/* def.c def management and symbol tables Copyright (C) 2002 Bill Currie Copyright (C) 1996-1997 Id Software, Inc. Author: Bill Currie Date: 2002/06/09 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 #ifdef HAVE_STRING_H # include #endif #ifdef HAVE_STRINGS_H # include #endif #include #include "QF/alloc.h" #include "QF/hash.h" #include "QF/sys.h" #include "QF/va.h" #include "tools/qfcc/include/qfcc.h" #include "tools/qfcc/include/class.h" #include "tools/qfcc/include/def.h" #include "tools/qfcc/include/defspace.h" #include "tools/qfcc/include/diagnostic.h" #include "tools/qfcc/include/emit.h" #include "tools/qfcc/include/expr.h" #include "tools/qfcc/include/function.h" #include "tools/qfcc/include/options.h" #include "tools/qfcc/include/reloc.h" #include "tools/qfcc/include/shared.h" #include "tools/qfcc/include/strpool.h" #include "tools/qfcc/include/struct.h" #include "tools/qfcc/include/symtab.h" #include "tools/qfcc/include/type.h" #include "tools/qfcc/include/value.h" static def_t *defs_freelist; static void set_storage_bits (def_t *def, storage_class_t storage) { switch (storage) { case sc_system: def->system = 1; // fall through case sc_global: def->global = 1; def->external = 0; def->local = 0; def->param = 0; break; case sc_extern: def->global = 1; def->external = 1; def->local = 0; def->param = 0; break; case sc_static: def->external = 0; def->global = 0; def->local = 0; def->param = 0; break; case sc_local: def->external = 0; def->global = 0; def->local = 1; def->param = 0; break; case sc_param: def->external = 0; def->global = 0; def->local = 1; def->param = 1; break; } def->initialized = 0; } def_t * new_def (const char *name, type_t *type, defspace_t *space, storage_class_t storage) { def_t *def; ALLOC (16384, def_t, defs, def); def->return_addr = __builtin_return_address (0); def->name = name ? save_string (name) : 0; def->type = type; def->file = pr.source_file; def->line = pr.source_line; set_storage_bits (def, storage); if (space) { if (space->type == ds_virtual && storage == sc_static) internal_error (0, "static in a virtual space"); if (space->type != ds_virtual && (storage == sc_param || storage == sc_local)) internal_error (0, "param or local in a non-virtual space"); def->space = space; *space->def_tail = def; space->def_tail = &def->next; } if (!type) return def; if (!space && storage != sc_extern) internal_error (0, "non-external def with no storage space"); if (is_class (type) || (is_array (type) && is_class(type->t.array.type))) { error (0, "statically allocated instance of class %s", type->t.class->name); return def; } if (storage != sc_extern) { int size = type_size (type); int alignment = type->alignment; if (!size) { error (0, "%s has incomplete type", name); size = 1; alignment = 1; } if (alignment < 1) { print_type (type); internal_error (0, "type has no alignment"); } def->offset = defspace_alloc_aligned_loc (space, size, alignment); } return def; } def_t * alias_def (def_t *def, type_t *type, int offset) { def_t *alias; if (def->alias) { expr_t e; e.file = def->file; e.line = def->line; internal_error (&e, "aliasing an alias def"); } if (type_size (type) > type_size (def->type)) internal_error (0, "aliasing a def to a larger type"); if (offset < 0 || offset + type_size (type) > type_size (def->type)) internal_error (0, "invalid alias offset"); if (type == def->type) return def; for (alias = def->alias_defs; alias; alias = alias->next) { if (alias->type == type && alias->offset == offset) return alias; } ALLOC (16384, def_t, defs, alias); alias->name = save_string (va (0, "[%s:%d]", def->name, offset)); alias->return_addr = __builtin_return_address (0); alias->offset = offset; alias->offset_reloc = 1; alias->type = type; alias->alias = def; alias->line = pr.source_line; alias->file = pr.source_file; alias->next = def->alias_defs; def->alias_defs = alias; return alias; } def_t * temp_def (type_t *type) { def_t *temp; defspace_t *space = current_func->symtab->space; int size = type_size (type); int alignment = type->alignment; if (size < 1 || size > 4) { internal_error (0, "%d invalid size for temp def", size); } if (alignment < 1) { internal_error (0, "temp type has no alignment"); } if ((temp = current_func->temp_defs[size - 1])) { current_func->temp_defs[size - 1] = temp->temp_next; temp->temp_next = 0; } else { ALLOC (16384, def_t, defs, temp); temp->offset = defspace_alloc_aligned_loc (space, size, alignment); *space->def_tail = temp; space->def_tail = &temp->next; temp->name = save_string (va (0, ".tmp%d", current_func->temp_num++)); } temp->return_addr = __builtin_return_address (0); temp->type = type; temp->file = pr.source_file; temp->line = pr.source_line; set_storage_bits (temp, sc_local); temp->space = space; return temp; } void free_temp_def (def_t *temp) { int size = type_size (temp->type) - 1; temp->temp_next = current_func->temp_defs[size]; current_func->temp_defs[size] = temp; } void free_def (def_t *def) { if (!def->return_addr) internal_error (0, "double free of def"); if (def->alias) { def_t **a; // pull the alias out of the base def's list of alias defs to avoid // messing up the list when the alias def is freed. for (a = &def->alias->alias_defs; *a; a = &(*a)->next) { if (*a == def) { *a = def->next; break; } } } else if (def->space) { def_t **d; for (d = &def->space->defs; *d && *d != def; d = &(*d)->next) ; if (!*d) internal_error (0, "freeing unlinked def %s", def->name); *d = def->next; if (&def->next == def->space->def_tail) def->space->def_tail = d; if (!def->external) defspace_free_loc (def->space, def->offset, type_size (def->type)); } def->return_addr = 0; def->free_addr = __builtin_return_address (0); FREE (defs, def); } void def_to_ddef (def_t *def, ddef_t *ddef, int aux) { const type_t *type = unalias_type (def->type); if (aux) type = type->t.fldptr.type; // aux is true only for fields ddef->type = type->type; ddef->ofs = def->offset; ddef->s_name = ReuseString (def->name); } static int zero_memory (expr_t *local_expr, def_t *def, type_t *zero_type, int init_size, int init_offset) { int zero_size = type_size (zero_type); expr_t *zero = convert_nil (new_nil_expr (), zero_type); expr_t *dst; for (; init_offset < init_size + 1 - zero_size; init_offset += zero_size) { dst = new_def_expr (def); dst = new_offset_alias_expr (zero_type, dst, init_offset); append_expr (local_expr, assign_expr (dst, zero)); } return init_offset; } static void init_elements_nil (def_t *def) { if (def->local && local_expr) { // memset to 0 int init_size = type_size (def->type); int init_offset = 0; if (options.code.progsversion != PROG_ID_VERSION) { init_offset = zero_memory (local_expr, def, &type_zero, init_size, init_offset); } // probably won't happen any time soon, but who knows... if (options.code.progsversion != PROG_ID_VERSION && init_size - init_offset >= type_size (&type_quaternion)) { init_offset = zero_memory (local_expr, def, &type_quaternion, init_size, init_offset); } if (init_size - init_offset >= type_size (&type_vector)) { init_offset = zero_memory (local_expr, def, &type_vector, init_size, init_offset); } if (options.code.progsversion != PROG_ID_VERSION && init_size - init_offset >= type_size (&type_double)) { init_offset = zero_memory (local_expr, def, &type_double, init_size, init_offset); } if (init_size - init_offset >= type_size (type_default)) { zero_memory (local_expr, def, type_default, init_size, init_offset); } } // it's a global, so already initialized to 0 } static void init_elements (struct def_s *def, expr_t *eles) { expr_t *c; pr_type_t *g; element_chain_t element_chain; element_t *element; if (eles->type == ex_nil) { init_elements_nil (def); return; } element_chain.head = 0; element_chain.tail = &element_chain.head; build_element_chain (&element_chain, def->type, eles, 0); if (def->local && local_expr) { expr_t *dst = new_def_expr (def); assign_elements (local_expr, dst, &element_chain); } else { def_t dummy = *def; for (element = element_chain.head; element; element = element->next) { if (!element->expr || ((c = constant_expr (element->expr))->type == ex_nil)) { // nil is type agnostic 0 and defspaces are initialized to // 0 on creation continue; } if (c->type == ex_nil) { c = convert_nil (c, element->type); } dummy.offset = def->offset + element->offset; g = D_POINTER (pr_type_t, &dummy); if (c->type == ex_labelref) { // reloc_def_* use only the def's offset and space, so dummy // is ok reloc_def_op (c->e.labelref.label, &dummy); continue; } else if (c->type == ex_value) { if (c->e.value->lltype == ev_integer && is_float (element->type)) { convert_int (c); } if (is_double (get_type (c)) && is_float (element->type) && c->implicit) { convert_double (c); } if (get_type (c) != element->type) { error (c, "type mismatch in initializer"); continue; } } else { if (!def->local || !local_expr) { error (c, "non-constant initializer"); continue; } } if (c->type != ex_value) { internal_error (c, "bogus expression type in init_elements()"); } if (c->e.value->lltype == ev_string) { EMIT_STRING (def->space, g->string_var, c->e.value->v.string_val); } else { memcpy (g, &c->e.value->v, type_size (get_type (c)) * 4); } } } free_element_chain (&element_chain); } static void init_vector_components (symbol_t *vector_sym, int is_field) { expr_t *vector_expr; int i; static const char *fields[] = { "x", "y", "z" }; vector_expr = new_symbol_expr (vector_sym); for (i = 0; i < 3; i++) { expr_t *expr = 0; symbol_t *sym; const char *name; name = va (0, "%s_%s", vector_sym->name, fields[i]); sym = symtab_lookup (current_symtab, name); if (sym) { if (sym->table == current_symtab) { if (sym->sy_type != sy_expr) { error (0, "%s redefined", name); sym = 0; } else { expr = sym->s.expr; if (is_field) { if (expr->type != ex_value || expr->e.value->lltype != ev_field) { error (0, "%s redefined", name); sym = 0; } else { expr->e.value->v.pointer.def = vector_sym->s.def; expr->e.value->v.pointer.val = i; } } } } else { sym = 0; } } if (!sym) sym = new_symbol (name); if (!expr) { if (is_field) { expr = new_field_expr (i, &type_float, vector_sym->s.def); } else { expr = field_expr (vector_expr, new_symbol_expr (new_symbol (fields[i]))); } } sym->sy_type = sy_expr; sym->s.expr = expr; if (!sym->table) symtab_addsymbol (current_symtab, sym); } } static void init_field_def (def_t *def, expr_t *init, storage_class_t storage) { type_t *type = (type_t *) dereference_type (def->type);//FIXME cast def_t *field_def; symbol_t *field_sym; reloc_t *relocs = 0; if (!init) { field_sym = symtab_lookup (pr.entity_fields, def->name); if (!field_sym) field_sym = new_symbol_type (def->name, type); if (field_sym->s.def && field_sym->s.def->external) { //FIXME this really is not the right way relocs = field_sym->s.def->relocs; free_def (field_sym->s.def); field_sym->s.def = 0; } if (!field_sym->s.def) { field_sym->s.def = new_def (def->name, type, pr.entity_data, storage); reloc_attach_relocs (relocs, &field_sym->s.def->relocs); field_sym->s.def->nosave = 1; } field_def = field_sym->s.def; if (!field_sym->table) symtab_addsymbol (pr.entity_fields, field_sym); if (storage != sc_extern) { D_INT (def) = field_def->offset; reloc_def_field (field_def, def); def->constant = 1; def->nosave = 1; } // no support for initialized field vector componets (yet?) if (is_vector(type) && options.code.vector_components) init_vector_components (field_sym, 1); } else if (init->type == ex_symbol) { symbol_t *sym = init->e.symbol; symbol_t *field = symtab_lookup (pr.entity_fields, sym->name); if (field) { expr_t *new = new_field_expr (0, field->type, field->s.def); init->type = new->type; init->e = new->e; } } } static int num_elements (expr_t *e) { int count = 0; for (e = e->e.block.head; e; e = e->next) { count++; } return count; } void initialize_def (symbol_t *sym, expr_t *init, defspace_t *space, storage_class_t storage) { symbol_t *check = symtab_lookup (current_symtab, sym->name); reloc_t *relocs = 0; if (check && check->table == current_symtab) { if (check->sy_type != sy_var || !type_same (check->type, sym->type)) { error (0, "%s redefined", sym->name); } else { // is var and same type if (!check->s.def) internal_error (0, "half defined var"); if (storage == sc_extern) { if (init) error (0, "initializing external variable"); return; } if (init && check->s.def->initialized) { error (0, "%s redefined", sym->name); return; } sym = check; } } sym->sy_type = sy_var; if (!sym->table) symtab_addsymbol (current_symtab, sym); if (sym->s.def && sym->s.def->external) { //FIXME this really is not the right way relocs = sym->s.def->relocs; free_def (sym->s.def); sym->s.def = 0; } if (!sym->s.def) { if (is_array (sym->type) && !type_size (sym->type) && init && init->type == ex_compound) { sym->type = array_type (sym->type->t.array.type, num_elements (init)); } sym->s.def = new_def (sym->name, sym->type, space, storage); reloc_attach_relocs (relocs, &sym->s.def->relocs); } if (is_vector(sym->type) && options.code.vector_components) init_vector_components (sym, 0); if (sym->type->type == ev_field && storage != sc_local && storage != sc_param) init_field_def (sym->s.def, init, storage); if (storage == sc_extern) { if (init) error (0, "initializing external variable"); return; } if (!init) return; convert_name (init); if (init->type == ex_error) return; if ((is_array (sym->type) || is_struct (sym->type) || is_vector(sym->type) || is_quaternion(sym->type)) && ((init->type == ex_compound) || init->type == ex_nil)) { init_elements (sym->s.def, init); sym->s.def->initialized = 1; } else { type_t *init_type; if (init->type == ex_nil) { convert_nil (init, sym->type); } init_type = get_type (init); if (!type_assignable (sym->type, init_type)) { error (init, "type mismatch in initializer"); return; } if (storage == sc_local && local_expr) { sym->s.def->initialized = 1; init = assign_expr (new_symbol_expr (sym), init); // fold_constants takes care of int/float conversions append_expr (local_expr, fold_constants (init)); } else { int offset = 0; if (!is_constant (init)) { error (init, "non-constant initializier"); return; } while ((init->type == ex_uexpr || init->type == ex_expr) && init->e.expr.op == 'A') { if (init->type == ex_expr) { offset += expr_integer (init->e.expr.e2); } init = init->e.expr.e1; } if (init->type != ex_value) { //FIXME enum etc internal_error (0, "initializier not a value"); return; } if (init->e.value->lltype == ev_pointer || init->e.value->lltype == ev_field) { // FIXME offset pointers D_INT (sym->s.def) = init->e.value->v.pointer.val; if (init->e.value->v.pointer.def) reloc_def_field (init->e.value->v.pointer.def, sym->s.def); } else { ex_value_t *v = init->e.value; if (!init->implicit && is_double (init_type) && (is_integral (sym->type) || is_float (sym->type))) { warning (init, "assigning double to %s in initializer " "(use a cast)", sym->type->name); } if (is_scalar (sym->type)) v = convert_value (v, sym->type); if (v->lltype == ev_string) { EMIT_STRING (sym->s.def->space, D_STRING (sym->s.def), v->v.string_val); } else { memcpy (D_POINTER (void, sym->s.def), &v->v, type_size (sym->type) * sizeof (pr_type_t)); } } sym->s.def->initialized = 1; if (options.code.const_initializers) { sym->s.def->constant = 1; sym->s.def->nosave = 1; } } } sym->s.def->initializer = init; } int def_overlap (def_t *d1, def_t *d2) { int offs1, size1; int offs2, size2; defspace_t *s1 = d1->space; defspace_t *s2 = d2->space; if (d1->alias) s1 = d1->alias->space; if (d2->alias) s2 = d2->alias->space; /// Defs in different spaces never overlap. if (s1 != s2) return 0; offs1 = d1->offset; if (d1->alias) offs1 += d1->alias->offset; size1 = type_size (d1->type); offs2 = d2->offset; if (d2->alias) offs2 += d2->alias->offset; size2 = type_size (d2->type); if (offs1 <= offs2 && offs1 + size1 >= offs2 + size2) return 2; // d1 fully overlaps d2 if (offs1 < offs2 + size2 && offs2 < offs1 + size1) return 1; // d1 and d2 at least partially overlap return 0; } int def_offset (def_t *def) { int offset = def->offset; if (def->alias) offset += def->alias->offset; return offset; } int def_size (def_t *def) { return type_size (def->type); } int def_visit_all (def_t *def, int overlap, int (*visit) (def_t *, void *), void *data) { def_t *start_def = def; int ret; if ((ret = visit (def, data))) return ret; if (def->alias) { def = def->alias; if ((ret = visit (def, data))) return ret; } else { overlap = 0; } for (def = def->alias_defs; def; def = def->next) { if (def == start_def) continue; if (overlap && def_overlap (def, start_def) < overlap) continue; if ((ret = visit (def, data))) return ret; } return 0; }