# Copyright (C) 2007-2017 Free Software Foundation, Inc. # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . # This file was written by Wu Zhou. (woodzltc@cn.ibm.com) # This file is part of the gdb testsuite. It is intended to test that # gdb could correctly handle decimal floating point introduced in IEEE 754R. standard_testfile .c # Try to compile the test case. If we can't, assume the # toolchain does not yet provide DFP support and bail out. if { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable {quiet debug}] != "" } { verbose "Skipping DFP tests." return -1 } clean_restart ${binfile} if ![runto_main] then { perror "couldn't run to breakpoint" continue } set sizeof_long [get_sizeof "long" 4] proc d32_set_tests {} { gdb_test "p d32=123.45df" " = 123.45" gdb_test "p d32=12345.df" " = 12345" gdb_test "p d32=12345.67df" " = 12345.67" gdb_test "p d32=1234567.df" " = 1234567" gdb_test "p d32=1.234567E0df" " = 1.234567" gdb_test "p d32=1.234567E10df" " = 1.234567E\\+10" gdb_test "p d32=1.234567E+96df" " = 1.234567E\\+96" # Test that gdb could handle the max, normalized min and subnormalized min. gdb_test "p d32=9.999999E96df" " = 9.999999E\\+96" gdb_test "p d32=1.0E-95df" " = 1.0E\\-95" gdb_test "p d32=1.E-101df" " = 1E\\-101" gdb_test "p d32=0.000001E-95df" " = 1E\\-101" # Test that gdb could detect coefficient/exponent out of range. # The coefficient out of range will be rounded to its nearest value. # And the exponent out of range will be handled as infinity. gdb_test "p d32=1.2345678df" " = 1.234568" "1.2345678 is rounded to 1.234568" gdb_test "p d32=1.0E-101df" " = 1E-101" "1.0E-101 is rounded to 1E-101" gdb_test "p d32=1.234567E+97df" " = Infinity" "1.234567E+97 is Infinity" # Test that gdb could detect the errors in the string representation of _Decimal32 gdb_test "p d32=12345.df" " = 12345" "12345. is a valid number" gdb_test "p d32=12345df" ".*Invalid number.*" "12345 is an invalid number" gdb_test "p d32=1.23Edf" ".*Conversion syntax.*" "1.23E is an invalid number" gdb_test "p d32=1.23E45Adf" ".*Conversion syntax.*" "1.23E45A is an invalid number" } proc d64_set_tests {} { gdb_test "p d64=123.45dd" " = 123.45" gdb_test "p d64=12345.dd" " = 12345" gdb_test "p d64=12345.67dd" " = 12345.67" gdb_test "p d64=1.234567890123456dd" " = 1.234567890123456" gdb_test "p d64=1.234567890123456E10dd" " = 12345678901.23456" gdb_test "p d64=1.234567890123456E100dd" " = 1.234567890123456E\\+100" gdb_test "p d64=1.234567890123456E384dd" " = 1.234567890123456E\\+384" # Test that gdb could handle the max, normalized min and subnormalized min. gdb_test "p d64=9.999999999999999E384dd" " = 9.999999999999999E\\+384" gdb_test "p d64=1.E-383dd" " = 1E\\-383" gdb_test "p d64=1.E-398dd" " = 1E\\-398" gdb_test "p d64=0.000000000000001E-383dd" " = 1E\\-398" # Test that gdb could detect coefficient/exponent out of range. # The coefficient out of range will be rounded to its nearest value. # And the exponent out of range will be handled as infinity. gdb_test "p d64=1.2345678901234567dd" " = 1.234567890123457" "1.2345678901234567 is rounded to 1.234567890123457" gdb_test "p d64=9.9999999999999999E384dd" " = Infinity" "d64=9.9999999999999999E384 is Infinity" gdb_test "p d64=1.234567890123456E385dd" " = Infinity" "d64=1.234567890123456E385 is Infinity" # Test that gdb could detect the errors in the string representation of _Decimal64 gdb_test "p d64=12345dd" ".*Invalid number.*" "12345dd is an invalid number" gdb_test "p d64=1.23Edd" ".*Conversion syntax.*" "1.23E is an invalid number" gdb_test "p d64=1.23E45Add" ".*Conversion syntax.*" "1.23E45A is an invalid number" } proc d128_set_tests {} { gdb_test "p d128=123.45dl" " = 123.45" gdb_test "p d128=12345.dl" " = 12345" gdb_test "p d128=12345.67dl" " = 12345.67" gdb_test "p d128=1.234567890123456789012345678901234dl" " = 1.234567890123456789012345678901234" gdb_test "p d128=1.234567890123456E10dl" " = 12345678901.23456" gdb_test "p d128=1.234567890123456E100dl" " = 1.234567890123456E\\+100" gdb_test "p d128=1.234567890123456E1000dl" " = 1.234567890123456E\\+1000" # Test that gdb could handle the max, normalized min and subnormalized min. gdb_test "p d128=9.999999999999999999999999999999999E6144dl" " = 9.999999999999999999999999999999999E\\+6144" gdb_test "p d128=1.E-6143dl" " = 1E\\-6143" gdb_test "p d128=1.E-6176dl" " = 1E\\-6176" gdb_test "p d128=0.000000000000000000000000000000001E-6143dl" " = 1E\\-6176" # Test that gdb could detect coefficient/exponent out of range. # The coefficient out of range will be rounded to its nearest value. # And the exponent out of range will be handled as infinity. gdb_test "p d128=1.2345678901234567890123456789012345dl" "1.234567890123456789012345678901234" "1.2345678901234567890123456789012345 is rounded to 1.234567890123456789012345678901234" gdb_test "p d128=1.234567890123456E6145dl" "Infinity" "d128=1.234567890123456E6145 is Infinity" # Test that gdb could detect the errors in the string representation of _Decimal128 gdb_test "p d128=12345dl" ".*Invalid number.*" "12345dl is an invalid number" gdb_test "p d128=1.23Edl" ".*Conversion syntax.*" "1.23E is an invalid number" gdb_test "p d128=1.23E45Adl" ".*Conversion syntax.*" "1.23E45A is an invalid number" } # Different tests on 32-bits decimal floating point, including the printing # of finite numbers, infinite and NaN, and also the setting of different # decimal value. if [gdb_test "next" \ ".*Positive infd32.*" \ "next after initializing d32"] then { gdb_suppress_tests } gdb_test "print d32" "1.2345" "d32 is initialized to 1.2345" if [gdb_test "next" \ ".*Negative infd32.*" \ "next after assigning builtin infinity to d32"] then { gdb_suppress_tests } gdb_test "print d32" "Infinity" "d32 is positive Infinity" if [gdb_test "next" \ ".*__builtin_nand32.*" \ "next after assigning negative builtin infinity to d32"] then { gdb_suppress_tests } gdb_test "print d32" "-Infinity" "d32 is negative Infinity" if [gdb_test "next" \ ".*d64 = 1.2345.*" \ "next after assigning builtin NaN to d32"] then { gdb_suppress_tests } gdb_test "print d32" "NaN" "d32 is NaN" d32_set_tests # Different tests on 64-bits decimal floating point, including the display # of finite number, infinite and NaN, and also the setting of different # decimal value. if [gdb_test "next" \ ".*Positive infd64.*" \ "next after initializing d64"] then { gdb_suppress_tests } gdb_test "print d64" "1.2345" "d64 is initialized to 1.2345" if [gdb_test "next" \ ".*Negative infd64.*" \ "next after assigning builtin infinity to d64"] then { gdb_suppress_tests } gdb_test "print d64" "Infinity" "d64 is positive Infinity" if [gdb_test "next" \ ".*__builtin_nand64.*" \ "next after assigning negative builtin infinity to d64"] then { gdb_suppress_tests } gdb_test "print d64" "-Infinity" "d64 is negative Infinity" if [gdb_test "next" \ ".*d128 = 1.2345.*" \ "next after assigning builtin NaN to d64"] then { gdb_suppress_tests } gdb_test "print d64" "NaN" "d64 is NaN" d64_set_tests # Different tests on 128-bits decimal floating point, including the display # of finite number, infinite and NaN, and also the setting of different # decimal value. if [gdb_test "next" \ ".*Positive infd128.*" \ "next after initializing d128"] then { gdb_suppress_tests } gdb_test "print d128" "1.2345" "d128 is initialized to 1.2345" d128_set_tests if [gdb_test "next" \ ".*Negative infd128.*" \ "next after assigning builtin infinity to d128"] then { gdb_suppress_tests } gdb_test "print d128" "Infinity" "d128 is positive Infinity" if [gdb_test "next" \ ".*__builtin_nand128.*" \ "next after assigning negative builtin infinity to d128"] then { gdb_suppress_tests } gdb_test "print d128" "-Infinity" "d128 is negative Infinity" if [gdb_test "next" \ ".*arg0_32.*" \ "next after assigning builtin NaN to d128"] then { gdb_suppress_tests } gdb_test "print d128" "NaN" "d128 is NaN" # The following tests are intended to verify that gdb can correctly handle # DFP types in function arguments. gdb_breakpoint arg0_32 gdb_continue_to_breakpoint "entry to arg0_32" gdb_test "backtrace" ".*arg0_32 \\(arg0=0.1, arg1=1.0, arg2=2.0, arg3=3.0, arg4=4.0, arg5=5.0\\).*" "backtrace at arg0_32" gdb_breakpoint arg0_64 gdb_continue_to_breakpoint "entry to arg0_64" gdb_test "backtrace" ".*arg0_64 \\(arg0=0.1, arg1=1.0, arg2=2.0, arg3=3.0, arg4=4.0, arg5=5.0\\).*" "backtrace at arg0_64" gdb_breakpoint arg0_128 gdb_continue_to_breakpoint "entry to arg0_128" gdb_test "backtrace" ".*arg0_128 \\(arg0=0.1, arg1=1.0, arg2=2.0, arg3=3.0, arg4=4.0, arg5=5.0\\).*" "backtrace at arg0_128" # Test calling inferior function with DFP arguments or return value. gdb_test "call arg0_32 (1.2df, 2.2df, 3.2df, 4.2df, 5.2df, 6.2df)" "Breakpoint.*arg0_32.*" "call function with correct _Decimal32 arguments." gdb_test "backtrace 1" "\n#\[0-9\]+ arg0_32 \\(arg0=1.2, arg1=2.2, arg2=3.2, arg3=4.2, arg4=5.2, arg5=6.2\\).*" "backtrace function with correct _Decimal32 arguments." gdb_test "finish" " = 1.2" "correct _Decimal32 return value from called function." gdb_test "call arg0_64 (1.2dd, 2.2dd, 3.2dd, 4.2dd, 5.2dd, 6.2dd)" "Breakpoint.*arg0_64.*" "call function with correct _Decimal64 arguments." gdb_test "backtrace 1" "\n#\[0-9\]+ arg0_64 \\(arg0=1.2, arg1=2.2, arg2=3.2, arg3=4.2, arg4=5.2, arg5=6.2\\).*" "backtrace function with correct _Decimal64 arguments." gdb_test "finish" " = 1.2" "correct _Decimal64 return value from called function." gdb_test "call arg0_128 (1.2dl, 2.2dl, 3.2dl, 4.2dl, 5.2dl, 6.2dl)" "Breakpoint.*arg0_128.*" "call function with correct _Decimal128 arguments." gdb_test "backtrace 1" "\n#\[0-9\]+ arg0_128 \\(arg0=1.2, arg1=2.2, arg2=3.2, arg3=4.2, arg4=5.2, arg5=6.2\\).*" "backtrace function with correct _Decimal128 arguments." gdb_test "finish" " = 1.2" "correct _Decimal128 return value from called function." gdb_test "call decimal_dec128_align (double_val1, dec128_val2, double_val3, double_val4, double_val5, double_val6, double_val7, double_val8, double_val9, double_val10, double_val11, double_val12, double_val13, double_val14)" " = 1" \ "Call function with mixed decimal float arguments TEST." gdb_test "call decimal_mixed (dec32_val1, dec64_val1, dec128_val1)" " = 1" \ "Call function with mixed decimal float arguments." gdb_test "call decimal_many_args_dec32 (dec32_val1, dec32_val2, dec32_val3, dec32_val4, dec32_val5, dec32_val6, dec32_val7, dec32_val8, dec32_val9, dec32_val10, dec32_val11, dec32_val12, dec32_val13, dec32_val14, dec32_val15, dec32_val16)" " = 1" \ "Call function with many _Decimal32 arguments." gdb_test "call decimal_many_args_dec64 (dec64_val1, dec64_val2, dec64_val3, dec64_val4, dec64_val5, dec64_val6, dec64_val7, dec64_val8, dec64_val9, dec64_val10, dec64_val11, dec64_val12, dec64_val13, dec64_val14, dec64_val15, dec64_val16)" " = 1" \ "Call function with many _Decimal64 arguments." gdb_test "call decimal_many_args_dec128 (dec128_val1, dec128_val2, dec128_val3, dec128_val4, dec128_val5, dec128_val6, dec128_val7, dec128_val8, dec128_val9, dec128_val10, dec128_val11, dec128_val12, dec128_val13, dec128_val14, dec128_val15, dec128_val16)" " = 1" \ "Call function with many _Decimal128 arguments." gdb_test "call decimal_many_args_mixed (dec32_val1, dec32_val2, dec32_val3, dec64_val4, dec64_val5, dec64_val6, dec64_val7, dec128_val8, dec128_val9, dec128_val10, dec32_val11, dec64_val12, dec32_val13, dec64_val14, dec128_val15)" " = 1" \ "Call function with many mixed decimal float arguments." # The following tests are intended to verify that gdb can handle DFP types # correctly in struct. gdb_breakpoint [gdb_get_line_number "Exit point"] gdb_continue_to_breakpoint "Setting a decimal struct" gdb_test "print ds.dec32" " = 1.2345" gdb_test "print ds.dec64" " = 1.2345" gdb_test "print ds.dec128" " = 1.2345" # Test expressions with DFP variables. gdb_test "print d32 + ds.dec32" " = 1.3345" gdb_test "print d64 + ds.dec64" " = 1.3345" gdb_test "print d128 + ds.dec128" " = 1.3345" # Test conversion between different _Decimal sizes. gdb_test "ptype d64 + ds.dec32" " = volatile _Decimal64" gdb_test "ptype d128 + ds.dec32" " = volatile _Decimal128" gdb_test "ptype d128 + ds.dec64" " = volatile _Decimal128" gdb_test "whatis d64 + ds.dec32" " = volatile _Decimal64" gdb_test "whatis d128 + ds.dec32" " = volatile _Decimal128" gdb_test "whatis d128 + ds.dec64" " = volatile _Decimal128" # Mixture of Decimal and integral operands gdb_test "p d32 + 1" " = 1.1" gdb_test "p 2 + d64" " = 2.1" gdb_test "p ds.int4 + d128" " = 1.1" gdb_test "p d32 + ds.long8" " = 2.1" gdb_test "ptype d32 + 1" " = volatile _Decimal32" gdb_test "ptype ds.int4 + d128" " = volatile _Decimal128" # Test other operations with DFP operands gdb_test "p !d32" " = 0" gdb_test "p !d64" " = 0" gdb_test "p !d128" " = 0" gdb_test "p +d32" " = 0.1" gdb_test "p +d64" " = 0.1" gdb_test "p +d128" " = 0.1" gdb_test "p d64 == d128" " = 1" gdb_test "p d128 == ds.dec32" " = 0" gdb_test "p d128 == d32" " = 1" gdb_test "p ds.dec32 == ds.dec64" " = 1" gdb_test "p d32 < ds.dec32" " = 1" gdb_test "p d64 < ds.dec64" " = 1" gdb_test "p d128 < ds.dec128" " = 1" gdb_test "p ds.dec32 < d32" " = 0" gdb_test "p d64 > ds.dec64" " = 0" gdb_test "p ds.dec128 > d128 " " = 1" gdb_test "p d32 < ds.int4" " = 1" gdb_test "p ds.int4 > d32" " = 1" gdb_test "p ds.dec32 < ds.int4" " = 0" gdb_test "p ds.int4 > ds.dec64" " = 0" gdb_test "p ds.dec128 > ds.int4" " = 1" # Reject operation with DFP and Binary FP gdb_test "p d64 + ds.float4" "Mixing decimal floating types with other floating types is not allowed." gdb_test "p ds.double8 + d128" "Mixing decimal floating types with other floating types is not allowed." # The following tests are intended to verify that gdb can handle "d1=d2" # and "d1=-d2" correctly. gdb_test "print ds.dec32=d32" " = 0.1" gdb_test "print ds.dec64=d64" " = 0.1" gdb_test "print ds.dec128=d128" " = 0.1" gdb_test "print ds.dec32 = -d32" " = -0.1" gdb_test "print ds.dec64 = -d64" " = -0.1" gdb_test "print ds.dec128 = -d128" " = -0.1" # Test cast to and from DFP values gdb_test "print ds.double8 = ds.dec64" " = -0.(0999.*|1000.*)" gdb_test "print ds.dec64 = ds.float4" " = 3.(0999.*|1000.*)" gdb_test "print ds.dec128 = -ds.double8" " = 0.(0999.*|1000.*)" gdb_test "print ds.dec128 = ds.dec32" " = -0.1" gdb_test "print ds.dec32 = ds.int4" " = 1" gdb_test "print ds.int4 = 7.3dl" " = 7" # Test "whatis"/"ptype" of expressions involving casts to/from dfp # typedefs. # This list is composed by sub-lists, and their elements are (in # order): # # - Type to cast to. This is also what "whatis" should print. # - What "ptype" should print. # Columns in the sublists represent: # to/whatis # ptype foreach elem { {"_Decimal32" "_Decimal32"} {"_Decimal64" "_Decimal64"} {"_Decimal128" "_Decimal128"} {"d32_t" "_Decimal32"} {"d64_t" "_Decimal64"} {"d128_t" "_Decimal128"} {"d32_t2" "_Decimal32"} {"d64_t2" "_Decimal64"} {"d128_t2" "_Decimal128"} } { set type [lindex $elem 0] set ptype [lindex $elem 1] gdb_test "whatis ($type) 0" " = $type" gdb_test "ptype ($type) 0" " = $ptype" } # Test: # - whatis/ptype of variables of typedef type. # - whatis/ptype of typedef type names. # - whatis/ptype of typedef-of-typedef type names. # Columns in the sublists represent: # Type name # whatis # ptype foreach elem { {"v_d32_t" "d32_t" "_Decimal32"} {"v_d64_t" "d64_t" "_Decimal64"} {"v_d128_t" "d128_t" "_Decimal128"} {"d32_t" "_Decimal32" "_Decimal32"} {"d64_t" "_Decimal64" "_Decimal64"} {"d128_t" "_Decimal128" "_Decimal128"} {"d32_t2" "d32_t" "_Decimal32"} {"d64_t2" "d64_t" "_Decimal64"} {"d128_t2" "d128_t" "_Decimal128"} } { set type [lindex $elem 0] set whatis [lindex $elem 1] set ptype [lindex $elem 2] gdb_test "whatis $type" " = $whatis" gdb_test "ptype $type" " = $ptype" }