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|
/*
* Mesa 3-D graphics library
* Version: 6.5.3
*
* Copyright (C) 2005-2007 Brian Paul All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* BRIAN PAUL BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN
* AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
/**
* \file slang_emit.c
* Emit program instructions (PI code) from IR trees.
* \author Brian Paul
*/
/***
*** NOTES
***
*** To emit GPU instructions, we basically just do an in-order traversal
*** of the IR tree.
***/
#include "imports.h"
#include "context.h"
#include "macros.h"
#include "program.h"
#include "prog_instruction.h"
#include "prog_parameter.h"
#include "prog_print.h"
#include "slang_builtin.h"
#include "slang_emit.h"
#define PEEPHOLE_OPTIMIZATIONS 1
#define ANNOTATE 0
/* XXX temporarily here */
typedef struct
{
slang_info_log *log;
slang_var_table *vt;
struct gl_program *prog;
/* code-gen options */
GLboolean EmitHighLevelInstructions;
GLboolean EmitComments;
} slang_emit_info;
/**
* Assembly and IR info
*/
typedef struct
{
slang_ir_opcode IrOpcode;
const char *IrName;
gl_inst_opcode InstOpcode;
GLuint ResultSize, NumParams;
} slang_ir_info;
static const slang_ir_info IrInfo[] = {
/* binary ops */
{ IR_ADD, "IR_ADD", OPCODE_ADD, 4, 2 },
{ IR_SUB, "IR_SUB", OPCODE_SUB, 4, 2 },
{ IR_MUL, "IR_MUL", OPCODE_MUL, 4, 2 },
{ IR_DIV, "IR_DIV", OPCODE_NOP, 0, 2 }, /* XXX broke */
{ IR_DOT4, "IR_DOT_4", OPCODE_DP4, 1, 2 },
{ IR_DOT3, "IR_DOT_3", OPCODE_DP3, 1, 2 },
{ IR_CROSS, "IR_CROSS", OPCODE_XPD, 3, 2 },
{ IR_LRP, "IR_LRP", OPCODE_LRP, 4, 3 },
{ IR_MIN, "IR_MIN", OPCODE_MIN, 4, 2 },
{ IR_MAX, "IR_MAX", OPCODE_MAX, 4, 2 },
{ IR_CLAMP, "IR_CLAMP", OPCODE_NOP, 4, 3 }, /* special case: emit_clamp() */
{ IR_SEQUAL, "IR_SEQUAL", OPCODE_SEQ, 4, 2 },
{ IR_SNEQUAL, "IR_SNEQUAL", OPCODE_SNE, 4, 2 },
{ IR_SGE, "IR_SGE", OPCODE_SGE, 4, 2 },
{ IR_SGT, "IR_SGT", OPCODE_SGT, 4, 2 },
{ IR_SLE, "IR_SLE", OPCODE_SLE, 4, 2 },
{ IR_SLT, "IR_SLT", OPCODE_SLT, 4, 2 },
{ IR_POW, "IR_POW", OPCODE_POW, 1, 2 },
/* unary ops */
{ IR_I_TO_F, "IR_I_TO_F", OPCODE_NOP, 1, 1 },
{ IR_F_TO_I, "IR_F_TO_I", OPCODE_INT, 4, 1 }, /* 4 floats to 4 ints */
{ IR_EXP, "IR_EXP", OPCODE_EXP, 1, 1 },
{ IR_EXP2, "IR_EXP2", OPCODE_EX2, 1, 1 },
{ IR_LOG2, "IR_LOG2", OPCODE_LG2, 1, 1 },
{ IR_RSQ, "IR_RSQ", OPCODE_RSQ, 1, 1 },
{ IR_RCP, "IR_RCP", OPCODE_RCP, 1, 1 },
{ IR_FLOOR, "IR_FLOOR", OPCODE_FLR, 4, 1 },
{ IR_FRAC, "IR_FRAC", OPCODE_FRC, 4, 1 },
{ IR_ABS, "IR_ABS", OPCODE_ABS, 4, 1 },
{ IR_NEG, "IR_NEG", OPCODE_NOP, 4, 1 }, /* special case: emit_negation() */
{ IR_DDX, "IR_DDX", OPCODE_DDX, 4, 1 },
{ IR_DDX, "IR_DDY", OPCODE_DDX, 4, 1 },
{ IR_SIN, "IR_SIN", OPCODE_SIN, 1, 1 },
{ IR_COS, "IR_COS", OPCODE_COS, 1, 1 },
{ IR_NOISE1, "IR_NOISE1", OPCODE_NOISE1, 1, 1 },
{ IR_NOISE2, "IR_NOISE2", OPCODE_NOISE2, 1, 1 },
{ IR_NOISE3, "IR_NOISE3", OPCODE_NOISE3, 1, 1 },
{ IR_NOISE4, "IR_NOISE4", OPCODE_NOISE4, 1, 1 },
/* other */
{ IR_SEQ, "IR_SEQ", OPCODE_NOP, 0, 0 },
{ IR_SCOPE, "IR_SCOPE", OPCODE_NOP, 0, 0 },
{ IR_LABEL, "IR_LABEL", OPCODE_NOP, 0, 0 },
{ IR_JUMP, "IR_JUMP", OPCODE_NOP, 0, 0 },
{ IR_IF, "IR_IF", OPCODE_NOP, 0, 0 },
{ IR_KILL, "IR_KILL", OPCODE_NOP, 0, 0 },
{ IR_COND, "IR_COND", OPCODE_NOP, 0, 0 },
{ IR_CALL, "IR_CALL", OPCODE_NOP, 0, 0 },
{ IR_MOVE, "IR_MOVE", OPCODE_NOP, 0, 1 },
{ IR_NOT, "IR_NOT", OPCODE_NOP, 1, 1 },
{ IR_VAR, "IR_VAR", OPCODE_NOP, 0, 0 },
{ IR_VAR_DECL, "IR_VAR_DECL", OPCODE_NOP, 0, 0 },
{ IR_TEX, "IR_TEX", OPCODE_TEX, 4, 1 },
{ IR_TEXB, "IR_TEXB", OPCODE_TXB, 4, 1 },
{ IR_TEXP, "IR_TEXP", OPCODE_TXP, 4, 1 },
{ IR_FLOAT, "IR_FLOAT", OPCODE_NOP, 0, 0 }, /* float literal */
{ IR_FIELD, "IR_FIELD", OPCODE_NOP, 0, 0 },
{ IR_ELEMENT, "IR_ELEMENT", OPCODE_NOP, 0, 0 },
{ IR_SWIZZLE, "IR_SWIZZLE", OPCODE_NOP, 0, 0 },
{ IR_NOP, NULL, OPCODE_NOP, 0, 0 }
};
static const slang_ir_info *
slang_find_ir_info(slang_ir_opcode opcode)
{
GLuint i;
for (i = 0; IrInfo[i].IrName; i++) {
if (IrInfo[i].IrOpcode == opcode) {
return IrInfo + i;
}
}
return NULL;
}
static const char *
slang_ir_name(slang_ir_opcode opcode)
{
return slang_find_ir_info(opcode)->IrName;
}
/**
* Swizzle a swizzle. That is, return swz2(swz1)
*/
static GLuint
swizzle_swizzle(GLuint swz1, GLuint swz2)
{
GLuint i, swz, s[4];
for (i = 0; i < 4; i++) {
GLuint c = GET_SWZ(swz2, i);
s[i] = GET_SWZ(swz1, c);
}
swz = MAKE_SWIZZLE4(s[0], s[1], s[2], s[3]);
return swz;
}
slang_ir_storage *
_slang_new_ir_storage(enum register_file file, GLint index, GLint size)
{
slang_ir_storage *st;
st = (slang_ir_storage *) _mesa_calloc(sizeof(slang_ir_storage));
if (st) {
st->File = file;
st->Index = index;
st->Size = size;
st->Swizzle = SWIZZLE_NOOP;
}
return st;
}
static const char *
swizzle_string(GLuint swizzle)
{
static char s[6];
GLuint i;
s[0] = '.';
for (i = 1; i < 5; i++) {
s[i] = "xyzw"[GET_SWZ(swizzle, i-1)];
}
s[i] = 0;
return s;
}
static const char *
writemask_string(GLuint writemask)
{
static char s[6];
GLuint i, j = 0;
s[j++] = '.';
for (i = 0; i < 4; i++) {
if (writemask & (1 << i))
s[j++] = "xyzw"[i];
}
s[j] = 0;
return s;
}
static const char *
storage_string(const slang_ir_storage *st)
{
static const char *files[] = {
"TEMP",
"LOCAL_PARAM",
"ENV_PARAM",
"STATE",
"INPUT",
"OUTPUT",
"NAMED_PARAM",
"CONSTANT",
"UNIFORM",
"WRITE_ONLY",
"ADDRESS",
"SAMPLER",
"UNDEFINED"
};
static char s[100];
#if 0
if (st->Size == 1)
sprintf(s, "%s[%d]", files[st->File], st->Index);
else
sprintf(s, "%s[%d..%d]", files[st->File], st->Index,
st->Index + st->Size - 1);
#endif
assert(st->File < (GLint) (sizeof(files) / sizeof(files[0])));
sprintf(s, "%s[%d]", files[st->File], st->Index);
return s;
}
static void
spaces(int n)
{
while (n-- > 0) {
printf(" ");
}
}
#define IND 0
void
slang_print_ir(const slang_ir_node *n, int indent)
{
if (!n)
return;
#if !IND
if (n->Opcode != IR_SEQ)
#else
printf("%3d:", indent);
#endif
spaces(indent);
switch (n->Opcode) {
case IR_SEQ:
#if IND
printf("SEQ at %p\n", (void*) n);
#endif
assert(n->Children[0]);
assert(n->Children[1]);
slang_print_ir(n->Children[0], indent + IND);
slang_print_ir(n->Children[1], indent + IND);
break;
case IR_SCOPE:
printf("NEW SCOPE\n");
assert(!n->Children[1]);
slang_print_ir(n->Children[0], indent + 3);
break;
case IR_MOVE:
printf("MOVE (writemask = %s)\n", writemask_string(n->Writemask));
slang_print_ir(n->Children[0], indent+3);
slang_print_ir(n->Children[1], indent+3);
break;
case IR_LABEL:
printf("LABEL: %s\n", n->Label->Name);
break;
case IR_COND:
printf("COND\n");
slang_print_ir(n->Children[0], indent + 3);
break;
case IR_JUMP:
printf("JUMP %s\n", n->Label->Name);
break;
case IR_IF:
printf("IF \n");
slang_print_ir(n->Children[0], indent+3);
spaces(indent);
printf("THEN\n");
slang_print_ir(n->Children[1], indent+3);
if (n->Children[2]) {
spaces(indent);
printf("ELSE\n");
slang_print_ir(n->Children[2], indent+3);
}
printf("ENDIF\n");
break;
case IR_BEGIN_SUB:
printf("BEGIN_SUB\n");
break;
case IR_END_SUB:
printf("END_SUB\n");
break;
case IR_RETURN:
printf("RETURN\n");
break;
case IR_CALL:
printf("CALL\n");
break;
case IR_LOOP:
printf("LOOP\n");
slang_print_ir(n->Children[0], indent+3);
spaces(indent);
printf("ENDLOOP\n");
break;
case IR_CONT:
printf("CONT\n");
break;
case IR_BREAK:
printf("BREAK\n");
break;
case IR_BREAK_IF_FALSE:
printf("BREAK_IF_FALSE\n");
slang_print_ir(n->Children[0], indent+3);
break;
case IR_BREAK_IF_TRUE:
printf("BREAK_IF_TRUE\n");
slang_print_ir(n->Children[0], indent+3);
break;
case IR_CONT_IF_FALSE:
printf("CONT_IF_FALSE\n");
slang_print_ir(n->Children[0], indent+3);
break;
case IR_CONT_IF_TRUE:
printf("CONT_IF_TRUE\n");
slang_print_ir(n->Children[0], indent+3);
break;
case IR_VAR:
printf("VAR %s%s at %s store %p\n",
(n->Var ? (char *) n->Var->a_name : "TEMP"),
swizzle_string(n->Store->Swizzle),
storage_string(n->Store), (void*) n->Store);
break;
case IR_VAR_DECL:
printf("VAR_DECL %s (%p) at %s store %p\n",
(n->Var ? (char *) n->Var->a_name : "TEMP"),
(void*) n->Var, storage_string(n->Store),
(void*) n->Store);
break;
case IR_FIELD:
printf("FIELD %s of\n", n->Field);
slang_print_ir(n->Children[0], indent+3);
break;
case IR_FLOAT:
printf("FLOAT %g %g %g %g\n",
n->Value[0], n->Value[1], n->Value[2], n->Value[3]);
break;
case IR_I_TO_F:
printf("INT_TO_FLOAT\n");
slang_print_ir(n->Children[0], indent+3);
break;
case IR_F_TO_I:
printf("FLOAT_TO_INT\n");
slang_print_ir(n->Children[0], indent+3);
break;
case IR_SWIZZLE:
printf("SWIZZLE %s of (store %p) \n",
swizzle_string(n->Store->Swizzle), (void*) n->Store);
slang_print_ir(n->Children[0], indent + 3);
break;
default:
printf("%s (%p, %p) (store %p)\n", slang_ir_name(n->Opcode),
(void*) n->Children[0], (void*) n->Children[1], (void*) n->Store);
slang_print_ir(n->Children[0], indent+3);
slang_print_ir(n->Children[1], indent+3);
}
}
/**
* Allocate temporary storage for an intermediate result (such as for
* a multiply or add, etc.
*/
static GLboolean
alloc_temp_storage(slang_emit_info *emitInfo, slang_ir_node *n, GLint size)
{
assert(!n->Var);
assert(!n->Store);
assert(size > 0);
n->Store = _slang_new_ir_storage(PROGRAM_TEMPORARY, -1, size);
if (!_slang_alloc_temp(emitInfo->vt, n->Store)) {
slang_info_log_error(emitInfo->log,
"Ran out of registers, too many temporaries");
return GL_FALSE;
}
return GL_TRUE;
}
/**
* Free temporary storage, if n->Store is, in fact, temp storage.
* Otherwise, no-op.
*/
static void
free_temp_storage(slang_var_table *vt, slang_ir_node *n)
{
if (n->Store->File == PROGRAM_TEMPORARY && n->Store->Index >= 0) {
if (_slang_is_temp(vt, n->Store)) {
_slang_free_temp(vt, n->Store);
n->Store->Index = -1;
n->Store->Size = -1;
}
}
}
/**
* Convert IR storage to an instruction dst register.
*/
static void
storage_to_dst_reg(struct prog_dst_register *dst, const slang_ir_storage *st,
GLuint writemask)
{
static const GLuint defaultWritemask[4] = {
WRITEMASK_X,
WRITEMASK_X | WRITEMASK_Y,
WRITEMASK_X | WRITEMASK_Y | WRITEMASK_Z,
WRITEMASK_X | WRITEMASK_Y | WRITEMASK_Z | WRITEMASK_W
};
assert(st->Index >= 0);
dst->File = st->File;
dst->Index = st->Index;
assert(st->File != PROGRAM_UNDEFINED);
assert(st->Size >= 1);
assert(st->Size <= 4);
if (st->Size == 1) {
GLuint comp = GET_SWZ(st->Swizzle, 0);
assert(comp < 4);
assert(writemask & WRITEMASK_X);
dst->WriteMask = WRITEMASK_X << comp;
}
else {
dst->WriteMask = defaultWritemask[st->Size - 1] & writemask;
}
}
/**
* Convert IR storage to an instruction src register.
*/
static void
storage_to_src_reg(struct prog_src_register *src, const slang_ir_storage *st)
{
static const GLuint defaultSwizzle[4] = {
MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_X, SWIZZLE_X, SWIZZLE_X),
MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_W),
MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_W),
MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_W)
};
assert(st->File >= 0 && st->File <= 16);
src->File = st->File;
src->Index = st->Index;
assert(st->File != PROGRAM_UNDEFINED);
assert(st->Size >= 1);
assert(st->Size <= 4);
if (st->Swizzle != SWIZZLE_NOOP)
src->Swizzle = st->Swizzle;
else
src->Swizzle = defaultSwizzle[st->Size - 1]; /*XXX really need this?*/
assert(GET_SWZ(src->Swizzle, 0) != SWIZZLE_NIL);
assert(GET_SWZ(src->Swizzle, 1) != SWIZZLE_NIL);
assert(GET_SWZ(src->Swizzle, 2) != SWIZZLE_NIL);
assert(GET_SWZ(src->Swizzle, 3) != SWIZZLE_NIL);
}
/**
* Add new instruction at end of given program.
* \param prog the program to append instruction onto
* \param opcode opcode for the new instruction
* \return pointer to the new instruction
*/
static struct prog_instruction *
new_instruction(slang_emit_info *emitInfo, gl_inst_opcode opcode)
{
struct gl_program *prog = emitInfo->prog;
struct prog_instruction *inst;
prog->Instructions = _mesa_realloc_instructions(prog->Instructions,
prog->NumInstructions,
prog->NumInstructions + 1);
inst = prog->Instructions + prog->NumInstructions;
prog->NumInstructions++;
_mesa_init_instructions(inst, 1);
inst->Opcode = opcode;
inst->BranchTarget = -1; /* invalid */
return inst;
}
#if 0
/**
* Return pointer to last instruction in program.
*/
static struct prog_instruction *
prev_instruction(struct gl_program *prog)
{
if (prog->NumInstructions == 0)
return NULL;
else
return prog->Instructions + prog->NumInstructions - 1;
}
#endif
static struct prog_instruction *
emit(slang_emit_info *emitInfo, slang_ir_node *n);
/**
* Return an annotation string for given node's storage.
*/
static char *
storage_annotation(const slang_ir_node *n, const struct gl_program *prog)
{
#if ANNOTATE
const slang_ir_storage *st = n->Store;
static char s[100] = "";
if (!st)
return _mesa_strdup("");
switch (st->File) {
case PROGRAM_CONSTANT:
if (st->Index >= 0) {
const GLfloat *val = prog->Parameters->ParameterValues[st->Index];
if (st->Swizzle == SWIZZLE_NOOP)
sprintf(s, "{%g, %g, %g, %g}", val[0], val[1], val[2], val[3]);
else {
sprintf(s, "%g", val[GET_SWZ(st->Swizzle, 0)]);
}
}
break;
case PROGRAM_TEMPORARY:
if (n->Var)
sprintf(s, "%s", (char *) n->Var->a_name);
else
sprintf(s, "t[%d]", st->Index);
break;
case PROGRAM_STATE_VAR:
case PROGRAM_UNIFORM:
sprintf(s, "%s", prog->Parameters->Parameters[st->Index].Name);
break;
case PROGRAM_VARYING:
sprintf(s, "%s", prog->Varying->Parameters[st->Index].Name);
break;
case PROGRAM_INPUT:
sprintf(s, "input[%d]", st->Index);
break;
case PROGRAM_OUTPUT:
sprintf(s, "output[%d]", st->Index);
break;
default:
s[0] = 0;
}
return _mesa_strdup(s);
#else
return NULL;
#endif
}
/**
* Return an annotation string for an instruction.
*/
static char *
instruction_annotation(gl_inst_opcode opcode, char *dstAnnot,
char *srcAnnot0, char *srcAnnot1, char *srcAnnot2)
{
#if ANNOTATE
const char *operator;
char *s;
int len = 50;
if (dstAnnot)
len += strlen(dstAnnot);
else
dstAnnot = _mesa_strdup("");
if (srcAnnot0)
len += strlen(srcAnnot0);
else
srcAnnot0 = _mesa_strdup("");
if (srcAnnot1)
len += strlen(srcAnnot1);
else
srcAnnot1 = _mesa_strdup("");
if (srcAnnot2)
len += strlen(srcAnnot2);
else
srcAnnot2 = _mesa_strdup("");
switch (opcode) {
case OPCODE_ADD:
operator = "+";
break;
case OPCODE_SUB:
operator = "-";
break;
case OPCODE_MUL:
operator = "*";
break;
case OPCODE_DP3:
operator = "DP3";
break;
case OPCODE_DP4:
operator = "DP4";
break;
case OPCODE_XPD:
operator = "XPD";
break;
case OPCODE_RSQ:
operator = "RSQ";
break;
case OPCODE_SGT:
operator = ">";
break;
default:
operator = ",";
}
s = (char *) malloc(len);
sprintf(s, "%s = %s %s %s %s", dstAnnot,
srcAnnot0, operator, srcAnnot1, srcAnnot2);
assert(_mesa_strlen(s) < len);
free(dstAnnot);
free(srcAnnot0);
free(srcAnnot1);
free(srcAnnot2);
return s;
#else
return NULL;
#endif
}
/**
* Generate code for a simple arithmetic instruction.
* Either 1, 2 or 3 operands.
*/
static struct prog_instruction *
emit_arith(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct prog_instruction *inst;
const slang_ir_info *info = slang_find_ir_info(n->Opcode);
char *srcAnnot[3], *dstAnnot;
GLuint i;
assert(info);
assert(info->InstOpcode != OPCODE_NOP);
srcAnnot[0] = srcAnnot[1] = srcAnnot[2] = dstAnnot = NULL;
#if PEEPHOLE_OPTIMIZATIONS
/* Look for MAD opportunity */
if (info->NumParams == 2 &&
n->Opcode == IR_ADD && n->Children[0]->Opcode == IR_MUL) {
/* found pattern IR_ADD(IR_MUL(A, B), C) */
emit(emitInfo, n->Children[0]->Children[0]); /* A */
emit(emitInfo, n->Children[0]->Children[1]); /* B */
emit(emitInfo, n->Children[1]); /* C */
/* generate MAD instruction */
inst = new_instruction(emitInfo, OPCODE_MAD);
/* operands: A, B, C: */
storage_to_src_reg(&inst->SrcReg[0], n->Children[0]->Children[0]->Store);
storage_to_src_reg(&inst->SrcReg[1], n->Children[0]->Children[1]->Store);
storage_to_src_reg(&inst->SrcReg[2], n->Children[1]->Store);
free_temp_storage(emitInfo->vt, n->Children[0]->Children[0]);
free_temp_storage(emitInfo->vt, n->Children[0]->Children[1]);
free_temp_storage(emitInfo->vt, n->Children[1]);
}
else if (info->NumParams == 2 &&
n->Opcode == IR_ADD && n->Children[1]->Opcode == IR_MUL) {
/* found pattern IR_ADD(A, IR_MUL(B, C)) */
emit(emitInfo, n->Children[0]); /* A */
emit(emitInfo, n->Children[1]->Children[0]); /* B */
emit(emitInfo, n->Children[1]->Children[1]); /* C */
/* generate MAD instruction */
inst = new_instruction(emitInfo, OPCODE_MAD);
/* operands: B, C, A */
storage_to_src_reg(&inst->SrcReg[0], n->Children[1]->Children[0]->Store);
storage_to_src_reg(&inst->SrcReg[1], n->Children[1]->Children[1]->Store);
storage_to_src_reg(&inst->SrcReg[2], n->Children[0]->Store);
free_temp_storage(emitInfo->vt, n->Children[1]->Children[0]);
free_temp_storage(emitInfo->vt, n->Children[1]->Children[1]);
free_temp_storage(emitInfo->vt, n->Children[0]);
}
else
#endif
{
/* normal case */
/* gen code for children */
for (i = 0; i < info->NumParams; i++)
emit(emitInfo, n->Children[i]);
/* gen this instruction and src registers */
inst = new_instruction(emitInfo, info->InstOpcode);
for (i = 0; i < info->NumParams; i++)
storage_to_src_reg(&inst->SrcReg[i], n->Children[i]->Store);
/* annotation */
for (i = 0; i < info->NumParams; i++)
srcAnnot[i] = storage_annotation(n->Children[i], emitInfo->prog);
/* free temps */
for (i = 0; i < info->NumParams; i++)
free_temp_storage(emitInfo->vt, n->Children[i]);
}
/* result storage */
if (!n->Store) {
if (!alloc_temp_storage(emitInfo, n, info->ResultSize))
return NULL;
}
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
dstAnnot = storage_annotation(n, emitInfo->prog);
inst->Comment = instruction_annotation(inst->Opcode, dstAnnot, srcAnnot[0],
srcAnnot[1], srcAnnot[2]);
/*_mesa_print_instruction(inst);*/
return inst;
}
/**
* Generate code for an IR_CLAMP instruction.
*/
static struct prog_instruction *
emit_clamp(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct prog_instruction *inst;
assert(n->Opcode == IR_CLAMP);
/* ch[0] = value
* ch[1] = min limit
* ch[2] = max limit
*/
inst = emit(emitInfo, n->Children[0]);
/* If lower limit == 0.0 and upper limit == 1.0,
* set prev instruction's SaturateMode field to SATURATE_ZERO_ONE.
* Else,
* emit OPCODE_MIN, OPCODE_MAX sequence.
*/
#if 0
/* XXX this isn't quite finished yet */
if (n->Children[1]->Opcode == IR_FLOAT &&
n->Children[1]->Value[0] == 0.0 &&
n->Children[1]->Value[1] == 0.0 &&
n->Children[1]->Value[2] == 0.0 &&
n->Children[1]->Value[3] == 0.0 &&
n->Children[2]->Opcode == IR_FLOAT &&
n->Children[2]->Value[0] == 1.0 &&
n->Children[2]->Value[1] == 1.0 &&
n->Children[2]->Value[2] == 1.0 &&
n->Children[2]->Value[3] == 1.0) {
if (!inst) {
inst = prev_instruction(prog);
}
if (inst && inst->Opcode != OPCODE_NOP) {
/* and prev instruction's DstReg matches n->Children[0]->Store */
inst->SaturateMode = SATURATE_ZERO_ONE;
n->Store = n->Children[0]->Store;
return inst;
}
}
#endif
if (!n->Store)
if (!alloc_temp_storage(emitInfo, n, n->Children[0]->Store->Size))
return NULL;
emit(emitInfo, n->Children[1]);
emit(emitInfo, n->Children[2]);
/* tmp = max(ch[0], ch[1]) */
inst = new_instruction(emitInfo, OPCODE_MAX);
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Children[0]->Store);
storage_to_src_reg(&inst->SrcReg[1], n->Children[1]->Store);
/* tmp = min(tmp, ch[2]) */
inst = new_instruction(emitInfo, OPCODE_MIN);
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Store);
storage_to_src_reg(&inst->SrcReg[1], n->Children[2]->Store);
return inst;
}
static struct prog_instruction *
emit_negation(slang_emit_info *emitInfo, slang_ir_node *n)
{
/* Implement as MOV dst, -src; */
/* XXX we could look at the previous instruction and in some circumstances
* modify it to accomplish the negation.
*/
struct prog_instruction *inst;
emit(emitInfo, n->Children[0]);
if (!n->Store)
if (!alloc_temp_storage(emitInfo, n, n->Children[0]->Store->Size))
return NULL;
inst = new_instruction(emitInfo, OPCODE_MOV);
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Children[0]->Store);
inst->SrcReg[0].NegateBase = NEGATE_XYZW;
return inst;
}
static struct prog_instruction *
emit_label(slang_emit_info *emitInfo, const slang_ir_node *n)
{
assert(n->Label);
assert(_slang_label_get_location(n->Label) < 0);
_slang_label_set_location(n->Label, emitInfo->prog->NumInstructions,
emitInfo->prog);
return NULL;
}
static struct prog_instruction *
emit_jump(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct prog_instruction *inst;
assert(n);
assert(n->Label);
inst = new_instruction(emitInfo, OPCODE_BRA);
inst->DstReg.CondMask = COND_TR; /* always branch */
inst->BranchTarget = _slang_label_get_location(n->Label);
if (inst->BranchTarget < 0) {
_slang_label_add_reference(n->Label, emitInfo->prog->NumInstructions - 1);
}
return inst;
}
static struct prog_instruction *
emit_kill(slang_emit_info *emitInfo)
{
struct prog_instruction *inst;
/* NV-KILL - discard fragment depending on condition code.
* Note that ARB-KILL depends on sign of vector operand.
*/
inst = new_instruction(emitInfo, OPCODE_KIL_NV);
inst->DstReg.CondMask = COND_TR; /* always branch */
return inst;
}
static struct prog_instruction *
emit_tex(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct prog_instruction *inst;
if (n->Opcode == IR_TEX) {
inst = new_instruction(emitInfo, OPCODE_TEX);
}
else if (n->Opcode == IR_TEXB) {
inst = new_instruction(emitInfo, OPCODE_TXB);
}
else {
assert(n->Opcode == IR_TEXP);
inst = new_instruction(emitInfo, OPCODE_TXP);
}
if (!n->Store)
if (!alloc_temp_storage(emitInfo, n, 4))
return NULL;
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
(void) emit(emitInfo, n->Children[1]);
/* Child[1] is the coord */
storage_to_src_reg(&inst->SrcReg[0], n->Children[1]->Store);
/* Child[0] is the sampler (a uniform which'll indicate the texture unit) */
assert(n->Children[0]->Store);
assert(n->Children[0]->Store->Size >= TEXTURE_1D_INDEX);
inst->Sampler = n->Children[0]->Store->Index; /* i.e. uniform's index */
inst->TexSrcTarget = n->Children[0]->Store->Size;
inst->TexSrcUnit = 27; /* Dummy value; the TexSrcUnit will be computed at
* link time, using the sampler uniform's value.
*/
return inst;
}
static struct prog_instruction *
emit_move(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct prog_instruction *inst;
/* rhs */
assert(n->Children[1]);
inst = emit(emitInfo, n->Children[1]);
assert(n->Children[1]->Store->Index >= 0);
/* lhs */
emit(emitInfo, n->Children[0]);
assert(!n->Store);
n->Store = n->Children[0]->Store;
#if PEEPHOLE_OPTIMIZATIONS
if (inst && _slang_is_temp(emitInfo->vt, n->Children[1]->Store)) {
/* Peephole optimization:
* Just modify the RHS to put its result into the dest of this
* MOVE operation. Then, this MOVE is a no-op.
*/
_slang_free_temp(emitInfo->vt, n->Children[1]->Store);
*n->Children[1]->Store = *n->Children[0]->Store;
/* fixup the prev (RHS) instruction */
assert(n->Children[0]->Store->Index >= 0);
assert(n->Children[0]->Store->Index < 16);
storage_to_dst_reg(&inst->DstReg, n->Children[0]->Store, n->Writemask);
return inst;
}
else
#endif
{
if (n->Children[0]->Store->Size > 4) {
/* move matrix/struct etc (block of registers) */
slang_ir_storage dstStore = *n->Children[0]->Store;
slang_ir_storage srcStore = *n->Children[1]->Store;
GLint size = srcStore.Size;
ASSERT(n->Children[0]->Writemask == WRITEMASK_XYZW);
ASSERT(n->Children[1]->Store->Swizzle == SWIZZLE_NOOP);
dstStore.Size = 4;
srcStore.Size = 4;
while (size >= 4) {
inst = new_instruction(emitInfo, OPCODE_MOV);
inst->Comment = _mesa_strdup("IR_MOVE block");
storage_to_dst_reg(&inst->DstReg, &dstStore, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], &srcStore);
srcStore.Index++;
dstStore.Index++;
size -= 4;
}
}
else {
/* single register move */
char *srcAnnot, *dstAnnot;
inst = new_instruction(emitInfo, OPCODE_MOV);
assert(n->Children[0]->Store->Index >= 0);
storage_to_dst_reg(&inst->DstReg, n->Children[0]->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Children[1]->Store);
dstAnnot = storage_annotation(n->Children[0], emitInfo->prog);
srcAnnot = storage_annotation(n->Children[1], emitInfo->prog);
inst->Comment = instruction_annotation(inst->Opcode, dstAnnot,
srcAnnot, NULL, NULL);
}
free_temp_storage(emitInfo->vt, n->Children[1]);
return inst;
}
}
static struct prog_instruction *
emit_cond(slang_emit_info *emitInfo, slang_ir_node *n)
{
/* Conditional expression (in if/while/for stmts).
* Need to update condition code register.
* Next instruction is typically an IR_IF.
*/
struct prog_instruction *inst;
if (!n->Children[0])
return NULL;
inst = emit(emitInfo, n->Children[0]);
if (inst) {
/* set inst's CondUpdate flag */
inst->CondUpdate = GL_TRUE;
return inst; /* XXX or null? */
}
else {
/* This'll happen for things like "if (i) ..." where no code
* is normally generated for the expression "i".
* Generate a move instruction just to set condition codes.
* Note: must use full 4-component vector since all four
* condition codes must be set identically.
*/
if (!alloc_temp_storage(emitInfo, n, 4))
return NULL;
inst = new_instruction(emitInfo, OPCODE_MOV);
inst->CondUpdate = GL_TRUE;
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Children[0]->Store);
_slang_free_temp(emitInfo->vt, n->Store);
inst->Comment = _mesa_strdup("COND expr");
return inst; /* XXX or null? */
}
}
/**
* Logical-NOT
*/
static struct prog_instruction *
emit_not(slang_emit_info *emitInfo, slang_ir_node *n)
{
GLfloat zero = 0.0;
slang_ir_storage st;
struct prog_instruction *inst;
/* need zero constant */
st.File = PROGRAM_CONSTANT;
st.Size = 1;
st.Index = _mesa_add_unnamed_constant(emitInfo->prog->Parameters, &zero,
1, &st.Swizzle);
/* child expr */
(void) emit(emitInfo, n->Children[0]);
/* XXXX if child instr is SGT convert to SLE, if SEQ, SNE, etc */
if (!n->Store)
if (!alloc_temp_storage(emitInfo, n, n->Children[0]->Store->Size))
return NULL;
inst = new_instruction(emitInfo, OPCODE_SEQ);
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Children[0]->Store);
storage_to_src_reg(&inst->SrcReg[1], &st);
free_temp_storage(emitInfo->vt, n->Children[0]);
inst->Comment = _mesa_strdup("NOT");
return inst;
}
static struct prog_instruction *
emit_if(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct gl_program *prog = emitInfo->prog;
struct prog_instruction *ifInst;
GLuint ifInstLoc, elseInstLoc = 0;
emit(emitInfo, n->Children[0]); /* the condition */
ifInstLoc = prog->NumInstructions;
if (emitInfo->EmitHighLevelInstructions) {
ifInst = new_instruction(emitInfo, OPCODE_IF);
ifInst->DstReg.CondMask = COND_NE; /* if cond is non-zero */
ifInst->DstReg.CondSwizzle = SWIZZLE_X;
}
else {
/* conditional jump to else, or endif */
ifInst = new_instruction(emitInfo, OPCODE_BRA);
ifInst->DstReg.CondMask = COND_EQ; /* BRA if cond is zero */
ifInst->DstReg.CondSwizzle = SWIZZLE_X;
ifInst->Comment = _mesa_strdup("if zero");
}
/* if body */
emit(emitInfo, n->Children[1]);
if (n->Children[2]) {
/* have else body */
elseInstLoc = prog->NumInstructions;
if (emitInfo->EmitHighLevelInstructions) {
(void) new_instruction(emitInfo, OPCODE_ELSE);
}
else {
/* jump to endif instruction */
struct prog_instruction *inst;
inst = new_instruction(emitInfo, OPCODE_BRA);
inst->Comment = _mesa_strdup("else");
inst->DstReg.CondMask = COND_TR; /* always branch */
}
ifInst = prog->Instructions + ifInstLoc;
ifInst->BranchTarget = prog->NumInstructions;
emit(emitInfo, n->Children[2]);
}
else {
/* no else body */
ifInst = prog->Instructions + ifInstLoc;
ifInst->BranchTarget = prog->NumInstructions + 1;
}
if (emitInfo->EmitHighLevelInstructions) {
(void) new_instruction(emitInfo, OPCODE_ENDIF);
}
if (n->Children[2]) {
struct prog_instruction *elseInst;
elseInst = prog->Instructions + elseInstLoc;
elseInst->BranchTarget = prog->NumInstructions;
}
return NULL;
}
static struct prog_instruction *
emit_loop(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct gl_program *prog = emitInfo->prog;
struct prog_instruction *beginInst, *endInst;
GLuint beginInstLoc, endInstLoc;
slang_ir_node *ir;
/* emit OPCODE_BGNLOOP */
beginInstLoc = prog->NumInstructions;
if (emitInfo->EmitHighLevelInstructions) {
(void) new_instruction(emitInfo, OPCODE_BGNLOOP);
}
/* body */
emit(emitInfo, n->Children[0]);
endInstLoc = prog->NumInstructions;
if (emitInfo->EmitHighLevelInstructions) {
/* emit OPCODE_ENDLOOP */
endInst = new_instruction(emitInfo, OPCODE_ENDLOOP);
}
else {
/* emit unconditional BRA-nch */
endInst = new_instruction(emitInfo, OPCODE_BRA);
endInst->DstReg.CondMask = COND_TR; /* always true */
}
/* end instruction's BranchTarget points to top of loop */
endInst->BranchTarget = beginInstLoc;
if (emitInfo->EmitHighLevelInstructions) {
/* BGNLOOP's BranchTarget points to the ENDLOOP inst */
beginInst = prog->Instructions + beginInstLoc;
beginInst->BranchTarget = prog->NumInstructions - 1;
}
/* Done emitting loop code. Now walk over the loop's linked list of
* BREAK and CONT nodes, filling in their BranchTarget fields (which
* will point to the ENDLOOP+1 or BGNLOOP instructions, respectively).
*/
for (ir = n->BranchNode; ir; ir = ir->BranchNode) {
struct prog_instruction *inst = prog->Instructions + ir->InstLocation;
assert(inst->BranchTarget < 0);
if (ir->Opcode == IR_BREAK ||
ir->Opcode == IR_BREAK_IF_FALSE ||
ir->Opcode == IR_BREAK_IF_TRUE) {
assert(inst->Opcode == OPCODE_BRK ||
inst->Opcode == OPCODE_BRA);
/* go to instruction after end of loop */
inst->BranchTarget = endInstLoc + 1;
}
else {
assert(ir->Opcode == IR_CONT ||
ir->Opcode == IR_CONT_IF_FALSE ||
ir->Opcode == IR_CONT_IF_TRUE);
assert(inst->Opcode == OPCODE_CONT ||
inst->Opcode == OPCODE_BRA);
/* to go instruction at top of loop */
inst->BranchTarget = beginInstLoc;
}
}
return NULL;
}
/**
* "Continue" or "break" statement.
* Either OPCODE_CONT, OPCODE_BRK or OPCODE_BRA will be emitted.
*/
static struct prog_instruction *
emit_cont_break(slang_emit_info *emitInfo, slang_ir_node *n)
{
gl_inst_opcode opcode;
struct prog_instruction *inst;
n->InstLocation = emitInfo->prog->NumInstructions;
if (emitInfo->EmitHighLevelInstructions) {
opcode = (n->Opcode == IR_CONT) ? OPCODE_CONT : OPCODE_BRK;
}
else {
opcode = OPCODE_BRA;
}
inst = new_instruction(emitInfo, opcode);
inst->DstReg.CondMask = COND_TR; /* always true */
return inst;
}
/**
* Conditional "continue" or "break" statement.
* Either OPCODE_CONT, OPCODE_BRK or OPCODE_BRA will be emitted.
*/
static struct prog_instruction *
emit_cont_break_if(slang_emit_info *emitInfo, slang_ir_node *n,
GLboolean breakTrue)
{
gl_inst_opcode opcode;
struct prog_instruction *inst;
/* evaluate condition expr, setting cond codes */
inst = emit(emitInfo, n->Children[0]);
assert(inst);
inst->CondUpdate = GL_TRUE;
n->InstLocation = emitInfo->prog->NumInstructions;
if (emitInfo->EmitHighLevelInstructions) {
if (n->Opcode == IR_CONT_IF_TRUE ||
n->Opcode == IR_CONT_IF_FALSE)
opcode = OPCODE_CONT;
else
opcode = OPCODE_BRK;
}
else {
opcode = OPCODE_BRA;
}
inst = new_instruction(emitInfo, opcode);
inst->DstReg.CondMask = breakTrue ? COND_NE : COND_EQ;
return inst;
}
/**
* Remove any SWIZZLE_NIL terms from given swizzle mask (smear prev term).
* Ex: fix_swizzle("zyNN") -> "zyyy"
*/
static GLuint
fix_swizzle(GLuint swizzle)
{
GLuint swz[4], i;
for (i = 0; i < 4; i++) {
swz[i] = GET_SWZ(swizzle, i);
if (swz[i] == SWIZZLE_NIL) {
swz[i] = swz[i - 1];
}
}
return MAKE_SWIZZLE4(swz[0], swz[1], swz[2], swz[3]);
}
static struct prog_instruction *
emit_swizzle(slang_emit_info *emitInfo, slang_ir_node *n)
{
GLuint swizzle;
/* swizzled storage access */
(void) emit(emitInfo, n->Children[0]);
/* "pull-up" the child's storage info, applying our swizzle info */
n->Store->File = n->Children[0]->Store->File;
n->Store->Index = n->Children[0]->Store->Index;
n->Store->Size = n->Children[0]->Store->Size;
/*n->Var = n->Children[0]->Var; XXX for debug */
assert(n->Store->Index >= 0);
swizzle = fix_swizzle(n->Store->Swizzle);
#ifdef DEBUG
{
GLuint s = n->Children[0]->Store->Swizzle;
assert(GET_SWZ(s, 0) != SWIZZLE_NIL);
assert(GET_SWZ(s, 1) != SWIZZLE_NIL);
assert(GET_SWZ(s, 2) != SWIZZLE_NIL);
assert(GET_SWZ(s, 3) != SWIZZLE_NIL);
}
#endif
/* apply this swizzle to child's swizzle to get composed swizzle */
n->Store->Swizzle = swizzle_swizzle(n->Children[0]->Store->Swizzle,
swizzle);
return NULL;
}
/**
* Dereference array element. Just resolve storage for the array
* element represented by this node.
*/
static struct prog_instruction *
emit_array_element(slang_emit_info *emitInfo, slang_ir_node *n)
{
assert(n->Store);
assert(n->Store->File != PROGRAM_UNDEFINED);
assert(n->Store->Size > 0);
if (n->Store->File == PROGRAM_STATE_VAR) {
n->Store->Index = _slang_alloc_statevar(n, emitInfo->prog->Parameters);
return NULL;
}
if (n->Children[1]->Opcode == IR_FLOAT) {
/* Constant index */
const GLint arrayAddr = n->Children[0]->Store->Index;
const GLint index = (GLint) n->Children[1]->Value[0];
n->Store->Index = arrayAddr + index;
}
else {
/* Variable index - PROBLEM */
const GLint arrayAddr = n->Children[0]->Store->Index;
const GLint index = 0;
_mesa_problem(NULL, "variable array indexes not supported yet!");
n->Store->Index = arrayAddr + index;
}
return NULL; /* no instruction */
}
/**
* Resolve storage for accessing a structure field.
*/
static struct prog_instruction *
emit_struct_field(slang_emit_info *emitInfo, slang_ir_node *n)
{
if (n->Store->File == PROGRAM_STATE_VAR) {
n->Store->Index = _slang_alloc_statevar(n, emitInfo->prog->Parameters);
}
else {
_mesa_problem(NULL, "structs/fields not supported yet");
}
return NULL; /* no instruction */
}
static struct prog_instruction *
emit(slang_emit_info *emitInfo, slang_ir_node *n)
{
struct prog_instruction *inst;
if (!n)
return NULL;
switch (n->Opcode) {
case IR_SEQ:
/* sequence of two sub-trees */
assert(n->Children[0]);
assert(n->Children[1]);
emit(emitInfo, n->Children[0]);
inst = emit(emitInfo, n->Children[1]);
assert(!n->Store);
n->Store = n->Children[1]->Store;
return inst;
case IR_SCOPE:
/* new variable scope */
_slang_push_var_table(emitInfo->vt);
inst = emit(emitInfo, n->Children[0]);
_slang_pop_var_table(emitInfo->vt);
return inst;
case IR_VAR_DECL:
/* Variable declaration - allocate a register for it */
assert(n->Store);
assert(n->Store->File != PROGRAM_UNDEFINED);
assert(n->Store->Size > 0);
assert(n->Store->Index < 0);
if (!n->Var || n->Var->isTemp) {
/* a nameless/temporary variable, will be freed after first use */
if (!_slang_alloc_temp(emitInfo->vt, n->Store)) {
slang_info_log_error(emitInfo->log,
"Ran out of registers, too many temporaries");
return NULL;
}
}
else {
/* a regular variable */
_slang_add_variable(emitInfo->vt, n->Var);
if (!_slang_alloc_var(emitInfo->vt, n->Store)) {
slang_info_log_error(emitInfo->log,
"Ran out of registers, too many variables");
return NULL;
}
/*
printf("IR_VAR_DECL %s %d store %p\n",
(char*) n->Var->a_name, n->Store->Index, (void*) n->Store);
*/
assert(n->Var->aux == n->Store);
}
if (emitInfo->EmitComments) {
/* emit NOP with comment describing the variable's storage location */
char s[1000];
sprintf(s, "TEMP[%d]%s = %s (size %d)",
n->Store->Index,
_mesa_swizzle_string(n->Store->Swizzle, 0, GL_FALSE),
(char *) n->Var->a_name,
n->Store->Size);
inst = new_instruction(emitInfo, OPCODE_NOP);
inst->Comment = _mesa_strdup(s);
return inst;
}
return NULL;
case IR_VAR:
/* Reference to a variable
* Storage should have already been resolved/allocated.
*/
assert(n->Store);
assert(n->Store->File != PROGRAM_UNDEFINED);
if (n->Store->File == PROGRAM_STATE_VAR &&
n->Store->Index < 0) {
n->Store->Index = _slang_alloc_statevar(n, emitInfo->prog->Parameters);
}
if (n->Store->Index < 0) {
printf("#### VAR %s not allocated!\n", (char*)n->Var->a_name);
}
assert(n->Store->Index >= 0);
assert(n->Store->Size > 0);
break;
case IR_ELEMENT:
return emit_array_element(emitInfo, n);
case IR_FIELD:
return emit_struct_field(emitInfo, n);
case IR_SWIZZLE:
return emit_swizzle(emitInfo, n);
case IR_I_TO_F:
/* just move */
emit(emitInfo, n->Children[0]);
inst = new_instruction(emitInfo, OPCODE_MOV);
if (!n->Store) {
if (!alloc_temp_storage(emitInfo, n, 1))
return NULL;
}
storage_to_dst_reg(&inst->DstReg, n->Store, n->Writemask);
storage_to_src_reg(&inst->SrcReg[0], n->Children[0]->Store);
if (emitInfo->EmitComments)
inst->Comment = _mesa_strdup("int to float");
return NULL;
/* Simple arithmetic */
/* unary */
case IR_RSQ:
case IR_RCP:
case IR_FLOOR:
case IR_FRAC:
case IR_F_TO_I:
case IR_ABS:
case IR_SIN:
case IR_COS:
case IR_DDX:
case IR_DDY:
case IR_NOISE1:
case IR_NOISE2:
case IR_NOISE3:
case IR_NOISE4:
/* binary */
case IR_ADD:
case IR_SUB:
case IR_MUL:
case IR_DOT4:
case IR_DOT3:
case IR_CROSS:
case IR_MIN:
case IR_MAX:
case IR_SEQUAL:
case IR_SNEQUAL:
case IR_SGE:
case IR_SGT:
case IR_SLE:
case IR_SLT:
case IR_POW:
case IR_EXP:
case IR_EXP2:
/* trinary operators */
case IR_LRP:
return emit_arith(emitInfo, n);
case IR_CLAMP:
return emit_clamp(emitInfo, n);
case IR_TEX:
case IR_TEXB:
case IR_TEXP:
return emit_tex(emitInfo, n);
case IR_NEG:
return emit_negation(emitInfo, n);
case IR_FLOAT:
/* find storage location for this float constant */
n->Store->Index = _mesa_add_unnamed_constant(emitInfo->prog->Parameters, n->Value,
n->Store->Size,
&n->Store->Swizzle);
if (n->Store->Index < 0) {
slang_info_log_error(emitInfo->log, "Ran out of space for constants");
return NULL;
}
return NULL;
case IR_MOVE:
return emit_move(emitInfo, n);
case IR_COND:
return emit_cond(emitInfo, n);
case IR_NOT:
return emit_not(emitInfo, n);
case IR_LABEL:
return emit_label(emitInfo, n);
case IR_JUMP:
assert(n);
assert(n->Label);
return emit_jump(emitInfo, n);
case IR_KILL:
return emit_kill(emitInfo);
case IR_IF:
return emit_if(emitInfo, n);
case IR_LOOP:
return emit_loop(emitInfo, n);
case IR_BREAK_IF_FALSE:
case IR_CONT_IF_FALSE:
return emit_cont_break_if(emitInfo, n, GL_FALSE);
case IR_BREAK_IF_TRUE:
case IR_CONT_IF_TRUE:
return emit_cont_break_if(emitInfo, n, GL_TRUE);
case IR_BREAK:
/* fall-through */
case IR_CONT:
return emit_cont_break(emitInfo, n);
case IR_BEGIN_SUB:
return new_instruction(emitInfo, OPCODE_BGNSUB);
case IR_END_SUB:
return new_instruction(emitInfo, OPCODE_ENDSUB);
case IR_RETURN:
return new_instruction(emitInfo, OPCODE_RET);
case IR_NOP:
return NULL;
default:
_mesa_problem(NULL, "Unexpected IR opcode in emit()\n");
abort();
}
return NULL;
}
GLboolean
_slang_emit_code(slang_ir_node *n, slang_var_table *vt,
struct gl_program *prog, GLboolean withEnd,
slang_info_log *log)
{
GET_CURRENT_CONTEXT(ctx);
GLboolean success;
slang_emit_info emitInfo;
emitInfo.log = log;
emitInfo.vt = vt;
emitInfo.prog = prog;
emitInfo.EmitHighLevelInstructions = ctx->Shader.EmitHighLevelInstructions;
emitInfo.EmitComments = ctx->Shader.EmitComments;
(void) emit(&emitInfo, n);
/* finish up by adding the END opcode to program */
if (withEnd) {
struct prog_instruction *inst;
inst = new_instruction(&emitInfo, OPCODE_END);
}
success = GL_TRUE;
printf("*********** End generate code (%u inst):\n", prog->NumInstructions);
#if 0
_mesa_print_program(prog);
_mesa_print_program_parameters(ctx,prog);
#endif
return success;
}
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