quakeforge/tools/qfcc/source/expr.c
Bill Currie 5b1ce309ef [qfcc] Implement multi-vector reversion
For a change, something that's actually general rather than specific to
PGA.
2023-08-28 11:56:35 +09:00

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/*
expr.c
expression construction and manipulations
Copyright (C) 2001 Bill Currie <bill@taniwha.org>
Author: Bill Currie <bill@taniwha.org>
Date: 2001/06/15
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/mathlib.h"
#include "QF/va.h"
#include "tools/qfcc/include/qfcc.h"
#include "tools/qfcc/include/algebra.h"
#include "tools/qfcc/include/class.h"
#include "tools/qfcc/include/def.h"
#include "tools/qfcc/include/defspace.h"
#include "tools/qfcc/include/diagnostic.h"
#include "tools/qfcc/include/emit.h"
#include "tools/qfcc/include/expr.h"
#include "tools/qfcc/include/function.h"
#include "tools/qfcc/include/idstuff.h"
#include "tools/qfcc/include/method.h"
#include "tools/qfcc/include/options.h"
#include "tools/qfcc/include/reloc.h"
#include "tools/qfcc/include/shared.h"
#include "tools/qfcc/include/strpool.h"
#include "tools/qfcc/include/struct.h"
#include "tools/qfcc/include/symtab.h"
#include "tools/qfcc/include/type.h"
#include "tools/qfcc/include/value.h"
#include "tools/qfcc/source/qc-parse.h"
ALLOC_STATE (expr_t, exprs);
void
convert_name (expr_t *e)
{
symbol_t *sym;
expr_t *new;
if (e->type != ex_symbol)
return;
sym = e->e.symbol;
if (!strcmp (sym->name, "__PRETTY_FUNCTION__")
&& current_func) {
new = new_string_expr (current_func->name);
goto convert;
}
if (!strcmp (sym->name, "__FUNCTION__")
&& current_func) {
new = new_string_expr (current_func->def->name);
goto convert;
}
if (!strcmp (sym->name, "__LINE__")
&& current_func) {
new = new_int_expr (e->line);
goto convert;
}
if (!strcmp (sym->name, "__INFINITY__")
&& current_func) {
new = new_float_expr (INFINITY);
goto convert;
}
if (!strcmp (sym->name, "__FILE__")
&& current_func) {
new = new_string_expr (GETSTR (e->file));
goto convert;
}
if (!sym->table) {
error (e, "%s undefined", sym->name);
sym->type = type_default;
//FIXME need a def
return;
}
if (sym->sy_type == sy_convert) {
new = sym->s.convert.conv (sym, sym->s.convert.data);
goto convert;
}
if (sym->sy_type == sy_expr) {
new = copy_expr (sym->s.expr);
goto convert;
}
if (sym->sy_type == sy_type)
internal_error (e, "unexpected typedef");
// var, const and func shouldn't need extra handling
return;
convert:
e->type = new->type;
e->e = new->e;
}
type_t *
get_type (expr_t *e)
{
const type_t *type = 0;
convert_name (e);
switch (e->type) {
case ex_branch:
type = e->e.branch.ret_type;
break;
case ex_labelref:
case ex_adjstk:
case ex_with:
return &type_void;
case ex_memset:
return 0;
case ex_error:
return 0;
case ex_return:
internal_error (e, "unexpected expression type");
case ex_label:
case ex_compound:
return 0;
case ex_bool:
if (options.code.progsversion == PROG_ID_VERSION)
return &type_float;
return &type_int;
case ex_nil:
if (e->e.nil) {
return e->e.nil;
}
// fall through
case ex_state:
return &type_void;
case ex_block:
if (e->e.block.result)
return get_type (e->e.block.result);
return &type_void;
case ex_expr:
case ex_uexpr:
type = e->e.expr.type;
break;
case ex_def:
type = e->e.def->type;
break;
case ex_symbol:
type = e->e.symbol->type;
break;
case ex_temp:
type = e->e.temp.type;
break;
case ex_value:
type = e->e.value->type;
break;
case ex_vector:
return e->e.vector.type;
case ex_selector:
return &type_SEL;
case ex_alias:
type = e->e.alias.type;
break;
case ex_address:
type = e->e.address.type;
break;
case ex_assign:
return get_type (e->e.assign.dst);
case ex_args:
return &type_va_list;
case ex_horizontal:
return e->e.hop.type;
case ex_swizzle:
return e->e.swizzle.type;
case ex_extend:
return e->e.extend.type;
case ex_multivec:
return e->e.multivec.type;
case ex_count:
internal_error (e, "invalid expression");
}
return (type_t *) unalias_type (type);//FIXME cast
}
etype_t
extract_type (expr_t *e)
{
type_t *type = get_type (e);
if (type)
return type->type;
return ev_type_count;
}
expr_t *
type_mismatch (expr_t *e1, expr_t *e2, int op)
{
e1 = error (e1, "type mismatch: %s %s %s",
get_type_string (get_type (e1)), get_op_string (op),
get_type_string (get_type (e2)));
return e1;
}
expr_t *
param_mismatch (expr_t *e, int param, const char *fn, type_t *t1, type_t *t2)
{
e = error (e, "type mismatch for parameter %d of %s: expected %s, got %s",
param, fn, get_type_string (t1), get_type_string (t2));
return e;
}
expr_t *
test_error (expr_t *e, type_t *t)
{
dstring_t *s = dstring_newstr ();
print_type_str (s, t);
e = error (e, "%s cannot be tested", s->str);
dstring_delete (s);
return e;
}
expr_t *
new_expr (void)
{
expr_t *e;
ALLOC (16384, expr_t, exprs, e);
e->line = pr.source_line;
e->file = pr.source_file;
return e;
}
expr_t *
copy_expr (expr_t *e)
{
expr_t *n;
expr_t *t;
if (!e)
return 0;
switch (e->type) {
case ex_error:
case ex_def:
case ex_symbol:
case ex_nil:
case ex_value:
// nothing to do here
n = new_expr ();
*n = *e;
n->line = pr.source_line;
n->file = pr.source_file;
return n;
case ex_state:
return new_state_expr (copy_expr (e->e.state.frame),
copy_expr (e->e.state.think),
copy_expr (e->e.state.step));
case ex_bool:
n = new_expr ();
*n = *e;
n->line = pr.source_line;
n->file = pr.source_file;
if (e->e.boolean.true_list) {
int count = e->e.boolean.true_list->size;
size_t size = (size_t)&((ex_list_t *) 0)->e[count];
n->e.boolean.true_list = malloc (size);
while (count--)
n->e.boolean.true_list->e[count] =
copy_expr (e->e.boolean.true_list->e[count]);
}
if (e->e.boolean.false_list) {
int count = e->e.boolean.false_list->size;
size_t size = (size_t)&((ex_list_t *) 0)->e[count];
n->e.boolean.false_list = malloc (size);
while (count--)
n->e.boolean.false_list->e[count] =
copy_expr (e->e.boolean.false_list->e[count]);
}
n->e.boolean.e = copy_expr (e->e.boolean.e);
return n;
case ex_label:
/// Create a fresh label
return new_label_expr ();
case ex_labelref:
return new_label_ref (e->e.labelref.label);
case ex_block:
n = new_expr ();
*n = *e;
n->line = pr.source_line;
n->file = pr.source_file;
n->e.block.head = 0;
n->e.block.tail = &n->e.block.head;
n->e.block.result = 0;
for (t = e->e.block.head; t; t = t->next) {
if (t == e->e.block.result) {
n->e.block.result = copy_expr (t);
append_expr (n, n->e.block.result);
} else {
append_expr (n, copy_expr (t));
}
}
if (e->e.block.result && !n->e.block.result)
internal_error (e, "bogus block result?");
return n;
case ex_expr:
n = new_expr ();
*n = *e;
n->line = pr.source_line;
n->file = pr.source_file;
n->e.expr.e1 = copy_expr (e->e.expr.e1);
n->e.expr.e2 = copy_expr (e->e.expr.e2);
return n;
case ex_uexpr:
n = new_expr ();
*n = *e;
n->line = pr.source_line;
n->file = pr.source_file;
n->e.expr.e1 = copy_expr (e->e.expr.e1);
return n;
case ex_temp:
n = new_expr ();
*n = *e;
n->line = pr.source_line;
n->file = pr.source_file;
return n;
case ex_vector:
n = new_expr ();
*n = *e;
n->e.vector.type = e->e.vector.type;
n->e.vector.list = copy_expr (e->e.vector.list);
t = e->e.vector.list;
e = n->e.vector.list;
while (t->next) {
e->next = copy_expr (t->next);
e = e->next;
t = t->next;
}
return n;
case ex_selector:
n = new_expr ();
*n = *e;
n->e.selector.sel_ref = copy_expr (e->e.selector.sel_ref);
return n;
case ex_compound:
n = new_expr ();
*n = *e;
for (element_t *i = e->e.compound.head; i; i = i->next) {
append_element (n, new_element (i->expr, i->designator));
}
return n;
case ex_memset:
n = new_expr ();
*n = *e;
n->e.memset.dst = copy_expr (e->e.memset.dst);
n->e.memset.val = copy_expr (e->e.memset.val);
n->e.memset.count = copy_expr (e->e.memset.count);
return n;
case ex_alias:
n = new_expr ();
*n = *e;
n->e.alias.expr = copy_expr (e->e.alias.expr);
n->e.alias.offset = copy_expr (e->e.alias.offset);
return n;
case ex_address:
n = new_expr ();
*n = *e;
n->e.address.lvalue = copy_expr (e->e.address.lvalue);
n->e.address.offset = copy_expr (e->e.address.offset);
return n;
case ex_assign:
n = new_expr ();
*n = *e;
n->e.assign.dst = copy_expr (e->e.assign.dst);
n->e.assign.src = copy_expr (e->e.assign.src);
return n;
case ex_branch:
n = new_expr ();
*n = *e;
n->e.branch.target = copy_expr (e->e.branch.target);
n->e.branch.index = copy_expr (e->e.branch.index);
n->e.branch.test = copy_expr (e->e.branch.test);
n->e.branch.args = copy_expr (e->e.branch.args);
return n;
case ex_return:
n = new_expr ();
*n = *e;
n->e.retrn.ret_val = copy_expr (e->e.retrn.ret_val);
return n;
case ex_adjstk:
n = new_expr ();
*n = *e;
return n;
case ex_with:
n = new_expr ();
*n = *e;
n->e.with.with = copy_expr (e->e.with.with);
return n;
case ex_args:
n = new_expr ();
*n = *e;
return n;
case ex_horizontal:
n = new_expr ();
*n = *e;
e->e.hop.vec = copy_expr (e->e.hop.vec);
return n;
case ex_swizzle:
n = new_expr ();
*n = *e;
e->e.swizzle.src = copy_expr (e->e.swizzle.src);
return n;
case ex_extend:
n = new_expr ();
*n = *e;
e->e.extend.src = copy_expr (e->e.extend.src);
return n;
case ex_multivec:
n = new_expr ();
*n = *e;
n->e.multivec.components = copy_expr (e->e.multivec.components);
t = e->e.multivec.components;
e = n->e.multivec.components;
while (t->next) {
e->next = copy_expr (t->next);
e = e->next;
t = t->next;
}
return n;
case ex_count:
break;
}
internal_error (e, "invalid expression");
}
expr_t *
expr_file_line (expr_t *dst, const expr_t *src)
{
dst->file = src->file;
dst->line = src->line;
return dst;
}
const char *
new_label_name (void)
{
static int label = 0;
int lnum = ++label;
const char *fname = current_func->sym->name;
const char *lname;
lname = save_string (va (0, "$%s_%d", fname, lnum));
return lname;
}
static expr_t *
new_error_expr (void)
{
expr_t *e = new_expr ();
e->type = ex_error;
return e;
}
expr_t *
new_state_expr (expr_t *frame, expr_t *think, expr_t *step)
{
expr_t *s = new_expr ();
s->type = ex_state;
s->e.state.frame = frame;
s->e.state.think = think;
s->e.state.step = step;
return s;
}
expr_t *
new_bool_expr (ex_list_t *true_list, ex_list_t *false_list, expr_t *e)
{
expr_t *b = new_expr ();
b->type = ex_bool;
b->e.boolean.true_list = true_list;
b->e.boolean.false_list = false_list;
b->e.boolean.e = e;
return b;
}
expr_t *
new_label_expr (void)
{
expr_t *l = new_expr ();
l->type = ex_label;
l->e.label.name = new_label_name ();
return l;
}
expr_t *
named_label_expr (symbol_t *label)
{
symbol_t *sym;
expr_t *l;
if (!current_func) {
// XXX this might be only an error
internal_error (0, "label defined outside of function scope");
}
sym = symtab_lookup (current_func->label_scope, label->name);
if (sym) {
return sym->s.expr;
}
l = new_label_expr ();
l->e.label.name = save_string (va (0, "%s_%s", l->e.label.name,
label->name));
l->e.label.symbol = label;
label->sy_type = sy_expr;
label->s.expr = l;
symtab_addsymbol (current_func->label_scope, label);
return label->s.expr;
}
expr_t *
new_label_ref (ex_label_t *label)
{
expr_t *l = new_expr ();
l->type = ex_labelref;
l->e.labelref.label = label;
label->used++;
return l;
}
expr_t *
new_block_expr (void)
{
expr_t *b = new_expr ();
b->type = ex_block;
b->e.block.head = 0;
b->e.block.tail = &b->e.block.head;
b->e.block.return_addr = __builtin_return_address (0);
return b;
}
expr_t *
new_binary_expr (int op, expr_t *e1, expr_t *e2)
{
expr_t *e = new_expr ();
if (e1->type == ex_error)
return e1;
if (e2 && e2->type == ex_error)
return e2;
e->type = ex_expr;
e->e.expr.op = op;
e->e.expr.e1 = e1;
e->e.expr.e2 = e2;
return e;
}
expr_t *
build_block_expr (expr_t *expr_list)
{
expr_t *b = new_block_expr ();
while (expr_list) {
expr_t *e = expr_list;
expr_list = e->next;
e->next = 0;
append_expr (b, e);
}
return b;
}
expr_t *
new_unary_expr (int op, expr_t *e1)
{
expr_t *e = new_expr ();
if (e1 && e1->type == ex_error)
return e1;
e->type = ex_uexpr;
e->e.expr.op = op;
e->e.expr.e1 = e1;
return e;
}
expr_t *
new_horizontal_expr (int op, expr_t *vec, type_t *type)
{
type_t *vec_type = get_type (vec);
if (!vec_type) {
return vec;
}
if (!is_math (vec_type) || is_scalar (vec_type)) {
internal_error (vec, "horizontal operand not a vector type");
}
if (!is_scalar (type)) {
internal_error (vec, "horizontal result not a scalar type");
}
expr_t *e = new_expr ();
e->type = ex_horizontal;
e->e.hop.op = op;
e->e.hop.vec = vec;
e->e.hop.type = type;
return e;
}
expr_t *
new_swizzle_expr (expr_t *src, const char *swizzle)
{
type_t *src_type = get_type (src);
if (!src_type) {
return src;
}
int src_width = type_width (src_type);
// swizzle always generates a *vec4
ex_swizzle_t swiz = {};
#define m(x) (1 << ((x) - 'a'))
#define v(x, mask) (((x) & 0x60) == 0x60 && (m(x) & (mask)))
#define vind(x) ((x) & 3)
#define cind(x) (-(((x) >> 3) ^ (x)) & 3)
#define tind(x) ((((~(x+1)>>2)&1) + x + 1) & 3)
const int color = m('r') | m('g') | m('b') | m('a');
const int vector = m('x') | m('y') | m('z') | m('w');
const int texture = m('s') | m('t') | m('p') | m('q');
int type_mask = 0;
int comp_count = 0;
for (const char *s = swizzle; *s; s++) {
if (comp_count >= 4) {
return error (src, "too many components in swizzle");
}
if (*s == '0') {
swiz.zero |= 1 << comp_count;
comp_count++;
} else if (*s == '-') {
swiz.neg |= 1 << comp_count;
} else {
int ind = 0;
int mask = 0;
if (v (*s, vector)) {
ind = vind (*s);
mask = 1;
} else if (v (*s, color)) {
ind = cind (*s);
mask = 2;
} else if (v (*s, texture)) {
ind = tind (*s);
mask = 4;
}
if (!mask) {
return error (src, "invalid component in swizzle");
}
if (type_mask & ~mask) {
return error (src, "mixed components in swizzle");
}
if (ind >= src_width) {
return error (src, "swizzle component out of bounds");
}
type_mask |= mask;
swiz.source[comp_count++] = ind;
}
}
swiz.zero |= (0xf << comp_count) & 0xf;
swiz.src = new_alias_expr (vector_type (base_type (src_type), src_width), src);
swiz.type = vector_type (base_type (src_type), 4);
expr_t *expr = new_expr ();
expr->type = ex_swizzle;
expr->e.swizzle = swiz;
return expr;
}
expr_t *
new_extend_expr (expr_t *src, type_t *type, int ext, bool rev)
{
expr_t *expr = new_expr ();
expr->type = ex_extend;
expr->e.extend.src = src;
expr->e.extend.extend = ext;
expr->e.extend.reverse = rev;
expr->e.extend.type = type;
return expr;
}
expr_t *
new_def_expr (def_t *def)
{
expr_t *e = new_expr ();
e->type = ex_def;
e->e.def = def;
return e;
}
expr_t *
new_symbol_expr (symbol_t *symbol)
{
expr_t *e = new_expr ();
e->type = ex_symbol;
e->e.symbol = symbol;
return e;
}
expr_t *
new_temp_def_expr (const type_t *type)
{
expr_t *e = new_expr ();
e->type = ex_temp;
e->e.temp.type = (type_t *) unalias_type (type); // FIXME cast
return e;
}
expr_t *
new_nil_expr (void)
{
expr_t *e = new_expr ();
e->type = ex_nil;
return e;
}
expr_t *
new_args_expr (void)
{
expr_t *e = new_expr ();
e->type = ex_args;
return e;
}
expr_t *
new_value_expr (ex_value_t *value)
{
expr_t *e = new_expr ();
e->type = ex_value;
e->e.value = value;
return e;
}
expr_t *
new_zero_expr (type_t *type)
{
pr_type_t zero[type_size (type)] = {};
return new_value_expr (new_type_value (type, zero));
}
expr_t *
new_name_expr (const char *name)
{
expr_t *e = new_expr ();
symbol_t *sym;
sym = symtab_lookup (current_symtab, name);
if (!sym)
sym = new_symbol (name);
e->type = ex_symbol;
e->e.symbol = sym;
return e;
}
expr_t *
new_string_expr (const char *string_val)
{
return new_value_expr (new_string_val (string_val));
}
expr_t *
new_double_expr (double double_val)
{
return new_value_expr (new_double_val (double_val));
}
expr_t *
new_float_expr (float float_val)
{
return new_value_expr (new_float_val (float_val));
}
expr_t *
new_vector_expr (const float *vector_val)
{
return new_value_expr (new_vector_val (vector_val));
}
expr_t *
new_entity_expr (int entity_val)
{
return new_value_expr (new_entity_val (entity_val));
}
expr_t *
new_field_expr (int field_val, type_t *type, def_t *def)
{
return new_value_expr (new_field_val (field_val, type, def));
}
expr_t *
new_func_expr (int func_val, type_t *type)
{
return new_value_expr (new_func_val (func_val, type));
}
expr_t *
new_pointer_expr (int val, type_t *type, def_t *def)
{
return new_value_expr (new_pointer_val (val, type, def, 0));
}
expr_t *
new_quaternion_expr (const float *quaternion_val)
{
return new_value_expr (new_quaternion_val (quaternion_val));
}
expr_t *
new_int_expr (int int_val)
{
return new_value_expr (new_int_val (int_val));
}
expr_t *
new_uint_expr (unsigned uint_val)
{
return new_value_expr (new_uint_val (uint_val));
}
expr_t *
new_long_expr (pr_long_t long_val)
{
return new_value_expr (new_long_val (long_val));
}
expr_t *
new_ulong_expr (pr_ulong_t ulong_val)
{
return new_value_expr (new_ulong_val (ulong_val));
}
expr_t *
new_short_expr (short short_val)
{
return new_value_expr (new_short_val (short_val));
}
int
is_constant (expr_t *e)
{
while (e->type == ex_alias) {
e = e->e.alias.expr;
}
if (e->type == ex_nil || e->type == ex_value || e->type == ex_labelref
|| (e->type == ex_symbol && e->e.symbol->sy_type == sy_const)
|| (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant))
return 1;
return 0;
}
int
is_variable (expr_t *e)
{
while (e->type == ex_alias) {
e = e->e.alias.expr;
}
if (e->type == ex_def
|| (e->type == ex_symbol && e->e.symbol->sy_type == sy_var)
|| e->type == ex_temp) {
return 1;
}
return 0;
}
int
is_selector (expr_t *e)
{
return e->type == ex_selector;
}
expr_t *
constant_expr (expr_t *e)
{
expr_t *new;
symbol_t *sym;
ex_value_t *value;
if (!is_constant (e))
return e;
if (e->type == ex_nil || e->type == ex_value || e->type == ex_labelref)
return e;
if (e->type != ex_symbol)
return e;
sym = e->e.symbol;
if (sym->sy_type == sy_const) {
value = sym->s.value;
} else if (sym->sy_type == sy_var && sym->s.def->constant) {
//FIXME pointers and fields
internal_error (e, "what to do here?");
//memset (&value, 0, sizeof (value));
//memcpy (&value.v, &D_INT (sym->s.def),
//type_size (sym->s.def->type) * sizeof (pr_type_t));
} else {
return e;
}
new = new_value_expr (value);
new->line = e->line;
new->file = e->file;
return new;
}
int
is_nil (expr_t *e)
{
return e->type == ex_nil;
}
int
is_string_val (expr_t *e)
{
if (e->type == ex_nil)
return 1;
if (e->type == ex_value && e->e.value->lltype == ev_string)
return 1;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_string)
return 1;
return 0;
}
const char *
expr_string (expr_t *e)
{
if (e->type == ex_nil)
return 0;
if (e->type == ex_value && e->e.value->lltype == ev_string)
return e->e.value->v.string_val;
internal_error (e, "not a string constant");
}
int
is_float_val (expr_t *e)
{
if (e->type == ex_nil)
return 1;
if (e->type == ex_value && e->e.value->lltype == ev_float)
return 1;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_float)
return 1;
return 0;
}
double
expr_double (expr_t *e)
{
if (e->type == ex_nil)
return 0;
if (e->type == ex_value && e->e.value->lltype == ev_double)
return e->e.value->v.double_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_double)
return e->e.symbol->s.value->v.double_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant
&& is_double (e->e.symbol->s.def->type))
return D_DOUBLE (e->e.symbol->s.def);
internal_error (e, "not a double constant");
}
float
expr_float (expr_t *e)
{
if (e->type == ex_nil)
return 0;
if (e->type == ex_value && e->e.value->lltype == ev_float)
return e->e.value->v.float_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_float)
return e->e.symbol->s.value->v.float_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant
&& is_float (e->e.symbol->s.def->type))
return D_FLOAT (e->e.symbol->s.def);
internal_error (e, "not a float constant");
}
int
is_vector_val (expr_t *e)
{
if (e->type == ex_nil)
return 1;
if (e->type == ex_value && e->e.value->lltype == ev_vector)
return 1;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_vector)
return 1;
return 0;
}
const float *
expr_vector (expr_t *e)
{
if (e->type == ex_nil)
return vec3_origin;
if (e->type == ex_value && e->e.value->lltype == ev_vector)
return e->e.value->v.vector_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_vector)
return e->e.symbol->s.value->v.vector_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant
&& e->e.symbol->s.def->type->type == ev_vector)
return D_VECTOR (e->e.symbol->s.def);
internal_error (e, "not a vector constant");
}
int
is_quaternion_val (expr_t *e)
{
if (e->type == ex_nil)
return 1;
if (e->type == ex_value && e->e.value->lltype == ev_quaternion)
return 1;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_quaternion)
return 1;
return 0;
}
const float *
expr_quaternion (expr_t *e)
{
if (e->type == ex_nil)
return quat_origin;
if (e->type == ex_value && e->e.value->lltype == ev_quaternion)
return e->e.value->v.quaternion_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_quaternion)
return e->e.symbol->s.value->v.quaternion_val;
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant
&& e->e.symbol->s.def->type->type == ev_quaternion)
return D_QUAT (e->e.symbol->s.def);
internal_error (e, "not a quaternion constant");
}
int
is_int_val (expr_t *e)
{
if (e->type == ex_nil) {
return 1;
}
if (e->type == ex_value && e->e.value->lltype == ev_int) {
return 1;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& is_integral (e->e.symbol->type)) {
return 1;
}
if (e->type == ex_def && e->e.def->constant
&& is_integral (e->e.def->type)) {
return 1;
}
return 0;
}
int
expr_int (expr_t *e)
{
if (e->type == ex_nil) {
return 0;
}
if (e->type == ex_value && e->e.value->lltype == ev_int) {
return e->e.value->v.int_val;
}
if (e->type == ex_value && e->e.value->lltype == ev_short) {
return e->e.value->v.short_val;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& (e->e.symbol->type->type == ev_int
|| is_enum (e->e.symbol->type))) {
return e->e.symbol->s.value->v.int_val;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant
&& is_integral (e->e.symbol->s.def->type)) {
return D_INT (e->e.symbol->s.def);
}
if (e->type == ex_def && e->e.def->constant
&& is_integral (e->e.def->type)) {
return D_INT (e->e.def);
}
internal_error (e, "not an int constant");
}
int
is_uint_val (expr_t *e)
{
if (e->type == ex_nil) {
return 1;
}
if (e->type == ex_value && e->e.value->lltype == ev_uint) {
return 1;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& is_integral (e->e.symbol->type)) {
return 1;
}
if (e->type == ex_def && e->e.def->constant
&& is_integral (e->e.def->type)) {
return 1;
}
return 0;
}
unsigned
expr_uint (expr_t *e)
{
if (e->type == ex_nil) {
return 0;
}
if (e->type == ex_value && e->e.value->lltype == ev_uint) {
return e->e.value->v.uint_val;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_uint) {
return e->e.symbol->s.value->v.uint_val;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_var
&& e->e.symbol->s.def->constant
&& is_integral (e->e.symbol->s.def->type)) {
return D_INT (e->e.symbol->s.def);
}
if (e->type == ex_def && e->e.def->constant
&& is_integral (e->e.def->type)) {
return D_INT (e->e.def);
}
internal_error (e, "not an unsigned constant");
}
int
is_short_val (expr_t *e)
{
if (e->type == ex_nil) {
return 1;
}
if (e->type == ex_value && e->e.value->lltype == ev_short) {
return 1;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_short) {
return 1;
}
return 0;
}
short
expr_short (expr_t *e)
{
if (e->type == ex_nil) {
return 0;
}
if (e->type == ex_value && e->e.value->lltype == ev_short) {
return e->e.value->v.short_val;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_short) {
return e->e.symbol->s.value->v.short_val;
}
internal_error (e, "not a short constant");
}
unsigned short
expr_ushort (expr_t *e)
{
if (e->type == ex_nil) {
return 0;
}
if (e->type == ex_value && e->e.value->lltype == ev_ushort) {
return e->e.value->v.ushort_val;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& e->e.symbol->type->type == ev_ushort) {
return e->e.symbol->s.value->v.ushort_val;
}
internal_error (e, "not a ushort constant");
}
int
is_integral_val (expr_t *e)
{
if (is_constant (e)) {
if (is_int_val (e)) {
return 1;
}
if (is_uint_val (e)) {
return 1;
}
if (is_short_val (e)) {
return 1;
}
}
return 0;
}
int
expr_integral (expr_t *e)
{
if (is_constant (e)) {
if (is_int_val (e)) {
return expr_int (e);
}
if (is_uint_val (e)) {
return expr_uint (e);
}
if (is_short_val (e)) {
return expr_short (e);
}
}
internal_error (e, "not an integral constant");
}
int
is_pointer_val (expr_t *e)
{
if (e->type == ex_value && e->e.value->lltype == ev_ptr) {
return 1;
}
return 0;
}
int
is_math_val (expr_t *e)
{
while (e->type == ex_alias) {
e = e->e.alias.expr;
}
if (e->type == ex_value && is_math (e->e.value->type)) {
return 1;
}
if (e->type == ex_symbol && e->e.symbol->sy_type == sy_const
&& is_math (e->e.symbol->s.value->type)) {
return 1;
}
return 0;
}
expr_t *
new_alias_expr (type_t *type, expr_t *expr)
{
if (is_ptr (type) && expr->type == ex_address) {
// avoid aliasing a pointer to a pointer (redundant)
expr = copy_expr (expr);
expr->e.address.type = type;
return expr;
}
if (expr->type == ex_alias) {
if (expr->e.alias.offset) {
return new_offset_alias_expr (type, expr, 0);
}
expr = expr->e.alias.expr;
}
// this can happen when constant folding an offset pointer results in
// a noop due to the offset being 0 and thus casting back to the original
// type
if (type == get_type (expr)) {
return expr;
}
expr_t *alias = new_expr ();
alias->type = ex_alias;
alias->e.alias.type = type;
alias->e.alias.expr = expr;
alias->file = expr->file;
alias->line = expr->line;
return alias;
}
expr_t *
new_offset_alias_expr (type_t *type, expr_t *expr, int offset)
{
if (expr->type == ex_alias && expr->e.alias.offset) {
expr_t *ofs_expr = expr->e.alias.offset;
if (!is_constant (ofs_expr)) {
internal_error (ofs_expr, "non-constant offset for alias expr");
}
offset += expr_int (ofs_expr);
if (expr->e.alias.expr->type == ex_alias) {
internal_error (expr, "alias expr of alias expr");
}
expr = expr->e.alias.expr;
}
expr_t *alias = new_expr ();
alias->type = ex_alias;
alias->e.alias.type = type;
alias->e.alias.expr = expr;
alias->e.alias.offset = new_int_expr (offset);
alias->file = expr->file;
alias->line = expr->line;
return alias;
}
expr_t *
new_address_expr (type_t *lvtype, expr_t *lvalue, expr_t *offset)
{
expr_t *addr = new_expr ();
addr->type = ex_address;
addr->e.address.type = pointer_type (lvtype);
addr->e.address.lvalue = lvalue;
addr->e.address.offset = offset;
return addr;
}
expr_t *
new_assign_expr (expr_t *dst, expr_t *src)
{
expr_t *addr = new_expr ();
addr->type = ex_assign;
addr->e.assign.dst = dst;
addr->e.assign.src = src;
return addr;
}
expr_t *
new_return_expr (expr_t *ret_val)
{
expr_t *retrn = new_expr ();
retrn->type = ex_return;
retrn->e.retrn.ret_val = ret_val;
return retrn;
}
expr_t *
new_adjstk_expr (int mode, int offset)
{
expr_t *adj = new_expr ();
adj->type = ex_adjstk;
adj->e.adjstk.mode = mode;
adj->e.adjstk.offset = offset;
return adj;
}
expr_t *
new_with_expr (int mode, int reg, expr_t *val)
{
expr_t *with = new_expr ();
with->type = ex_with;
with->e.with.mode = mode;
with->e.with.reg = reg;
with->e.with.with = val;
return with;
}
static expr_t *
param_expr (const char *name, type_t *type)
{
symbol_t *sym;
expr_t *sym_expr;
sym = make_symbol (name, &type_param, pr.symtab->space, sc_extern);
if (!sym->table)
symtab_addsymbol (pr.symtab, sym);
sym_expr = new_symbol_expr (sym);
return new_alias_expr (type, sym_expr);
}
expr_t *
new_ret_expr (type_t *type)
{
return param_expr (".return", type);
}
expr_t *
new_param_expr (type_t *type, int num)
{
return param_expr (va (0, ".param_%d", num), type);
}
expr_t *
new_memset_expr (expr_t *dst, expr_t *val, expr_t *count)
{
expr_t *e = new_expr ();
e->type = ex_memset;
e->e.memset.dst = dst;
e->e.memset.val = val;
e->e.memset.count = count;
return e;
}
expr_t *
append_expr (expr_t *block, expr_t *e)
{
if (block->type != ex_block)
internal_error (block, "not a block expression");
if (!e || e->type == ex_error)
return block;
if (e->next)
internal_error (e, "append_expr: expr loop detected");
*block->e.block.tail = e;
block->e.block.tail = &e->next;
return block;
}
expr_t *
prepend_expr (expr_t *block, expr_t *e)
{
if (block->type != ex_block)
internal_error (block, "not a block expression");
if (!e || e->type == ex_error)
return block;
if (e->next)
internal_error (e, "append_expr: expr loop detected");
e->next = block->e.block.head;
block->e.block.head = e;
if (block->e.block.tail == &block->e.block.head) {
block->e.block.tail = &e->next;
}
return block;
}
static symbol_t *
get_struct_field (const type_t *t1, expr_t *e1, expr_t *e2)
{
symtab_t *strct = t1->t.symtab;
symbol_t *sym = e2->e.symbol;//FIXME need to check
symbol_t *field;
if (!strct) {
error (e1, "dereferencing pointer to incomplete type");
return 0;
}
field = symtab_lookup (strct, sym->name);
if (!field && !is_entity(t1)) {
const char *name = t1->name;
if (!strncmp (name, "tag ", 4)) {
name += 4;
}
error (e2, "'%s' has no member named '%s'", name, sym->name);
e1->type = ex_error;
}
return field;
}
expr_t *
field_expr (expr_t *e1, expr_t *e2)
{
const type_t *t1, *t2;
expr_t *e;
t1 = get_type (e1);
if (e1->type == ex_error)
return e1;
if (is_entity (t1)) {
symbol_t *field = 0;
if (e2->type == ex_symbol)
field = get_struct_field (&type_entity, e1, e2);
if (field) {
e2 = new_field_expr (0, field->type, field->s.def);
e = new_binary_expr ('.', e1, e2);
e->e.expr.type = field->type;
return e;
} else {
t2 = get_type (e2);
if (e2->type == ex_error)
return e2;
if (t2->type == ev_field) {
e = new_binary_expr ('.', e1, e2);
e->e.expr.type = t2->t.fldptr.type;
return e;
}
}
} else if (is_ptr (t1)) {
if (is_struct (t1->t.fldptr.type) || is_union (t1->t.fldptr.type)) {
symbol_t *field;
field = get_struct_field (t1->t.fldptr.type, e1, e2);
if (!field)
return e1;
expr_t *offset = new_short_expr (field->s.offset);
e1 = offset_pointer_expr (e1, offset);
e1 = cast_expr (pointer_type (field->type), e1);
return unary_expr ('.', e1);
} else if (is_class (t1->t.fldptr.type)) {
class_t *class = t1->t.fldptr.type->t.class;
symbol_t *sym = e2->e.symbol;//FIXME need to check
symbol_t *ivar;
int protected = class_access (current_class, class);
ivar = class_find_ivar (class, protected, sym->name);
if (!ivar)
return new_error_expr ();
expr_t *offset = new_short_expr (ivar->s.offset);
e1 = offset_pointer_expr (e1, offset);
e1 = cast_expr (pointer_type (ivar->type), e1);
return unary_expr ('.', e1);
}
} else if (is_nonscalar (t1) || is_struct (t1) || is_union (t1)) {
symbol_t *field;
field = get_struct_field (t1, e1, e2);
if (!field)
return e1;
if (e1->type == ex_expr && e1->e.expr.op == '.'
&& is_entity(get_type (e1->e.expr.e1))) {
// undo the . expression
e2 = e1->e.expr.e2;
e1 = e1->e.expr.e1;
// offset the field expresion
if (e2->type == ex_symbol) {
symbol_t *sym;
def_t *def;
sym = symtab_lookup (pr.entity_fields, e2->e.symbol->name);
if (!sym) {
internal_error (e2, "failed to find entity field %s",
e2->e.symbol->name);
}
def = sym->s.def;
e2 = new_field_expr (0, field->type, def);
} else if (e2->type != ex_value
|| e2->e.value->lltype != ev_field) {
internal_error (e2, "unexpected field exression");
}
e2->e.value = new_field_val (e2->e.value->v.pointer.val + field->s.offset, field->type, e2->e.value->v.pointer.def);
// create a new . expression
return field_expr (e1, e2);
} else {
if (e1->type == ex_uexpr && e1->e.expr.op == '.') {
expr_t *offset = new_short_expr (field->s.offset);
e1 = offset_pointer_expr (e1->e.expr.e1, offset);
e1 = cast_expr (pointer_type (field->type), e1);
return unary_expr ('.', e1);
} else {
return new_offset_alias_expr (field->type, e1, field->s.offset);
}
}
} else if (is_class (t1)) {
//Class instance variables aren't allowed and thus declaring one
//is treated as an error, so this is a follow-on error.
return error (e1, "class instance access");
}
return type_mismatch (e1, e2, '.');
}
expr_t *
convert_from_bool (expr_t *e, type_t *type)
{
expr_t *zero;
expr_t *one;
expr_t *cond;
if (is_float (type)) {
one = new_float_expr (1);
zero = new_float_expr (0);
} else if (is_int (type)) {
one = new_int_expr (1);
zero = new_int_expr (0);
} else if (is_enum (type) && enum_as_bool (type, &zero, &one)) {
// don't need to do anything
} else if (is_uint (type)) {
one = new_uint_expr (1);
zero = new_uint_expr (0);
} else {
return error (e, "can't convert from boolean value");
}
cond = new_expr ();
*cond = *e;
cond->next = 0;
cond = conditional_expr (cond, one, zero);
e->type = cond->type;
e->e = cond->e;
return e;
}
expr_t *
convert_nil (expr_t *e, type_t *t)
{
e->e.nil = t;
return e;
}
int
is_compare (int op)
{
if (op == EQ || op == NE || op == LE || op == GE || op == LT || op == GT
|| op == '>' || op == '<')
return 1;
return 0;
}
int
is_math_op (int op)
{
if (op == '*' || op == '/' || op == '+' || op == '-')
return 1;
return 0;
}
int
is_logic (int op)
{
if (op == OR || op == AND)
return 1;
return 0;
}
int
has_function_call (expr_t *e)
{
switch (e->type) {
case ex_bool:
return has_function_call (e->e.boolean.e);
case ex_block:
if (e->e.block.is_call)
return 1;
for (e = e->e.block.head; e; e = e->next)
if (has_function_call (e))
return 1;
return 0;
case ex_expr:
return (has_function_call (e->e.expr.e1)
|| has_function_call (e->e.expr.e2));
case ex_uexpr:
return has_function_call (e->e.expr.e1);
case ex_alias:
return has_function_call (e->e.alias.expr);
case ex_address:
return has_function_call (e->e.address.lvalue);
case ex_assign:
return (has_function_call (e->e.assign.dst)
|| has_function_call (e->e.assign.src));
case ex_branch:
if (e->e.branch.type == pr_branch_call) {
return 1;
}
if (e->e.branch.type == pr_branch_jump) {
return 0;
}
return has_function_call (e->e.branch.test);
case ex_return:
return has_function_call (e->e.retrn.ret_val);
case ex_horizontal:
return has_function_call (e->e.hop.vec);
case ex_swizzle:
return has_function_call (e->e.swizzle.src);
case ex_extend:
return has_function_call (e->e.extend.src);
case ex_error:
case ex_state:
case ex_label:
case ex_labelref:
case ex_def:
case ex_symbol:
case ex_temp:
case ex_vector:
case ex_selector:
case ex_nil:
case ex_value:
case ex_compound:
case ex_memset:
case ex_adjstk:
case ex_with:
case ex_args:
return 0;
case ex_multivec:
for (auto c = e->e.multivec.components; c; c = c->next) {
if (has_function_call (c)) {
return 1;
}
}
return 0;
case ex_count:
break;
}
internal_error (e, "invalid expression type");
}
int
is_function_call (expr_t *e)
{
if (e->type != ex_block || !e->e.block.is_call) {
return 0;
}
e = e->e.block.result;
return e->type == ex_branch && e->e.branch.type == pr_branch_call;
}
expr_t *
asx_expr (int op, expr_t *e1, expr_t *e2)
{
if (e1->type == ex_error)
return e1;
else if (e2->type == ex_error)
return e2;
else {
expr_t *e = new_expr ();
*e = *e1;
e2->paren = 1;
return assign_expr (e, binary_expr (op, e1, e2));
}
}
expr_t *
unary_expr (int op, expr_t *e)
{
vec3_t v;
quat_t q;
const char *s;
expr_t *new;
type_t *t;
convert_name (e);
if (e->type == ex_error)
return e;
switch (op) {
case '-':
if (!is_math (get_type (e)))
return error (e, "invalid type for unary -");
if (is_constant (e)) {
switch (extract_type (e)) {
case ev_string:
case ev_entity:
case ev_field:
case ev_func:
case ev_ptr:
internal_error (e, "type check failed!");
case ev_double:
new = new_double_expr (-expr_double (e));
new->implicit = e->implicit;
return new;
case ev_float:
return new_float_expr (-expr_float (e));
case ev_vector:
VectorNegate (expr_vector (e), v);
return new_vector_expr (v);
case ev_quaternion:
QuatNegate (expr_vector (e), q);
return new_vector_expr (q);
case ev_long:
case ev_ulong:
case ev_ushort:
internal_error (e, "long not implemented");
case ev_int:
return new_int_expr (-expr_int (e));
case ev_uint:
return new_uint_expr (-expr_uint (e));
case ev_short:
return new_short_expr (-expr_short (e));
case ev_invalid:
case ev_type_count:
case ev_void:
break;
}
internal_error (e, "weird expression type");
}
switch (e->type) {
case ex_value: // should be handled above
case ex_error:
case ex_label:
case ex_labelref:
case ex_state:
case ex_compound:
case ex_memset:
case ex_selector:
case ex_return:
case ex_adjstk:
case ex_with:
case ex_args:
internal_error (e, "unexpected expression type");
case ex_uexpr:
if (e->e.expr.op == '-') {
return e->e.expr.e1;
}
{
expr_t *n = new_unary_expr (op, e);
n->e.expr.type = get_type (e);
return n;
}
case ex_block:
if (!e->e.block.result) {
return error (e, "invalid type for unary -");
}
{
expr_t *n = new_unary_expr (op, e);
n->e.expr.type = get_type (e);
return n;
}
case ex_branch:
return error (e, "invalid type for unary -");
case ex_expr:
case ex_bool:
case ex_temp:
case ex_vector:
case ex_alias:
case ex_assign:
case ex_horizontal:
case ex_swizzle:
case ex_extend:
{
expr_t *n = new_unary_expr (op, e);
n->e.expr.type = get_type (e);
return n;
}
case ex_def:
{
expr_t *n = new_unary_expr (op, e);
n->e.expr.type = e->e.def->type;
return n;
}
case ex_symbol:
{
expr_t *n = new_unary_expr (op, e);
n->e.expr.type = e->e.symbol->type;
return n;
}
case ex_multivec:
return algebra_negate (e);
case ex_nil:
case ex_address:
return error (e, "invalid type for unary -");
case ex_count:
internal_error (e, "invalid expression");
}
break;
case '!':
if (is_constant (e)) {
switch (extract_type (e)) {
case ev_entity:
case ev_field:
case ev_func:
case ev_ptr:
internal_error (e, 0);
case ev_string:
s = expr_string (e);
return new_int_expr (!s || !s[0]);
case ev_double:
return new_int_expr (!expr_double (e));
case ev_float:
return new_int_expr (!expr_float (e));
case ev_vector:
return new_int_expr (!VectorIsZero (expr_vector (e)));
case ev_quaternion:
return new_int_expr (!QuatIsZero (expr_quaternion (e)));
case ev_long:
case ev_ulong:
case ev_ushort:
internal_error (e, "long not implemented");
case ev_int:
return new_int_expr (!expr_int (e));
case ev_uint:
return new_uint_expr (!expr_uint (e));
case ev_short:
return new_short_expr (!expr_short (e));
case ev_invalid:
case ev_type_count:
case ev_void:
break;
}
internal_error (e, "weird expression type");
}
switch (e->type) {
case ex_value: // should be handled above
case ex_error:
case ex_label:
case ex_labelref:
case ex_state:
case ex_compound:
case ex_memset:
case ex_selector:
case ex_return:
case ex_adjstk:
case ex_with:
case ex_args:
internal_error (e, "unexpected expression type");
case ex_bool:
return new_bool_expr (e->e.boolean.false_list,
e->e.boolean.true_list, e);
case ex_block:
if (!e->e.block.result)
return error (e, "invalid type for unary !");
case ex_uexpr:
case ex_expr:
case ex_def:
case ex_symbol:
case ex_temp:
case ex_vector:
case ex_alias:
case ex_address:
case ex_assign:
case ex_horizontal:
case ex_swizzle:
case ex_extend:
if (options.code.progsversion == PROG_VERSION) {
return binary_expr (EQ, e, new_nil_expr ());
} else {
expr_t *n = new_unary_expr (op, e);
if (options.code.progsversion > PROG_ID_VERSION)
n->e.expr.type = &type_int;
else
n->e.expr.type = &type_float;
return n;
}
case ex_multivec:
return algebra_dual (e);
case ex_branch:
case ex_nil:
return error (e, "invalid type for unary !");
case ex_count:
internal_error (e, "invalid expression");
}
break;
case '~':
if (is_constant (e)) {
switch (extract_type (e)) {
case ev_string:
case ev_entity:
case ev_field:
case ev_func:
case ev_ptr:
case ev_vector:
case ev_double:
return error (e, "invalid type for unary ~");
case ev_float:
return new_float_expr (~(int) expr_float (e));
case ev_quaternion:
QuatConj (expr_vector (e), q);
return new_vector_expr (q);
case ev_long:
case ev_ulong:
case ev_ushort:
internal_error (e, "long not implemented");
case ev_int:
return new_int_expr (~expr_int (e));
case ev_uint:
return new_uint_expr (~expr_uint (e));
case ev_short:
return new_short_expr (~expr_short (e));
case ev_invalid:
t = get_type (e);
if (t->meta == ty_enum) {
return new_int_expr (~expr_int (e));
}
break;
case ev_type_count:
case ev_void:
break;
}
internal_error (e, "weird expression type");
}
switch (e->type) {
case ex_value: // should be handled above
case ex_error:
case ex_label:
case ex_labelref:
case ex_state:
case ex_compound:
case ex_memset:
case ex_selector:
case ex_return:
case ex_adjstk:
case ex_with:
case ex_args:
internal_error (e, "unexpected expression type");
case ex_uexpr:
if (e->e.expr.op == '~')
return e->e.expr.e1;
goto bitnot_expr;
case ex_block:
if (!e->e.block.result)
return error (e, "invalid type for unary ~");
goto bitnot_expr;
case ex_branch:
return error (e, "invalid type for unary ~");
case ex_expr:
case ex_bool:
case ex_def:
case ex_symbol:
case ex_temp:
case ex_vector:
case ex_alias:
case ex_assign:
case ex_horizontal:
case ex_swizzle:
case ex_extend:
bitnot_expr:
if (options.code.progsversion == PROG_ID_VERSION) {
expr_t *n1 = new_int_expr (-1);
return binary_expr ('-', n1, e);
} else {
expr_t *n = new_unary_expr (op, e);
type_t *t = get_type (e);
if (!is_int(t) && !is_float(t)
&& !is_quaternion(t))
return error (e, "invalid type for unary ~");
n->e.expr.type = t;
return n;
}
case ex_multivec:
return algebra_reverse (e);
case ex_nil:
case ex_address:
return error (e, "invalid type for unary ~");
case ex_count:
internal_error (e, "invalid expression");
}
break;
case '.':
if (extract_type (e) != ev_ptr)
return error (e, "invalid type for unary .");
e = new_unary_expr ('.', e);
e->e.expr.type = get_type (e->e.expr.e1)->t.fldptr.type;
return e;
case '+':
if (!is_math (get_type (e)))
return error (e, "invalid type for unary +");
return e;
case REVERSE:
return algebra_reverse (e);
}
internal_error (e, 0);
}
expr_t *
build_function_call (expr_t *fexpr, const type_t *ftype, expr_t *params)
{
expr_t *e;
expr_t *p;
int arg_count = 0, param_count = 0;
int i;
expr_t *args = 0, **a = &args;
int arg_expr_count = 0;
int emit_args = 0;
expr_t *assign;
expr_t *call;
expr_t *err = 0;
for (e = params; e; e = e->next) {
if (e->type == ex_error)
return e;
arg_count++;
}
if (options.code.progsversion < PROG_VERSION
&& arg_count > PR_MAX_PARAMS) {
return error (fexpr, "more than %d parameters", PR_MAX_PARAMS);
}
type_t *arg_types[arg_count];
expr_t *arg_exprs[arg_count][2];
if (ftype->t.func.num_params < -1) {
if (-arg_count > ftype->t.func.num_params + 1) {
if (!options.traditional)
return error (fexpr, "too few arguments");
if (options.warnings.traditional)
warning (fexpr, "too few arguments");
}
param_count = -ftype->t.func.num_params - 1;
} else if (ftype->t.func.num_params >= 0) {
if (arg_count > ftype->t.func.num_params) {
return error (fexpr, "too many arguments");
} else if (arg_count < ftype->t.func.num_params) {
if (!options.traditional)
return error (fexpr, "too few arguments");
if (options.warnings.traditional)
warning (fexpr, "too few arguments");
}
param_count = ftype->t.func.num_params;
}
if (ftype->t.func.num_params < 0) {
emit_args = !ftype->t.func.no_va_list;
}
// params is reversed (a, b, c) -> c, b, a
for (i = arg_count - 1, e = params; i >= 0; i--, e = e->next) {
type_t *t;
if (e->type == ex_compound) {
if (i < param_count) {
t = ftype->t.func.param_types[i];
} else {
return error (e, "cannot pass compound initializer "
"through ...");
}
} else {
t = get_type (e);
}
if (!t) {
return e;
}
if (!type_size (t)) {
err = error (e, "type of formal parameter %d is incomplete",
i + 1);
}
if (!is_array (t) && value_too_large (t)) {
err = error (e, "formal parameter %d is too large to be passed by"
" value", i + 1);
}
if (i < param_count) {
if (e->type == ex_nil)
convert_nil (e, t = ftype->t.func.param_types[i]);
if (e->type == ex_bool)
convert_from_bool (e, ftype->t.func.param_types[i]);
if (e->type == ex_error)
return e;
if (!type_assignable (ftype->t.func.param_types[i], t)) {
err = param_mismatch (e, i + 1, fexpr->e.symbol->name,
ftype->t.func.param_types[i], t);
}
t = ftype->t.func.param_types[i];
} else {
if (e->type == ex_nil)
convert_nil (e, t = type_nil);
if (e->type == ex_bool)
convert_from_bool (e, get_type (e));
if (is_int_val (e)
&& options.code.progsversion == PROG_ID_VERSION)
e = cast_expr (&type_float, e);
if (options.code.promote_float) {
if (is_scalar (get_type (e)) && is_float (get_type (e))) {
t = &type_double;
}
} else {
if (is_scalar (get_type (e)) && is_double (get_type (e))) {
if (!e->implicit) {
warning (e, "passing double into ... function");
}
if (is_constant (e)) {
// don't auto-demote non-constant doubles
t = &type_float;
}
}
}
if (is_int_val (e) && options.warnings.vararg_integer)
warning (e, "passing int constant into ... function");
}
arg_types[arg_count - 1 - i] = t;
}
if (err)
return err;
call = expr_file_line (new_block_expr (), fexpr);
call->e.block.is_call = 1;
// args is built in reverse order so it matches params
for (p = params, i = 0; p; p = p->next, i++) {
if (emit_args && arg_count - i == param_count) {
emit_args = 0;
*a = new_args_expr ();
a = &(*a)->next;
}
expr_t *e = p;
if (e->type == ex_compound) {
e = expr_file_line (initialized_temp_expr (arg_types[i], e), e);
}
// FIXME this is target-specific info and should not be in the
// expression tree
// That, or always use a temp, since it should get optimized out
if (has_function_call (e)) {
expr_t *cast = cast_expr (arg_types[i], e);
expr_t *tmp = new_temp_def_expr (arg_types[i]);
*a = expr_file_line (tmp, e);
arg_exprs[arg_expr_count][0] = expr_file_line (cast, e);
arg_exprs[arg_expr_count][1] = *a;
arg_expr_count++;
} else {
*a = expr_file_line (cast_expr (arg_types[i], e), e);
}
a = &(*a)->next;
}
if (emit_args) {
emit_args = 0;
*a = new_args_expr ();
a = &(*a)->next;
}
for (i = 0; i < arg_expr_count - 1; i++) {
assign = assign_expr (arg_exprs[i][1], arg_exprs[i][0]);
append_expr (call, expr_file_line (assign, arg_exprs[i][0]));
}
if (arg_expr_count) {
e = assign_expr (arg_exprs[arg_expr_count - 1][1],
arg_exprs[arg_expr_count - 1][0]);
e = expr_file_line (e, arg_exprs[arg_expr_count - 1][0]);
append_expr (call, e);
}
e = expr_file_line (call_expr (fexpr, args, ftype->t.func.type), fexpr);
call->e.block.result = e;
return call;
}
expr_t *
function_expr (expr_t *fexpr, expr_t *params)
{
type_t *ftype;
find_function (fexpr, params);
ftype = get_type (fexpr);
if (fexpr->type == ex_error)
return fexpr;
if (ftype->type != ev_func) {
if (fexpr->type == ex_symbol)
return error (fexpr, "Called object \"%s\" is not a function",
fexpr->e.symbol->name);
else
return error (fexpr, "Called object is not a function");
}
if (fexpr->type == ex_symbol && params && is_string_val (params)) {
// FIXME eww, I hate this, but it's needed :(
// FIXME make a qc hook? :)
if (strncmp (fexpr->e.symbol->name, "precache_sound", 14) == 0)
PrecacheSound (expr_string (params), fexpr->e.symbol->name[14]);
else if (strncmp (fexpr->e.symbol->name, "precache_model", 14) == 0)
PrecacheModel (expr_string (params), fexpr->e.symbol->name[14]);
else if (strncmp (fexpr->e.symbol->name, "precache_file", 13) == 0)
PrecacheFile (expr_string (params), fexpr->e.symbol->name[13]);
}
return build_function_call (fexpr, ftype, params);
}
expr_t *
branch_expr (int op, expr_t *test, expr_t *label)
{
// need to translated op due to precedence rules dictating the layout
// of the token ids
static pr_branch_e branch_type [] = {
pr_branch_eq,
pr_branch_ne,
pr_branch_lt,
pr_branch_gt,
pr_branch_le,
pr_branch_ge,
};
if (op < EQ || op > LE) {
internal_error (label, "invalid op: %d", op);
}
if (label && label->type != ex_label) {
internal_error (label, "not a label");
}
if (label) {
label->e.label.used++;
}
expr_t *branch = new_expr ();
branch->type = ex_branch;
branch->e.branch.type = branch_type[op - EQ];
branch->e.branch.target = label;
branch->e.branch.test = test;
return branch;
}
expr_t *
goto_expr (expr_t *label)
{
if (label && label->type != ex_label) {
internal_error (label, "not a label");
}
if (label) {
label->e.label.used++;
}
expr_t *branch = new_expr ();
branch->type = ex_branch;
branch->e.branch.type = pr_branch_jump;
branch->e.branch.target = label;
return branch;
}
expr_t *
jump_table_expr (expr_t *table, expr_t *index)
{
expr_t *branch = new_expr ();
branch->type = ex_branch;
branch->e.branch.type = pr_branch_jump;
branch->e.branch.target = table;//FIXME separate? all branch types can
branch->e.branch.index = index;
return branch;
}
expr_t *
call_expr (expr_t *func, expr_t *args, type_t *ret_type)
{
expr_t *branch = new_expr ();
branch->type = ex_branch;
branch->e.branch.type = pr_branch_call;
branch->e.branch.target = func;
branch->e.branch.args = args;
branch->e.branch.ret_type = ret_type;
return branch;
}
expr_t *
return_expr (function_t *f, expr_t *e)
{
const type_t *t;
const type_t *ret_type = unalias_type (f->type->t.func.type);
if (!e) {
if (!is_void(ret_type)) {
if (options.traditional) {
if (options.warnings.traditional)
warning (e,
"return from non-void function without a value");
// force a nil return value in case qf code is being generated
e = new_nil_expr ();
} else {
e = error (e, "return from non-void function without a value");
return e;
}
}
// the traditional check above may have set e
if (!e) {
return new_return_expr (0);
}
}
if (e->type == ex_compound) {
e = expr_file_line (initialized_temp_expr (ret_type, e), e);
}
t = get_type (e);
if (!t) {
return e;
}
if (is_void(ret_type)) {
if (!options.traditional)
return error (e, "returning a value for a void function");
if (options.warnings.traditional)
warning (e, "returning a value for a void function");
}
if (e->type == ex_bool) {
e = convert_from_bool (e, (type_t *) ret_type); //FIXME cast
}
if (is_float(ret_type) && is_int_val (e)) {
e = cast_expr (&type_float, e);
t = &type_float;
}
if (is_void(t)) {
if (e->type == ex_nil) {
t = ret_type;
convert_nil (e, (type_t *) t);//FIXME cast
} else {
if (!options.traditional)
return error (e, "void value not ignored as it ought to be");
if (options.warnings.traditional)
warning (e, "void value not ignored as it ought to be");
//FIXME does anything need to be done here?
}
}
if (!type_assignable (ret_type, t)) {
if (!options.traditional)
return error (e, "type mismatch for return value of %s: %s -> %s",
f->sym->name, get_type_string (t),
get_type_string (ret_type));
if (options.warnings.traditional)
warning (e, "type mismatch for return value of %s",
f->sym->name);
} else {
if (ret_type != t) {
e = cast_expr ((type_t *) ret_type, e);//FIXME cast
t = f->sym->type->t.func.type;
}
}
if (e->type == ex_vector) {
e = assign_expr (new_temp_def_expr (t), e);
}
if (e->type == ex_block) {
e->e.block.result->rvalue = 1;
}
return new_return_expr (e);
}
expr_t *
at_return_expr (function_t *f, expr_t *e)
{
const type_t *ret_type = unalias_type (f->type->t.func.type);
if (!is_void(ret_type)) {
return error (e, "use of @return in non-void function");
}
if (is_nil (e)) {
// int or pointer 0 seems reasonable
return new_return_expr (new_int_expr (0));
} else if (!is_function_call (e)) {
return error (e, "@return value not a function");
}
expr_t *call_expr = e->e.block.result->e.branch.target;
const type_t *call_type = get_type (call_expr);
if (!is_func (call_type) && !call_type->t.func.void_return) {
return error (e, "@return function not void_return");
}
expr_t *ret_expr = new_return_expr (e);
ret_expr->e.retrn.at_return = 1;
return ret_expr;
}
expr_t *
conditional_expr (expr_t *cond, expr_t *e1, expr_t *e2)
{
expr_t *block = new_block_expr ();
type_t *type1 = get_type (e1);
type_t *type2 = get_type (e2);
expr_t *tlabel = new_label_expr ();
expr_t *flabel = new_label_expr ();
expr_t *elabel = new_label_expr ();
if (cond->type == ex_error)
return cond;
if (e1->type == ex_error)
return e1;
if (e2->type == ex_error)
return e2;
cond = convert_bool (cond, 1);
if (cond->type == ex_error)
return cond;
backpatch (cond->e.boolean.true_list, tlabel);
backpatch (cond->e.boolean.false_list, flabel);
block->e.block.result = (type1 == type2) ? new_temp_def_expr (type1) : 0;
append_expr (block, cond);
append_expr (cond->e.boolean.e, flabel);
if (block->e.block.result)
append_expr (block, assign_expr (block->e.block.result, e2));
else
append_expr (block, e2);
append_expr (block, goto_expr (elabel));
append_expr (block, tlabel);
if (block->e.block.result)
append_expr (block, assign_expr (block->e.block.result, e1));
else
append_expr (block, e1);
append_expr (block, elabel);
return block;
}
expr_t *
incop_expr (int op, expr_t *e, int postop)
{
expr_t *one;
if (e->type == ex_error)
return e;
one = new_int_expr (1); // int constants get auto-cast to float
if (postop) {
expr_t *t1, *t2;
type_t *type = get_type (e);
expr_t *block = new_block_expr ();
expr_t *res = new_expr ();
if (e->type == ex_error) // get_type failed
return e;
t1 = new_temp_def_expr (type);
t2 = new_temp_def_expr (type);
append_expr (block, assign_expr (t1, e));
append_expr (block, assign_expr (t2, binary_expr (op, t1, one)));
res = copy_expr (e);
if (res->type == ex_uexpr && res->e.expr.op == '.')
res = deref_pointer_expr (address_expr (res, 0));
append_expr (block, assign_expr (res, t2));
block->e.block.result = t1;
return block;
} else {
return asx_expr (op, e, one);
}
}
expr_t *
array_expr (expr_t *array, expr_t *index)
{
type_t *array_type = get_type (array);
type_t *index_type = get_type (index);
type_t *ele_type;
expr_t *scale;
expr_t *offset;
expr_t *base;
expr_t *ptr;
expr_t *e;
int ind = 0;
if (array->type == ex_error)
return array;
if (index->type == ex_error)
return index;
if (!is_ptr (array_type) && !is_array (array_type)
&& !is_nonscalar (array_type))
return error (array, "not an array");
if (!is_integral (index_type))
return error (index, "invalid array index type");
if (is_short_val (index))
ind = expr_short (index);
if (is_int_val (index))
ind = expr_int (index);
if (is_array (array_type)
&& array_type->t.array.size
&& is_constant (index)
&& (ind < array_type->t.array.base
|| ind - array_type->t.array.base >= array_type->t.array.size)) {
return error (index, "array index out of bounds");
}
if (is_nonscalar (array_type)
&& is_constant (index)
&& (ind < 0 || ind >= array_type->width)) {
return error (index, "array index out of bounds");
}
if (is_array (array_type)) {
ele_type = array_type->t.array.type;
base = new_int_expr (array_type->t.array.base);
} else if (is_ptr (array_type)) {
ele_type = array_type->t.fldptr.type;
base = new_int_expr (0);
} else {
ele_type = ev_types[array_type->type];
if (array->type == ex_uexpr && array->e.expr.op == '.') {
expr_t *vec = offset_pointer_expr (array->e.expr.e1, index);
vec = cast_expr (pointer_type (ele_type), vec);
return unary_expr ('.', vec);
}
base = new_int_expr (0);
}
scale = new_int_expr (type_size (ele_type));
index = binary_expr ('*', index, scale);
offset = binary_expr ('*', base, scale);
index = binary_expr ('-', index, offset);
if (is_short_val (index))
ind = expr_short (index);
if (is_int_val (index))
ind = expr_int (index);
if (is_array (array_type)) {
if (array->type == ex_uexpr && array->e.expr.op == '.') {
ptr = array->e.expr.e1;
} else {
expr_t *alias = new_offset_alias_expr (ele_type, array, 0);
ptr = new_address_expr (ele_type, alias, 0);
}
} else if (is_nonscalar (array_type)) {
expr_t *alias = new_offset_alias_expr (ele_type, array, 0);
ptr = new_address_expr (ele_type, alias, 0);
} else {
ptr = array;
}
ptr = offset_pointer_expr (ptr, index);
ptr = cast_expr (pointer_type (ele_type), ptr);
e = unary_expr ('.', ptr);
return e;
}
expr_t *
deref_pointer_expr (expr_t *pointer)
{
type_t *pointer_type = get_type (pointer);
if (pointer->type == ex_error)
return pointer;
if (pointer_type->type != ev_ptr)
return error (pointer, "not a pointer");
return unary_expr ('.', pointer);
}
expr_t *
offset_pointer_expr (expr_t *pointer, expr_t *offset)
{
type_t *ptr_type = get_type (pointer);
if (!is_ptr (ptr_type)) {
internal_error (pointer, "not a pointer");
}
if (!is_integral (get_type (offset))) {
internal_error (offset, "pointer offset is not an integer type");
}
expr_t *ptr;
if (pointer->type == ex_alias && !pointer->e.alias.offset
&& is_integral (get_type (pointer->e.alias.expr))) {
ptr = pointer->e.alias.expr;
} else if (pointer->type == ex_address && is_constant (offset)) {
if (pointer->e.address.offset) {
offset = binary_expr ('+', pointer->e.address.offset, offset);
}
pointer->e.address.offset = offset;
return pointer;
} else {
ptr = cast_expr (&type_int, pointer);
}
ptr = binary_expr ('+', ptr, offset);
return cast_expr (ptr_type, ptr);
}
expr_t *
address_expr (expr_t *e1, type_t *t)
{
expr_t *e;
if (e1->type == ex_error)
return e1;
if (!t)
t = get_type (e1);
switch (e1->type) {
case ex_def:
{
def_t *def = e1->e.def;
type_t *type = def->type;
//FIXME this test should be in statements.c
if (options.code.progsversion == PROG_VERSION
&& (def->local || def->param)) {
e = new_address_expr (t, e1, 0);
return e;
}
if (is_array (type)) {
e = e1;
e->type = ex_value;
e->e.value = new_pointer_val (0, t, def, 0);
} else {
e = new_pointer_expr (0, t, def);
e->line = e1->line;
e->file = e1->file;
}
}
break;
case ex_symbol:
if (e1->e.symbol->sy_type == sy_var) {
def_t *def = e1->e.symbol->s.def;
type_t *type = def->type;
//FIXME this test should be in statements.c
if (options.code.progsversion == PROG_VERSION
&& (def->local || def->param)) {
e = new_address_expr (t, e1, 0);
return e;
}
if (is_array (type)) {
e = e1;
e->type = ex_value;
e->e.value = new_pointer_val (0, t, def, 0);
} else {
e = new_pointer_expr (0, t, def);
e->line = e1->line;
e->file = e1->file;
}
break;
}
return error (e1, "invalid type for unary &");
case ex_expr:
if (e1->e.expr.op == '.') {
e = new_address_expr (e1->e.expr.type,
e1->e.expr.e1, e1->e.expr.e2);
break;
}
return error (e1, "invalid type for unary &");
case ex_uexpr:
if (e1->e.expr.op == '.') {
e = e1->e.expr.e1;
if (e->type == ex_expr && e->e.expr.op == '.') {
e = new_address_expr (e->e.expr.type, e->e.expr.e1, e->e.expr.e2);
}
break;
}
return error (e1, "invalid type for unary &");
case ex_label:
return new_label_ref (&e1->e.label);
case ex_temp:
e = new_address_expr (t, e1, 0);
break;
case ex_alias:
if (!t) {
t = e1->e.alias.type;
}
return new_address_expr (t, e1, 0);
default:
return error (e1, "invalid type for unary &");
}
return e;
}
expr_t *
build_if_statement (int not, expr_t *test, expr_t *s1, expr_t *els, expr_t *s2)
{
int line = pr.source_line;
pr_string_t file = pr.source_file;
expr_t *if_expr;
expr_t *tl = new_label_expr ();
expr_t *fl = new_label_expr ();
if (els && !s2) {
warning (els,
"suggest braces around empty body in an ‘else’ statement");
}
if (!els && !s1) {
warning (test,
"suggest braces around empty body in an ‘if’ statement");
}
pr.source_line = test->line;
pr.source_file = test->file;
if_expr = new_block_expr ();
test = convert_bool (test, 1);
if (test->type != ex_error) {
if (not) {
backpatch (test->e.boolean.true_list, fl);
backpatch (test->e.boolean.false_list, tl);
} else {
backpatch (test->e.boolean.true_list, tl);
backpatch (test->e.boolean.false_list, fl);
}
append_expr (test->e.boolean.e, tl);
append_expr (if_expr, test);
}
append_expr (if_expr, s1);
if (els) {
pr.source_line = els->line;
pr.source_file = els->file;
}
if (s2) {
expr_t *nl = new_label_expr ();
append_expr (if_expr, goto_expr (nl));
append_expr (if_expr, fl);
append_expr (if_expr, s2);
append_expr (if_expr, nl);
} else {
append_expr (if_expr, fl);
}
pr.source_line = line;
pr.source_file = file;
return if_expr;
}
expr_t *
build_while_statement (int not, expr_t *test, expr_t *statement,
expr_t *break_label, expr_t *continue_label)
{
int line = pr.source_line;
pr_string_t file = pr.source_file;
expr_t *l1 = new_label_expr ();
expr_t *l2 = break_label;
expr_t *while_expr;
pr.source_line = test->line;
pr.source_file = test->file;
while_expr = new_block_expr ();
append_expr (while_expr, goto_expr (continue_label));
append_expr (while_expr, l1);
append_expr (while_expr, statement);
append_expr (while_expr, continue_label);
test = convert_bool (test, 1);
if (test->type != ex_error) {
if (not) {
backpatch (test->e.boolean.true_list, l2);
backpatch (test->e.boolean.false_list, l1);
} else {
backpatch (test->e.boolean.true_list, l1);
backpatch (test->e.boolean.false_list, l2);
}
append_expr (test->e.boolean.e, l2);
append_expr (while_expr, test);
}
pr.source_line = line;
pr.source_file = file;
return while_expr;
}
expr_t *
build_do_while_statement (expr_t *statement, int not, expr_t *test,
expr_t *break_label, expr_t *continue_label)
{
expr_t *l1 = new_label_expr ();
int line = pr.source_line;
pr_string_t file = pr.source_file;
expr_t *do_while_expr;
if (!statement) {
warning (break_label,
"suggest braces around empty body in a ‘do’ statement");
}
pr.source_line = test->line;
pr.source_file = test->file;
do_while_expr = new_block_expr ();
append_expr (do_while_expr, l1);
append_expr (do_while_expr, statement);
append_expr (do_while_expr, continue_label);
test = convert_bool (test, 1);
if (test->type != ex_error) {
if (not) {
backpatch (test->e.boolean.true_list, break_label);
backpatch (test->e.boolean.false_list, l1);
} else {
backpatch (test->e.boolean.true_list, l1);
backpatch (test->e.boolean.false_list, break_label);
}
append_expr (test->e.boolean.e, break_label);
append_expr (do_while_expr, test);
}
pr.source_line = line;
pr.source_file = file;
return do_while_expr;
}
expr_t *
build_for_statement (expr_t *init, expr_t *test, expr_t *next,
expr_t *statement,
expr_t *break_label, expr_t *continue_label)
{
expr_t *tl = new_label_expr ();
expr_t *fl = break_label;
expr_t *l1 = 0;
expr_t *t;
int line = pr.source_line;
pr_string_t file = pr.source_file;
expr_t *for_expr;
if (next)
t = next;
else if (test)
t = test;
else if (init)
t = init;
else
t = continue_label;
pr.source_line = t->line;
pr.source_file = t->file;
for_expr = new_block_expr ();
append_expr (for_expr, init);
if (test) {
l1 = new_label_expr ();
append_expr (for_expr, goto_expr (l1));
}
append_expr (for_expr, tl);
append_expr (for_expr, statement);
append_expr (for_expr, continue_label);
append_expr (for_expr, next);
if (test) {
append_expr (for_expr, l1);
test = convert_bool (test, 1);
if (test->type != ex_error) {
backpatch (test->e.boolean.true_list, tl);
backpatch (test->e.boolean.false_list, fl);
append_expr (test->e.boolean.e, fl);
append_expr (for_expr, test);
}
} else {
append_expr (for_expr, goto_expr (tl));
append_expr (for_expr, fl);
}
pr.source_line = line;
pr.source_file = file;
return for_expr;
}
expr_t *
build_state_expr (expr_t *e)
{
expr_t *frame = 0;
expr_t *think = 0;
expr_t *step = 0;
e = reverse_expr_list (e);
frame = e;
think = frame->next;
step = think->next;
if (think->type == ex_symbol)
think = think_expr (think->e.symbol);
if (is_int_val (frame))
frame = cast_expr (&type_float, frame);
if (!type_assignable (&type_float, get_type (frame)))
return error (frame, "invalid type for frame number");
if (extract_type (think) != ev_func)
return error (think, "invalid type for think");
if (step) {
if (step->next)
return error (step->next, "too many state arguments");
if (is_int_val (step))
step = cast_expr (&type_float, step);
if (!type_assignable (&type_float, get_type (step)))
return error (step, "invalid type for step");
}
return new_state_expr (frame, think, step);
}
expr_t *
think_expr (symbol_t *think_sym)
{
symbol_t *sym;
if (think_sym->table)
return new_symbol_expr (think_sym);
sym = symtab_lookup (current_symtab, "think");
if (sym && sym->sy_type == sy_var && sym->type
&& sym->type->type == ev_field
&& sym->type->t.fldptr.type->type == ev_func) {
think_sym->type = sym->type->t.fldptr.type;
} else {
think_sym->type = &type_func;
}
think_sym = function_symbol (think_sym, 0, 1);
make_function (think_sym, 0, current_symtab->space, current_storage);
return new_symbol_expr (think_sym);
}
expr_t *
encode_expr (type_t *type)
{
dstring_t *encoding = dstring_newstr ();
expr_t *e;
encode_type (encoding, type);
e = new_string_expr (encoding->str);
free (encoding);
return e;
}
expr_t *
sizeof_expr (expr_t *expr, struct type_s *type)
{
if (!((!expr) ^ (!type)))
internal_error (0, 0);
if (!type)
type = get_type (expr);
if (type) {
expr = new_int_expr (type_size (type));
}
return expr;
}
expr_t *
reverse_expr_list (expr_t *e)
{
expr_t *r = 0;
while (e) {
expr_t *t = e->next;
e->next = r;
r = e;
e = t;
}
return r;
}