@noindent
When using GNAT, the first four of these types may be obtained from the
standard Ada 95 package @code{Interfaces}.
Alternatively, by use of the pragma
@code{Extend_System}, identical
declarations can be referenced directly in package @code{System}.
On both GNAT and DEC Ada, the maximum integer size is 64 bits.

@node Floating-Point Types and Representations
@subsection Floating-Point Types and Representations
@cindex Floating-Point types

@noindent
The set of predefined floating-point types is identical in DEC Ada and GNAT.
Furthermore the representation of these floating-point
types is also identical. One important difference is that the default
representation for DEC Ada is VAX_Float, but the default representation
for GNAT is IEEE.

Specific types may be declared to be VAX_Float or IEEE, using the pragma
@code{Float_Representation} as described in the DEC Ada documentation.
For example, the declarations:

@smallexample
@group
@cartouche
@b{type} F_Float @b{is digits} 6;
@b{pragma} Float_Representation (VAX_Float, F_Float);
@end cartouche
@end group
@end smallexample

@noindent
declare a type F_Float that will be represented in VAX_Float format.
This set of declarations actually appears in System.Aux_DEC, which provides
the full set of additional floating-point declarations provided in
the DEC Ada version of package
System. This and similar declarations may be accessed in a user program by using
pragma @code{Extend_System}. The use of this
pragma, and the related pragma @code{Long_Float} is described in further
detail in the following section.

@node Pragmas Float_Representation and Long_Float
@subsection Pragmas Float_Representation and Long_Float

@noindent
DEC Ada provides the pragma @code{Float_Representation}, which
acts as a program library switch to allow control over
the internal representation chosen for the predefined
floating-point types declared in the package @code{Standard}.
The format of this pragma is as follows:

@smallexample
@group
@cartouche
@b{pragma} @code{Float_Representation}(VAX_Float | IEEE_Float);
@end cartouche
@end group
@end smallexample

@noindent
This pragma controls the representation of floating-point
types as follows:

@itemize @bullet
@item
@code{VAX_Float} specifies that floating-point
types are represented by default with the VAX hardware types
F-floating, D-floating, G-floating. Note that the H-floating
type is available only on DIGITAL Vax systems, and is not available
in either DEC Ada or GNAT for Alpha systems.

@item
@code{IEEE_Float} specifies that floating-point
types are represented by default with the IEEE single and
double floating-point types.
@end itemize

@noindent
GNAT provides an identical implementation of the pragma
@code{Float_Representation}, except that it functions as a
configuration pragma, as defined by Ada 95. Note that the
notion of configuration pragma corresponds closely to the
DEC Ada notion of a program library switch.

When no pragma is used in GNAT, the default is IEEE_Float, which is different
from DEC Ada 83, where the default is VAX_Float. In addition, the
predefined libraries in GNAT are built using IEEE_Float, so it is not
advisable to change the format of numbers passed to standard library
routines, and if necessary explicit type conversions may be needed.

The use of IEEE_Float is recommended in GNAT since it is more efficient,
and (given that it conforms to an international standard) potentially more
portable. The situation in which VAX_Float may be useful is in interfacing
to existing code and data that expects the use of VAX_Float. There are
two possibilities here. If the requirement for the use of VAX_Float is
localized, then the best approach is to use the predefined VAX_Float
types in package @code{System}, as extended by
@code{Extend_System}. For example, use @code{System.F_Float}
to specify the 32-bit @code{F-Float} format.

Alternatively, if an entire program depends heavily on the use of
the @code{VAX_Float} and in particular assumes that the types in
package @code{Standard} are in @code{Vax_Float} format, then it
may be desirable to reconfigure GNAT to assume Vax_Float by default.
This is done by using the GNAT LIBRARY command to rebuild the library, and
then using the general form of the @code{Float_Representation}
pragma to ensure that this default format is used throughout.
The form of the GNAT LIBRARY command is:

@smallexample
GNAT LIBRARY /CONFIG=@i{file} /CREATE=@i{directory}
@end smallexample

@noindent
where @i{file} contains the new configuration pragmas
and @i{directory} is the directory to be created to contain
the new library.

@noindent
On OpenVMS systems, DEC Ada provides the pragma @code{Long_Float}
to allow control over the internal representation chosen
for the predefined type @code{Long_Float} and for floating-point
type declarations with digits specified in the range 7 .. 15.
The format of this pragma is as follows:

@smallexample
@cartouche
@b{pragma} Long_Float (D_FLOAT | G_FLOAT);
@end cartouche
@end smallexample

@node Fixed-Point Types and Representations
@subsection Fixed-Point Types and Representations

@noindent
On DEC Ada for OpenVMS Alpha systems, rounding is
away from zero for both positive and negative numbers.
Therefore, +0.5 rounds to 1 and -0.5 rounds to -1.

On GNAT for OpenVMS Alpha, the results of operations
on fixed-point types are in accordance with the Ada 95
rules. In particular, results of operations on decimal
fixed-point types are truncated.

@node Record and Array Component Alignment
@subsection Record and Array Component Alignment

@noindent
On DEC Ada for OpenVMS Alpha, all non composite components
are aligned on natural boundaries. For example, 1-byte
components are aligned on byte boundaries, 2-byte
components on 2-byte boundaries, 4-byte components on 4-byte
byte boundaries, and so on. The OpenVMS Alpha hardware
runs more efficiently with naturally aligned data.

ON GNAT for OpenVMS Alpha, alignment rules are compatible
with DEC Ada for OpenVMS Alpha.

@node Address Clauses
@subsection Address Clauses

@noindent
In DEC Ada and GNAT, address clauses are supported for
objects and imported subprograms.
The predefined type @code{System.Address} is a private type
in both compilers, with the same representation (it is simply
a machine pointer). Addition, subtraction, and comparison
operations are available in the standard Ada 95 package
@code{System.Storage_Elements}, or in package @code{System}
if it is extended to include @code{System.Aux_DEC} using a
pragma @code{Extend_System} as previously described.

Note that code that with's both this extended package @code{System}
and the package @code{System.Storage_Elements} should not @code{use}
both packages, or ambiguities will result. In general it is better
not to mix these two sets of facilities. The Ada 95 package was
designed specifically to provide the kind of features that DEC Ada
adds directly to package @code{System}.

GNAT is compatible with DEC Ada in its handling of address
clauses, except for some limitations in
the form of address clauses for composite objects with
initialization. Such address clauses are easily replaced
by the use of an explicitly-defined constant as described
in the Ada 95 Reference Manual (13.1(22)). For example, the sequence
of declarations:

@smallexample
@group
@cartouche
X, Y : Integer := Init_Func;
Q : String (X .. Y) := "abc";
...
@b{for} Q'Address @b{use} Compute_Address;
@end cartouche
@end group
@end smallexample

@noindent
will be rejected by GNAT, since the address cannot be computed at the time
that Q is declared. To achieve the intended effect, write instead:

@smallexample
@group
@cartouche
X, Y : Integer := Init_Func;
Q_Address : @b{constant} Address := Compute_Address;
Q : String (X .. Y) := "abc";
...
@b{for} Q'Address @b{use} Q_Address;
@end cartouche
@end group
@end smallexample

@noindent
which will be accepted by GNAT (and other Ada 95 compilers), and is also
backwards compatible with Ada 83. A fuller description of the restrictions
on address specifications is found in the GNAT Reference Manual.

@node Other Representation Clauses
@subsection Other Representation Clauses

@noindent
GNAT supports in a compatible manner all the representation
clauses supported by DEC Ada. In addition, it
supports representation clause forms that are new in Ada 95
including COMPONENT_SIZE and SIZE clauses for objects.

@node The Package STANDARD
@section The Package STANDARD

@noindent
The package STANDARD, as implemented by DEC Ada, is fully
described in the Reference Manual for the Ada Programming
Language (ANSI/MIL-STD-1815A-1983) and in the DEC Ada
Language Reference Manual. As implemented by GNAT, the
package STANDARD is described in the Ada 95 Reference
Manual.

In addition, DEC Ada supports the Latin-1 character set in
the type CHARACTER. GNAT supports the Latin-1 character set
in the type CHARACTER and also Unicode (ISO 10646 BMP) in
the type WIDE_CHARACTER.

The floating-point types supported by GNAT are those
supported by DEC Ada, but defaults are different, and are controlled by
pragmas. See @pxref{Floating-Point Types and Representations} for details.

@node The Package SYSTEM
@section The Package SYSTEM

@noindent
DEC Ada provides a system-specific version of the package
SYSTEM for each platform on which the language ships.
For the complete specification of the package SYSTEM, see
Appendix F of the DEC Ada Language Reference Manual.

On DEC Ada, the package SYSTEM includes the following conversion functions:
@itemize @bullet
@item TO_ADDRESS(INTEGER)

@item  TO_ADDRESS(UNSIGNED_LONGWORD)

@item  TO_ADDRESS(universal_integer)

@item  TO_INTEGER(ADDRESS)

@item  TO_UNSIGNED_LONGWORD(ADDRESS)

@item  Function IMPORT_VALUE return UNSIGNED_LONGWORD and the
                 functions IMPORT_ADDRESS and IMPORT_LARGEST_VALUE
@end itemize

@noindent
By default, GNAT supplies a version of SYSTEM that matches
the definition given in the Ada 95 Reference Manual.
This
is a subset of the DIGITAL system definitions, which is as
close as possible to the original definitions. The only difference
is that the definition of SYSTEM_NAME is different:

@smallexample
@group
@cartouche
@b{type} Name @b{is} (SYSTEM_NAME_GNAT);
System_Name : @b{constant} Name := SYSTEM_NAME_GNAT;
@end cartouche
@end group
@end smallexample

@noindent
Also, GNAT adds the new Ada 95 declarations for
BIT_ORDER and DEFAULT_BIT_ORDER.

However, the use of the following pragma causes GNAT
to extend the definition of package SYSTEM so that it
encompasses the full set of DIGITAL-specific extensions,
including the functions listed above:

@smallexample
@cartouche
@b{pragma} Extend_System (Aux_DEC);
@end cartouche
@end smallexample

@noindent
The pragma Extend_System is a configuration pragma that
is most conveniently placed in the @file{gnat.adc} file. See the
GNAT Reference Manual for further details.

DEC Ada does not allow the recompilation of the package
SYSTEM. Instead DEC Ada provides several pragmas (SYSTEM_
NAME, STORAGE_UNIT, and MEMORY_SIZE) to modify values in
the package SYSTEM. On OpenVMS Alpha systems, the pragma
SYSTEM_NAME takes the enumeration literal OPENVMS_AXP as
its single argument.

GNAT does permit the recompilation of package SYSTEM using
a special switch (-gnatg) and this switch can be used if
it is necessary to change constants in SYSTEM. GNAT does
not permit the specification of SYSTEM_NAME, STORAGE_UNIT
or MEMORY_SIZE by any other means.

On GNAT systems, the pragma SYSTEM_NAME takes the
enumeration literal SYSTEM_NAME_GNAT.

The definitions provided by the use of

@smallexample
pragma Extend_System (AUX_Dec);
@end smallexample

@noindent
are virtually identical to those provided by the DEC Ada 83 package
System. One important difference is that the name of the TO_ADDRESS
function for type UNSIGNED_LONGWORD is changed to TO_ADDRESS_LONG.
See the GNAT Reference manual for a discussion of why this change was
necessary.

@noindent
The version of TO_ADDRESS taking a universal integer argument is in fact
an extension to Ada 83 not strictly compatible with the reference manual.
In GNAT, we are constrained to be exactly compatible with the standard,
and this means we cannot provide this capability. In DEC Ada 83, the
point of this definition is to deal with a call like:

@smallexample
TO_ADDRESS (16#12777#);
@end smallexample

@noindent
Normally, according to the Ada 83 standard, one would expect this to be
ambiguous, since it matches both the INTEGER and UNSIGNED_LONGWORD forms
of TO_ADDRESS. However, in DEC Ada 83, there is no ambiguity, since the
definition using universal_integer takes precedence.

In GNAT, since the version with universal_integer cannot be supplied, it is
not possible to be 100% compatible. Since there are many programs using
numeric constants for the argument to TO_ADDRESS, the decision in GNAT was
to change the name of the function in the UNSIGNED_LONGWORD case, so the
declarations provided in the GNAT version of AUX_Dec are:

@smallexample
function To_Address (X : Integer) return Address;
pragma Pure_Function (To_Address);

function To_Address_Long (X : Unsigned_Longword) return Address;
pragma Pure_Function (To_Address_Long);
@end smallexample

@noindent
This means that programs using TO_ADDRESS for UNSIGNED_LONGWORD must
change the name to TO_ADDRESS_LONG.

@node Tasking and Task-Related Features
@section Tasking and Task-Related Features

@noindent
The concepts relevant to a comparison of tasking on GNAT
and on DEC Ada for OpenVMS Alpha systems are discussed in
the following sections.

For detailed information on concepts related to tasking in
DEC Ada, see the DEC Ada Language Reference Manual and the
relevant run-time reference manual.

@node Implementation of Tasks in DEC Ada for OpenVMS Alpha Systems
@section Implementation of Tasks in DEC Ada for OpenVMS Alpha Systems

@noindent
On OpenVMS Alpha systems, each Ada task (except a passive
task) is implemented as a single stream of execution
that is created and managed by the kernel. On these
systems, DEC Ada tasking support is based on DECthreads,
an implementation of the POSIX standard for threads.

Although tasks are implemented as threads, all tasks in
an Ada program are part of the same process. As a result,
resources such as open files and virtual memory can be
shared easily among tasks. Having all tasks in one process
allows better integration with the programming environment
(the shell and the debugger, for example).

Also, on OpenVMS Alpha systems, DEC Ada tasks and foreign
code that calls DECthreads routines can be used together.
The interaction between Ada tasks and DECthreads routines
can have some benefits. For example when on OpenVMS Alpha,
DEC Ada can call C code that is already threaded.
GNAT on OpenVMS Alpha uses the facilities of DECthreads,
and Ada tasks are mapped to threads.

@menu
* Assigning Task IDs::
* Task IDs and Delays::
* Task-Related Pragmas::
* Scheduling and Task Priority::
* The Task Stack::
* External Interrupts::
@end menu

@node Assigning Task IDs
@subsection Assigning Task IDs

@noindent
The DEC Ada Run-Time Library always assigns %TASK 1 to
the environment task that executes the main program. On
OpenVMS Alpha systems, %TASK 0 is often used for tasks
that have been created but are not yet activated.

On OpenVMS Alpha systems, task IDs are assigned at
activation. On GNAT systems, task IDs are also assigned at
task creation but do not have the same form or values as
task ID values in DEC Ada. There is no null task, and the
environment task does not have a specific task ID value.

@node Task IDs and Delays
@subsection Task IDs and Delays

@noindent
On OpenVMS Alpha systems, tasking delays are implemented
using Timer System Services. The Task ID is used for the
identification of the timer request (the REQIDT parameter).
If Timers are used in the application take care not to use
0 for the identification, because cancelling such a timer
will cancel all timers and may lead to unpredictable results.

@node Task-Related Pragmas
@subsection Task-Related Pragmas

@noindent
Ada supplies the pragma TASK_STORAGE, which allows
specification of the size of the guard area for a task
stack. (The guard area forms an area of memory that has no
read or write access and thus helps in the detection of
stack overflow.) On OpenVMS Alpha systems, if the pragma
TASK_STORAGE specifies a value of zero, a minimal guard
area is created. In the absence of a pragma TASK_STORAGE, a default guard
area is created.

GNAT supplies the following task-related pragmas:

@itemize @bullet
@item  TASK_INFO

              This pragma appears within a task definition and
              applies to the task in which it appears. The argument
              must be of type SYSTEM.TASK_INFO.TASK_INFO_TYPE.

@item  TASK_STORAGE

              GNAT implements pragma TASK_STORAGE in the same way as
              DEC Ada.
              Both DEC Ada and GNAT supply the pragmas PASSIVE,
              SUPPRESS, and VOLATILE.
@end itemize
@node Scheduling and Task Priority
@subsection Scheduling and Task Priority

@noindent
DEC Ada implements the Ada language requirement that
when two tasks are eligible for execution and they have
different priorities, the lower priority task does not
execute while the higher priority task is waiting. The DEC
Ada Run-Time Library keeps a task running until either the
task is suspended or a higher priority task becomes ready.

On OpenVMS Alpha systems, the default strategy is round-
robin with preemption. Tasks of equal priority take turns
at the processor. A task is run for a certain period of
time and then placed at the rear of the ready queue for
its priority level.

DEC Ada provides the implementation-defined pragma TIME_SLICE,
which can be used to enable or disable round-robin
scheduling of tasks with the same priority.
See the relevant DEC Ada run-time reference manual for
information on using the pragmas to control DEC Ada task
scheduling.

GNAT follows the scheduling rules of Annex D (real-time
Annex) of the Ada 95 Reference Manual. In general, this
scheduling strategy is fully compatible with DEC Ada
although it provides some additional constraints (as
fully documented in Annex D).
GNAT implements time slicing control in a manner compatible with
DEC Ada 83, by means of the pragma Time_Slice, whose semantics are identical
to the DEC Ada 83 pragma of the same name.
Note that it is not possible to mix GNAT tasking and
DEC Ada 83 tasking in the same program, since the two run times are
not compatible.

@node The Task Stack
@subsection The Task Stack

@noindent
In DEC Ada, a task stack is allocated each time a
non passive task is activated. As soon as the task is
terminated, the storage for the task stack is deallocated.
If you specify a size of zero (bytes) with T'STORAGE_SIZE,
a default stack size is used. Also, regardless of the size
specified, some additional space is allocated for task
management purposes. On OpenVMS Alpha systems, at least
one page is allocated.

GNAT handles task stacks in a similar manner. According to
the Ada 95 rules, it provides the pragma STORAGE_SIZE as
an alternative method for controlling the task stack size.
The specification of the attribute T'STORAGE_SIZE is also
supported in a manner compatible with DEC Ada.

@node External Interrupts
@subsection External Interrupts

@noindent
On DEC Ada, external interrupts can be associated with task entries.
GNAT is compatible with DEC Ada in its handling of external interrupts.

@node Pragmas and Pragma-Related Features
@section Pragmas and Pragma-Related Features

@noindent
Both DEC Ada and GNAT supply all language-defined pragmas
as specified by the Ada 83 standard. GNAT also supplies all
language-defined pragmas specified in the Ada 95 Reference Manual.
In addition, GNAT implements the implementation-defined pragmas
from DEC Ada 83.

@itemize @bullet
@item  AST_ENTRY

@item  COMMON_OBJECT

@item  COMPONENT_ALIGNMENT

@item  EXPORT_EXCEPTION

@item  EXPORT_FUNCTION

@item  EXPORT_OBJECT

@item  EXPORT_PROCEDURE

@item  EXPORT_VALUED_PROCEDURE

@item  FLOAT_REPRESENTATION

@item  IDENT

@item  IMPORT_EXCEPTION

@item  IMPORT_FUNCTION

@item  IMPORT_OBJECT

@item  IMPORT_PROCEDURE

@item  IMPORT_VALUED_PROCEDURE

@item  INLINE_GENERIC

@item  INTERFACE_NAME

@item  LONG_FLOAT

@item  MAIN_STORAGE

@item  PASSIVE

@item  PSET_OBJECT

@item  SHARE_GENERIC

@item  SUPPRESS_ALL

@item  TASK_STORAGE

@item  TIME_SLICE

@item  TITLE
@end itemize

@noindent
These pragmas are all fully implemented, with the exception of @code{Title},
@code{Passive}, and @code{Share_Generic}, which are
recognized, but which have no
effect in GNAT. The effect of @code{Passive} may be obtained by the
use of protected objects in Ada 95. In GNAT, all generics are inlined.

Unlike DEC Ada, the GNAT 'EXPORT_@i{subprogram}' pragmas require
a separate subprogram specification which must appear before the
subprogram body.

GNAT also supplies a number of implementation-defined pragmas as follows:
@itemize @bullet
@item  C_PASS_BY_COPY

@item  EXTEND_SYSTEM

@item  SOURCE_FILE_NAME

@item  UNSUPPRESS

@item  WARNINGS

@item  ABORT_DEFER

@item  ADA_83

@item  ADA_95

@item  ANNOTATE

@item  ASSERT

@item  CPP_CLASS

@item  CPP_CONSTRUCTOR

@item  CPP_DESTRUCTOR

@item  CPP_VIRTUAL

@item  CP_VTABLE

@item  DEBUG

@item  LINKER_ALIAS

@item  LINKER_SECTION

@item  MACHINE_ATTRIBUTE

@item  NO_RETURN

@item  PURE_FUNCTION

@item  SOURCE_REFERENCE

@item  TASK_INFO

@item  UNCHECKED_UNION

@item  UNIMPLEMENTED_UNIT

@item  WEAK_EXTERNAL
@end itemize

@noindent
For full details on these GNAT implementation-defined pragmas, see
the GNAT Reference Manual.

@menu
* Restrictions on the Pragma INLINE::
* Restrictions on the Pragma INTERFACE::
* Restrictions on the Pragma SYSTEM_NAME::
@end menu

@node Restrictions on the Pragma INLINE
@subsection Restrictions on the Pragma INLINE

@noindent
DEC Ada applies the following restrictions to the pragma INLINE:
@itemize @bullet
@item  Parameters cannot be a task type.

@item  Function results cannot be task types, unconstrained
array types, or unconstrained types with discriminants.

@item  Bodies cannot declare the following:
@itemize @bullet
@item  Subprogram body or stub (imported subprogram is allowed)

@item  Tasks

@item  Generic declarations

@item  Instantiations

@item  Exceptions

@item  Access types (types derived from access types allowed)

@item  Array or record types

@item  Dependent tasks

@item  Direct recursive calls of subprogram or containing
subprogram, directly or via a renaming

@end itemize
@end itemize

@noindent
In GNAT, the only restriction on pragma INLINE is that the
body must occur before the call if both are in the same
unit, and the size must be appropriately small. There are
no other specific restrictions which cause subprograms to
be incapable of being inlined.

@node  Restrictions on the Pragma INTERFACE
@subsection  Restrictions on the Pragma INTERFACE

@noindent
The following lists and describes the restrictions on the
pragma INTERFACE on DEC Ada and GNAT:
@itemize @bullet
@item  Languages accepted: Ada, Bliss, C, Fortran, Default.
Default is the default on OpenVMS Alpha systems.

@item  Parameter passing: Language specifies default
mechanisms but can be overridden with an EXPORT pragma.

@itemize @bullet
@item  Ada: Use internal Ada rules.

@item  Bliss, C: Parameters must be mode @code{in}; cannot be
record or task type. Result cannot be a string, an
array, or a record.

@item  Fortran: Parameters cannot be a task. Result cannot
be a string, an array, or a record.
@end itemize
@end itemize

@noindent
GNAT is entirely upwards compatible with DEC Ada, and in addition allows
record parameters for all languages.

@node  Restrictions on the Pragma SYSTEM_NAME
@subsection  Restrictions on the Pragma SYSTEM_NAME

@noindent
For DEC Ada for OpenVMS Alpha, the enumeration literal
for the type NAME is OPENVMS_AXP. In GNAT, the enumeration
literal for the type NAME is SYSTEM_NAME_GNAT.

@node  Library of Predefined Units
@section  Library of Predefined Units

@noindent
A library of predefined units is provided as part of the
DEC Ada and GNAT implementations. DEC Ada does not provide
the package MACHINE_CODE but instead recommends importing
assembler code.

The GNAT versions of the DEC Ada Run-Time Library (ADA$PREDEFINED:)
units are taken from the OpenVMS Alpha version, not the OpenVMS VAX
version. During GNAT installation, the DEC Ada Predefined
Library units are copied into the GNU:[LIB.OPENVMS7_x.2_8_x.DECLIB]
(aka DECLIB) directory and patched to remove Ada 95 incompatibilities
and to make them interoperable with GNAT, @pxref{Changes to DECLIB}
for details.

The GNAT RTL is contained in
the GNU:[LIB.OPENVMS7_x.2_8_x.ADALIB] (aka ADALIB) directory and
the default search path is set up to find DECLIB units in preference
to ADALIB units with the same name (TEXT_IO, SEQUENTIAL_IO, and DIRECT_IO,
for example).

However, it is possible to change the default so that the
reverse is true, or even to mix them using child package
notation. The DEC Ada 83 units are available as DEC.xxx where xxx
is the package name, and the Ada units are available in the
standard manner defined for Ada 95, that is to say as Ada.xxx. To
change the default, set ADA_INCLUDE_PATH and ADA_OBJECTS_PATH
appropriately. For example, to change the default to use the Ada95
versions do:

@smallexample
$ DEFINE ADA_INCLUDE_PATH GNU:[LIB.OPENVMS7_1.2_8_1.ADAINCLUDE],-
                          GNU:[LIB.OPENVMS7_1.2_8_1.DECLIB]
$ DEFINE ADA_OBJECTS_PATH GNU:[LIB.OPENVMS7_1.2_8_1.ADALIB],-
                          GNU:[LIB.OPENVMS7_1.2_8_1.DECLIB]
@end smallexample

@menu
* Changes to DECLIB::
@end menu

@node Changes to DECLIB
@subsection Changes to DECLIB

@noindent
The changes made to the DEC Ada predefined library for GNAT and Ada 95
compatibility are minor and include the following:

@itemize @bullet
@item  Adjusting the location of pragmas and record representation
clauses to obey Ada 95 rules

@item  Adding the proper notation to generic formal parameters
that take unconstrained types in instantiation

@item  Adding pragma ELABORATE_BODY to package specifications
that have package bodies not otherwise allowed

@item  Occurrences of the identifier "PROTECTED" are renamed to "PROTECTD".
Currently these are found only in the STARLET package spec.
@end itemize

@noindent
None of the above changes is visible to users.

@node Bindings
@section Bindings

@noindent
On OpenVMS Alpha, DEC Ada provides the following strongly-typed bindings:
@itemize @bullet

@item  Command Language Interpreter (CLI interface)

@item  DECtalk Run-Time Library (DTK interface)

@item  Librarian utility routines (LBR interface)

@item  General Purpose Run-Time Library (LIB interface)

@item  Math Run-Time Library (MTH interface)

@item  National Character Set Run-Time Library (NCS interface)

@item  Compiled Code Support Run-Time Library (OTS interface)

@item  Parallel Processing Run-Time Library (PPL interface)

@item  Screen Management Run-Time Library (SMG interface)

@item  Sort Run-Time Library (SOR interface)

@item  String Run-Time Library (STR interface)

@item STARLET System Library
@findex Starlet

@item  X Window System Version 11R4 and 11R5 (X, XLIB interface)

@item  X Windows Toolkit (XT interface)

@item  X/Motif Version 1.1.3 and 1.2 (XM interface)
@end itemize

@noindent
GNAT provides implementations of these DEC bindings in the DECLIB directory.

The X/Motif bindings used to build DECLIB are whatever versions are in the
DEC Ada ADA$PREDEFINED directory with extension .ADC. The build script will
automatically add a pragma Linker_Options to packages Xm, Xt, and X_Lib
causing the default X/Motif shareable image libraries to be linked in. This
is done via options files named xm.opt, xt.opt, and x_lib.opt (also located
in the DECLIB directory).

It may be necessary to edit these options files to update or correct the
library names if, for example, the newer X/Motif bindings from ADA$EXAMPLES
had been (previous to installing GNAT) copied and renamed to superseded the
default ADA$PREDEFINED versions.

@menu
* Shared Libraries and Options Files::
* Interfaces to C::
@end menu

@node Shared Libraries and Options Files
@subsection Shared Libraries and Options Files

@noindent
When using the DEC Ada
predefined X and Motif bindings, the linking with their shareable images is
done automatically by GNAT LINK. When using other X and Motif bindings, it
is necessary to add the corresponding shareable images to the command line for
GNAT LINK. When linking with shared libraries, or with .OPT files, it is
also necessary to add them to the command line for GNAT LINK.

A shared library to be used with GNAT is built in the same way as other
libraries under VMS. The VMS Link command can be used in standard fashion.

@node Interfaces to C
@subsection Interfaces to C

@noindent
DEC Ada
provides the following Ada types and operations:

@itemize @bullet
@item C types package (C_TYPES)

@item C strings (C_TYPES.NULL_TERMINATED)

@item Other_types (SHORT_INT)
@end itemize

@noindent
Interfacing to C with GNAT, one can use the above approach
described for DEC Ada or the facilities of Annex B of
the Ada 95 Reference Manual (packages INTERFACES.C,
INTERFACES.C.STRINGS and INTERFACES.C.POINTERS). For more
information, see the section "Interfacing to C" in the
GNAT Reference Manual.

The @option{-gnatF} qualifier forces default and explicit
@code{External_Name} parameters in pragmas Import and Export
to be uppercased for compatibility with the default behavior
of DEC C. The qualifier has no effect on @code{Link_Name} parameters.

@node Main Program Definition
@section Main Program Definition

@noindent
The following section discusses differences in the
definition of main programs on DEC Ada and GNAT.
On DEC Ada, main programs are defined to meet the
following conditions:
@itemize @bullet
@item  Procedure with no formal parameters (returns 0 upon
       normal completion)

@item  Procedure with no formal parameters (returns 42 when
       unhandled exceptions are raised)

@item  Function with no formal parameters whose returned value
       is of a discrete type

@item  Procedure with one OUT formal of a discrete type for
       which a specification of pragma EXPORT_VALUED_PROCEDURE is given.

@end itemize

@noindent
When declared with the pragma EXPORT_VALUED_PROCEDURE,
a main function or main procedure returns a discrete
value whose size is less than 64 bits (32 on VAX systems),
the value is zero- or sign-extended as appropriate.
On GNAT, main programs are defined as follows:
@itemize @bullet
@item  Must be a non-generic, parameter-less subprogram that
is either a procedure or function returning an Ada
STANDARD.INTEGER (the predefined type)

@item  Cannot be a generic subprogram or an instantiation of a
generic subprogram
@end itemize

@node Implementation-Defined Attributes
@section Implementation-Defined Attributes

@noindent
GNAT provides all DEC Ada implementation-defined
attributes.

@node Compiler and Run-Time Interfacing
@section Compiler and Run-Time Interfacing

@noindent
DEC Ada provides the following ways to pass options to the linker (ACS LINK):
@itemize @bullet
@item  /WAIT and /SUBMIT qualifiers

@item  /COMMAND qualifier

@item  /[NO]MAP qualifier

@item  /OUTPUT=file-spec

@item  /[NO]DEBUG and /[NO]TRACEBACK qualifiers
@end itemize

@noindent
To pass options to the linker, GNAT provides the following
switches:

@itemize @bullet
@item   /EXECUTABLE=exec-name

@item   /VERBOSE qualifier

@item   /[NO]DEBUG and /[NO]TRACEBACK qualifiers
@end itemize

@noindent
For more information on these switches, see the section
"Switches for gnatlink" in the corresponding section of this Guide.
In DEC Ada, the command-line switch /OPTIMIZE is available
to control optimization. DEC Ada also supplies the
following pragmas:
@itemize @bullet
@item  OPTIMIZE

@item  INLINE

@item  INLINE_GENERIC

@item  SUPPRESS_ALL

@item  PASSIVE
@end itemize

@noindent
In GNAT, optimization is controlled strictly by command
line parameters, as described in the corresponding section of this guide.
The DIGITAL pragmas for control of optimization are
recognized but ignored.

Note that in GNAT, the default is optimization off, whereas in DEC Ada 83,
the default is that optimization is turned on.

@node Program Compilation and Library Management
@section Program Compilation and Library Management

@noindent
DEC Ada and GNAT provide a comparable set of commands to
build programs. DEC Ada also provides a program library,
which is a concept that does not exist on GNAT. Instead,
GNAT provides directories of sources that are compiled as
needed.

The following table summarizes
the DEC Ada commands and provides
equivalent GNAT commands. In this table, some GNAT
equivalents reflect the fact that GNAT does not use the
concept of a program library. Instead, it uses a model
in which collections of source and object files are used
in a manner consistent with other languages like C and
Fortran. Therefore, standard system file commands are used
to manipulate these elements. Those GNAT commands are marked with
an asterisk in the table that follows.
Note that, unlike DEC Ada,  none of the GNAT commands accepts wild cards.

@need 1500
@multitable @columnfractions .31 .30 .39

@item @strong{DEC_Ada_Command}
@tab @strong{GNAT_Equivalent}
@tab @strong{Description}

@item  ADA
@tab     GNAT COMPILE
@tab     Invokes the compiler to compile one or more Ada source files.

@item  ACS ATTACH
@tab     No equivalent
@tab     Switches control of terminal from current process running the program
                                                library manager.

@item   ACS CHECK
@tab      GNAT MAKE /DEPENDENCY_LIST
@tab      Forms the execution closure of one
          or more compiled units and checks completeness and currency.

@item   ACS COMPILE
@tab      GNAT MAKE /ACTIONS=COMPILE
@tab      Forms the execution closure of one or
          more specified units, checks completeness and currency,
          identifies units that have revised source files, compiles same,
          and recompiles units that are or will become obsolete.
          Also completes incomplete generic instantiations.

@item   ACS COPY FOREIGN
@tab      Copy (*)
@tab      Copies a foreign object file into the program library as a
          library unit body.

@item   ACS COPY UNIT
@tab      Copy (*)
@tab      Copies a compiled unit from one program library to another.

@item   ACS CREATE LIBRARY
@tab      Create /directory (*)
@tab      Creates a program library.

@item   ACS CREATE SUBLIBRARY
@tab      Create /directory (*)
@tab      Creates a program sublibrary.

@item   ACS DELETE LIBRARY
@tab
@tab       Deletes a program library and its contents.

@item   ACS DELETE SUBLIBRARY
@tab
@tab      Deletes a program sublibrary and its contents.

@item   ACS DELETE UNIT
@tab      Delete @i{file} (*)
@tab      On OpenVMS systems, deletes one or more compiled units from
          the current program library.

@item   ACS DIRECTORY
@tab       Directory (*)
@tab       On OpenVMS systems, lists units contained in the current
           program library.

@item   ACS ENTER FOREIGN
@tab      Copy (*)
@tab      Allows the import of a foreign body as an Ada library
          specification and enters a reference to a pointer.

@item   ACS ENTER UNIT
@tab      Copy (*)
@tab      Enters a reference (pointer) from the current program library to
          a unit compiled into another program library.

@item   ACS EXIT
@tab      No equivalent
@tab      Exits from the program library manager.

@item   ACS EXPORT
@tab      Copy (*)
@tab      Creates an object file that contains system-specific object code
          for one or more units. With GNAT, object files can simply be copied
          into the desired directory.

@item   ACS EXTRACT SOURCE
@tab      Copy (*)
@tab      Allows access to the copied source file for each Ada compilation unit

@item   ACS HELP
@tab      HELP GNAT
@tab      Provides online help.

@item    ACS LINK
@tab       GNAT LINK
@tab       Links an object file containing Ada units into an executable
           file.

@item    ACS LOAD
@tab       Copy (*)
@tab       Loads (partially compiles) Ada units into the program library.
           Allows loading a program from a collection of files into a library
           without knowing the relationship among units.

@item    ACS MERGE
@tab      Copy (*)
@tab      Merges into the current program library, one or more units from
          another library where they were modified.

@item    ACS RECOMPILE
@tab       GNAT MAKE /ACTIONS=COMPILE
@tab       Recompiles from   external or copied source files any obsolete
           unit in the closure. Also, completes any incomplete generic
           instantiations.

@item    ACS REENTER
@tab       GNAT MAKE
@tab       Reenters current references to units compiled after last entered
           with the ACS ENTER UNIT command.

@item    ACS SET LIBRARY
@tab       Set default (*)
@tab       Defines a program library to be the compilation context as well
           as the target library for compiler output and commands in general.

@item    ACS SET PRAGMA
@tab       Edit gnat.adc (*)
@tab       Redefines specified  values of the library characteristics
            LONG_ FLOAT, MEMORY_SIZE, SYSTEM_NAME, and @code{Float_Representation}.

@item    ACS SET SOURCE
@tab       define @* ADA_INCLUDE_PATH @i{path} (*)
@tab       Defines the source file search list for the ACS COMPILE  command.

@item    ACS SHOW LIBRARY
@tab       Directory (*)
@tab        Lists information about one or more program libraries.

@item    ACS SHOW PROGRAM
@tab       No equivalent
@tab       Lists information about the execution closure of one or
           more units in the program library.

@item    ACS SHOW SOURCE
@tab       Show logical @* ADA_INCLUDE_PATH
@tab       Shows the source file search used when compiling units.

@item    ACS SHOW VERSION
@tab       Compile with VERBOSE option
@tab       Displays the version number of the compiler and program library
           manager used.

@item    ACS SPAWN
@tab        No equivalent
@tab        Creates a subprocess of the current process (same as DCL SPAWN
            command).

@item    ACS VERIFY
@tab       No equivalent
@tab       Performs a series of consistency checks on a program library to
           determine whether the library structure and library files are in
           valid_form.

@end multitable

@noindent

@node Input-Output
@section Input-Output

@noindent
On OpenVMS Alpha systems, DEC Ada uses OpenVMS Record
Management Services (RMS) to perform operations on
external files.

@noindent
DEC Ada and GNAT predefine an identical set of input-
output packages. To make the use of the
generic TEXT_IO operations more convenient, DEC Ada
provides predefined library packages that instantiate the
integer and floating-point operations for the predefined
integer and floating-point types as shown in the following table.

@table @code

@item   Package_Name
      Instantiation

@item   INTEGER_TEXT_IO
      INTEGER_IO(INTEGER)

@item   SHORT_INTEGER_TEXT_IO
     INTEGER_IO(SHORT_INTEGER)

@item   SHORT_SHORT_INTEGER_TEXT_IO
     INTEGER_IO(SHORT_SHORT_ INTEGER)

@item   FLOAT_TEXT_IO
      FLOAT_IO(FLOAT)

@item   LONG_FLOAT_TEXT_IO
      FLOAT_IO(LONG_FLOAT)
@end table

@noindent
The DEC Ada predefined packages and their operations
are implemented using OpenVMS Alpha files and input-
output facilities. DEC Ada supports asynchronous input-
output on OpenVMS Alpha. Familiarity with the following is
recommended:
@itemize @bullet
@item  RMS file organizations and access methods

@item  OpenVMS file specifications and directories

@item  OpenVMS File Definition Language (FDL)
@end itemize

@noindent
GNAT provides I/O facilities that are completely
compatible with DEC Ada. The distribution includes the
standard DEC Ada versions of all I/O packages, operating
in a manner compatible with DEC Ada. In particular, the
following packages are by default the DEC Ada (Ada 83)
versions of these packages rather than the renamings
suggested in annex J of the Ada 95 Reference Manual:
@itemize @bullet
@item  TEXT_IO

@item  SEQUENTIAL_IO

@item  DIRECT_IO
@end itemize

@noindent
The use of the standard Ada 95 syntax for child packages (for
example, ADA.TEXT_IO) retrieves the Ada 95 versions of these
packages, as defined in the Ada 95 Reference Manual.
GNAT provides DIGITAL-compatible predefined instantiations
of the TEXT_IO packages, and also
provides the standard predefined instantiations required
by the Ada 95 Reference Manual.

For further information on how GNAT interfaces to the file
system or how I/O is implemented in programs written in
mixed languages, see the chapter "Implementation of the
Standard I/O" in the GNAT Reference Manual.
This chapter covers the following:
@itemize @bullet
@item  Standard I/O packages

@item  FORM strings

@item  DIRECT_IO

@item  SEQUENTIAL_IO

@item  TEXT_IO

@item  Stream pointer positioning

@item  Reading and writing non-regular files

@item  GET_IMMEDIATE

@item  Treating TEXT_IO files as streams

@item  Shared files

@item  Open modes
@end itemize

@node Implementation Limits
@section Implementation Limits

@noindent
The following table lists implementation limits for DEC Ada and GNAT systems.
@multitable @columnfractions .60 .20 .20
@item  Compilation Parameter
@tab   DEC Ada
@tab   GNAT

@item  In a subprogram or entry  declaration, maximum number of
       formal parameters that are of an unconstrained record type
@tab   32
@tab   No set limit

@item  Maximum identifier length (number of characters)
@tab   255
@tab   255

@item  Maximum number of characters in a source line
@tab   255
@tab   255

@item  Maximum collection size   (number of bytes)
@tab   2**31-1
@tab   2**31-1

@item  Maximum number of discriminants for a record type
@tab   245
@tab   No set limit

@item  Maximum number of formal parameters in an entry or
       subprogram declaration
@tab   246
@tab    No set limit

@item  Maximum number of dimensions in an array type
@tab   255
@tab   No set limit

@item  Maximum number of library  units and subunits in a compilation.
@tab   4095
@tab   No set limit

@item  Maximum number of library units and subunits in an execution.
@tab   16383
@tab   No set limit

@item  Maximum number of objects declared with the pragma COMMON_OBJECT
       or PSECT_OBJECT
@tab   32757
@tab   No set limit

@item  Maximum number of enumeration literals in an enumeration type
       definition
@tab   65535
@tab   No set limit

@item  Maximum number of lines in a source file
@tab   65534
@tab   No set limit

@item  Maximum number of bits in any object
@tab   2**31-1
@tab   2**31-1

@item  Maximum size of the static portion of a stack frame (approximate)
@tab   2**31-1
@tab   2**31-1
@end multitable

@node  Tools
@section Tools

@end ifset

@node Inline Assembler
@chapter Inline Assembler

@noindent
If you need to write low-level software that interacts directly with the hardware, Ada provides two ways to incorporate assembly language code into your program.  First, you can import and invoke external routines written in assembly language, an Ada feature fully supported by GNAT.  However, for small sections of code it may be simpler or more efficient to include assembly language statements directly in your Ada source program, using the facilities of the implementation-defined package @code{System.Machine_Code}, which incorporates the gcc Inline Assembler.  The Inline Assembler approach offers a number of advantages, including the following:

@itemize @bullet
@item No need to use non-Ada tools
@item Consistent interface over different targets
@item Automatic usage of the proper calling conventions
@item Access to Ada constants and variables
@item Definition of intrinsic routines
@item Possibility of inlining a subprogram comprising assembler code
@item Code optimizer can take Inline Assembler code into account
@end itemize

This chapter presents a series of examples to show you how to use the Inline Assembler.  Although it focuses on the Intel x86, the general approach applies also to other processors.  It is assumed that you are familiar with Ada and with assembly language programming.

@menu
* Basic Assembler Syntax::
* A Simple Example of Inline Assembler::
* Output Variables in Inline Assembler::
* Input Variables in Inline Assembler::
* Inlining Inline Assembler Code::
* Other Asm Functionality::
* A Complete Example::
@end menu

@c ---------------------------------------------------------------------------
@node Basic Assembler Syntax
@section Basic Assembler Syntax

@noindent
The assembler used by GNAT and gcc is based not on the Intel assembly language, but rather on a
language that descends from the AT&T Unix assembler @emph{as} (and which is often
referred to as ``AT&T syntax'').
The following table summarizes the main features of @emph{as} syntax and points out the differences from the Intel conventions.
See the gcc @emph{as} and @emph{gas} (an @emph{as} macro
pre-processor) documentation for further information.

@table @asis
@item Register names
gcc / @emph{as}: Prefix with ``%''; for example @code{%eax}
@*
Intel: No extra punctuation; for example @code{eax}

@item Immediate operand
gcc / @emph{as}: Prefix with ``$''; for example @code{$4}
@*
Intel: No extra punctuation; for example @code{4}

@item Address
gcc / @emph{as}: Prefix with ``$''; for example @code{$loc}
@*
Intel: No extra punctuation; for example @code{loc}

@item Memory contents
gcc / @emph{as}: No extra punctuation; for example @code{loc}
@*
Intel: Square brackets; for example @code{[loc]}

@item Register contents
gcc / @emph{as}: Parentheses; for example @code{(%eax)}
@*
Intel: Square brackets; for example @code{[eax]}

@item Hexadecimal numbers
gcc / @emph{as}: Leading ``0x'' (C language syntax); for example @code{0xA0}
@*
Intel: Trailing ``h''; for example @code{A0h}

@item Operand size
gcc / @emph{as}: Explicit in op code; for example @code{movw} to move a 16-bit word
@*
Intel: Implicit, deduced by assembler; for example @code{mov}

@item Instruction repetition
gcc / @emph{as}: Split into two lines; for example
@*
@code{rep}
@*
@code{stosl}
@*
Intel: Keep on one line; for example @code{rep stosl}

@item Order of operands
gcc / @emph{as}: Source first; for example @code{movw $4, %eax}
@*
Intel: Destination first; for example @code{mov eax, 4}
@end table

@c ---------------------------------------------------------------------------
@node A Simple Example of Inline Assembler
@section A Simple Example of Inline Assembler

@noindent
The following example will generate a single assembly language statement, @code{nop}, which does nothing.  Despite its lack of run-time effect, the example will be useful in illustrating the basics of the Inline Assembler facility.

@smallexample
@group
with System.Machine_Code; use System.Machine_Code;
procedure Nothing is
begin
   Asm ("nop");
end Nothing;
@end group
@end smallexample

@code{Asm} is a procedure declared in package @code{System.Machine_Code}; here it takes one parameter, a @emph{template string} that must be a static expression and that will form the generated instruction.
@code{Asm} may be regarded as a compile-time procedure that parses the template string and additional parameters (none here), from which it generates a sequence of assembly language instructions.

The examples in this chapter will illustrate several of the forms for invoking @code{Asm}; a complete specification of the syntax is found in the @cite{GNAT Reference Manual}.

Under the standard GNAT conventions, the @code{Nothing} procedure should be in a file named @file{nothing.adb}.  You can build the executable in the usual way:
@smallexample
gnatmake nothing
@end smallexample
However, the interesting aspect of this example is not its run-time behavior but rather the
generated assembly code.  To see this output, invoke the compiler as follows:
@smallexample
   gcc -c -S -fomit-frame-pointer -gnatp @file{nothing.adb}
@end smallexample
where the options are:

@table @code
@item -c
compile only (no bind or link)
@item -S
generate assembler listing
@item -fomit-frame-pointer
do not set up separate stack frames
@item -gnatp
do not add runtime checks
@end table

This gives a human-readable assembler version of the code. The resulting
file will have the same name as the Ada source file, but with a @code{.s} extension.
In our example, the file @file{nothing.s} has the following contents:

@smallexample
@group
.file "nothing.adb"
gcc2_compiled.:
___gnu_compiled_ada:
.text
   .align 4
.globl __ada_nothing
__ada_nothing:
#APP
   nop
#NO_APP
   jmp L1
   .align 2,0x90
L1:
   ret
@end group
@end smallexample

The assembly code you included is clearly indicated by
the compiler, between the @code{#APP} and @code{#NO_APP}
delimiters. The character before the 'APP' and 'NOAPP'
can differ on different targets. For example, Linux uses '#APP' while
on NT you will see '/APP'.

If you make a mistake in your assembler code (such as using the
wrong size modifier, or using a wrong operand for the instruction) GNAT
will report this error in a temporary file, which will be deleted when
the compilation is finished.  Generating an assembler file will help
in such cases, since you can assemble this file separately using the
@emph{as} assembler that comes with gcc.

Assembling the file using the command

@smallexample
as @file{nothing.s}
@end smallexample
@noindent
will give you error messages whose lines correspond to the assembler
input file, so you can easily find and correct any mistakes you made.
If there are no errors, @emph{as} will generate an object file @file{nothing.out}.

@c ---------------------------------------------------------------------------
@node Output Variables in Inline Assembler
@section Output Variables in Inline Assembler

@noindent
The examples in this section, showing how to access the processor flags, illustrate how to specify the destination operands for assembly language statements.

@smallexample
@group
with Interfaces; use Interfaces;
with Ada.Text_IO; use Ada.Text_IO;
with System.Machine_Code; use System.Machine_Code;
procedure Get_Flags is
   Flags : Unsigned_32;
   use ASCII;
begin
   Asm ("pushfl"          & LF & HT & -- push flags on stack
        "popl %%eax"      & LF & HT & -- load eax with flags
        "movl %%eax, %0",             -- store flags in variable
        Outputs => Unsigned_32'Asm_Output ("=g", Flags));
   Put_Line ("Flags register:" & Flags'Img);
end Get_Flags;
@end group
@end smallexample

In order to have a nicely aligned assembly listing, we have separated
multiple assembler statements in the Asm template string with linefeed (ASCII.LF)
and horizontal tab (ASCII.HT) characters.  The resulting section of the
assembly output file is:

@smallexample
@group
#APP
   pushfl
   popl %eax
   movl %eax, -40(%ebp)
#NO_APP
@end group
@end smallexample

It would have been legal to write the Asm invocation as:

@smallexample
Asm ("pushfl popl %%eax movl %%eax, %0")
@end smallexample

but in the generated assembler file, this would come out as:

@smallexample
#APP
   pushfl popl %eax movl %eax, -40(%ebp)
#NO_APP
@end smallexample

which is not so convenient for the human reader.

We use Ada comments
at the end of each line to explain what the assembler instructions
actually do.  This is a useful convention.

When writing Inline Assembler instructions, you need to precede each register and variable name with a percent sign.  Since the assembler already requires a percent sign at the beginning of a register name, you need two consecutive percent signs for such names in the Asm template string, thus @code{%%eax}.  In the generated assembly code, one of the percent signs will be stripped off.

Names such as @code{%0}, @code{%1}, @code{%2}, etc., denote input or output variables: operands you later define using @code{Input} or @code{Output} parameters to @code{Asm}.
An output variable is illustrated in
the third statement in the Asm template string:
@smallexample
movl %%eax, %0
@end smallexample
The intent is to store the contents of the eax register in a variable that can be accessed in Ada.  Simply writing @code{movl %%eax, Flags} would not necessarily work, since the compiler might optimize by using a register to hold Flags, and the expansion of the @code{movl} instruction would not be aware of this optimization.  The solution is not to store the result directly but rather to advise the compiler to choose the correct operand form; that is the purpose of the @code{%0} output variable.

Information about the output variable is supplied in the @code{Outputs} parameter to @code{Asm}:
@smallexample
Outputs => Unsigned_32'Asm_Output ("=g", Flags));
@end smallexample

The output is defined by the @code{Asm_Output} attribute of the target type; the general format is
@smallexample
Type'Asm_Output (constraint_string, variable_name)
@end smallexample

The constraint string directs the compiler how
to store/access the associated variable.  In the example
@smallexample
Unsigned_32'Asm_Output ("=m", Flags);
@end smallexample
the @code{"m"} (memory) constraint tells the compiler that the variable
@code{Flags} should be stored in a memory variable, thus preventing
the optimizer from keeping it in a register.  In contrast,
@smallexample
Unsigned_32'Asm_Output ("=r", Flags);
@end smallexample
uses the @code{"r"} (register) constraint, telling the compiler to
store the variable in a register.

If the constraint is preceded by the equal character (@strong{=}), it tells the
compiler that the variable will be used to store data into it.

In the @code{Get_Flags} example, we used the "g" (global) constraint, allowing the optimizer
to choose whatever it deems best.

There are a fairly large number of constraints, but the ones that are most useful (for the Intel x86 processor) are the following:

@table @code
@item =
output constraint
@item g
global (i.e. can be stored anywhere)
@item m
in memory
@item I
a constant
@item a
use eax
@item b
use ebx
@item c
use ecx
@item d
use edx
@item S
use esi
@item D
use edi
@item r
use one of eax, ebx, ecx or edx
@item q
use one of eax, ebx, ecx, edx, esi or edi
@end table

The full set of constraints is described in the gcc and @emph{as} documentation; note that it is possible to combine certain constraints in one constraint string.

You specify the association of an output variable with an assembler operand through the @code{%}@emph{n} notation, where @emph{n} is a non-negative integer.  Thus in
@smallexample
@group
Asm ("pushfl"          & LF & HT & -- push flags on stack
     "popl %%eax"      & LF & HT & -- load eax with flags
     "movl %%eax, %0",             -- store flags in variable
     Outputs => Unsigned_32'Asm_Output ("=g", Flags));
@end group
@end smallexample
@noindent
@code{%0} will be replaced in the expanded code by the appropriate operand,
whatever
the compiler decided for the @code{Flags} variable.

In general, you may have any number of output variables:
@itemize @bullet
@item
Count the operands starting at 0; thus @code{%0}, @code{%1}, etc.
@item
Specify the @code{Outputs} parameter as a parenthesized comma-separated list of @code{Asm_Output} attributes
@end itemize

For example:
@smallexample
@group
Asm ("movl %%eax, %0" & LF & HT &
     "movl %%ebx, %1" & LF & HT &
     "movl %%ecx, %2",
     Outputs => (Unsigned_32'Asm_Output ("=g", Var_A),   --  %0 = Var_A
                 Unsigned_32'Asm_Output ("=g", Var_B),   --  %1 = Var_B
                 Unsigned_32'Asm_Output ("=g", Var_C))); --  %2 = Var_C
@end group
@end smallexample
@noindent
where @code{Var_A}, @code{Var_B}, and @code{Var_C} are variables in the Ada program.

As a variation on the @code{Get_Flags} example, we can use the constraints string to direct the compiler to store the eax register into the @code{Flags} variable, instead of including the store instruction explicitly in the @code{Asm} template string:

@smallexample
@group
with Interfaces; use Interfaces;
with Ada.Text_IO; use Ada.Text_IO;
with System.Machine_Code; use System.Machine_Code;
procedure Get_Flags_2 is
   Flags : Unsigned_32;
   use ASCII;
begin
   Asm ("pushfl"      & LF & HT & -- push flags on stack
        "popl %%eax",             -- save flags in eax
        Outputs => Unsigned_32'Asm_Output ("=a", Flags));
   Put_Line ("Flags register:" & Flags'Img);
end Get_Flags_2;
@end group
@end smallexample

@noindent
The @code{"a"} constraint tells the compiler that the @code{Flags}
variable will come from the eax register. Here is the resulting code:

@smallexample
@group
#APP
   pushfl
   popl %eax
#NO_APP
   movl %eax,-40(%ebp)
@end group
@end smallexample

@noindent
The compiler generated the store of eax into Flags after
expanding the assembler code.

Actually, there was no need to pop the flags into the eax register; more simply, we could just pop the flags directly into the program variable:

@smallexample
@group
with Interfaces; use Interfaces;
with Ada.Text_IO; use Ada.Text_IO;
with System.Machine_Code; use System.Machine_Code;
procedure Get_Flags_3 is
   Flags : Unsigned_32;
   use ASCII;
begin
   Asm ("pushfl"  & LF & HT & -- push flags on stack
        "pop %0",             -- save flags in Flags
        Outputs => Unsigned_32'Asm_Output ("=g", Flags));
   Put_Line ("Flags register:" & Flags'Img);
end Get_Flags_3;
@end group
@end smallexample

@c ---------------------------------------------------------------------------
@node Input Variables in Inline Assembler
@section Input Variables in Inline Assembler

@noindent
The example in this section illustrates how to specify the source operands for assembly language statements.  The program simply increments its input value by 1:

@smallexample
@group
with Interfaces; use Interfaces;
with Ada.Text_IO; use Ada.Text_IO;
with System.Machine_Code; use System.Machine_Code;
procedure Increment is

   function Incr (Value : Unsigned_32) return Unsigned_32 is
      Result : Unsigned_32;
   begin
      Asm ("incl %0",
           Inputs  => Unsigned_32'Asm_Input ("a", Value),
           Outputs => Unsigned_32'Asm_Output ("=a", Result));
      return Result;
   end Incr;

   Value : Unsigned_32;

begin
   Value := 5;
   Put_Line ("Value before is" & Value'Img);
   Value := Incr (Value);
   Put_Line ("Value after is" & Value'Img);
end Increment;
@end group
@end smallexample

The @code{Outputs} parameter to @code{Asm} specifies
that the result will be in the eax register and that it is to be stored in the @code{Result}
variable.

The @code{Inputs} parameter looks much like the @code{Outputs} parameter, but with an
@code{Asm_Input} attribute. The
@code{"="} constraint, indicating an output value, is not present.

You can have multiple input variables, in the same way that you can have more
than one output variable.

The parameter count (%0, %1) etc, now starts at the first input
statement, and continues with the output statements.
When both parameters use the same variable, the
compiler will treat them as the same %n operand, which is the case here.

Just as the @code{Outputs} parameter causes the register to be stored into the
target variable after execution of the assembler statements, so does the
@code{Inputs} parameter cause its variable to be loaded into the register before execution
of the
assembler statements.

Thus the effect of the @code{Asm} invocation is:
@enumerate
@item load the 32-bit value of @code{Value} into eax
@item execute the @code{incl %eax} instruction
@item store the contents of eax into the @code{Result} variable
@end enumerate

The resulting assembler file (with @code{-O2} optimization) contains:
@smallexample
@group
_increment__incr.1:
   subl $4,%esp
   movl 8(%esp),%eax
#APP
   incl %eax
#NO_APP
   movl %eax,%edx
   movl %ecx,(%esp)
   addl $4,%esp
   ret
@end group
@end smallexample

@c ---------------------------------------------------------------------------
@node Inlining Inline Assembler Code
@section Inlining Inline Assembler Code

@noindent
For a short subprogram such as the @code{Incr} function in the previous section, the overhead of the call and return (creating / deleting the stack frame)
can be significant, compared to the amount of code in the subprogram body.
A solution is to apply Ada's @code{Inline} pragma to the subprogram,
which directs the compiler to expand invocations of the subprogram at the point(s)
of call, instead of setting up a stack frame for out-of-line calls.
Here is the resulting program:

@smallexample
@group
with Interfaces; use Interfaces;
with Ada.Text_IO; use Ada.Text_IO;
with System.Machine_Code; use System.Machine_Code;
procedure Increment_2 is

   function Incr (Value : Unsigned_32) return Unsigned_32 is
      Result : Unsigned_32;
   begin
      Asm ("incl %0",
           Inputs  => Unsigned_32'Asm_Input ("a", Value),
           Outputs => Unsigned_32'Asm_Output ("=a", Result));
      return Result;
   end Incr;
   pragma Inline (Increment);

   Value : Unsigned_32;

begin
   Value := 5;
   Put_Line ("Value before is" & Value'Img);
   Value := Increment (Value);
   Put_Line ("Value after is" & Value'Img);
end Increment_2;
@end group
@end smallexample

Compile the program with both optimization (@code{-O2}) and inlining
enabled (@option{-gnatpn} instead of @option{-gnatp}).

The @code{Incr} function is still compiled as usual, but at the
point in @code{Increment} where our function used to be called:

@smallexample
@group
pushl %edi
call _increment__incr.1
@end group
@end smallexample

@noindent
the code for the function body directly appears:

@smallexample
@group
movl %esi,%eax
#APP
   incl %eax
#NO_APP
   movl %eax,%edx
@end group
@end smallexample

@noindent
thus saving the overhead of stack frame setup and an out-of-line call.

@c ---------------------------------------------------------------------------
@node Other Asm Functionality
@section Other @code{Asm} Functionality

@noindent
This section describes two important parameters to the @code{Asm} procedure: @code{Clobber}, which identifies register usage; and @code{Volatile}, which inhibits unwanted optimizations.

@menu
* The Clobber Parameter::
* The Volatile Parameter::
@end menu

@c ---------------------------------------------------------------------------
@node The Clobber Parameter
@subsection The @code{Clobber} Parameter

@noindent
One of the dangers of intermixing assembly language and a compiled language such as Ada is
that the compiler needs to be aware of which registers are being used by the assembly code.
In some cases, such as the earlier examples, the constraint string is sufficient to
indicate register usage (e.g. "a" for the eax register).  But more generally, the
compiler needs an explicit identification of the registers that are used by the Inline
Assembly statements.

Using a register that the compiler doesn't know about
could be a side effect of an instruction (like @code{mull}
storing its result in both eax and edx).
It can also arise from explicit register usage in your
assembly code; for example:
@smallexample
@group
Asm ("movl %0, %%ebx" & LF & HT &
     "movl %%ebx, %1",
     Inputs  => Unsigned_32'Asm_Input  ("g", Var_In),
     Outputs => Unsigned_32'Asm_Output ("=g", Var_Out));
@end group
@end smallexample
@noindent
where the compiler (since it does not analyze the @code{Asm} template string)
does not know you are using the ebx register.

In such cases you need to supply the @code{Clobber} parameter to @code{Asm},
to identify the registers that will be used by your assembly code:

@smallexample
@group
Asm ("movl %0, %%ebx" & LF & HT &
     "movl %%ebx, %1",
     Inputs  => Unsigned_32'Asm_Input  ("g", Var_In),
     Outputs => Unsigned_32'Asm_Output ("=g", Var_Out),
     Clobber => "ebx");
@end group
@end smallexample

The Clobber parameter is a static string expression specifying the
register(s) you are using.  Note that register names are @emph{not} prefixed by a percent sign.
Also, if more than one register is used then their names are separated by commas; e.g., @code{"eax, ebx"}

The @code{Clobber} parameter has several additional uses:
@enumerate
@item Use the "register" name @code{cc} to indicate that flags might have changed
@item Use the "register" name @code{memory} if you changed a memory location
@end enumerate

@c ---------------------------------------------------------------------------
@node The Volatile Parameter
@subsection The @code{Volatile} Parameter
@cindex Volatile parameter

@noindent
Compiler optimizations in the presence of Inline Assembler may sometimes have unwanted effects.
For example, when
an @code{Asm} invocation with an input variable is inside a loop, the compiler might move
the loading of the input variable outside the loop, regarding it as a
one-time initialization.

If this effect is not desired, you can disable such optimizations by setting the
@code{Volatile} parameter to @code{True}; for example:

@smallexample
@group
Asm ("movl %0, %%ebx" & LF & HT &
     "movl %%ebx, %1",
     Inputs   => Unsigned_32'Asm_Input  ("g", Var_In),
     Outputs  => Unsigned_32'Asm_Output ("=g", Var_Out),
     Clobber  => "ebx",
     Volatile => True);
@end group
@end smallexample

By default, @code{Volatile} is set to @code{False} unless there is no @code{Outputs}
parameter.

Although setting @code{Volatile} to @code{True} prevents unwanted optimizations,
it will also disable other optimizations that might be important for efficiency.
In general, you should set @code{Volatile} to @code{True} only if the compiler's
optimizations have created problems.

@c ---------------------------------------------------------------------------
@node A Complete Example
@section A Complete Example

@noindent
This section contains a complete program illustrating a realistic usage of GNAT's Inline Assembler
capabilities.  It comprises a main procedure @code{Check_CPU} and a package @code{Intel_CPU}.
The package declares a collection of functions that detect the properties of the 32-bit
x86 processor that is running the program.  The main procedure invokes these functions
and displays the information.

The Intel_CPU package could be enhanced by adding functions to
detect the type of x386 co-processor, the processor caching options and
special operations such as the SIMD extensions.

Although the Intel_CPU package has been written for 32-bit Intel
compatible CPUs, it is OS neutral. It has been tested on DOS,
Windows/NT and Linux.

@menu
* Check_CPU Procedure::
* Intel_CPU Package Specification::
* Intel_CPU Package Body::
@end menu

@c ---------------------------------------------------------------------------
@node Check_CPU Procedure
@subsection @code{Check_CPU} Procedure
@cindex Check_CPU procedure

@smallexample
---------------------------------------------------------------------
--                                                                 --
--  Uses the Intel_CPU package to identify the CPU the program is  --
--  running on, and some of the features it supports.              --
--                                                                 --
---------------------------------------------------------------------

with Intel_CPU;                     --  Intel CPU detection functions
with Ada.Text_IO;                   --  Standard text I/O
with Ada.Command_Line;              --  To set the exit status

procedure Check_CPU is

   Type_Found : Boolean := False;
   --  Flag to indicate that processor was identified

   Features   : Intel_CPU.Processor_Features;
   --  The processor features

   Signature  : Intel_CPU.Processor_Signature;
   --  The processor type signature

begin

   -----------------------------------
   --  Display the program banner.  --
   -----------------------------------

   Ada.Text_IO.Put_Line (Ada.Command_Line.Command_Name &
                         ": check Intel CPU version and features, v1.0");
   Ada.Text_IO.Put_Line ("distribute freely, but no warranty whatsoever");
   Ada.Text_IO.New_Line;

   -----------------------------------------------------------------------
   --  We can safely start with the assumption that we are on at least  --
   --  a x386 processor. If the CPUID instruction is present, then we   --
   --  have a later processor type.                                     --
   -----------------------------------------------------------------------

   if Intel_CPU.Has_CPUID = False then

      --  No CPUID instruction, so we assume this is indeed a x386
      --  processor. We can still check if it has a FP co-processor.
      if Intel_CPU.Has_FPU then
         Ada.Text_IO.Put_Line
           ("x386-type processor with a FP co-processor");
      else
         Ada.Text_IO.Put_Line
           ("x386-type processor without a FP co-processor");
      end if;  --  check for FPU

      --  Program done
      Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Success);
      return;

   end if;  --  check for CPUID

   -----------------------------------------------------------------------
   --  If CPUID is supported, check if this is a true Intel processor,  --
   --  if it is not, display a warning.                                 --
   -----------------------------------------------------------------------

   if Intel_CPU.Vendor_ID /= Intel_CPU.Intel_Processor then
      Ada.Text_IO.Put_Line ("*** This is a Intel compatible processor");
      Ada.Text_IO.Put_Line ("*** Some information may be incorrect");
   end if;  --  check if Intel

   ----------------------------------------------------------------------
   --  With the CPUID instruction present, we can assume at least a    --
   --  x486 processor. If the CPUID support level is < 1 then we have  --
   --  to leave it at that.                                            --
   ----------------------------------------------------------------------

   if Intel_CPU.CPUID_Level < 1 then

      --  Ok, this is a x486 processor. we still can get the Vendor ID
      Ada.Text_IO.Put_Line ("x486-type processor");
      Ada.Text_IO.Put_Line ("Vendor ID is " & Intel_CPU.Vendor_ID);

      --  We can also check if there is a FPU present
      if Intel_CPU.Has_FPU then
         Ada.Text_IO.Put_Line ("Floating-Point support");
      else
         Ada.Text_IO.Put_Line ("No Floating-Point support");
      end if;  --  check for FPU

      --  Program done
      Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Success);
      return;

   end if;  --  check CPUID level

   ---------------------------------------------------------------------
   --  With a CPUID level of 1 we can use the processor signature to  --
   --  determine it's exact type.                                     --
   ---------------------------------------------------------------------

   Signature := Intel_CPU.Signature;

   ----------------------------------------------------------------------
   --  Ok, now we go into a lot of messy comparisons to get the        --
   --  processor type. For clarity, no attememt to try to optimize the --
   --  comparisons has been made. Note that since Intel_CPU does not   --
   --  support getting cache info, we cannot distinguish between P5    --
   --  and Celeron types yet.                                          --
   ----------------------------------------------------------------------

   --  x486SL
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0100# and
     Signature.Model           = 2#0100# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("x486SL processor");
   end if;

   --  x486DX2 Write-Back
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0100# and
     Signature.Model           = 2#0111# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("Write-Back Enhanced x486DX2 processor");
   end if;

   --  x486DX4
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0100# and
     Signature.Model           = 2#1000# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("x486DX4 processor");
   end if;

   --  x486DX4 Overdrive
   if Signature.Processor_Type = 2#01#   and
     Signature.Family          = 2#0100# and
     Signature.Model           = 2#1000# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("x486DX4 OverDrive processor");
   end if;

   --  Pentium (60, 66)
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0001# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("Pentium processor (60, 66)");
   end if;

   --  Pentium (75, 90, 100, 120, 133, 150, 166, 200)
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0010# then
      Type_Found := True;
      Ada.Text_IO.Put_Line
        ("Pentium processor (75, 90, 100, 120, 133, 150, 166, 200)");
   end if;

   --  Pentium OverDrive (60, 66)
   if Signature.Processor_Type = 2#01#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0001# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("Pentium OverDrive processor (60, 66)");
   end if;

   --  Pentium OverDrive (75, 90, 100, 120, 133, 150, 166, 200)
   if Signature.Processor_Type = 2#01#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0010# then
      Type_Found := True;
      Ada.Text_IO.Put_Line
        ("Pentium OverDrive cpu (75, 90, 100, 120, 133, 150, 166, 200)");
   end if;

   --  Pentium OverDrive processor for x486 processor-based systems
   if Signature.Processor_Type = 2#01#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0011# then
      Type_Found := True;
      Ada.Text_IO.Put_Line
        ("Pentium OverDrive processor for x486 processor-based systems");
   end if;

   --  Pentium processor with MMX technology (166, 200)
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0100# then
      Type_Found := True;
      Ada.Text_IO.Put_Line
        ("Pentium processor with MMX technology (166, 200)");
   end if;

   --  Pentium OverDrive with MMX for Pentium (75, 90, 100, 120, 133)
   if Signature.Processor_Type = 2#01#   and
     Signature.Family          = 2#0101# and
     Signature.Model           = 2#0100# then
      Type_Found := True;
      Ada.Text_IO.Put_Line
        ("Pentium OverDrive processor with MMX " &
         "technology for Pentium processor (75, 90, 100, 120, 133)");
   end if;

   --  Pentium Pro processor
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0110# and
     Signature.Model           = 2#0001# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("Pentium Pro processor");
   end if;

   --  Pentium II processor, model 3
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0110# and
     Signature.Model           = 2#0011# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("Pentium II processor, model 3");
   end if;

   --  Pentium II processor, model 5 or Celeron processor
   if Signature.Processor_Type = 2#00#   and
     Signature.Family          = 2#0110# and
     Signature.Model           = 2#0101# then
      Type_Found := True;
      Ada.Text_IO.Put_Line
        ("Pentium II processor, model 5 or Celeron processor");
   end if;

   --  Pentium Pro OverDrive processor
   if Signature.Processor_Type = 2#01#   and
     Signature.Family          = 2#0110# and
     Signature.Model           = 2#0011# then
      Type_Found := True;
      Ada.Text_IO.Put_Line ("Pentium Pro OverDrive processor");
   end if;

   --  If no type recognized, we have an unknown. Display what
   --  we _do_ know
   if Type_Found = False then
      Ada.Text_IO.Put_Line ("Unknown processor");
   end if;

   -----------------------------------------
   --  Display processor stepping level.  --
   -----------------------------------------

   Ada.Text_IO.Put_Line ("Stepping level:" & Signature.Stepping'Img);

   ---------------------------------
   --  Display vendor ID string.  --
   ---------------------------------

   Ada.Text_IO.Put_Line ("Vendor ID: " & Intel_CPU.Vendor_ID);

   ------------------------------------
   --  Get the processors features.  --
   ------------------------------------

   Features := Intel_CPU.Features;

   -----------------------------
   --  Check for a FPU unit.  --
   -----------------------------

   if Features.FPU = True then
      Ada.Text_IO.Put_Line ("Floating-Point unit available");
   else
      Ada.Text_IO.Put_Line ("no Floating-Point unit");
   end if;  --  check for FPU

   --------------------------------
   --  List processor features.  --
   --------------------------------

   Ada.Text_IO.Put_Line ("Supported features: ");

   --  Virtual Mode Extension
   if Features.VME = True then
      Ada.Text_IO.Put_Line ("    VME    - Virtual Mode Extension");
   end if;

   --  Debugging Extension
   if Features.DE = True then
      Ada.Text_IO.Put_Line ("    DE     - Debugging Extension");
   end if;

   --  Page Size Extension
   if Features.PSE = True then
      Ada.Text_IO.Put_Line ("    PSE    - Page Size Extension");
   end if;

   --  Time Stamp Counter
   if Features.TSC = True then
      Ada.Text_IO.Put_Line ("    TSC    - Time Stamp Counter");
   end if;

   --  Model Specific Registers
   if Features.MSR = True then
      Ada.Text_IO.Put_Line ("    MSR    - Model Specific Registers");
   end if;

   --  Physical Address Extension
   if Features.PAE = True then
      Ada.Text_IO.Put_Line ("    PAE    - Physical Address Extension");
   end if;

   --  Machine Check Extension
   if Features.MCE = True then
      Ada.Text_IO.Put_Line ("    MCE    - Machine Check Extension");
   end if;

   --  CMPXCHG8 instruction supported
   if Features.CX8 = True then
      Ada.Text_IO.Put_Line ("    CX8    - CMPXCHG8 instruction");
   end if;

   --  on-chip APIC hardware support
   if Features.APIC = True then
      Ada.Text_IO.Put_Line ("    APIC   - on-chip APIC hardware support");
   end if;

   --  Fast System Call
   if Features.SEP = True then
      Ada.Text_IO.Put_Line ("    SEP    - Fast System Call");
   end if;

   --  Memory Type Range Registers
   if Features.MTRR = True then
      Ada.Text_IO.Put_Line ("    MTTR   - Memory Type Range Registers");
   end if;

   --  Page Global Enable
   if Features.PGE = True then
      Ada.Text_IO.Put_Line ("    PGE    - Page Global Enable");
   end if;

   --  Machine Check Architecture
   if Features.MCA = True then
      Ada.Text_IO.Put_Line ("    MCA    - Machine Check Architecture");
   end if;

   --  Conditional Move Instruction Supported
   if Features.CMOV = True then
      Ada.Text_IO.Put_Line
        ("    CMOV   - Conditional Move Instruction Supported");
   end if;

   --  Page Attribute Table
   if Features.PAT = True then
      Ada.Text_IO.Put_Line ("    PAT    - Page Attribute Table");
   end if;

   --  36-bit Page Size Extension
   if Features.PSE_36 = True then
      Ada.Text_IO.Put_Line ("    PSE_36 - 36-bit Page Size Extension");
   end if;

   --  MMX technology supported
   if Features.MMX = True then
      Ada.Text_IO.Put_Line ("    MMX    - MMX technology supported");
   end if;

   --  Fast FP Save and Restore
   if Features.FXSR = True then
      Ada.Text_IO.Put_Line ("    FXSR   - Fast FP Save and Restore");
   end if;

   ---------------------
   --  Program done.  --
   ---------------------

   Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Success);

exception

   when others =>
      Ada.Command_Line.Set_Exit_Status (Ada.Command_Line.Failure);
      raise;

end Check_CPU;
@end smallexample

@c ---------------------------------------------------------------------------
@node Intel_CPU Package Specification
@subsection @code{Intel_CPU} Package Specification
@cindex Intel_CPU package specification

@smallexample
-------------------------------------------------------------------------
--                                                                     --
--  file: intel_cpu.ads                                                --
--                                                                     --
--           *********************************************             --
--           * WARNING: for 32-bit Intel processors only *             --
--           *********************************************             --
--                                                                     --
--  This package contains a number of subprograms that are useful in   --
--  determining the Intel x86 CPU (and the features it supports) on    --
--  which the program is running.                                      --
--                                                                     --
--  The package is based upon the information given in the Intel       --
--  Application Note AP-485: "Intel Processor Identification and the   --
--  CPUID Instruction" as of April 1998. This application note can be  --
--  found on www.intel.com.                                            --
--                                                                     --
--  It currently deals with 32-bit processors only, will not detect    --
--  features added after april 1998, and does not guarantee proper     --
--  results on Intel-compatible processors.                            --
--                                                                     --
--  Cache info and x386 fpu type detection are not supported.          --
--                                                                     --
--  This package does not use any privileged instructions, so should   --
--  work on any OS running on a 32-bit Intel processor.                --
--                                                                     --
-------------------------------------------------------------------------

with Interfaces;             use Interfaces;
--  for using unsigned types

with System.Machine_Code;    use System.Machine_Code;
--  for using inline assembler code

with Ada.Characters.Latin_1; use Ada.Characters.Latin_1;
--  for inserting control characters

package Intel_CPU is

   ----------------------
   --  Processor bits  --
   ----------------------

   subtype Num_Bits is Natural range 0 .. 31;
   --  the number of processor bits (32)

   --------------------------
   --  Processor register  --
   --------------------------

   --  define a processor register type for easy access to
   --  the individual bits

   type Processor_Register is array (Num_Bits) of Boolean;
   pragma Pack (Processor_Register);
   for Processor_Register'Size use 32;

   -------------------------
   --  Unsigned register  --
   -------------------------

   --  define a processor register type for easy access to
   --  the individual bytes

   type Unsigned_Register is
      record
         L1 : Unsigned_8;
         H1 : Unsigned_8;
         L2 : Unsigned_8;
         H2 : Unsigned_8;
      end record;

   for Unsigned_Register use
      record
         L1 at 0 range  0 ..  7;
         H1 at 0 range  8 .. 15;
         L2 at 0 range 16 .. 23;
         H2 at 0 range 24 .. 31;
      end record;

   for Unsigned_Register'Size use 32;

   ---------------------------------
   --  Intel processor vendor ID  --
   ---------------------------------

   Intel_Processor : constant String (1 .. 12) := "GenuineIntel";
   --  indicates an Intel manufactured processor

   ------------------------------------
   --  Processor signature register  --
   ------------------------------------

   --  a register type to hold the processor signature

   type Processor_Signature is
      record
         Stepping       : Natural range 0 .. 15;
         Model          : Natural range 0 .. 15;
         Family         : Natural range 0 .. 15;
         Processor_Type : Natural range 0 .. 3;
         Reserved       : Natural range 0 .. 262143;
      end record;

   for Processor_Signature use
      record
         Stepping       at 0 range  0 ..  3;
         Model          at 0 range  4 ..  7;
         Family         at 0 range  8 .. 11;
         Processor_Type at 0 range 12 .. 13;
         Reserved       at 0 range 14 .. 31;
      end record;

   for Processor_Signature'Size use 32;

   -----------------------------------
   --  Processor features register  --
   -----------------------------------

   --  a processor register to hold the processor feature flags

   type Processor_Features is
      record
         FPU    : Boolean;                --  floating point unit on chip
         VME    : Boolean;                --  virtual mode extension
         DE     : Boolean;                --  debugging extension
         PSE    : Boolean;                --  page size extension
         TSC    : Boolean;                --  time stamp counter
         MSR    : Boolean;                --  model specific registers
         PAE    : Boolean;                --  physical address extension
         MCE    : Boolean;                --  machine check extension
         CX8    : Boolean;                --  cmpxchg8 instruction
         APIC   : Boolean;                --  on-chip apic hardware
         Res_1  : Boolean;                --  reserved for extensions
         SEP    : Boolean;                --  fast system call
         MTRR   : Boolean;                --  memory type range registers
         PGE    : Boolean;                --  page global enable
         MCA    : Boolean;                --  machine check architecture
         CMOV   : Boolean;                --  conditional move supported
         PAT    : Boolean;                --  page attribute table
         PSE_36 : Boolean;                --  36-bit page size extension
         Res_2  : Natural range 0 .. 31;  --  reserved for extensions
         MMX    : Boolean;                --  MMX technology supported
         FXSR   : Boolean;                --  fast FP save and restore
         Res_3  : Natural range 0 .. 127; --  reserved for extensions
      end record;

   for Processor_Features use
      record
         FPU    at 0 range  0 ..  0;
         VME    at 0 range  1 ..  1;
         DE     at 0 range  2 ..  2;
         PSE    at 0 range  3 ..  3;
         TSC    at 0 range  4 ..  4;
         MSR    at 0 range  5 ..  5;
         PAE    at 0 range  6 ..  6;
         MCE    at 0 range  7 ..  7;
         CX8    at 0 range  8 ..  8;
         APIC   at 0 range  9 ..  9;
         Res_1  at 0 range 10 .. 10;
         SEP    at 0 range 11 .. 11;
         MTRR   at 0 range 12 .. 12;
         PGE    at 0 range 13 .. 13;
         MCA    at 0 range 14 .. 14;
         CMOV   at 0 range 15 .. 15;
         PAT    at 0 range 16 .. 16;
         PSE_36 at 0 range 17 .. 17;
         Res_2  at 0 range 18 .. 22;
         MMX    at 0 range 23 .. 23;
         FXSR   at 0 range 24 .. 24;
         Res_3  at 0 range 25 .. 31;
      end record;

   for Processor_Features'Size use 32;

   -------------------
   --  Subprograms  --
   -------------------

   function Has_FPU return Boolean;
   --  return True if a FPU is found
   --  use only if CPUID is not supported

   function Has_CPUID return Boolean;
   --  return True if the processor supports the CPUID instruction

   function CPUID_Level return Natural;
   --  return the CPUID support level (0, 1 or 2)
   --  can only be called if the CPUID instruction is supported

   function Vendor_ID return String;
   --  return the processor vendor identification string
   --  can only be called if the CPUID instruction is supported

   function Signature return Processor_Signature;
   --  return the processor signature
   --  can only be called if the CPUID instruction is supported

   function Features return Processor_Features;
   --  return the processors features
   --  can only be called if the CPUID instruction is supported

private

   ------------------------
   --  EFLAGS bit names  --
   ------------------------

   ID_Flag : constant Num_Bits := 21;
   --  ID flag bit

end Intel_CPU;
@end smallexample

@c ---------------------------------------------------------------------------
@node Intel_CPU Package Body
@subsection @code{Intel_CPU} Package Body
@cindex Intel_CPU package body

@smallexample
package body Intel_CPU is

   ---------------------------
   --  Detect FPU presence  --
   ---------------------------

   --  There is a FPU present if we can set values to the FPU Status
   --  and Control Words.

   function Has_FPU return Boolean is

      Register : Unsigned_16;
      --  processor register to store a word

   begin

      --  check if we can change the status word
      Asm (

           --  the assembler code
           "finit"              & LF & HT &    --  reset status word
           "movw $0x5A5A, %%ax" & LF & HT &    --  set value status word
           "fnstsw %0"          & LF & HT &    --  save status word
           "movw %%ax, %0",                    --  store status word

           --  output stored in Register
           --  register must be a memory location
           Outputs => Unsigned_16'Asm_output ("=m", Register),

           --  tell compiler that we used eax
           Clobber => "eax");

      --  if the status word is zero, there is no FPU
      if Register = 0 then
         return False;   --  no status word
      end if;  --  check status word value

      --  check if we can get the control word
      Asm (

           --  the assembler code
           "fnstcw %0",   --  save the control word

           --  output into Register
           --  register must be a memory location
           Outputs => Unsigned_16'Asm_output ("=m", Register));

      --  check the relevant bits
      if (Register and 16#103F#) /= 16#003F# then
         return False;   --  no control word
      end if;  --  check control word value

      --  FPU found
      return True;

   end Has_FPU;

   --------------------------------
   --  Detect CPUID instruction  --
   --------------------------------

   --  The processor supports the CPUID instruction if it is possible
   --  to change the value of ID flag bit in the EFLAGS register.

   function Has_CPUID return Boolean is

      Original_Flags, Modified_Flags : Processor_Register;
      --  EFLAG contents before and after changing the ID flag

   begin

      --  try flipping the ID flag in the EFLAGS register
      Asm (

           --  the assembler code
           "pushfl"               & LF & HT &     --  push EFLAGS on stack
           "pop %%eax"            & LF & HT &     --  pop EFLAGS into eax
           "movl %%eax, %0"       & LF & HT &     --  save EFLAGS content
           "xor $0x200000, %%eax" & LF & HT &     --  flip ID flag
           "push %%eax"           & LF & HT &     --  push EFLAGS on stack
           "popfl"                & LF & HT &     --  load EFLAGS register
           "pushfl"               & LF & HT &     --  push EFLAGS on stack
           "pop %1",                              --  save EFLAGS content

           --  output values, may be anything
           --  Original_Flags is %0
           --  Modified_Flags is %1
           Outputs =>
              (Processor_Register'Asm_output ("=g", Original_Flags),
               Processor_Register'Asm_output ("=g", Modified_Flags)),

           --  tell compiler eax is destroyed
           Clobber => "eax");

      --  check if CPUID is supported
      if Original_Flags(ID_Flag) /= Modified_Flags(ID_Flag) then
         return True;   --  ID flag was modified
      else
         return False;  --  ID flag unchanged
      end if;  --  check for CPUID

   end Has_CPUID;

   -------------------------------
   --  Get CPUID support level  --
   -------------------------------

   function CPUID_Level return Natural is

      Level : Unsigned_32;
      --  returned support level

   begin

      --  execute CPUID, storing the results in the Level register
      Asm (

           --  the assembler code
           "cpuid",    --  execute CPUID

           --  zero is stored in eax
           --  returning the support level in eax
           Inputs => Unsigned_32'Asm_input ("a", 0),

           --  eax is stored in Level
           Outputs => Unsigned_32'Asm_output ("=a", Level),

           --  tell compiler ebx, ecx and edx registers are destroyed
           Clobber => "ebx, ecx, edx");

      --  return the support level
      return Natural (Level);

   end CPUID_Level;

   --------------------------------
   --  Get CPU Vendor ID String  --
   --------------------------------

   --  The vendor ID string is returned in the ebx, ecx and edx register
   --  after executing the CPUID instruction with eax set to zero.
   --  In case of a true Intel processor the string returned is
   --  "GenuineIntel"

   function Vendor_ID return String is

      Ebx, Ecx, Edx : Unsigned_Register;
      --  registers containing the vendor ID string

      Vendor_ID : String (1 .. 12);
      -- the vendor ID string

   begin

      --  execute CPUID, storing the results in the processor registers
      Asm (

           --  the assembler code
           "cpuid",    --  execute CPUID

           --  zero stored in eax
           --  vendor ID string returned in ebx, ecx and edx
           Inputs => Unsigned_32'Asm_input ("a", 0),

           --  ebx is stored in Ebx
           --  ecx is stored in Ecx
           --  edx is stored in Edx
           Outputs => (Unsigned_Register'Asm_output ("=b", Ebx),
                       Unsigned_Register'Asm_output ("=c", Ecx),
                       Unsigned_Register'Asm_output ("=d", Edx)));

      --  now build the vendor ID string
      Vendor_ID( 1) := Character'Val (Ebx.L1);
      Vendor_ID( 2) := Character'Val (Ebx.H1);
      Vendor_ID( 3) := Character'Val (Ebx.L2);
      Vendor_ID( 4) := Character'Val (Ebx.H2);
      Vendor_ID( 5) := Character'Val (Edx.L1);
      Vendor_ID( 6) := Character'Val (Edx.H1);
      Vendor_ID( 7) := Character'Val (Edx.L2);
      Vendor_ID( 8) := Character'Val (Edx.H2);
      Vendor_ID( 9) := Character'Val (Ecx.L1);
      Vendor_ID(10) := Character'Val (Ecx.H1);
      Vendor_ID(11) := Character'Val (Ecx.L2);
      Vendor_ID(12) := Character'Val (Ecx.H2);

      --  return string
      return Vendor_ID;

   end Vendor_ID;

   -------------------------------
   --  Get processor signature  --
   -------------------------------

   function Signature return Processor_Signature is

      Result : Processor_Signature;
      --  processor signature returned

   begin

      --  execute CPUID, storing the results in the Result variable
      Asm (

           --  the assembler code
           "cpuid",    --  execute CPUID

           --  one is stored in eax
           --  processor signature returned in eax
           Inputs => Unsigned_32'Asm_input ("a", 1),

           --  eax is stored in Result
           Outputs => Processor_Signature'Asm_output ("=a", Result),

           --  tell compiler that ebx, ecx and edx are also destroyed
           Clobber => "ebx, ecx, edx");

      --  return processor signature
      return Result;

   end Signature;

   ------------------------------
   --  Get processor features  --
   ------------------------------

   function Features return Processor_Features is

      Result : Processor_Features;
      --  processor features returned

   begin

      --  execute CPUID, storing the results in the Result variable
      Asm (

           --  the assembler code
           "cpuid",    --  execute CPUID

           --  one stored in eax
           --  processor features returned in edx
           Inputs => Unsigned_32'Asm_input ("a", 1),

           --  edx is stored in Result
           Outputs => Processor_Features'Asm_output ("=d", Result),

           --  tell compiler that ebx and ecx are also destroyed
           Clobber => "ebx, ecx");

      --  return processor signature
      return Result;

   end Features;

end Intel_CPU;
@end smallexample
@c END OF INLINE ASSEMBLER CHAPTER
@c ===============================

@ifset wnt
@node Microsoft Windows Topics
@chapter Microsoft Windows Topics
@cindex Windows NT
@cindex Windows 95
@cindex Windows 98

@noindent
This chapter describes topics that are specific to the Microsoft Windows
platforms (NT, 95 and 98).

@menu
* Using GNAT on Windows::
* GNAT Setup Tool::
* CONSOLE and WINDOWS subsystems::
* Temporary Files::
* Mixed-Language Programming on Windows::
* Windows Calling Conventions::
* Introduction to Dynamic Link Libraries (DLLs)::
* Using DLLs with GNAT::
* Building DLLs with GNAT::
* GNAT and Windows Resources::
* Debugging a DLL::
* GNAT and COM/DCOM Objects::
@end menu

@node Using GNAT on Windows
@section Using GNAT on Windows

@noindent
One of the strengths of the GNAT technology is that its tool set
(@code{gcc}, @code{gnatbind}, @code{gnatlink}, @code{gnatmake}, the
@code{gdb} debugger, etc.) is used in the same way regardless of the
platform.

On Windows this tool set is complemented by a number of Microsoft-specific
tools that have been provided to facilitate interoperability with Windows
when this is required. With these tools:

@itemize @bullet

@item
You can build applications using the @code{CONSOLE} or @code{WINDOWS}
subsystems.

@item
You can use any Dynamically Linked Library (DLL) in your Ada code (both
relocatable and non-relocatable DLLs are supported).

@item
You can build Ada DLLs for use in other applications. These applications
can be written in a language other than Ada (e.g., C, C++, etc). Again both
relocatable and non-relocatable Ada DLLs are supported.

@item
You can include Windows resources in your Ada application.

@item
You can use or create COM/DCOM objects.
@end itemize

@noindent
Immediately below are listed all known general GNAT-for-Windows restrictions.
Other restrictions about specific features like Windows Resources and DLLs
are listed in separate sections below.

@itemize @bullet

@item
It is not possible to use @code{GetLastError} and @code{SetLastError}
when tasking, protected records, or exceptions are used. In these
cases, in order to implement Ada semantics, the GNAT run-time system
calls certain Win32 routines that set the last error variable to 0 upon
success. It should be possible to use @code{GetLastError} and
@code{SetLastError} when tasking, protected record, and exception
features are not used, but it is not guaranteed to work.
@end itemize

@node GNAT Setup Tool
@section GNAT Setup Tool
@cindex GNAT Setup Tool
@cindex Setup Tool
@cindex gnatreg

@menu
* Command-line arguments::
* Creating a network installation of GNAT::
* Registering and unregistering additional libraries::
@end menu

@noindent
GNAT installation on Windows is using the Windows registry in order to
locate proper executables and standard libraries. GNAT setup tool, called
@code{gnatreg.exe}, is provided in order to display and modify GNAT-specific
registry entries, allowing to create network GNAT installations, modify the
locations of GNAT components, as well as register and unregister additional
libraries for use with GNAT.

@node Command-line arguments
@subsection Command-line arguments

@noindent
@code{gnatreg [switches] [parameter]}

@noindent
Specifying no arguments causes gnatreg to display current configuration.

@noindent
The switches understood by gnatreg are:
@table @asis
@item  -h
       print the help message
@item  -a
       add a standard library
@item  -r
       remove a standard library
@item  -f
       force creation of keys if they don't exist
@item  -q
       be quiet/terse
@end table

@node Creating a network installation of GNAT
@subsection Creating a network installation of GNAT

@noindent
Make sure the system on which GNAT is installed is accessible from the
current machine.

Use the command

@code{@ @ @ gnatreg -f \\server\sharename\path}

in order to setup the registry entries on a current machine.

For example, if GNAT is installed in @file{\GNAT} directory of a share location
called @file{c-drive} on a machine @file{LOKI}, the command that can be used on
other machines to allow the remote use of GNAT is,

@code{@ @ @ gnatreg -f \\loki\c-drive\gnat}

Remember to also add @file{\\loki\c-drive\gnat\bin} in front of your PATH variable.

Be aware that every compilation using the network installation results in the
transfer of large amounts of data across the network and may cause serious
performance penalty.

@node Registering and unregistering additional libraries
@subsection Registering and unregistering additional libraries

@noindent
To register a standard library use a command:

@code{@ @ @ gnatreg -a <library_name>=<path>}

For example:

@code{@ @ @ gnatreg -a WIN32ADA=c:\Win32Ada}

The libraries registered in this manner will be treated like standard libraries
by the compiler (i.e. they don't have to be specified in -I and -l switches to
various GNAT tools).

To unregister a library, enter
@code{   gnatreg -r <library_name>}

e.g.,
@code{   gnatreg -r WIN32ADA}

@node CONSOLE and WINDOWS subsystems
@section CONSOLE and WINDOWS subsystems
@cindex CONSOLE Subsystem
@cindex WINDOWS Subsystem
@cindex -mwindows

@noindent
Under Windows there is two main subsystems. The @code{CONSOLE} subsystem
(which is the default subsystem) will always create a console when
launching the application. This is not something desirable when the
application has a Windows GUI. To get rid of this console the
application must be using the @code{WINDOWS} subsystem. To do so
the @code{-mwindows} linker option must be specified.

@smallexample
$ gnatmake winprog -largs -mwindows
@end smallexample

@node Temporary Files
@section Temporary Files
@cindex Temporary files

@noindent
It is possible to control where temporary files gets created by setting
the TMP environment variable. The file will be created:

@itemize
@item Under the directory pointed to by the TMP environment variable if
this directory exists.

@item Under c:\temp, if the TMP environment variable is not set (or not
pointing to a directory) and if this directory exists.

@item Under the current working directory otherwise.
@end itemize

@noindent
This allows you to determine exactly where the temporary
file will be created. This is particularly useful in networked
environments where you may not have write access to some
directories.

@node Mixed-Language Programming on Windows
@section Mixed-Language Programming on Windows

@noindent
Developing pure Ada applications on Windows is no different than on
other GNAT-supported platforms. However, when developing or porting an
application that contains a mix of Ada and C/C++, the choice of your
Windows C/C++ development environment conditions your overall
interoperability strategy.

If you use @code{gcc} to compile the non-Ada part of your application,
there are no Windows-specific restrictions that affect the overall
interoperability with your Ada code. If you plan to use
Microsoft tools (e.g. Microsoft Visual C/C++), you should be aware of
the following limitations:

@itemize @bullet
@item
You cannot link your Ada code with an object or library generated with
Microsoft tools if these use the @code{.tls} section (Thread Local
Storage section) since the GNAT linker does not yet support this section.

@item
You cannot link your Ada code with an object or library generated with
Microsoft tools if these use I/O routines other than those provided in
the Microsoft DLL: @code{msvcrt.dll}. This is because the GNAT run time
uses the services of @code{msvcrt.dll} for its I/Os. Use of other I/O
libraries can cause a conflict with @code{msvcrt.dll} services. For
instance Visual C++ I/O stream routines conflict with those in
@code{msvcrt.dll}.
@end itemize

@noindent
If you do want to use the Microsoft tools for your non-Ada code and hit one
of the above limitations, you have two choices:

@enumerate
@item
Encapsulate your non Ada code in a DLL to be linked with your Ada
application. In this case, use the Microsoft or whatever environment to
build the DLL and use GNAT to build your executable
(@pxref{Using DLLs with GNAT}).

@item
Or you can encapsulate your Ada code in a DLL to be linked with the
other part of your application. In this case, use GNAT to build the DLL
(@pxref{Building DLLs with GNAT}) and use the Microsoft or whatever
environment to build your executable.
@end enumerate

@node Windows Calling Conventions
@section Windows Calling Conventions
@findex Stdcall
@findex APIENTRY

@menu
* C Calling Convention::
* Stdcall Calling Convention::
* DLL Calling Convention::
@end menu

@noindent
When a subprogram @code{F} (caller) calls a subprogram @code{G}
(callee), there are several ways to push @code{G}'s parameters on the
stack and there are several possible scenarios to clean up the stack
upon @code{G}'s return. A calling convention is an agreed upon software
protocol whereby the responsibilities between the caller (@code{F}) and
the callee (@code{G}) are clearly defined. Several calling conventions
are available for Windows:

@itemize @bullet
@item
@code{C} (Microsoft defined)

@item
@code{Stdcall} (Microsoft defined)

@item
@code{DLL} (GNAT specific)
@end itemize

@node C Calling Convention
@subsection @code{C} Calling Convention

@noindent
This is the default calling convention used when interfacing to C/C++
routines compiled with either @code{gcc} or Microsoft Visual C++.

In the @code{C} calling convention subprogram parameters are pushed on the
stack by the caller from right to left. The caller itself is in charge of
cleaning up the stack after the call. In addition, the name of a routine
with @code{C} calling convention is mangled by adding a leading underscore.

The name to use on the Ada side when importing (or exporting) a routine
with @code{C} calling convention is the name of the routine. For
instance the C function:

@smallexample
int get_val (long);
@end smallexample

@noindent
should be imported from Ada as follows:

@smallexample
@group
@b{function} Get_Val (V : Interfaces.C.long) @b{return} Interfaces.C.int;
@b{pragma} Import (C, Get_Val, External_Name => "get_val");
@end group
@end smallexample

@noindent
Note that in this particular case the @code{External_Name} parameter could
have been omitted since, when missing, this parameter is taken to be the
name of the Ada entity in lower case. When the @code{Link_Name} parameter
is missing, as in the above example, this parameter is set to be the
@code{External_Name} with a leading underscore.

When importing a variable defined in C, you should always use the @code{C}
calling convention unless the object containing the variable is part of a
DLL (in which case you should use the @code{DLL} calling convention,
@pxref{DLL Calling Convention}).

@node Stdcall Calling Convention
@subsection @code{Stdcall} Calling Convention

@noindent
This convention, which was the calling convention used for Pascal
programs, is used by Microsoft for all the routines in the Win32 API for
efficiency reasons. It must be used to import any routine for which this
convention was specified.

In the @code{Stdcall} calling convention subprogram parameters are pushed
on the stack by the caller from right to left. The callee (and not the
caller) is in charge of cleaning the stack on routine exit. In addition,
the name of a routine with @code{Stdcall} calling convention is mangled by
adding a leading underscore (as for the @code{C} calling convention) and a
trailing @code{@@}@code{@i{nn}}, where @i{nn} is the overall size (in
bytes) of the parameters passed to the routine.

The name to use on the Ada side when importing a C routine with a
@code{Stdcall} calling convention is the name of the C routine. The leading
underscore and trailing @code{@@}@code{@i{nn}} are added automatically by
the compiler. For instance the Win32 function:

@smallexample
@b{APIENTRY} int get_val (long);
@end smallexample

@noindent
should be imported from Ada as follows:

@smallexample
@group
@b{function} Get_Val (V : Interfaces.C.long) @b{return} Interfaces.C.int;
@b{pragma} Import (Stdcall, Get_Val);
--  @i{On the x86 a long is 4 bytes, so the Link_Name is }"_get_val@@4"
@end group
@end smallexample

@noindent
As for the @code{C} calling convention, when the @code{External_Name}
parameter is missing, it is taken to be the name of the Ada entity in lower
case. If instead of writing the above import pragma you write:

@smallexample
@group
@b{function} Get_Val (V : Interfaces.C.long) @b{return} Interfaces.C.int;
@b{pragma} Import (Stdcall, Get_Val, External_Name => "retrieve_val");
@end group
@end smallexample

@noindent
then the imported routine is @code{_retrieve_val@@4}. However, if instead
of specifying the @code{External_Name} parameter you specify the
@code{Link_Name} as in the following example:

@smallexample
@group
@b{function} Get_Val (V : Interfaces.C.long) @b{return} Interfaces.C.int;
@b{pragma} Import (Stdcall, Get_Val, Link_Name => "retrieve_val");
@end group
@end smallexample

@noindent
then the imported routine is @code{retrieve_val@@4}, that is, there is no
trailing underscore but the appropriate @code{@@}@code{@i{nn}} is always
added at the end of the @code{Link_Name} by the compiler.

@noindent
Note, that in some special cases a DLL's entry point name lacks a trailing
@code{@@}@code{@i{nn}} while the exported name generated for a call has it.
The @code{gnatdll} tool, which creates the import library for the DLL, is able
to handle those cases (see the description of the switches in
@pxref{Using gnatdll} section).

@node DLL Calling Convention
@subsection @code{DLL} Calling Convention

@noindent
This convention, which is GNAT-specific, must be used when you want to
import in Ada a variables defined in a DLL. For functions and procedures
this convention is equivalent to the @code{Stdcall} convention. As an
example, if a DLL contains a variable defined as:

@smallexample
int my_var;
@end smallexample

@noindent
then, to access this variable from Ada you should write:

@smallexample
@group
My_Var : Interfaces.C.int;
@b{pragma} Import (DLL, My_Var);
@end group
@end smallexample

The remarks concerning the @code{External_Name} and @code{Link_Name}
parameters given in the previous sections equally apply to the @code{DLL}
calling convention.

@node Introduction to Dynamic Link Libraries (DLLs)
@section Introduction to Dynamic Link Libraries (DLLs)
@findex DLL

@noindent
A Dynamically Linked Library (DLL) is a library that can be shared by
several applications running under Windows. A DLL can contain any number of
routines and variables.

One advantage of DLLs is that you can change and enhance them without
forcing all the applications that depend on them to be relinked or
recompiled. However, you should be aware than all calls to DLL routines are
slower since, as you will understand below, such calls are indirect.

To illustrate the remainder of this section, suppose that an application
wants to use the services of a DLL @file{API.dll}. To use the services
provided by @file{API.dll} you must statically link against an import
library which contains a jump table with an entry for each routine and
variable exported by the DLL. In the Microsoft world this import library is
called @file{API.lib}. When using GNAT this import library is called either
@file{libAPI.a} or @file{libapi.a} (names are case insensitive).

After you have statically linked your application with the import library
and you run your application, here is what happens:

@enumerate
@item
Your application is loaded into memory.

@item
The DLL @file{API.dll} is mapped into the address space of your
application. This means that:

@itemize @bullet
@item
The DLL will use the stack of the calling thread.

@item
The DLL will use the virtual address space of the calling process.

@item
The DLL will allocate memory from the virtual address space of the calling
process.

@item
Handles (pointers) can be safely exchanged between routines in the DLL
routines and routines in the application using the DLL.
@end itemize

@item
The entries in the @file{libAPI.a} or @file{API.lib} jump table which is
part of your application are initialized with the addresses of the routines
and variables in @file{API.dll}.

@item
If present in @file{API.dll}, routines @code{DllMain} or
@code{DllMainCRTStartup} are invoked. These routines typically contain
the initialization code needed for the well-being of the routines and
variables exported by the DLL.
@end enumerate

@noindent
There is an additional point which is worth mentioning. In the Windows
world there are two kind of DLLs: relocatable and non-relocatable
DLLs. Non-relocatable DLLs can only be loaded at a very specific address
in the target application address space. If the addresses of two
non-relocatable DLLs overlap and these happen to be used by the same
application, a conflict will occur and the application will run
incorrectly. Hence, when possible, it is always preferable to use and
build relocatable DLLs. Both relocatable and non-relocatable DLLs are
supported by GNAT.

As a side note, an interesting difference between Microsoft DLLs and
Unix shared libraries, is the fact that on most Unix systems all public
routines are exported by default in a Unix shared library, while under
Windows the exported routines must be listed explicitly in a definition
file (@pxref{The Definition File}).

@node Using DLLs with GNAT
@section Using DLLs with GNAT

@menu
* Creating an Ada Spec for the DLL Services::
* Creating an Import Library::
@end menu

@noindent
To use the services of a DLL, say @file{API.dll}, in your Ada application
you must have:

@enumerate
@item
The Ada spec for the routines and/or variables you want to access in
@file{API.dll}. If not available this Ada spec must be built from the C/C++
header files provided with the DLL.

@item
The import library (@file{libAPI.a} or @file{API.lib}). As previously
mentioned an import library is a statically linked library containing the
import table which will be filled at load time to point to the actual
@file{API.dll} routines. Sometimes you don't have an import library for the
DLL you want to use. The following sections will explain how to build one.

@item
The actual DLL, @file{API.dll}.
@end enumerate

@noindent
Once you have all the above, to compile an Ada application that uses the
services of @file{API.dll} and whose main subprogram is @code{My_Ada_App},
you simply issue the command

@smallexample
$ gnatmake my_ada_app -largs -lAPI
@end smallexample

@noindent
The argument @code{-largs -lAPI} at the end of the @code{gnatmake} command
tells the GNAT linker to look first for a library named @file{API.lib}
(Microsoft-style name) and if not found for a library named @file{libAPI.a}
(GNAT-style name). Note that if the Ada package spec for @file{API.dll}
contains the following pragma

@smallexample
@b{pragma} Linker_Options ("-lAPI");
@end smallexample

@noindent
you do not have to add @code{-largs -lAPI} at the end of the @code{gnatmake}
command.

If any one of the items above is missing you will have to create it
yourself. The following sections explain how to do so using as an
example a fictitious DLL called @file{API.dll}.

@node Creating an Ada Spec for the DLL Services
@subsection Creating an Ada Spec for the DLL Services

@noindent
A DLL typically comes with a C/C++ header file which provides the
definitions of the routines and variables exported by the DLL. The Ada
equivalent of this header file is a package spec that contains definitions
for the imported entities. If the DLL you intend to use does not come with
an Ada spec you have to generate one such spec yourself. For example if
the header file of @file{API.dll} is a file @file{api.h} containing the
following two definitions:

@smallexample
@group
@cartouche
int some_var;
int get (char *);
@end cartouche
@end group
@end smallexample

@noindent
then the equivalent Ada spec could be:

@smallexample
@group
@cartouche
@b{with} Interfaces.C.Strings;
@b{package} API @b{is}
   @b{use} Interfaces;

   Some_Var : C.int;
   @b{function} Get (Str : C.Strings.Chars_Ptr) @b{return} C.int;

@b{private}
   @b{pragma} Import (C, Get);
   @b{pragma} Import (DLL, Some_Var);
@b{end} API;
@end cartouche
@end group
@end smallexample

@noindent
Note that a variable is @strong{always imported with a DLL convention}. A
function can have @code{C}, @code{Stdcall} or @code{DLL} convention. For
subprograms, the @code{DLL} convention is a synonym of @code{Stdcall}
(@pxref{Windows Calling Conventions}).

@node Creating an Import Library
@subsection Creating an Import Library
@cindex Import library

@menu
* The Definition File::
* GNAT-Style Import Library::
* Microsoft-Style Import Library::
@end menu

@noindent
If a Microsoft-style import library @file{API.lib} or a GNAT-style
import library @file{libAPI.a} is available with @file{API.dll} you
can skip this section. Otherwise read on.

@node The Definition File
@subsubsection The Definition File
@cindex Definition file
@findex .def

@noindent
As previously mentioned, and unlike Unix systems, the list of symbols
that are exported from a DLL must be provided explicitly in Windows.
The main goal of a definition file is precisely that: list the symbols
exported by a DLL. A definition file (usually a file with a @code{.def}
suffix) has the following structure:

@smallexample
@group
@cartouche
[LIBRARY @i{name}]
[DESCRIPTION @i{string}]
EXPORTS
   @i{symbol1}
   @i{symbol2}
   ...
@end cartouche
@end group
@end smallexample

@table @code
@item LIBRARY @i{name}
This section, which is optional, gives the name of the DLL.

@item DESCRIPTION @i{string}
This section, which is optional, gives a description string that will be
embedded in the import library.

@item EXPORTS
This section gives the list of exported symbols (procedures, functions or
variables). For instance in the case of @file{API.dll} the @code{EXPORTS}
section of @file{API.def} looks like:

@smallexample
@group
@cartouche
EXPORTS
   some_var
   get
@end cartouche
@end group
@end smallexample
@end table

@noindent
Note that you must specify the correct suffix (@code{@@}@code{@i{nn}})
(@pxref{Windows Calling Conventions}) for a Stdcall
calling convention function in the exported symbols list.

@noindent
There can actually be other sections in a definition file, but these
sections are not relevant to the discussion at hand.

@node GNAT-Style Import Library
@subsubsection GNAT-Style Import Library

@noindent
To create a static import library from @file{API.dll} with the GNAT tools
you should proceed as follows:

@enumerate
@item
Create the definition file @file{API.def} (@pxref{The Definition File}).
For that use the @code{dll2def} tool as follows:

@smallexample
$ dll2def API.dll > API.def
@end smallexample

@noindent
@code{dll2def} is a very simple tool: it takes as input a DLL and prints
to standard output the list of entry points in the DLL. Note that if
some routines in the DLL have the @code{Stdcall} convention
(@pxref{Windows Calling Conventions}) with stripped @code{@@}@i{nn}
suffix then you'll have to edit @file{api.def} to add it.

@noindent
Here are some hints to find the right @code{@@}@i{nn} suffix.

@enumerate
@item
If you have the Microsoft import library (.lib), it is possible to get
the right symbols by using Microsoft @code{dumpbin} tool (see the
corresponding Microsoft documentation for further details).

@smallexample
$ dumpbin /exports api.lib
@end smallexample

@item
If you have a message about a missing symbol at link time the compiler
tells you what symbol is expected. You just have to go back to the
definition file and add the right suffix.
@end enumerate

@item
Build the import library @code{libAPI.a}, using @code{gnatdll}
(@pxref{Using gnatdll}) as follows:

@smallexample
$ gnatdll -e API.def -d API.dll
@end smallexample

@noindent
@code{gnatdll} takes as input a definition file @file{API.def} and the
name of the DLL containing the services listed in the definition file
@file{API.dll}. The name of the static import library generated is
computed from the name of the definition file as follows: if the
definition file name is @i{xyz}@code{.def}, the import library name will
be @code{lib}@i{xyz}@code{.a}. Note that in the previous example option
@code{-e} could have been removed because the name of the definition
file (before the "@code{.def}" suffix) is the same as the name of the
DLL (@pxref{Using gnatdll} for more information about @code{gnatdll}).
@end enumerate

@node Microsoft-Style Import Library
@subsubsection Microsoft-Style Import Library

@noindent
With GNAT you can either use a GNAT-style or Microsoft-style import
library. A Microsoft import library is needed only if you plan to make an
Ada DLL available to applications developed with Microsoft
tools (@pxref{Mixed-Language Programming on Windows}).

To create a Microsoft-style import library for @file{API.dll} you
should proceed as follows:

@enumerate
@item
Create the definition file @file{API.def} from the DLL. For this use either
the @code{dll2def} tool as described above or the Microsoft @code{dumpbin}
tool (see the corresponding Microsoft documentation for further details).

@item
Build the actual import library using Microsoft's @code{lib} utility:

@smallexample
$ lib -machine:IX86 -def:API.def -out:API.lib
@end smallexample

@noindent
If you use the above command the definition file @file{API.def} must
contain a line giving the name of the DLL:

@smallexample
LIBRARY      "API"
@end smallexample

@noindent
See the Microsoft documentation for further details about the usage of
@code{lib}.
@end enumerate

@node Building DLLs with GNAT
@section Building DLLs with GNAT
@cindex DLLs, building

@menu
* Limitations When Using Ada DLLs from Ada::
* Exporting Ada Entities::
* Ada DLLs and Elaboration::
* Ada DLLs and Finalization::
* Creating a Spec for Ada DLLs::
* Creating the Definition File::
* Using gnatdll::
@end menu

@noindent
This section explains how to build DLLs containing Ada code. These DLLs
will be referred to as Ada DLLs in the remainder of this section.

The steps required to build an Ada DLL that is to be used by Ada as well as
non-Ada applications are as follows:

@enumerate
@item
You need to mark each Ada @i{entity} exported by the DLL with a @code{C} or
@code{Stdcall} calling convention to avoid any Ada name mangling for the
entities exported by the DLL (@pxref{Exporting Ada Entities}). You can
skip this step if you plan to use the Ada DLL only from Ada applications.

@item
Your Ada code must export an initialization routine which calls the routine
@code{adainit} generated by @code{gnatbind} to perform the elaboration of
the Ada code in the DLL (@pxref{Ada DLLs and Elaboration}). The initialization
routine exported by the Ada DLL must be invoked by the clients of the DLL
to initialize the DLL.

@item
When useful, the DLL should also export a finalization routine which calls
routine @code{adafinal} generated by @code{gnatbind} to perform the
finalization of the Ada code in the DLL (@pxref{Ada DLLs and Finalization}).
The finalization routine exported by the Ada DLL must be invoked by the
clients of the DLL when the DLL services are no further needed.

@item
You must provide a spec for the services exported by the Ada DLL in each
of the programming languages to which you plan to make the DLL available.

@item
You must provide a definition file listing the exported entities
(@pxref{The Definition File}).

@item
Finally you must use @code{gnatdll} to produce the DLL and the import
library (@pxref{Using gnatdll}).
@end enumerate

@node Limitations When Using Ada DLLs from Ada
@subsection Limitations When Using Ada DLLs from Ada

@noindent
When using Ada DLLs from Ada applications there is a limitation users
should be aware of. Because on Windows the GNAT run time is not in a DLL of
its own, each Ada DLL includes a part of the GNAT run time. Specifically,
each Ada DLL includes the services of the GNAT run time that are necessary
to the Ada code inside the DLL. As a result, when an Ada program uses an
Ada DLL there are two independent GNAT run times: one in the Ada DLL and
one in the main program.

It is therefore not possible to exchange GNAT run-time objects between the
Ada DLL and the main Ada program. Example of GNAT run-time objects are file
handles (e.g. @code{Text_IO.File_Type}), tasks types, protected objects
types, etc.

It is completely safe to exchange plain elementary, array or record types,
Windows object handles, etc.

@node Exporting Ada Entities
@subsection Exporting Ada Entities
@cindex Export table

@noindent
Building a DLL is a way to encapsulate a set of services usable from any
application. As a result, the Ada entities exported by a DLL should be
exported with the @code{C} or @code{Stdcall} calling conventions to avoid
any Ada name mangling. Please note that the @code{Stdcall} convention
should only be used for subprograms, not for variables. As an example here
is an Ada package @code{API}, spec and body, exporting two procedures, a
function, and a variable:

@smallexample
@group
@cartouche
@b{with} Interfaces.C; @b{use} Interfaces;
@b{package} API @b{is}
   Count : C.int := 0;
   @b{function} Factorial (Val : C.int) @b{return} C.int;

   @b{procedure} Initialize_API;
   @b{procedure} Finalize_API;
   --  @i{Initialization & Finalization routines. More in the next section.}
@b{private}
   @b{pragma} Export (C, Initialize_API);
   @b{pragma} Export (C, Finalize_API);
   @b{pragma} Export (C, Count);
   @b{pragma} Export (C, Factorial);
@b{end} API;
@end cartouche
@end group
@end smallexample

@smallexample
@group
@cartouche
@b{package body} API @b{is}
   @b{function} Factorial (Val : C.int) @b{return} C.int @b{is}
      Fact : C.int := 1;
   @b{begin}
      Count := Count + 1;
      @b{for} K @b{in} 1 .. Val @b{loop}
         Fact := Fact * K;
      @b{end loop};
      @b{return} Fact;
   @b{end} Factorial;

   @b{procedure} Initialize_API @b{is}
      @b{procedure} Adainit;
      @b{pragma} Import (C, Adainit);
   @b{begin}
      Adainit;
   @b{end} Initialize_API;

   @b{procedure} Finalize_API @b{is}
      @b{procedure} Adafinal;
      @b{pragma} Import (C, Adafinal);
   @b{begin}
      Adafinal;
   @b{end} Finalize_API;
@b{end} API;
@end cartouche
@end group
@end smallexample

@noindent
If the Ada DLL you are building will only be used by Ada applications
you do not have to export Ada entities with a @code{C} or @code{Stdcall}
convention. As an example, the previous package could be written as
follows:

@smallexample
@group
@cartouche
@b{package} API @b{is}
   Count : Integer := 0;
   @b{function} Factorial (Val : Integer) @b{return} Integer;

   @b{procedure} Initialize_API;
   @b{procedure} Finalize_API;
   --  @i{Initialization and Finalization routines.}
@b{end} API;
@end cartouche
@end group
@end smallexample

@smallexample
@group
@cartouche
@b{package body} API @b{is}
   @b{function} Factorial (Val : Integer) @b{return} Integer @b{is}
      Fact : Integer := 1;
   @b{begin}
      Count := Count + 1;
      @b{for} K @b{in} 1 .. Val @b{loop}
         Fact := Fact * K;
      @b{end loop};
      @b{return} Fact;
      @b{end} Factorial;

   ...
   --  @i{The remainder of this package body is unchanged.}
@b{end} API;
@end cartouche
@end group
@end smallexample

@noindent
Note that if you do not export the Ada entities with a @code{C} or
@code{Stdcall} convention you will have to provide the mangled Ada names
in the definition file of the Ada DLL
(@pxref{Creating the Definition File}).

@node Ada DLLs and Elaboration
@subsection Ada DLLs and Elaboration
@cindex DLLs and elaboration

@noindent
The DLL that you are building contains your Ada code as well as all the
routines in the Ada library that are needed by it. The first thing a
user of your DLL must do is elaborate the Ada code
(@pxref{Elaboration Order Handling in GNAT}).

To achieve this you must export an initialization routine
(@code{Initialize_API} in the previous example), which must be invoked
before using any of the DLL services. This elaboration routine must call
the Ada elaboration routine @code{adainit} generated by the GNAT binder
(@pxref{Binding with Non-Ada Main Programs}). See the body of
@code{Initialize_Api} for an example. Note that the GNAT binder is
automatically invoked during the DLL build process by the @code{gnatdll}
tool (@pxref{Using gnatdll}).

When a DLL is loaded, Windows systematically invokes a routine called
@code{DllMain}. It would therefore be possible to call @code{adainit}
directly from @code{DllMain} without having to provide an explicit
initialization routine. Unfortunately, it is not possible to call
@code{adainit} from the @code{DllMain} if your program has library level
tasks because access to the @code{DllMain} entry point is serialized by
the system (that is, only a single thread can execute "through" it at a
time), which means that the GNAT run time will deadlock waiting for the
newly created task to complete its initialization.

@node Ada DLLs and Finalization
@subsection Ada DLLs and Finalization
@cindex DLLs and finalization

@noindent
When the services of an Ada DLL are no longer needed, the client code should
invoke the DLL finalization routine, if available. The DLL finalization
routine is in charge of releasing all resources acquired by the DLL. In the
case of the Ada code contained in the DLL, this is achieved by calling
routine @code{adafinal} generated by the GNAT binder
(@pxref{Binding with Non-Ada Main Programs}).
See the body of @code{Finalize_Api} for an
example. As already pointed out the GNAT binder is automatically invoked
during the DLL build process by the @code{gnatdll} tool
(@pxref{Using gnatdll}).

@code{-g}
@cindex @code{-g} (@code{gnatdll})
@*
Generate debugging information. This information is stored in the object
file and copied from there to the final DLL file by the linker,
where it can be read by the debugger. You must use the
@code{-g} switch if you plan on using the debugger or the symbolic
stack traceback.

@node Creating a Spec for Ada DLLs
@subsection Creating a Spec for Ada DLLs

@noindent
To use the services exported by the Ada DLL from another programming
language (e.g. C), you have to translate the specs of the exported Ada
entities in that language. For instance in the case of @code{API.dll},
the corresponding C header file could look like:

@smallexample
@group
@cartouche
extern int *__imp__count;
#define count (*__imp__count)
int factorial (int);
@end cartouche
@end group
@end smallexample

@noindent
It is important to understand that when building an Ada DLL to be used by
other Ada applications, you need two different specs for the packages
contained in the DLL: one for building the DLL and the other for using
the DLL. This is because the @code{DLL} calling convention is needed to
use a variable defined in a DLL, but when building the DLL, the variable
must have either the @code{Ada} or @code{C} calling convention. As an
example consider a DLL comprising the following package @code{API}:

@smallexample
@group
@cartouche
@b{package} API @b{is}
   Count : Integer := 0;
   ...
   --  @i{Remainder of the package omitted.}
@b{end} API;
@end cartouche
@end group
@end smallexample

@noindent
After producing a DLL containing package @code{API}, the spec that
must be used to import @code{API.Count} from Ada code outside of the
DLL is:

@smallexample
@group
@cartouche
@b{package} API @b{is}
   Count : Integer;
   @b{pragma} Import (DLL, Count);
@b{end} API;
@end cartouche
@end group
@end smallexample

@node Creating the Definition File
@subsection Creating the Definition File

@noindent
The definition file is the last file needed to build the DLL. It lists
the exported symbols. As an example, the definition file for a DLL
containing only package @code{API} (where all the entities are exported
with a @code{C} calling convention) is:

@smallexample
@group
@cartouche
EXPORTS
    count
    factorial
    finalize_api
    initialize_api
@end cartouche
@end group
@end smallexample

@noindent
If the @code{C} calling convention is missing from package @code{API},
then the definition file contains the mangled Ada names of the above
entities, which in this case are:

@smallexample
@group
@cartouche
EXPORTS
    api__count
    api__factorial
    api__finalize_api
    api__initialize_api
@end cartouche
@end group
@end smallexample

@node Using gnatdll
@subsection Using @code{gnatdll}
@findex gnatdll

@menu
* gnatdll Example::
* gnatdll behind the Scenes::
* Using dlltool::
@end menu

@noindent
@code{gnatdll} is a tool to automate the DLL build process once all the Ada
and non-Ada sources that make up your DLL have been compiled.
@code{gnatdll} is actually in charge of two distinct tasks: build the
static import library for the DLL and the actual DLL. The form of the
@code{gnatdll} command is

@smallexample
@cartouche
$ gnatdll [@var{switches}] @var{list-of-files} [-largs @var{opts}]
@end cartouche
@end smallexample

@noindent
where @i{list-of-files} is a list of ALI and object files. The object
file list must be the exact list of objects corresponding to the non-Ada
sources whose services are to be included in the DLL. The ALI file list
must be the exact list of ALI files for the corresponding Ada sources
whose services are to be included in the DLL. If @i{list-of-files} is
missing, only the static import library is generated.

@noindent
You may specify any of the following switches to @code{gnatdll}:

@table @code
@item -a[@var{address}]
@cindex @code{-a} (@code{gnatdll})
Build a non-relocatable DLL at @var{address}. If @var{address} is not
specified the default address @var{0x11000000} will be used. By default,
when this switch is missing, @code{gnatdll} builds relocatable DLL. We
advise the reader to build relocatable DLL.

@item -b @var{address}
@cindex @code{-b} (@code{gnatdll})
Set the relocatable DLL base address. By default the address is
@var{0x11000000}.

@item -d @var{dllfile}
@cindex @code{-d} (@code{gnatdll})
@var{dllfile} is the name of the DLL. This switch must be present for
@code{gnatdll} to do anything. The name of the generated import library is
obtained algorithmically from @var{dllfile} as shown in the following
example: if @var{dllfile} is @code{xyz.dll}, the import library name is
@code{libxyz.a}. The name of the definition file to use (if not specified
by option @code{-e}) is obtained algorithmically from @var{dllfile} as shown in
the following example: if @var{dllfile} is @code{xyz.dll}, the definition
file used is @code{xyz.def}.

@item -e @var{deffile}
@cindex @code{-e} (@code{gnatdll})
@var{deffile} is the name of the definition file.

@item -h
@cindex @code{-h} (@code{gnatdll})
Help mode. Displays @code{gnatdll} switch usage information.

@item -Idir
Direct @code{gnatdll} to search the @var{dir} directory for source and
object files needed to build the DLL.
(@pxref{Search Paths and the Run-Time Library (RTL)}).

@item -k
Removes the @code{@@}@i{nn} suffix from the import library's exported
names. You must specified this option if you want to use a
@code{Stdcall} function in a DLL for which the @code{@@}@i{nn} suffix
has been removed. This is the case for most of the Windows NT DLL for
example. This option has no effect when @code{-n} option is specified.

@item -l @var{file}
@cindex @code{-l} (@code{gnatdll})
The list of ALI and object files used to build the DLL are listed in
@var{file}, instead of being given in the command line. Each line in
@var{file} contains the name of an ALI or object file.

@item -n
@cindex @code{-n} (@code{gnatdll})
No Import. Do not create the import library.

@item -q
@cindex @code{-q} (@code{gnatdll})
Quiet mode. Do not display unnecessary messages.

@item -v
@cindex @code{-v} (@code{gnatdll})
Verbose mode. Display extra information.

@item -largs @var{opts}
@cindex @code{-largs} (@code{gnatdll})
Linker options. Pass @var{opts} to the linker.
@end table

@node gnatdll Example
@subsubsection @code{gnatdll} Example

@noindent
As an example the command to build a relocatable DLL from @file{api.adb}
once @file{api.adb} has been compiled and @file{api.def} created is

@smallexample
$ gnatdll -d api.dll api.ali
@end smallexample

@noindent
The above command creates two files: @file{libapi.a} (the import
library) and @file{api.dll} (the actual DLL). If you want to create
only the DLL, just type:

@smallexample
$ gnatdll -d api.dll -n api.ali
@end smallexample

@noindent
Alternatively if you want to create just the import library, type:

@smallexample
$ gnatdll -d api.dll
@end smallexample

@node gnatdll behind the Scenes
@subsubsection @code{gnatdll} behind the Scenes

@noindent
This section details the steps involved in creating a DLL. @code{gnatdll}
does these steps for you. Unless you are interested in understanding what
goes on behind the scenes, you should skip this section.

We use the previous example of a DLL containing the Ada package @code{API},
to illustrate the steps necessary to build a DLL. The starting point is a
set of objects that will make up the DLL and the corresponding ALI
files. In the case of this example this means that @file{api.o} and
@file{api.ali} are available. To build a relocatable DLL, @code{gnatdll} does
the following:

@enumerate
@item
@code{gnatdll} builds the base file (@file{api.base}). A base file gives
the information necessary to generate relocation information for the
DLL.

@smallexample
@group
$ gnatbind -n api
$ gnatlink api -o api.jnk -mdll -Wl,--base-file,api.base
@end group
@end smallexample

@noindent
In addition to the base file, the @code{gnatlink} command generates an
output file @file{api.jnk} which can be discarded. The @code{-mdll} switch
asks @code{gnatlink} to generate the routines @code{DllMain} and
@code{DllMainCRTStartup} that are called by the Windows loader when the DLL
is loaded into memory.

@item
@code{gnatdll} uses @code{dlltool} (@pxref{Using dlltool}) to build the
export table (@file{api.exp}). The export table contains the relocation
information in a form which can be used during the final link to ensure
that the Windows loader is able to place the DLL anywhere in memory.

@smallexample
@group
$ dlltool --dllname api.dll --def api.def --base-file api.base \
          --output-exp api.exp
@end group
@end smallexample

@item
@code{gnatdll} builds the base file using the new export table. Note that
@code{gnatbind} must be called once again since the binder generated file
has been deleted during the previous call to @code{gnatlink}.

@smallexample
@group
$ gnatbind -n api
$ gnatlink api -o api.jnk api.exp -mdll
      -Wl,--base-file,api.base
@end group
@end smallexample

@item
@code{gnatdll} builds the new export table using the new base file and
generates the DLL import library @file{libAPI.a}.

@smallexample
@group
$ dlltool --dllname api.dll --def api.def --base-file api.base \
          --output-exp api.exp --output-lib libAPI.a
@end group
@end smallexample

@item
Finally @code{gnatdll} builds the relocatable DLL using the final export
table.

@smallexample
@group
$ gnatbind -n api
$ gnatlink api api.exp -o api.dll -mdll
@end group
@end smallexample
@end enumerate

@node Using dlltool
@subsubsection Using @code{dlltool}

@noindent
@code{dlltool} is the low-level tool used by @code{gnatdll} to build
DLLs and static import libraries. This section summarizes the most
common @code{dlltool} switches. The form of the @code{dlltool} command
is

@smallexample
$ dlltool [@var{switches}]
@end smallexample

@noindent
@code{dlltool} switches include:

@table @code
@item --base-file @var{basefile}
Read the base file @var{basefile} generated by the linker. This switch
is used to create a relocatable DLL.

@item --def @var{deffile}
Read the definition file.

@item --dllname @var{name}
Gives the name of the DLL. This switch is used to embed the name of the
DLL in the static import library generated by @code{dlltool} with switch
@code{--output-lib}.

@item -k
Kill @code{@@}@i{nn} from exported names
(@pxref{Windows Calling Conventions}
for a discussion about @code{Stdcall}-style symbols.

@item --help
Prints the @code{dlltool} switches with a concise description.

@item --output-exp @var{exportfile}
Generate an export file @var{exportfile}. The export file contains the
export table (list of symbols in the DLL) and is used to create the DLL.

@item --output-lib @i{libfile}
Generate a static import library @var{libfile}.

@item -v
Verbose mode.

@item --as @i{assembler-name}
Use @i{assembler-name} as the assembler. The default is @code{as}.
@end table

@node GNAT and Windows Resources
@section GNAT and Windows Resources
@cindex Resources, windows

@menu
* Building Resources::
* Compiling Resources::
* Using Resources::
* Limitations::
@end menu

@noindent
Resources are an easy way to add Windows specific objects to your
application. The objects that can be added as resources include:

@itemize @bullet
@item
menus

@item
accelerators

@item
dialog boxes

@item
string tables

@item
bitmaps

@item
cursors

@item
icons

@item
fonts
@end itemize

@noindent
This section explains how to build, compile and use resources.

@node Building Resources
@subsection Building Resources
@cindex Resources, building

@noindent
A resource file is an ASCII file. By convention resource files have an
@file{.rc} extension.
The easiest way to build a resource file is to use Microsoft tools
such as @code{imagedit.exe} to build bitmaps, icons and cursors and
@code{dlgedit.exe} to build dialogs.
It is always possible to build an @file{.rc} file yourself by writing a
resource script.

It is not our objective to explain how to write a resource file. A
complete description of the resource script language can be found in the
Microsoft documentation.

@node Compiling Resources
@subsection Compiling Resources
@findex rc
@findex rcl
@findex res2coff
@cindex Resources, compiling

@noindent
This section describes how to build a GNAT-compatible (COFF) object file
containing the resources. This is done using the Resource Compiler
@code{rcl} as follows:

@smallexample
$ rcl -i myres.rc -o myres.o
@end smallexample

@noindent
By default @code{rcl} will run @code{gcc} to preprocess the @file{.rc}
file. You can specify an alternate preprocessor (usually named
@file{cpp.exe}) using the @code{rcl} @code{-cpp} parameter. A list of
all possible options may be obtained by entering the command @code{rcl}
with no parameters.

It is also possible to use the Microsoft resource compiler @code{rc.exe}
to produce a @file{.res} file (binary resource file). See the
corresponding Microsoft documentation for further details. In this case
you need to use @code{res2coff} to translate the @file{.res} file to a
GNAT-compatible object file as follows:

@smallexample
$ res2coff -i myres.res -o myres.o
@end smallexample

@node Using Resources
@subsection Using Resources
@cindex Resources, using

@noindent
To include the resource file in your program just add the
GNAT-compatible object file for the resource(s) to the linker
arguments. With @code{gnatmake} this is done by using the @code{-largs}
option:

@smallexample
$ gnatmake myprog -largs myres.o
@end smallexample

@node Limitations
@subsection Limitations
@cindex Resources, limitations

@noindent
In this section we describe the current limitations together with
suggestions for workarounds.

@itemize @bullet
@item
@code{rcl} does not handle the @code{RCINCLUDE} directive.
@*
Workaround: replace @code{RCINCLUDE} by an @code{#include} directive.

@item
@code{rcl} does not handle the brackets as block delimiters.
@*
Workaround: replace character '@{' by @code{BEGIN} and '@}' by
@code{END}. Note that Microsoft's @code{rc} handles both forms of block
delimiters.

@item
@code{rcl} does not handle @code{TypeLib} resources. This type of
resource is used to build COM, DCOM or ActiveX objects.
@*
Workaround: use @code{rc}, the Microsoft resource compiler.

@item
It is not possible to use @code{strip} to remove the debugging symbols
from a program with resources.
@*
Workaround: use linker option @code{-s} to strip debugging symbols from
the final executable.
@end itemize

@node Debugging a DLL
@section Debugging a DLL
@cindex DLL debugging

@menu
* The Program and the DLL Are Built with GCC/GNAT::
* The Program Is Built with Some Foreign Tools and the DLL Is Built with GCC/GNAT::
@end menu

@noindent
Debugging a DLL is similar to debugging a standard program. But
we have to deal with two different executable parts: the DLL and the
program that uses it. We have the following four possibilities:

@enumerate 1
@item
The program and the DLL are built with @code{GCC/GNAT}.
@item
The program is built with foreign tools and the DLL is built with
@code{GCC/GNAT}.
@item
The program is built with @code{GCC/GNAT} and the DLL is built with
foreign tools.
@item
@end enumerate

@noindent
In this section we address only cases one and two above.
There is no point in trying to debug
a DLL with @code{GNU/GDB}, if there is no GDB-compatible debugging
information in it. To do so you must use a debugger compatible with the
tools suite used to build the DLL.

@node The Program and the DLL Are Built with GCC/GNAT
@subsection The Program and the DLL Are Built with GCC/GNAT

@noindent
This is the simplest case. Both the DLL and the program have @code{GDB}
compatible debugging information. It is then possible to break anywhere in
the process. Let's suppose here that the main procedure is named
@code{ada_main} and that in the DLL there is an entry point named
@code{ada_dll}.

@noindent
The DLL (@pxref{Introduction to Dynamic Link Libraries (DLLs)}) and
program must have been built with the debugging information (see GNAT -g
switch). Here are the step-by-step instructions for debugging it:

@enumerate 1
@item Launch @code{GDB} on the main program.

@smallexample
$ gdb -nw ada_main
@end smallexample

@item Break on the main procedure and run the program.

@smallexample
(gdb) break ada_main
(gdb) run
@end smallexample

@noindent
This step is required to be able to set a breakpoint inside the DLL. As long
as the program is not run, the DLL is not loaded. This has the
consequence that the DLL debugging information is also not loaded, so it is not
possible to set a breakpoint in the DLL.

@item Set a breakpoint inside the DLL

@smallexample
(gdb) break ada_dll
(gdb) run
@end smallexample

@end enumerate

@noindent
At this stage a breakpoint is set inside the DLL. From there on
you can use the standard approach to debug the whole program
(@pxref{Running and Debugging Ada Programs}).

@node The Program Is Built with Some Foreign Tools and the DLL Is Built with GCC/GNAT
@subsection The Program Is Built with Some Foreign Tools and the DLL Is Built with GCC/GNAT

@menu
* Debugging the DLL Directly::
* Attaching to a Running Process::
@end menu

@noindent
In this case things are slightly more complex because it is not possible to
start the main program and then break at the beginning to load the DLL and the
associated DLL debugging information. It is not possible to break at the
beginning of the program because there is no @code{GDB} debugging information,
and therefore there is no direct way of getting initial control. This
section addresses this issue by describing some methods that can be used
to break somewhere in the DLL to debug it.

@noindent
First suppose that the main procedure is named @code{main} (this is for
example some C code built with Microsoft Visual C) and that there is a
DLL named @code{test.dll} containing an Ada entry point named
@code{ada_dll}.

@noindent
The DLL (@pxref{Introduction to Dynamic Link Libraries (DLLs)}) must have
been built with debugging information (see GNAT -g option).

@node Debugging the DLL Directly
@subsubsection Debugging the DLL Directly

@enumerate 1
@item
Launch the debugger on the DLL.

@smallexample
$ gdb -nw test.dll
@end smallexample

@item Set a breakpoint on a DLL subroutine.

@smallexample
(gdb) break ada_dll
@end smallexample

@item
Specify the executable file to @code{GDB}.

@smallexample
(gdb) exec-file main.exe
@end smallexample

@item
Run the program.

@smallexample
(gdb) run
@end smallexample

@noindent
This will run the program until it reaches the breakpoint that has been
set. From that point you can use the standard way to debug a program
as described in (@pxref{Running and Debugging Ada Programs}).

@end enumerate

@noindent
It is also possible to debug the DLL by attaching to a running process.

@node Attaching to a Running Process
@subsubsection Attaching to a Running Process
@cindex DLL debugging, attach to process

@noindent
With @code{GDB} it is always possible to debug a running process by
attaching to it. It is possible to debug a DLL this way. The limitation
of this approach is that the DLL must run long enough to perform the
attach operation. It may be useful for instance to insert a time wasting
loop in the code of the DLL to meet this criterion.

@enumerate 1

@item Launch the main program @file{main.exe}.

@smallexample
$ main
@end smallexample

@item Use the Windows @i{Task Manager} to find the process ID. Let's say
that the process PID for @file{main.exe} is 208.

@item Launch gdb.

@smallexample
$ gdb -nw
@end smallexample

@item Attach to the running process to be debugged.

@smallexample
(gdb) attach 208
@end smallexample

@item Load the process debugging information.

@smallexample
(gdb) symbol-file main.exe
@end smallexample

@item Break somewhere in the DLL.

@smallexample
(gdb) break ada_dll
@end smallexample

@item Continue process execution.

@smallexample
(gdb) continue
@end smallexample

@end enumerate

@noindent
This last step will resume the process execution, and stop at
the breakpoint we have set. From there you can use the standard
approach to debug a program as described in
(@pxref{Running and Debugging Ada Programs}).

@node GNAT and COM/DCOM Objects
@section GNAT and COM/DCOM Objects
@findex COM
@findex DCOM

@noindent
This section is temporarily left blank.

@ignore
@reread
???????????? WE NEED TO DECIDE WHETHER TO DISTRIBUTE IT ??????????????????????

@node gnatreg : Registry Tool for NT
@section @code{gnatreg} : Registry Tool for NT
@findex gnatreg
@cindex Registry

@menu
* Changing the GNAT compiler to Use::
* Adding/Changing a Library Path::
* Removing a Library Path::
* List Current Configuration::
@end menu

@noindent
This tool can be used to switch from one compiler to another and to manage
the list of directories where GNAT must look to find packages. It is
also a convenient way to do network installation of GNAT.

The form of the @code{gnatreg} command is

@smallexample
$ gnatreg [@var{-hqcarf}] parameter
@end smallexample

@noindent
Commons options are

@table @code

@item -h
print a usage message.

@item -q
quiet/terse - display nothing, just do the job.

@item -f
force mode - create the registry keys if they do not
exist. @code{gnatreg} will exit with an error if this option is omitted
and some registry keys are not setup correctly.

@end table

@subsection Changing the GNAT compiler to use

@smallexample
$ gnatreg c:\gnatpro
@end smallexample

@noindent
This will setup the registry to use the GNAT compiler that has been
installed under c:\gnatpro. @code{gnatreg} check that this directory contain
effectively a GNAT compiler. If you want to setup a network installation
and if GNAT has never been installed on this computer you'll have to use
the -f option.

@subsection Adding/Changing a library path

@smallexample
$ gnatreg -a COMPNT=c:\ada\components
@end smallexample

@noindent
Add the directory c:\ada\components to the list of standards libraries. When
running gnatmake the option -Ic:\ada\components is added automatically to the
command line.

The directory c:\ada\components is associated with the name COMPNT. This
name will be used to remove the library path.

@subsection Removing a library path

@smallexample
$ gnatreg -r COMPNT
@end smallexample

@noindent
Remove the library path named COMPNT.

@subsection List current configuration

@smallexample
$ gnatreg -c
@end smallexample

@noindent
@code{gnatreg} will display the GNAT and AdaGIDE path used and
all the standards libraries and their associated names that have been set.

@end ignore
@end ifset

@ifset vxworks
@node VxWorks Topics
@chapter VxWorks Topics

@noindent
This chapter describes topics that are specific to the GNAT for VxWorks
configurations.

@menu
* Kernel Configuration for VxWorks::
* Kernel Compilation Issues for VxWorks::
* Handling Relocation Issues for PowerPc Targets::
* Support for Software Floating Point on PowerPC Processors::
* Interrupt Handling for VxWorks::
* Simulating Command Line Arguments for VxWorks::
* Debugging Issues for VxWorks::
* Using GNAT from the Tornado 2 Project Facility::
* Frequently Asked Questions for VxWorks::
@end menu

@node Kernel Configuration for VxWorks
@section Kernel Configuration for VxWorks

@noindent
When configuring your VxWorks kernel we recommend including the target
shell. If you omit it from the configuration, you may get undefined
symbols at load time, e.g.

@smallexample
-> ld < hello.exe
Loading hello.exe
Undefined symbols:
mkdir
@end smallexample

@noindent
Generally, such undefined symbols are harmless since these are used by
optional parts of the GNAT run time. However if running your application
generates a VxWorks exception or illegal instruction, you should reconfigure
your kernel to resolve these symbols.

@node Kernel Compilation Issues for VxWorks
@section Kernel Compilation Issues for VxWorks

@noindent
If you plan to link an Ada module with a Tornado 2 Kernel, follow these steps.
(Note that these recommendations apply to @file{cygnus-2.7.2-960126},
shipped with Tornado 2 as the C compiler toolchain.)

@itemize @bullet
@item
Compile your Ada module without linking it with the VxWorks Library:
@smallexample
gnatmake foo.adb -largs -nostdlib
@end smallexample

@item
Edit your makefile and add on the @code{LIBS} line the exact path and name
of the GCC library file provided with GNAT.
@smallexample
LIBS             = $(WIND_BASE)/target/lib/libPPC604gnuvx.a \
/opt/gnu/gnat/lib/gcc-lib/powerpc-wrs-vxworks/2.8.1/libgcc.a
@end smallexample

@noindent
To know the exact name and location of this file, type
@code{<arch>-gcc -print-libgcc-file-name} in a console. Note that this version of GCC is the
one provided with GNAT.
@smallexample
~ >powerpc-wrs-vxworks-gcc -print-libgcc-file-name
/opt/gnu/gnat/lib/gcc-lib/powerpc-wrs-vxworks/2.8.1/libgcc.a
@end smallexample
@end itemize


@node Handling Relocation Issues for PowerPc Targets
@section Handling Relocation Issues for PowerPc Targets
@cindex Relocation issues for PowerPc VxWorks targets
@cindex PowerPc VxWorks, relocation issues
@cindex VxWorks PowerPc, relocation issues

@noindent
Under certain circumstances, loading a program onto a PowerPC
board will fail with the message
@emph{Relocation value does not fit in 24 bits}.

For some background on this issue, please refer to WRS' SPRs
6040, 20257, and 22767.
In summary,
VxWorks on the PowerPC follows the variation of the SVR4 ABI known
as the Embedded ABI (@emph{EABI}).
@cindex Embedded ABI (for VxWorks on PowerPc)
@cindex EABI (for VxWorks on PowerPc)
In order to save space and time in
embedded applications, the EABI specifies that the default for
subprogram calls should be the branch instruction with relative
addressing using an immediate operand.  The immediate operand
to this instruction (relative address) is 24 bits wide.  It
is sign extended and 2#00# is appended for the last 2 bits (all
instructions must be on a 4 byte boundary).
The resulting
26 bit offset means that the target of the branch must be within
+/- 32 Mbytes of the relative branch instruction.  When VxWorks
is loading a program it completes the linking phase by
resolving all of the unresolved references in the object being
loaded.  When one of those references is a relative address in
a branch instruction, and the linker determines that the target
is more than 32 Mbytes away from the branch, the error occurs.

This only happens when the BSP is configured to use
more than 32 MBytes of memory.  The VxWorks kernel is loaded into
low memory addresses, and the error usually occurs when the target
loader is used (because it loads objects into high memory, and thus
calls from the program to the VxWorks kernel can be too far).
@cindex VxWorks kernel (relocation issues on PowerPc)

One way to solve this problem is to use the Tornado
host loader; this will place programs in low memory, close to the kernel.

Another approach is to make use of the @code{-mlongcall} option to the
compiler;
@cindex @code{-mlongcall} (gcc)
GNAT has incorporated WRS'
gcc modification that implements this option.
If a subprogram call is
compiled with the @code{-mlongcall} option, then the generated code
constructs an absolute address in a register and uses a branch
instruction with absolute addressing mode.

Starting with release 3.15, the GNAT runtime libraries that are
distributed are compiled with the @code{-mlongcall} option.  In many
cases the use of these libraries is sufficient to avoid the
relocation problem, since it is the runtime library that contains
calls to the VxWorks kernel that need to span the address space gap.
If you are using an earlier GNAT release or a manually-built runtime,
you should recompile the GNAT runtime library with @code{-mlongcall};
you can use the
@file{Makefile.adalib} file from the @file{adalib} directory.

Application code may need to be compiled with @code{-mlongcall} if there
are calls directly to the kernel, the application is very large,
or in some specialized linking/loading scenarios.

You can compile individual files with @code{-mlongcall} by placing this
option on the @code{gcc} command line (for brevity we are omitting the
@code{powerpc-wrs-vxworks-} prefix on the commands shown in this
paragraph).
If you provide @code{-mlongcall} as an option for @code{gnatmake}, it will be
passed to all invocations of @code{gcc} that @code{gnatmake} directly performs.
Note that one other compilation is made by @code{gnatlink}, on the file created
by @code{gnatbind} for the elaboration package body
(see @ref{Binding Using gnatbind}).
Passing @code{-mlongcall} to @code{gnatlink}, either directly
on the @code{gnatlink} command line or by including @code{-mlongcall} in the
@code{-largs} list of @code{gnatmake}, will direct @code{gnatlink} to compile the
binder file with the @code{-mlongcall} option.

To see the effect of @code{-mlongcall}, consider the following small example:

@smallexample
   procedure Proc is
      procedure Imported_Proc;
      pragma Import (Ada, Imported_Proc);
   begin
      Imported_Proc;
   end;
@end smallexample

@noindent
If you compile @code{Proc} with the default options (no @code{-mlongcall}), the following code is generated:

@smallexample
   _ada_proc:
           ...
           bl imported_proc
           ...
@end smallexample

@noindent
In contrast, here is the result with the @code{-mlongcall} option:

@smallexample
   _ada_proc:
           ...
           addis 9,0,imported_proc@@ha
           addi 0,9,imported_proc@@l
           mtlr 0
           blrl
           ...
@end smallexample


@node Support for Software Floating Point on PowerPC Processors
@section Support for Software Floating Point on PowerPC Processors

@noindent
The PowerPC 860 processor does not have hardware floating-point support.
In order to build and run GNAT modules properly, you need to install and
invoke software-emulated floating-point support as follows:

@itemize @bullet
@item
At installation time:
@itemize @bullet
@item
Create a file @file{ada_object_path} under the directory
@file{BASE\lib\gcc-lib\powerpc-wrs-vxworks\2.8.1}
(by default @file{BASE}=@file{c:\gnatpro})
containing the following line:
@smallexample
rts-soft-float\adalib
@end smallexample

@item
Create a file @file{ada_source_path} under the directory
@file{BASE\lib\gcc-lib\powerpc-wrs-vxworks\2.8.1}
(by default @file{BASE}=@file{c:\gnatpro})
containing the following line:
@smallexample
rts-soft-float\adainclude
@end smallexample
@end itemize

@item
When using the compiler, specify @option{-msoft-float}
as a compiler and a linker option, e.g.:
@smallexample
$powerpc-wrs-vxworks-gnatmake -msoft-float module -largs -msoft-float
@end smallexample
@end itemize


@node Interrupt Handling for VxWorks
@section Interrupt Handling for VxWorks

@noindent
GNAT offers a range of options for hardware interrupt handling. In rough
order of latency and lack of restrictions:

@itemize @bullet
@item Directly vectored interrupt procedure handlers
@item Directly vectored interrupt procedures that signal a task using
a suspension object
@item Ada 95 protected procedure handlers for interrupts
@item Ada 83 style interrupt entry handlers for interrupts
@end itemize

@noindent
In general, the range of possible solutions trades off latency versus
restrictions in the handler code.  Restrictions in direct vectored
interrupt handlers  are documented in the @cite{VxWorks Programmer's Guide}.
Protected procedure handlers have only the
restriction that no potentially blocking operations are performed within
the handler.  Interrupt entries have no restrictions.  We recommend the
use of the protected procedure mechanism as providing the best balance
of these considerations for most applications.

All handler types must explicitly perform any required hardware cleanups,
such as issuing an end-of-interrupt if necessary.

For VxWorks/AE, applications that handle interrupts must be loaded into
the kernel protection domain.

@itemize @bullet
@item Direct Vectored Interrupt Routines

@noindent
This approach provides the lowest interrupt latency, but has the most
restrictions on what VxWorks and Ada runtime calls can be made, as well
as on what Ada entities are accessible to the handler code.  Such handlers
are most useful when there are stringent latency requirements, and very
little processing is to be performed in the handler.   Access to the
necessary VxWorks routines for setting up such handlers is provided in
the package @code{Interfaces.VxWorks}.

VxWorks restrictions are described in the @cite{VxWorks Programmer's Manual}.
Note in particular that floating point context is not automatically saved and
restored when interrupts are vectored to the handler.  If the handler is
to execute floating point instructions, the statements involved must be
bracketed by a pair of calls to @code{fppSave} and @code{fppRestore} defined
in @code{Interfaces.VxWorks}.

In general, it is a good idea to save and restore the handler that was
installed prior to application startup.  The routines @code{intVecGet}
and @code{intVecSet} are used for this purpose.  The Ada handler code
is installed into the vector table using routine @code{intConnect},
which generates wrapper code to save and restore registers.

Example:

@smallexample
with Interfaces.VxWorks; use Interfaces.VxWorks;
with System;

package P is

   Count : Natural := 0;
   pragma Atomic (Count);

   --  Interrupt level used by this example
   Level : constant := 1;

   --  Be sure to use a reasonable interrupt number for the target
   --  board!  Refer to the BSP for details.
   Interrupt : constant := 16#14#;

   procedure Handler (Parameter : System.Address);

end P;

package body P is

   procedure Handler (parameter : System.Address) is
      S : Status;
   begin
      Count := Count + 1;
      --  Acknowledge interrupt.  Not necessary for all interrupts.
      S := sysBusIntAck (intLevel => Level);
   end Handler;
end P;

with Interfaces.VxWorks; use Interfaces.VxWorks;
with Ada.Text_IO; use Ada.Text_IO;

with P; use P;
procedure Useint is
   task T;

   S : Status;

   task body T is
   begin
      for I in 1 .. 10 loop
         Put_Line ("Generating an interrupt...");
         delay 1.0;

         --  Generate interrupt, using interrupt number
         S := sysBusIntGen (Level, Interrupt);
      end loop;
   end T;

   --  Save old handler
   Old_Handler : VOIDFUNCPTR := intVecGet (INUM_TO_IVEC (Interrupt));
begin
   S := intConnect (INUM_TO_IVEC (Interrupt), Handler'Access);
   S := sysIntEnable (intLevel => Level);

   for I in 1 .. 10 loop
      delay 2.0;
      Put_Line ("value of count:" & P.Count'Img);
   end loop;

   --  Restore previous handler
   S := sysIntDisable (intLevel => Level);
   intVecSet (INUM_TO_IVEC (Interrupt), Old_Handler);
end Useint;
@end smallexample

@item Direct Vectored Interrupt Routines

@noindent
A variation on the direct vectored routine that allows for less restrictive
handler code is to separate the interrupt processing into two levels.

The first level is the same as in the previous section.  Here we perform
simple hardware actions and signal a task pending on a Suspension_Object
(defined in @code{Ada.Synchronous_Task_Control}) to perform the more complex
and time-consuming operations.  The routine @code{Set_True} signals a task
whose body loops and pends on the suspension object using @code{Suspend_Until_True}.
The suspension object is declared in a scope global to both the handler and
the task. This approach can be thought of as a slightly higher-level
application of the @code{C} example using a binary semaphore given in the
VxWorks Programmer's Manual.  In fact, the implementation of
@code{Ada.Synchronous_Task_Control} is a very thin wrapper around a VxWorks
binary semaphore.

This approach has a latency between the direct vectored approach and the
protected procedure approach.  There are no restrictions in the Ada task
code, while the handler code has the same restrictions as any other
direct interrupt handler.

Example:

@smallexample
with System;
package Sem_Handler is

   Count : Natural := 0;
   pragma Atomic (Count);

   --  Interrupt level used by this example
   Level : constant := 1;
   Interrupt : constant := 16#14#;

   --  Interrupt handler providing "immediate" handling
   procedure Handler (Param : System.Address);

   --  Task whose body provides "deferred" handling
   task Receiver is
       pragma Interrupt_Priority
          (System.Interrupt_Priority'First + Level + 1);
    end Receiver;

end Sem_Handler;

with Ada.Synchronous_Task_Control; use Ada.Synchronous_Task_Control;
with Interfaces.VxWorks; use Interfaces.VxWorks;
package body Sema_Handler is

   SO : Suspension_Object;

   task body Receiver is
   begin
      loop
         --  Wait for notification from immediate handler
         Suspend_Until_True (SO);

         --  Interrupt processing
         Count := Count + 1;
      end loop;
   end Receiver;

   procedure Handler (Param : System.Address) is
      S : STATUS;
   begin
      --  Hardware cleanup, if necessary
      S := sysBusIntAck (Level);

      --  Signal the task
      Set_True (SO);
   end Handler;

end Sem_Handler;

with Interfaces.VxWorks; use Interfaces.VxWorks;
with Ada.Text_IO; use Ada.Text_IO;
with Sem_Handler; use Sem_Handler;
procedure Useint is

   S : STATUS;

   task T;

   task body T is
   begin
      for I in 1 .. 10 loop
         Put_Line ("Generating an interrupt...");
         delay 1.0;

         --  Generate interrupt, using interrupt number
         S := sysBusIntGen (Level, Interrupt);
      end loop;
   end T;

   --  Save old handler
   Old_Handler : VOIDFUNCPTR := intVecGet (INUM_TO_IVEC (Interrupt));
begin
   S := intConnect (INUM_TO_IVEC (Interrupt), Handler'Access);
   S := sysIntEnable (intLevel => Level);

   for I in 1 .. 10 loop
      delay 2.0;
      Put_Line ("value of Count:" & Sem_Handler.Count'Img);
   end loop;

   --  Restore handler
   S := sysIntDisable (intLevel => Level);
   intVecSet (INUM_TO_IVEC (Interrupt), Old_Handler);
   abort Receiver;
end Useint;
@end smallexample

@item Protected Procedure Handlers for Interrupts

@noindent
This is the recommended default mechanism for interrupt handling.
It essentially wraps the hybrid handler / task mechanism in a higher-level
abstraction, and provides a good balance between latency and capability.

Vectored interrupts are designated by their interrupt number, starting from
0 and ranging to the number of entries in the interrupt vector table - 1.

In the GNAT VxWorks implementation, the following priority mappings are used:
@itemize @bullet
@item Normal task priorities are in the range 0 .. 245.
@item Interrupt priority 246 is used by the GNAT @code{Interrupt_Manager}
task.
@item Interrupt priority 247 is used for vectored interrupts
that do not correspond to those generated via an interrupt controller.
@item Interrupt priorities 248 .. 255 correspond to PIC interrupt levels
0 .. 7.
@item Priority 256 is reserved to the VxWorks kernel.
@end itemize

Except for reserved priorities, the above are recommendations for setting the
ceiling priority of a protected object that handles interrupts, or the
priority of a task with interrupt entries.  It's a very good idea to follow
these recommendations for vectored interrupts that come in through the PIC
as it will determine the priority of execution of the code in the protected
procedure or interrupt entry.

No vectored interrupt numbers are reserved in this implementation, because
dedicated interrupts are determined by the board support package. Obviously,
careful consideration of the hardware is necessary when handling interrupts.
The VxWorks BSP for the board is the definitive reference for interrupt
assignments.

Example:

@smallexample
package PO_Handler is

   --  Interrupt level used by this example
   Level : constant := 1;

   Interrupt : constant := 16#14#;

   protected Protected_Handler is
      procedure Handler;
      pragma Attach_Handler (Handler, Interrupt);

      function Count return Natural;

      pragma Interrupt_Priority (248);
   private
      The_Count : Natural := 0;
   end Protected_Handler;

end PO_Handler;

with Interfaces.VxWorks; use Interfaces.VxWorks;
package body PO_Handler is

   protected body Protected_Handler is

      procedure Handler is
         S : Status;
      begin
         --  Hardware cleanup if necessary
         S := sysBusIntAck (Level);

         --  Interrupt processing
         The_Count := The_Count + 1;
      end Handler;

      function Count return Natural is
      begin
         return The_Count;
      end Count;
   end Protected_Handler;

end PO_Handler;

with Interfaces.VxWorks; use Interfaces.VxWorks;
with Ada.Text_IO; use Ada.Text_IO;

with PO_Handler; use PO_Handler;
procedure Useint is

   task T;

   S : STATUS;

   task body T is
   begin
      for I in 1 .. 10 loop
         Put_Line ("Generating an interrupt...");
         delay 1.0;

         --  Generate interrupt, using interrupt number
         S := sysBusIntGen (Level, Interrupt);
      end loop;
   end T;

begin
   S := sysIntEnable (intLevel => Level);

   for I in 1 .. 10 loop
      delay 2.0;
      Put_Line ("value of count:" & Protected_Handler.Count'Img);
   end loop;

   S := sysIntDisable (intLevel => Level);
end Useint;
@end smallexample

@noindent
This is obviously significantly higher-level and easier to write than the
previous examples.

@item Ada 83 Style Interrupt Entries

GNAT provides a full implementation of the Ada 83 interrupt entry mechanism
for vectored interrupts.  However, due to latency issues,
we only recommend using these for backward compatibility.  The comments in
the previous section regarding interrupt priorities and reserved interrupts
apply here.

In order to associate an interrupt with an entry, GNAT provides the
standard Ada convenience routine @code{Ada.Interrupts.Reference}.  It is used
as follows:

@smallexample
Interrupt_Address : constant System.Address :=
   Ada.Interrupts.Reference (Int_Num);

task Handler_Task is
   pragma Interrupt_Priority (248);  -- For instance
   entry Handler;
   for Handler'Address use Interrupt_Address;
end Handler_Task;
@end smallexample

@noindent
Since there is no restriction within an interrupt entry on blocking operations,
be sure to perform any hardware interrupt controller related operations before
executing a call that could block within the entry's accept statements.  It
is assumed that interrupt entries are always open alternatives when they
appear within a selective wait statement.  The presence of a guard gives
undefined behavior.

Example:

@smallexample
with Ada.Interrupts;
with System;
package Task_Handler is

   --  Interrupt level used by this example
   Level : constant := 1;

   Interrupt : constant := 16#14#;

   Interrupt_Address : constant System.Address :=
      Ada.Interrupts.Reference (Int_Num);

   task Handler_Task is
      pragma Interrupt_Priority (248);  -- For instance
      entry Handler;
      for Handler'Address use Interrupt_Address;

      entry Count (Value : out Natural);
   end Handler_Task;
end Task_Handler;

with Interfaces.VxWorks; use Interfaces.VxWorks;
package body Task_Handler is

   task body Handler_Task is
      The_Count : Natural := 0;
      S : STATUS;
   begin
      loop
         select
            accept Handler do
               --  Hardware cleanup if necessary
               S := sysBusIntAck (Level);

               --  Interrupt processing
               The_Count := The_Count + 1;
            end Handler;
         or
            accept Count (Value : out Natural) do
               Value := The_Count;
            end Count;
         end select;
      end loop;
   end Handler_Task;

end Handler_Task;

with Interfaces.VxWorks; use Interfaces.VxWorks;
with Ada.Text_IO; use Ada.Text_IO;

with Handler_Task; use Handler_Task;
procedure Useint is

   task T;

   S : STATUS;
   Current_Count : Natural := 0;

   task body T is
   begin
      for I in 1 .. 10 loop
         Put_Line ("Generating an interrupt...");
         delay 1.0;

         --  Generate interrupt, using interrupt number
         S := sysBusIntGen (Level, Interrupt);
      end loop;
   end T;

begin
   S := sysIntEnable (intLevel => Level);

   for I in 1 .. 10 loop
      delay 2.0;
      Handler_Task.Count (Current_Count);
      Put_Line ("value of count:" & Current_Count'Img);
   end loop;

   S := sysIntDisable (intLevel => Level);
   abort Handler_Task;
end Useint;
@end smallexample
@end itemize


@node Simulating Command Line Arguments for VxWorks
@section Simulating Command Line Arguments for VxWorks

@noindent
The GNAT implementation of @code{Ada.Command_Line} relies on the standard C
symbols @code{argv} and @code{argc}.  The model for invoking "programs" under
VxWorks does not provide these symbols.  The typical method for invoking a
program under VxWorks is to call the @code{sp} function in order to spawn a
thread in which to execute a designated function (in GNAT, this is the implicit
main generated by gnatbind. @code{sp} provides the capability to push a variable
number of arguments onto the stack when the function is invoked.  But this does
not work for the implicit Ada main, because it has no way of knowing how many
arguments might be required.  This eliminates the possibility to use
@code{Ada.Command_Line}.

One way to solve this problem is to define symbols in the VxWorks environment,
then import them into the Ada application.  For example, we could define the
following package that imports two symbols, one an int and the other a string:

@smallexample
with Interfaces.C.Strings;
use Interfaces.C.Strings;
package Args is
   --  Define and import a variable for each argument
   Int_Arg : Interfaces.C.Int;
   String_Arg : Chars_Ptr;
private
   pragma Import (C, Int_Arg, "intarg");
   pragma Import (C, String_Arg, "stringarg");
end Args;
@end smallexample

@noindent
An Ada unit could then use the two imported variables @code{Int_Arg} and
@code{String_Arg} as follows:

@smallexample
with Args; use Args;
with Interfaces.C.Strings;
use Interfaces.C, Interfaces.C.Strings;
with Ada.Text_IO; use Ada.Text_IO;
procedure Argtest is
begin
   Put_Line (Int'Image (Int_Arg));
   Put_Line (Value (String_Arg));
end Argtest;
@end smallexample

@noindent
When invoking the application from the shell, one will then set the values
to be imported, and spawn the application, as follows:

@smallexample
-> intarg=10
-> stringarg="Hello"
-> sp (argtest)
@end smallexample


@node Debugging Issues for VxWorks
@section Debugging Issues for VxWorks

@noindent
The debugger can be launched directly from the Tornado environment or from @code{glide}
through its graphical interface: @code{gvd}. It can also be used
directly in text mode as shown below:
@noindent
The command to run @code{GDB} in text mode is

@smallexample
$ @i{target}-gdb
@end smallexample

@noindent
where @i{target} is the name of target of the cross GNAT
compiler. In contrast with native @code{gdb}, it is not useful to give the name of
the program to debug on the command line. Before starting a debugging
session, one needs to connect to the VxWorks-configured board and load
the relocatable object produced by @code{gnatlink}. This can be achieved
by the following commands:

@smallexample
(vxgdb) target wtx myboard
(vxgdb) load program
@end smallexample

@noindent
where @code{myboard} is the host name or IP number of the target board, and
@code{wtx} is the name of debugging protocol used to communicate
with the VxWorks board. Early versions of VxWorks, up tp 5.2, only
support the @code{<vxworks>} protocol whereas starting with VxWorks 5.3
and Tornado, another protocol called  @code{<wtx>} was made available. The
choice of the protocol can be made when configuring the VxWorks
kernel itself. When available, the @code{<wtx>} is greatly preferable
and actually the only supported protocol with GNAT. When the debugger
is  launched directly from Tornado, the proper @code{target} command
is automatically generated by the environment.

The GNAT debugger can be used for debugging multitasking programs in two
different modes and some minimal understanding of these modes is
necessary in order to use the debugger effectively. The two modes are:

@itemize @bullet
@item Monotask mode: attach to, and debug, a single task.
This mode is equivalent to the capabilities offered by CrossWind. The
debugger interacts with a single task, while not affecting other tasks
(insofar as possible). This is the DEFAULT mode.

@item Multitask mode:
The debugger has control over all Ada tasks in an application. It is
possible to gather information about all application tasks, and to
switch from one to another within a single debugging session.
@end itemize

@noindent
It is not advised to switch between the two modes within a debugging
session. A third mode called System mode is also available and can be
used in place of the Multitask mode. Consult the Tornado documentation
for this.

Among the criteria for selecting the appropriate mode is the effect of
task synchronization on the application's behavior. Debugging a
tasking application affects the timing of the application; minimizing
such effects may be critical in certain situations. The two modes have
different effects: monotask mode only affects the attached task:
others will run normally (if possible). Multitask mode stops all tasks
at each breakpoint and restarts them on single-step, next, finish or
continue; this may help avoid deadlocks in the presence of task
synchronization despite the inherent latency of stopping and
restarting the tasks.

@subsection Using the debugger in monotask mode

@noindent
There are two ways to begin your debugging session:

@itemize @bullet
@item The program is already running on the board.

@noindent
The sequence of commands to use this mode is:
@itemize @bullet
@item Launch GVD (possibly from the Tornado menu)

@noindent
Verify that the debugger has access to the debug information of both
your program and the kernel. The Console window should have a message
"Looking for all loaded modules:" followed by the names of the modules
on the board and "ok". If you have some error messages here instead of
"ok", the debugging session may not work as expected.

@item Attach to the desired task using
@smallexample
        File --> Attach...
@end smallexample
@noindent
This task is stopped by the debugger. Other tasks continue to operate
normally (unless they are blocked by synchronization with the stopped
task). The source window should display the code on which the task has
been stopped, and if the stack display is enabled, it should reflect
the stack of the task.
@end itemize

@item The program hasn't been loaded yet on the board
@itemize @bullet
@item Launch GVD (possibly from the Tornado menu)
@item Load your program to the board:
@smallexample
File --> Open Program...
@end smallexample

@noindent
GVD should display:
@smallexample
Downloading your_program ...done.
Reading symbols from your_program...expanding to full symbols...done.
@end smallexample

@item Set breakpoints in your program.

@noindent
WARNING: they must be set in the main task (if your program runs
several tasks)

@item Run your program using one of the three methods below:
@itemize @bullet
@item
Click on button <run> or <start>

@item Menu
@smallexample
Program --> Run/Start
@end smallexample

@item
Type in GVD's Console window
@smallexample
(gdb) run your_program
@end smallexample
@end itemize
@end itemize

@item Whichever method you chose to start your debugging session,
you can use the following commands at this point:
@itemize @bullet
@item  Browse sources and set breakpoints
@item  Examine the call stack (Data --> call stack)
@item  Go "up" and "down" in the call stack ("up" & "down" buttons)
@item  Examine data
(Data --> Display local variables, or any of the other methods for viewing data in GVD)
@item Continue/finish
@end itemize

Next/step/finish will only work if the top frame in the call stack has
debug information.  This is almost never the case when first attaching
to the task since the task is usually stopped by the attach operation
in the GNAT runtime. You can verify which frames of the call stack
have debug information by:
@smallexample
Data --> call stack
<right Button> (contextual menu inside the call stack window)
 add "file location"
@end smallexample

@noindent
If the current frame does not have a "file location", then there is no
debug information for the frame.  We strongly recommended that you set
breakpoints in the source where debug information can be found and
"continue" until a breakpoint is reached before using
"next/step". Another convenient possibility is to use the "continue
until" capability available from the contextual menu of the Source
window.

You can also examine the state of other tasks using
@smallexample
Data -> tasks
@end smallexample

@noindent
but you can't "switch" to another task by clicking on the
elements of the task list. If you try to, you will get an error
message in GVD's console:
@smallexample
"Task switching is not allowed when multi-tasks mode is not active"
@end smallexample

@noindent
Once you have completed your debugging session on the attached
task, you can detach from the task:
@smallexample
File --> detach
@end smallexample

@noindent
The task resumes normal execution at this stage.  WARNING: when you
detach from a task, be sure that you are in a frame where there is
debug information. Otherwise, the task won't resume properly. You can
then start another attach/detach cycle if you wish.

Note that it is possible to launch several GVD sessions and
simultaneously attach each to a distinct task in monotask mode:
@smallexample
File --> New Debugger...  (uncheck the box: Replace Current Debugger)
File --> Attach...     (in the new window)
File --> detach
@end smallexample
@end itemize


@subsection Using the debugger in Multitask mode

@noindent
The steps are as follows

@itemize @bullet
@item
Launch GVD (possibly from the Tornado menu)

@noindent
There are two possibilities:
@itemize @bullet
@item
If the program is already loaded on the target board, you need only verify
that debug information has been found by the debugger as described
above.

@item
Otherwise, load the program on the board using
@smallexample
File --> Open program
@end smallexample
@end itemize

@item Set breakpoints in the desired parts of the program

@item Start the program

@noindent
The simplest way to start the debugger in multitask mode is to use the
menu
@smallexample
Program --> Run/Start
@end smallexample

@noindent
and check the box "enable vxWorks multi-tasks mode".
You can also use the following gdb commands in the console window
@smallexample
        (gdb) set multi-tasks-mode on
        (gdb) run your_program
@end smallexample

@item Debug the stopped program

@noindent
Once stopped at a breakpoint
(or if you pressed the "stop" button), you can use all the standard
commands listed for monotask mode + task switching (using Data -->
tasks). Using next/step under this mode is possible with the same
restrictions as for monotask mode, but is not recommended because all
tasks are restarted, leading to the possibility that a different task
hits a breakpoint before the stepping operation has completed.  Such
an occurrence can result in a confusing state for both the user and
the debugger. So we strongly suggest the use of only breakpoints and
"continue" in this mode.
@end itemize

A final reminder: whatever the mode, whether you are debugging or not,
the program has to be reloaded before each new execution, so that data
initialized by the loader is set correctly. For instance, if you wish
to restart the same execution of the same program, you can use the
following sequence of gdb commands in the console window:
@smallexample
(gdb) detach
(gdb) unload your_program(.exe)
(gdb) load your_program(.exe)
(gdb) run your_program
@end smallexample


@node Using GNAT from the Tornado 2 Project Facility
@section Using GNAT from the Tornado 2 Project Facility
@cindex Tornado II Project

@menu
* The GNAT Toolchain as Used from the Tornado 2 Project Facility::
* Building a Simple Application::
* Mixing C and Ada Code in a Tornado 2 Project::
* Compilation Switches::
* Autoscale and Minimal Kernel Configuration::
* Adapting BSPs to GNAT::
* Using GNAT Project Files in a Tornado 2 Project::
@end menu

@noindent
This section describes how to add an Ada module in a Tornado project
using the Tornado 2 Project facility described in
@cite{Tornado User's Guide}, Chapter 4.
All recommendations apply for both 'Downloadable Modules' and 'Kernel'
project types.


@node The GNAT Toolchain as Used from the Tornado 2 Project Facility
@subsection The GNAT Toolchain as Used from the Tornado 2 Project Facility

@noindent
Tornado 2 allows you to integrate third-party C toolchains.
(@cite{Tornado 2 API Programmer's Guide}, Chapter 7).
Thus the GNAT toolchain will be seen as a new C toolchain when used from
the Tornado 2 Project Facility. For each processor you can compile for,
you will find a <proc>gnat toolchain, e.g. PPC604gnat. These toolchains will
allow you to include Ada modules into your projects, and simply build them.

The name of the so-called C compiler is @emph{cc_gnat_<arch>}, the name
of the 'linker' is @emph{ld_gnat_<arch>}, where <arch> is an architecture; e.g.,
PPC. These scripts will call the correct executables during the compilation or
link processes, thus the C compiler, the C linker, or the GNAT toolchain,
depending on the context.


@node  Building a Simple Application
@subsection  Building a Simple Application

@noindent
First, create a new project, using one of the gnat toolchains.

To add an Ada source file to the current project, just click on
@code{Project -> Add/Include}, browse to the relevant file, and include it.
The Ada source file included should be the Ada entry point. Only
one Ada entry point is allowed in a project. Any other required Ada source
files will be automatically compiled and linked by the underlying tools.

You can now compile the project, @code{Build->Rebuild all}.
A log of the compilation process can be found in the build directory, in
@file{gnatbuild.log}. It contains all the calls executed by the scripts, and
associated information.


@node Mixing C and Ada Code in a Tornado 2 Project
@subsection Mixing C and Ada Code in a Tornado 2 Project

@noindent
You can mix C and Ada code in your projects. Your source files and the build
options should comply with the recommendations from the section
@cite{Interfacing to C}.
This means that you can have several or no C source files, and one or no Ada entry
point in your Tornado 2 Project.


@node Compilation Switches
@subsection Compilation Switches
@noindent
Once you have included all your source files, you may modify some compilation
and linking options.
To pass specific options to the GNAT toolchain, go to the Project's build
settings, on the @code{C/C++ Compiler} tab, and add your arguments in the
input window.

You must comply with several rules to pass arguments to GNAT.
Arguments to be passed should be

@itemize @bullet

@item after any arguments passed to the C toolchain.

@item prefixed depending on the tool that uses them, with the following syntax

@itemize @bullet
@item @code{-cargs @emph{gnatmake-options}} to pass arguments to gnatmake
@item @code{-bargs @emph{gnatbind-options}} to pass arguments to gnatbind
@item @code{-largs @emph{gnatlink-options}} to pass arguments to gnatlink
@end itemize
@end itemize

@noindent
You will find more information on the compilation process of Ada source files
in the section @cite{The GNAT Compilation Model}.
For a list of all available switches, refer to the sections describing
@code{gnatmake}, @code{gnatbind} and @code{gnatlink}.

Here is an example that passes the option @code{-v} to the GNAT compiler :
@smallexample
-g -mstrict-align -prjtype $(PRJ_TYPE) -ansi -nostdinc -DRW_MULTI_THREAD -D_REENTRANT
-fno-builtin -fno-for-scope -I. -I/usr/windppc-2.0/target/h -DCPU=PPC604
-cargs -v
@end smallexample

@noindent
Here is an example that passes the option @code{-v} to the GNAT compiler, binder and linker,
and @code{-v} and @code{-g} to the compiler :
@smallexample
-g -mstrict-align -prjtype $(PRJ_TYPE) -ansi -nostdinc -DRW_MULTI_THREAD -D_REENTRANT
-fno-builtin -fno-for-scope -I. -I/usr/windppc-2.0/target/h -DCPU=PPC604
-cargs -v -g -O2 -bargs -v -largs -v
@end smallexample

@noindent
In both examples, the following arguments have been automatically added by the Project
Facility, and will be used by the C compiler.
@smallexample
-g -mstrict-align -prjtype $(PRJ_TYPE) -ansi -nostdinc -DRW_MULTI_THREAD -D_REENTRANT
-fno-builtin -fno-for-scope -I. -I/usr/windppc-2.0/target/h -DCPU=PPC604
@end smallexample

@noindent
Note: The @code{-prjtype $(PRJ_TYPE)} option present in a few input
boxes is used by the GNAT toolchain. It is required for the compilation
process. You should not remove it from any input box.


@node Autoscale and Minimal Kernel Configuration
@subsection Autoscale and Minimal Kernel Configuration

@noindent
The Autoscale feature, present in the Project Facility  can be used on your
VxWorks Kernel projects to determine the minimum set of components required
for your kernel to work.
(Please refer to the @cite{Tornado II User's Guide} Section 4.4 for more details.)
This feature is also available for projects involving Ada code. Just click on
@code{Project->Autoscale} to launch a check and determine the minimal kernel
configuration.


@node Adapting BSPs to GNAT
@subsection Adapting BSPs to GNAT

@noindent
To use your Board Support Packages with the GNAT toolchain, you will have to adapt them,
either manually or using the @code{adaptbsp4gnat} script.
This procedure is described in the @cite{Tornado API Programmer's Guide},
Chapter 7.
Here is a summary of this setup, depending on the context.

@itemize @bullet
@item To do the adaptation manually:

@itemize @bullet

@item Copy your BSP directory contents into a new directory

@item Go to this directory

@item Edit the file @file{Makefile},

@itemize @bullet
@item Set tool to gnat, @code{TOOL=gnat}

@item Reverse the order of the following lines
@itemize @bullet
@item @code{include $(TGT_DIR)/h/make/make.$(CPU)$(TOOL)}
@item @code{include $(TGT_DIR)/h/make/defs.$(WIND_HOST_TYPE)}
@end itemize

@end itemize

@end itemize

@item To do the adaptation automatically, you may use the @code{adaptbsp4gnat}
script. Its syntax is @code{adaptbsp4gnat <path_to_bsp>}.

@noindent
This script follows the different steps described above to perform the
adaptation.
The name of the new bsp is given after the modification.  By default, if
@file{<bsp>} is the name of your BSP, @file{<bsp>-gnat}, will be the name of
the BSP created.
@end itemize


@node Using GNAT Project Files in a Tornado 2 Project
@subsection Using GNAT Project Files in a Tornado 2 Project

@noindent
You can use GNAT Project files to compile your Ada files.
To do so, you need to use the @option{-Pproject_file.gpr} option from @command{gnatmake}.
The path to the project file can be either absolute, or relative to the build
directory, i.e. where the executable will be placed (e.g. @file{~/myproject/PPC604gnat}).
Your project file should set the @code{Object_Dir} variable to a specific
value.
@smallexample
project Sample is

   Target := external ("TARGET_DIR");
   for Object_Dir use Target;

end Sample;
@end smallexample


@node Frequently Asked Questions for VxWorks
@section Frequently Asked Questions for VxWorks

@itemize @bullet

@item
When I run my program twice on the board, it does not work, why?

@noindent
Usually, Ada programs require elaboration and finalization, so the
compiler creates a wrapper procedure whose name is the same as the Ada
name of the main subprogram, which takes care of calling the elaboration
and finalization routines before and after your program. But the static
part of the elaboration is taken care of while loading the program
itself and thus if you launch it twice this part of the elaboration will
not be performed. This affects the proper elaboration of the
GNAT runtime and thus it is mandatory to reload your program before
relaunching it.

@item
Can I load a collection of subprograms rather than a standalone program?

@noindent
It is possible to write Ada programs with multiple entry points which
can be called from the VxWorks shell; you just need to consider your
main program as the VxWorks shell itself and generate an Ada subsystem
callable from outside @xref{Binding with Non-Ada Main Programs}. If you
use this method, you need to call @code{adainit} manually before calling
any Ada entry point.

@item
When I use the @code{break exception} command, I get the message
@code{"exception" is not a function}, why?

You are not in the proper language mode. Issue the command:
@smallexample
(vxgdb) set language ada
@end smallexample

@item
When I load a large application from the VxWorks shell using the "ld"
command, the load hangs and never finishes. How can I load large
executables?

This is a classic VxWorks problem when using the default "rsh" communication
method. Using NFS instead should work. Use the @code{nfsShowMount} command to
verify that your program is in a NFS mounted directory.

@item
When I load a large application from the debugger using the wtx target
connection, the load never finishes, why?

Make sure that the memory cache size parameter of the target server is
large enough. (@code{target -m big_enough_size}, or Memory cache size box in GUI.)
See @cite{Tornado 1.01 API Programming Guide}, Section 3.6.2.

@item
When I spawn my program under the VxWorks shell, interactive input does
not work, why?

Only programs directly launched from the shell can have interactive
input. For a program spawned with the @code{sp} or @code{taskSpawn}
command, you need to have file redirection for input:
@smallexample
->    # here you can have interactive input
-> main
->    # here you cannot
-> sp main
->    # neither here
-> taskSpawn("ess",100,0,8000000,main)
->    # but you can input from a file:
-> taskSpawn("Bae",100,0,8000000,main) < input_file
@end smallexample
@end itemize


@node LynxOS Topics
@chapter LynxOS Topics
@noindent
This chapter describes topics that are specific to the GNAT for LynxOS
cross configurations.

@menu
* Getting Started with GNAT on LynxOS::
* Kernel Configuration for LynxOS::
* Patch Level Issues for LynxOS::
* Debugging Issues for LynxOS::
* An Example Debugging Session for LynxOS::
@end menu

@node Getting Started with GNAT on LynxOS
@section Getting Started with GNAT on LynxOS

@noindent
This section is a starting point for using GNAT to develop and
execute Ada 95 programs for LynuxWorks' LynxOS target environment from a
Unix host environment.
We assume that you know how to use GNAT in a native environment
and how to start a telnet or other login session to connect to your LynxOS board.

To compile code for a LynxOS system running on a PowerPC
board, the basic compiler command is
@command{powerpc-xcoff-lynxos-gcc}.

With GNAT, the easiest way to build the basic @code{Hello World} program is
with @code{gnatmake}. For the LynxOS PowerPC target this would look
like:

@smallexample
$ powerpc-xcoff-lynxos-gnatmake hello
@i{powerpc-xcoff-lynxos-gcc -c hello.adb
powerpc-xcoff-lynxos-gnatbind -x hello.ali
powerpc-xcoff-lynxos-gnatlink hello.ali}
@end smallexample

@noindent
(The first line is the command entered by the user -- the subseqent three
are the programs run by @code{gnatmake}.)

This creates the executable @command{hello}" which you then need to load on the
board (using ftp or an NFS directory for example) to run it.


@node Kernel Configuration for LynxOS
@section Kernel Configuration for LynxOS

@noindent
The appropriate configuration for your LynxOS kernel depends
on the target system and the requirements of your application. GNAT itself
adds no additional demands; however in some situations it may be appropriate
to increase the conservative
resource assumptions made by the default configuration.

Kernel parameters limiting the maximum number of file descriptors,
kernel and user threads, synchronization objects, etc., may be set in the
file @file{uparam.h}. You may also wish to modify the file
@file{/etc/starttab}, which places limits on data, stack, and core file
size. See the documentation provided by LynuxWorks for more information.


@node Patch Level Issues for LynxOS
@section Patch Level Issues for LynxOS

@noindent
The GNAT runtime requires that your system run at patch level 040 or
later. Please see the file @file{PatchCompatibility.txt} from the
distribution for more information.


@node Debugging Issues for LynxOS
@section Debugging Issues for LynxOS

@noindent
GNAT's debugger is based on the same GNU gdb technology as the debugger
provided by LynxOS, though with a great number of extensions and
enhancements to support the Ada language and GNAT. The LynxOS
documentation is relevant to understanding how to get the debugger
started if you run into difficulties.

To demonstrate a debugging session, we will use a slightly more complex
program called @file{demo1.adb}, which can be found in the @file{examples}
directory of the GNAT distribution. This program is compiled with
debugging information as follows:

@smallexample
$ powerpc-xcoff-lynxos-gnatmake -g demo1
powerpc-xcoff-lynxos-gcc -c -g demo1.adb
powerpc-xcoff-lynxos-gcc -c -g gen_list.adb
powerpc-xcoff-lynxos-gcc -c -g instr.adb
powerpc-xcoff-lynxos-gnatbind -x demo1.ali
powerpc-xcoff-lynxos-gnatlink -g demo1.ali
@end smallexample

@noindent
Once the executable is created, copy it to your working directory on the
board. In this directory, you will have to launch the gdb server and
choose a free port number on your TCP/IP socket. Presuming the Internet
hostname of the board is @file{myboard} and the port chosen is 2345,
issue the following command:

@smallexample
myboard> gdbserver myboard:2345 demo1
@end smallexample

@noindent
Then return to your host environment.

The graphical debugger interface, @command{gvd}, supports both native
and cross environments at the same time. @command{gvd} can be launched from
@command{Glide} (see @file{README.Glide} for more information on customizing
@command{Glide} for LynxOS) or it can be launched from the command line as
follows:

@smallexample
$ gvd --debugger powerpc-xcoff-lynxos-gdb
@end smallexample

@noindent
Then to attach to the target, enter in @command{gvd}'s command line window:

@smallexample
(gdb) target remote myboard:2345
@end smallexample

@noindent
For more information see the GVD documentation.

The comments below concern debugging directly from the command line but
they also apply to @command{gvd}, though in most cases an equivalent
graphical command is also available.

To run the cross debugger from the command line without the visual
interface use the command @code{powerpc-xcoff-lynxos-gdb}.

You will see something like:

@smallexample
GNU gdb 4.17.gnat.3.14a1
Copyright 1998 Free Software Foundation, Inc.
GDB is free software, covered by the GNU General Public License, and you are
welcome to change it and/or distribute copies of it under certain conditions.
Type "show copying" to see the conditions.
There is absolutely no warranty for GDB.  Type "show warranty" for details.
This GDB was configured as "--host=sparc-sun-solaris2.5.1 --target=powerpc-xc
off-lynxos".
(gdb)
@end smallexample

@noindent
Where @command{(gdb)} is the debugger's prompt. The first thing to do at the
prompt from within @command{gdb} is to load the symbol table from the
executable:

@smallexample
(gdb) file demo1
Reading symbols from demo1...done.
(gdb)
@end smallexample

@noindent
You then have to attach to the server running on the board. Issue the command:

@smallexample
(gdb) target remote myboard:2345
@end smallexample

@noindent
After the server has been started and attached from the host, the program is
running on the target but has halted execution at the very beginning.
The following commands set a breakpoint and continue execution:

@smallexample
(gdb) break demo1.adb:37
Breakpoint 1 at 0x100064d0: file demo1.adb, line 37.
(gdb) cont
Continuing.

Breakpoint 1, demo1 () at demo1.adb:37
37         Set_Name (Fuel, "Fuel");
(gdb)
@end smallexample

@noindent
Here the execution has stopped at the breakpoint set above. Now
you can use the standard @code{gdb} commands to examine the stack and
program variables.

Note that once execution has completed, the server on the board must be
restarted before a new debugging session may begin.

@node An Example Debugging Session for LynxOS
@section An Example Debugging Session for LynxOS

@noindent
Carrying on a little further with the debugging session, the following
example illustrates some of the usual debugging commands for moving
around and seeing where you are:

@smallexample
(gdb) next
38         Set_Name (Water, "Water");
(gdb) bt
#0  demo1 () at demo1.adb:38
#1  0x10001218 in main (argc=1, argv=2147483640, envp=2147483520) at
b~demo1.adb:118
#2  0x10017538 in runmainthread ()
#3  0x10001048 in __start ()
(gdb) up
#1  0x10001218 in main (argc=1, argv=2147483640, envp=2147483520) at
b~demo1.adb:118
118       Ada_Main_Program;
(gdb) down
#0  demo1 () at demo1.adb:38
38         Set_Name (Water, "Water");
(gdb)
@end smallexample

@noindent
To examine and modify variables (of a tagged type here):

@smallexample
(gdb) print speed
$1 = (name => "Speed         ", value => -286331154)
(gdb) ptype speed
type = new instr.instrument with record
    value: instr.speed;
end record
(gdb) speed.value := 3
$2 = 3
(gdb) print speed
$3 = (name => "Speed         ", value => 3)
(gdb) info local
speed = (name => "Speed         ", value => 3)
fuel = (name => "Fuel          ", value => -286331154)
oil = (name => ' ' <repeats 14 times>, value => -286331154, size => 20,
  fill => 42 '*', empty => 46 '.')
water = (name => ' ' <repeats 14 times>, value => -286331154, size => 20,
  fill => 42 '*', empty => 46 '.')
time = (name => ' ' <repeats 14 times>, seconds => 0, minutes => 0, hours =>
0)
chrono = (name => ' ' <repeats 14 times>, seconds => 0, minutes => 0,
  hours => 0)
db = (access demo1.dash_board.internal) 0x0
(gdb)
@end smallexample

@noindent
And finally letting the program it run to completion:

@smallexample
(gdb) c
Continuing.

Program exited normally.
(gdb)
@end smallexample
@end ifset


@node Performance Considerations
@chapter Performance Considerations
@cindex Performance

@noindent
The GNAT system provides a number of options that allow a trade-off
between

@itemize @bullet
@item
performance of the generated code

@item
speed of compilation

@item
minimization of dependences and recompilation

@item
the degree of run-time checking.
@end itemize

@noindent
The defaults (if no options are selected) aim at improving the speed
of compilation and minimizing dependences, at the expense of performance
of the generated code:

@itemize @bullet
@item
no optimization

@item
no inlining of subprogram calls

@item
all run-time checks enabled except overflow and elaboration checks
@end itemize

@noindent
These options are suitable for most program development purposes. This
chapter describes how you can modify these choices, and also provides
some guidelines on debugging optimized code.

@menu
* Controlling Run-Time Checks::
* Optimization Levels::
* Debugging Optimized Code::
* Inlining of Subprograms::
@ifset vms
* Coverage Analysis::
@end ifset
@end menu

@node Controlling Run-Time Checks
@section Controlling Run-Time Checks

@noindent
By default, GNAT generates all run-time checks, except arithmetic overflow
checking for integer operations and checks for access before elaboration on
subprogram calls. The latter are not required in default mode, because all
necessary checking is done at compile time.
@cindex @option{-gnatp} (@code{gcc})
@cindex @option{-gnato} (@code{gcc})
Two gnat switches, @option{-gnatp} and @option{-gnato} allow this default to
be modified. @xref{Run-Time Checks}.

Our experience is that the default is suitable for most development
purposes.

We treat integer overflow specially because these
are quite expensive and in our experience are not as important as other
run-time checks in the development process. Note that division by zero
is not considered an overflow check, and divide by zero checks are
generated where required by default.

Elaboration checks are off by default, and also not needed by default, since
GNAT uses a static elaboration analysis approach that avoids the need for
run-time checking. This manual contains a full chapter discussing the issue
of elaboration checks, and if the default is not satisfactory for your use,
you should read this chapter.

For validity checks, the minimal checks required by the Ada Reference
Manual (for case statements and assignments to array elements) are on
by default. These can be suppressed by use of the @option{-gnatVn} switch.
Note that in Ada 83, there were no validity checks, so if the Ada 83 mode
is acceptable (or when comparing GNAT performance with an Ada 83 compiler),
it may be reasonable to routinely use @option{-gnatVn}. Validity checks
are also suppressed entirely if @option{-gnatp} is used.

@cindex Overflow checks
@cindex Checks, overflow
@findex Suppress
@findex Unsuppress
@cindex pragma Suppress
@cindex pragma Unsuppress
Note that the setting of the switches controls the default setting of
the checks. They may be modified using either @code{pragma Suppress} (to
remove checks) or @code{pragma Unsuppress} (to add back suppressed
checks) in the program source.

@node Optimization Levels
@section Optimization Levels
@cindex @code{^-O^/OPTIMIZE^} (@code{gcc})

@noindent
The default is optimization off. This results in the fastest compile
times, but GNAT makes absolutely no attempt to optimize, and the
generated programs are considerably larger and slower than when
optimization is enabled. You can use the
@ifclear vms
@code{-O@var{n}} switch, where @var{n} is an integer from 0 to 3,
@end ifclear
@ifset vms
@code{^-O^/OPTIMIZE^}
@end ifset
on the @code{gcc} command line to control the optimization level:

@table @code
@item -O0
no optimization (the default)

@item -O1
medium level optimization

@item -O2
full optimization

@item -O3
full optimization, and also attempt automatic inlining of small
subprograms within a unit (@pxref{Inlining of Subprograms}).
@end table

Higher optimization levels perform more global transformations on the
program and apply more expensive analysis algorithms in order to generate
faster and more compact code. The price in compilation time, and the
resulting improvement in execution time,
both depend on the particular application and the hardware environment.
You should experiment to find the best level for your application.

Note: Unlike some other compilation systems, @code{gcc} has
been tested extensively at all optimization levels. There are some bugs
which appear only with optimization turned on, but there have also been
bugs which show up only in @emph{unoptimized} code. Selecting a lower
level of optimization does not improve the reliability of the code
generator, which in practice is highly reliable at all optimization
levels.

Note regarding the use of @code{-O3}: The use of this optimization level
is generally discouraged with GNAT, since it often results in larger
executables which run more slowly. See further discussion of this point
in @pxref{Inlining of Subprograms}.

@node Debugging Optimized Code
@section Debugging Optimized Code

@noindent
Since the compiler generates debugging tables for a compilation unit before
it performs optimizations, the optimizing transformations may invalidate some
of the debugging data.  You therefore need to anticipate certain
anomalous situations that may arise while debugging optimized code.  This
section describes the most common cases.

@enumerate
@item
@i{The "hopping Program Counter":}  Repeated 'step' or 'next' commands show the PC
bouncing back and forth in the code.  This may result from any of the following
optimizations:

@itemize @bullet
@item
@i{Common subexpression elimination:} using a single instance of code for a
quantity that the source computes several times.  As a result you
may not be able to stop on what looks like a statement.

@item
@i{Invariant code motion:} moving an expression that does not change within a
loop, to the beginning of the loop.

@item
@i{Instruction scheduling:} moving instructions so as to
overlap loads and stores (typically) with other code, or in
general to move computations of values closer to their uses. Often
this causes you to pass an assignment statement without the assignment
happening and then later bounce back to the statement when the
value is actually needed.  Placing a breakpoint on a line of code
and then stepping over it may, therefore, not always cause all the
expected side-effects.
@end itemize

@item
@i{The "big leap":} More commonly known as @i{cross-jumping}, in which two
identical pieces of code are merged and the program counter suddenly
jumps to a statement that is not supposed to be executed, simply because
it (and the code following) translates to the same thing as the code
that @emph{was} supposed to be executed.  This effect is typically seen in
sequences that end in a jump, such as a @code{goto}, a @code{return}, or
a @code{break} in a C @code{switch} statement.

@item
@i{The "roving variable":} The symptom is an unexpected value in a variable.
There are various reasons for this effect:

@itemize @bullet
@item
In a subprogram prologue, a parameter may not yet have been moved to its
"home".

@item
A variable may be dead, and its register re-used.  This is
probably the most common cause.

@item
As mentioned above, the assignment of a value to a variable may
have been moved.

@item
A variable may be eliminated entirely by value propagation or
other means.  In this case, GCC may incorrectly generate debugging
information for the variable
@end itemize

@noindent
In general, when an unexpected value appears for a local variable or parameter
you should first ascertain if that value was actually computed by
your program, as opposed to being incorrectly reported by the debugger.
Record fields or
array elements in an object designated by an access value
are generally less of a problem, once you have ascertained that the access value
is sensible.
Typically, this means checking variables in the preceding code and in the
calling subprogram to verify that the value observed is explainable from other
values (one must apply the procedure recursively to those
other values); or re-running the code and stopping a little earlier
(perhaps before the call) and stepping to better see how the variable obtained
the value in question; or continuing to step @emph{from} the point of the
strange value to see if code motion had simply moved the variable's
assignments later.
@end enumerate

@node Inlining of Subprograms
@section Inlining of Subprograms

@noindent
A call to a subprogram in the current unit is inlined if all the
following conditions are met:

@itemize @bullet
@item
The optimization level is at least @code{-O1}.

@item
The called subprogram is suitable for inlining: It must be small enough
and not contain nested subprograms or anything else that @code{gcc}
cannot support in inlined subprograms.

@item
The call occurs after the definition of the body of the subprogram.

@item
@cindex pragma Inline
@findex Inline
Either @code{pragma Inline} applies to the subprogram or it is
small and automatic inlining (optimization level @code{-O3}) is
specified.
@end itemize

@noindent
Calls to subprograms in @code{with}'ed units are normally not inlined.
To achieve this level of inlining, the following conditions must all be
true:

@itemize @bullet
@item
The optimization level is at least @code{-O1}.

@item
The called subprogram is suitable for inlining: It must be small enough
and not contain nested subprograms or anything else @code{gcc} cannot
support in inlined subprograms.

@item
The call appears in a body (not in a package spec).

@item
There is a @code{pragma Inline} for the subprogram.

@item
@cindex @option{-gnatn} (@code{gcc})
The @code{^-gnatn^/INLINE^} switch
is used in the @code{gcc} command line
@end itemize

Note that specifying the @option{-gnatn} switch causes additional
compilation dependencies. Consider the following:

@smallexample
@group
@cartouche
@b{package} R @b{is}
   @b{procedure} Q;
   @b{pragma} Inline (Q);
@b{end} R;
@b{package body} R @b{is}
   ...
@b{end} R;

@b{with} R;
@b{procedure} Main @b{is}
@b{begin}
   ...
   R.Q;
@b{end} Main;
@end cartouche
@end group
@end smallexample

@noindent
With the default behavior (no @option{-gnatn} switch specified), the
compilation of the @code{Main} procedure depends only on its own source,
@file{main.adb}, and the spec of the package in file @file{r.ads}. This
means that editing the body of @code{R} does not require recompiling
@code{Main}.

On the other hand, the call @code{R.Q} is not inlined under these
circumstances. If the @option{-gnatn} switch is present when @code{Main}
is compiled, the call will be inlined if the body of @code{Q} is small
enough, but now @code{Main} depends on the body of @code{R} in
@file{r.adb} as well as on the spec. This means that if this body is edited,
the main program must be recompiled. Note that this extra dependency
occurs whether or not the call is in fact inlined by @code{gcc}.

The use of front end inlining with @option{-gnatN} generates similar
additional dependencies.

@cindex @code{^-fno-inline^/INLINE=SUPPRESS^} (@code{gcc})
Note: The @code{^-fno-inline^/INLINE=SUPPRESS^} switch
can be used to prevent
all inlining. This switch overrides all other conditions and ensures
that no inlining occurs. The extra dependences resulting from
@option{-gnatn} will still be active, even if
this switch is used to suppress the resulting inlining actions.

Note regarding the use of @code{-O3}: There is no difference in inlining
behavior between @code{-O2} and @code{-O3} for subprograms with an explicit
pragma @code{Inline} assuming the use of @option{-gnatn}
or @option{-gnatN} (the switches that activate inlining). If you have used
pragma @code{Inline} in appropriate cases, then it is usually much better
to use @code{-O2} and @option{-gnatn} and avoid the use of @code{-O3} which
in this case only has the effect of inlining subprograms you did not
think should be inlined. We often find that the use of @code{-O3} slows
down code by performing excessive inlining, leading to increased instruction
cache pressure from the increased code size. So the bottom line here is
that you should not automatically assume that @code{-O3} is better than
@code{-O2}, and indeed you should use @code{-O3} only if tests show that
it actually improves performance.

@ifset vms
@node Coverage Analysis
@section Coverage Analysis

@noindent
GNAT supports the Digital Performance Coverage Analyzer (PCA), which allows
the user to determine the distribution of execution time across a program,
@pxref{Profiling} for details of usage.
@end ifset

@include fdl.texi
@c GNU Free Documentation License

@node Index,,GNU Free Documentation License, Top
@unnumbered Index

@printindex cp

@contents

@bye