quakeforge/tools/qfcc/source/function.c
Bill Currie eb8fd55677 Move set.c into libQFutil.
Also move the ALLOC/FREE macros from qfcc.h to QF/alloc.h (needed to for
set.c).

Both modules are more generally useful than just for qfcc (eg, set
builtins for ruamoko).
2012-12-06 20:52:53 +09:00

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/*
function.c
QC function 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
#ifdef HAVE_STRING_H
# include <string.h>
#endif
#ifdef HAVE_STRINGS_H
# include <strings.h>
#endif
#include <stdlib.h>
#include "QF/alloc.h"
#include "QF/dstring.h"
#include "QF/hash.h"
#include "QF/va.h"
#include "qfcc.h"
#include "codespace.h"
#include "debug.h"
#include "def.h"
#include "defspace.h"
#include "diagnostic.h"
#include "emit.h"
#include "expr.h"
#include "flow.h"
#include "function.h"
#include "opcodes.h"
#include "options.h"
#include "reloc.h"
#include "shared.h"
#include "statements.h"
#include "strpool.h"
#include "symtab.h"
#include "type.h"
#include "value.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 (const void *_f, void *unused)
{
overloaded_function_t *f = (overloaded_function_t *) _f;
return f->full_name;
}
static const char *
func_map_get_key (const 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 *
param_append_identifiers (param_t *params, symbol_t *idents, type_t *type)
{
param_t **p = &params;
while (*p)
p = &(*p)->next;
if (!idents) {
*p = new_param (0, 0, 0);
p = &(*p)->next;
}
while (idents) {
idents->type = type;
*p = new_param (0, type, idents->name);
(*p)->symbol = idents;
p = &(*p)->next;
idents = idents->next;
}
return params;
}
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;
new = new_type ();
new->type = ev_func;
new->t.func.type = type;
new->t.func.num_params = 0;
for (p = parms; p; p = p->next) {
if (new->t.func.num_params > MAX_PARMS) {
error (0, "too many params");
return type;
}
if (!p->selector && !p->type && !p->name) {
if (p->next)
internal_error (0, 0);
new->t.func.num_params = -(new->t.func.num_params + 1);
} else if (p->type) {
new->t.func.param_types[new->t.func.num_params] = p->type;
new->t.func.num_params++;
}
}
return new;
}
param_t *
check_params (param_t *params)
{
int num = 1;
param_t *p = params;
if (!params)
return 0;
while (p) {
if (p->type == &type_void) {
if (p->name) {
error (0, "parameter %d ('%s') has incomplete type", num,
p->name);
p->type = type_default;
} else if (num > 1 || p->next) {
error (0, "'void' must be the only parameter");
p->name = "void";
} else {
// this is a void function
return 0;
}
}
p = p->next;
}
return params;
}
static 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) {
expr_t *e = new_expr ();
e->line = func->line;
e->file = func->file;
warning (0, "creating overloaded function %s without @overload",
full_name);
warning (e, "(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;
func->file = pr.source_file;
func->line = pr.source_line;
Hash_Add (overloaded_functions, func);
Hash_Add (function_map, func);
return func;
}
symbol_t *
function_symbol (symbol_t *sym, int overload, int create)
{
const char *name = sym->name;
overloaded_function_t *func;
symbol_t *s;
func = get_function (name, sym->type, overload, create);
if (func && func->overloaded)
name = func->full_name;
s = symtab_lookup (current_symtab, name);
if ((!s || s->table != current_symtab) && create) {
s = new_symbol (name);
s->sy_type = sy_func;
s->type = sym->type;
s->params = sym->params;
s->s.func = 0; // function not yet defined
symtab_addsymbol (current_symtab, s);
}
return s;
}
// 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->t.func.num_params;
int nb = tb->t.func.num_params;
int ret, i;
if (na < 0)
na = ~na;
if (nb < 0)
nb = ~nb;
if (na != nb)
return nb - na;
if ((ret = (fb->type->t.func.num_params - fa->type->t.func.num_params)))
return ret;
for (i = 0; i < na && i < nb; i++)
if (ta->t.func.param_types[i] != tb->t.func.param_types[i])
return (long)(tb->t.func.param_types[i] - ta->t.func.param_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_symbol)
return fexpr;
memset (&type, 0, sizeof (type));
for (e = params; e; e = e->next) {
if (e->type == ex_error)
return e;
type.t.func.num_params++;
}
if (type.t.func.num_params > MAX_PARMS)
return fexpr;
for (i = 0, e = params; e; i++, e = e->next) {
type.t.func.param_types[type.t.func.num_params - 1 - i] = get_type (e);
if (e->type == ex_error)
return e;
}
funcs = Hash_FindList (function_map, fexpr->e.symbol->name);
if (!funcs)
return fexpr;
for (func_count = 0; funcs[func_count]; func_count++)
;
if (func_count < 2) {
free (funcs);
return fexpr;
}
type.t.func.type = ((overloaded_function_t *) funcs[0])->type->t.func.type;
dummy.type = find_type (&type);
qsort (funcs, func_count, sizeof (void *), func_compare);
dummy.full_name = save_string (va ("%s|%s", fexpr->e.symbol->name,
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.symbol->name = f->full_name;
free (funcs);
return fexpr;
}
for (i = 0; i < func_count; i++) {
f = (overloaded_function_t *) funcs[i];
parm_count = f->type->t.func.num_params;
if ((parm_count >= 0 && parm_count != type.t.func.num_params)
|| (parm_count < 0 && ~parm_count > type.t.func.num_params)) {
funcs[i] = 0;
continue;
}
if (parm_count < 0)
parm_count = ~parm_count;
for (j = 0; j < parm_count; j++) {
if (!type_assignable (f->type->t.func.param_types[j],
type.t.func.param_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.symbol = symtab_lookup (current_symtab,
best->full_name);
if (!fexpr->e.symbol)
internal_error (fexpr, "overloaded function %s not found",
best->full_name);
}
free (funcs);
return fexpr;
}
error (fexpr, "unable to find function matching %s", dummy.full_name);
free (funcs);
return fexpr;
}
static void
check_function (symbol_t *fsym)
{
param_t *params = fsym->params;
param_t *p;
int i;
if (!type_size (fsym->type->t.func.type)) {
error (0, "return type is an incomplete type");
fsym->type->t.func.type = &type_void;//FIXME better type?
}
if (type_size (fsym->type->t.func.type) > type_size (&type_param)) {
error (0, "return value too large to be passed by value");
fsym->type->t.func.type = &type_void;//FIXME better type?
}
for (p = params, i = 0; p; p = p->next, i++) {
if (!p->selector && !p->type && !p->name)
continue; // ellipsis marker
if (!p->type)
continue; // non-param selector
if (!type_size (p->type))
error (0, "parameter %d (‘%s’) has incomplete type",
i + 1, p->name);
if (type_size (p->type) > type_size (&type_param))
error (0, "param %d (‘%s’) is too large to be passed by value",
i + 1, p->name);
}
}
static void
build_scope (symbol_t *fsym, symtab_t *parent)
{
int i;
param_t *p;
symbol_t *args = 0;
symbol_t *param;
symtab_t *symtab;
symtab_t *cs = current_symtab;
check_function (fsym);
symtab = new_symtab (parent, stab_local);
fsym->s.func->symtab = symtab;
symtab->space = defspace_new (ds_virtual);
current_symtab = symtab;
if (fsym->type->t.func.num_params < 0) {
args = new_symbol_type (".args", &type_va_list);
initialize_def (args, args->type, 0, symtab->space, sc_param);
}
for (p = fsym->params, i = 0; p; p = p->next) {
if (!p->selector && !p->type && !p->name)
continue; // ellipsis marker
if (!p->type)
continue; // non-param selector
param = new_symbol_type (p->name, p->type);
initialize_def (param, param->type, 0, symtab->space, sc_param);
i++;
}
if (args) {
while (i < MAX_PARMS) {
param = new_symbol_type (va (".par%d", i), &type_param);
initialize_def (param, &type_param, 0, symtab->space, sc_param);
i++;
}
}
current_symtab = cs;
}
function_t *
new_function (const char *name, const char *nice_name)
{
function_t *f;
ALLOC (1024, function_t, functions, f);
f->s_name = ReuseString (name);
f->s_file = pr.source_file;
if (!(f->name = nice_name))
f->name = name;
return f;
}
void
make_function (symbol_t *sym, const char *nice_name, defspace_t *space,
storage_class_t storage)
{
reloc_t *relocs = 0;
if (sym->sy_type != sy_func)
internal_error (0, "%s is not a function", sym->name);
if (storage == sc_extern && sym->s.func)
return;
if (!sym->s.func) {
sym->s.func = new_function (sym->name, nice_name);
sym->s.func->sym = sym;
}
if (sym->s.func->def && sym->s.func->def->external
&& storage != sc_extern) {
//FIXME this really is not the right way
relocs = sym->s.func->def->relocs;
free_def (sym->s.func->def);
sym->s.func->def = 0;
}
if (!sym->s.func->def) {
sym->s.func->def = new_def (sym->name, sym->type, space, storage);
reloc_attach_relocs (relocs, &sym->s.func->def->relocs);
}
}
void
add_function (function_t *f)
{
*pr.func_tail = f;
pr.func_tail = &f->next;
f->function_num = pr.num_functions++;
}
function_t *
begin_function (symbol_t *sym, const char *nicename, symtab_t *parent,
int far)
{
defspace_t *space;
if (sym->sy_type != sy_func) {
error (0, "%s is not a function", sym->name);
sym = new_symbol_type (sym->name, &type_function);
sym = function_symbol (sym, 1, 1);
}
if (sym->s.func && sym->s.func->def && sym->s.func->def->initialized) {
error (0, "%s redefined", sym->name);
sym = new_symbol_type (sym->name, sym->type);
sym = function_symbol (sym, 1, 1);
}
space = sym->table->space;
if (far)
space = pr.far_data;
make_function (sym, nicename, space, current_storage);
if (!sym->s.func->def->external) {
sym->s.func->def->initialized = 1;
sym->s.func->def->constant = 1;
sym->s.func->def->nosave = 1;
add_function (sym->s.func);
reloc_def_func (sym->s.func, sym->s.func->def);
}
sym->s.func->code = pr.code->size;
sym->s.func->s_file = pr.source_file;
if (options.code.debug) {
pr_lineno_t *lineno = new_lineno ();
sym->s.func->line_info = lineno - pr.linenos;
}
build_scope (sym, parent);
return sym->s.func;
}
function_t *
build_code_function (symbol_t *fsym, expr_t *state_expr, expr_t *statements)
{
if (fsym->sy_type != sy_func) // probably in error recovery
return 0;
build_function (fsym->s.func);
if (state_expr) {
state_expr->next = statements;
statements = state_expr;
}
emit_function (fsym->s.func, statements);
finish_function (fsym->s.func);
return fsym->s.func;
}
function_t *
build_builtin_function (symbol_t *sym, expr_t *bi_val, int far)
{
int bi;
defspace_t *space;
if (sym->sy_type != sy_func) {
error (bi_val, "%s is not a function", sym->name);
return 0;
}
if (sym->s.func && sym->s.func->def && sym->s.func->def->initialized) {
error (bi_val, "%s redefined", sym->name);
return 0;
}
if (!is_integer_val (bi_val) && !is_float_val (bi_val)) {
error (bi_val, "invalid constant for = #");
return 0;
}
space = sym->table->space;
if (far)
space = pr.far_data;
make_function (sym, 0, space, current_storage);
if (sym->s.func->def->external)
return 0;
add_function (sym->s.func);
if (is_integer_val (bi_val))
bi = expr_integer (bi_val);
else
bi = expr_float (bi_val);
sym->s.func->builtin = bi;
reloc_def_func (sym->s.func, sym->s.func->def);
build_function (sym->s.func);
finish_function (sym->s.func);
// for debug info
build_scope (sym, current_symtab);
return sym->s.func;
}
void
build_function (function_t *f)
{
// FIXME
// 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)
{
}
void
emit_function (function_t *f, expr_t *e)
{
f->code = pr.code->size;
lineno_base = f->def->line;
f->sblock = make_statements (e);
if (options.code.optimize) {
flow_build_vars (f);
f->graph = flow_build_graph (f->sblock, f);
f->graph->func = f;
flow_data_flow (f->graph);
f->sblock = flow_generate (f->graph);
} else {
statements_count_temps (f->sblock);
}
emit_statements (f->sblock);
}
int
function_parms (function_t *f, byte *parm_size)
{
int count, i;
ty_func_t *func = &f->sym->type->t.func;
if (func->num_params >= 0)
count = func->num_params;
else
count = -func->num_params - 1;
for (i = 0; i < count; i++)
parm_size[i] = type_size (func->param_types[i]);
return func->num_params;
}
void
clear_functions (void)
{
if (overloaded_functions)
Hash_FlushTable (overloaded_functions);
if (function_map)
Hash_FlushTable (function_map);
}