/* function.c QC function support code Copyright (C) 2002 Bill Currie Author: Bill Currie Date: 2002/5/7 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to: Free Software Foundation, Inc. 59 Temple Place - Suite 330 Boston, MA 02111-1307, USA */ #ifdef HAVE_CONFIG_H # include "config.h" #endif static __attribute__ ((used)) const char rcsid[] = "$Id$"; #ifdef HAVE_STRING_H # include #endif #ifdef HAVE_STRINGS_H # include #endif #include #include "QF/dstring.h" #include "QF/hash.h" #include "QF/va.h" #include "qfcc.h" #include "debug.h" #include "def.h" #include "emit.h" #include "expr.h" #include "function.h" #include "immediate.h" #include "opcodes.h" #include "options.h" #include "reloc.h" #include "type.h" static param_t *free_params; static function_t *free_functions; static hashtab_t *overloaded_functions; static hashtab_t *function_map; static const char * ol_func_get_key (void *_f, void *unused) { overloaded_function_t *f = (overloaded_function_t *) _f; return f->full_name; } static const char * func_map_get_key (void *_f, void *unused) { overloaded_function_t *f = (overloaded_function_t *) _f; return f->name; } param_t * new_param (const char *selector, type_t *type, const char *name) { param_t *param; ALLOC (4096, param_t, params, param); param->next = 0; param->selector = selector; param->type = type; param->name = name; return param; } param_t * _reverse_params (param_t *params, param_t *next) { param_t *p = params; if (params->next) p = _reverse_params (params->next, params); params->next = next; return p; } param_t * reverse_params (param_t *params) { if (!params) return 0; return _reverse_params (params, 0); } param_t * copy_params (param_t *params) { param_t *n_parms = 0, **p = &n_parms; while (params) { *p = new_param (params->selector, params->type, params->name); params = params->next; p = &(*p)->next; } return n_parms; } type_t * parse_params (type_t *type, param_t *parms) { param_t *p; type_t new; memset (&new, 0, sizeof (new)); new.type = ev_func; new.aux_type = type; new.num_parms = 0; for (p = parms; p; p = p->next) { if (new.num_parms > MAX_PARMS) { error (0, "too many params"); return type; } if (!p->selector && !p->type && !p->name) { if (p->next) { error (0, "internal error"); abort (); } new.num_parms = -(new.num_parms + 1); } else if (p->type) { new.parm_types[new.num_parms] = p->type; new.num_parms++; } } //print_type (&new); puts(""); return find_type (&new); } overloaded_function_t * get_function (const char *name, type_t *type, int overload, int create) { const char *full_name; overloaded_function_t *func; if (!overloaded_functions) { overloaded_functions = Hash_NewTable (1021, ol_func_get_key, 0, 0); function_map = Hash_NewTable (1021, func_map_get_key, 0, 0); } name = save_string (name); full_name = save_string (va ("%s|%s", name, encode_params (type))); func = Hash_Find (overloaded_functions, full_name); if (func) { if (func->type != type) { error (0, "can't overload on return types"); return func; } return func; } if (!create) return 0; func = Hash_Find (function_map, name); if (func) { if (!overload && !func->overloaded) { warning (0, "creating overloaded function %s without @overload", full_name); warning (0, "(previous function is %s)", func->full_name); } overload = 1; } func = calloc (1, sizeof (overloaded_function_t)); func->name = name; func->full_name = full_name; func->type = type; func->overloaded = overload; Hash_Add (overloaded_functions, func); Hash_Add (function_map, func); return func; } def_t * get_function_def (const char *name, struct type_s *type, scope_t *scope, storage_class_t storage, int overload, int create) { overloaded_function_t *func; func = get_function (name, type, overload, create); if (func && func->overloaded) name = func->full_name; return get_def (type, name, scope, storage); } // NOTE sorts the list in /reverse/ order static int func_compare (const void *a, const void *b) { overloaded_function_t *fa = *(overloaded_function_t **) a; overloaded_function_t *fb = *(overloaded_function_t **) b; type_t *ta = fa->type; type_t *tb = fb->type; int na = ta->num_parms; int nb = tb->num_parms; int ret, i; if (na < 0) na = ~na; if (nb < 0) nb = ~nb; if (na != nb) return nb - na; if ((ret = (fb->type->num_parms - fa->type->num_parms))) return ret; for (i = 0; i < na && i < nb; i++) if (ta->parm_types[i] != tb->parm_types[i]) return (long)(tb->parm_types[i] - ta->parm_types[i]); return 0; } expr_t * find_function (expr_t *fexpr, expr_t *params) { expr_t *e; int i, j, func_count, parm_count, reported = 0; overloaded_function_t *f, dummy, *best = 0; type_t type; void **funcs, *dummy_p = &dummy; if (fexpr->type != ex_name) return fexpr; memset (&type, 0, sizeof (type)); for (e = params; e; e = e->next) { if (e->type == ex_error) return e; type.num_parms++; } if (type.num_parms > MAX_PARMS) return fexpr; for (i = 0, e = params; e; i++, e = e->next) { type.parm_types[type.num_parms - 1 - i] = get_type (e); if (e->type == ex_error) return e; } funcs = Hash_FindList (function_map, fexpr->e.string_val); if (!funcs) return fexpr; for (func_count = 0; funcs[func_count]; func_count++) ; if (func_count < 2) { free (funcs); return fexpr; } type.aux_type = ((overloaded_function_t *) funcs[0])->type->aux_type; dummy.type = find_type (&type); qsort (funcs, func_count, sizeof (void *), func_compare); dummy.full_name = save_string (va ("%s|%s", fexpr->e.string_val, encode_params (&type))); dummy_p = bsearch (&dummy_p, funcs, func_count, sizeof (void *), func_compare); if (dummy_p) { f = (overloaded_function_t *) *(void **) dummy_p; if (f->overloaded) fexpr->e.string_val = f->full_name; free (funcs); return fexpr; } for (i = 0; i < func_count; i++) { f = (overloaded_function_t *) funcs[i]; parm_count = f->type->num_parms; if ((parm_count >= 0 && parm_count != type.num_parms) || (parm_count < 0 && ~parm_count > type.num_parms)) { funcs[i] = 0; continue; } if (parm_count < 0) parm_count = ~parm_count; for (j = 0; j < parm_count; j++) { if (!type_assignable (f->type->parm_types[j], type.parm_types[j])) { funcs[i] = 0; break; } } if (j < parm_count) continue; } for (i = 0; i < func_count; i++) { f = (overloaded_function_t *) funcs[i]; if (f) { if (!best) { best = f; } else { if (!reported) { reported = 1; error (fexpr, "unable to disambiguate %s", dummy.full_name); error (fexpr, "possible match: %s", best->full_name); } error (fexpr, "possible match: %s", f->full_name); } } } if (reported) return fexpr; if (best) { if (best->overloaded) fexpr->e.string_val = best->full_name; free (funcs); return fexpr; } error (fexpr, "unable to find function matching %s", dummy.full_name); free (funcs); return fexpr; } void build_scope (function_t *f, def_t *func, param_t *params) { int i; def_t *def; param_t *p; def_t *args = 0; int parm_ofs[MAX_PARMS]; f->scope = new_scope (sc_params, new_defspace (), pr.scope); if (func->type->num_parms < 0) { args = get_def (&type_va_list, ".args", f->scope, st_local); args->used = 1; def_initialized (args); } for (p = params, i = 0; p; p = p->next) { if (!p->selector && !p->type && !p->name) continue; // ellipsis marker if (!p->type) continue; // non-param selector def = get_def (p->type, p->name, f->scope, st_local); parm_ofs[i] = def->ofs; if (i > 0 && parm_ofs[i] < parm_ofs[i - 1]) { error (0, "bad parm order"); abort (); } //printf ("%s%s %d\n", p == params ? "" : " ", p->name, def->ofs); def->used = 1; // don't warn for unused params def_initialized (def); // params are assumed to be initialized i++; } if (args) { while (i < MAX_PARMS) { def = get_def (&type_vector, 0, f->scope, st_local);//XXX param def->used = 1; i++; } } } function_t * new_function (const char *name) { function_t *f; ALLOC (1024, function_t, functions, f); *pr.func_tail = f; pr.func_tail = &f->next; f->function_num = pr.num_functions++; f->s_name = ReuseString (name); f->s_file = pr.source_file; if (options.code.debug) f->aux = new_auxfunction (); return f; } function_t * build_code_function (function_t *f, expr_t *state_expr, expr_t *statements) { build_function (f); if (state_expr) { state_expr->next = statements; emit_function (f, state_expr); } else { emit_function (f, statements); } finish_function (f); return f; } function_t * build_builtin_function (def_t *def, expr_t *bi_val) { function_t *f; if (def->type->type != ev_func) { error (bi_val, "%s is not a function", def->name); return 0; } if (def->constant) { error (bi_val, "%s redefined", def->name); return 0; } if (bi_val->type != ex_integer && bi_val->type != ex_float) { error (bi_val, "invalid constant for = #"); return 0; } f = new_function (def->name); f->builtin = bi_val->type == ex_integer ? bi_val->e.integer_val : (int)bi_val->e.float_val; f->def = def; reloc_def_func (f, def->ofs); build_function (f); finish_function (f); return f; } void build_function (function_t *f) { f->def->constant = 1; f->def->nosave = 1; f->def->initialized = 1; G_FUNCTION (f->def->ofs) = f->function_num; } void finish_function (function_t *f) { if (f->aux) { def_t *def; f->aux->function = f->function_num; if (f->scope) { for (def = f->scope->head; def; def = def->def_next) { if (def->name) { def_to_ddef (def, new_local (), 0); f->aux->num_locals++; } } } } } void emit_function (function_t *f, expr_t *e) { //printf (" %s =\n", f->def->name); if (f->aux) lineno_base = f->aux->source_line; while (f->var_init) { emit_expr (f->var_init); f->var_init = f->var_init->next; } current_scope = f->scope; while (e) { //printf ("%d ", pr.source_line); //print_expr (e); //puts(""); emit_expr (e); e = e->next; } emit_statement (0, op_done, 0, 0, 0); flush_scope (current_scope, 0); current_scope = pr.scope; reset_tempdefs (); //puts (""); } int function_parms (function_t *f, byte *parm_size) { int count, i; if (f->def->type->num_parms >= 0) count = f->def->type->num_parms; else count = -f->def->type->num_parms - 1; for (i = 0; i < count; i++) parm_size[i] = type_size (f->def->type->parm_types[i]); return f->def->type->num_parms; }