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|
/*
* Copyright (C) 2005 Ben Skeggs.
*
* Copyright 2008 Corbin Simpson <MostAwesomeDude@gmail.com>
* Adaptation and modification for ATI/AMD Radeon R500 GPU chipsets.
*
* 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 (including the
* next paragraph) 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 THE COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS 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
*
* \author Ben Skeggs <darktama@iinet.net.au>
*
* \author Jerome Glisse <j.glisse@gmail.com>
*
* \author Corbin Simpson <MostAwesomeDude@gmail.com>
*
*/
#include "r500_fragprog.h"
#include "../r300_reg.h"
#include "radeon_program_pair.h"
#define PROG_CODE \
struct r500_fragment_program_code *code = &c->code->code.r500
#define error(fmt, args...) do { \
rc_error(&c->Base, "%s::%s(): " fmt "\n", \
__FILE__, __FUNCTION__, ##args); \
} while(0)
struct branch_info {
int If;
int Else;
int Endif;
};
struct emit_state {
struct radeon_compiler * C;
struct r500_fragment_program_code * Code;
struct branch_info * Branches;
unsigned int CurrentBranchDepth;
unsigned int BranchesReserved;
unsigned int MaxBranchDepth;
};
static unsigned int translate_rgb_op(struct r300_fragment_program_compiler *c, rc_opcode opcode)
{
switch(opcode) {
case RC_OPCODE_CMP: return R500_ALU_RGBA_OP_CMP;
case RC_OPCODE_DDX: return R500_ALU_RGBA_OP_MDH;
case RC_OPCODE_DDY: return R500_ALU_RGBA_OP_MDV;
case RC_OPCODE_DP3: return R500_ALU_RGBA_OP_DP3;
case RC_OPCODE_DP4: return R500_ALU_RGBA_OP_DP4;
case RC_OPCODE_FRC: return R500_ALU_RGBA_OP_FRC;
default:
error("translate_rgb_op(%d): unknown opcode\n", opcode);
/* fall through */
case RC_OPCODE_NOP:
/* fall through */
case RC_OPCODE_MAD: return R500_ALU_RGBA_OP_MAD;
case RC_OPCODE_MAX: return R500_ALU_RGBA_OP_MAX;
case RC_OPCODE_MIN: return R500_ALU_RGBA_OP_MIN;
case RC_OPCODE_REPL_ALPHA: return R500_ALU_RGBA_OP_SOP;
}
}
static unsigned int translate_alpha_op(struct r300_fragment_program_compiler *c, rc_opcode opcode)
{
switch(opcode) {
case RC_OPCODE_CMP: return R500_ALPHA_OP_CMP;
case RC_OPCODE_COS: return R500_ALPHA_OP_COS;
case RC_OPCODE_DDX: return R500_ALPHA_OP_MDH;
case RC_OPCODE_DDY: return R500_ALPHA_OP_MDV;
case RC_OPCODE_DP3: return R500_ALPHA_OP_DP;
case RC_OPCODE_DP4: return R500_ALPHA_OP_DP;
case RC_OPCODE_EX2: return R500_ALPHA_OP_EX2;
case RC_OPCODE_FRC: return R500_ALPHA_OP_FRC;
case RC_OPCODE_LG2: return R500_ALPHA_OP_LN2;
default:
error("translate_alpha_op(%d): unknown opcode\n", opcode);
/* fall through */
case RC_OPCODE_NOP:
/* fall through */
case RC_OPCODE_MAD: return R500_ALPHA_OP_MAD;
case RC_OPCODE_MAX: return R500_ALPHA_OP_MAX;
case RC_OPCODE_MIN: return R500_ALPHA_OP_MIN;
case RC_OPCODE_RCP: return R500_ALPHA_OP_RCP;
case RC_OPCODE_RSQ: return R500_ALPHA_OP_RSQ;
case RC_OPCODE_SIN: return R500_ALPHA_OP_SIN;
}
}
static unsigned int fix_hw_swizzle(unsigned int swz)
{
if (swz == 5) swz = 6;
if (swz == RC_SWIZZLE_UNUSED) swz = 4;
return swz;
}
static unsigned int translate_arg_rgb(struct rc_pair_instruction *inst, int arg)
{
unsigned int t = inst->RGB.Arg[arg].Source;
int comp;
t |= inst->RGB.Arg[arg].Negate << 11;
t |= inst->RGB.Arg[arg].Abs << 12;
for(comp = 0; comp < 3; ++comp)
t |= fix_hw_swizzle(GET_SWZ(inst->RGB.Arg[arg].Swizzle, comp)) << (3*comp + 2);
return t;
}
static unsigned int translate_arg_alpha(struct rc_pair_instruction *inst, int i)
{
unsigned int t = inst->Alpha.Arg[i].Source;
t |= fix_hw_swizzle(inst->Alpha.Arg[i].Swizzle) << 2;
t |= inst->Alpha.Arg[i].Negate << 5;
t |= inst->Alpha.Arg[i].Abs << 6;
return t;
}
static uint32_t translate_alu_result_op(struct r300_fragment_program_compiler * c, rc_compare_func func)
{
switch(func) {
case RC_COMPARE_FUNC_EQUAL: return R500_INST_ALU_RESULT_OP_EQ;
case RC_COMPARE_FUNC_LESS: return R500_INST_ALU_RESULT_OP_LT;
case RC_COMPARE_FUNC_GEQUAL: return R500_INST_ALU_RESULT_OP_GE;
case RC_COMPARE_FUNC_NOTEQUAL: return R500_INST_ALU_RESULT_OP_NE;
default:
rc_error(&c->Base, "%s: unsupported compare func %i\n", __FUNCTION__, func);
return 0;
}
}
static void use_temporary(struct r500_fragment_program_code* code, unsigned int index)
{
if (index > code->max_temp_idx)
code->max_temp_idx = index;
}
static unsigned int use_source(struct r500_fragment_program_code* code, struct radeon_pair_instruction_source src)
{
if (src.File == RC_FILE_CONSTANT) {
return src.Index | 0x100;
} else if (src.File == RC_FILE_TEMPORARY) {
use_temporary(code, src.Index);
return src.Index;
}
return 0;
}
/**
* Emit a paired ALU instruction.
*/
static void emit_paired(struct r300_fragment_program_compiler *c, struct rc_pair_instruction *inst)
{
PROG_CODE;
if (code->inst_end >= 511) {
error("emit_alu: Too many instructions");
return;
}
int ip = ++code->inst_end;
code->inst[ip].inst5 = translate_rgb_op(c, inst->RGB.Opcode);
code->inst[ip].inst4 = translate_alpha_op(c, inst->Alpha.Opcode);
if (inst->RGB.OutputWriteMask || inst->Alpha.OutputWriteMask || inst->Alpha.DepthWriteMask) {
code->inst[ip].inst0 = R500_INST_TYPE_OUT;
if (inst->WriteALUResult) {
error("%s: cannot write output and ALU result at the same time");
return;
}
} else {
code->inst[ip].inst0 = R500_INST_TYPE_ALU;
}
code->inst[ip].inst0 |= R500_INST_TEX_SEM_WAIT;
code->inst[ip].inst0 |= (inst->RGB.WriteMask << 11) | (inst->Alpha.WriteMask << 14);
code->inst[ip].inst0 |= (inst->RGB.OutputWriteMask << 15) | (inst->Alpha.OutputWriteMask << 18);
if (inst->Alpha.DepthWriteMask) {
code->inst[ip].inst4 |= R500_ALPHA_W_OMASK;
c->code->writes_depth = 1;
}
code->inst[ip].inst4 |= R500_ALPHA_ADDRD(inst->Alpha.DestIndex);
code->inst[ip].inst5 |= R500_ALU_RGBA_ADDRD(inst->RGB.DestIndex);
use_temporary(code, inst->Alpha.DestIndex);
use_temporary(code, inst->RGB.DestIndex);
if (inst->RGB.Saturate)
code->inst[ip].inst0 |= R500_INST_RGB_CLAMP;
if (inst->Alpha.Saturate)
code->inst[ip].inst0 |= R500_INST_ALPHA_CLAMP;
code->inst[ip].inst1 |= R500_RGB_ADDR0(use_source(code, inst->RGB.Src[0]));
code->inst[ip].inst1 |= R500_RGB_ADDR1(use_source(code, inst->RGB.Src[1]));
code->inst[ip].inst1 |= R500_RGB_ADDR2(use_source(code, inst->RGB.Src[2]));
code->inst[ip].inst2 |= R500_ALPHA_ADDR0(use_source(code, inst->Alpha.Src[0]));
code->inst[ip].inst2 |= R500_ALPHA_ADDR1(use_source(code, inst->Alpha.Src[1]));
code->inst[ip].inst2 |= R500_ALPHA_ADDR2(use_source(code, inst->Alpha.Src[2]));
code->inst[ip].inst3 |= translate_arg_rgb(inst, 0) << R500_ALU_RGB_SEL_A_SHIFT;
code->inst[ip].inst3 |= translate_arg_rgb(inst, 1) << R500_ALU_RGB_SEL_B_SHIFT;
code->inst[ip].inst5 |= translate_arg_rgb(inst, 2) << R500_ALU_RGBA_SEL_C_SHIFT;
code->inst[ip].inst4 |= translate_arg_alpha(inst, 0) << R500_ALPHA_SEL_A_SHIFT;
code->inst[ip].inst4 |= translate_arg_alpha(inst, 1) << R500_ALPHA_SEL_B_SHIFT;
code->inst[ip].inst5 |= translate_arg_alpha(inst, 2) << R500_ALU_RGBA_ALPHA_SEL_C_SHIFT;
if (inst->WriteALUResult) {
code->inst[ip].inst3 |= R500_ALU_RGB_WMASK;
if (inst->WriteALUResult == RC_ALURESULT_X)
code->inst[ip].inst0 |= R500_INST_ALU_RESULT_SEL_RED;
else
code->inst[ip].inst0 |= R500_INST_ALU_RESULT_SEL_ALPHA;
code->inst[ip].inst0 |= translate_alu_result_op(c, inst->ALUResultCompare);
}
}
static unsigned int translate_strq_swizzle(unsigned int swizzle)
{
unsigned int swiz = 0;
int i;
for (i = 0; i < 4; i++)
swiz |= (GET_SWZ(swizzle, i) & 0x3) << i*2;
return swiz;
}
/**
* Emit a single TEX instruction
*/
static int emit_tex(struct r300_fragment_program_compiler *c, struct rc_sub_instruction *inst)
{
PROG_CODE;
if (code->inst_end >= 511) {
error("emit_tex: Too many instructions");
return 0;
}
int ip = ++code->inst_end;
code->inst[ip].inst0 = R500_INST_TYPE_TEX
| (inst->DstReg.WriteMask << 11)
| R500_INST_TEX_SEM_WAIT;
code->inst[ip].inst1 = R500_TEX_ID(inst->TexSrcUnit)
| R500_TEX_SEM_ACQUIRE | R500_TEX_IGNORE_UNCOVERED;
if (inst->TexSrcTarget == RC_TEXTURE_RECT)
code->inst[ip].inst1 |= R500_TEX_UNSCALED;
switch (inst->Opcode) {
case RC_OPCODE_KIL:
code->inst[ip].inst1 |= R500_TEX_INST_TEXKILL;
break;
case RC_OPCODE_TEX:
code->inst[ip].inst1 |= R500_TEX_INST_LD;
break;
case RC_OPCODE_TXB:
code->inst[ip].inst1 |= R500_TEX_INST_LODBIAS;
break;
case RC_OPCODE_TXP:
code->inst[ip].inst1 |= R500_TEX_INST_PROJ;
break;
default:
error("emit_tex can't handle opcode %x\n", inst->Opcode);
}
use_temporary(code, inst->SrcReg[0].Index);
if (inst->Opcode != RC_OPCODE_KIL)
use_temporary(code, inst->DstReg.Index);
code->inst[ip].inst2 = R500_TEX_SRC_ADDR(inst->SrcReg[0].Index)
| (translate_strq_swizzle(inst->SrcReg[0].Swizzle) << 8)
| R500_TEX_DST_ADDR(inst->DstReg.Index)
| R500_TEX_DST_R_SWIZ_R | R500_TEX_DST_G_SWIZ_G
| R500_TEX_DST_B_SWIZ_B | R500_TEX_DST_A_SWIZ_A;
return 1;
}
static void grow_branches(struct emit_state * s)
{
unsigned int newreserved = s->BranchesReserved * 2;
struct branch_info * newbranches;
if (!newreserved)
newreserved = 4;
newbranches = memory_pool_malloc(&s->C->Pool, newreserved*sizeof(struct branch_info));
memcpy(newbranches, s->Branches, s->CurrentBranchDepth*sizeof(struct branch_info));
s->Branches = newbranches;
s->BranchesReserved = newreserved;
}
static void emit_flowcontrol(struct emit_state * s, struct rc_instruction * inst)
{
if (s->Code->inst_end >= 511) {
rc_error(s->C, "emit_tex: Too many instructions");
return;
}
unsigned int newip = ++s->Code->inst_end;
s->Code->inst[newip].inst0 = R500_INST_TYPE_FC | R500_INST_ALU_WAIT;
if (inst->U.I.Opcode == RC_OPCODE_IF) {
if (s->CurrentBranchDepth >= 32) {
rc_error(s->C, "Branch depth exceeds hardware limit");
return;
}
if (s->CurrentBranchDepth >= s->BranchesReserved)
grow_branches(s);
struct branch_info * branch = &s->Branches[s->CurrentBranchDepth++];
branch->If = newip;
branch->Else = -1;
branch->Endif = -1;
if (s->CurrentBranchDepth > s->MaxBranchDepth)
s->MaxBranchDepth = s->CurrentBranchDepth;
/* actual instruction is filled in at ENDIF time */
} else if (inst->U.I.Opcode == RC_OPCODE_ELSE) {
if (!s->CurrentBranchDepth) {
rc_error(s->C, "%s: got ELSE outside a branch", __FUNCTION__);
return;
}
struct branch_info * branch = &s->Branches[s->CurrentBranchDepth - 1];
branch->Else = newip;
/* actual instruction is filled in at ENDIF time */
} else if (inst->U.I.Opcode == RC_OPCODE_ENDIF) {
if (!s->CurrentBranchDepth) {
rc_error(s->C, "%s: got ELSE outside a branch", __FUNCTION__);
return;
}
struct branch_info * branch = &s->Branches[s->CurrentBranchDepth - 1];
branch->Endif = newip;
s->Code->inst[branch->If].inst2 = R500_FC_OP_JUMP
| R500_FC_A_OP_NONE /* no address stack */
| R500_FC_JUMP_FUNC(0x0f) /* jump if ALU result is false */
| R500_FC_B_OP0_INCR /* increment branch counter if stay */
;
if (branch->Else >= 0) {
/* increment branch counter also if jump */
s->Code->inst[branch->If].inst2 |= R500_FC_B_OP1_INCR;
s->Code->inst[branch->If].inst3 = R500_FC_JUMP_ADDR(branch->Else + 1);
s->Code->inst[branch->Else].inst2 = R500_FC_OP_JUMP
| R500_FC_A_OP_NONE /* no address stack */
| R500_FC_B_ELSE /* all active pixels want to jump */
| R500_FC_B_OP0_NONE /* no counter op if stay */
| R500_FC_B_OP1_DECR /* decrement branch counter if jump */
| R500_FC_B_POP_CNT(1)
;
s->Code->inst[branch->Else].inst3 = R500_FC_JUMP_ADDR(branch->Endif + 1);
} else {
/* don't touch branch counter on jump */
s->Code->inst[branch->If].inst2 |= R500_FC_B_OP1_NONE;
s->Code->inst[branch->If].inst3 = R500_FC_JUMP_ADDR(branch->Endif + 1);
}
s->Code->inst[branch->Endif].inst2 = R500_FC_OP_JUMP
| R500_FC_A_OP_NONE /* no address stack */
| R500_FC_JUMP_ANY /* docs says set this, but I don't understand why */
| R500_FC_B_OP0_DECR /* decrement branch counter if stay */
| R500_FC_B_OP1_NONE /* no branch counter if stay */
| R500_FC_B_POP_CNT(1)
;
s->Code->inst[branch->Endif].inst3 = R500_FC_JUMP_ADDR(branch->Endif + 1);
s->CurrentBranchDepth--;
} else {
rc_error(s->C, "%s: unknown opcode %i\n", __FUNCTION__, inst->U.I.Opcode);
}
}
void r500BuildFragmentProgramHwCode(struct r300_fragment_program_compiler *compiler)
{
struct emit_state s;
struct r500_fragment_program_code *code = &compiler->code->code.r500;
memset(&s, 0, sizeof(s));
s.C = &compiler->Base;
s.Code = code;
memset(code, 0, sizeof(*code));
code->max_temp_idx = 1;
code->inst_end = -1;
for(struct rc_instruction * inst = compiler->Base.Program.Instructions.Next;
inst != &compiler->Base.Program.Instructions && !compiler->Base.Error;
inst = inst->Next) {
if (inst->Type == RC_INSTRUCTION_NORMAL) {
const struct rc_opcode_info * opcode = rc_get_opcode_info(inst->U.I.Opcode);
if (opcode->IsFlowControl) {
emit_flowcontrol(&s, inst);
} else if (inst->U.I.Opcode == RC_OPCODE_BEGIN_TEX) {
continue;
} else {
emit_tex(compiler, &inst->U.I);
}
} else {
emit_paired(compiler, &inst->U.P);
}
}
if (code->max_temp_idx >= 128)
rc_error(&compiler->Base, "Too many hardware temporaries used");
if (compiler->Base.Error)
return;
if ((code->inst[code->inst_end].inst0 & R500_INST_TYPE_MASK) != R500_INST_TYPE_OUT) {
/* This may happen when dead-code elimination is disabled or
* when most of the fragment program logic is leading to a KIL */
if (code->inst_end >= 511) {
rc_error(&compiler->Base, "Introducing fake OUT: Too many instructions");
return;
}
int ip = ++code->inst_end;
code->inst[ip].inst0 = R500_INST_TYPE_OUT | R500_INST_TEX_SEM_WAIT;
}
if (s.MaxBranchDepth >= 4) {
if (code->max_temp_idx < 1)
code->max_temp_idx = 1;
code->us_fc_ctrl |= R500_FC_FULL_FC_EN;
}
}
|