quakeforge/tools/qfcc/source/emit.c
2002-07-12 16:01:40 +00:00

631 lines
14 KiB
C

/*
#FILENAME#
#DESCRIPTION#
Copyright (C) 2001 #AUTHOR#
Author: #AUTHOR#
Date: #DATE#
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
*/
static const char rcsid[] =
"$Id$";
#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/mathlib.h>
#include <QF/va.h>
#include "def.h"
#include "debug.h"
#include "emit.h"
#include "expr.h"
#include "immediate.h"
#include "opcodes.h"
#include "options.h"
#include "qfcc.h"
#include "reloc.h"
#include "type.h"
#include "qc-parse.h"
static expr_t zero;
codespace_t *
codespace_new (void)
{
return calloc (1, sizeof (codespace_t));
}
void
codespace_delete (codespace_t *codespace)
{
free (codespace->code);
free (codespace);
}
void
codespace_addcode (codespace_t *codespace, dstatement_t *code, int size)
{
if (codespace->size + size > codespace->max_size) {
codespace->max_size = (codespace->size + size + 16383) & ~16383;
codespace->code = realloc (codespace->code,
codespace->max_size * sizeof (dstatement_t));
}
memcpy (codespace->code + codespace->size, code,
size * sizeof (dstatement_t));
codespace->size += size;
}
dstatement_t *
codespace_newstatement (codespace_t *codespace)
{
if (codespace->size >= codespace->max_size) {
codespace->max_size += 16384;
codespace->code = realloc (codespace->code,
codespace->max_size * sizeof (dstatement_t));
}
return codespace->code + codespace->size++;
}
void
add_statement_ref (def_t *def, dstatement_t *st, reloc_type type)
{
if (def) {
reloc_t *ref = new_reloc (st - pr.code->code, type);
ref->next = def->refs;
def->refs = ref;
def->users--;
def->used = 1;
}
}
def_t *
emit_statement (expr_t *e, opcode_t *op, def_t *var_a, def_t *var_b,
def_t *var_c)
{
dstatement_t *statement;
def_t *ret;
if (!op) {
error (e, "ice ice baby\n");
abort ();
}
if (options.code.debug) {
int line = (e ? e->line : pr.source_line) - lineno_base;
if (line != linenos[num_linenos - 1].line) {
pr_lineno_t *lineno = new_lineno ();
lineno->line = line;
lineno->fa.addr = pr.code->size;
}
}
statement = codespace_newstatement (pr.code);
statement->op = op->opcode;
statement->a = var_a ? var_a->ofs : 0;
statement->b = var_b ? var_b->ofs : 0;
if (op->type_c == ev_void || op->right_associative) {
// ifs, gotos, and assignments don't need vars allocated
if (op->type_c == ev_void) {
var_c = NULL;
statement->c = 0;
} else {
statement->c = var_c->ofs;
}
ret = var_a;
} else { // allocate result space
if (!var_c) {
var_c = get_tempdef (types[op->type_c], current_scope);
var_c->users += 2;
}
statement->c = var_c->ofs;
ret = var_c;
}
#if 0
printf ("%s %s(%d) %s(%d) %s(%d)\n", op->opname,
var_a ? var_a->name : "", statement->a,
var_b ? var_b->name : "", statement->b,
var_c ? var_c->name : "", statement->c);
#endif
add_statement_ref (var_a, statement, rel_op_a_def);
add_statement_ref (var_b, statement, rel_op_b_def);
add_statement_ref (var_c, statement, rel_op_c_def);
if (op->right_associative)
return var_a;
return var_c;
}
void
emit_branch (expr_t *_e, opcode_t *op, expr_t *e, expr_t *l)
{
dstatement_t *st;
reloc_t *ref;
def_t *def = 0;
int ofs;
if (e)
def = emit_sub_expr (e, 0);
st = &pr.code->code[ofs = pr.code->size];
emit_statement (_e, op, def, 0, 0);
if (l->e.label.ofs) {
if (op == op_goto)
st->a = l->e.label.ofs - ofs;
else
st->b = l->e.label.ofs - ofs;
} else {
ref = new_reloc (ofs, op == op_goto ? rel_op_a_op : rel_op_b_op);
ref->next = l->e.label.refs;
l->e.label.refs = ref;
}
}
def_t *
emit_function_call (expr_t *e, def_t *dest)
{
def_t *func = emit_sub_expr (e->e.expr.e1, 0);
def_t parm;
def_t *arg;
expr_t *earg;
opcode_t *op;
int count = 0, ind;
for (earg = e->e.expr.e2; earg; earg = earg->next)
count++;
ind = count;
for (earg = e->e.expr.e2; earg; earg = earg->next) {
ind--;
parm = def_parms[ind];
parm.type = types[extract_type (earg)];
arg = emit_sub_expr (earg, &parm);
if (earg->type != ex_expr && earg->type != ex_uexpr) {
op = opcode_find ("=", arg, &parm, &def_void);
emit_statement (e, op, arg, &parm, 0);
}
}
op = opcode_find (va ("<CALL%d>", count), &def_function, &def_void,
&def_void);
emit_statement (e, op, func, 0, 0);
def_ret.type = func->type->aux_type;
if (dest) {
op = opcode_find ("=", dest, &def_ret, &def_void);
emit_statement (e, op, &def_ret, dest, 0);
return dest;
} else {
return &def_ret;
}
}
def_t *
emit_assign_expr (int oper, expr_t *e)
{
def_t *def_a, *def_b, *def_c;
opcode_t *op;
expr_t *e1 = e->e.expr.e1;
expr_t *e2 = e->e.expr.e2;
const char *operator = get_op_string (oper);
if (e1->type == ex_temp && e1->e.temp.users < 2) {
e1->e.temp.users--;
return 0;
}
if (oper == '=') {
def_a = emit_sub_expr (e1, 0);
if (def_a->constant) {
if (options.code.cow) {
int size = type_size (def_a->type);
int ofs = new_location (def_a->type, pr.near_data);
memcpy (G_POINTER (void, ofs), G_POINTER (void, def_a->ofs),
size);
def_a->ofs = ofs;
def_a->constant = 0;
if (options.warnings.cow)
warning (e1, "assignment to constant %s (Moooooooo!)",
def_a->name);
} else {
if (options.traditional)
warning (e1, "assignment to constant %s", def_a->name);
else
error (e1, "assignment to constant %s", def_a->name);
}
}
def_b = emit_sub_expr (e2, def_a);
if (def_b != def_a) {
op = opcode_find (operator, def_b, def_a, &def_void);
emit_statement (e, op, def_b, def_a, 0);
}
return def_a;
} else {
def_b = emit_sub_expr (e2, 0);
if (e->rvalue && def_b->managed)
def_b->users++;
if (e1->type == ex_expr && extract_type (e1->e.expr.e1) == ev_pointer
&& e1->e.expr.e1->type < ex_string) {
def_a = emit_sub_expr (e1->e.expr.e1, 0);
def_c = emit_sub_expr (e1->e.expr.e2, 0);
op = opcode_find (operator, def_b, def_a, def_c);
} else {
def_a = emit_sub_expr (e1, 0);
def_c = 0;
op = opcode_find (operator, def_b, def_a, &def_void);
}
emit_statement (e, op, def_b, def_a, def_c);
return def_b;
}
}
def_t *
emit_bind_expr (expr_t *e1, expr_t *e2)
{
type_t *t1 = get_type (e1);
type_t *t2 = get_type (e2);
def_t *def;
if (!e2 || e2->type != ex_temp) {
error (e1, "internal error");
abort ();
}
def = emit_sub_expr (e1, e2->e.temp.def);
if (t1 != t2) {
def_t *tmp = new_def (t2, 0, current_scope);
tmp->ofs = def->ofs;
tmp->users = e2->e.temp.users;
tmp->freed = 1; // don't free this offset when freeing def
def = tmp;
}
e2->e.temp.def = def;
return e2->e.temp.def;
}
def_t *
emit_address_expr (expr_t *e)
{
def_t *def_a, *def_b, *d;
opcode_t *op;
def_a = emit_sub_expr (e->e.expr.e1, 0);
def_b = emit_sub_expr (e->e.expr.e2, 0);
op = opcode_find ("&", def_a, def_b, 0);
d = emit_statement (e, op, def_a, def_b, 0);
return d;
}
def_t *
emit_deref_expr (expr_t *e, def_t *dest)
{
def_t *d;
type_t *type = e->e.expr.type;
def_t *z;
opcode_t *op;
e = e->e.expr.e1;
if (e->type == ex_pointer) {
if (e->e.pointer.val > 0 && e->e.pointer.val < 65536) {
d = new_def (e->e.pointer.type, 0, current_scope);
d->ofs = e->e.pointer.val;
d->absolute = e->e.pointer.abs;
} else {
d = ReuseConstant (e, 0);
zero.type = ex_short;
z = emit_sub_expr (&zero, 0);
op = opcode_find (".", d, z, dest);
d = emit_statement (e, op, d, z, dest);
}
return d;
}
if (!dest && (e->type != ex_pointer
|| !(e->e.pointer.val > 0
&& e->e.pointer.val < 65536))) {
dest = get_tempdef (type, current_scope);
dest->users += 2;
}
if (e->type == ex_expr
&& e->e.expr.op == '&'
&& e->e.expr.e1->type < ex_string)
e->e.expr.op = '.';
d = emit_sub_expr (e, dest);
if (dest && d != dest) {
zero.type = ex_short;
z = emit_sub_expr (&zero, 0);
op = opcode_find (".", d, z, dest);
d = emit_statement (e, op, d, z, dest);
} else {
if (!d->name)
d->type = type;
}
return d;
}
def_t *
emit_sub_expr (expr_t *e, def_t *dest)
{
opcode_t *op;
const char *operator;
def_t *def_a, *def_b, *d = 0;
def_t *tmp = 0;
switch (e->type) {
case ex_block:
if (e->e.block.result) {
d = emit_sub_expr (e->e.block.result, dest);
for (e = e->e.block.head; e; e = e->next)
emit_expr (e);
break;
}
case ex_name:
case ex_nil:
case ex_label:
case ex_error:
error (e, "internal error");
abort ();
case ex_expr:
if (e->e.expr.op == 'c') {
d = emit_function_call (e, dest);
break;
}
if (e->e.expr.op == '=' || e->e.expr.op == PAS) {
d = emit_assign_expr (e->e.expr.op, e);
if (!d->managed)
d->users++;
break;
}
if (e->e.expr.op == '&' && e->e.expr.type->type == ev_pointer) {
d = emit_address_expr (e);
break;
}
if (e->e.expr.e1->type == ex_block
&& e->e.expr.e1->e.block.is_call) {
def_b = emit_sub_expr (e->e.expr.e2, 0);
def_a = emit_sub_expr (e->e.expr.e1, 0);
} else {
def_a = emit_sub_expr (e->e.expr.e1, 0);
def_b = emit_sub_expr (e->e.expr.e2, 0);
}
operator = get_op_string (e->e.expr.op);
if (!dest) {
dest = get_tempdef (e->e.expr.type, current_scope);
dest->users += 2;
}
op = opcode_find (operator, def_a, def_b, dest);
d = emit_statement (e, op, def_a, def_b, dest);
break;
case ex_uexpr:
switch (e->e.expr.op) {
case '!':
operator = "!";
def_a = emit_sub_expr (e->e.expr.e1, 0);
def_b = &def_void;
break;
case '~':
operator = "~";
def_a = emit_sub_expr (e->e.expr.e1, 0);
def_b = &def_void;
break;
case '-':
zero.type = expr_types[extract_type (e->e.expr.e1)];
operator = "-";
def_a = ReuseConstant (&zero, 0);
def_b = emit_sub_expr (e->e.expr.e1, 0);
if (!dest) {
dest = get_tempdef (e->e.expr.type, current_scope);
dest->users += 2;
}
break;
case '&':
zero.type = ex_short;
operator = "&";
if (e->e.expr.e1->type == ex_expr
&& e->e.expr.e1->e.expr.op == '.') {
tmp = get_tempdef (e->e.expr.type, current_scope);
tmp->users += 2;
def_b = emit_sub_expr (&zero, 0);
} else {
def_b = &def_void;
}
def_a = emit_sub_expr (e->e.expr.e1, tmp);
if (!dest) {
dest = get_tempdef (e->e.expr.type, current_scope);
dest->users += 2;
}
break;
case '.':
return emit_deref_expr (e, dest);
case 'C':
def_a = emit_sub_expr (e->e.expr.e1, 0);
if (def_a->type->type == ev_pointer
&& e->e.expr.type->type == ev_pointer) {
return def_a;
}
def_b = &def_void;
if (!dest) {
dest = get_tempdef (e->e.expr.type, current_scope);
dest->users = 2;
}
operator = "=";
break;
default:
abort ();
}
op = opcode_find (operator, def_a, def_b, dest);
d = emit_statement (e, op, def_a, def_b, dest);
break;
case ex_def:
d = e->e.def;
break;
case ex_temp:
if (!e->e.temp.def) {
if (dest)
e->e.temp.def = dest;
else
e->e.temp.def = get_tempdef (e->e.temp.type, current_scope);
e->e.temp.def->users = e->e.temp.users;
e->e.temp.def->expr = e;
e->e.temp.def->managed = 1;
}
d = e->e.temp.def;
break;
case ex_pointer:
case ex_string:
case ex_float:
case ex_vector:
case ex_entity:
case ex_field:
case ex_func:
case ex_quaternion:
case ex_integer:
case ex_uinteger:
d = ReuseConstant (e, 0);
break;
case ex_short:
d = new_def (&type_short, 0, 0);
d->ofs = e->e.short_val;
d->absolute = 1;
d->users = 1;
break;
}
free_tempdefs ();
return d;
}
void
emit_expr (expr_t *e)
{
def_t *def;
def_t *def_a;
def_t *def_b;
ex_label_t *label;
//printf ("%d ", e->line);
//print_expr (e);
//puts ("");
switch (e->type) {
case ex_error:
break;
case ex_label:
label = &e->e.label;
label->ofs = pr.code->size;
break;
case ex_block:
for (e = e->e.block.head; e; e = e->next)
emit_expr (e);
break;
case ex_expr:
switch (e->e.expr.op) {
case PAS:
case '=':
emit_assign_expr (e->e.expr.op, e);
break;
case 'n':
emit_branch (e, op_ifnot, e->e.expr.e1, e->e.expr.e2);
break;
case 'i':
emit_branch (e, op_if, e->e.expr.e1, e->e.expr.e2);
break;
case IFBE:
emit_branch (e, op_ifbe, e->e.expr.e1, e->e.expr.e2);
break;
case IFB:
emit_branch (e, op_ifb, e->e.expr.e1, e->e.expr.e2);
break;
case IFAE:
emit_branch (e, op_ifae, e->e.expr.e1, e->e.expr.e2);
break;
case IFA:
emit_branch (e, op_ifa, e->e.expr.e1, e->e.expr.e2);
break;
case 'c':
emit_function_call (e, 0);
break;
case 's':
def_a = emit_sub_expr (e->e.expr.e1, 0);
def_b = emit_sub_expr (e->e.expr.e2, 0);
emit_statement (e, op_state, def_a, def_b, 0);
break;
case 'b':
emit_bind_expr (e->e.expr.e1, e->e.expr.e2);
break;
case 'g':
def_a = emit_sub_expr (e->e.expr.e1, 0);
def_b = emit_sub_expr (e->e.expr.e2, 0);
emit_statement (e, op_jumpb, def_a, def_b, 0);
break;
default:
warning (e, "Ignoring useless expression");
break;
}
break;
case ex_uexpr:
switch (e->e.expr.op) {
case 'r':
def = 0;
if (e->e.expr.e1)
def = emit_sub_expr (e->e.expr.e1, 0);
emit_statement (e, op_return, def, 0, 0);
break;
case 'g':
emit_branch (e, op_goto, 0, e->e.expr.e1);
break;
default:
warning (e, "useless expression");
emit_expr (e->e.expr.e1);
break;
}
break;
case ex_def:
case ex_temp:
case ex_string:
case ex_float:
case ex_vector:
case ex_entity:
case ex_field:
case ex_func:
case ex_pointer:
case ex_quaternion:
case ex_integer:
case ex_uinteger:
case ex_short:
case ex_name:
case ex_nil:
warning (e, "Ignoring useless expression");
break;
}
free_tempdefs ();
}