#include <string.h>
#include <math.h>
-#include "gmqcc.h"
-#include "lexer.h"
-#include "ast.h"
+#include "parser.h"
-/* beginning of locals */
#define PARSER_HT_LOCALS 2
-
-#define PARSER_HT_SIZE 128
-#define TYPEDEF_HT_SIZE 16
-
-typedef struct parser_s {
- lex_file *lex;
- int tok;
-
- bool ast_cleaned;
-
- ast_expression **globals;
- ast_expression **fields;
- ast_function **functions;
- ast_value **imm_float;
- ast_value **imm_string;
- ast_value **imm_vector;
- size_t translated;
-
- ht ht_imm_string;
-
- /* must be deleted first, they reference immediates and values */
- ast_value **accessors;
-
- ast_value *imm_float_zero;
- ast_value *imm_float_one;
- ast_value *imm_float_neg_one;
-
- ast_value *imm_vector_zero;
-
- ast_value *nil;
- ast_value *reserved_version;
-
- size_t crc_globals;
- size_t crc_fields;
-
- ast_function *function;
- ht aliases;
-
- /* All the labels the function defined...
- * Should they be in ast_function instead?
- */
- ast_label **labels;
- ast_goto **gotos;
- const char **breaks;
- const char **continues;
-
- /* A list of hashtables for each scope */
- ht *variables;
- ht htfields;
- ht htglobals;
- ht *typedefs;
-
- /* same as above but for the spelling corrector */
- correct_trie_t **correct_variables;
- size_t ***correct_variables_score; /* vector of vector of size_t* */
-
- /* not to be used directly, we use the hash table */
- ast_expression **_locals;
- size_t *_blocklocals;
- ast_value **_typedefs;
- size_t *_blocktypedefs;
- lex_ctx *_block_ctx;
-
- /* we store the '=' operator info */
- const oper_info *assign_op;
-
- /* magic values */
- ast_value *const_vec[3];
-
- /* pragma flags */
- bool noref;
-
- /* collected information */
- size_t max_param_count;
-
- /* code generator */
- code_t *code;
-} parser_t;
-
-static ast_expression * const intrinsic_debug_typestring = (ast_expression*)0x1;
+#define PARSER_HT_SIZE 512
+#define TYPEDEF_HT_SIZE 512
static void parser_enterblock(parser_t *parser);
static bool parser_leaveblock(parser_t *parser);
return r;
}
-/**********************************************************************
- * some maths used for constant folding
- */
-
-vector vec3_add(vector a, vector b)
-{
- vector out;
- out.x = a.x + b.x;
- out.y = a.y + b.y;
- out.z = a.z + b.z;
- return out;
-}
-
-vector vec3_sub(vector a, vector b)
-{
- vector out;
- out.x = a.x - b.x;
- out.y = a.y - b.y;
- out.z = a.z - b.z;
- return out;
-}
-
-qcfloat vec3_mulvv(vector a, vector b)
-{
- return (a.x * b.x + a.y * b.y + a.z * b.z);
-}
-
-vector vec3_mulvf(vector a, float b)
-{
- vector out;
- out.x = a.x * b;
- out.y = a.y * b;
- out.z = a.z * b;
- return out;
-}
-
/**********************************************************************
* parsing
*/
#define parser_tokval(p) ((p)->lex->tok.value)
#define parser_token(p) (&((p)->lex->tok))
-#define parser_ctx(p) ((p)->lex->tok.ctx)
-
-static ast_value* parser_const_float(parser_t *parser, double d)
-{
- size_t i;
- ast_value *out;
- lex_ctx ctx;
- for (i = 0; i < vec_size(parser->imm_float); ++i) {
- const double compare = parser->imm_float[i]->constval.vfloat;
- if (memcmp((const void*)&compare, (const void *)&d, sizeof(double)) == 0)
- return parser->imm_float[i];
- }
- if (parser->lex)
- ctx = parser_ctx(parser);
- else {
- memset(&ctx, 0, sizeof(ctx));
- }
- out = ast_value_new(ctx, "#IMMEDIATE", TYPE_FLOAT);
- out->cvq = CV_CONST;
- out->hasvalue = true;
- out->isimm = true;
- out->constval.vfloat = d;
- vec_push(parser->imm_float, out);
- return out;
-}
-
-static ast_value* parser_const_float_0(parser_t *parser)
-{
- if (!parser->imm_float_zero)
- parser->imm_float_zero = parser_const_float(parser, 0);
- return parser->imm_float_zero;
-}
-
-static ast_value* parser_const_float_neg1(parser_t *parser) {
- if (!parser->imm_float_neg_one)
- parser->imm_float_neg_one = parser_const_float(parser, -1);
- return parser->imm_float_neg_one;
-}
-static ast_value* parser_const_float_1(parser_t *parser)
-{
- if (!parser->imm_float_one)
- parser->imm_float_one = parser_const_float(parser, 1);
- return parser->imm_float_one;
-}
-
-static char *parser_strdup(const char *str)
+char *parser_strdup(const char *str)
{
if (str && !*str) {
/* actually dup empty strings */
return util_strdup(str);
}
-static ast_value* parser_const_string(parser_t *parser, const char *str, bool dotranslate)
-{
- size_t hash = util_hthash(parser->ht_imm_string, str);
- ast_value *out;
- if ( (out = (ast_value*)util_htgeth(parser->ht_imm_string, str, hash)) ) {
- if (dotranslate && out->name[0] == '#') {
- char name[32];
- util_snprintf(name, sizeof(name), "dotranslate_%lu", (unsigned long)(parser->translated++));
- ast_value_set_name(out, name);
- out->expression.flags |= AST_FLAG_INCLUDE_DEF;
- }
- return out;
- }
- /*
- for (i = 0; i < vec_size(parser->imm_string); ++i) {
- if (!strcmp(parser->imm_string[i]->constval.vstring, str))
- return parser->imm_string[i];
- }
- */
- if (dotranslate) {
- char name[32];
- util_snprintf(name, sizeof(name), "dotranslate_%lu", (unsigned long)(parser->translated++));
- out = ast_value_new(parser_ctx(parser), name, TYPE_STRING);
- out->expression.flags |= AST_FLAG_INCLUDE_DEF;
- } else
- out = ast_value_new(parser_ctx(parser), "#IMMEDIATE", TYPE_STRING);
- out->cvq = CV_CONST;
- out->hasvalue = true;
- out->isimm = true;
- out->constval.vstring = parser_strdup(str);
- vec_push(parser->imm_string, out);
- util_htseth(parser->ht_imm_string, str, hash, out);
- return out;
-}
-
-static ast_value* parser_const_vector(parser_t *parser, vector v)
-{
- size_t i;
- ast_value *out;
- for (i = 0; i < vec_size(parser->imm_vector); ++i) {
- if (!memcmp(&parser->imm_vector[i]->constval.vvec, &v, sizeof(v)))
- return parser->imm_vector[i];
- }
- out = ast_value_new(parser_ctx(parser), "#IMMEDIATE", TYPE_VECTOR);
- out->cvq = CV_CONST;
- out->hasvalue = true;
- out->isimm = true;
- out->constval.vvec = v;
- vec_push(parser->imm_vector, out);
- return out;
-}
-
-static ast_value* parser_const_vector_f(parser_t *parser, float x, float y, float z)
-{
- vector v;
- v.x = x;
- v.y = y;
- v.z = z;
- return parser_const_vector(parser, v);
-}
-
-static ast_value* parser_const_vector_0(parser_t *parser)
-{
- if (!parser->imm_vector_zero)
- parser->imm_vector_zero = parser_const_vector_f(parser, 0, 0, 0);
- return parser->imm_vector_zero;
-}
-
static ast_expression* parser_find_field(parser_t *parser, const char *name)
{
return ( ast_expression*)util_htget(parser->htfields, name);
return NULL;
}
-static ast_expression* parser_find_global(parser_t *parser, const char *name)
+ast_expression* parser_find_global(parser_t *parser, const char *name)
{
ast_expression *var = (ast_expression*)util_htget(parser->aliases, parser_tokval(parser));
if (var)
return NULL;
}
-/* include intrinsics */
-#include "intrin.h"
-
typedef struct
{
size_t etype; /* 0 = expression, others are operators */
size_t off;
ast_expression *out;
ast_block *block; /* for commas and function calls */
- lex_ctx ctx;
+ lex_ctx_t ctx;
} sy_elem;
enum {
unsigned int *paren;
} shunt;
-static sy_elem syexp(lex_ctx ctx, ast_expression *v) {
+static sy_elem syexp(lex_ctx_t ctx, ast_expression *v) {
sy_elem e;
e.etype = 0;
e.off = 0;
return e;
}
-static sy_elem syblock(lex_ctx ctx, ast_block *v) {
+static sy_elem syblock(lex_ctx_t ctx, ast_block *v) {
sy_elem e;
e.etype = 0;
e.off = 0;
return e;
}
-static sy_elem syop(lex_ctx ctx, const oper_info *op) {
+static sy_elem syop(lex_ctx_t ctx, const oper_info *op) {
sy_elem e;
e.etype = 1 + (op - operators);
e.off = 0;
return e;
}
-static sy_elem syparen(lex_ctx ctx, size_t off) {
+static sy_elem syparen(lex_ctx_t ctx, size_t off) {
sy_elem e;
e.etype = 0;
e.off = off;
ast_expression *sub;
ast_expression *entity;
- lex_ctx ctx = ast_ctx(*out);
+ lex_ctx_t ctx = ast_ctx(*out);
if (!ast_istype(*out, ast_array_index))
return false;
return true;
}
-static bool immediate_is_true(lex_ctx ctx, ast_value *v)
+static bool check_write_to(lex_ctx_t ctx, ast_expression *expr)
{
- switch (v->expression.vtype) {
- case TYPE_FLOAT:
- return !!v->constval.vfloat;
- case TYPE_INTEGER:
- return !!v->constval.vint;
- case TYPE_VECTOR:
- if (OPTS_FLAG(CORRECT_LOGIC))
- return v->constval.vvec.x &&
- v->constval.vvec.y &&
- v->constval.vvec.z;
- else
- return !!(v->constval.vvec.x);
- case TYPE_STRING:
- if (!v->constval.vstring)
+ if (ast_istype(expr, ast_value)) {
+ ast_value *val = (ast_value*)expr;
+ if (val->cvq == CV_CONST) {
+ if (val->name[0] == '#') {
+ compile_error(ctx, "invalid assignment to a literal constant");
return false;
- if (v->constval.vstring && OPTS_FLAG(TRUE_EMPTY_STRINGS))
- return true;
- return !!v->constval.vstring[0];
- default:
- compile_error(ctx, "internal error: immediate_is_true on invalid type");
- return !!v->constval.vfunc;
+ }
+ /*
+ * To work around quakeworld we must elide the error and make it
+ * a warning instead.
+ */
+ if (OPTS_OPTION_U32(OPTION_STANDARD) != COMPILER_QCC)
+ compile_error(ctx, "assignment to constant `%s`", val->name);
+ else
+ (void)!compile_warning(ctx, WARN_CONST_OVERWRITE, "assignment to constant `%s`", val->name);
+ return false;
+ }
}
+ return true;
}
static bool parser_sy_apply_operator(parser_t *parser, shunt *sy)
{
const oper_info *op;
- lex_ctx ctx;
+ lex_ctx_t ctx;
ast_expression *out = NULL;
ast_expression *exprs[3];
ast_block *blocks[3];
- ast_value *asvalue[3];
ast_binstore *asbinstore;
size_t i, assignop, addop, subop;
- qcint generated_op = 0;
+ qcint_t generated_op = 0;
char ty1[1024];
char ty2[1024];
ctx = vec_last(sy->ops).ctx;
if (vec_size(sy->out) < op->operands) {
- compile_error(ctx, "internal error: not enough operands: %i (operator %s (%i))", vec_size(sy->out),
- op->op, (int)op->id);
+ if (op->flags & OP_PREFIX)
+ compile_error(ctx, "expected expression after unary operator `%s`", op->op, (int)op->id);
+ else /* this should have errored previously already */
+ compile_error(ctx, "expected expression after operator `%s`", op->op, (int)op->id);
return false;
}
for (i = 0; i < op->operands; ++i) {
exprs[i] = sy->out[vec_size(sy->out)+i].out;
blocks[i] = sy->out[vec_size(sy->out)+i].block;
- asvalue[i] = (ast_value*)exprs[i];
if (exprs[i]->vtype == TYPE_NOEXPR &&
!(i != 0 && op->id == opid2('?',':')) &&
#define NotSameType(T) \
(exprs[0]->vtype != exprs[1]->vtype || \
exprs[0]->vtype != T)
-#define CanConstFold1(A) \
- (ast_istype((A), ast_value) && ((ast_value*)(A))->hasvalue && (((ast_value*)(A))->cvq == CV_CONST) &&\
- (A)->vtype != TYPE_FUNCTION)
-#define CanConstFold(A, B) \
- (CanConstFold1(A) && CanConstFold1(B))
-#define ConstV(i) (asvalue[(i)]->constval.vvec)
-#define ConstF(i) (asvalue[(i)]->constval.vfloat)
-#define ConstS(i) (asvalue[(i)]->constval.vstring)
switch (op->id)
{
default:
out = exprs[0];
break;
case opid2('-','P'):
- switch (exprs[0]->vtype) {
- case TYPE_FLOAT:
- if (CanConstFold1(exprs[0]))
- out = (ast_expression*)parser_const_float(parser, -ConstF(0));
- else
- out = (ast_expression*)ast_binary_new(ctx, INSTR_SUB_F,
- (ast_expression*)parser_const_float_0(parser),
- exprs[0]);
- break;
- case TYPE_VECTOR:
- if (CanConstFold1(exprs[0]))
- out = (ast_expression*)parser_const_vector_f(parser,
- -ConstV(0).x, -ConstV(0).y, -ConstV(0).z);
- else
- out = (ast_expression*)ast_binary_new(ctx, INSTR_SUB_V,
- (ast_expression*)parser_const_vector_0(parser),
- exprs[0]);
- break;
- default:
- compile_error(ctx, "invalid types used in expression: cannot negate type %s",
- type_name[exprs[0]->vtype]);
+ if ((out = fold_op(parser->fold, op, exprs)))
+ break;
+ if (exprs[0]->vtype != TYPE_FLOAT &&
+ exprs[0]->vtype != TYPE_VECTOR) {
+ compile_error(ctx, "invalid types used in unary expression: cannot negate type %s",
+ type_name[exprs[0]->vtype]);
return false;
}
+ out = (ast_expression*)ast_unary_new(ctx, (VINSTR_NEG_F-TYPE_FLOAT) + exprs[0]->vtype, exprs[0]);
break;
case opid2('!','P'):
- switch (exprs[0]->vtype) {
- case TYPE_FLOAT:
- if (CanConstFold1(exprs[0]))
- out = (ast_expression*)parser_const_float(parser, !ConstF(0));
- else
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ switch (exprs[0]->vtype) {
+ case TYPE_FLOAT:
out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_F, exprs[0]);
- break;
- case TYPE_VECTOR:
- if (CanConstFold1(exprs[0]))
- out = (ast_expression*)parser_const_float(parser,
- (!ConstV(0).x && !ConstV(0).y && !ConstV(0).z));
- else
+ break;
+ case TYPE_VECTOR:
out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_V, exprs[0]);
- break;
- case TYPE_STRING:
- if (CanConstFold1(exprs[0])) {
- if (OPTS_FLAG(TRUE_EMPTY_STRINGS))
- out = (ast_expression*)parser_const_float(parser, !ConstS(0));
- else
- out = (ast_expression*)parser_const_float(parser, !ConstS(0) || !*ConstS(0));
- } else {
+ break;
+ case TYPE_STRING:
if (OPTS_FLAG(TRUE_EMPTY_STRINGS))
out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_F, exprs[0]);
else
out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_S, exprs[0]);
- }
- break;
- /* we don't constant-fold NOT for these types */
- case TYPE_ENTITY:
- out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_ENT, exprs[0]);
- break;
- case TYPE_FUNCTION:
- out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_FNC, exprs[0]);
- break;
- default:
- compile_error(ctx, "invalid types used in expression: cannot logically negate type %s",
- type_name[exprs[0]->vtype]);
- return false;
+ break;
+ /* we don't constant-fold NOT for these types */
+ case TYPE_ENTITY:
+ out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_ENT, exprs[0]);
+ break;
+ case TYPE_FUNCTION:
+ out = (ast_expression*)ast_unary_new(ctx, INSTR_NOT_FNC, exprs[0]);
+ break;
+ default:
+ compile_error(ctx, "invalid types used in expression: cannot logically negate type %s",
+ type_name[exprs[0]->vtype]);
+ return false;
+ }
}
break;
case opid1('+'):
if (exprs[0]->vtype != exprs[1]->vtype ||
- (exprs[0]->vtype != TYPE_VECTOR && exprs[0]->vtype != TYPE_FLOAT) )
+ (exprs[0]->vtype != TYPE_VECTOR && exprs[0]->vtype != TYPE_FLOAT) )
{
compile_error(ctx, "invalid types used in expression: cannot add type %s and %s",
type_name[exprs[0]->vtype],
type_name[exprs[1]->vtype]);
return false;
}
- switch (exprs[0]->vtype) {
- case TYPE_FLOAT:
- if (CanConstFold(exprs[0], exprs[1]))
- {
- out = (ast_expression*)parser_const_float(parser, ConstF(0) + ConstF(1));
- }
- else
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ switch (exprs[0]->vtype) {
+ case TYPE_FLOAT:
out = (ast_expression*)ast_binary_new(ctx, INSTR_ADD_F, exprs[0], exprs[1]);
- break;
- case TYPE_VECTOR:
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_vector(parser, vec3_add(ConstV(0), ConstV(1)));
- else
+ break;
+ case TYPE_VECTOR:
out = (ast_expression*)ast_binary_new(ctx, INSTR_ADD_V, exprs[0], exprs[1]);
- break;
- default:
- compile_error(ctx, "invalid types used in expression: cannot add type %s and %s",
- type_name[exprs[0]->vtype],
- type_name[exprs[1]->vtype]);
- return false;
- };
+ break;
+ default:
+ compile_error(ctx, "invalid types used in expression: cannot add type %s and %s",
+ type_name[exprs[0]->vtype],
+ type_name[exprs[1]->vtype]);
+ return false;
+ }
+ }
break;
case opid1('-'):
- if (exprs[0]->vtype != exprs[1]->vtype ||
- (exprs[0]->vtype != TYPE_VECTOR && exprs[0]->vtype != TYPE_FLOAT) )
+ if (exprs[0]->vtype != exprs[1]->vtype ||
+ (exprs[0]->vtype != TYPE_VECTOR && exprs[0]->vtype != TYPE_FLOAT))
{
compile_error(ctx, "invalid types used in expression: cannot subtract type %s from %s",
type_name[exprs[1]->vtype],
type_name[exprs[0]->vtype]);
return false;
}
- switch (exprs[0]->vtype) {
- case TYPE_FLOAT:
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_float(parser, ConstF(0) - ConstF(1));
- else
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ switch (exprs[0]->vtype) {
+ case TYPE_FLOAT:
out = (ast_expression*)ast_binary_new(ctx, INSTR_SUB_F, exprs[0], exprs[1]);
- break;
- case TYPE_VECTOR:
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_vector(parser, vec3_sub(ConstV(0), ConstV(1)));
- else
+ break;
+ case TYPE_VECTOR:
out = (ast_expression*)ast_binary_new(ctx, INSTR_SUB_V, exprs[0], exprs[1]);
- break;
- default:
- compile_error(ctx, "invalid types used in expression: cannot subtract type %s from %s",
- type_name[exprs[1]->vtype],
- type_name[exprs[0]->vtype]);
- return false;
- };
+ break;
+ default:
+ compile_error(ctx, "invalid types used in expression: cannot subtract type %s from %s",
+ type_name[exprs[1]->vtype],
+ type_name[exprs[0]->vtype]);
+ return false;
+ }
+ }
break;
case opid1('*'):
if (exprs[0]->vtype != exprs[1]->vtype &&
type_name[exprs[0]->vtype]);
return false;
}
- switch (exprs[0]->vtype) {
- case TYPE_FLOAT:
- if (exprs[1]->vtype == TYPE_VECTOR)
- {
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_vector(parser, vec3_mulvf(ConstV(1), ConstF(0)));
- else
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ switch (exprs[0]->vtype) {
+ case TYPE_FLOAT:
+ if (exprs[1]->vtype == TYPE_VECTOR)
out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_FV, exprs[0], exprs[1]);
- }
- else
- {
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_float(parser, ConstF(0) * ConstF(1));
else
out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, exprs[0], exprs[1]);
- }
- break;
- case TYPE_VECTOR:
- if (exprs[1]->vtype == TYPE_FLOAT)
- {
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_vector(parser, vec3_mulvf(ConstV(0), ConstF(1)));
- else
+ break;
+ case TYPE_VECTOR:
+ if (exprs[1]->vtype == TYPE_FLOAT)
out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_VF, exprs[0], exprs[1]);
- }
- else
- {
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_float(parser, vec3_mulvv(ConstV(0), ConstV(1)));
- else if (OPTS_OPTIMIZATION(OPTIM_VECTOR_COMPONENTS) && CanConstFold1(exprs[0])) {
- vector vec = ConstV(0);
- if (!vec.y && !vec.z) { /* 'n 0 0' * v */
- ++opts_optimizationcount[OPTIM_VECTOR_COMPONENTS];
- out = (ast_expression*)ast_member_new(ctx, exprs[1], 0, NULL);
- out->node.keep = false;
- ((ast_member*)out)->rvalue = true;
- if (vec.x != 1)
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, (ast_expression*)parser_const_float(parser, vec.x), out);
- }
- else if (!vec.x && !vec.z) { /* '0 n 0' * v */
- ++opts_optimizationcount[OPTIM_VECTOR_COMPONENTS];
- out = (ast_expression*)ast_member_new(ctx, exprs[1], 1, NULL);
- out->node.keep = false;
- ((ast_member*)out)->rvalue = true;
- if (vec.y != 1)
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, (ast_expression*)parser_const_float(parser, vec.y), out);
- }
- else if (!vec.x && !vec.y) { /* '0 n 0' * v */
- ++opts_optimizationcount[OPTIM_VECTOR_COMPONENTS];
- out = (ast_expression*)ast_member_new(ctx, exprs[1], 2, NULL);
- out->node.keep = false;
- ((ast_member*)out)->rvalue = true;
- if (vec.z != 1)
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, (ast_expression*)parser_const_float(parser, vec.z), out);
- }
- else
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_V, exprs[0], exprs[1]);
- }
- else if (OPTS_OPTIMIZATION(OPTIM_VECTOR_COMPONENTS) && CanConstFold1(exprs[1])) {
- vector vec = ConstV(1);
- if (!vec.y && !vec.z) { /* v * 'n 0 0' */
- ++opts_optimizationcount[OPTIM_VECTOR_COMPONENTS];
- out = (ast_expression*)ast_member_new(ctx, exprs[0], 0, NULL);
- out->node.keep = false;
- ((ast_member*)out)->rvalue = true;
- if (vec.x != 1)
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, out, (ast_expression*)parser_const_float(parser, vec.x));
- }
- else if (!vec.x && !vec.z) { /* v * '0 n 0' */
- ++opts_optimizationcount[OPTIM_VECTOR_COMPONENTS];
- out = (ast_expression*)ast_member_new(ctx, exprs[0], 1, NULL);
- out->node.keep = false;
- ((ast_member*)out)->rvalue = true;
- if (vec.y != 1)
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, out, (ast_expression*)parser_const_float(parser, vec.y));
- }
- else if (!vec.x && !vec.y) { /* v * '0 n 0' */
- ++opts_optimizationcount[OPTIM_VECTOR_COMPONENTS];
- out = (ast_expression*)ast_member_new(ctx, exprs[0], 2, NULL);
- out->node.keep = false;
- ((ast_member*)out)->rvalue = true;
- if (vec.z != 1)
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_F, out, (ast_expression*)parser_const_float(parser, vec.z));
- }
- else
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_V, exprs[0], exprs[1]);
- }
else
out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_V, exprs[0], exprs[1]);
- }
- break;
- default:
- compile_error(ctx, "invalid types used in expression: cannot multiply types %s and %s",
- type_name[exprs[1]->vtype],
- type_name[exprs[0]->vtype]);
- return false;
- };
+ break;
+ default:
+ compile_error(ctx, "invalid types used in expression: cannot multiply types %s and %s",
+ type_name[exprs[1]->vtype],
+ type_name[exprs[0]->vtype]);
+ return false;
+ }
+ }
break;
+
case opid1('/'):
if (exprs[1]->vtype != TYPE_FLOAT) {
ast_type_to_string(exprs[0], ty1, sizeof(ty1));
ast_type_to_string(exprs[1], ty2, sizeof(ty2));
- compile_error(ctx, "invalid types used in expression: cannot divide tyeps %s and %s", ty1, ty2);
+ compile_error(ctx, "invalid types used in expression: cannot divide types %s and %s", ty1, ty2);
return false;
}
- if (exprs[0]->vtype == TYPE_FLOAT) {
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_float(parser, ConstF(0) / ConstF(1));
- else
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ if (exprs[0]->vtype == TYPE_FLOAT)
out = (ast_expression*)ast_binary_new(ctx, INSTR_DIV_F, exprs[0], exprs[1]);
- }
- else if (exprs[0]->vtype == TYPE_VECTOR) {
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_vector(parser, vec3_mulvf(ConstV(0), 1.0/ConstF(1)));
else {
- if (CanConstFold1(exprs[1])) {
- out = (ast_expression*)parser_const_float(parser, 1.0 / ConstF(1));
- } else {
- out = (ast_expression*)ast_binary_new(ctx, INSTR_DIV_F,
- (ast_expression*)parser_const_float_1(parser),
- exprs[1]);
- }
- if (!out) {
- compile_error(ctx, "internal error: failed to generate division");
- return false;
- }
- out = (ast_expression*)ast_binary_new(ctx, INSTR_MUL_VF, exprs[0], out);
+ ast_type_to_string(exprs[0], ty1, sizeof(ty1));
+ ast_type_to_string(exprs[1], ty2, sizeof(ty2));
+ compile_error(ctx, "invalid types used in expression: cannot divide types %s and %s", ty1, ty2);
+ return false;
}
}
- else
- {
- ast_type_to_string(exprs[0], ty1, sizeof(ty1));
- ast_type_to_string(exprs[1], ty2, sizeof(ty2));
- compile_error(ctx, "invalid types used in expression: cannot divide tyeps %s and %s", ty1, ty2);
- return false;
- }
break;
case opid1('%'):
type_name[exprs[0]->vtype],
type_name[exprs[1]->vtype]);
return false;
- }
- if (CanConstFold(exprs[0], exprs[1])) {
- out = (ast_expression*)parser_const_float(parser,
- (float)(((qcint)ConstF(0)) % ((qcint)ConstF(1))));
- } else {
+ } else if (!(out = fold_op(parser->fold, op, exprs))) {
/* generate a call to __builtin_mod */
- ast_expression *mod = intrin_func(parser, "mod");
+ ast_expression *mod = intrin_func(parser->intrin, "mod");
ast_call *call = NULL;
if (!mod) return false; /* can return null for missing floor */
case opid1('|'):
case opid1('&'):
- if (NotSameType(TYPE_FLOAT)) {
- compile_error(ctx, "invalid types used in expression: cannot perform bit operations between types %s and %s",
- type_name[exprs[0]->vtype],
- type_name[exprs[1]->vtype]);
- return false;
- }
- if (CanConstFold(exprs[0], exprs[1]))
- out = (ast_expression*)parser_const_float(parser,
- (op->id == opid1('|') ? (float)( ((qcint)ConstF(0)) | ((qcint)ConstF(1)) ) :
- (float)( ((qcint)ConstF(0)) & ((qcint)ConstF(1)) ) ));
- else
- out = (ast_expression*)ast_binary_new(ctx,
- (op->id == opid1('|') ? INSTR_BITOR : INSTR_BITAND),
- exprs[0], exprs[1]);
- break;
case opid1('^'):
- /*
- * Okay lets designate what the hell is an acceptable use
- * of the ^ operator. In many vector processing units, XOR
- * is allowed to be used on vectors, but only if the first
- * operand is a vector, the second operand can be a float
- * or vector. It's never legal for the first operand to be
- * a float, and then the following operand to be a vector.
- * Further more, the only time it is legal to do XOR otherwise
- * is when both operand are floats. This nicely crafted if
- * statement catches them all.
- *
- * In the event that the first operand is a vector, two
- * possible situations can arise, thus, each element of
- * vector A (operand A) is exclusive-ORed with the corresponding
- * element of vector B (operand B), If B is scalar, the
- * scalar value is first replicated for each element.
- *
- * The QCVM itself lacks a BITXOR instruction. Thus emulating
- * the mathematics of it is required. The following equation
- * is used: (LHS | RHS) & ~(LHS & RHS). However, due to the
- * QCVM also lacking a BITNEG instruction, we need to emulate
- * ~FOO with -1 - FOO, the whole process becoming this nicely
- * crafted expression: (LHS | RHS) & (-1 - (LHS & RHS)).
- *
- * When A is not scalar, this process is repeated for all
- * components of vector A with the value in operand B,
- * only if operand B is scalar. When A is not scalar, and B
- * is also not scalar, this process is repeated for all
- * components of the vector A with the components of vector B.
- * Finally when A is scalar and B is scalar, this process is
- * simply used once for A and B being LHS and RHS respectfully.
- *
- * Yes the semantics are a bit strange (no pun intended).
- * But then again BITXOR is strange itself, consdering it's
- * commutative, assocative, and elements of the BITXOR operation
- * are their own inverse.
- */
if ( !(exprs[0]->vtype == TYPE_FLOAT && exprs[1]->vtype == TYPE_FLOAT) &&
!(exprs[0]->vtype == TYPE_VECTOR && exprs[1]->vtype == TYPE_FLOAT) &&
!(exprs[0]->vtype == TYPE_VECTOR && exprs[1]->vtype == TYPE_VECTOR))
return false;
}
- /*
- * IF the first expression is float, the following will be too
- * since scalar ^ vector is not allowed.
- */
- if (exprs[0]->vtype == TYPE_FLOAT) {
- if(CanConstFold(exprs[0], exprs[1])) {
- out = (ast_expression*)parser_const_float(parser, (float)((qcint)(ConstF(0)) ^ ((qcint)(ConstF(1)))));
- } else {
- ast_binary *expr = ast_binary_new(
- ctx,
- INSTR_SUB_F,
- (ast_expression*)parser_const_float_neg1(parser),
- (ast_expression*)ast_binary_new(
- ctx,
- INSTR_BITAND,
- exprs[0],
- exprs[1]
- )
- );
- expr->refs = AST_REF_NONE;
-
- out = (ast_expression*)
- ast_binary_new(
- ctx,
- INSTR_BITAND,
- (ast_expression*)ast_binary_new(
- ctx,
- INSTR_BITOR,
- exprs[0],
- exprs[1]
- ),
- (ast_expression*)expr
- );
- out->refs = AST_REF_LEFT;
- }
- } else {
+ if (!(out = fold_op(parser->fold, op, exprs))) {
/*
- * The first is a vector: vector is allowed to xor with vector and
- * with scalar, branch here for the second operand.
+ * IF the first expression is float, the following will be too
+ * since scalar ^ vector is not allowed.
*/
- if (exprs[1]->vtype == TYPE_VECTOR) {
- /*
- * Xor all the values of the vector components against the
- * vectors components in question.
- */
- if (CanConstFold(exprs[0], exprs[1])) {
- out = (ast_expression*)parser_const_vector_f(
- parser,
- (float)(((qcint)(ConstV(0).x)) ^ ((qcint)(ConstV(1).x))),
- (float)(((qcint)(ConstV(0).y)) ^ ((qcint)(ConstV(1).y))),
- (float)(((qcint)(ConstV(0).z)) ^ ((qcint)(ConstV(1).z)))
- );
- } else {
- compile_error(ast_ctx(exprs[0]), "Not Yet Implemented: bit-xor for vector against vector");
- return false;
- }
+ if (exprs[0]->vtype == TYPE_FLOAT) {
+ out = (ast_expression*)ast_binary_new(ctx,
+ (op->id == opid1('^') ? VINSTR_BITXOR : op->id == opid1('|') ? INSTR_BITOR : INSTR_BITAND),
+ exprs[0], exprs[1]);
} else {
/*
- * Xor all the values of the vector components against the
- * scalar in question.
+ * The first is a vector: vector is allowed to bitop with vector and
+ * with scalar, branch here for the second operand.
*/
- if (CanConstFold(exprs[0], exprs[1])) {
- out = (ast_expression*)parser_const_vector_f(
- parser,
- (float)(((qcint)(ConstV(0).x)) ^ ((qcint)(ConstF(1)))),
- (float)(((qcint)(ConstV(0).y)) ^ ((qcint)(ConstF(1)))),
- (float)(((qcint)(ConstV(0).z)) ^ ((qcint)(ConstF(1))))
- );
+ if (exprs[1]->vtype == TYPE_VECTOR) {
+ /*
+ * Bitop all the values of the vector components against the
+ * vectors components in question.
+ */
+ out = (ast_expression*)ast_binary_new(ctx,
+ (op->id == opid1('^') ? VINSTR_BITXOR_V : op->id == opid1('|') ? VINSTR_BITOR_V : VINSTR_BITAND_V),
+ exprs[0], exprs[1]);
} else {
- compile_error(ast_ctx(exprs[0]), "Not Yet Implemented: bit-xor for vector against float");
- return false;
+ out = (ast_expression*)ast_binary_new(ctx,
+ (op->id == opid1('^') ? VINSTR_BITXOR_VF : op->id == opid1('|') ? VINSTR_BITOR_VF : VINSTR_BITAND_VF),
+ exprs[0], exprs[1]);
}
}
}
-
break;
case opid2('<','<'):
case opid2('>','>'):
- if (CanConstFold(exprs[0], exprs[1]) && ! NotSameType(TYPE_FLOAT)) {
- if (op->id == opid2('<','<'))
- out = (ast_expression*)parser_const_float(parser, (double)((unsigned int)(ConstF(0)) << (unsigned int)(ConstF(1))));
- else
- out = (ast_expression*)parser_const_float(parser, (double)((unsigned int)(ConstF(0)) >> (unsigned int)(ConstF(1))));
- break;
- }
case opid3('<','<','='):
case opid3('>','>','='):
- compile_error(ast_ctx(exprs[0]), "Not Yet Implemented: bit-shifts");
- return false;
+ if(!(out = fold_op(parser->fold, op, exprs))) {
+ compile_error(ast_ctx(exprs[0]), "Not Yet Implemented: bit-shifts");
+ return false;
+ }
+ break;
case opid2('|','|'):
generated_op += 1; /* INSTR_OR */
case opid2('&','&'):
generated_op += INSTR_AND;
- if (CanConstFold(exprs[0], exprs[1]))
- {
- if (OPTS_FLAG(PERL_LOGIC)) {
- if (immediate_is_true(ctx, asvalue[0]))
- out = exprs[1];
- }
- else
- out = (ast_expression*)parser_const_float(parser,
- ( (generated_op == INSTR_OR)
- ? (immediate_is_true(ctx, asvalue[0]) || immediate_is_true(ctx, asvalue[1]))
- : (immediate_is_true(ctx, asvalue[0]) && immediate_is_true(ctx, asvalue[1])) )
- ? 1 : 0);
- }
- else
- {
+ if (!(out = fold_op(parser->fold, op, exprs))) {
if (OPTS_FLAG(PERL_LOGIC) && !ast_compare_type(exprs[0], exprs[1])) {
ast_type_to_string(exprs[0], ty1, sizeof(ty1));
ast_type_to_string(exprs[1], ty2, sizeof(ty2));
compile_error(ctx, "operands of ternary expression must have the same type, got %s and %s", ty1, ty2);
return false;
}
- if (CanConstFold1(exprs[0]))
- out = (immediate_is_true(ctx, asvalue[0]) ? exprs[1] : exprs[2]);
- else
+ if (!(out = fold_op(parser->fold, op, exprs)))
out = (ast_expression*)ast_ternary_new(ctx, exprs[0], exprs[1], exprs[2]);
break;
ast_type_to_string(exprs[1], ty2, sizeof(ty2));
compile_error(ctx, "invalid types used in exponentiation: %s and %s",
ty1, ty2);
-
return false;
}
- if (CanConstFold(exprs[0], exprs[1])) {
- out = (ast_expression*)parser_const_float(parser, powf(ConstF(0), ConstF(1)));
- } else {
- ast_call *gencall = ast_call_new(parser_ctx(parser), intrin_func(parser, "pow"));
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ ast_call *gencall = ast_call_new(parser_ctx(parser), intrin_func(parser->intrin, "pow"));
vec_push(gencall->params, exprs[0]);
vec_push(gencall->params, exprs[1]);
out = (ast_expression*)gencall;
}
break;
+ case opid2('>', '<'):
+ if (NotSameType(TYPE_VECTOR)) {
+ ast_type_to_string(exprs[0], ty1, sizeof(ty1));
+ ast_type_to_string(exprs[1], ty2, sizeof(ty2));
+ compile_error(ctx, "invalid types used in cross product: %s and %s",
+ ty1, ty2);
+ return false;
+ }
+
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ out = (ast_expression*)ast_binary_new(
+ parser_ctx(parser),
+ VINSTR_CROSS,
+ exprs[0],
+ exprs[1]
+ );
+ }
+
+ break;
+
case opid3('<','=','>'): /* -1, 0, or 1 */
if (NotSameType(TYPE_FLOAT)) {
ast_type_to_string(exprs[0], ty1, sizeof(ty1));
return false;
}
- if (CanConstFold(exprs[0], exprs[1])) {
- if (ConstF(0) < ConstF(1))
- out = (ast_expression*)parser_const_float_neg1(parser);
- else if (ConstF(0) == ConstF(1))
- out = (ast_expression*)parser_const_float_0(parser);
- else if (ConstF(0) > ConstF(1))
- out = (ast_expression*)parser_const_float_1(parser);
- } else {
+ if (!(out = fold_op(parser->fold, op, exprs))) {
ast_binary *eq = ast_binary_new(ctx, INSTR_EQ_F, exprs[0], exprs[1]);
eq->refs = AST_REF_NONE;
out = (ast_expression*)ast_ternary_new(ctx,
(ast_expression*)ast_binary_new(ctx, INSTR_LT, exprs[0], exprs[1]),
/* out = -1 */
- (ast_expression*)parser_const_float_neg1(parser),
+ (ast_expression*)parser->fold->imm_float[2],
/* } else { */
/* if (eq) { */
(ast_expression*)ast_ternary_new(ctx, (ast_expression*)eq,
/* out = 0 */
- (ast_expression*)parser_const_float_0(parser),
+ (ast_expression*)parser->fold->imm_float[0],
/* } else { */
/* out = 1 */
- (ast_expression*)parser_const_float_1(parser)
+ (ast_expression*)parser->fold->imm_float[1]
/* } */
)
/* } */
type_name[exprs[1]->vtype]);
return false;
}
- out = (ast_expression*)ast_binary_new(ctx, generated_op, exprs[0], exprs[1]);
+ if (!(out = fold_op(parser->fold, op, exprs)))
+ out = (ast_expression*)ast_binary_new(ctx, generated_op, exprs[0], exprs[1]);
break;
case opid2('!', '='):
if (exprs[0]->vtype != exprs[1]->vtype) {
type_name[exprs[1]->vtype]);
return false;
}
- out = (ast_expression*)ast_binary_new(ctx, type_ne_instr[exprs[0]->vtype], exprs[0], exprs[1]);
+ if (!(out = fold_op(parser->fold, op, exprs)))
+ out = (ast_expression*)ast_binary_new(ctx, type_ne_instr[exprs[0]->vtype], exprs[0], exprs[1]);
break;
case opid2('=', '='):
if (exprs[0]->vtype != exprs[1]->vtype) {
type_name[exprs[1]->vtype]);
return false;
}
- out = (ast_expression*)ast_binary_new(ctx, type_eq_instr[exprs[0]->vtype], exprs[0], exprs[1]);
+ if (!(out = fold_op(parser->fold, op, exprs)))
+ out = (ast_expression*)ast_binary_new(ctx, type_eq_instr[exprs[0]->vtype], exprs[0], exprs[1]);
break;
case opid1('='):
compile_error(ctx, "invalid types in assignment: cannot assign %s to %s", ty2, ty1);
}
}
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ctx, "assignment to constant `%s`", asvalue[0]->name);
- }
+ (void)check_write_to(ctx, exprs[0]);
out = (ast_expression*)ast_store_new(ctx, assignop, exprs[0], exprs[1]);
break;
case opid3('+','+','P'):
addop = INSTR_ADD_F;
else
addop = INSTR_SUB_F;
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ast_ctx(exprs[0]), "assignment to constant `%s`", asvalue[0]->name);
- }
+ (void)check_write_to(ast_ctx(exprs[0]), exprs[0]);
if (ast_istype(exprs[0], ast_entfield)) {
out = (ast_expression*)ast_binstore_new(ctx, INSTR_STOREP_F, addop,
exprs[0],
- (ast_expression*)parser_const_float_1(parser));
+ (ast_expression*)parser->fold->imm_float[1]);
} else {
out = (ast_expression*)ast_binstore_new(ctx, INSTR_STORE_F, addop,
exprs[0],
- (ast_expression*)parser_const_float_1(parser));
+ (ast_expression*)parser->fold->imm_float[1]);
}
break;
case opid3('S','+','+'):
addop = INSTR_SUB_F;
subop = INSTR_ADD_F;
}
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ast_ctx(exprs[0]), "assignment to constant `%s`", asvalue[0]->name);
- }
+ (void)check_write_to(ast_ctx(exprs[0]), exprs[0]);
if (ast_istype(exprs[0], ast_entfield)) {
out = (ast_expression*)ast_binstore_new(ctx, INSTR_STOREP_F, addop,
exprs[0],
- (ast_expression*)parser_const_float_1(parser));
+ (ast_expression*)parser->fold->imm_float[1]);
} else {
out = (ast_expression*)ast_binstore_new(ctx, INSTR_STORE_F, addop,
exprs[0],
- (ast_expression*)parser_const_float_1(parser));
+ (ast_expression*)parser->fold->imm_float[1]);
}
if (!out)
return false;
out = (ast_expression*)ast_binary_new(ctx, subop,
out,
- (ast_expression*)parser_const_float_1(parser));
+ (ast_expression*)parser->fold->imm_float[1]);
break;
case opid2('+','='):
case opid2('-','='):
ty1, ty2);
return false;
}
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ctx, "assignment to constant `%s`", asvalue[0]->name);
- }
+ (void)check_write_to(ctx, exprs[0]);
if (ast_istype(exprs[0], ast_entfield))
assignop = type_storep_instr[exprs[0]->vtype];
else
ty1, ty2);
return false;
}
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ctx, "assignment to constant `%s`", asvalue[0]->name);
- }
+ (void)check_write_to(ctx, exprs[0]);
if (ast_istype(exprs[0], ast_entfield))
assignop = type_storep_instr[exprs[0]->vtype];
else
out = (ast_expression*)ast_binstore_new(ctx, assignop, INSTR_MUL_VF,
exprs[0], exprs[1]);
} else {
- /* there's no DIV_VF */
- if (CanConstFold1(exprs[1])) {
- out = (ast_expression*)parser_const_float(parser, 1.0 / ConstF(1));
- } else {
- out = (ast_expression*)ast_binary_new(ctx, INSTR_DIV_F,
- (ast_expression*)parser_const_float_1(parser),
+ out = (ast_expression*)ast_binary_new(ctx, INSTR_DIV_F,
+ (ast_expression*)parser->fold->imm_float[1],
exprs[1]);
- }
if (!out) {
compile_error(ctx, "internal error: failed to generate division");
return false;
break;
case opid2('&','='):
case opid2('|','='):
- if (NotSameType(TYPE_FLOAT)) {
+ case opid2('^','='):
+ if (NotSameType(TYPE_FLOAT) && NotSameType(TYPE_VECTOR)) {
ast_type_to_string(exprs[0], ty1, sizeof(ty1));
ast_type_to_string(exprs[1], ty2, sizeof(ty2));
compile_error(ctx, "invalid types used in expression: %s and %s",
ty1, ty2);
return false;
}
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ctx, "assignment to constant `%s`", asvalue[0]->name);
- }
+ (void)check_write_to(ctx, exprs[0]);
if (ast_istype(exprs[0], ast_entfield))
assignop = type_storep_instr[exprs[0]->vtype];
else
assignop = type_store_instr[exprs[0]->vtype];
- out = (ast_expression*)ast_binstore_new(ctx, assignop,
- (op->id == opid2('&','=') ? INSTR_BITAND : INSTR_BITOR),
- exprs[0], exprs[1]);
+ if (exprs[0]->vtype == TYPE_FLOAT)
+ out = (ast_expression*)ast_binstore_new(ctx, assignop,
+ (op->id == opid2('^','=') ? VINSTR_BITXOR : op->id == opid2('&','=') ? INSTR_BITAND : INSTR_BITOR),
+ exprs[0], exprs[1]);
+ else
+ out = (ast_expression*)ast_binstore_new(ctx, assignop,
+ (op->id == opid2('^','=') ? VINSTR_BITXOR_V : op->id == opid2('&','=') ? VINSTR_BITAND_V : VINSTR_BITOR_V),
+ exprs[0], exprs[1]);
break;
case opid3('&','~','='):
/* This is like: a &= ~(b);
* But QC has no bitwise-not, so we implement it as
* a -= a & (b);
*/
- if (NotSameType(TYPE_FLOAT)) {
+ if (NotSameType(TYPE_FLOAT) && NotSameType(TYPE_VECTOR)) {
ast_type_to_string(exprs[0], ty1, sizeof(ty1));
ast_type_to_string(exprs[1], ty2, sizeof(ty2));
compile_error(ctx, "invalid types used in expression: %s and %s",
assignop = type_storep_instr[exprs[0]->vtype];
else
assignop = type_store_instr[exprs[0]->vtype];
- out = (ast_expression*)ast_binary_new(ctx, INSTR_BITAND, exprs[0], exprs[1]);
+ if (exprs[0]->vtype == TYPE_FLOAT)
+ out = (ast_expression*)ast_binary_new(ctx, INSTR_BITAND, exprs[0], exprs[1]);
+ else
+ out = (ast_expression*)ast_binary_new(ctx, VINSTR_BITAND_V, exprs[0], exprs[1]);
if (!out)
return false;
- if (ast_istype(exprs[0], ast_value) && asvalue[0]->cvq == CV_CONST) {
- compile_error(ctx, "assignment to constant `%s`", asvalue[0]->name);
- }
- asbinstore = ast_binstore_new(ctx, assignop, INSTR_SUB_F, exprs[0], out);
+ (void)check_write_to(ctx, exprs[0]);
+ if (exprs[0]->vtype == TYPE_FLOAT)
+ asbinstore = ast_binstore_new(ctx, assignop, INSTR_SUB_F, exprs[0], out);
+ else
+ asbinstore = ast_binstore_new(ctx, assignop, INSTR_SUB_V, exprs[0], out);
asbinstore->keep_dest = true;
out = (ast_expression*)asbinstore;
break;
case opid2('~', 'P'):
- if (exprs[0]->vtype != TYPE_FLOAT) {
+ if (exprs[0]->vtype != TYPE_FLOAT && exprs[0]->vtype != TYPE_VECTOR) {
ast_type_to_string(exprs[0], ty1, sizeof(ty1));
compile_error(ast_ctx(exprs[0]), "invalid type for bit not: %s", ty1);
return false;
}
-
- if(CanConstFold1(exprs[0]))
- out = (ast_expression*)parser_const_float(parser, ~(qcint)ConstF(0));
- else
- out = (ast_expression*)
- ast_binary_new(ctx, INSTR_SUB_F, (ast_expression*)parser_const_float_neg1(parser), exprs[0]);
+ if (!(out = fold_op(parser->fold, op, exprs))) {
+ if (exprs[0]->vtype == TYPE_FLOAT) {
+ out = (ast_expression*)ast_binary_new(ctx, INSTR_SUB_F, (ast_expression*)parser->fold->imm_float[2], exprs[0]);
+ } else {
+ out = (ast_expression*)ast_binary_new(ctx, INSTR_SUB_V, (ast_expression*)parser->fold->imm_vector[1], exprs[0]);
+ }
+ }
break;
}
#undef NotSameType
-
if (!out) {
compile_error(ctx, "failed to apply operator %s", op->op);
return false;
size_t fid;
size_t paramcount, i;
+ bool fold = true;
fid = vec_last(sy->ops).off;
vec_shrinkby(sy->ops, 1);
return false;
}
- fun = sy->out[fid].out;
-
- if (fun == intrinsic_debug_typestring) {
+ /*
+ * TODO handle this at the intrinsic level with an ast_intrinsic
+ * node and codegen.
+ */
+ if ((fun = sy->out[fid].out) == intrin_debug_typestring(parser->intrin)) {
char ty[1024];
if (fid+2 != vec_size(sy->out) ||
vec_last(sy->out).block)
ast_type_to_string(vec_last(sy->out).out, ty, sizeof(ty));
ast_unref(vec_last(sy->out).out);
sy->out[fid] = syexp(ast_ctx(vec_last(sy->out).out),
- (ast_expression*)parser_const_string(parser, ty, false));
+ (ast_expression*)fold_constgen_string(parser->fold, ty, false));
+ vec_shrinkby(sy->out, 1);
+ return true;
+ }
+
+ /*
+ * Now we need to determine if the function that is being called is
+ * an intrinsic so we can evaluate if the arguments to it are constant
+ * and than fruitfully fold them.
+ */
+#define fold_can_1(X) \
+ (ast_istype(((ast_expression*)(X)), ast_value) && (X)->hasvalue && ((X)->cvq == CV_CONST) && \
+ ((ast_expression*)(X))->vtype != TYPE_FUNCTION)
+
+ if (fid + 1 < vec_size(sy->out))
+ ++paramcount;
+
+ for (i = 0; i < paramcount; ++i) {
+ if (!fold_can_1((ast_value*)sy->out[fid + 1 + i].out)) {
+ fold = false;
+ break;
+ }
+ }
+
+ /*
+ * All is well which ends well, if we make it into here we can ignore the
+ * intrinsic call and just evaluate it i.e constant fold it.
+ */
+ if (fold && ast_istype(fun, ast_value) && ((ast_value*)fun)->intrinsic) {
+ ast_expression **exprs = NULL;
+ ast_expression *foldval = NULL;
+
+ for (i = 0; i < paramcount; i++)
+ vec_push(exprs, sy->out[fid+1 + i].out);
+
+ if (!(foldval = intrin_fold(parser->intrin, (ast_value*)fun, exprs))) {
+ vec_free(exprs);
+ goto fold_leave;
+ }
+
+ /*
+ * Blub: what sorts of unreffing and resizing of
+ * sy->out should I be doing here?
+ */
+ sy->out[fid] = syexp(foldval->node.context, foldval);
vec_shrinkby(sy->out, 1);
+ vec_free(exprs);
+
return true;
}
+ fold_leave:
call = ast_call_new(sy->ops[vec_size(sy->ops)].ctx, fun);
+
if (!call)
return false;
- if (fid+1 < vec_size(sy->out))
- ++paramcount;
-
if (fid+1 + paramcount != vec_size(sy->out)) {
parseerror(parser, "internal error: parameter count mismatch: (%lu+1+%lu), %lu",
(unsigned long)fid, (unsigned long)paramcount, (unsigned long)vec_size(sy->out));
if ((fun->flags & AST_FLAG_VARIADIC) &&
!(/*funval->cvq == CV_CONST && */ funval->hasvalue && funval->constval.vfunc->builtin))
{
- call->va_count = (ast_expression*)parser_const_float(parser, (double)paramcount);
+ call->va_count = (ast_expression*)fold_constgen_float(parser->fold, (qcfloat_t)paramcount);
}
}
static void parser_reclassify_token(parser_t *parser)
{
size_t i;
+ if (parser->tok >= TOKEN_START)
+ return;
for (i = 0; i < operator_count; ++i) {
if (!strcmp(parser_tokval(parser), operators[i].op)) {
parser->tok = TOKEN_OPERATOR;
ast_expression *idx, *out;
ast_value *typevar;
ast_value *funtype = parser->function->vtype;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
if (!parser->function->varargs) {
parseerror(parser, "function has no variable argument list");
}
/* not to be exposed */
-extern bool ftepp_predef_exists(const char *name);
-
+bool ftepp_predef_exists(const char *name);
static bool parse_sya_operand(parser_t *parser, shunt *sy, bool with_labels)
{
if (OPTS_FLAG(TRANSLATABLE_STRINGS) &&
parseerror(parser, "expected a constant string in translatable-string extension");
return false;
}
- val = parser_const_string(parser, parser_tokval(parser), true);
+ val = (ast_value*)fold_constgen_string(parser->fold, parser_tokval(parser), true);
if (!val)
return false;
vec_push(sy->out, syexp(parser_ctx(parser), (ast_expression*)val));
return true;
}
else if (parser->tok == TOKEN_FLOATCONST) {
- ast_value *val;
- val = parser_const_float(parser, (parser_token(parser)->constval.f));
+ ast_expression *val = fold_constgen_float(parser->fold, (parser_token(parser)->constval.f));
if (!val)
return false;
- vec_push(sy->out, syexp(parser_ctx(parser), (ast_expression*)val));
+ vec_push(sy->out, syexp(parser_ctx(parser), val));
return true;
}
else if (parser->tok == TOKEN_INTCONST || parser->tok == TOKEN_CHARCONST) {
- ast_value *val;
- val = parser_const_float(parser, (double)(parser_token(parser)->constval.i));
+ ast_expression *val = fold_constgen_float(parser->fold, (qcfloat_t)(parser_token(parser)->constval.i));
if (!val)
return false;
- vec_push(sy->out, syexp(parser_ctx(parser), (ast_expression*)val));
+ vec_push(sy->out, syexp(parser_ctx(parser), val));
return true;
}
else if (parser->tok == TOKEN_STRINGCONST) {
- ast_value *val;
- val = parser_const_string(parser, parser_tokval(parser), false);
+ ast_expression *val = fold_constgen_string(parser->fold, parser_tokval(parser), false);
if (!val)
return false;
- vec_push(sy->out, syexp(parser_ctx(parser), (ast_expression*)val));
+ vec_push(sy->out, syexp(parser_ctx(parser), val));
return true;
}
else if (parser->tok == TOKEN_VECTORCONST) {
- ast_value *val;
- val = parser_const_vector(parser, parser_token(parser)->constval.v);
+ ast_expression *val = fold_constgen_vector(parser->fold, parser_token(parser)->constval.v);
if (!val)
return false;
- vec_push(sy->out, syexp(parser_ctx(parser), (ast_expression*)val));
+ vec_push(sy->out, syexp(parser_ctx(parser), val));
return true;
}
else if (parser->tok == TOKEN_IDENT)
/* a_vector.{x,y,z} */
if (!vec_size(sy->ops) ||
!vec_last(sy->ops).etype ||
- operators[vec_last(sy->ops).etype-1].id != opid1('.') ||
- (prev >= intrinsic_debug_typestring &&
- prev <= intrinsic_debug_typestring))
+ operators[vec_last(sy->ops).etype-1].id != opid1('.'))
{
/* When adding more intrinsics, fix the above condition */
prev = NULL;
}
}
if (!var && !strcmp(parser_tokval(parser), "__FUNC__"))
- var = (ast_expression*)parser_const_string(parser, parser->function->name, false);
+ var = (ast_expression*)fold_constgen_string(parser->fold, parser->function->name, false);
if (!var) {
- /* intrinsics */
- if (!strcmp(parser_tokval(parser), "__builtin_debug_typestring")) {
- var = (ast_expression*)intrinsic_debug_typestring;
- }
- /* now we try for the real intrinsic hashtable. If the string
+ /*
+ * now we try for the real intrinsic hashtable. If the string
* begins with __builtin, we simply skip past it, otherwise we
* use the identifier as is.
*/
- else if (!strncmp(parser_tokval(parser), "__builtin_", 10)) {
- var = intrin_func(parser, parser_tokval(parser) + 10 /* skip __builtin */);
+ if (!strncmp(parser_tokval(parser), "__builtin_", 10)) {
+ var = intrin_func(parser->intrin, parser_tokval(parser));
}
if (!var) {
correct = correct_str(&corr, parser->correct_variables[i], parser_tokval(parser));
if (strcmp(correct, parser_tokval(parser))) {
break;
- } else if (correct) {
+ } else {
mem_d(correct);
correct = NULL;
}
/* only warn once about an assignment in a truth value because the current code
* would trigger twice on: if(a = b && ...), once for the if-truth-value, once for the && part
*/
- bool warn_truthvalue = true;
+ bool warn_parenthesis = true;
/* count the parens because an if starts with one, so the
* end of a condition is an unmatched closing paren
}
}
if (o == operator_count) {
- compile_error(parser_ctx(parser), "unknown operator: %s", parser_tokval(parser));
+ compile_error(parser_ctx(parser), "unexpected operator: %s", parser_tokval(parser));
goto onerr;
}
/* found an operator */
if (vec_size(sy.ops) && !vec_last(sy.ops).isparen)
olast = &operators[vec_last(sy.ops).etype-1];
+ /* first only apply higher precedences, assoc_left+equal comes after we warn about precedence rules */
+ while (olast && op->prec < olast->prec)
+ {
+ if (!parser_sy_apply_operator(parser, &sy))
+ goto onerr;
+ if (vec_size(sy.ops) && !vec_last(sy.ops).isparen)
+ olast = &operators[vec_last(sy.ops).etype-1];
+ else
+ olast = NULL;
+ }
+
#define IsAssignOp(x) (\
(x) == opid1('=') || \
(x) == opid2('+','=') || \
(x) == opid2('|','=') || \
(x) == opid3('&','~','=') \
)
- if (warn_truthvalue) {
+ if (warn_parenthesis) {
if ( (olast && IsAssignOp(olast->id) && (op->id == opid2('&','&') || op->id == opid2('|','|'))) ||
(olast && IsAssignOp(op->id) && (olast->id == opid2('&','&') || olast->id == opid2('|','|'))) ||
(truthvalue && !vec_size(sy.paren) && IsAssignOp(op->id))
)
{
(void)!parsewarning(parser, WARN_PARENTHESIS, "suggesting parenthesis around assignment used as truth value");
- warn_truthvalue = false;
+ warn_parenthesis = false;
+ }
+
+ if (olast && olast->id != op->id) {
+ if ((op->id == opid1('&') || op->id == opid1('|') || op->id == opid1('^')) &&
+ (olast->id == opid1('&') || olast->id == opid1('|') || olast->id == opid1('^')))
+ {
+ (void)!parsewarning(parser, WARN_PARENTHESIS, "suggesting parenthesis around bitwise operations");
+ warn_parenthesis = false;
+ }
+ else if ((op->id == opid2('&','&') || op->id == opid2('|','|')) &&
+ (olast->id == opid2('&','&') || olast->id == opid2('|','|')))
+ {
+ (void)!parsewarning(parser, WARN_PARENTHESIS, "suggesting parenthesis around logical operations");
+ warn_parenthesis = false;
+ }
}
}
{
char *newstr = NULL;
util_asprintf(&newstr, "%s%s", last->constval.vstring, parser_tokval(parser));
- vec_last(sy.out).out = (ast_expression*)parser_const_string(parser, newstr, false);
+ vec_last(sy.out).out = (ast_expression*)fold_constgen_string(parser->fold, newstr, false);
mem_d(newstr);
concatenated = true;
}
parser->lex->flags.noops = true;
if (vec_size(sy.out) != 1) {
- parseerror(parser, "expression with not 1 but %lu output values...", (unsigned long) vec_size(sy.out));
+ parseerror(parser, "expression expected");
expr = NULL;
} else
expr = sy.out[0].out;
}
unary = (ast_unary*)cond;
- while (ast_istype(cond, ast_unary) && unary->op == INSTR_NOT_F)
+ /* ast_istype dereferences cond, should test here for safety */
+ while (cond && ast_istype(cond, ast_unary) && unary->op == INSTR_NOT_F)
{
cond = unary->operand;
unary->operand = NULL;
ast_expression *cond, *ontrue = NULL, *onfalse = NULL;
bool ifnot = false;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
(void)block; /* not touching */
bool ifnot = false;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
(void)block; /* not touching */
if (vec_last(parser->breaks) != label || vec_last(parser->continues) != label) {
parseerror(parser, "internal error: label stack corrupted");
rv = false;
- ast_delete(*out);
+ /*
+ * Test for NULL otherwise ast_delete dereferences null pointer
+ * and boom.
+ */
+ if (*out)
+ ast_delete(*out);
*out = NULL;
}
else {
bool ifnot = false;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
(void)block; /* not touching */
bool ifnot = false;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
parser_enterblock(parser);
/* parse the incrementor */
if (parser->tok != ')') {
- lex_ctx condctx = parser_ctx(parser);
+ lex_ctx_t condctx = parser_ctx(parser);
increment = parse_expression_leave(parser, false, false, false);
if (!increment)
goto onerr;
ast_value *retval = parser->function->return_value;
ast_value *expected = parser->function->vtype;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
(void)block; /* not touching */
{
size_t i;
unsigned int levels = 0;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
const char **loops = (is_continue ? parser->continues : parser->breaks);
(void)block; /* not touching */
else if (!strcmp(parser_tokval(parser), "inline")) {
flags |= AST_FLAG_INLINE;
if (!parser_next(parser) || parser->tok != TOKEN_ATTRIBUTE_CLOSE) {
- parseerror(parser, "`noref` attribute has no parameters, expected `]]`");
+ parseerror(parser, "`inline` attribute has no parameters, expected `]]`");
+ *cvq = CV_WRONG;
+ return false;
+ }
+ }
+ else if (!strcmp(parser_tokval(parser), "eraseable")) {
+ flags |= AST_FLAG_ERASEABLE;
+ if (!parser_next(parser) || parser->tok != TOKEN_ATTRIBUTE_CLOSE) {
+ parseerror(parser, "`eraseable` attribute has no parameters, expected `]]`");
*cvq = CV_WRONG;
return false;
}
bool noref, is_static;
uint32_t qflags = 0;
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
(void)block; /* not touching */
(void)opval;
if (!(expression = parse_expression(parser, false, true)) ||
!(*out = parse_goto_computed(parser, &expression))) {
parseerror(parser, "invalid goto expression");
- ast_unref(expression);
+ if(expression)
+ ast_unref(expression);
return false;
}
else
{
(void)!parsewarning(parser, WARN_UNKNOWN_PRAGMAS, "ignoring #pragma %s", parser_tokval(parser));
- return false;
+
+ /* skip to eol */
+ while (!parse_eol(parser)) {
+ parser_next(parser);
+ }
+
+ return true;
}
return true;
}
else
{
- lex_ctx ctx = parser_ctx(parser);
+ lex_ctx_t ctx = parser_ctx(parser);
ast_expression *exp = parse_expression(parser, false, false);
if (!exp)
return false;
{
bool flag = false;
bool reverse = false;
- qcfloat num = 0;
+ qcfloat_t num = 0;
ast_value **values = NULL;
ast_value *var = NULL;
ast_value *asvalue;
}
if (has_frame_think) {
- lex_ctx ctx;
+ lex_ctx_t ctx;
ast_expression *self_frame;
ast_expression *self_nextthink;
ast_expression *self_think;
self_think = (ast_expression*)ast_entfield_new(ctx, gbl_self, fld_think);
time_plus_1 = (ast_expression*)ast_binary_new(ctx, INSTR_ADD_F,
- gbl_time, (ast_expression*)parser_const_float(parser, 0.1));
+ gbl_time, (ast_expression*)fold_constgen_float(parser->fold, 0.1f));
if (!self_frame || !self_nextthink || !self_think || !time_plus_1) {
if (self_frame) ast_delete(self_frame);
ast_block_delete(block);
goto enderrfn;
}
- func->varargs = varargs;
-
- func->fixedparams = parser_const_float(parser, vec_size(var->expression.params));
+ func->varargs = varargs;
+ func->fixedparams = (ast_value*)fold_constgen_float(parser->fold, vec_size(var->expression.params));
}
parser->function = func;
ast_ifthen *ifthen;
ast_binary *cmp;
- lex_ctx ctx = ast_ctx(array);
+ lex_ctx_t ctx = ast_ctx(array);
if (!left || !right) {
if (left) ast_delete(left);
cmp = ast_binary_new(ctx, INSTR_LT,
(ast_expression*)index,
- (ast_expression*)parser_const_float(parser, middle));
+ (ast_expression*)fold_constgen_float(parser->fold, middle));
if (!cmp) {
ast_delete(left);
ast_delete(right);
static ast_expression *array_setter_node(parser_t *parser, ast_value *array, ast_value *index, ast_value *value, size_t from, size_t afterend)
{
- lex_ctx ctx = ast_ctx(array);
+ lex_ctx_t ctx = ast_ctx(array);
if (from+1 == afterend) {
/* set this value */
if (value->expression.vtype == TYPE_FIELD && value->expression.next->vtype == TYPE_VECTOR)
assignop = INSTR_STORE_V;
- subscript = ast_array_index_new(ctx, (ast_expression*)array, (ast_expression*)parser_const_float(parser, from));
+ subscript = ast_array_index_new(ctx, (ast_expression*)array, (ast_expression*)fold_constgen_float(parser->fold, from));
if (!subscript)
return NULL;
size_t from,
size_t afterend)
{
- lex_ctx ctx = ast_ctx(array);
+ lex_ctx_t ctx = ast_ctx(array);
if (from+1 == afterend) {
/* set this value */
if (value->expression.vtype == TYPE_FIELD && value->expression.next->vtype == TYPE_VECTOR)
assignop = INSTR_STOREP_V;
- subscript = ast_array_index_new(ctx, (ast_expression*)array, (ast_expression*)parser_const_float(parser, from));
+ subscript = ast_array_index_new(ctx, (ast_expression*)array, (ast_expression*)fold_constgen_float(parser->fold, from));
if (!subscript)
return NULL;
static ast_expression *array_getter_node(parser_t *parser, ast_value *array, ast_value *index, size_t from, size_t afterend)
{
- lex_ctx ctx = ast_ctx(array);
+ lex_ctx_t ctx = ast_ctx(array);
if (from+1 == afterend) {
ast_return *ret;
ast_array_index *subscript;
- subscript = ast_array_index_new(ctx, (ast_expression*)array, (ast_expression*)parser_const_float(parser, from));
+ subscript = ast_array_index_new(ctx, (ast_expression*)array, (ast_expression*)fold_constgen_float(parser->fold, from));
if (!subscript)
return NULL;
static ast_value *parse_typename(parser_t *parser, ast_value **storebase, ast_value *cached_typedef);
static ast_value *parse_parameter_list(parser_t *parser, ast_value *var)
{
- lex_ctx ctx;
+ lex_ctx_t ctx;
size_t i;
ast_value **params;
ast_value *param;
{
ast_expression *cexp;
ast_value *cval, *tmp;
- lex_ctx ctx;
+ lex_ctx_t ctx;
ctx = parser_ctx(parser);
* The base type makes up every bit of type information which comes *before* the
* variable name.
*
+ * NOTE: The value must either be named, have a NULL name, or a name starting
+ * with '<'. In the first case, this will be the actual variable or type
+ * name, in the other cases it is assumed that the name will appear
+ * later, and an error is generated otherwise.
+ *
* The following will be parsed in its entirety:
* void() foo()
* The 'basetype' in this case is 'void()'
static ast_value *parse_typename(parser_t *parser, ast_value **storebase, ast_value *cached_typedef)
{
ast_value *var, *tmp;
- lex_ctx ctx;
+ lex_ctx_t ctx;
const char *name = NULL;
bool isfield = false;
if (!typevar)
return false;
+ /* while parsing types, the ast_value's get named '<something>' */
+ if (!typevar->name || typevar->name[0] == '<') {
+ parseerror(parser, "missing name in typedef");
+ ast_delete(typevar);
+ return false;
+ }
+
if ( (old = parser_find_var(parser, typevar->name)) ) {
parseerror(parser, "cannot define a type with the same name as a variable: %s\n"
" -> `%s` has been declared here: %s:%i",
return false;
}
+ /* while parsing types, the ast_value's get named '<something>' */
+ if (!var->name || var->name[0] == '<') {
+ parseerror(parser, "declaration does not declare anything");
+ if (basetype)
+ ast_delete(basetype);
+ return false;
+ }
+
while (true) {
proto = NULL;
wasarray = false;
retval = false;
goto cleanup;
}
+ /* doing this here as the above is just for a single scope */
old = parser_find_local(parser, var->name, 0, &isparam);
if (old && isparam) {
if (parsewarning(parser, WARN_LOCAL_SHADOWS,
}
if (OPTS_OPTION_U32(OPTION_STANDARD) != COMPILER_GMQCC) {
ast_delete(var);
- var = NULL;
- goto skipvar;
+ if (ast_istype(old, ast_value))
+ var = proto = (ast_value*)old;
+ else {
+ var = NULL;
+ goto skipvar;
+ }
}
}
}
return false;
}
- if (var->expression.vtype != find->vtype) {
+ if (!ast_compare_type((ast_expression*)var, find)) {
char ty1[1024];
char ty2[1024];
if (parser->tok != '{' || var->expression.vtype != TYPE_FUNCTION) {
if (parser->tok != '=') {
- parseerror(parser, "missing semicolon or initializer, got: `%s`", parser_tokval(parser));
- break;
+ if (!strcmp(parser_tokval(parser), "break")) {
+ if (!parser_next(parser)) {
+ parseerror(parser, "error parsing break definition");
+ break;
+ }
+ (void)!parsewarning(parser, WARN_BREAKDEF, "break definition ignored (suggest removing it)");
+ } else {
+ parseerror(parser, "missing semicolon or initializer, got: `%s`", parser_tokval(parser));
+ break;
+ }
}
if (!parser_next(parser)) {
return old;
}
-static void generate_checksum(parser_t *parser)
+static void generate_checksum(parser_t *parser, ir_builder *ir)
{
uint16_t crc = 0xFFFF;
size_t i;
crc = progdefs_crc_both(crc, ";\n");
}
crc = progdefs_crc_both(crc, "} entvars_t;\n\n");
-
- parser->code->crc = crc;
+ ir->code->crc = crc;
}
parser_t *parser_create()
{
parser_t *parser;
- lex_ctx empty_ctx;
+ lex_ctx_t empty_ctx;
size_t i;
parser = (parser_t*)mem_a(sizeof(parser_t));
memset(parser, 0, sizeof(*parser));
- if (!(parser->code = code_init())) {
- mem_d(parser);
- return NULL;
- }
-
for (i = 0; i < operator_count; ++i) {
if (operators[i].id == opid1('=')) {
parser->assign_op = operators+i;
}
}
if (!parser->assign_op) {
- printf("internal error: initializing parser: failed to find assign operator\n");
+ con_err("internal error: initializing parser: failed to find assign operator\n");
mem_d(parser);
return NULL;
}
parser->aliases = util_htnew(PARSER_HT_SIZE);
- parser->ht_imm_string = util_htnew(512);
-
/* corrector */
vec_push(parser->correct_variables, correct_trie_new());
vec_push(parser->correct_variables_score, NULL);
- empty_ctx.file = "<internal>";
- empty_ctx.line = 0;
+ empty_ctx.file = "<internal>";
+ empty_ctx.line = 0;
+ empty_ctx.column = 0;
parser->nil = ast_value_new(empty_ctx, "nil", TYPE_NIL);
parser->nil->cvq = CV_CONST;
if (OPTS_FLAG(UNTYPED_NIL))
parser->reserved_version = NULL;
}
+ parser->fold = fold_init (parser);
+ parser->intrin = intrin_init(parser);
return parser;
}
for (i = 0; i < vec_size(parser->functions); ++i) {
ast_delete(parser->functions[i]);
}
- for (i = 0; i < vec_size(parser->imm_vector); ++i) {
- ast_delete(parser->imm_vector[i]);
- }
- for (i = 0; i < vec_size(parser->imm_string); ++i) {
- ast_delete(parser->imm_string[i]);
- }
- for (i = 0; i < vec_size(parser->imm_float); ++i) {
- ast_delete(parser->imm_float[i]);
- }
for (i = 0; i < vec_size(parser->fields); ++i) {
ast_delete(parser->fields[i]);
}
}
vec_free(parser->accessors);
vec_free(parser->functions);
- vec_free(parser->imm_vector);
- vec_free(parser->imm_string);
- util_htdel(parser->ht_imm_string);
- vec_free(parser->imm_float);
vec_free(parser->globals);
vec_free(parser->fields);
ast_value_delete(parser->const_vec[0]);
ast_value_delete(parser->const_vec[1]);
ast_value_delete(parser->const_vec[2]);
-
+
if (parser->reserved_version)
ast_value_delete(parser->reserved_version);
util_htdel(parser->aliases);
- intrin_intrinsics_destroy(parser);
+ fold_cleanup(parser->fold);
+ intrin_cleanup(parser->intrin);
}
void parser_cleanup(parser_t *parser)
{
parser_remove_ast(parser);
- code_cleanup(parser->code);
-
mem_d(parser);
}
}
}
/* Now we can generate immediates */
- for (i = 0; i < vec_size(parser->imm_float); ++i) {
- if (!ast_global_codegen(parser->imm_float[i], ir, false)) {
- con_out("failed to generate global %s\n", parser->imm_float[i]->name);
- ir_builder_delete(ir);
- return false;
- }
- }
- for (i = 0; i < vec_size(parser->imm_string); ++i) {
- if (!ast_global_codegen(parser->imm_string[i], ir, false)) {
- con_out("failed to generate global %s\n", parser->imm_string[i]->name);
- ir_builder_delete(ir);
- return false;
- }
- }
- for (i = 0; i < vec_size(parser->imm_vector); ++i) {
- if (!ast_global_codegen(parser->imm_vector[i], ir, false)) {
- con_out("failed to generate global %s\n", parser->imm_vector[i]->name);
- ir_builder_delete(ir);
- return false;
- }
- }
+ if (!fold_generate(parser->fold, ir))
+ return false;
+
for (i = 0; i < vec_size(parser->globals); ++i) {
ast_value *asvalue;
if (!ast_istype(parser->globals[i], ast_value))
}
}
- generate_checksum(parser);
+ generate_checksum(parser, ir);
+
if (OPTS_OPTION_BOOL(OPTION_DUMP))
ir_builder_dump(ir, con_out);
for (i = 0; i < vec_size(parser->functions); ++i) {
if (OPTS_OPTION_BOOL(OPTION_DUMPFIN))
ir_builder_dump(ir, con_out);
- if (!ir_builder_generate(parser->code, ir, output)) {
+ if (!ir_builder_generate(ir, output)) {
con_out("*** failed to generate output file\n");
ir_builder_delete(ir);
return false;