/* class.c QC class 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/pr_obj.h" #include "QF/va.h" #include "qfcc.h" #include "codespace.h" #include "class.h" #include "def.h" #include "defspace.h" #include "diagnostic.h" #include "emit.h" #include "expr.h" #include "immediate.h" #include "method.h" #include "options.h" #include "reloc.h" #include "strpool.h" #include "struct.h" #include "symtab.h" #include "type.h" static hashtab_t *class_hash; static hashtab_t *category_hash; static hashtab_t *protocol_hash; // these will be built up further type_t type_SEL = { ev_pointer, "SEL" }; type_t type_IMP = { ev_func, "IMP", ty_none, {{&type_id, -3, {&type_id, &type_SEL}}}}; type_t type_supermsg = { ev_func, ".supermsg", ty_none, {{&type_id, -3, {0, &type_SEL}}}}; type_t type_obj_exec_class = { ev_func, "function", ty_none, {{&type_void, 1, { 0 }}}}; type_t type_Method = { ev_invalid, "Method" }; type_t type_Super = { ev_invalid, "Super" }; type_t type_method_description = { ev_invalid, "obj_method_description", ty_struct }; type_t type_category; type_t type_ivar; type_t type_module; type_t type_object = {ev_invalid, "object", ty_class}; type_t type_id = { ev_pointer, "id", ty_none, {{&type_object}}}; type_t type_Class = { ev_invalid, "Class", ty_class}; type_t type_ClassPtr = { ev_pointer, 0, ty_none, {{&type_Class}}}; type_t type_Protocol = { ev_invalid, "Protocol", ty_class}; class_t class_object = {1, "id"}; class_t class_Class = {1, "Class"}; class_t class_Protocol = {1, "Protocol"}; static struct_def_t sel_struct[] = { {"sel_id", &type_string}, {"sel_types", &type_string}, {0, 0} }; static struct_def_t method_struct[] = { {"method_name", &type_SEL}, {"method_types", &type_string}, {"method_imp", &type_IMP}, {0, 0} }; static struct_def_t method_desc_struct[] = { {"name", &type_string}, {"types", &type_string}, {0, 0} }; static struct_def_t category_struct[] = { {"category_name", &type_string}, {"class_name", &type_string}, {"instance_methods", &type_pointer}, {"class_methods", &type_pointer}, {"protocols", &type_pointer}, {0, 0} }; static struct_def_t ivar_struct[] = { {"ivar_name", &type_string}, {"ivar_type", &type_string}, {"ivar_offset", &type_integer}, {0, 0} }; static struct_def_t super_struct[] = { {"self", &type_id}, {"class", &type_Class}, {0, 0} }; static struct_def_t module_struct[] = { {"version", &type_integer}, {"size", &type_integer}, {"name", &type_string}, {"symtab", &type_pointer}, {0, 0} }; static struct_def_t class_ivars[] = { {"class_pointer", &type_Class}, {"super_class", &type_Class}, {"name", &type_string}, {"version", &type_integer}, {"info", &type_integer}, {"instance_size", &type_integer}, {"ivars", &type_pointer}, {"methods", &type_pointer}, {"dtable", &type_pointer}, {"subclass_list", &type_pointer}, {"sibling_class", &type_pointer}, {"protocols", &type_pointer}, {"gc_object_type", &type_pointer}, }; static struct_def_t protocol_ivars[] = { {"class_pointer", &type_Class}, {"protocol_name", &type_string}, {"protocol_list", &type_pointer}, {"instance_methods", &type_pointer}, {"class_methods", &type_pointer}, {0, 0} }; static struct_def_t object_ivars[] = { {"class_pointer", &type_Class}, {0, 0} }; static const char * class_get_key (void *class, void *unused) { return ((class_t *) class)->name; } static const char * protocol_get_key (void *protocol, void *unused) { return ((protocol_t *) protocol)->name; } const char * get_class_name (class_type_t *class_type, int pretty) { switch (class_type->type) { case ct_class: if (pretty) return class_type->c.class->name; else return va ("%s_", class_type->c.class->name); case ct_category: if (pretty) return va ("%s (%s)", class_type->c.category->class->name, class_type->c.category->name); else return va ("%s_%s", class_type->c.category->class->name, class_type->c.category->name); case ct_protocol: return va ("<%s>", class_type->c.protocol->name); } return "???"; } static void init_objective_structs (void) { type_SEL.t.fldptr.type = make_structure (0, 's', sel_struct, 0)->type; chain_type (&type_SEL); chain_type (&type_IMP); make_structure (0, 's', method_struct, &type_Method); chain_type (&type_Method); make_structure (0, 's', method_desc_struct, &type_method_description); chain_type (&type_method_description); make_structure (0, 's', category_struct, &type_category); chain_type (&type_category); make_structure (0, 's', ivar_struct, &type_ivar); chain_type (&type_ivar); make_structure (0, 's', super_struct, &type_Super); chain_type (&type_Super); make_structure ("obj_module_s", 's', module_struct, &type_module); chain_type (&type_module); type_supermsg.t.func.param_types[0] = pointer_type (&type_Super); chain_type (&type_supermsg); type_obj_exec_class.t.func.param_types[0] = pointer_type (&type_module); chain_type (&type_obj_exec_class); } static void init_classes (void) { symbol_t *sym; type_Class.ty = ty_class; type_Class.t.class = &class_Class; chain_type (&type_Class); sym = make_structure (0, 's', class_ivars, 0); class_Class.ivars = sym->type->t.symtab; class_Class.type = &type_Class; class_Class.super_class = get_class (sym = new_symbol ("Object"), 1); class_Class.methods = new_methodlist (); symtab_addsymbol (pr.symtab, sym); chain_type (&type_ClassPtr); type_Protocol.ty = ty_class; type_Protocol.t.class = &class_Protocol; chain_type (&type_Protocol); sym = make_structure (0, 's', protocol_ivars, &type_Protocol); class_Protocol.ivars = sym->type->t.symtab; class_Protocol.type = &type_Protocol; type_object.t.class = &class_object; chain_type (&type_object); sym = make_structure (0, 's', object_ivars, 0); class_object.ivars = sym->type->t.symtab; class_object.type = &type_id; chain_type (&type_id); } void class_init (void) { symbol_t *sym; init_classes (); init_objective_structs (); sym = new_symbol_type ("obj_module_t", &type_module); sym->sy_type = sy_type; symtab_addsymbol (pr.symtab, sym); } symbol_t * class_symbol (class_type_t *class_type, int external) { const char *name = 0; type_t *type = 0; switch (class_type->type) { case ct_category: name = va ("_OBJ_CATEGORY_%s_%s", class_type->c.category->class->name, class_type->c.category->name); type = &type_category; break; case ct_class: name = va ("_OBJ_CLASS_%s", class_type->c.class->name); type = &type_Class; break; case ct_protocol: return 0; // probably in error recovery } return make_symbol (name, type, pr.far_data, external ? st_extern : st_global); } class_t * get_class (symbol_t *sym, int create) { class_t *c; type_t new; if (!class_hash) class_hash = Hash_NewTable (1021, class_get_key, 0, 0); if (sym) { c = Hash_Find (class_hash, sym->name); if (c || !create) return c; } c = calloc (sizeof (class_t), 1); if (sym) c->name = sym->name; new = type_Class; new.t.class = c; c->type = find_type (&new); c->methods = new_methodlist (); c->class_type.type = ct_class; c->class_type.c.class = c; if (sym) { Hash_Add (class_hash, c); sym->type = c->type; } return c; } static void set_self_type (class_t *class, method_t *method) { if (method->instance) method->params->type = pointer_type (class->type); else method->params->type = &type_ClassPtr; } static void methods_set_self_type (class_t *class, methodlist_t *methods) { method_t *method; for (method = methods->head; method; method = method->next) set_self_type (class, method); } void class_add_methods (class_t *class, methodlist_t *methods) { if (!methods) return; *class->methods->tail = methods->head; class->methods->tail = methods->tail; free (methods); methods_set_self_type (class, class->methods); } void class_add_protocols (class_t *class, protocollist_t *protocols) { int i; protocol_t *p; methodlist_t *methods; if (!protocols) return; methods = class->methods; for (i = 0; i < protocols->count; i++) { p = protocols->list[i]; copy_methods (methods, p->methods); if (p->protocols) class_add_protocols (class, p->protocols); } class->protocols = protocols; } static void begin_category (category_t *category) { pr_category_t *pr_category; class_t *class = category->class; symbol_t *sym; def_t *def; defspace_t *space; current_class = &category->class_type; sym = class_symbol (current_class, 0); category->def = def = sym->s.def; def->initialized = def->constant = def->nosave = 1; space = def->space; pr_category = &D_STRUCT (pr_category_t, def); EMIT_STRING (space, pr_category->category_name, category->name); EMIT_STRING (space, pr_category->class_name, class->name); EMIT_DEF (space, pr_category->protocols, emit_protocol_list (category->protocols, va ("%s_%s", class->name, category->name))); } typedef struct { int count; symbol_t *ivars; dstring_t *encoding; } ivar_data_t; static void emit_ivar_count (def_t *def, void *data, int index) { ivar_data_t *ivar_data = (ivar_data_t *) data; if (def->type != &type_integer) internal_error (0, "%s: expected integer def", __FUNCTION__); D_INT (def) = ivar_data->count; } static void emit_ivar_list_item (def_t *def, void *data, int index) { ivar_data_t *ivar_data = (ivar_data_t *) data; symbol_t *ivar_sym; pr_ivar_t *ivar; defspace_t *space; #if 0 //FIXME the type is dynamic, so need a way to pass it before it cn be //checked if (def->type != &XXX) internal_error (0, "%s: expected XXX def", __FUNCTION__); #endif if (index < 0 || index >= ivar_data->count) internal_error (0, "%s: out of bounds index: %d %d", __FUNCTION__, index, ivar_data->count); for (ivar_sym = ivar_data->ivars; ivar_sym; ivar_sym = ivar_sym->next) { if (ivar_sym->sy_type != sy_var) continue; if (!index--) break; } ivar = D_POINTER (pr_ivar_t, def); space = def->space; dstring_clearstr (ivar_data->encoding); EMIT_STRING (space, ivar->ivar_name, ivar_sym->name); encode_type (ivar_data->encoding, ivar_sym->type); EMIT_STRING (space, ivar->ivar_type, ivar_data->encoding->str); ivar->ivar_offset = ivar_sym->s.offset; } static def_t * emit_ivars (symtab_t *ivars, const char *name) { static struct_def_t ivar_list_struct[] = { {"ivar_count", &type_integer, emit_ivar_count}, {"ivar_list", 0, emit_ivar_list_item}, {0, 0} }; ivar_data_t ivar_data = {0, 0}; symbol_t *s; def_t *def; ivar_data.encoding = dstring_newstr (); ivar_data.ivars = ivars->symbols; for (s = ivars->symbols; s; s = s->next) if (s->sy_type == sy_var) ivar_data.count++; ivar_list_struct[1].type = array_type (&type_ivar, ivar_data.count); def = emit_structure (va ("_OBJ_INSTANCE_VARIABLES_%s", name), 's', ivar_list_struct, 0, &ivar_data, st_static); dstring_delete (ivar_data.encoding); return def; } static void begin_class (class_t *class) { def_t *meta_def; pr_class_t *meta; pr_class_t *pr_class; symbol_t *sym; def_t *def; defspace_t *space; sym = make_symbol (va ("_OBJ_METACLASS_%s", class->name), &type_Class, pr.far_data, st_static); meta_def = sym->s.def; meta_def->initialized = meta_def->constant = meta_def->nosave = 1; space = meta_def->space; meta = &D_STRUCT (pr_class_t, meta_def); EMIT_STRING (space, meta->class_pointer, class->name); if (class->super_class) EMIT_STRING (space, meta->super_class, class->super_class->name); EMIT_STRING (space, meta->name, class->name); meta->info = _PR_CLS_META; meta->instance_size = type_size (&type_Class); EMIT_DEF (space, meta->ivars, emit_ivars (class_Class.ivars, "Class")); current_class = &class->class_type; sym = class_symbol (current_class, 0); class->def = def = sym->s.def; def->initialized = def->constant = def->nosave = 1; space = def->space; pr_class = &D_STRUCT (pr_class_t, def); EMIT_DEF (space, pr_class->class_pointer, meta_def); if (class->super_class) { class_type_t class_type = {ct_class, {0}}; class_type.c.class = class->super_class; EMIT_STRING (space, pr_class->super_class, class->super_class->name); class_symbol (&class_type, 1); } EMIT_STRING (space, pr_class->name, class->name); pr_class->info = _PR_CLS_CLASS; EMIT_DEF (space, pr_class->protocols, emit_protocol_list (class->protocols, class->name)); } void class_begin (class_type_t *class_type) { switch (class_type->type) { case ct_category: begin_category (class_type->c.category); break; case ct_class: begin_class (class_type->c.class); break; case ct_protocol: return; // probably error recovery } } void emit_class_ref (const char *class_name) { def_t *def; def_t *ref; def = make_symbol (va (".obj_class_ref_%s", class_name), &type_pointer, pr.far_data, st_static)->s.def; if (def->initialized) return; def->initialized = def->constant = def->nosave = 1; ref = make_symbol (va (".obj_class_name_%s", class_name), &type_pointer, pr.far_data, st_extern)->s.def; if (!ref->external) D_INT (def) = ref->offset; reloc_def_def (ref, def->offset); } static void emit_class_name (const char *class_name) { def_t *def; def = make_symbol (va (".obj_class_name_%s", class_name), &type_pointer, pr.far_data, st_global)->s.def; if (def->initialized) return; def->initialized = def->constant = 1; def->nosave = 1; D_INT (def) = 0; } void emit_category_ref (const char *class_name, const char *category_name) { def_t *def; def_t *ref; def = make_symbol (va (".obj_category_ref_%s_%s", class_name, category_name), &type_pointer, pr.far_data, st_static)->s.def; if (def->initialized) return; def->initialized = def->constant = 1; def->nosave = 1; ref = make_symbol (va (".obj_category_name_%s_%s", class_name, category_name), &type_pointer, pr.far_data, st_extern)->s.def; if (!ref->external) D_INT (def) = ref->offset; reloc_def_def (ref, def->offset); } static void emit_category_name (const char *class_name, const char *category_name) { def_t *def; def = make_symbol (va (".obj_category_name_%s_%s", class_name, category_name), &type_pointer, pr.far_data, st_global)->s.def; if (def->initialized) return; def->initialized = def->constant = 1; def->nosave = 1; D_INT (def) = 0; } static void finish_category (category_t *category) { pr_category_t *pr_category; class_t *class = category->class; char *name; defspace_t *space; if (!category->def) // probably in error recovery return; name = nva ("%s_%s", class->name, category->name); pr_category = &D_STRUCT (pr_category_t, category->def); space = category->def->space; EMIT_DEF (space, pr_category->instance_methods, emit_methods (category->methods, name, 1)); EMIT_DEF (space, pr_category->class_methods, emit_methods (category->methods, name, 0)); free (name); emit_class_ref (class->name); emit_category_name (class->name, category->name); } static void finish_class (class_t *class) { pr_class_t *meta; pr_class_t *cls; defspace_t *space; if (!class->def) // probably in error recovery return; space = class->def->space; cls = &D_STRUCT (pr_class_t, class->def); meta = &G_STRUCT (space, pr_class_t, cls->class_pointer); EMIT_DEF (space, meta->methods, emit_methods (class->methods, class->name, 0)); cls->instance_size = class->ivars ? class->ivars->size : 0; EMIT_DEF (space, cls->ivars, emit_ivars (class->ivars, class->name)); EMIT_DEF (space, cls->methods, emit_methods (class->methods, class->name, 1)); if (class->super_class) emit_class_ref (class->super_class->name); emit_class_name (class->name); } void class_finish (class_type_t *class_type) { switch (class_type->type) { case ct_category: finish_category (class_type->c.category); break; case ct_class: finish_class (class_type->c.class); break; case ct_protocol: return; // probably in error recovery } } class_t * extract_class (class_type_t *class_type) { switch (class_type->type) { case ct_class: return current_class->c.class; case ct_category: return current_class->c.category->class; case ct_protocol: return 0; // probably in error recovery } return 0; // should not happen } int class_access (class_type_t *class_type, class_t *class) { class_t *cur; if (class_type) { if (!(cur = extract_class (class_type))) return vis_private; if (cur == class) return vis_private; cur = cur->super_class; while (cur) { if (cur == class) return vis_protected; cur = cur->super_class; } } return vis_public; } symbol_t * class_find_ivar (class_t *class, int vis, const char *name) { symbol_t *ivar; ivar = symtab_lookup (class->ivars, name); if (ivar) { if (ivar->visibility > (vis_e) vis) goto access_error; return ivar; } error (0, "%s.%s does not exist", class->name, name); return 0; access_error: error (0, "%s.%s is not accessable here", class->name, name); return 0; } method_t * class_find_method (class_type_t *class_type, method_t *method) { methodlist_t *methods = 0, *start_methods; method_t *m; dstring_t *sel; class_t *class = 0, *start_class; const char *class_name; const char *category_name = 0; switch (class_type->type) { case ct_category: methods = class_type->c.category->methods; category_name = class_type->c.category->name; class = class_type->c.category->class; break; case ct_class: class = class_type->c.class; methods = class->methods; break; case ct_protocol: return 0; // probably in error recovery } class_name = class->name; start_methods = methods; start_class = class; while (class) { for (m = methods->head; m; m = m->next) if (method_compare (method, m)) { if (m->type != method->type) error (0, "method type mismatch"); if (methods != start_methods) { m = copy_method (m); set_self_type (start_class, m); add_method (start_methods, m); } method_set_param_names (m, method); return m; } if (class->methods == methods) class = class->super_class; else methods = class->methods; } sel = dstring_newstr (); selector_name (sel, (keywordarg_t *)method->selector); set_self_type (start_class, method); add_method (start_methods, method); dstring_delete (sel); return method; } method_t * class_message_response (class_t *class, int class_msg, expr_t *sel) { selector_t *selector; method_t *m; class_t *c = class; category_t *cat; if (sel->type != ex_value && sel->e.value.type != ev_pointer && sel->e.value.v.pointer.type != type_SEL.t.fldptr.type) { error (sel, "not a selector"); return 0; } selector = get_selector (sel); if (class->type == &type_id) { m = find_method (selector->name); if (m) return m; //FIXME right option? if (options.warnings.interface_check) warning (sel, "could not find method for %c%s", class_msg ? '+' : '-', selector->name); return 0; } else { while (c) { for (cat = c->categories; cat; cat = cat->next) { for (m = cat->methods->head; m; m = m->next) { if (((!c->super_class && class_msg) || class_msg != m->instance) && strcmp (selector->name, m->name) == 0) return m; } } for (m = c->methods->head; m; m = m->next) { if (((!c->super_class && class_msg) || class_msg != m->instance) && strcmp (selector->name, m->name) == 0) return m; } c = c->super_class; } //FIXME right option? if (options.warnings.interface_check) warning (sel, "%s may not respond to %c%s", class->name, class_msg ? '+' : '-', selector->name); } return 0; } static uintptr_t category_get_hash (void *_c, void *unused) { category_t *c = (category_t *) _c; return Hash_String (c->name) ^ Hash_String (c->class->name); } static int category_compare (void *_c1, void *_c2, void *unused) { category_t *c1 = (category_t *) _c1; category_t *c2 = (category_t *) _c2; return strcmp (c1->name, c2->name) == 0 && strcmp (c1->class->name, c2->class->name) == 0; } symtab_t * class_new_ivars (class_t *class) { symtab_t *ivars; symtab_t *super_ivars = 0; if (class->super_class) super_ivars = class->super_class->ivars; ivars = new_symtab (super_ivars, stab_local); return ivars; } void class_add_ivars (class_t *class, symtab_t *ivars) { class->ivars = ivars; } void class_check_ivars (class_t *class, symtab_t *ivars) { symbol_t *civ, *iv; if (!class->ivars != !ivars) goto missmatch; if (ivars) { for (civ = class->ivars->symbols, iv = ivars->symbols; civ && iv; civ = civ->next, iv = iv->next) { if (memcmp (civ, iv, sizeof (*civ))) //FIXME does this work? goto missmatch; } } class->ivars = ivars; return; missmatch: //FIXME right option? if (options.warnings.interface_check) warning (0, "instance variable missmatch for %s", class->name); class->ivars = ivars; } category_t * get_category (symbol_t *class_name, const char *category_name, int create) { category_t *category; class_t *class; if (!category_hash) { category_hash = Hash_NewTable (1021, 0, 0, 0); Hash_SetHashCompare (category_hash, category_get_hash, category_compare); } class = get_class (class_name, 0); if (!class) { error (0, "undefined class %s", class_name->name); return 0; } if (class_name && category_name) { category_t _c = {0, category_name, class}; category = Hash_FindElement (category_hash, &_c); if (category || !create) return category; } category = calloc (sizeof (category_t), 1); category->next = class->categories; class->categories = category; category->name = category_name; category->class = class; category->methods = new_methodlist (); category->class_type.type = ct_category; category->class_type.c.category = category; if (class_name && category_name) Hash_AddElement (category_hash, category); return category; } void category_add_methods (category_t *category, methodlist_t *methods) { if (!methods) return; *category->methods->tail = methods->head; category->methods->tail = methods->tail; free (methods); methods_set_self_type (category->class, category->methods); } void category_add_protocols (category_t *category, protocollist_t *protocols) { int i; protocol_t *p; methodlist_t *methods; if (!protocols) return; methods = category->methods; for (i = 0; i < protocols->count; i++) { p = protocols->list[i]; copy_methods (methods, p->methods); if (p->protocols) category_add_protocols (category, p->protocols); } category->protocols = protocols; } symbol_t * class_pointer_symbol (class_t *class) { def_t *def; symbol_t *sym; class_type_t class_type = {ct_class, {0}}; class_type.c.class = class; sym = make_symbol (va ("_OBJ_CLASS_POINTER_%s", class->name), pointer_type (class->type), pr.far_data, st_static); if (!sym->table) symtab_addsymbol (pr.symtab, sym); def = sym->s.def; if (def->initialized) return sym; def->initialized = def->constant = 1; def->nosave = 1; if (!class->def) class->def = class_symbol (&class_type, 1)->s.def; if (!class->def->external) D_INT (def) = class->def->offset; reloc_def_def (class->def, def->offset); return sym; } typedef struct { def_t *refs; class_t **classes; int cls_def_cnt; category_t **categories; int cat_def_cnt; } obj_symtab_data_t; static void emit_symtab_ref_cnt (def_t *def, void *data, int index) { obj_symtab_data_t *da = (obj_symtab_data_t *)data; if (def->type != &type_integer) internal_error (0, "%s: expected integer def", __FUNCTION__); D_INT (def) = da->refs->type->t.array.size; } static void emit_symtab_refs (def_t *def, void *data, int index) { obj_symtab_data_t *da = (obj_symtab_data_t *)data; if (def->type != &type_SEL) internal_error (0, "%s: expected SEL def", __FUNCTION__); EMIT_DEF (def->space, def->offset, da->refs); } static void emit_symtab_cls_def_cnt (def_t *def, void *data, int index) { obj_symtab_data_t *da = (obj_symtab_data_t *)data; if (def->type != &type_integer) internal_error (0, "%s: expected integer def", __FUNCTION__); D_INT (def) = da->cls_def_cnt; } static void emit_symtab_cat_def_cnt (def_t *def, void *data, int index) { obj_symtab_data_t *da = (obj_symtab_data_t *)data; if (def->type != &type_integer) internal_error (0, "%s: expected integer def", __FUNCTION__); D_INT (def) = da->cat_def_cnt; } static void emit_symtab_defs (def_t *def, void *data, int index) { obj_symtab_data_t *da = (obj_symtab_data_t *)data; if (def->type != &type_pointer) internal_error (0, "%s: expected pointer def", __FUNCTION__); if (index < 0 || index >= da->cls_def_cnt + da->cat_def_cnt) internal_error (0, "%s: out of bounds index: %d %d", __FUNCTION__, index, da->cls_def_cnt + da->cat_def_cnt); if (index < da->cls_def_cnt) { class_t *cl = da->classes[index]; EMIT_DEF (def->space, def->offset, cl->def); } else { category_t *ca = da->categories[index - da->cls_def_cnt]; EMIT_DEF (def->space, def->offset, ca->def); } } void class_finish_module (void) { static struct_def_t symtab_struct[] = { {"sel_ref_cnt", &type_integer, emit_symtab_ref_cnt}, {"refs", &type_SEL, emit_symtab_refs}, {"cls_def_cnt", &type_integer, emit_symtab_cls_def_cnt}, {"cat_def_cnt", &type_integer, emit_symtab_cat_def_cnt}, {"defs", 0, emit_symtab_defs}, {0, 0} }; obj_symtab_data_t data = {0, 0, 0, 0, 0}; class_t **cl; category_t **ca; def_t *symtab_def; symbol_t *module_sym; pr_module_t *module; symbol_t *exec_class_sym; symbol_t *init_sym; function_t *init_func; expr_t *init_expr; data.refs = emit_selectors (); if (class_hash) { data.classes = (class_t **) Hash_GetList (class_hash); for (cl = data.classes; *cl; cl++) if ((*cl)->def && !(*cl)->def->external) data.cls_def_cnt++; } if (category_hash) { data.categories = (category_t **) Hash_GetList (category_hash); for (ca = data.categories; *ca; ca++) if ((*ca)->def && !(*ca)->def->external) data.cat_def_cnt++; } if (!data.refs && !data.cls_def_cnt && !data.cat_def_cnt) return; symtab_struct[4].type = array_type (&type_pointer, data.cls_def_cnt + data.cat_def_cnt); symtab_def = emit_structure ("_OBJ_SYMTAB", 's', symtab_struct, 0, &data, st_static); module_sym = make_symbol ("_OBJ_MODULE", &type_module, pr.near_data, st_static); module = &D_STRUCT (pr_module_t, module_sym->s.def); module->size = type_size (&type_module); EMIT_STRING (module_sym->s.def->space, module->name, GETSTR (pr.source_file)); EMIT_DEF (module_sym->s.def->space, module->symtab, symtab_def); exec_class_sym = new_symbol_type ("__obj_exec_class", &type_obj_exec_class); symtab_addsymbol (current_symtab, exec_class_sym); init_sym = new_symbol_type (".ctor", &type_function); symtab_addsymbol (current_symtab, init_sym); init_expr = new_block_expr (); append_expr (init_expr, build_function_call (new_symbol_expr (exec_class_sym), exec_class_sym->type, address_expr (new_symbol_expr (module_sym), 0, 0))); current_func = init_func = begin_function (init_sym, 0, current_symtab); build_code_function (init_sym, 0, init_expr);; current_func = 0; } protocol_t * get_protocol (const char *name, int create) { protocol_t *p; if (!protocol_hash) protocol_hash = Hash_NewTable (1021, protocol_get_key, 0, 0); if (name) { p = Hash_Find (protocol_hash, name); if (p || !create) return p; } p = calloc (sizeof (protocol_t), 1); p->name = name; p->methods = new_methodlist (); p->class_type.type = ct_protocol; p->class_type.c.protocol = p; if (name) Hash_Add (protocol_hash, p); return p; } void protocol_add_methods (protocol_t *protocol, methodlist_t *methods) { if (!methods) return; *protocol->methods->tail = methods->head; protocol->methods->tail = methods->tail; free (methods); } void protocol_add_protocols (protocol_t *protocol, protocollist_t *protocols) { protocol->protocols = protocols; } def_t * protocol_def (protocol_t *protocol) { return make_symbol (protocol->name, &type_Protocol, pr.far_data, st_static)->s.def; } protocollist_t * new_protocol_list (void) { protocollist_t *protocollist = malloc (sizeof (protocollist_t)); protocollist->count = 0; protocollist->list = 0; return protocollist; } protocollist_t * add_protocol (protocollist_t *protocollist, const char *name) { protocol_t *protocol = get_protocol (name, 0); if (!protocol) { error (0, "undefined protocol `%s'", name); return protocollist; } protocollist->count++; protocollist->list = realloc (protocollist->list, sizeof (protocol_t) * protocollist->count); protocollist->list[protocollist->count - 1] = protocol; return protocollist; } def_t * emit_protocol (protocol_t *protocol) { def_t *proto_def; pr_protocol_t *proto; defspace_t *space; proto_def = make_symbol (va ("_OBJ_PROTOCOL_%s", protocol->name), &type_Protocol, pr.far_data, st_static)->s.def; if (proto_def->initialized) return proto_def; proto_def->initialized = proto_def->constant = 1; proto_def->nosave = 1; space = proto_def->space; proto = &D_STRUCT (pr_protocol_t, proto_def); proto->class_pointer = 0; EMIT_STRING (space, proto->protocol_name, protocol->name); EMIT_DEF (space, proto->protocol_list, emit_protocol_list (protocol->protocols, va ("PROTOCOL_%s", protocol->name))); EMIT_DEF (space, proto->instance_methods, emit_method_descriptions (protocol->methods, protocol->name, 1)); EMIT_DEF (space, proto->class_methods, emit_method_descriptions (protocol->methods, protocol->name, 0)); emit_class_ref ("Protocol"); return proto_def; } def_t * emit_protocol_list (protocollist_t *protocols, const char *name) { //FIXME use emit_struct static struct_def_t proto_list_struct[] = { {"next", &type_pointer}, {"count", &type_integer}, {"list", 0}, // type will be filled in at run time {0, 0}, }; type_t *proto_list_type; def_t *proto_list_def; defspace_t *space; pr_protocol_list_t *proto_list; int i; if (!protocols) return 0; proto_list_struct[2].type = array_type (&type_pointer, protocols->count); proto_list_type = make_structure (0, 's', proto_list_struct, 0)->type; proto_list_def = make_symbol (va ("_OBJ_PROTOCOLS_%s", name), proto_list_type, pr.far_data, st_static)->s.def; proto_list_def->initialized = proto_list_def->constant = 1; proto_list_def->nosave = 1; space = proto_list_def->space; proto_list = &D_STRUCT (pr_protocol_list_t, proto_list_def); proto_list->next = 0; proto_list->count = protocols->count; for (i = 0; i < protocols->count; i++) EMIT_DEF (space, proto_list->list[i], emit_protocol (protocols->list[i])); return proto_list_def; } void clear_classes (void) { if (class_hash) Hash_FlushTable (class_hash); if (protocol_hash) Hash_FlushTable (protocol_hash); if (category_hash) Hash_FlushTable (category_hash); if (class_hash) class_Class.super_class = get_class (new_symbol ("Object"), 1); } symtab_t * class_to_struct (class_t *class, symtab_t *symtab) { symtab_t *parent = symtab->parent; symtab_t *ivars = class->ivars; symtab_t *ancestor; if (!ivars) return symtab; // disconnect the struct symbol table from the scope symtab->parent = 0; // find the ancestor of the ivars symbol table chain for (ancestor = ivars; ancestor->parent; ancestor = ancestor->parent) ; // connect the ivars symbol table chain to the struct symbol table ancestor->parent = symtab; // create a new struct symbol table from the ivars symbol table chain symtab = symtab_flat_copy (ivars, 0); // disconnect the ivars symbol table chain ancestor->parent = 0; // connect the new struct symbol table to the scope symtab->parent = parent; return symtab; } symtab_t * class_ivar_scope (class_type_t *class_type, symtab_t *parent) { class_t *class = extract_class (class_type); return symtab_flat_copy (class->ivars, parent); } void class_finish_ivar_scope (class_type_t *class_type, symtab_t *ivar_scope, symtab_t *param_scope) { class_t *class = extract_class (class_type); type_t *class_ptr = pointer_type (class->type); symbol_t *sym; symbol_t *self; expr_t *self_expr; self = symtab_lookup (param_scope, "self"); if (!self) internal_error (0, "I've lost my self!"); self_expr = new_symbol_expr (self); if (self->type != class_ptr) { debug (0, "class method scope"); //FIXME should generate a warning on access self_expr = cast_expr (class_ptr, self_expr); } for (sym = ivar_scope->symbols; sym; sym = sym->next) { if (sym->sy_type != sy_var) continue; sym->sy_type = sy_expr; sym->s.expr = binary_expr ('.', copy_expr (self_expr), new_symbol_expr (new_symbol (sym->name))); } }