quakeforge/tools/qfcc/source/value.c

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2002-10-22 14:53:18 +00:00
/*
value.c
value handling
2002-10-22 14:53:18 +00:00
Copyright (C) 2002 Bill Currie <bill@taniwha.org>
2002-10-22 14:53:18 +00:00
Author: Bill Currie <bill@taniwha.org>
Date: 2002/06/04
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
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#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/mathlib.h"
#include "QF/progs.h"
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#include "QF/va.h"
#include "QF/simd/types.h"
#include "tools/qfcc/include/qfcc.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/options.h"
#include "tools/qfcc/include/reloc.h"
#include "tools/qfcc/include/strpool.h"
#include "tools/qfcc/include/symtab.h"
#include "tools/qfcc/include/type.h"
#include "tools/qfcc/include/value.h"
//FIXME I don't like this being here (or aligned_alloc being necessary in
//the first place, but not at all sure what to do about that)
#ifdef _WIN32
#define aligned_alloc(al, sz) _aligned_malloc(sz, al)
#define free(x) _aligned_free(x)
#endif
typedef struct {
def_t *def;
union {
#define EV_TYPE(type) pr_##type##_t type##_val;
#include "QF/progs/pr_type_names.h"
#define VEC_TYPE(type_name, base_type) pr_##type_name##_t type_name##_val;
#include "tools/qfcc/include/vec_types.h"
ex_pointer_t pointer;
} i;
} immediate_t;
static hashtab_t *value_table;
ALLOC_STATE (ex_value_t, values);
//FIXME this (to setup_value_progs) should be in its own file and more
//general (good for constant folding, too, and maybe some others).
static void
value_debug_handler (prdebug_t event, void *param, void *data)
{
progs_t *pr = data;
switch (event) {
case prd_trace:
dstatement_t *st = pr->pr_statements + pr->pr_xstatement;
PR_PrintStatement (pr, st, 0);
break;
case prd_breakpoint:
case prd_subenter:
case prd_subexit:
case prd_runerror:
case prd_watchpoint:
case prd_begin:
case prd_terminate:
case prd_error:
case prd_none:
break;
}
}
enum {
vf_null,
vf_convert,
};
#define BASE(b, base) (((base) & 3) << OP_##b##_SHIFT)
#define OP(a, b, c, op) ((op) | BASE(A, a) | BASE(B, b) | BASE(C, c))
static bfunction_t value_functions[] = {
{}, // null function
[vf_convert] = { .first_statement = vf_convert * 16 },
};
static __attribute__((aligned(64)))
dstatement_t value_statements[] = {
[vf_convert * 16 - 1] = {},
{ OP_CONV, 0, 07777, 16 },
{ OP_RETURN, 16, 0, 0 },
};
#define num_globals 16384
#define stack_size 8192
static __attribute__((aligned(64)))
pr_type_t value_globals[num_globals + 128] = {
[num_globals - stack_size] = { .uint_value = num_globals },
};
static dprograms_t value_progs = {
.version = PROG_VERSION,
.statements = {
.count = sizeof (value_statements) / sizeof (value_statements[0]),
},
};
static progs_t value_pr = {
.progs = &value_progs,
.debug_handler = value_debug_handler,
.debug_data = &value_pr,
.pr_trace = 1,
.pr_trace_depth = -1,
.function_table = value_functions,
.pr_statements = value_statements,
.globals_size = num_globals,
.pr_globals = value_globals,
.stack_bottom = num_globals - stack_size + 4,
.pr_return_buffer = value_globals + num_globals,
.pr_return = value_globals + num_globals,
.globals = {
.stack = (pr_ptr_t *) (value_globals + num_globals - stack_size),
}
};
static void
setup_value_progs (void)
{
PR_Init (&value_pr);
PR_Debug_Init (&value_pr);
}
static uintptr_t
value_get_hash (const void *_val, void *unused)
{
const ex_value_t *val = (const ex_value_t *) _val;
return Hash_Buffer (&val->v, sizeof (val->v)) ^ (uintptr_t) val->type;
}
static int
value_compare (const void *_val1, const void *_val2, void *unused)
{
const ex_value_t *val1 = (const ex_value_t *) _val1;
const ex_value_t *val2 = (const ex_value_t *) _val2;
if (val1->type != val2->type)
return 0;
return memcmp (&val1->v, &val2->v, sizeof (val1->v)) == 0;
}
static ex_value_t *
new_value (void)
{
ex_value_t *value;
#define malloc(x) aligned_alloc (__alignof__(ex_value_t), x)
ALLOC (256, ex_value_t, values, value);
#undef malloc
return value;
}
static void
set_val_type (ex_value_t *val, type_t *type)
{
val->type = type;
val->lltype = low_level_type (type);
}
static ex_value_t *
find_value (const ex_value_t *val)
{
ex_value_t *value;
value = Hash_FindElement (value_table, val);
if (value)
return value;
value = new_value ();
*value = *val;
Hash_AddElement (value_table, value);
return value;
}
ex_value_t *
new_string_val (const char *string_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_string);
if (string_val)
val.v.string_val = save_string (string_val);
return find_value (&val);
}
ex_value_t *
new_double_val (double double_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_double);
val.v.double_val = double_val;
return find_value (&val);
}
ex_value_t *
new_float_val (float float_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_float);
val.v.float_val = float_val;
return find_value (&val);
}
ex_value_t *
new_vector_val (const float *vector_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_vector);
VectorCopy (vector_val, val.v.vector_val);
return find_value (&val);
}
ex_value_t *
new_entity_val (int entity_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_entity);
val.v.entity_val = entity_val;
return find_value (&val);
}
ex_value_t *
new_field_val (int field_val, type_t *type, def_t *def)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, field_type (type));
val.v.pointer.val = field_val;
val.v.pointer.type = type;
val.v.pointer.def = def;
return find_value (&val);
}
ex_value_t *
new_func_val (int func_val, type_t *type)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, type);
val.v.func_val.val = func_val;
val.v.func_val.type = type;
return find_value (&val);
}
ex_value_t *
new_pointer_val (int pointer_val, type_t *type, def_t *def,
struct operand_s *tempop)
{
ex_value_t val;
if (!type) {
internal_error (0, "pointer value with no type");
}
memset (&val, 0, sizeof (val));
set_val_type (&val, pointer_type (type));
val.v.pointer.val = pointer_val;
val.v.pointer.type = type;
val.v.pointer.def = def;
val.v.pointer.tempop = tempop;
return find_value (&val);
}
ex_value_t *
new_quaternion_val (const float *quaternion_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_quaternion);
QuatCopy (quaternion_val, val.v.quaternion_val);
return find_value (&val);
}
ex_value_t *
new_int_val (int int_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_int);
val.v.int_val = int_val;
return find_value (&val);
}
ex_value_t *
new_uint_val (int uint_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_uint);
val.v.uint_val = uint_val;
return find_value (&val);
}
ex_value_t *
new_long_val (pr_long_t long_val)
{
ex_value_t val = { .v = { .long_val = long_val } };
set_val_type (&val, &type_long);
return find_value (&val);
}
ex_value_t *
new_ulong_val (pr_ulong_t ulong_val)
{
ex_value_t val = { .v = { .ulong_val = ulong_val } };
set_val_type (&val, &type_ulong);
return find_value (&val);
}
ex_value_t *
new_short_val (short short_val)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, &type_short);
val.v.short_val = short_val;
return find_value (&val);
}
ex_value_t *
new_nil_val (type_t *type)
{
ex_value_t val;
memset (&val, 0, sizeof (val));
set_val_type (&val, type);
if (val.lltype == ev_void) {
val.lltype = type_nil->type;
}
if (val.lltype == ev_ptr || val.lltype == ev_field )
val.v.pointer.type = type->t.fldptr.type;
if (val.lltype == ev_func)
val.v.func_val.type = type;
return find_value (&val);
}
ex_value_t *
new_type_value (const type_t *type, const pr_type_t *data)
{
size_t typeSize = type_size (type) * sizeof (pr_type_t);
ex_value_t val = {};
set_val_type (&val, (type_t *) type);//FIXME cast
memcpy (&val.v, data, typeSize);
return find_value (&val);
}
void
value_store (pr_type_t *dst, const type_t *dstType, const expr_t *src)
{
size_t dstSize = type_size (dstType) * sizeof (pr_type_t);
if (src->type == ex_nil) {
memset (dst, 0, dstSize);
return;
}
if (src->type == ex_symbol && src->e.symbol->sy_type == sy_var) {
// initialized global def treated as a constant
// from the tests in cast_expr, the def is known to be constant
def_t *def = src->e.symbol->s.def;
memcpy (dst, &D_PACKED (pr_type_t, def), dstSize);
return;
}
ex_value_t *val = 0;
if (src->type == ex_value) {
val = src->e.value;
}
if (src->type == ex_symbol && src->e.symbol->sy_type == sy_const) {
val = src->e.symbol->s.value;
}
if (!val) {
internal_error (src, "unexpected constant expression type");
}
memcpy (dst, &val->v, dstSize);
}
const char *
get_value_string (const ex_value_t *value)
{
const type_t *type = value->type;
const char *str = "";
switch (type->type) {
case ev_string:
return va (0, "\"%s\"", quote_string (value->v.string_val));
case ev_vector:
case ev_quaternion:
case ev_float:
switch (type_width (type)) {
case 1:
str = va (0, "%.9g", value->v.float_val);
break;
case 2:
str = va (0, VEC2F_FMT, VEC2_EXP (value->v.vec2_val));
break;
case 3:
str = va (0, "[%.9g, %.9g, %.9g]",
VectorExpand (value->v.vec3_val));
break;
case 4:
str = va (0, VEC4F_FMT, VEC4_EXP (value->v.vec4_val));
break;
}
return va (0, "%s %s", type->name, str);
case ev_entity:
case ev_func:
return va (0, "%s %d", type->name, value->v.int_val);
case ev_field:
if (value->v.pointer.def) {
int offset = value->v.pointer.val;
offset += value->v.pointer.def->offset;
return va (0, "field %d", offset);
} else {
return va (0, "field %d", value->v.pointer.val);
}
case ev_ptr:
if (value->v.pointer.def) {
str = va (0, "<%s>", value->v.pointer.def->name);
}
return va (0, "(* %s)[%d]%s",
value->v.pointer.type
? get_type_string (value->v.pointer.type) : "???",
value->v.pointer.val, str);
case ev_int:
switch (type_width (type)) {
case 1:
str = va (0, "%"PRIi32, value->v.int_val);
break;
case 2:
str = va (0, VEC2I_FMT, VEC2_EXP (value->v.ivec2_val));
break;
case 3:
str = va (0, "[%"PRIi32", %"PRIi32", %"PRIi32"]",
VectorExpand (value->v.ivec3_val));
break;
case 4:
str = va (0, VEC4I_FMT, VEC4_EXP (value->v.ivec4_val));
break;
}
return va (0, "%s %s", type->name, str);
case ev_uint:
switch (type_width (type)) {
case 1:
str = va (0, "%"PRIu32, value->v.uint_val);
break;
case 2:
str = va (0, "[%"PRIu32", %"PRIi32"]",
VEC2_EXP (value->v.uivec2_val));
break;
case 3:
str = va (0, "[%"PRIu32", %"PRIi32", %"PRIi32"]",
VectorExpand (value->v.uivec3_val));
break;
case 4:
str = va (0, "[%"PRIu32", %"PRIi32", %"PRIi32", %"PRIi32"]",
VEC4_EXP (value->v.uivec4_val));
break;
}
return va (0, "%s %s", type->name, str);
case ev_short:
return va (0, "%s %"PRIi16, type->name, value->v.short_val);
case ev_ushort:
return va (0, "%s %"PRIu16, type->name, value->v.ushort_val);
case ev_double:
switch (type_width (type)) {
case 1:
str = va (0, "%.17g", value->v.double_val);
break;
case 2:
str = va (0, VEC2D_FMT, VEC2_EXP (value->v.dvec2_val));
break;
case 3:
str = va (0, "[%.17g, %.17g, %.17g]",
VectorExpand (value->v.dvec3_val));
break;
case 4:
str = va (0, VEC4D_FMT, VEC4_EXP (value->v.dvec4_val));
break;
}
return va (0, "%s %s", type->name, str);
case ev_long:
switch (type_width (type)) {
case 1:
str = va (0, "%"PRIi64, value->v.long_val);
break;
case 2:
str = va (0, VEC2L_FMT, VEC2_EXP (value->v.lvec2_val));
break;
case 3:
str = va (0, "[%"PRIi64", %"PRIi64", %"PRIi64"]",
VectorExpand (value->v.lvec3_val));
break;
case 4:
str = va (0, VEC4L_FMT, VEC4_EXP (value->v.lvec4_val));
break;
}
return va (0, "%s %s", type->name, str);
case ev_ulong:
switch (type_width (type)) {
case 1:
str = va (0, "%"PRIu64, value->v.ulong_val);
break;
case 2:
str = va (0, "[%"PRIu64", %"PRIi64"]",
VEC2_EXP (value->v.ulvec2_val));
break;
case 3:
str = va (0, "[%"PRIu64", %"PRIi64", %"PRIi64"]",
VectorExpand (value->v.ulvec3_val));
break;
case 4:
str = va (0, "[%"PRIu64", %"PRIi64", %"PRIi64", %"PRIi64"]",
VEC4_EXP (value->v.ulvec4_val));
break;
}
return va (0, "%s %s", type->name, str);
case ev_void:
return "<void>";
case ev_invalid:
return "<invalid>";
case ev_type_count:
return "<type_count>";
}
return "invalid type";
}
static hashtab_t *string_imm_defs;
static hashtab_t *fldptr_imm_defs;
static hashtab_t *value_imm_defs;
static void
imm_free (void *_imm, void *unused)
{
free (_imm);
}
static __attribute__((pure)) uintptr_t
imm_get_hash (const void *_imm, void *_tab)
{
immediate_t *imm = (immediate_t *) _imm;
hashtab_t **tab = (hashtab_t **) _tab;
if (tab == &string_imm_defs) {
const char *str = pr.strings->strings + imm->i.string_val;
return str ? Hash_String (str) : 0;
} else if (tab == &fldptr_imm_defs) {
return Hash_Buffer (&imm->i.pointer, sizeof (&imm->i.pointer));
} else if (tab == &value_imm_defs) {
size_t size = type_size (imm->def->type) * sizeof (pr_type_t);
return Hash_Buffer (&imm->i, size) ^ (uintptr_t) imm->def->type;
} else {
internal_error (0, "invalid immediate hash table");
}
}
static __attribute__((pure)) int
imm_compare (const void *_imm1, const void *_imm2, void *_tab)
{
immediate_t *imm1 = (immediate_t *) _imm1;
immediate_t *imm2 = (immediate_t *) _imm2;
hashtab_t **tab = (hashtab_t **) _tab;
if (tab == &string_imm_defs) {
const char *str1 = pr.strings->strings + imm1->i.string_val;
const char *str2 = pr.strings->strings + imm2->i.string_val;
return (str1 == str2 || (str1 && str2 && !strcmp (str1, str2)));
} else if (tab == &fldptr_imm_defs) {
return !memcmp (&imm1->i.pointer, &imm2->i.pointer,
sizeof (imm1->i.pointer));
} else if (tab == &value_imm_defs) {
size_t size = type_size (imm1->def->type) * sizeof (pr_type_t);
return !memcmp (&imm1->i, &imm2->i, size);
} else {
internal_error (0, "invalid immediate hash table");
}
}
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int
ReuseString (const char *str)
{
return strpool_addstr (pr.strings, str);
2002-06-04 18:44:03 +00:00
}
ex_value_t *
convert_value (ex_value_t *value, type_t *type)
{
if (!is_math (type) || !is_math (value->type)) {
error (0, "unable to convert non-math value");
return value;
}
if (type_width (type) != type_width (value->type)) {
error (0, "unable to convert between values of different widths");
return value;
}
int from = type_cast_map[base_type (value->type)->type];
int to = type_cast_map[base_type (type)->type];
int width = type_width (value->type) - 1;
int conv = TYPE_CAST_CODE (from, to, width);
int addr = value_functions[vf_convert].first_statement;
value_statements[addr + 0].b = conv;
value_statements[addr + 1].c = type_size (type) - 1;
memcpy (value_globals, &value->v,
type_size (value->type) * sizeof (pr_type_t));
value_pr.pr_trace = options.verbosity > 1;
PR_ExecuteProgram (&value_pr, vf_convert);
return new_type_value (type, value_pr.pr_return_buffer);
}
ex_value_t *
alias_value (ex_value_t *value, type_t *type)
{
ex_value_t new;
if (type_size (type) != type_size (ev_types[value->lltype])) {
error (0, "unable to alias different sized values");
return value;
}
new = *value;
set_val_type (&new, type);
return find_value (&new);
}
static immediate_t *
make_def_imm (def_t *def, hashtab_t *tab, ex_value_t *val)
{
immediate_t *imm;
imm = aligned_alloc (__alignof__(immediate_t), sizeof (immediate_t));
memset (imm, 0, sizeof (immediate_t));
imm->def = def;
memcpy (&imm->i, &val->v, sizeof (imm->i));
Hash_AddElement (tab, imm);
return imm;
}
def_t *
emit_value (ex_value_t *value, def_t *def)
{
def_t *cn;
hashtab_t *tab = 0;
type_t *type;
ex_value_t val = *value;
if (!string_imm_defs) {
clear_immediates ();
}
cn = 0;
// if (val.type == ev_void)
// val.type = type_nil->type;
switch (val.lltype) {
case ev_entity:
case ev_func:
case ev_int:
case ev_uint:
case ev_float:
case ev_vector:
case ev_quaternion:
case ev_double:
case ev_long:
case ev_ulong:
tab = value_imm_defs;
type = val.type;
break;
case ev_field:
case ev_ptr:
tab = fldptr_imm_defs;
type = ev_types[val.lltype];
break;
case ev_string:
val.v.int_val = ReuseString (val.v.string_val);
tab = string_imm_defs;
type = &type_string;
break;
default:
internal_error (0, "unexpected value type: %s",
val.type->type < ev_type_count
? pr_type_name[val.lltype]
: va (0, "%d", val.lltype));
}
def_t search_def = { .type = type };
immediate_t search = { .def = &search_def };
memcpy (&search.i, &val.v, sizeof (search.i));
immediate_t *imm = Hash_FindElement (tab, &search);
if (imm && strcmp (imm->def->name, ".zero") == 0) {
if (def) {
imm = 0; //FIXME do full def aliasing
} else {
symbol_t *sym;
sym = make_symbol (".zero", &type_zero, 0, sc_extern);
return sym->s.def;
}
}
if (imm) {
cn = imm->def;
if (def) {
defspace_free_loc (def->space, def->offset, type_size (def->type));
def->offset = cn->offset;
def->initialized = def->constant = 1;
def->nosave = 1;
def->local = 0;
cn = def;
} else {
if (cn->type != type) {
def = new_def (".imm", type, pr.near_data, sc_static);
def->offset = cn->offset;
cn = def;
}
}
return cn;
}
// allocate a new one
// always share immediates
if (def) {
if (def->type != type) {
cn = new_def (".imm", type, pr.near_data, sc_static);
cn->offset = def->offset;
} else {
cn = def;
}
} else {
cn = new_def (".imm", type, pr.near_data, sc_static);
}
cn->initialized = cn->constant = 1;
cn->nosave = 1;
// copy the immediate to the global area
switch (val.lltype) {
case ev_string:
reloc_def_string (cn);
break;
case ev_func:
if (val.v.func_val.val) {
reloc_t *reloc;
reloc = new_reloc (cn->space, cn->offset, rel_def_func);
reloc->next = pr.relocs;
pr.relocs = reloc;
}
break;
case ev_field:
if (val.v.pointer.def)
reloc_def_field_ofs (val.v.pointer.def, cn);
break;
case ev_ptr:
if (val.v.pointer.def) {
EMIT_DEF_OFS (pr.near_data, D_INT (cn),
val.v.pointer.def);
}
break;
default:
break;
}
memcpy (D_POINTER (pr_type_t, cn), &val.v, 4 * type_size (type));
make_def_imm (cn, tab, &val);
return cn;
}
void
clear_immediates (void)
{
def_t *def;
ex_value_t zero_val;
if (value_table) {
Hash_FlushTable (value_table);
Hash_FlushTable (string_imm_defs);
Hash_FlushTable (fldptr_imm_defs);
Hash_FlushTable (value_imm_defs);
} else {
setup_value_progs ();
value_table = Hash_NewTable (16381, 0, 0, 0, 0);
Hash_SetHashCompare (value_table, value_get_hash, value_compare);
string_imm_defs = Hash_NewTable (16381, 0, imm_free,
&string_imm_defs, 0);
Hash_SetHashCompare (string_imm_defs, imm_get_hash, imm_compare);
fldptr_imm_defs = Hash_NewTable (16381, 0, imm_free,
&fldptr_imm_defs, 0);
Hash_SetHashCompare (fldptr_imm_defs, imm_get_hash, imm_compare);
2020-02-14 11:08:59 +00:00
value_imm_defs = Hash_NewTable (16381, 0, imm_free,
&value_imm_defs, 0);
Hash_SetHashCompare (value_imm_defs, imm_get_hash, imm_compare);
}
def = make_symbol (".zero", &type_zero, 0, sc_extern)->s.def;
memset (&zero_val, 0, sizeof (zero_val));
make_def_imm (def, string_imm_defs, &zero_val);
make_def_imm (def, fldptr_imm_defs, &zero_val);
make_def_imm (def, value_imm_defs, &zero_val);
}