/* * Copyright 2011 Steven Watanabe * Distributed under the Boost Software License, Version 1.0. * (See accompanying file LICENSE_1_0.txt or copy at * http://www.boost.org/LICENSE_1_0.txt) */ #include "jam.h" #include "function.h" #include "class.h" #include "compile.h" #include "constants.h" #include "filesys.h" #include "frames.h" #include "lists.h" #include "mem.h" #include "pathsys.h" #include "rules.h" #include "search.h" #include "variable.h" #include #include #include #include #ifdef OS_CYGWIN # include # include # ifdef CYGWIN_VERSION_CYGWIN_CONV # include # endif # include #endif int glob( char const * s, char const * c ); void backtrace( FRAME * ); void backtrace_line( FRAME * ); #define INSTR_PUSH_EMPTY 0 #define INSTR_PUSH_CONSTANT 1 #define INSTR_PUSH_ARG 2 #define INSTR_PUSH_VAR 3 #define INSTR_PUSH_VAR_FIXED 57 #define INSTR_PUSH_GROUP 4 #define INSTR_PUSH_RESULT 5 #define INSTR_PUSH_APPEND 6 #define INSTR_SWAP 7 #define INSTR_JUMP_EMPTY 8 #define INSTR_JUMP_NOT_EMPTY 9 #define INSTR_JUMP 10 #define INSTR_JUMP_LT 11 #define INSTR_JUMP_LE 12 #define INSTR_JUMP_GT 13 #define INSTR_JUMP_GE 14 #define INSTR_JUMP_EQ 15 #define INSTR_JUMP_NE 16 #define INSTR_JUMP_IN 17 #define INSTR_JUMP_NOT_IN 18 #define INSTR_JUMP_NOT_GLOB 19 #define INSTR_FOR_INIT 56 #define INSTR_FOR_LOOP 20 #define INSTR_SET_RESULT 21 #define INSTR_RETURN 22 #define INSTR_POP 23 #define INSTR_PUSH_LOCAL 24 #define INSTR_POP_LOCAL 25 #define INSTR_SET 26 #define INSTR_APPEND 27 #define INSTR_DEFAULT 28 #define INSTR_PUSH_LOCAL_FIXED 58 #define INSTR_POP_LOCAL_FIXED 59 #define INSTR_SET_FIXED 60 #define INSTR_APPEND_FIXED 61 #define INSTR_DEFAULT_FIXED 62 #define INSTR_PUSH_LOCAL_GROUP 29 #define INSTR_POP_LOCAL_GROUP 30 #define INSTR_SET_GROUP 31 #define INSTR_APPEND_GROUP 32 #define INSTR_DEFAULT_GROUP 33 #define INSTR_PUSH_ON 34 #define INSTR_POP_ON 35 #define INSTR_SET_ON 36 #define INSTR_APPEND_ON 37 #define INSTR_DEFAULT_ON 38 #define INSTR_GET_ON 65 #define INSTR_CALL_RULE 39 #define INSTR_CALL_MEMBER_RULE 66 #define INSTR_APPLY_MODIFIERS 40 #define INSTR_APPLY_INDEX 41 #define INSTR_APPLY_INDEX_MODIFIERS 42 #define INSTR_APPLY_MODIFIERS_GROUP 43 #define INSTR_APPLY_INDEX_GROUP 44 #define INSTR_APPLY_INDEX_MODIFIERS_GROUP 45 #define INSTR_COMBINE_STRINGS 46 #define INSTR_GET_GRIST 64 #define INSTR_INCLUDE 47 #define INSTR_RULE 48 #define INSTR_ACTIONS 49 #define INSTR_PUSH_MODULE 50 #define INSTR_POP_MODULE 51 #define INSTR_CLASS 52 #define INSTR_BIND_MODULE_VARIABLES 63 #define INSTR_APPEND_STRINGS 53 #define INSTR_WRITE_FILE 54 #define INSTR_OUTPUT_STRINGS 55 typedef struct instruction { unsigned int op_code; int arg; } instruction; typedef struct _subfunction { OBJECT * name; FUNCTION * code; int local; } SUBFUNCTION; typedef struct _subaction { OBJECT * name; FUNCTION * command; int flags; } SUBACTION; #define FUNCTION_BUILTIN 0 #define FUNCTION_JAM 1 struct argument { int flags; #define ARG_ONE 0 #define ARG_OPTIONAL 1 #define ARG_PLUS 2 #define ARG_STAR 3 #define ARG_VARIADIC 4 OBJECT * type_name; OBJECT * arg_name; int index; }; struct arg_list { int size; struct argument * args; }; struct _function { int type; int reference_count; OBJECT * rulename; struct arg_list * formal_arguments; int num_formal_arguments; }; typedef struct _builtin_function { FUNCTION base; LIST * ( * func )( FRAME *, int flags ); int flags; } BUILTIN_FUNCTION; typedef struct _jam_function { FUNCTION base; int code_size; instruction * code; int num_constants; OBJECT * * constants; int num_subfunctions; SUBFUNCTION * functions; int num_subactions; SUBACTION * actions; FUNCTION * generic; OBJECT * file; int line; } JAM_FUNCTION; #ifdef HAVE_PYTHON #define FUNCTION_PYTHON 2 typedef struct _python_function { FUNCTION base; PyObject * python_function; } PYTHON_FUNCTION; static LIST * call_python_function( PYTHON_FUNCTION *, FRAME * ); #endif struct _stack { void * data; }; static void * stack; STACK * stack_global() { static STACK result; if ( !stack ) { int const size = 1 << 21; stack = BJAM_MALLOC( size ); result.data = (char *)stack + size; } return &result; } struct list_alignment_helper { char ch; LIST * l; }; #define LISTPTR_ALIGN_BASE ( sizeof( struct list_alignment_helper ) - sizeof( LIST * ) ) #define LISTPTR_ALIGN ( ( LISTPTR_ALIGN_BASE > sizeof( LIST * ) ) ? sizeof( LIST * ) : LISTPTR_ALIGN_BASE ) static void check_alignment( STACK * s ) { assert( (size_t)s->data % LISTPTR_ALIGN == 0 ); } void * stack_allocate( STACK * s, int size ) { check_alignment( s ); s->data = (char *)s->data - size; check_alignment( s ); return s->data; } void stack_deallocate( STACK * s, int size ) { check_alignment( s ); s->data = (char *)s->data + size; check_alignment( s ); } void stack_push( STACK * s, LIST * l ) { *(LIST * *)stack_allocate( s, sizeof( LIST * ) ) = l; } LIST * stack_pop( STACK * s ) { LIST * const result = *(LIST * *)s->data; stack_deallocate( s, sizeof( LIST * ) ); return result; } LIST * stack_top( STACK * s ) { check_alignment( s ); return *(LIST * *)s->data; } LIST * stack_at( STACK * s, int n ) { check_alignment( s ); return *( (LIST * *)s->data + n ); } void stack_set( STACK * s, int n, LIST * value ) { check_alignment( s ); *((LIST * *)s->data + n) = value; } void * stack_get( STACK * s ) { check_alignment( s ); return s->data; } LIST * frame_get_local( FRAME * frame, int idx ) { /* The only local variables are the arguments. */ return list_copy( lol_get( frame->args, idx ) ); } static OBJECT * function_get_constant( JAM_FUNCTION * function, int idx ) { return function->constants[ idx ]; } static LIST * function_get_variable( JAM_FUNCTION * function, FRAME * frame, int idx ) { return list_copy( var_get( frame->module, function->constants[ idx ] ) ); } static void function_set_variable( JAM_FUNCTION * function, FRAME * frame, int idx, LIST * value ) { var_set( frame->module, function->constants[ idx ], value, VAR_SET ); } static LIST * function_swap_variable( JAM_FUNCTION * function, FRAME * frame, int idx, LIST * value ) { return var_swap( frame->module, function->constants[ idx ], value ); } static void function_append_variable( JAM_FUNCTION * function, FRAME * frame, int idx, LIST * value ) { var_set( frame->module, function->constants[ idx ], value, VAR_APPEND ); } static void function_default_variable( JAM_FUNCTION * function, FRAME * frame, int idx, LIST * value ) { var_set( frame->module, function->constants[ idx ], value, VAR_DEFAULT ); } static void function_set_rule( JAM_FUNCTION * function, FRAME * frame, STACK * s, int idx ) { SUBFUNCTION * sub = function->functions + idx; new_rule_body( frame->module, sub->name, sub->code, !sub->local ); } static void function_set_actions( JAM_FUNCTION * function, FRAME * frame, STACK * s, int idx ) { SUBACTION * sub = function->actions + idx; LIST * bindlist = stack_pop( s ); new_rule_actions( frame->module, sub->name, sub->command, bindlist, sub->flags ); } /* * Returns the index if name is "<", ">", "1", "2", ... or "19" otherwise * returns -1. */ static int get_argument_index( char const * s ) { if ( s[ 0 ] != '\0') { if ( s[ 1 ] == '\0' ) { switch ( s[ 0 ] ) { case '<': return 0; case '>': return 1; case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': return s[ 0 ] - '1'; } } else if ( s[ 0 ] == '1' && s[ 2 ] == '\0' ) { switch( s[ 1 ] ) { case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': return s[ 1 ] - '0' + 10 - 1; } } } return -1; } static LIST * function_get_named_variable( JAM_FUNCTION * function, FRAME * frame, OBJECT * name ) { int const idx = get_argument_index( object_str( name ) ); return idx == -1 ? list_copy( var_get( frame->module, name ) ) : list_copy( lol_get( frame->args, idx ) ); } static void function_set_named_variable( JAM_FUNCTION * function, FRAME * frame, OBJECT * name, LIST * value) { var_set( frame->module, name, value, VAR_SET ); } static LIST * function_swap_named_variable( JAM_FUNCTION * function, FRAME * frame, OBJECT * name, LIST * value ) { return var_swap( frame->module, name, value ); } static void function_append_named_variable( JAM_FUNCTION * function, FRAME * frame, OBJECT * name, LIST * value) { var_set( frame->module, name, value, VAR_APPEND ); } static void function_default_named_variable( JAM_FUNCTION * function, FRAME * frame, OBJECT * name, LIST * value ) { var_set( frame->module, name, value, VAR_DEFAULT ); } static LIST * function_call_rule( JAM_FUNCTION * function, FRAME * frame, STACK * s, int n_args, char const * unexpanded, OBJECT * file, int line ) { FRAME inner[ 1 ]; int i; LIST * first = stack_pop( s ); LIST * result = L0; OBJECT * rulename; LIST * trailing; frame->file = file; frame->line = line; if ( list_empty( first ) ) { backtrace_line( frame ); printf( "warning: rulename %s expands to empty string\n", unexpanded ); backtrace( frame ); list_free( first ); for ( i = 0; i < n_args; ++i ) list_free( stack_pop( s ) ); return result; } rulename = object_copy( list_front( first ) ); frame_init( inner ); inner->prev = frame; inner->prev_user = frame->module->user_module ? frame : frame->prev_user; inner->module = frame->module; /* This gets fixed up in evaluate_rule(). */ for ( i = 0; i < n_args; ++i ) lol_add( inner->args, stack_at( s, n_args - i - 1 ) ); for ( i = 0; i < n_args; ++i ) stack_pop( s ); trailing = list_pop_front( first ); if ( trailing ) { if ( inner->args->count == 0 ) lol_add( inner->args, trailing ); else { LIST * * const l = &inner->args->list[ 0 ]; *l = list_append( trailing, *l ); } } result = evaluate_rule( bindrule( rulename, inner->module ), rulename, inner ); frame_free( inner ); object_free( rulename ); return result; } static LIST * function_call_member_rule( JAM_FUNCTION * function, FRAME * frame, STACK * s, int n_args, OBJECT * rulename, OBJECT * file, int line ) { FRAME inner[ 1 ]; int i; LIST * first = stack_pop( s ); LIST * result = L0; LIST * trailing; RULE * rule; module_t * module; OBJECT * real_rulename = 0; frame->file = file; frame->line = line; if ( list_empty( first ) ) { backtrace_line( frame ); printf( "warning: object is empty\n" ); backtrace( frame ); list_free( first ); for( i = 0; i < n_args; ++i ) { list_free( stack_pop( s ) ); } return result; } /* FIXME: handle generic case */ assert( list_length( first ) == 1 ); module = bindmodule( list_front( first ) ); if ( module->class_module ) { rule = bindrule( rulename, module ); real_rulename = object_copy( function_rulename( rule->procedure ) ); } else { string buf[ 1 ]; string_new( buf ); string_append( buf, object_str( list_front( first ) ) ); string_push_back( buf, '.' ); string_append( buf, object_str( rulename ) ); real_rulename = object_new( buf->value ); string_free( buf ); rule = bindrule( real_rulename, frame->module ); } frame_init( inner ); inner->prev = frame; inner->prev_user = frame->module->user_module ? frame : frame->prev_user; inner->module = frame->module; /* This gets fixed up in evaluate_rule(), below. */ for( i = 0; i < n_args; ++i ) { lol_add( inner->args, stack_at( s, n_args - i - 1 ) ); } for( i = 0; i < n_args; ++i ) { stack_pop( s ); } if ( list_length( first ) > 1 ) { string buf[ 1 ]; LIST * trailing = L0; LISTITER iter = list_begin( first ), end = list_end( first ); iter = list_next( iter ); string_new( buf ); for ( ; iter != end; iter = list_next( iter ) ) { string_append( buf, object_str( list_item( iter ) ) ); string_push_back( buf, '.' ); string_append( buf, object_str( rulename ) ); trailing = list_push_back( trailing, object_new( buf->value ) ); string_truncate( buf, 0 ); } string_free( buf ); if ( inner->args->count == 0 ) lol_add( inner->args, trailing ); else { LIST * * const l = &inner->args->list[ 0 ]; *l = list_append( trailing, *l ); } } result = evaluate_rule( rule, real_rulename, inner ); frame_free( inner ); object_free( rulename ); object_free( real_rulename ); return result; } /* Variable expansion */ typedef struct { int sub1; int sub2; } subscript_t; typedef struct { PATHNAME f; /* :GDBSMR -- pieces */ char parent; /* :P -- go to parent directory */ char filemods; /* one of the above applied */ char downshift; /* :L -- downshift result */ char upshift; /* :U -- upshift result */ char to_slashes; /* :T -- convert "\" to "/" */ char to_windows; /* :W -- convert cygwin to native paths */ PATHPART empty; /* :E -- default for empties */ PATHPART join; /* :J -- join list with char */ } VAR_EDITS; static LIST * apply_modifiers_impl( LIST * result, string * buf, VAR_EDITS * edits, int n, LISTITER iter, LISTITER end ); static void get_iters( subscript_t const subscript, LISTITER * const first, LISTITER * const last, int const length ); /* * var_edit_parse() - parse : modifiers into PATHNAME structure * * The : modifiers in a $(varname:modifier) currently support replacing or * omitting elements of a filename, and so they are parsed into a PATHNAME * structure (which contains pointers into the original string). * * Modifiers of the form "X=value" replace the component X with the given value. * Modifiers without the "=value" cause everything but the component X to be * omitted. X is one of: * * G * D directory name * B base name * S .suffix * M (member) * R root directory - prepended to whole path * * This routine sets: * * f->f_xxx.ptr = 0 * f->f_xxx.len = 0 * -> leave the original component xxx * * f->f_xxx.ptr = string * f->f_xxx.len = strlen( string ) * -> replace component xxx with string * * f->f_xxx.ptr = "" * f->f_xxx.len = 0 * -> omit component xxx * * var_edit_file() below and path_build() obligingly follow this convention. */ static int var_edit_parse( char const * mods, VAR_EDITS * edits, int havezeroed ) { while ( *mods ) { PATHPART * fp; switch ( *mods++ ) { case 'L': edits->downshift = 1; continue; case 'U': edits->upshift = 1; continue; case 'P': edits->parent = edits->filemods = 1; continue; case 'E': fp = &edits->empty; goto strval; case 'J': fp = &edits->join; goto strval; case 'G': fp = &edits->f.f_grist; goto fileval; case 'R': fp = &edits->f.f_root; goto fileval; case 'D': fp = &edits->f.f_dir; goto fileval; case 'B': fp = &edits->f.f_base; goto fileval; case 'S': fp = &edits->f.f_suffix; goto fileval; case 'M': fp = &edits->f.f_member; goto fileval; case 'T': edits->to_slashes = 1; continue; case 'W': edits->to_windows = 1; continue; default: continue; /* Should complain, but so what... */ } fileval: /* Handle :CHARS, where each char (without a following =) selects a * particular file path element. On the first such char, we deselect all * others (by setting ptr = "", len = 0) and for each char we select * that element (by setting ptr = 0). */ edits->filemods = 1; if ( *mods != '=' ) { if ( !havezeroed++ ) { int i; for ( i = 0; i < 6; ++i ) { edits->f.part[ i ].len = 0; edits->f.part[ i ].ptr = ""; } } fp->ptr = 0; continue; } strval: /* Handle :X=value, or :X */ if ( *mods != '=' ) { fp->ptr = ""; fp->len = 0; } else { fp->ptr = ++mods; fp->len = strlen( mods ); mods += fp->len; } } return havezeroed; } /* * var_edit_file() - copy input target name to output, modifying filename. */ static void var_edit_file( char const * in, string * out, VAR_EDITS * edits ) { if ( edits->filemods ) { PATHNAME pathname; /* Parse apart original filename, putting parts into "pathname". */ path_parse( in, &pathname ); /* Replace any pathname with edits->f */ if ( edits->f.f_grist .ptr ) pathname.f_grist = edits->f.f_grist; if ( edits->f.f_root .ptr ) pathname.f_root = edits->f.f_root; if ( edits->f.f_dir .ptr ) pathname.f_dir = edits->f.f_dir; if ( edits->f.f_base .ptr ) pathname.f_base = edits->f.f_base; if ( edits->f.f_suffix.ptr ) pathname.f_suffix = edits->f.f_suffix; if ( edits->f.f_member.ptr ) pathname.f_member = edits->f.f_member; /* If requested, modify pathname to point to parent. */ if ( edits->parent ) path_parent( &pathname ); /* Put filename back together. */ path_build( &pathname, out ); } else string_append( out, in ); } /* * var_edit_cyg2win() - conversion of a cygwin to a Windows path. * * FIXME: skip grist */ #ifdef OS_CYGWIN static void var_edit_cyg2win( string * out, size_t pos, VAR_EDITS * edits ) { if ( edits->to_windows ) { #ifdef CYGWIN_VERSION_CYGWIN_CONV /* Use new Cygwin API added with Cygwin 1.7. Old one had no error * handling and has been deprecated. */ char * dynamicBuffer = 0; char buffer[ MAX_PATH + 1001 ]; char const * result = buffer; cygwin_conv_path_t const conv_type = CCP_POSIX_TO_WIN_A | CCP_RELATIVE; ssize_t const apiResult = cygwin_conv_path( conv_type, out->value + pos, buffer, sizeof( buffer ) / sizeof( *buffer ) ); assert( apiResult == 0 || apiResult == -1 ); assert( apiResult || strlen( result ) < sizeof( buffer ) / sizeof( *buffer ) ); if ( apiResult ) { result = 0; if ( errno == ENOSPC ) { ssize_t const size = cygwin_conv_path( conv_type, out->value + pos, NULL, 0 ); assert( size >= -1 ); if ( size > 0 ) { dynamicBuffer = (char *)BJAM_MALLOC_ATOMIC( size ); if ( dynamicBuffer ) { ssize_t const apiResult = cygwin_conv_path( conv_type, out->value + pos, dynamicBuffer, size ); assert( apiResult == 0 || apiResult == -1 ); if ( !apiResult ) { result = dynamicBuffer; assert( strlen( result ) < size ); } } } } } #else /* CYGWIN_VERSION_CYGWIN_CONV */ /* Use old Cygwin API deprecated with Cygwin 1.7. */ char result[ MAX_PATH + 1 ]; cygwin_conv_to_win32_path( out->value + pos, result ); assert( strlen( result ) <= MAX_PATH ); #endif /* CYGWIN_VERSION_CYGWIN_CONV */ if ( result ) { string_truncate( out, pos ); string_append( out, result ); edits->to_slashes = 0; } #ifdef CYGWIN_VERSION_CYGWIN_CONV if ( dynamicBuffer ) BJAM_FREE( dynamicBuffer ); #endif } } #endif /* OS_CYGWIN */ /* * var_edit_shift() - do upshift/downshift & other mods. */ static void var_edit_shift( string * out, size_t pos, VAR_EDITS * edits ) { #ifdef OS_CYGWIN var_edit_cyg2win( out, pos, edits ); #endif if ( edits->upshift || edits->downshift || edits->to_slashes ) { /* Handle upshifting, downshifting and slash translation now. */ char * p; for ( p = out->value + pos; *p; ++p ) { if ( edits->upshift ) *p = toupper( *p ); else if ( edits->downshift ) *p = tolower( *p ); if ( edits->to_slashes && ( *p == '\\' ) ) *p = '/'; } } } /* * Reads n LISTs from the top of the STACK and combines them to form VAR_EDITS. * Returns the number of VAR_EDITS pushed onto the STACK. */ static int expand_modifiers( STACK * s, int n ) { int i; int total = 1; LIST * * args = stack_get( s ); for ( i = 0; i < n; ++i ) total *= list_length( args[ i ] ); if ( total != 0 ) { VAR_EDITS * out = stack_allocate( s, total * sizeof( VAR_EDITS ) ); LISTITER * iter = stack_allocate( s, n * sizeof( LIST * ) ); for ( i = 0; i < n; ++i ) iter[ i ] = list_begin( args[ i ] ); i = 0; { int havezeroed; loop: memset( out, 0, sizeof( *out ) ); havezeroed = 0; for ( i = 0; i < n; ++i ) havezeroed = var_edit_parse( object_str( list_item( iter[ i ] ) ), out, havezeroed ); ++out; while ( --i >= 0 ) { if ( list_next( iter[ i ] ) != list_end( args[ i ] ) ) { iter[ i ] = list_next( iter[ i ] ); goto loop; } iter[ i ] = list_begin( args[ i ] ); } } stack_deallocate( s, n * sizeof( LIST * ) ); } return total; } static LIST * apply_modifiers( STACK * s, int n ) { LIST * value = stack_top( s ); LIST * result = L0; VAR_EDITS * const edits = (VAR_EDITS *)( (LIST * *)stack_get( s ) + 1 ); string buf[ 1 ]; string_new( buf ); result = apply_modifiers_impl( result, buf, edits, n, list_begin( value ), list_end( value ) ); string_free( buf ); return result; } /* * Parse a string of the form "1-2", "-2--1", "2-" and return the two * subscripts. */ subscript_t parse_subscript( char const * s ) { subscript_t result; result.sub1 = 0; result.sub2 = 0; do /* so we can use "break" */ { /* Allow negative subscripts. */ if ( !isdigit( *s ) && ( *s != '-' ) ) { result.sub2 = 0; break; } result.sub1 = atoi( s ); /* Skip over the first symbol, which is either a digit or dash. */ ++s; while ( isdigit( *s ) ) ++s; if ( *s == '\0' ) { result.sub2 = result.sub1; break; } if ( *s != '-' ) { result.sub2 = 0; break; } ++s; if ( *s == '\0' ) { result.sub2 = -1; break; } if ( !isdigit( *s ) && ( *s != '-' ) ) { result.sub2 = 0; break; } /* First, compute the index of the last element. */ result.sub2 = atoi( s ); while ( isdigit( *++s ) ); if ( *s != '\0' ) result.sub2 = 0; } while ( 0 ); return result; } static LIST * apply_subscript( STACK * s ) { LIST * value = stack_top( s ); LIST * indices = stack_at( s, 1 ); LIST * result = L0; int length = list_length( value ); string buf[ 1 ]; LISTITER indices_iter = list_begin( indices ); LISTITER const indices_end = list_end( indices ); string_new( buf ); for ( ; indices_iter != indices_end; indices_iter = list_next( indices_iter ) ) { LISTITER iter = list_begin( value ); LISTITER end = list_end( value ); subscript_t const subscript = parse_subscript( object_str( list_item( indices_iter ) ) ); get_iters( subscript, &iter, &end, length ); for ( ; iter != end; iter = list_next( iter ) ) result = list_push_back( result, object_copy( list_item( iter ) ) ); } string_free( buf ); return result; } /* * Reads the LIST from first and applies subscript to it. The results are * written to *first and *last. */ static void get_iters( subscript_t const subscript, LISTITER * const first, LISTITER * const last, int const length ) { int start; int size; LISTITER iter; LISTITER end; { if ( subscript.sub1 < 0 ) start = length + subscript.sub1; else if ( subscript.sub1 > length ) start = length; else start = subscript.sub1 - 1; size = subscript.sub2 < 0 ? length + 1 + subscript.sub2 - start : subscript.sub2 - start; /* * HACK: When the first subscript is before the start of the list, it * magically becomes the beginning of the list. This is inconsistent, * but needed for backwards compatibility. */ if ( start < 0 ) start = 0; /* The "sub2 < 0" test handles the semantic error of sub2 < sub1. */ if ( size < 0 ) size = 0; if ( start + size > length ) size = length - start; } iter = *first; while ( start-- > 0 ) iter = list_next( iter ); end = iter; while ( size-- > 0 ) end = list_next( end ); *first = iter; *last = end; } static LIST * apply_modifiers_empty( LIST * result, string * buf, VAR_EDITS * edits, int n ) { int i; for ( i = 0; i < n; ++i ) { if ( edits[ i ].empty.ptr ) { /** FIXME: is empty.ptr always null-terminated? */ var_edit_file( edits[ i ].empty.ptr, buf, edits + i ); var_edit_shift( buf, 0, edits + i ); result = list_push_back( result, object_new( buf->value ) ); string_truncate( buf, 0 ); } } return result; } static LIST * apply_modifiers_non_empty( LIST * result, string * buf, VAR_EDITS * edits, int n, LISTITER begin, LISTITER end ) { int i; LISTITER iter; for ( i = 0; i < n; ++i ) { if ( edits[ i ].join.ptr ) { var_edit_file( object_str( list_item( begin ) ), buf, edits + i ); var_edit_shift( buf, 0, edits + i ); for ( iter = list_next( begin ); iter != end; iter = list_next( iter ) ) { size_t size; string_append( buf, edits[ i ].join.ptr ); size = buf->size; var_edit_file( object_str( list_item( iter ) ), buf, edits + i ); var_edit_shift( buf, size, edits + i ); } result = list_push_back( result, object_new( buf->value ) ); string_truncate( buf, 0 ); } else { for ( iter = begin; iter != end; iter = list_next( iter ) ) { var_edit_file( object_str( list_item( iter ) ), buf, edits + i ); var_edit_shift( buf, 0, edits + i ); result = list_push_back( result, object_new( buf->value ) ); string_truncate( buf, 0 ); } } } return result; } static LIST * apply_modifiers_impl( LIST * result, string * buf, VAR_EDITS * edits, int n, LISTITER iter, LISTITER end ) { return iter == end ? apply_modifiers_empty( result, buf, edits, n ) : apply_modifiers_non_empty( result, buf, edits, n, iter, end ); } static LIST * apply_subscript_and_modifiers( STACK * s, int n ) { LIST * const value = stack_top( s ); LIST * const indices = stack_at( s, 1 ); LIST * result = L0; VAR_EDITS * const edits = (VAR_EDITS *)((LIST * *)stack_get( s ) + 2); int const length = list_length( value ); string buf[ 1 ]; LISTITER indices_iter = list_begin( indices ); LISTITER const indices_end = list_end( indices ); string_new( buf ); for ( ; indices_iter != indices_end; indices_iter = list_next( indices_iter ) ) { LISTITER iter = list_begin( value ); LISTITER end = list_end( value ); subscript_t const sub = parse_subscript( object_str( list_item( indices_iter ) ) ); get_iters( sub, &iter, &end, length ); result = apply_modifiers_impl( result, buf, edits, n, iter, end ); } string_free( buf ); return result; } /* * expand() - expands a list of concatenated strings and variable refereces * * Takes a list of expansion items - each representing one element to be * concatenated and each containing a list of its values. Returns a list of all * possible values constructed by selecting a single value from each of the * elements and concatenating them together. * * For example, in the following code: * * local a = one two three four ; * local b = foo bar ; * ECHO /$(a)/$(b)/$(a)/ ; * * When constructing the result of /$(a)/$(b)/ this function would get called * with the following 7 expansion items: * 1. / * 2. one two three four * 3. / * 4. foo bar * 5. / * 6. one two three four * 7. / * * And would result in a list containing 32 values: * 1. /one/foo/one/ * 2. /one/foo/two/ * 3. /one/foo/three/ * 4. /one/foo/four/ * 5. /one/bar/one/ * ... * */ typedef struct expansion_item { /* Item's value list initialized prior to calling expand(). */ LIST * values; /* Internal data initialized and used inside expand(). */ LISTITER current; /* Currently used value. */ int size; /* Concatenated string length prior to concatenating the * item's current value. */ } expansion_item; static LIST * expand( expansion_item * items, int const length ) { LIST * result = L0; string buf[ 1 ]; int size = 0; int i; assert( length > 0 ); for ( i = 0; i < length; ++i ) { LISTITER iter = list_begin( items[ i ].values ); LISTITER const end = list_end( items[ i ].values ); /* If any of the items has no values - the result is an empty list. */ if ( iter == end ) return L0; /* Set each item's 'current' to its first listed value. This indicates * each item's next value to be used when constructing the list of all * possible concatenated values. */ items[ i ].current = iter; /* Calculate the longest concatenated string length - to know how much * memory we need to allocate as a buffer for holding the concatenated * strings. */ { int max = 0; for ( ; iter != end; iter = list_next( iter ) ) { int const len = strlen( object_str( list_item( iter ) ) ); if ( len > max ) max = len; } size += max; } } string_new( buf ); string_reserve( buf, size ); i = 0; while ( i >= 0 ) { for ( ; i < length; ++i ) { items[ i ].size = buf->size; string_append( buf, object_str( list_item( items[ i ].current ) ) ); } result = list_push_back( result, object_new( buf->value ) ); while ( --i >= 0 ) { if ( list_next( items[ i ].current ) != list_end( items[ i ].values ) ) { items[ i ].current = list_next( items[ i ].current ); string_truncate( buf, items[ i ].size ); break; } else items[ i ].current = list_begin( items[ i ].values ); } } string_free( buf ); return result; } static void combine_strings( STACK * s, int n, string * out ) { int i; for ( i = 0; i < n; ++i ) { LIST * const values = stack_pop( s ); LISTITER iter = list_begin( values ); LISTITER const end = list_end( values ); if ( iter != end ) { string_append( out, object_str( list_item( iter ) ) ); for ( iter = list_next( iter ); iter != end; iter = list_next( iter ) ) { string_push_back( out, ' ' ); string_append( out, object_str( list_item( iter ) ) ); } list_free( values ); } } } struct dynamic_array { int size; int capacity; void * data; }; static void dynamic_array_init( struct dynamic_array * array ) { array->size = 0; array->capacity = 0; array->data = 0; } static void dynamic_array_free( struct dynamic_array * array ) { BJAM_FREE( array->data ); } static void dynamic_array_push_impl( struct dynamic_array * const array, void const * const value, int const unit_size ) { if ( array->capacity == 0 ) { array->capacity = 2; array->data = BJAM_MALLOC( array->capacity * unit_size ); } else if ( array->capacity == array->size ) { void * new_data; array->capacity *= 2; new_data = BJAM_MALLOC( array->capacity * unit_size ); memcpy( new_data, array->data, array->size * unit_size ); BJAM_FREE( array->data ); array->data = new_data; } memcpy( (char *)array->data + array->size * unit_size, value, unit_size ); ++array->size; } #define dynamic_array_push( array, value ) (dynamic_array_push_impl(array, &value, sizeof(value))) #define dynamic_array_at( type, array, idx ) (((type *)(array)->data)[idx]) /* * struct compiler */ struct label_info { int absolute_position; struct dynamic_array uses[ 1 ]; }; struct stored_rule { OBJECT * name; PARSE * parse; int num_arguments; struct arg_list * arguments; int local; }; typedef struct compiler { struct dynamic_array code[ 1 ]; struct dynamic_array constants[ 1 ]; struct dynamic_array labels[ 1 ]; struct dynamic_array rules[ 1 ]; struct dynamic_array actions[ 1 ]; } compiler; static void compiler_init( compiler * c ) { dynamic_array_init( c->code ); dynamic_array_init( c->constants ); dynamic_array_init( c->labels ); dynamic_array_init( c->rules ); dynamic_array_init( c->actions ); } static void compiler_free( compiler * c ) { int i; dynamic_array_free( c->actions ); dynamic_array_free( c->rules ); for ( i = 0; i < c->labels->size; ++i ) dynamic_array_free( dynamic_array_at( struct label_info, c->labels, i ).uses ); dynamic_array_free( c->labels ); dynamic_array_free( c->constants ); dynamic_array_free( c->code ); } static void compile_emit_instruction( compiler * c, instruction instr ) { dynamic_array_push( c->code, instr ); } static int compile_new_label( compiler * c ) { int result = c->labels->size; struct label_info info; info.absolute_position = -1; dynamic_array_init( info.uses ); dynamic_array_push( c->labels, info ); return result; } static void compile_set_label( compiler * c, int label ) { struct label_info * const l = &dynamic_array_at( struct label_info, c->labels, label ); int const pos = c->code->size; int i; assert( l->absolute_position == -1 ); l->absolute_position = pos; for ( i = 0; i < l->uses->size; ++i ) { int id = dynamic_array_at( int, l->uses, i ); int offset = (int)( pos - id - 1 ); dynamic_array_at( instruction, c->code, id ).arg = offset; } } static void compile_emit( compiler * c, unsigned int op_code, int arg ) { instruction instr; instr.op_code = op_code; instr.arg = arg; compile_emit_instruction( c, instr ); } static void compile_emit_branch( compiler * c, unsigned int op_code, int label ) { struct label_info * const l = &dynamic_array_at( struct label_info, c->labels, label ); int const pos = c->code->size; instruction instr; instr.op_code = op_code; if ( l->absolute_position == -1 ) { instr.arg = 0; dynamic_array_push( l->uses, pos ); } else instr.arg = (int)( l->absolute_position - pos - 1 ); compile_emit_instruction( c, instr ); } static int compile_emit_constant( compiler * c, OBJECT * value ) { OBJECT * copy = object_copy( value ); dynamic_array_push( c->constants, copy ); return c->constants->size - 1; } static int compile_emit_rule( compiler * c, OBJECT * name, PARSE * parse, int num_arguments, struct arg_list * arguments, int local ) { struct stored_rule rule; rule.name = object_copy( name ); rule.parse = parse; rule.num_arguments = num_arguments; rule.arguments = arguments; rule.local = local; dynamic_array_push( c->rules, rule ); return (int)( c->rules->size - 1 ); } static int compile_emit_actions( compiler * c, PARSE * parse ) { SUBACTION a; a.name = object_copy( parse->string ); a.command = function_compile_actions( object_str( parse->string1 ), parse->file, parse->line ); a.flags = parse->num; dynamic_array_push( c->actions, a ); return (int)( c->actions->size - 1 ); } static JAM_FUNCTION * compile_to_function( compiler * c ) { JAM_FUNCTION * const result = BJAM_MALLOC( sizeof( JAM_FUNCTION ) ); int i; result->base.type = FUNCTION_JAM; result->base.reference_count = 1; result->base.formal_arguments = 0; result->base.num_formal_arguments = 0; result->base.rulename = 0; result->code_size = c->code->size; result->code = BJAM_MALLOC( c->code->size * sizeof( instruction ) ); memcpy( result->code, c->code->data, c->code->size * sizeof( instruction ) ); result->constants = BJAM_MALLOC( c->constants->size * sizeof( OBJECT * ) ); memcpy( result->constants, c->constants->data, c->constants->size * sizeof( OBJECT * ) ); result->num_constants = c->constants->size; result->num_subfunctions = c->rules->size; result->functions = BJAM_MALLOC( c->rules->size * sizeof( SUBFUNCTION ) ); for ( i = 0; i < c->rules->size; ++i ) { struct stored_rule * const rule = &dynamic_array_at( struct stored_rule, c->rules, i ); result->functions[ i ].name = rule->name; result->functions[ i ].code = function_compile( rule->parse ); result->functions[ i ].code->num_formal_arguments = rule->num_arguments; result->functions[ i ].code->formal_arguments = rule->arguments; result->functions[ i ].local = rule->local; } result->actions = BJAM_MALLOC( c->actions->size * sizeof( SUBACTION ) ); memcpy( result->actions, c->actions->data, c->actions->size * sizeof( SUBACTION ) ); result->num_subactions = c->actions->size; result->generic = 0; result->file = 0; result->line = -1; return result; } /* * Parsing of variable expansions */ typedef struct VAR_PARSE_GROUP { struct dynamic_array elems[ 1 ]; } VAR_PARSE_GROUP; typedef struct VAR_PARSE_ACTIONS { struct dynamic_array elems[ 1 ]; } VAR_PARSE_ACTIONS; #define VAR_PARSE_TYPE_VAR 0 #define VAR_PARSE_TYPE_STRING 1 #define VAR_PARSE_TYPE_FILE 2 typedef struct _var_parse { int type; /* string, variable or file */ } VAR_PARSE; typedef struct { VAR_PARSE base; VAR_PARSE_GROUP * name; VAR_PARSE_GROUP * subscript; struct dynamic_array modifiers[ 1 ]; } VAR_PARSE_VAR; typedef struct { VAR_PARSE base; OBJECT * s; } VAR_PARSE_STRING; typedef struct { VAR_PARSE base; struct dynamic_array filename[ 1 ]; struct dynamic_array contents[ 1 ]; } VAR_PARSE_FILE; static void var_parse_free( VAR_PARSE * ); /* * VAR_PARSE_GROUP */ static VAR_PARSE_GROUP * var_parse_group_new() { VAR_PARSE_GROUP * const result = BJAM_MALLOC( sizeof( VAR_PARSE_GROUP ) ); dynamic_array_init( result->elems ); return result; } static void var_parse_group_free( VAR_PARSE_GROUP * group ) { int i; for ( i = 0; i < group->elems->size; ++i ) var_parse_free( dynamic_array_at( VAR_PARSE *, group->elems, i ) ); dynamic_array_free( group->elems ); BJAM_FREE( group ); } static void var_parse_group_add( VAR_PARSE_GROUP * group, VAR_PARSE * elem ) { dynamic_array_push( group->elems, elem ); } static void var_parse_group_maybe_add_constant( VAR_PARSE_GROUP * group, char const * start, char const * end ) { if ( start != end ) { string buf[ 1 ]; VAR_PARSE_STRING * const value = (VAR_PARSE_STRING *)BJAM_MALLOC( sizeof(VAR_PARSE_STRING) ); value->base.type = VAR_PARSE_TYPE_STRING; string_new( buf ); string_append_range( buf, start, end ); value->s = object_new( buf->value ); string_free( buf ); var_parse_group_add( group, (VAR_PARSE *)value ); } } VAR_PARSE_STRING * var_parse_group_as_literal( VAR_PARSE_GROUP * group ) { if ( group->elems->size == 1 ) { VAR_PARSE * result = dynamic_array_at( VAR_PARSE *, group->elems, 0 ); if ( result->type == VAR_PARSE_TYPE_STRING ) return (VAR_PARSE_STRING *)result; } return 0; } /* * VAR_PARSE_ACTIONS */ static VAR_PARSE_ACTIONS * var_parse_actions_new() { VAR_PARSE_ACTIONS * const result = (VAR_PARSE_ACTIONS *)BJAM_MALLOC( sizeof(VAR_PARSE_ACTIONS) ); dynamic_array_init( result->elems ); return result; } static void var_parse_actions_free( VAR_PARSE_ACTIONS * actions ) { int i; for ( i = 0; i < actions->elems->size; ++i ) var_parse_group_free( dynamic_array_at( VAR_PARSE_GROUP *, actions->elems, i ) ); dynamic_array_free( actions->elems ); BJAM_FREE( actions ); } /* * VAR_PARSE_VAR */ static VAR_PARSE_VAR * var_parse_var_new() { VAR_PARSE_VAR * result = BJAM_MALLOC( sizeof( VAR_PARSE_VAR ) ); result->base.type = VAR_PARSE_TYPE_VAR; result->name = var_parse_group_new(); result->subscript = 0; dynamic_array_init( result->modifiers ); return result; } static void var_parse_var_free( VAR_PARSE_VAR * var ) { int i; var_parse_group_free( var->name ); if ( var->subscript ) var_parse_group_free( var->subscript ); for ( i = 0; i < var->modifiers->size; ++i ) var_parse_group_free( dynamic_array_at( VAR_PARSE_GROUP *, var->modifiers, i ) ); dynamic_array_free( var->modifiers ); BJAM_FREE( var ); } static VAR_PARSE_GROUP * var_parse_var_new_modifier( VAR_PARSE_VAR * var ) { VAR_PARSE_GROUP * result = var_parse_group_new(); dynamic_array_push( var->modifiers, result ); return result; } /* * VAR_PARSE_STRING */ static void var_parse_string_free( VAR_PARSE_STRING * string ) { object_free( string->s ); BJAM_FREE( string ); } /* * VAR_PARSE_FILE */ static VAR_PARSE_FILE * var_parse_file_new( void ) { VAR_PARSE_FILE * const result = (VAR_PARSE_FILE *)BJAM_MALLOC( sizeof( VAR_PARSE_FILE ) ); result->base.type = VAR_PARSE_TYPE_FILE; dynamic_array_init( result->filename ); dynamic_array_init( result->contents ); return result; } static void var_parse_file_free( VAR_PARSE_FILE * file ) { int i; for ( i = 0; i < file->filename->size; ++i ) var_parse_group_free( dynamic_array_at( VAR_PARSE_GROUP *, file->filename, i ) ); dynamic_array_free( file->filename ); for ( i = 0; i < file->contents->size; ++i ) var_parse_group_free( dynamic_array_at( VAR_PARSE_GROUP *, file->contents, i ) ); dynamic_array_free( file->contents ); BJAM_FREE( file ); } /* * VAR_PARSE */ static void var_parse_free( VAR_PARSE * parse ) { switch ( parse->type ) { case VAR_PARSE_TYPE_VAR: var_parse_var_free( (VAR_PARSE_VAR *)parse ); break; case VAR_PARSE_TYPE_STRING: var_parse_string_free( (VAR_PARSE_STRING *)parse ); break; case VAR_PARSE_TYPE_FILE: var_parse_file_free( (VAR_PARSE_FILE *)parse ); break; default: assert( !"Invalid type" ); } } /* * Compile VAR_PARSE */ static void var_parse_group_compile( VAR_PARSE_GROUP const * parse, compiler * c ); static void var_parse_var_compile( VAR_PARSE_VAR const * parse, compiler * c ) { int expand_name = 0; int is_get_grist = 0; int has_modifiers = 0; /* Special case common modifiers */ if ( parse->modifiers->size == 1 ) { VAR_PARSE_GROUP * mod = dynamic_array_at( VAR_PARSE_GROUP *, parse->modifiers, 0 ); if ( mod->elems->size == 1 ) { VAR_PARSE * mod1 = dynamic_array_at( VAR_PARSE *, mod->elems, 0 ); if ( mod1->type == VAR_PARSE_TYPE_STRING ) { OBJECT * s = ( (VAR_PARSE_STRING *)mod1 )->s; if ( ! strcmp ( object_str( s ), "G" ) ) { is_get_grist = 1; } } } } /* If there are modifiers, emit them in reverse order. */ if ( parse->modifiers->size > 0 && !is_get_grist ) { int i; has_modifiers = 1; for ( i = 0; i < parse->modifiers->size; ++i ) var_parse_group_compile( dynamic_array_at( VAR_PARSE_GROUP *, parse->modifiers, parse->modifiers->size - i - 1 ), c ); } /* If there is a subscript, emit it. */ if ( parse->subscript ) var_parse_group_compile( parse->subscript, c ); /* If the variable name is empty, look it up. */ if ( parse->name->elems->size == 0 ) compile_emit( c, INSTR_PUSH_VAR, compile_emit_constant( c, constant_empty ) ); /* If the variable name does not need to be expanded, look it up. */ else if ( parse->name->elems->size == 1 && dynamic_array_at( VAR_PARSE *, parse->name->elems, 0 )->type == VAR_PARSE_TYPE_STRING ) { OBJECT * const name = ( (VAR_PARSE_STRING *)dynamic_array_at( VAR_PARSE *, parse->name->elems, 0 ) )->s; int const idx = get_argument_index( object_str( name ) ); if ( idx != -1 ) compile_emit( c, INSTR_PUSH_ARG, idx ); else compile_emit( c, INSTR_PUSH_VAR, compile_emit_constant( c, name ) ); } /* Otherwise, push the var names and use the group instruction. */ else { var_parse_group_compile( parse->name, c ); expand_name = 1; } /** Select the instruction for expanding the variable. */ if ( !has_modifiers && !parse->subscript && !expand_name ) ; else if ( !has_modifiers && !parse->subscript && expand_name ) compile_emit( c, INSTR_PUSH_GROUP, 0 ); else if ( !has_modifiers && parse->subscript && !expand_name ) compile_emit( c, INSTR_APPLY_INDEX, 0 ); else if ( !has_modifiers && parse->subscript && expand_name ) compile_emit( c, INSTR_APPLY_INDEX_GROUP, 0 ); else if ( has_modifiers && !parse->subscript && !expand_name ) compile_emit( c, INSTR_APPLY_MODIFIERS, parse->modifiers->size ); else if ( has_modifiers && !parse->subscript && expand_name ) compile_emit( c, INSTR_APPLY_MODIFIERS_GROUP, parse->modifiers->size ); else if ( has_modifiers && parse->subscript && !expand_name ) compile_emit( c, INSTR_APPLY_INDEX_MODIFIERS, parse->modifiers->size ); else if ( has_modifiers && parse->subscript && expand_name ) compile_emit( c, INSTR_APPLY_INDEX_MODIFIERS_GROUP, parse->modifiers->size ); /* Now apply any special modifiers */ if ( is_get_grist ) { compile_emit( c, INSTR_GET_GRIST, 0 ); } } static void var_parse_string_compile( VAR_PARSE_STRING const * parse, compiler * c ) { compile_emit( c, INSTR_PUSH_CONSTANT, compile_emit_constant( c, parse->s ) ); } static void var_parse_file_compile( VAR_PARSE_FILE const * parse, compiler * c ) { int i; for ( i = 0; i < parse->filename->size; ++i ) var_parse_group_compile( dynamic_array_at( VAR_PARSE_GROUP *, parse->filename, parse->filename->size - i - 1 ), c ); compile_emit( c, INSTR_APPEND_STRINGS, parse->filename->size ); for ( i = 0; i < parse->contents->size; ++i ) var_parse_group_compile( dynamic_array_at( VAR_PARSE_GROUP *, parse->contents, parse->contents->size - i - 1 ), c ); compile_emit( c, INSTR_WRITE_FILE, parse->contents->size ); } static void var_parse_compile( VAR_PARSE const * parse, compiler * c ) { switch ( parse->type ) { case VAR_PARSE_TYPE_VAR: var_parse_var_compile( (VAR_PARSE_VAR const *)parse, c ); break; case VAR_PARSE_TYPE_STRING: var_parse_string_compile( (VAR_PARSE_STRING const *)parse, c ); break; case VAR_PARSE_TYPE_FILE: var_parse_file_compile( (VAR_PARSE_FILE const *)parse, c ); break; default: assert( !"Unknown var parse type." ); } } static void var_parse_group_compile( VAR_PARSE_GROUP const * parse, compiler * c ) { /* Emit the elements in reverse order. */ int i; for ( i = 0; i < parse->elems->size; ++i ) var_parse_compile( dynamic_array_at( VAR_PARSE *, parse->elems, parse->elems->size - i - 1 ), c ); /* If there are no elements, emit an empty string. */ if ( parse->elems->size == 0 ) compile_emit( c, INSTR_PUSH_CONSTANT, compile_emit_constant( c, constant_empty ) ); /* If there is more than one element, combine them. */ if ( parse->elems->size > 1 ) compile_emit( c, INSTR_COMBINE_STRINGS, parse->elems->size ); } static void var_parse_actions_compile( VAR_PARSE_ACTIONS const * actions, compiler * c ) { int i; for ( i = 0; i < actions->elems->size; ++i ) var_parse_group_compile( dynamic_array_at( VAR_PARSE_GROUP *, actions->elems, actions->elems->size - i - 1 ), c ); compile_emit( c, INSTR_OUTPUT_STRINGS, actions->elems->size ); } /* * Parse VAR_PARSE_VAR */ static VAR_PARSE * parse_at_file( char const * start, char const * mid, char const * end ); static VAR_PARSE * parse_variable( char const * * string ); static int try_parse_variable( char const * * s_, char const * * string, VAR_PARSE_GROUP * out ); static void balance_parentheses( char const * * s_, char const * * string, VAR_PARSE_GROUP * out ); static void parse_var_string( char const * first, char const * last, struct dynamic_array * out ); /* * Parses a string that can contain variables to expand. */ static VAR_PARSE_GROUP * parse_expansion( char const * * string ) { VAR_PARSE_GROUP * result = var_parse_group_new(); char const * s = *string; for ( ; ; ) { if ( try_parse_variable( &s, string, result ) ) {} else if ( s[ 0 ] == '\0' ) { var_parse_group_maybe_add_constant( result, *string, s ); return result; } else ++s; } } static VAR_PARSE_ACTIONS * parse_actions( char const * string ) { VAR_PARSE_ACTIONS * const result = var_parse_actions_new(); parse_var_string( string, string + strlen( string ), result->elems ); return result; } /* * Checks whether the string a *s_ starts with a variable expansion "$(". * *string should point to the first unemitted character before *s. If *s_ * starts with variable expansion, appends elements to out up to the closing * ")", and adjusts *s_ and *string to point to next character. Returns 1 if s_ * starts with a variable, 0 otherwise. */ static int try_parse_variable( char const * * s_, char const * * string, VAR_PARSE_GROUP * out ) { char const * s = *s_; if ( s[ 0 ] == '$' && s[ 1 ] == '(' ) { var_parse_group_maybe_add_constant( out, *string, s ); s += 2; var_parse_group_add( out, parse_variable( &s ) ); *string = s; *s_ = s; return 1; } if ( s[ 0 ] == '@' && s[ 1 ] == '(' ) { int depth = 1; char const * ine; char const * split = 0; var_parse_group_maybe_add_constant( out, *string, s ); s += 2; ine = s; /* Scan the content of the response file @() section. */ while ( *ine && ( depth > 0 ) ) { switch ( *ine ) { case '(': ++depth; break; case ')': --depth; break; case ':': if ( ( depth == 1 ) && ( ine[ 1 ] == 'E' ) && ( ine[ 2 ] == '=' ) ) split = ine; break; } ++ine; } if ( !split || depth ) return 0; var_parse_group_add( out, parse_at_file( s, split, ine - 1 ) ); *string = ine; *s_ = ine; return 1; } return 0; } static char const * current_file = ""; static int current_line; static void parse_error( char const * message ) { printf( "%s:%d: %s\n", current_file, current_line, message ); } /* * Parses a single variable up to the closing ")" and adjusts *string to point * to the next character. *string should point to the character immediately * after the initial "$(". */ static VAR_PARSE * parse_variable( char const * * string ) { VAR_PARSE_VAR * const result = var_parse_var_new(); VAR_PARSE_GROUP * const name = result->name; char const * s = *string; for ( ; ; ) { if ( try_parse_variable( &s, string, name ) ) {} else if ( s[ 0 ] == ':' ) { VAR_PARSE_GROUP * mod; var_parse_group_maybe_add_constant( name, *string, s ); ++s; *string = s; mod = var_parse_var_new_modifier( result ); for ( ; ; ) { if ( try_parse_variable( &s, string, mod ) ) {} else if ( s[ 0 ] == ')' ) { var_parse_group_maybe_add_constant( mod, *string, s ); *string = ++s; return (VAR_PARSE *)result; } else if ( s[ 0 ] == '(' ) { ++s; balance_parentheses( &s, string, mod ); } else if ( s[ 0 ] == ':' ) { var_parse_group_maybe_add_constant( mod, *string, s ); *string = ++s; mod = var_parse_var_new_modifier( result ); } else if ( s[ 0 ] == '[' ) { parse_error("unexpected subscript"); ++s; } else if ( s[ 0 ] == '\0' ) { parse_error( "unbalanced parentheses" ); var_parse_group_maybe_add_constant( mod, *string, s ); *string = s; return (VAR_PARSE *)result; } else ++s; } } else if ( s[ 0 ] == '[' ) { VAR_PARSE_GROUP * subscript = var_parse_group_new(); result->subscript = subscript; var_parse_group_maybe_add_constant( name, *string, s ); *string = ++s; for ( ; ; ) { if ( try_parse_variable( &s, string, subscript ) ) {} else if ( s[ 0 ] == ']' ) { var_parse_group_maybe_add_constant( subscript, *string, s ); *string = ++s; if ( s[ 0 ] != ')' && s[ 0 ] != ':' && s[ 0 ] != '\0' ) parse_error( "unexpected text following []" ); break; } else if ( isdigit( s[ 0 ] ) || s[ 0 ] == '-' ) { ++s; } else if ( s[ 0 ] == '\0' ) { parse_error( "malformed subscript" ); break; } else { parse_error( "malformed subscript" ); ++s; } } } else if ( s[ 0 ] == ')' ) { var_parse_group_maybe_add_constant( name, *string, s ); *string = ++s; return (VAR_PARSE *)result; } else if ( s[ 0 ] == '(' ) { ++s; balance_parentheses( &s, string, name ); } else if ( s[ 0 ] == '\0' ) { parse_error( "unbalanced parentheses" ); var_parse_group_maybe_add_constant( name, *string, s ); *string = s; return (VAR_PARSE *)result; } else ++s; } } static void parse_var_string( char const * first, char const * last, struct dynamic_array * out ) { char const * saved = first; while ( first != last ) { /* Handle whitespace. */ while ( first != last && isspace( *first ) ) ++first; if ( saved != first ) { VAR_PARSE_GROUP * const group = var_parse_group_new(); var_parse_group_maybe_add_constant( group, saved, first ); saved = first; dynamic_array_push( out, group ); } if ( first == last ) break; /* Handle non-whitespace */ { VAR_PARSE_GROUP * group = var_parse_group_new(); for ( ; ; ) { if ( first == last || isspace( *first ) ) { var_parse_group_maybe_add_constant( group, saved, first ); saved = first; break; } if ( try_parse_variable( &first, &saved, group ) ) assert( first <= last ); else ++first; } dynamic_array_push( out, group ); } } } /* * start should point to the character immediately following the opening "@(", * mid should point to the ":E=", and end should point to the closing ")". */ static VAR_PARSE * parse_at_file( char const * start, char const * mid, char const * end ) { VAR_PARSE_FILE * result = var_parse_file_new(); parse_var_string( start, mid, result->filename ); parse_var_string( mid + 3, end, result->contents ); return (VAR_PARSE *)result; } /* * Given that *s_ points to the character after a "(", parses up to the matching * ")". *string should point to the first unemitted character before *s_. * * When the function returns, *s_ will point to the character after the ")", and * *string will point to the first unemitted character before *s_. The range * from *string to *s_ does not contain any variables that need to be expanded. */ void balance_parentheses( char const * * s_, char const * * string, VAR_PARSE_GROUP * out) { int depth = 1; char const * s = *s_; for ( ; ; ) { if ( try_parse_variable( &s, string, out ) ) { } else if ( s[ 0 ] == ':' || s[ 0 ] == '[' ) { parse_error( "unbalanced parentheses" ); ++s; } else if ( s[ 0 ] == '\0' ) { parse_error( "unbalanced parentheses" ); break; } else if ( s[ 0 ] == ')' ) { ++s; if ( --depth == 0 ) break; } else if ( s[ 0 ] == '(' ) { ++depth; ++s; } else ++s; } *s_ = s; } /* * Main compile. */ #define RESULT_STACK 0 #define RESULT_RETURN 1 #define RESULT_NONE 2 static void compile_parse( PARSE * parse, compiler * c, int result_location ); static struct arg_list * arg_list_compile( PARSE * parse, int * num_arguments ); static void compile_condition( PARSE * parse, compiler * c, int branch_true, int label ) { assert( parse->type == PARSE_EVAL ); switch ( parse->num ) { case EXPR_EXISTS: compile_parse( parse->left, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_NOT_EMPTY, label ); else compile_emit_branch( c, INSTR_JUMP_EMPTY, label ); break; case EXPR_EQUALS: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_EQ, label ); else compile_emit_branch( c, INSTR_JUMP_NE, label ); break; case EXPR_NOTEQ: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_NE, label ); else compile_emit_branch( c, INSTR_JUMP_EQ, label ); break; case EXPR_LESS: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_LT, label ); else compile_emit_branch( c, INSTR_JUMP_GE, label ); break; case EXPR_LESSEQ: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_LE, label ); else compile_emit_branch( c, INSTR_JUMP_GT, label ); break; case EXPR_MORE: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_GT, label ); else compile_emit_branch( c, INSTR_JUMP_LE, label ); break; case EXPR_MOREEQ: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_GE, label ); else compile_emit_branch( c, INSTR_JUMP_LT, label ); break; case EXPR_IN: compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( branch_true ) compile_emit_branch( c, INSTR_JUMP_IN, label ); else compile_emit_branch( c, INSTR_JUMP_NOT_IN, label ); break; case EXPR_AND: if ( branch_true ) { int f = compile_new_label( c ); compile_condition( parse->left, c, 0, f ); compile_condition( parse->right, c, 1, label ); compile_set_label( c, f ); } else { compile_condition( parse->left, c, 0, label ); compile_condition( parse->right, c, 0, label ); } break; case EXPR_OR: if ( branch_true ) { compile_condition( parse->left, c, 1, label ); compile_condition( parse->right, c, 1, label ); } else { int t = compile_new_label( c ); compile_condition( parse->left, c, 1, t ); compile_condition( parse->right, c, 0, label ); compile_set_label( c, t ); } break; case EXPR_NOT: compile_condition( parse->left, c, !branch_true, label ); break; } } static void adjust_result( compiler * c, int actual_location, int desired_location ) { if ( actual_location == desired_location ) ; else if ( actual_location == RESULT_STACK && desired_location == RESULT_RETURN ) compile_emit( c, INSTR_SET_RESULT, 0 ); else if ( actual_location == RESULT_STACK && desired_location == RESULT_NONE ) compile_emit( c, INSTR_POP, 0 ); else if ( actual_location == RESULT_RETURN && desired_location == RESULT_STACK ) compile_emit( c, INSTR_PUSH_RESULT, 0 ); else if ( actual_location == RESULT_RETURN && desired_location == RESULT_NONE ) ; else if ( actual_location == RESULT_NONE && desired_location == RESULT_STACK ) compile_emit( c, INSTR_PUSH_EMPTY, 0 ); else if ( actual_location == RESULT_NONE && desired_location == RESULT_RETURN ) { compile_emit( c, INSTR_PUSH_EMPTY, 0 ); compile_emit( c, INSTR_SET_RESULT, 0 ); } else assert( !"invalid result location" ); } static char const * parse_type( PARSE * parse ) { switch ( parse->type ) { case PARSE_APPEND: return "append"; case PARSE_EVAL: return "eval"; case PARSE_RULES: return "rules"; default: return "unknown"; } } static void compile_append_chain( PARSE * parse, compiler * c ) { assert( parse->type == PARSE_APPEND ); if ( parse->left->type == PARSE_NULL ) compile_parse( parse->right, c, RESULT_STACK ); else { if ( parse->left->type == PARSE_APPEND ) compile_append_chain( parse->left, c ); else compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); compile_emit( c, INSTR_PUSH_APPEND, 0 ); } } static void compile_parse( PARSE * parse, compiler * c, int result_location ) { if ( parse->type == PARSE_APPEND ) { compile_append_chain( parse, c ); adjust_result( c, RESULT_STACK, result_location ); } else if ( parse->type == PARSE_EVAL ) { /* FIXME: This is only needed because of the bizarre parsing of * conditions. */ if ( parse->num == EXPR_EXISTS ) compile_parse( parse->left, c, result_location ); else { int f = compile_new_label( c ); int end = compile_new_label( c ); printf( "%s:%d: Conditional used as list (check operator " "precedence).\n", object_str( parse->file ), parse->line ); /* Emit the condition */ compile_condition( parse, c, 0, f ); compile_emit( c, INSTR_PUSH_CONSTANT, compile_emit_constant( c, constant_true ) ); compile_emit_branch( c, INSTR_JUMP, end ); compile_set_label( c, f ); compile_emit( c, INSTR_PUSH_EMPTY, 0 ); compile_set_label( c, end ); adjust_result( c, RESULT_STACK, result_location ); } } else if ( parse->type == PARSE_FOREACH ) { int var = compile_emit_constant( c, parse->string ); int top = compile_new_label( c ); int end = compile_new_label( c ); /* * Evaluate the list. */ compile_parse( parse->left, c, RESULT_STACK ); /* Localize the loop variable */ if ( parse->num ) { compile_emit( c, INSTR_PUSH_EMPTY, 0 ); compile_emit( c, INSTR_PUSH_LOCAL, var ); compile_emit( c, INSTR_SWAP, 1 ); } compile_emit( c, INSTR_FOR_INIT, 0 ); compile_set_label( c, top ); compile_emit_branch( c, INSTR_FOR_LOOP, end ); compile_emit( c, INSTR_SET, var ); /* Run the loop body */ compile_parse( parse->right, c, RESULT_NONE ); compile_emit_branch( c, INSTR_JUMP, top ); compile_set_label( c, end ); if ( parse->num ) compile_emit( c, INSTR_POP_LOCAL, var ); adjust_result( c, RESULT_NONE, result_location); } else if ( parse->type == PARSE_IF ) { int f = compile_new_label( c ); /* Emit the condition */ compile_condition( parse->left, c, 0, f ); /* Emit the if block */ compile_parse( parse->right, c, result_location ); if ( parse->third->type != PARSE_NULL || result_location != RESULT_NONE ) { /* Emit the else block */ int end = compile_new_label( c ); compile_emit_branch( c, INSTR_JUMP, end ); compile_set_label( c, f ); compile_parse( parse->third, c, result_location ); compile_set_label( c, end ); } else compile_set_label( c, f ); } else if ( parse->type == PARSE_WHILE ) { int nested_result = result_location == RESULT_NONE ? RESULT_NONE : RESULT_RETURN; int test = compile_new_label( c ); int top = compile_new_label( c ); /* Make sure that we return an empty list if the loop runs zero times. */ adjust_result( c, RESULT_NONE, nested_result ); /* Jump to the loop test. */ compile_emit_branch( c, INSTR_JUMP, test ); compile_set_label( c, top ); /* Emit the loop body. */ compile_parse( parse->right, c, nested_result ); /* Emit the condition. */ compile_set_label( c, test ); compile_condition( parse->left, c, 1, top ); adjust_result( c, nested_result, result_location ); } else if ( parse->type == PARSE_INCLUDE ) { compile_parse( parse->left, c, RESULT_STACK ); compile_emit( c, INSTR_INCLUDE, 0 ); compile_emit( c, INSTR_BIND_MODULE_VARIABLES, 0 ); adjust_result( c, RESULT_NONE, result_location ); } else if ( parse->type == PARSE_MODULE ) { int const nested_result = result_location == RESULT_NONE ? RESULT_NONE : RESULT_RETURN; compile_parse( parse->left, c, RESULT_STACK ); compile_emit( c, INSTR_PUSH_MODULE, 0 ); compile_parse( parse->right, c, nested_result ); compile_emit( c, INSTR_POP_MODULE, 0 ); adjust_result( c, nested_result, result_location ); } else if ( parse->type == PARSE_CLASS ) { /* Evaluate the class name. */ compile_parse( parse->left->right, c, RESULT_STACK ); /* Evaluate the base classes. */ if ( parse->left->left ) compile_parse( parse->left->left->right, c, RESULT_STACK ); else compile_emit( c, INSTR_PUSH_EMPTY, 0 ); compile_emit( c, INSTR_CLASS, 0 ); compile_parse( parse->right, c, RESULT_NONE ); compile_emit( c, INSTR_BIND_MODULE_VARIABLES, 0 ); compile_emit( c, INSTR_POP_MODULE, 0 ); adjust_result( c, RESULT_NONE, result_location ); } else if ( parse->type == PARSE_LIST ) { OBJECT * const o = parse->string; char const * s = object_str( o ); VAR_PARSE_GROUP * group; current_file = object_str( parse->file ); current_line = parse->line; group = parse_expansion( &s ); var_parse_group_compile( group, c ); var_parse_group_free( group ); adjust_result( c, RESULT_STACK, result_location ); } else if ( parse->type == PARSE_LOCAL ) { int nested_result = result_location == RESULT_NONE ? RESULT_NONE : RESULT_RETURN; /* This should be left recursive group of compile_appends. */ PARSE * vars = parse->left; /* Special case an empty list of vars */ if ( vars->type == PARSE_NULL ) { compile_parse( parse->right, c, RESULT_NONE ); compile_parse( parse->third, c, result_location ); nested_result = result_location; } /* Check whether there is exactly one variable with a constant name. */ else if ( vars->left->type == PARSE_NULL && vars->right->type == PARSE_LIST ) { char const * s = object_str( vars->right->string ); VAR_PARSE_GROUP * group; current_file = object_str( parse->file ); current_line = parse->line; group = parse_expansion( &s ); if ( group->elems->size == 1 && dynamic_array_at( VAR_PARSE *, group->elems, 0 )->type == VAR_PARSE_TYPE_STRING ) { int const name = compile_emit_constant( c, ( (VAR_PARSE_STRING *)dynamic_array_at( VAR_PARSE *, group->elems, 0 ) )->s ); var_parse_group_free( group ); compile_parse( parse->right, c, RESULT_STACK ); compile_emit( c, INSTR_PUSH_LOCAL, name ); compile_parse( parse->third, c, nested_result ); compile_emit( c, INSTR_POP_LOCAL, name ); } else { var_parse_group_compile( group, c ); var_parse_group_free( group ); compile_parse( parse->right, c, RESULT_STACK ); compile_emit( c, INSTR_PUSH_LOCAL_GROUP, 0 ); compile_parse( parse->third, c, nested_result ); compile_emit( c, INSTR_POP_LOCAL_GROUP, 0 ); } } else { compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); compile_emit( c, INSTR_PUSH_LOCAL_GROUP, 0 ); compile_parse( parse->third, c, nested_result ); compile_emit( c, INSTR_POP_LOCAL_GROUP, 0 ); } adjust_result( c, nested_result, result_location ); } else if ( parse->type == PARSE_ON ) { if ( parse->right->type == PARSE_APPEND && parse->right->left->type == PARSE_NULL && parse->right->right->type == PARSE_LIST ) { /* [ on $(target) return $(variable) ] */ PARSE * value = parse->right->right; OBJECT * const o = value->string; char const * s = object_str( o ); VAR_PARSE_GROUP * group; OBJECT * varname = 0; current_file = object_str( value->file ); current_line = value->line; group = parse_expansion( &s ); if ( group->elems->size == 1 ) { VAR_PARSE * one = dynamic_array_at( VAR_PARSE *, group->elems, 0 ); if ( one->type == VAR_PARSE_TYPE_VAR ) { VAR_PARSE_VAR * var = ( VAR_PARSE_VAR * )one; if ( var->modifiers->size == 0 && !var->subscript && var->name->elems->size == 1 ) { VAR_PARSE * name = dynamic_array_at( VAR_PARSE *, var->name->elems, 0 ); if ( name->type == VAR_PARSE_TYPE_STRING ) { varname = ( ( VAR_PARSE_STRING * )name )->s; } } } } if ( varname ) { /* We have one variable with a fixed name and no modifiers. */ compile_parse( parse->left, c, RESULT_STACK ); compile_emit( c, INSTR_GET_ON, compile_emit_constant( c, varname ) ); } else { /* Too complex. Fall back on push/pop. */ int end = compile_new_label( c ); compile_parse( parse->left, c, RESULT_STACK ); compile_emit_branch( c, INSTR_PUSH_ON, end ); var_parse_group_compile( group, c ); compile_emit( c, INSTR_POP_ON, 0 ); compile_set_label( c, end ); } var_parse_group_free( group ); } else { int end = compile_new_label( c ); compile_parse( parse->left, c, RESULT_STACK ); compile_emit_branch( c, INSTR_PUSH_ON, end ); compile_parse( parse->right, c, RESULT_STACK ); compile_emit( c, INSTR_POP_ON, 0 ); compile_set_label( c, end ); } adjust_result( c, RESULT_STACK, result_location ); } else if ( parse->type == PARSE_RULE ) { PARSE * p; int n = 0; VAR_PARSE_GROUP * group; char const * s = object_str( parse->string ); if ( parse->left->left || parse->left->right->type != PARSE_NULL ) for ( p = parse->left; p; p = p->left ) { compile_parse( p->right, c, RESULT_STACK ); ++n; } current_file = object_str( parse->file ); current_line = parse->line; group = parse_expansion( &s ); if ( group->elems->size == 2 && dynamic_array_at( VAR_PARSE *, group->elems, 0 )->type == VAR_PARSE_TYPE_VAR && dynamic_array_at( VAR_PARSE *, group->elems, 1 )->type == VAR_PARSE_TYPE_STRING && ( object_str( ( (VAR_PARSE_STRING *)dynamic_array_at( VAR_PARSE *, group->elems, 1 ) )->s )[ 0 ] == '.' ) ) { VAR_PARSE_STRING * access = (VAR_PARSE_STRING *)dynamic_array_at( VAR_PARSE *, group->elems, 1 ); OBJECT * member = object_new( object_str( access->s ) + 1 ); /* Emit the object */ var_parse_var_compile( (VAR_PARSE_VAR *)dynamic_array_at( VAR_PARSE *, group->elems, 0 ), c ); var_parse_group_free( group ); compile_emit( c, INSTR_CALL_MEMBER_RULE, n ); compile_emit( c, compile_emit_constant( c, member ), parse->line ); object_free( member ); } else { var_parse_group_compile( group, c ); var_parse_group_free( group ); compile_emit( c, INSTR_CALL_RULE, n ); compile_emit( c, compile_emit_constant( c, parse->string ), parse->line ); } adjust_result( c, RESULT_STACK, result_location ); } else if ( parse->type == PARSE_RULES ) { do compile_parse( parse->left, c, RESULT_NONE ); while ( ( parse = parse->right )->type == PARSE_RULES ); compile_parse( parse, c, result_location ); } else if ( parse->type == PARSE_SET ) { PARSE * vars = parse->left; unsigned int op_code; unsigned int op_code_group; switch ( parse->num ) { case ASSIGN_APPEND: op_code = INSTR_APPEND; op_code_group = INSTR_APPEND_GROUP; break; case ASSIGN_DEFAULT: op_code = INSTR_DEFAULT; op_code_group = INSTR_DEFAULT_GROUP; break; default: op_code = INSTR_SET; op_code_group = INSTR_SET_GROUP; break; } /* Check whether there is exactly one variable with a constant name. */ if ( vars->type == PARSE_LIST ) { char const * s = object_str( vars->string ); VAR_PARSE_GROUP * group; current_file = object_str( parse->file ); current_line = parse->line; group = parse_expansion( &s ); if ( group->elems->size == 1 && dynamic_array_at( VAR_PARSE *, group->elems, 0 )->type == VAR_PARSE_TYPE_STRING ) { int const name = compile_emit_constant( c, ( (VAR_PARSE_STRING *)dynamic_array_at( VAR_PARSE *, group->elems, 0 ) )->s ); var_parse_group_free( group ); compile_parse( parse->right, c, RESULT_STACK ); if ( result_location != RESULT_NONE ) { compile_emit( c, INSTR_SET_RESULT, 1 ); } compile_emit( c, op_code, name ); } else { var_parse_group_compile( group, c ); var_parse_group_free( group ); compile_parse( parse->right, c, RESULT_STACK ); if ( result_location != RESULT_NONE ) { compile_emit( c, INSTR_SET_RESULT, 1 ); } compile_emit( c, op_code_group, 0 ); } } else { compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); if ( result_location != RESULT_NONE ) { compile_emit( c, INSTR_SET_RESULT, 1 ); } compile_emit( c, op_code_group, 0 ); } if ( result_location != RESULT_NONE ) { adjust_result( c, RESULT_RETURN, result_location ); } } else if ( parse->type == PARSE_SETCOMP ) { int n_args; struct arg_list * args = arg_list_compile( parse->right, &n_args ); int const rule_id = compile_emit_rule( c, parse->string, parse->left, n_args, args, parse->num ); compile_emit( c, INSTR_RULE, rule_id ); adjust_result( c, RESULT_NONE, result_location ); } else if ( parse->type == PARSE_SETEXEC ) { int const actions_id = compile_emit_actions( c, parse ); compile_parse( parse->left, c, RESULT_STACK ); compile_emit( c, INSTR_ACTIONS, actions_id ); adjust_result( c, RESULT_NONE, result_location ); } else if ( parse->type == PARSE_SETTINGS ) { compile_parse( parse->left, c, RESULT_STACK ); compile_parse( parse->third, c, RESULT_STACK ); compile_parse( parse->right, c, RESULT_STACK ); switch ( parse->num ) { case ASSIGN_APPEND: compile_emit( c, INSTR_APPEND_ON, 0 ); break; case ASSIGN_DEFAULT: compile_emit( c, INSTR_DEFAULT_ON, 0 ); break; default: compile_emit( c, INSTR_SET_ON, 0 ); break; } adjust_result( c, RESULT_STACK, result_location ); } else if ( parse->type == PARSE_SWITCH ) { int const switch_end = compile_new_label( c ); compile_parse( parse->left, c, RESULT_STACK ); for ( parse = parse->right; parse; parse = parse->right ) { int const id = compile_emit_constant( c, parse->left->string ); int const next_case = compile_new_label( c ); compile_emit( c, INSTR_PUSH_CONSTANT, id ); compile_emit_branch( c, INSTR_JUMP_NOT_GLOB, next_case ); compile_parse( parse->left->left, c, result_location ); compile_emit_branch( c, INSTR_JUMP, switch_end ); compile_set_label( c, next_case ); } compile_emit( c, INSTR_POP, 0 ); adjust_result( c, RESULT_NONE, result_location ); compile_set_label( c, switch_end ); } else if ( parse->type == PARSE_NULL ) adjust_result( c, RESULT_NONE, result_location ); else assert( !"unknown PARSE type." ); } OBJECT * function_rulename( FUNCTION * function ) { return function->rulename; } void function_set_rulename( FUNCTION * function, OBJECT * rulename ) { function->rulename = rulename; } void function_location( FUNCTION * function_, OBJECT * * file, int * line ) { if ( function_->type == FUNCTION_BUILTIN ) { *file = constant_builtin; *line = -1; } #ifdef HAVE_PYTHON if ( function_->type == FUNCTION_PYTHON ) { *file = constant_builtin; *line = -1; } #endif else { JAM_FUNCTION * function = (JAM_FUNCTION *)function_; assert( function_->type == FUNCTION_JAM ); *file = function->file; *line = function->line; } } static struct arg_list * arg_list_compile_builtin( char const * * args, int * num_arguments ); FUNCTION * function_builtin( LIST * ( * func )( FRAME * frame, int flags ), int flags, char const * * args ) { BUILTIN_FUNCTION * result = BJAM_MALLOC( sizeof( BUILTIN_FUNCTION ) ); result->base.type = FUNCTION_BUILTIN; result->base.reference_count = 1; result->base.rulename = 0; result->base.formal_arguments = arg_list_compile_builtin( args, &result->base.num_formal_arguments ); result->func = func; result->flags = flags; return (FUNCTION *)result; } FUNCTION * function_compile( PARSE * parse ) { compiler c[ 1 ]; JAM_FUNCTION * result; compiler_init( c ); compile_parse( parse, c, RESULT_RETURN ); compile_emit( c, INSTR_RETURN, 0 ); result = compile_to_function( c ); compiler_free( c ); result->file = object_copy( parse->file ); result->line = parse->line; return (FUNCTION *)result; } FUNCTION * function_compile_actions( char const * actions, OBJECT * file, int line ) { compiler c[ 1 ]; JAM_FUNCTION * result; VAR_PARSE_ACTIONS * parse; current_file = object_str( file ); current_line = line; parse = parse_actions( actions ); compiler_init( c ); var_parse_actions_compile( parse, c ); var_parse_actions_free( parse ); compile_emit( c, INSTR_RETURN, 0 ); result = compile_to_function( c ); compiler_free( c ); result->file = object_copy( file ); result->line = line; return (FUNCTION *)result; } static void argument_list_print( struct arg_list * args, int num_args ); /* Define delimiters for type check elements in argument lists (and return type * specifications, eventually). */ # define TYPE_OPEN_DELIM '[' # define TYPE_CLOSE_DELIM ']' /* * is_type_name() - true iff the given string represents a type check * specification. */ int is_type_name( char const * s ) { return s[ 0 ] == TYPE_OPEN_DELIM && s[ strlen( s ) - 1 ] == TYPE_CLOSE_DELIM; } static void argument_error( char const * message, FUNCTION * procedure, FRAME * frame, OBJECT * arg ) { extern void print_source_line( FRAME * ); LOL * actual = frame->args; backtrace_line( frame->prev ); printf( "*** argument error\n* rule %s ( ", frame->rulename ); argument_list_print( procedure->formal_arguments, procedure->num_formal_arguments ); printf( " )\n* called with: ( " ); lol_print( actual ); printf( " )\n* %s %s\n", message, arg ? object_str ( arg ) : "" ); function_location( procedure, &frame->file, &frame->line ); print_source_line( frame ); printf( "see definition of rule '%s' being called\n", frame->rulename ); backtrace( frame->prev ); exit( 1 ); } static void type_check_range( OBJECT * type_name, LISTITER iter, LISTITER end, FRAME * caller, FUNCTION * called, OBJECT * arg_name ) { static module_t * typecheck = 0; /* If nothing to check, bail now. */ if ( iter == end || !type_name ) return; if ( !typecheck ) typecheck = bindmodule( constant_typecheck ); /* If the checking rule can not be found, also bail. */ if ( !typecheck->rules || !hash_find( typecheck->rules, type_name ) ) return; for ( ; iter != end; iter = list_next( iter ) ) { LIST * error; FRAME frame[ 1 ]; frame_init( frame ); frame->module = typecheck; frame->prev = caller; frame->prev_user = caller->module->user_module ? caller : caller->prev_user; /* Prepare the argument list */ lol_add( frame->args, list_new( object_copy( list_item( iter ) ) ) ); error = evaluate_rule( bindrule( type_name, frame->module ), type_name, frame ); if ( !list_empty( error ) ) argument_error( object_str( list_front( error ) ), called, caller, arg_name ); frame_free( frame ); } } static void type_check( OBJECT * type_name, LIST * values, FRAME * caller, FUNCTION * called, OBJECT * arg_name ) { type_check_range( type_name, list_begin( values ), list_end( values ), caller, called, arg_name ); } void argument_list_check( struct arg_list * formal, int formal_count, FUNCTION * function, FRAME * frame ) { LOL * all_actual = frame->args; int i; for ( i = 0; i < formal_count; ++i ) { LIST * actual = lol_get( all_actual, i ); LISTITER actual_iter = list_begin( actual ); LISTITER const actual_end = list_end( actual ); int j; for ( j = 0; j < formal[ i ].size; ++j ) { struct argument * formal_arg = &formal[ i ].args[ j ]; LIST * value; switch ( formal_arg->flags ) { case ARG_ONE: if ( actual_iter == actual_end ) argument_error( "missing argument", function, frame, formal_arg->arg_name ); type_check_range( formal_arg->type_name, actual_iter, list_next( actual_iter ), frame, function, formal_arg->arg_name ); actual_iter = list_next( actual_iter ); break; case ARG_OPTIONAL: if ( actual_iter == actual_end ) value = L0; else { type_check_range( formal_arg->type_name, actual_iter, list_next( actual_iter ), frame, function, formal_arg->arg_name ); actual_iter = list_next( actual_iter ); } break; case ARG_PLUS: if ( actual_iter == actual_end ) argument_error( "missing argument", function, frame, formal_arg->arg_name ); /* fallthrough */ case ARG_STAR: type_check_range( formal_arg->type_name, actual_iter, actual_end, frame, function, formal_arg->arg_name ); actual_iter = actual_end; break; case ARG_VARIADIC: return; } } if ( actual_iter != actual_end ) argument_error( "extra argument", function, frame, list_item( actual_iter ) ); } for ( ; i < all_actual->count; ++i ) { LIST * actual = lol_get( all_actual, i ); if ( !list_empty( actual ) ) argument_error( "extra argument", function, frame, list_front( actual ) ); } } void argument_list_push( struct arg_list * formal, int formal_count, FUNCTION * function, FRAME * frame, STACK * s ) { LOL * all_actual = frame->args; int i; for ( i = 0; i < formal_count; ++i ) { LIST * actual = lol_get( all_actual, i ); LISTITER actual_iter = list_begin( actual ); LISTITER const actual_end = list_end( actual ); int j; for ( j = 0; j < formal[ i ].size; ++j ) { struct argument * formal_arg = &formal[ i ].args[ j ]; LIST * value; switch ( formal_arg->flags ) { case ARG_ONE: if ( actual_iter == actual_end ) argument_error( "missing argument", function, frame, formal_arg->arg_name ); value = list_new( object_copy( list_item( actual_iter ) ) ); actual_iter = list_next( actual_iter ); break; case ARG_OPTIONAL: if ( actual_iter == actual_end ) value = L0; else { value = list_new( object_copy( list_item( actual_iter ) ) ); actual_iter = list_next( actual_iter ); } break; case ARG_PLUS: if ( actual_iter == actual_end ) argument_error( "missing argument", function, frame, formal_arg->arg_name ); /* fallthrough */ case ARG_STAR: value = list_copy_range( actual, actual_iter, actual_end ); actual_iter = actual_end; break; case ARG_VARIADIC: return; } type_check( formal_arg->type_name, value, frame, function, formal_arg->arg_name ); if ( formal_arg->index != -1 ) { LIST * * const old = &frame->module->fixed_variables[ formal_arg->index ]; stack_push( s, *old ); *old = value; } else stack_push( s, var_swap( frame->module, formal_arg->arg_name, value ) ); } if ( actual_iter != actual_end ) argument_error( "extra argument", function, frame, list_item( actual_iter ) ); } for ( ; i < all_actual->count; ++i ) { LIST * const actual = lol_get( all_actual, i ); if ( !list_empty( actual ) ) argument_error( "extra argument", function, frame, list_front( actual ) ); } } void argument_list_pop( struct arg_list * formal, int formal_count, FRAME * frame, STACK * s ) { int i; for ( i = formal_count - 1; i >= 0; --i ) { int j; for ( j = formal[ i ].size - 1; j >= 0 ; --j ) { struct argument * formal_arg = &formal[ i ].args[ j ]; if ( formal_arg->flags == ARG_VARIADIC ) continue; if ( formal_arg->index != -1 ) { LIST * const old = stack_pop( s ); LIST * * const pos = &frame->module->fixed_variables[ formal_arg->index ]; list_free( *pos ); *pos = old; } else var_set( frame->module, formal_arg->arg_name, stack_pop( s ), VAR_SET ); } } } struct argument_compiler { struct dynamic_array args[ 1 ]; struct argument arg; int state; #define ARGUMENT_COMPILER_START 0 #define ARGUMENT_COMPILER_FOUND_TYPE 1 #define ARGUMENT_COMPILER_FOUND_OBJECT 2 #define ARGUMENT_COMPILER_DONE 3 }; static void argument_compiler_init( struct argument_compiler * c ) { dynamic_array_init( c->args ); c->state = ARGUMENT_COMPILER_START; } static void argument_compiler_free( struct argument_compiler * c ) { dynamic_array_free( c->args ); } static void argument_compiler_add( struct argument_compiler * c, OBJECT * arg, OBJECT * file, int line ) { switch ( c->state ) { case ARGUMENT_COMPILER_FOUND_OBJECT: if ( object_equal( arg, constant_question_mark ) ) { c->arg.flags = ARG_OPTIONAL; } else if ( object_equal( arg, constant_plus ) ) { c->arg.flags = ARG_PLUS; } else if ( object_equal( arg, constant_star ) ) { c->arg.flags = ARG_STAR; } dynamic_array_push( c->args, c->arg ); c->state = ARGUMENT_COMPILER_START; if ( c->arg.flags != ARG_ONE ) break; /* fall-through */ case ARGUMENT_COMPILER_START: c->arg.type_name = 0; c->arg.index = -1; c->arg.flags = ARG_ONE; if ( is_type_name( object_str( arg ) ) ) { c->arg.type_name = object_copy( arg ); c->state = ARGUMENT_COMPILER_FOUND_TYPE; break; } /* fall-through */ case ARGUMENT_COMPILER_FOUND_TYPE: if ( is_type_name( object_str( arg ) ) ) { printf( "%s:%d: missing argument name before type name: %s\n", object_str( file ), line, object_str( arg ) ); exit( 1 ); } c->arg.arg_name = object_copy( arg ); if ( object_equal( arg, constant_star ) ) { c->arg.flags = ARG_VARIADIC; dynamic_array_push( c->args, c->arg ); c->state = ARGUMENT_COMPILER_DONE; } else { c->state = ARGUMENT_COMPILER_FOUND_OBJECT; } break; case ARGUMENT_COMPILER_DONE: break; } } static void argument_compiler_recurse( struct argument_compiler * c, PARSE * parse ) { if ( parse->type == PARSE_APPEND ) { argument_compiler_recurse( c, parse->left ); argument_compiler_recurse( c, parse->right ); } else if ( parse->type != PARSE_NULL ) { assert( parse->type == PARSE_LIST ); argument_compiler_add( c, parse->string, parse->file, parse->line ); } } static struct arg_list arg_compile_impl( struct argument_compiler * c, OBJECT * file, int line ) { struct arg_list result; switch ( c->state ) { case ARGUMENT_COMPILER_START: case ARGUMENT_COMPILER_DONE: break; case ARGUMENT_COMPILER_FOUND_TYPE: printf( "%s:%d: missing argument name after type name: %s\n", object_str( file ), line, object_str( c->arg.type_name ) ); exit( 1 ); case ARGUMENT_COMPILER_FOUND_OBJECT: dynamic_array_push( c->args, c->arg ); break; } result.size = c->args->size; result.args = BJAM_MALLOC( c->args->size * sizeof( struct argument ) ); memcpy( result.args, c->args->data, c->args->size * sizeof( struct argument ) ); return result; } static struct arg_list arg_compile( PARSE * parse ) { struct argument_compiler c[ 1 ]; struct arg_list result; argument_compiler_init( c ); argument_compiler_recurse( c, parse ); result = arg_compile_impl( c, parse->file, parse->line ); argument_compiler_free( c ); return result; } struct argument_list_compiler { struct dynamic_array args[ 1 ]; }; static void argument_list_compiler_init( struct argument_list_compiler * c ) { dynamic_array_init( c->args ); } static void argument_list_compiler_free( struct argument_list_compiler * c ) { dynamic_array_free( c->args ); } static void argument_list_compiler_add( struct argument_list_compiler * c, PARSE * parse ) { struct arg_list args = arg_compile( parse ); dynamic_array_push( c->args, args ); } static void argument_list_compiler_recurse( struct argument_list_compiler * c, PARSE * parse ) { if ( parse ) { argument_list_compiler_add( c, parse->right ); argument_list_compiler_recurse( c, parse->left ); } } static struct arg_list * arg_list_compile( PARSE * parse, int * num_arguments ) { if ( parse ) { struct argument_list_compiler c[ 1 ]; struct arg_list * result; argument_list_compiler_init( c ); argument_list_compiler_recurse( c, parse ); *num_arguments = c->args->size; result = BJAM_MALLOC( c->args->size * sizeof( struct arg_list ) ); memcpy( result, c->args->data, c->args->size * sizeof( struct arg_list ) ); argument_list_compiler_free( c ); return result; } *num_arguments = 0; return 0; } static struct arg_list * arg_list_compile_builtin( char const * * args, int * num_arguments ) { if ( args ) { struct argument_list_compiler c[ 1 ]; struct arg_list * result; argument_list_compiler_init( c ); while ( *args ) { struct argument_compiler arg_comp[ 1 ]; struct arg_list arg; argument_compiler_init( arg_comp ); for ( ; *args; ++args ) { OBJECT * token; if ( strcmp( *args, ":" ) == 0 ) { ++args; break; } token = object_new( *args ); argument_compiler_add( arg_comp, token, constant_builtin, -1 ); object_free( token ); } arg = arg_compile_impl( arg_comp, constant_builtin, -1 ); dynamic_array_push( c->args, arg ); argument_compiler_free( arg_comp ); } *num_arguments = c->args->size; result = BJAM_MALLOC( c->args->size * sizeof( struct arg_list ) ); memcpy( result, c->args->data, c->args->size * sizeof( struct arg_list ) ); argument_list_compiler_free( c ); return result; } *num_arguments = 0; return 0; } static void argument_list_print( struct arg_list * args, int num_args ) { if ( args ) { int i; for ( i = 0; i < num_args; ++i ) { int j; if ( i ) printf( " : " ); for ( j = 0; j < args[ i ].size; ++j ) { struct argument * formal_arg = &args[ i ].args[ j ]; if ( j ) printf( " " ); if ( formal_arg->type_name ) printf( "%s ", object_str( formal_arg->type_name ) ); printf( "%s", object_str( formal_arg->arg_name ) ); switch ( formal_arg->flags ) { case ARG_OPTIONAL: printf( " ?" ); break; case ARG_PLUS: printf( " +" ); break; case ARG_STAR: printf( " *" ); break; } } } } } struct arg_list * argument_list_bind_variables( struct arg_list * formal, int formal_count, module_t * module, int * counter ) { if ( formal ) { struct arg_list * result = (struct arg_list *)BJAM_MALLOC( sizeof( struct arg_list ) * formal_count ); int i; for ( i = 0; i < formal_count; ++i ) { int j; struct argument * args = (struct argument *)BJAM_MALLOC( sizeof( struct argument ) * formal[ i ].size ); for ( j = 0; j < formal[ i ].size; ++j ) { args[ j ] = formal[ i ].args[ j ]; if ( args[ j ].type_name ) args[ j ].type_name = object_copy( args[ j ].type_name ); args[ j ].arg_name = object_copy( args[ j ].arg_name ); if ( args[ j ].flags != ARG_VARIADIC ) args[ j ].index = module_add_fixed_var( module, args[ j ].arg_name, counter ); } result[ i ].args = args; result[ i ].size = formal[ i ].size; } return result; } return 0; } void argument_list_free( struct arg_list * args, int args_count ) { int i; for ( i = 0; i < args_count; ++i ) { int j; for ( j = 0; j < args[ i ].size; ++j ) { if ( args[ i ].args[ j ].type_name ) object_free( args[ i ].args[ j ].type_name ); object_free( args[ i ].args[ j ].arg_name ); } BJAM_FREE( args[ i ].args ); } BJAM_FREE( args ); } FUNCTION * function_unbind_variables( FUNCTION * f ) { if ( f->type == FUNCTION_JAM ) { JAM_FUNCTION * const func = (JAM_FUNCTION *)f; return func->generic ? func->generic : f; } #ifdef HAVE_PYTHON if ( f->type == FUNCTION_PYTHON ) return f; #endif assert( f->type == FUNCTION_BUILTIN ); return f; } FUNCTION * function_bind_variables( FUNCTION * f, module_t * module, int * counter ) { if ( f->type == FUNCTION_BUILTIN ) return f; #ifdef HAVE_PYTHON if ( f->type == FUNCTION_PYTHON ) return f; #endif { JAM_FUNCTION * func = (JAM_FUNCTION *)f; JAM_FUNCTION * new_func = BJAM_MALLOC( sizeof( JAM_FUNCTION ) ); instruction * code; int i; assert( f->type == FUNCTION_JAM ); memcpy( new_func, func, sizeof( JAM_FUNCTION ) ); new_func->base.reference_count = 1; new_func->base.formal_arguments = argument_list_bind_variables( f->formal_arguments, f->num_formal_arguments, module, counter ); new_func->code = BJAM_MALLOC( func->code_size * sizeof( instruction ) ); memcpy( new_func->code, func->code, func->code_size * sizeof( instruction ) ); new_func->generic = (FUNCTION *)func; func = new_func; for ( i = 0; ; ++i ) { OBJECT * key; int op_code; code = func->code + i; switch ( code->op_code ) { case INSTR_PUSH_VAR: op_code = INSTR_PUSH_VAR_FIXED; break; case INSTR_PUSH_LOCAL: op_code = INSTR_PUSH_LOCAL_FIXED; break; case INSTR_POP_LOCAL: op_code = INSTR_POP_LOCAL_FIXED; break; case INSTR_SET: op_code = INSTR_SET_FIXED; break; case INSTR_APPEND: op_code = INSTR_APPEND_FIXED; break; case INSTR_DEFAULT: op_code = INSTR_DEFAULT_FIXED; break; case INSTR_RETURN: return (FUNCTION *)new_func; case INSTR_CALL_MEMBER_RULE: case INSTR_CALL_RULE: ++i; continue; case INSTR_PUSH_MODULE: { int depth = 1; ++i; while ( depth > 0 ) { code = func->code + i; switch ( code->op_code ) { case INSTR_PUSH_MODULE: case INSTR_CLASS: ++depth; break; case INSTR_POP_MODULE: --depth; break; case INSTR_CALL_RULE: ++i; break; } ++i; } --i; } default: continue; } key = func->constants[ code->arg ]; if ( !( object_equal( key, constant_TMPDIR ) || object_equal( key, constant_TMPNAME ) || object_equal( key, constant_TMPFILE ) || object_equal( key, constant_STDOUT ) || object_equal( key, constant_STDERR ) ) ) { code->op_code = op_code; code->arg = module_add_fixed_var( module, key, counter ); } } } } void function_refer( FUNCTION * func ) { ++func->reference_count; } void function_free( FUNCTION * function_ ) { int i; if ( --function_->reference_count != 0 ) return; if ( function_->formal_arguments ) argument_list_free( function_->formal_arguments, function_->num_formal_arguments ); if ( function_->type == FUNCTION_JAM ) { JAM_FUNCTION * func = (JAM_FUNCTION *)function_; BJAM_FREE( func->code ); if ( func->generic ) function_free( func->generic ); else { if ( function_->rulename ) object_free( function_->rulename ); for ( i = 0; i < func->num_constants; ++i ) object_free( func->constants[ i ] ); BJAM_FREE( func->constants ); for ( i = 0; i < func->num_subfunctions; ++i ) { object_free( func->functions[ i ].name ); function_free( func->functions[ i ].code ); } BJAM_FREE( func->functions ); for ( i = 0; i < func->num_subactions; ++i ) { object_free( func->actions[ i ].name ); function_free( func->actions[ i ].command ); } BJAM_FREE( func->actions ); object_free( func->file ); } } #ifdef HAVE_PYTHON else if ( function_->type == FUNCTION_PYTHON ) { PYTHON_FUNCTION * func = (PYTHON_FUNCTION *)function_; Py_DECREF( func->python_function ); if ( function_->rulename ) object_free( function_->rulename ); } #endif else { assert( function_->type == FUNCTION_BUILTIN ); if ( function_->rulename ) object_free( function_->rulename ); } BJAM_FREE( function_ ); } /* Alignment check for stack */ struct align_var_edits { char ch; VAR_EDITS e; }; struct align_expansion_item { char ch; expansion_item e; }; static char check_align_var_edits[ sizeof(struct align_var_edits) <= sizeof(VAR_EDITS) + sizeof(void *) ? 1 : -1 ]; static char check_align_expansion_item[ sizeof(struct align_expansion_item) <= sizeof(expansion_item) + sizeof(void *) ? 1 : -1 ]; static char check_ptr_size1[ sizeof(LIST *) <= sizeof(void *) ? 1 : -1 ]; static char check_ptr_size2[ sizeof(char *) <= sizeof(void *) ? 1 : -1 ]; void function_run_actions( FUNCTION * function, FRAME * frame, STACK * s, string * out ) { *(string * *)stack_allocate( s, sizeof( string * ) ) = out; list_free( function_run( function, frame, s ) ); stack_deallocate( s, sizeof( string * ) ); } /* * WARNING: The instruction set is tuned for Jam and is not really generic. Be * especially careful about stack push/pop. */ LIST * function_run( FUNCTION * function_, FRAME * frame, STACK * s ) { JAM_FUNCTION * function; instruction * code; LIST * l; LIST * r; LIST * result = L0; void * saved_stack = s->data; if ( function_->type == FUNCTION_BUILTIN ) { BUILTIN_FUNCTION const * const f = (BUILTIN_FUNCTION *)function_; if ( function_->formal_arguments ) argument_list_check( function_->formal_arguments, function_->num_formal_arguments, function_, frame ); return f->func( frame, f->flags ); } #ifdef HAVE_PYTHON else if ( function_->type == FUNCTION_PYTHON ) { PYTHON_FUNCTION * f = (PYTHON_FUNCTION *)function_; return call_python_function( f, frame ); } #endif assert( function_->type == FUNCTION_JAM ); if ( function_->formal_arguments ) argument_list_push( function_->formal_arguments, function_->num_formal_arguments, function_, frame, s ); function = (JAM_FUNCTION *)function_; code = function->code; for ( ; ; ) { switch ( code->op_code ) { /* * Basic stack manipulation */ case INSTR_PUSH_EMPTY: stack_push( s, L0 ); break; case INSTR_PUSH_CONSTANT: { OBJECT * value = function_get_constant( function, code->arg ); stack_push( s, list_new( object_copy( value ) ) ); break; } case INSTR_PUSH_ARG: stack_push( s, frame_get_local( frame, code->arg ) ); break; case INSTR_PUSH_VAR: stack_push( s, function_get_variable( function, frame, code->arg ) ); break; case INSTR_PUSH_VAR_FIXED: stack_push( s, list_copy( frame->module->fixed_variables[ code->arg ] ) ); break; case INSTR_PUSH_GROUP: { LIST * value = L0; LISTITER iter; LISTITER end; l = stack_pop( s ); for ( iter = list_begin( l ), end = list_end( l ); iter != end; iter = list_next( iter ) ) value = list_append( value, function_get_named_variable( function, frame, list_item( iter ) ) ); list_free( l ); stack_push( s, value ); break; } case INSTR_PUSH_APPEND: r = stack_pop( s ); l = stack_pop( s ); stack_push( s, list_append( l, r ) ); break; case INSTR_SWAP: l = stack_top( s ); stack_set( s, 0, stack_at( s, code->arg ) ); stack_set( s, code->arg, l ); break; case INSTR_POP: list_free( stack_pop( s ) ); break; /* * Branch instructions */ case INSTR_JUMP: code += code->arg; break; case INSTR_JUMP_EMPTY: l = stack_pop( s ); if ( !list_cmp( l, L0 ) ) code += code->arg; list_free( l ); break; case INSTR_JUMP_NOT_EMPTY: l = stack_pop( s ); if ( list_cmp( l, L0 ) ) code += code->arg; list_free( l ); break; case INSTR_JUMP_LT: r = stack_pop( s ); l = stack_pop( s ); if ( list_cmp( l, r ) < 0 ) code += code->arg; list_free( l ); list_free( r ); break; case INSTR_JUMP_LE: r = stack_pop( s ); l = stack_pop( s ); if ( list_cmp( l, r ) <= 0 ) code += code->arg; list_free( l ); list_free( r ); break; case INSTR_JUMP_GT: r = stack_pop( s ); l = stack_pop( s ); if ( list_cmp( l, r ) > 0 ) code += code->arg; list_free( l ); list_free( r ); break; case INSTR_JUMP_GE: r = stack_pop( s ); l = stack_pop( s ); if ( list_cmp( l, r ) >= 0 ) code += code->arg; list_free( l ); list_free( r ); break; case INSTR_JUMP_EQ: r = stack_pop( s ); l = stack_pop( s ); if ( list_cmp( l, r ) == 0 ) code += code->arg; list_free( l ); list_free( r ); break; case INSTR_JUMP_NE: r = stack_pop(s); l = stack_pop(s); if ( list_cmp(l, r) != 0 ) code += code->arg; list_free(l); list_free(r); break; case INSTR_JUMP_IN: r = stack_pop(s); l = stack_pop(s); if ( list_is_sublist( l, r ) ) code += code->arg; list_free(l); list_free(r); break; case INSTR_JUMP_NOT_IN: r = stack_pop( s ); l = stack_pop( s ); if ( !list_is_sublist( l, r ) ) code += code->arg; list_free( l ); list_free( r ); break; /* * For */ case INSTR_FOR_INIT: l = stack_top( s ); *(LISTITER *)stack_allocate( s, sizeof( LISTITER ) ) = list_begin( l ); break; case INSTR_FOR_LOOP: { LISTITER iter = *(LISTITER *)stack_get( s ); stack_deallocate( s, sizeof( LISTITER ) ); l = stack_top( s ); if ( iter == list_end( l ) ) { list_free( stack_pop( s ) ); code += code->arg; } else { r = list_new( object_copy( list_item( iter ) ) ); iter = list_next( iter ); *(LISTITER *)stack_allocate( s, sizeof( LISTITER ) ) = iter; stack_push( s, r ); } break; } /* * Switch */ case INSTR_JUMP_NOT_GLOB: { char const * pattern; char const * match; l = stack_pop( s ); r = stack_top( s ); pattern = list_empty( l ) ? "" : object_str( list_front( l ) ); match = list_empty( r ) ? "" : object_str( list_front( r ) ); if ( glob( pattern, match ) ) code += code->arg; else list_free( stack_pop( s ) ); list_free( l ); break; } /* * Return */ case INSTR_SET_RESULT: list_free( result ); if ( !code->arg ) result = stack_pop( s ); else result = list_copy( stack_top( s ) ); break; case INSTR_PUSH_RESULT: stack_push( s, result ); result = L0; break; case INSTR_RETURN: { if ( function_->formal_arguments ) argument_list_pop( function_->formal_arguments, function_->num_formal_arguments, frame, s ); #ifndef NDEBUG if ( !( saved_stack == s->data ) ) { frame->file = function->file; frame->line = function->line; backtrace_line( frame ); printf( "error: stack check failed.\n" ); backtrace( frame ); assert( saved_stack == s->data ); } #endif assert( saved_stack == s->data ); return result; } /* * Local variables */ case INSTR_PUSH_LOCAL: { LIST * value = stack_pop( s ); stack_push( s, function_swap_variable( function, frame, code->arg, value ) ); break; } case INSTR_POP_LOCAL: function_set_variable( function, frame, code->arg, stack_pop( s ) ); break; case INSTR_PUSH_LOCAL_FIXED: { LIST * value = stack_pop( s ); LIST * * ptr = &frame->module->fixed_variables[ code->arg ]; assert( code->arg < frame->module->num_fixed_variables ); stack_push( s, *ptr ); *ptr = value; break; } case INSTR_POP_LOCAL_FIXED: { LIST * value = stack_pop( s ); LIST * * ptr = &frame->module->fixed_variables[ code->arg ]; assert( code->arg < frame->module->num_fixed_variables ); list_free( *ptr ); *ptr = value; break; } case INSTR_PUSH_LOCAL_GROUP: { LIST * const value = stack_pop( s ); LISTITER iter; LISTITER end; l = stack_pop( s ); for ( iter = list_begin( l ), end = list_end( l ); iter != end; iter = list_next( iter ) ) stack_push( s, function_swap_named_variable( function, frame, list_item( iter ), list_copy( value ) ) ); list_free( value ); stack_push( s, l ); break; } case INSTR_POP_LOCAL_GROUP: { LISTITER iter; LISTITER end; r = stack_pop( s ); l = list_reverse( r ); list_free( r ); for ( iter = list_begin( l ), end = list_end( l ); iter != end; iter = list_next( iter ) ) function_set_named_variable( function, frame, list_item( iter ), stack_pop( s ) ); list_free( l ); break; } /* * on $(TARGET) variables */ case INSTR_PUSH_ON: { LIST * targets = stack_top( s ); if ( !list_empty( targets ) ) { /* FIXME: push the state onto the stack instead of using * pushsettings. */ TARGET * t = bindtarget( list_front( targets ) ); pushsettings( frame->module, t->settings ); } else { /* [ on $(TARGET) ... ] is ignored if $(TARGET) is empty. */ list_free( stack_pop( s ) ); stack_push( s, L0 ); code += code->arg; } break; } case INSTR_POP_ON: { LIST * result = stack_pop( s ); LIST * targets = stack_pop( s ); if ( !list_empty( targets ) ) { TARGET * t = bindtarget( list_front( targets ) ); popsettings( frame->module, t->settings ); } list_free( targets ); stack_push( s, result ); break; } case INSTR_SET_ON: { LIST * targets = stack_pop( s ); LIST * value = stack_pop( s ); LIST * vars = stack_pop( s ); LISTITER iter = list_begin( targets ); LISTITER const end = list_end( targets ); for ( ; iter != end; iter = list_next( iter ) ) { TARGET * t = bindtarget( list_item( iter ) ); LISTITER vars_iter = list_begin( vars ); LISTITER const vars_end = list_end( vars ); for ( ; vars_iter != vars_end; vars_iter = list_next( vars_iter ) ) t->settings = addsettings( t->settings, VAR_SET, list_item( vars_iter ), list_copy( value ) ); } list_free( vars ); list_free( targets ); stack_push( s, value ); break; } case INSTR_APPEND_ON: { LIST * targets = stack_pop( s ); LIST * value = stack_pop( s ); LIST * vars = stack_pop( s ); LISTITER iter = list_begin( targets ); LISTITER const end = list_end( targets ); for ( ; iter != end; iter = list_next( iter ) ) { TARGET * const t = bindtarget( list_item( iter ) ); LISTITER vars_iter = list_begin( vars ); LISTITER const vars_end = list_end( vars ); for ( ; vars_iter != vars_end; vars_iter = list_next( vars_iter ) ) t->settings = addsettings( t->settings, VAR_APPEND, list_item( vars_iter ), list_copy( value ) ); } list_free( vars ); list_free( targets ); stack_push( s, value ); break; } case INSTR_DEFAULT_ON: { LIST * targets = stack_pop( s ); LIST * value = stack_pop( s ); LIST * vars = stack_pop( s ); LISTITER iter = list_begin( targets ); LISTITER const end = list_end( targets ); for ( ; iter != end; iter = list_next( iter ) ) { TARGET * t = bindtarget( list_item( iter ) ); LISTITER vars_iter = list_begin( vars ); LISTITER const vars_end = list_end( vars ); for ( ; vars_iter != vars_end; vars_iter = list_next( vars_iter ) ) t->settings = addsettings( t->settings, VAR_DEFAULT, list_item( vars_iter ), list_copy( value ) ); } list_free( vars ); list_free( targets ); stack_push( s, value ); break; } /* [ on $(target) return $(variable) ] */ case INSTR_GET_ON: { LIST * targets = stack_pop( s ); LIST * result = L0; if ( !list_empty( targets ) ) { OBJECT * varname = function->constants[ code->arg ]; TARGET * t = bindtarget( list_front( targets ) ); SETTINGS * s = t->settings; int found = 0; for ( ; s != 0; s = s->next ) { if ( object_equal( s->symbol, varname ) ) { result = s->value; found = 1; break; } } if ( !found ) { result = var_get( frame->module, varname ) ; } } stack_push( s, list_copy( result ) ); break; } /* * Variable setting */ case INSTR_SET: function_set_variable( function, frame, code->arg, stack_pop( s ) ); break; case INSTR_APPEND: function_append_variable( function, frame, code->arg, stack_pop( s ) ); break; case INSTR_DEFAULT: function_default_variable( function, frame, code->arg, stack_pop( s ) ); break; case INSTR_SET_FIXED: { LIST * * ptr = &frame->module->fixed_variables[ code->arg ]; assert( code->arg < frame->module->num_fixed_variables ); list_free( *ptr ); *ptr = stack_pop( s ); break; } case INSTR_APPEND_FIXED: { LIST * * ptr = &frame->module->fixed_variables[ code->arg ]; assert( code->arg < frame->module->num_fixed_variables ); *ptr = list_append( *ptr, stack_pop( s ) ); break; } case INSTR_DEFAULT_FIXED: { LIST * * ptr = &frame->module->fixed_variables[ code->arg ]; LIST * value = stack_pop( s ); assert( code->arg < frame->module->num_fixed_variables ); if ( list_empty( *ptr ) ) *ptr = value; else list_free( value ); break; } case INSTR_SET_GROUP: { LIST * value = stack_pop( s ); LIST * vars = stack_pop( s ); LISTITER iter = list_begin( vars ); LISTITER const end = list_end( vars ); for ( ; iter != end; iter = list_next( iter ) ) function_set_named_variable( function, frame, list_item( iter ), list_copy( value ) ); list_free( vars ); list_free( value ); break; } case INSTR_APPEND_GROUP: { LIST * value = stack_pop( s ); LIST * vars = stack_pop( s ); LISTITER iter = list_begin( vars ); LISTITER const end = list_end( vars ); for ( ; iter != end; iter = list_next( iter ) ) function_append_named_variable( function, frame, list_item( iter ), list_copy( value ) ); list_free( vars ); list_free( value ); break; } case INSTR_DEFAULT_GROUP: { LIST * value = stack_pop( s ); LIST * vars = stack_pop( s ); LISTITER iter = list_begin( vars ); LISTITER const end = list_end( vars ); for ( ; iter != end; iter = list_next( iter ) ) function_default_named_variable( function, frame, list_item( iter ), list_copy( value ) ); list_free( vars ); list_free( value ); break; } /* * Rules */ case INSTR_CALL_RULE: { char const * unexpanded = object_str( function_get_constant( function, code[ 1 ].op_code ) ); LIST * result = function_call_rule( function, frame, s, code->arg, unexpanded, function->file, code[ 1 ].arg ); stack_push( s, result ); ++code; break; } case INSTR_CALL_MEMBER_RULE: { OBJECT * rule_name = function_get_constant( function, code[1].op_code ); LIST * result = function_call_member_rule( function, frame, s, code->arg, rule_name, function->file, code[1].arg ); stack_push( s, result ); ++code; break; } case INSTR_RULE: function_set_rule( function, frame, s, code->arg ); break; case INSTR_ACTIONS: function_set_actions( function, frame, s, code->arg ); break; /* * Variable expansion */ case INSTR_APPLY_MODIFIERS: { int n; int i; l = stack_pop( s ); n = expand_modifiers( s, code->arg ); stack_push( s, l ); l = apply_modifiers( s, n ); list_free( stack_pop( s ) ); stack_deallocate( s, n * sizeof( VAR_EDITS ) ); for ( i = 0; i < code->arg; ++i ) list_free( stack_pop( s ) ); /* pop modifiers */ stack_push( s, l ); break; } case INSTR_APPLY_INDEX: l = apply_subscript( s ); list_free( stack_pop( s ) ); list_free( stack_pop( s ) ); stack_push( s, l ); break; case INSTR_APPLY_INDEX_MODIFIERS: { int i; int n; l = stack_pop( s ); r = stack_pop( s ); n = expand_modifiers( s, code->arg ); stack_push( s, r ); stack_push( s, l ); l = apply_subscript_and_modifiers( s, n ); list_free( stack_pop( s ) ); list_free( stack_pop( s ) ); stack_deallocate( s, n * sizeof( VAR_EDITS ) ); for ( i = 0; i < code->arg; ++i ) list_free( stack_pop( s ) ); /* pop modifiers */ stack_push( s, l ); break; } case INSTR_APPLY_MODIFIERS_GROUP: { int i; LIST * const vars = stack_pop( s ); int const n = expand_modifiers( s, code->arg ); LIST * result = L0; LISTITER iter = list_begin( vars ); LISTITER const end = list_end( vars ); for ( ; iter != end; iter = list_next( iter ) ) { stack_push( s, function_get_named_variable( function, frame, list_item( iter ) ) ); result = list_append( result, apply_modifiers( s, n ) ); list_free( stack_pop( s ) ); } list_free( vars ); stack_deallocate( s, n * sizeof( VAR_EDITS ) ); for ( i = 0; i < code->arg; ++i ) list_free( stack_pop( s ) ); /* pop modifiers */ stack_push( s, result ); break; } case INSTR_APPLY_INDEX_GROUP: { LIST * vars = stack_pop( s ); LIST * result = L0; LISTITER iter = list_begin( vars ); LISTITER const end = list_end( vars ); for ( ; iter != end; iter = list_next( iter ) ) { stack_push( s, function_get_named_variable( function, frame, list_item( iter ) ) ); result = list_append( result, apply_subscript( s ) ); list_free( stack_pop( s ) ); } list_free( vars ); list_free( stack_pop( s ) ); stack_push( s, result ); break; } case INSTR_APPLY_INDEX_MODIFIERS_GROUP: { int i; LIST * const vars = stack_pop( s ); LIST * const r = stack_pop( s ); int const n = expand_modifiers( s, code->arg ); LIST * result = L0; LISTITER iter = list_begin( vars ); LISTITER const end = list_end( vars ); stack_push( s, r ); for ( ; iter != end; iter = list_next( iter ) ) { stack_push( s, function_get_named_variable( function, frame, list_item( iter ) ) ); result = list_append( result, apply_subscript_and_modifiers( s, n ) ); list_free( stack_pop( s ) ); } list_free( stack_pop( s ) ); list_free( vars ); stack_deallocate( s, n * sizeof( VAR_EDITS ) ); for ( i = 0; i < code->arg; ++i ) list_free( stack_pop( s ) ); /* pop modifiers */ stack_push( s, result ); break; } case INSTR_COMBINE_STRINGS: { size_t const buffer_size = code->arg * sizeof( expansion_item ); LIST * * const stack_pos = stack_get( s ); expansion_item * items = stack_allocate( s, buffer_size ); LIST * result; int i; for ( i = 0; i < code->arg; ++i ) items[ i ].values = stack_pos[ i ]; result = expand( items, code->arg ); stack_deallocate( s, buffer_size ); for ( i = 0; i < code->arg; ++i ) list_free( stack_pop( s ) ); stack_push( s, result ); break; } case INSTR_GET_GRIST: { LIST * vals = stack_pop( s ); LIST * result = L0; LISTITER iter, end; for ( iter = list_begin( vals ), end = list_end( vals ); iter != end; ++iter ) { OBJECT * new_object; const char * value = object_str( list_item( iter ) ); const char * p; if ( value[ 0 ] == '<' && ( p = strchr( value, '>' ) ) ) { if( p[ 1 ] ) new_object = object_new_range( value, p - value + 1 ); else new_object = object_copy( list_item( iter ) ); } else { new_object = object_copy( constant_empty ); } result = list_push_back( result, new_object ); } list_free( vals ); stack_push( s, result ); break; } case INSTR_INCLUDE: { LIST * nt = stack_pop( s ); if ( !list_empty( nt ) ) { TARGET * const t = bindtarget( list_front( nt ) ); list_free( nt ); /* DWA 2001/10/22 - Perforce Jam cleared the arguments here, * which prevented an included file from being treated as part * of the body of a rule. I did not see any reason to do that, * so I lifted the restriction. */ /* Bind the include file under the influence of "on-target" * variables. Though they are targets, include files are not * built with make(). */ pushsettings( root_module(), t->settings ); /* We do not expect that a file to be included is generated by * some action. Therefore, pass 0 as third argument. If the name * resolves to a directory, let it error out. */ object_free( t->boundname ); t->boundname = search( t->name, &t->time, 0, 0 ); popsettings( root_module(), t->settings ); parse_file( t->boundname, frame ); } break; } /* * Classes and modules */ case INSTR_PUSH_MODULE: { LIST * const module_name = stack_pop( s ); module_t * const outer_module = frame->module; frame->module = !list_empty( module_name ) ? bindmodule( list_front( module_name ) ) : root_module(); list_free( module_name ); *(module_t * *)stack_allocate( s, sizeof( module_t * ) ) = outer_module; break; } case INSTR_POP_MODULE: { module_t * const outer_module = *(module_t * *)stack_get( s ); stack_deallocate( s, sizeof( module_t * ) ); frame->module = outer_module; break; } case INSTR_CLASS: { LIST * bases = stack_pop( s ); LIST * name = stack_pop( s ); OBJECT * class_module = make_class_module( name, bases, frame ); module_t * const outer_module = frame->module; frame->module = bindmodule( class_module ); object_free( class_module ); *(module_t * *)stack_allocate( s, sizeof( module_t * ) ) = outer_module; break; } case INSTR_BIND_MODULE_VARIABLES: module_bind_variables( frame->module ); break; case INSTR_APPEND_STRINGS: { string buf[ 1 ]; string_new( buf ); combine_strings( s, code->arg, buf ); stack_push( s, list_new( object_new( buf->value ) ) ); string_free( buf ); break; } case INSTR_WRITE_FILE: { string buf[ 1 ]; char const * out; OBJECT * tmp_filename = 0; int out_debug = DEBUG_EXEC ? 1 : 0; FILE * out_file = 0; string_new( buf ); combine_strings( s, code->arg, buf ); out = object_str( list_front( stack_top( s ) ) ); /* For stdout/stderr we will create a temp file and generate a * command that outputs the content as needed. */ if ( ( strcmp( "STDOUT", out ) == 0 ) || ( strcmp( "STDERR", out ) == 0 ) ) { int err_redir = strcmp( "STDERR", out ) == 0; string result[ 1 ]; tmp_filename = path_tmpfile(); string_new( result ); #ifdef OS_NT string_append( result, "type \"" ); #else string_append( result, "cat \"" ); #endif string_append( result, object_str( tmp_filename ) ); string_push_back( result, '\"' ); if ( err_redir ) string_append( result, " 1>&2" ); /* Replace STDXXX with the temporary file. */ list_free( stack_pop( s ) ); stack_push( s, list_new( object_new( result->value ) ) ); out = object_str( tmp_filename ); string_free( result ); /* Make sure temp files created by this get nuked eventually. */ file_remove_atexit( tmp_filename ); } if ( !globs.noexec ) { string out_name[ 1 ]; /* Handle "path to file" filenames. */ if ( ( out[ 0 ] == '"' ) && ( out[ strlen( out ) - 1 ] == '"' ) ) { string_copy( out_name, out + 1 ); string_truncate( out_name, out_name->size - 1 ); } else string_copy( out_name, out ); out_file = fopen( out_name->value, "w" ); if ( !out_file ) { printf( "failed to write output file '%s'!\n", out_name->value ); exit( EXITBAD ); } string_free( out_name ); } if ( out_debug ) printf( "\nfile %s\n", out ); if ( out_file ) fputs( buf->value, out_file ); if ( out_debug ) fputs( buf->value, stdout ); if ( out_file ) { fflush( out_file ); fclose( out_file ); } string_free( buf ); if ( tmp_filename ) object_free( tmp_filename ); if ( out_debug ) fputc( '\n', stdout ); break; } case INSTR_OUTPUT_STRINGS: { string * const buf = *(string * *)( (char *)stack_get( s ) + ( code->arg * sizeof( LIST * ) ) ); combine_strings( s, code->arg, buf ); break; } } ++code; } } #ifdef HAVE_PYTHON static struct arg_list * arg_list_compile_python( PyObject * bjam_signature, int * num_arguments ) { if ( bjam_signature ) { struct argument_list_compiler c[ 1 ]; struct arg_list * result; Py_ssize_t s; Py_ssize_t i; argument_list_compiler_init( c ); s = PySequence_Size( bjam_signature ); for ( i = 0; i < s; ++i ) { struct argument_compiler arg_comp[ 1 ]; struct arg_list arg; PyObject * v = PySequence_GetItem( bjam_signature, i ); Py_ssize_t j; Py_ssize_t inner; argument_compiler_init( arg_comp ); inner = PySequence_Size( v ); for ( j = 0; j < inner; ++j ) argument_compiler_add( arg_comp, object_new( PyString_AsString( PySequence_GetItem( v, j ) ) ), constant_builtin, -1 ); arg = arg_compile_impl( arg_comp, constant_builtin, -1 ); dynamic_array_push( c->args, arg ); argument_compiler_free( arg_comp ); Py_DECREF( v ); } *num_arguments = c->args->size; result = BJAM_MALLOC( c->args->size * sizeof( struct arg_list ) ); memcpy( result, c->args->data, c->args->size * sizeof( struct arg_list ) ); argument_list_compiler_free( c ); return result; } *num_arguments = 0; return 0; } FUNCTION * function_python( PyObject * function, PyObject * bjam_signature ) { PYTHON_FUNCTION * result = BJAM_MALLOC( sizeof( PYTHON_FUNCTION ) ); result->base.type = FUNCTION_PYTHON; result->base.reference_count = 1; result->base.rulename = 0; result->base.formal_arguments = arg_list_compile_python( bjam_signature, &result->base.num_formal_arguments ); Py_INCREF( function ); result->python_function = function; return (FUNCTION *)result; } static void argument_list_to_python( struct arg_list * formal, int formal_count, FUNCTION * function, FRAME * frame, PyObject * kw ) { LOL * all_actual = frame->args; int i; for ( i = 0; i < formal_count; ++i ) { LIST * actual = lol_get( all_actual, i ); LISTITER actual_iter = list_begin( actual ); LISTITER const actual_end = list_end( actual ); int j; for ( j = 0; j < formal[ i ].size; ++j ) { struct argument * formal_arg = &formal[ i ].args[ j ]; PyObject * value; LIST * l; switch ( formal_arg->flags ) { case ARG_ONE: if ( actual_iter == actual_end ) argument_error( "missing argument", function, frame, formal_arg->arg_name ); type_check_range( formal_arg->type_name, actual_iter, list_next( actual_iter ), frame, function, formal_arg->arg_name ); value = PyString_FromString( object_str( list_item( actual_iter ) ) ); actual_iter = list_next( actual_iter ); break; case ARG_OPTIONAL: if ( actual_iter == actual_end ) value = 0; else { type_check_range( formal_arg->type_name, actual_iter, list_next( actual_iter ), frame, function, formal_arg->arg_name ); value = PyString_FromString( object_str( list_item( actual_iter ) ) ); actual_iter = list_next( actual_iter ); } break; case ARG_PLUS: if ( actual_iter == actual_end ) argument_error( "missing argument", function, frame, formal_arg->arg_name ); /* fallthrough */ case ARG_STAR: type_check_range( formal_arg->type_name, actual_iter, actual_end, frame, function, formal_arg->arg_name ); l = list_copy_range( actual, actual_iter, actual_end ); value = list_to_python( l ); list_free( l ); actual_iter = actual_end; break; case ARG_VARIADIC: return; } if ( value ) { PyObject * key = PyString_FromString( object_str( formal_arg->arg_name ) ); PyDict_SetItem( kw, key, value ); Py_DECREF( key ); Py_DECREF( value ); } } if ( actual_iter != actual_end ) argument_error( "extra argument", function, frame, list_item( actual_iter ) ); } for ( ; i < all_actual->count; ++i ) { LIST * const actual = lol_get( all_actual, i ); if ( !list_empty( actual ) ) argument_error( "extra argument", function, frame, list_front( actual ) ); } } /* Given a Python object, return a string to use in Jam code instead of the said * object. * * If the object is a string, use the string value. * If the object implemenets __jam_repr__ method, use that. * Otherwise return 0. */ OBJECT * python_to_string( PyObject * value ) { if ( PyString_Check( value ) ) return object_new( PyString_AS_STRING( value ) ); /* See if this instance defines the special __jam_repr__ method. */ if ( PyInstance_Check( value ) && PyObject_HasAttrString( value, "__jam_repr__" ) ) { PyObject * repr = PyObject_GetAttrString( value, "__jam_repr__" ); if ( repr ) { PyObject * arguments2 = PyTuple_New( 0 ); PyObject * value2 = PyObject_Call( repr, arguments2, 0 ); Py_DECREF( repr ); Py_DECREF( arguments2 ); if ( PyString_Check( value2 ) ) return object_new( PyString_AS_STRING( value2 ) ); Py_DECREF( value2 ); } } return 0; } static module_t * python_module() { static module_t * python = 0; if ( !python ) python = bindmodule( constant_python ); return python; } static LIST * call_python_function( PYTHON_FUNCTION * function, FRAME * frame ) { LIST * result = 0; PyObject * arguments = 0; PyObject * kw = NULL; int i; PyObject * py_result; FRAME * prev_frame_before_python_call; if ( function->base.formal_arguments ) { arguments = PyTuple_New( 0 ); kw = PyDict_New(); argument_list_to_python( function->base.formal_arguments, function->base.num_formal_arguments, &function->base, frame, kw ); } else { arguments = PyTuple_New( frame->args->count ); for ( i = 0; i < frame->args->count; ++i ) PyTuple_SetItem( arguments, i, list_to_python( lol_get( frame->args, i ) ) ); } frame->module = python_module(); prev_frame_before_python_call = frame_before_python_call; frame_before_python_call = frame; py_result = PyObject_Call( function->python_function, arguments, kw ); frame_before_python_call = prev_frame_before_python_call; Py_DECREF( arguments ); Py_XDECREF( kw ); if ( py_result != NULL ) { if ( PyList_Check( py_result ) ) { int size = PyList_Size( py_result ); int i; for ( i = 0; i < size; ++i ) { OBJECT * s = python_to_string( PyList_GetItem( py_result, i ) ); if ( !s ) fprintf( stderr, "Non-string object returned by Python call.\n" ); else result = list_push_back( result, s ); } } else if ( py_result == Py_None ) { result = L0; } else { OBJECT * const s = python_to_string( py_result ); if ( s ) result = list_new( s ); else /* We have tried all we could. Return empty list. There are * cases, e.g. feature.feature function that should return a * value for the benefit of Python code and which also can be * called by Jam code, where no sensible value can be returned. * We cannot even emit a warning, since there would be a pile of * them. */ result = L0; } Py_DECREF( py_result ); } else { PyErr_Print(); fprintf( stderr, "Call failed\n" ); } return result; } #endif void function_done( void ) { BJAM_FREE( stack ); }