quakeforge/tools/qfcc/source/class.c
Bill Currie 4336fc2c73 Move method function defs into the far data space.
As they are never referenced directly by instructions, there's no need for
them to be in the near data space, taking precious def locations.
2011-02-15 15:33:18 +09:00

1406 lines
36 KiB
C

/*
class.c
QC class support code
Copyright (C) 2002 Bill Currie
Author: Bill Currie <bill@taniwha.org>
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 <string.h>
#endif
#ifdef HAVE_STRINGS_H
# include <strings.h>
#endif
#include <stdlib.h>
#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_Super = { ev_invalid, "Super" };
type_t type_SuperPtr = { ev_pointer, 0, ty_none, {{&type_Super}}};
type_t type_supermsg = { ev_func, ".supermsg", ty_none,
{{&type_id, -3, {&type_SuperPtr, &type_SEL}}}};
type_t type_Method = { ev_invalid, "Method" };
type_t type_method_description = { ev_invalid, "obj_method_description",
ty_struct };
type_t type_category = { ev_invalid, "category", ty_struct};
type_t type_ivar = { ev_invalid, "ivar", ty_struct};
type_t type_module = { ev_invalid, 0, ty_struct};
type_t type_moduleptr = { ev_pointer, 0, ty_none, {{&type_module}}};
type_t type_obj_exec_class = { ev_func, 0, ty_none,
{{&type_void, 1, { &type_moduleptr }}}};
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_ClassPtr},
{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_ClassPtr},
{"super_class", &type_ClassPtr},
{"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_ClassPtr},
{"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_ClassPtr},
{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);
chain_type (&type_SuperPtr);
chain_type (&type_supermsg);
make_structure ("obj_module_s", 's', module_struct, &type_module);
}
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)
{
if (!current_symtab)
current_symtab = pr.symtab;
init_classes ();
init_objective_structs ();
}
void
class_init_obj_module (void)
{
symbol_t *sym;
sym = new_symbol ("obj_module_s");
sym = find_struct ('s', sym, &type_module);
chain_type (&type_module);
chain_type (&type_moduleptr);
chain_type (&type_obj_exec_class);
if (!sym->table)
symtab_addsymbol (pr.symtab, sym);
sym = new_symbol_type ("obj_module_t", sym->type);
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;
symbol_t *sym;
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
}
sym = make_symbol (name, type, pr.far_data,
external ? st_extern : st_global);
if (!sym->table)
symtab_addsymbol (pr.symtab, sym);
return sym;
}
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;
sym->sy_type = sy_class;
}
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, 0};
symbol_t *s;
def_t *def;
ivar_data.encoding = dstring_newstr ();
if (ivars) {
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)
{
symbol_t *ref_sym;
symbol_t *name_sym;
def_t *ref_def;
def_t *name_def;
ref_sym = make_symbol (va (".obj_class_ref_%s", class_name), &type_pointer,
pr.far_data, st_static);
if (!ref_sym->table)
symtab_addsymbol (pr.symtab, ref_sym);
ref_def = ref_sym->s.def;
if (ref_def->initialized)
return;
ref_def->initialized = ref_def->constant = ref_def->nosave = 1;
name_sym = make_symbol (va (".obj_class_name_%s", class_name),
&type_pointer, pr.far_data, st_extern);
if (!name_sym->table)
symtab_addsymbol (pr.symtab, name_sym);
name_def = name_sym->s.def;
if (!name_def->external)
D_INT (ref_def) = name_def->offset;
reloc_def_def (name_def, ref_def);
}
static void
emit_class_name (const char *class_name)
{
symbol_t *name_sym;
def_t *name_def;
name_sym = make_symbol (va (".obj_class_name_%s", class_name),
&type_pointer, pr.far_data, st_global);
if (!name_sym->table)
symtab_addsymbol (pr.symtab, name_sym);
name_def = name_sym->s.def;
if (name_def->initialized)
return;
name_def->initialized = name_def->constant = 1;
name_def->nosave = 1;
D_INT (name_def) = 0;
}
void
emit_category_ref (const char *class_name, const char *category_name)
{
symbol_t *ref_sym;
symbol_t *name_sym;
def_t *ref_def;
def_t *name_def;
ref_sym = make_symbol (va (".obj_category_ref_%s_%s",
class_name, category_name),
&type_pointer, pr.far_data, st_static);
if (!ref_sym->table)
symtab_addsymbol (pr.symtab, ref_sym);
ref_def = ref_sym->s.def;
if (ref_def->initialized)
return;
ref_def->initialized = ref_def->constant = 1;
ref_def->nosave = 1;
name_sym = make_symbol (va (".obj_category_name_%s_%s",
class_name, category_name),
&type_pointer, pr.far_data, st_extern);
if (!name_sym->table)
symtab_addsymbol (pr.symtab, name_sym);
name_def = name_sym->s.def;
if (!name_def->external)
D_INT (ref_def) = name_def->offset;
reloc_def_def (name_def, ref_def);
}
static void
emit_category_name (const char *class_name, const char *category_name)
{
symbol_t *name_sym;
def_t *name_def;
name_sym = make_symbol (va (".obj_category_name_%s_%s",
class_name, category_name),
&type_pointer, pr.far_data, st_global);
if (!name_sym->table)
symtab_addsymbol (pr.symtab, name_sym);
name_def = name_sym->s.def;
if (name_def->initialized)
return;
name_def->initialized = name_def->constant = 1;
name_def->nosave = 1;
D_INT (name_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;
selector = get_selector (sel);
if (!selector)
return 0;
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)
{
int base = 0;
symbol_t *sym;
if (class->super_class)
base = type_size (class->super_class->type);
for (sym = ivars->symbols; sym; sym = sym->next)
sym->s.offset += base;
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),
&type_ClassPtr,
pr.near_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);
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) = 0;
if (da->refs)
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__);
D_INT (def) = 0;
if (da->refs)
EMIT_DEF (def->space, D_INT (def), 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 (!is_array (def->type) || def->type->t.array.type->type != ev_pointer)
internal_error (0, "%s: expected array of pointers 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;
for (cl = da->classes; *cl; cl++)
if ((*cl)->def && !(*cl)->def->external)
if (!index--)
break;
EMIT_DEF (def->space, D_INT (def), (*cl)->def);
} else {
category_t **ca;
index -= da->cls_def_cnt;
for (ca = da->categories; *ca; ca++)
if ((*ca)->def && !(*ca)->def->external)
if (!index--)
break;
EMIT_DEF (def->space, D_INT (def), (*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;
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);
free (data.classes);
free (data.categories);
module_sym = make_symbol ("_OBJ_MODULE", &type_module, pr.far_data,
st_static);
symtab_addsymbol (current_symtab, module_sym);
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 = symtab_lookup (pr.symtab, "__obj_exec_class");
if (!exec_class_sym) {
exec_class_sym = new_symbol_type ("__obj_exec_class",
&type_obj_exec_class);
exec_class_sym = function_symbol (exec_class_sym, 0, 1);
make_function (exec_class_sym, 0, exec_class_sym->table->space,
st_extern);
}
init_sym = new_symbol_type (".ctor", &type_function);
init_sym = function_symbol (init_sym, 0, 1);
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 = begin_function (init_sym, 0, current_symtab, 1);
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)));
}
}