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|
/**************************************************************************
*
* Copyright 2008 Tungsten Graphics, Inc., Cedar Park, Texas.
* 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, sub license, 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 NON-INFRINGEMENT.
* IN NO EVENT SHALL TUNGSTEN GRAPHICS 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.
*
**************************************************************************/
/**
* TGSI to PowerPC code generation.
*/
#include "pipe/p_config.h"
#if defined(PIPE_ARCH_PPC)
#include "util/u_debug.h"
#include "pipe/p_shader_tokens.h"
#include "util/u_math.h"
#include "util/u_memory.h"
#include "util/u_sse.h"
#include "tgsi/tgsi_info.h"
#include "tgsi/tgsi_parse.h"
#include "tgsi/tgsi_util.h"
#include "tgsi_dump.h"
#include "tgsi_exec.h"
#include "tgsi_ppc.h"
#include "rtasm/rtasm_ppc.h"
/**
* Since it's pretty much impossible to form PPC vector immediates, load
* them from memory here:
*/
PIPE_ALIGN_VAR(16, const float ppc_builtin_constants[]) = {
1.0f, -128.0f, 128.0, 0.0
};
#define FOR_EACH_CHANNEL( CHAN )\
for (CHAN = 0; CHAN < NUM_CHANNELS; CHAN++)
#define IS_DST0_CHANNEL_ENABLED( INST, CHAN )\
((INST).Dst[0].Register.WriteMask & (1 << (CHAN)))
#define IF_IS_DST0_CHANNEL_ENABLED( INST, CHAN )\
if (IS_DST0_CHANNEL_ENABLED( INST, CHAN ))
#define FOR_EACH_DST0_ENABLED_CHANNEL( INST, CHAN )\
FOR_EACH_CHANNEL( CHAN )\
IF_IS_DST0_CHANNEL_ENABLED( INST, CHAN )
#define CHAN_X 0
#define CHAN_Y 1
#define CHAN_Z 2
#define CHAN_W 3
/**
* How many TGSI temps should be implemented with real PPC vector registers
* rather than memory.
*/
#define MAX_PPC_TEMPS 3
/**
* Context/state used during code gen.
*/
struct gen_context
{
struct ppc_function *f;
int inputs_reg; /**< GP register pointing to input params */
int outputs_reg; /**< GP register pointing to output params */
int temps_reg; /**< GP register pointing to temporary "registers" */
int immed_reg; /**< GP register pointing to immediates buffer */
int const_reg; /**< GP register pointing to constants buffer */
int builtins_reg; /**< GP register pointint to built-in constants */
int offset_reg; /**< used to reduce redundant li instructions */
int offset_value;
int one_vec; /**< vector register with {1.0, 1.0, 1.0, 1.0} */
int bit31_vec; /**< vector register with {1<<31, 1<<31, 1<<31, 1<<31} */
/**
* Map TGSI temps to PPC vector temps.
* We have 32 PPC vector regs. Use 16 of them for storing 4 TGSI temps.
* XXX currently only do this for TGSI temps [0..MAX_PPC_TEMPS-1].
*/
int temps_map[MAX_PPC_TEMPS][4];
/**
* Cache of src registers.
* This is used to avoid redundant load instructions.
*/
struct {
struct tgsi_full_src_register src;
uint chan;
uint vec;
} regs[12]; /* 3 src regs, 4 channels */
uint num_regs;
};
/**
* Initialize code generation context.
*/
static void
init_gen_context(struct gen_context *gen, struct ppc_function *func)
{
uint i;
memset(gen, 0, sizeof(*gen));
gen->f = func;
gen->inputs_reg = ppc_reserve_register(func, 3); /* first function param */
gen->outputs_reg = ppc_reserve_register(func, 4); /* second function param */
gen->temps_reg = ppc_reserve_register(func, 5); /* ... */
gen->immed_reg = ppc_reserve_register(func, 6);
gen->const_reg = ppc_reserve_register(func, 7);
gen->builtins_reg = ppc_reserve_register(func, 8);
gen->one_vec = -1;
gen->bit31_vec = -1;
gen->offset_reg = -1;
gen->offset_value = -9999999;
for (i = 0; i < MAX_PPC_TEMPS; i++) {
gen->temps_map[i][0] = ppc_allocate_vec_register(gen->f);
gen->temps_map[i][1] = ppc_allocate_vec_register(gen->f);
gen->temps_map[i][2] = ppc_allocate_vec_register(gen->f);
gen->temps_map[i][3] = ppc_allocate_vec_register(gen->f);
}
}
/**
* Is the given TGSI register stored as a real PPC vector register?
*/
static boolean
is_ppc_vec_temporary(const struct tgsi_full_src_register *reg)
{
return (reg->Register.File == TGSI_FILE_TEMPORARY &&
reg->Register.Index < MAX_PPC_TEMPS);
}
/**
* Is the given TGSI register stored as a real PPC vector register?
*/
static boolean
is_ppc_vec_temporary_dst(const struct tgsi_full_dst_register *reg)
{
return (reg->Register.File == TGSI_FILE_TEMPORARY &&
reg->Register.Index < MAX_PPC_TEMPS);
}
/**
* All PPC vector load/store instructions form an effective address
* by adding the contents of two registers. For example:
* lvx v2,r8,r9 # v2 = memory[r8 + r9]
* stvx v2,r8,r9 # memory[r8 + r9] = v2;
* So our lvx/stvx instructions are typically preceded by an 'li' instruction
* to load r9 (above) with an immediate (an offset).
* This code emits that 'li' instruction, but only if the offset value is
* different than the previous 'li'.
* This optimization seems to save about 10% in the instruction count.
* Note that we need to unconditionally emit an 'li' inside basic blocks
* (such as inside loops).
*/
static int
emit_li_offset(struct gen_context *gen, int offset)
{
if (gen->offset_reg <= 0) {
/* allocate a GP register for storing load/store offset */
gen->offset_reg = ppc_allocate_register(gen->f);
}
/* emit new 'li' if offset is changing */
if (gen->offset_value < 0 || gen->offset_value != offset) {
gen->offset_value = offset;
ppc_li(gen->f, gen->offset_reg, offset);
}
return gen->offset_reg;
}
/**
* Forces subsequent emit_li_offset() calls to emit an 'li'.
* To be called at the top of basic blocks.
*/
static void
reset_li_offset(struct gen_context *gen)
{
gen->offset_value = -9999999;
}
/**
* Load the given vector register with {value, value, value, value}.
* The value must be in the ppu_builtin_constants[] array.
* We wouldn't need this if there was a simple way to load PPC vector
* registers with immediate values!
*/
static void
load_constant_vec(struct gen_context *gen, int dst_vec, float value)
{
uint pos;
for (pos = 0; pos < Elements(ppc_builtin_constants); pos++) {
if (ppc_builtin_constants[pos] == value) {
int offset = pos * 4;
int offset_reg = emit_li_offset(gen, offset);
/* Load 4-byte word into vector register.
* The vector slot depends on the effective address we load from.
* We know that our builtins start at a 16-byte boundary so we
* know that 'swizzle' tells us which vector slot will have the
* loaded word. The other vector slots will be undefined.
*/
ppc_lvewx(gen->f, dst_vec, gen->builtins_reg, offset_reg);
/* splat word[pos % 4] across the vector reg */
ppc_vspltw(gen->f, dst_vec, dst_vec, pos % 4);
return;
}
}
assert(0 && "Need to add new constant to ppc_builtin_constants array");
}
/**
* Return index of vector register containing {1.0, 1.0, 1.0, 1.0}.
*/
static int
gen_one_vec(struct gen_context *gen)
{
if (gen->one_vec < 0) {
gen->one_vec = ppc_allocate_vec_register(gen->f);
load_constant_vec(gen, gen->one_vec, 1.0f);
}
return gen->one_vec;
}
/**
* Return index of vector register containing {1<<31, 1<<31, 1<<31, 1<<31}.
*/
static int
gen_get_bit31_vec(struct gen_context *gen)
{
if (gen->bit31_vec < 0) {
gen->bit31_vec = ppc_allocate_vec_register(gen->f);
ppc_vspltisw(gen->f, gen->bit31_vec, -1);
ppc_vslw(gen->f, gen->bit31_vec, gen->bit31_vec, gen->bit31_vec);
}
return gen->bit31_vec;
}
/**
* Register fetch. Return PPC vector register with result.
*/
static int
emit_fetch(struct gen_context *gen,
const struct tgsi_full_src_register *reg,
const unsigned chan_index)
{
uint swizzle = tgsi_util_get_full_src_register_swizzle(reg, chan_index);
int dst_vec = -1;
switch (swizzle) {
case TGSI_SWIZZLE_X:
case TGSI_SWIZZLE_Y:
case TGSI_SWIZZLE_Z:
case TGSI_SWIZZLE_W:
switch (reg->Register.File) {
case TGSI_FILE_INPUT:
case TGSI_FILE_SYSTEM_VALUE:
{
int offset = (reg->Register.Index * 4 + swizzle) * 16;
int offset_reg = emit_li_offset(gen, offset);
dst_vec = ppc_allocate_vec_register(gen->f);
ppc_lvx(gen->f, dst_vec, gen->inputs_reg, offset_reg);
}
break;
case TGSI_FILE_TEMPORARY:
if (is_ppc_vec_temporary(reg)) {
/* use PPC vec register */
dst_vec = gen->temps_map[reg->Register.Index][swizzle];
}
else {
/* use memory-based temp register "file" */
int offset = (reg->Register.Index * 4 + swizzle) * 16;
int offset_reg = emit_li_offset(gen, offset);
dst_vec = ppc_allocate_vec_register(gen->f);
ppc_lvx(gen->f, dst_vec, gen->temps_reg, offset_reg);
}
break;
case TGSI_FILE_IMMEDIATE:
{
int offset = (reg->Register.Index * 4 + swizzle) * 4;
int offset_reg = emit_li_offset(gen, offset);
dst_vec = ppc_allocate_vec_register(gen->f);
/* Load 4-byte word into vector register.
* The vector slot depends on the effective address we load from.
* We know that our immediates start at a 16-byte boundary so we
* know that 'swizzle' tells us which vector slot will have the
* loaded word. The other vector slots will be undefined.
*/
ppc_lvewx(gen->f, dst_vec, gen->immed_reg, offset_reg);
/* splat word[swizzle] across the vector reg */
ppc_vspltw(gen->f, dst_vec, dst_vec, swizzle);
}
break;
case TGSI_FILE_CONSTANT:
{
int offset = (reg->Register.Index * 4 + swizzle) * 4;
int offset_reg = emit_li_offset(gen, offset);
dst_vec = ppc_allocate_vec_register(gen->f);
/* Load 4-byte word into vector register.
* The vector slot depends on the effective address we load from.
* We know that our constants start at a 16-byte boundary so we
* know that 'swizzle' tells us which vector slot will have the
* loaded word. The other vector slots will be undefined.
*/
ppc_lvewx(gen->f, dst_vec, gen->const_reg, offset_reg);
/* splat word[swizzle] across the vector reg */
ppc_vspltw(gen->f, dst_vec, dst_vec, swizzle);
}
break;
default:
assert( 0 );
}
break;
default:
assert( 0 );
}
assert(dst_vec >= 0);
{
uint sign_op = tgsi_util_get_full_src_register_sign_mode(reg, chan_index);
if (sign_op != TGSI_UTIL_SIGN_KEEP) {
int bit31_vec = gen_get_bit31_vec(gen);
int dst_vec2;
if (is_ppc_vec_temporary(reg)) {
/* need to use a new temp */
dst_vec2 = ppc_allocate_vec_register(gen->f);
}
else {
dst_vec2 = dst_vec;
}
switch (sign_op) {
case TGSI_UTIL_SIGN_CLEAR:
/* vec = vec & ~bit31 */
ppc_vandc(gen->f, dst_vec2, dst_vec, bit31_vec);
break;
case TGSI_UTIL_SIGN_SET:
/* vec = vec | bit31 */
ppc_vor(gen->f, dst_vec2, dst_vec, bit31_vec);
break;
case TGSI_UTIL_SIGN_TOGGLE:
/* vec = vec ^ bit31 */
ppc_vxor(gen->f, dst_vec2, dst_vec, bit31_vec);
break;
default:
assert(0);
}
return dst_vec2;
}
}
return dst_vec;
}
/**
* Test if two TGSI src registers refer to the same memory location.
* We use this to avoid redundant register loads.
*/
static boolean
equal_src_locs(const struct tgsi_full_src_register *a, uint chan_a,
const struct tgsi_full_src_register *b, uint chan_b)
{
int swz_a, swz_b;
int sign_a, sign_b;
if (a->Register.File != b->Register.File)
return FALSE;
if (a->Register.Index != b->Register.Index)
return FALSE;
swz_a = tgsi_util_get_full_src_register_swizzle(a, chan_a);
swz_b = tgsi_util_get_full_src_register_swizzle(b, chan_b);
if (swz_a != swz_b)
return FALSE;
sign_a = tgsi_util_get_full_src_register_sign_mode(a, chan_a);
sign_b = tgsi_util_get_full_src_register_sign_mode(b, chan_b);
if (sign_a != sign_b)
return FALSE;
return TRUE;
}
/**
* Given a TGSI src register and channel index, return the PPC vector
* register containing the value. We use a cache to prevent re-loading
* the same register multiple times.
* \return index of PPC vector register with the desired src operand
*/
static int
get_src_vec(struct gen_context *gen,
struct tgsi_full_instruction *inst, int src_reg, uint chan)
{
const const struct tgsi_full_src_register *src =
&inst->Src[src_reg];
int vec;
uint i;
/* check the cache */
for (i = 0; i < gen->num_regs; i++) {
if (equal_src_locs(&gen->regs[i].src, gen->regs[i].chan, src, chan)) {
/* cache hit */
assert(gen->regs[i].vec >= 0);
return gen->regs[i].vec;
}
}
/* cache miss: allocate new vec reg and emit fetch/load code */
vec = emit_fetch(gen, src, chan);
gen->regs[gen->num_regs].src = *src;
gen->regs[gen->num_regs].chan = chan;
gen->regs[gen->num_regs].vec = vec;
gen->num_regs++;
assert(gen->num_regs <= Elements(gen->regs));
assert(vec >= 0);
return vec;
}
/**
* Clear the src operand cache. To be called at the end of each emit function.
*/
static void
release_src_vecs(struct gen_context *gen)
{
uint i;
for (i = 0; i < gen->num_regs; i++) {
const const struct tgsi_full_src_register src = gen->regs[i].src;
if (!is_ppc_vec_temporary(&src)) {
ppc_release_vec_register(gen->f, gen->regs[i].vec);
}
}
gen->num_regs = 0;
}
static int
get_dst_vec(struct gen_context *gen,
const struct tgsi_full_instruction *inst,
unsigned chan_index)
{
const struct tgsi_full_dst_register *reg = &inst->Dst[0];
if (is_ppc_vec_temporary_dst(reg)) {
int vec = gen->temps_map[reg->Register.Index][chan_index];
return vec;
}
else {
return ppc_allocate_vec_register(gen->f);
}
}
/**
* Register store. Store 'src_vec' at location indicated by 'reg'.
* \param free_vec Should the src_vec be released when done?
*/
static void
emit_store(struct gen_context *gen,
int src_vec,
const struct tgsi_full_instruction *inst,
unsigned chan_index,
boolean free_vec)
{
const struct tgsi_full_dst_register *reg = &inst->Dst[0];
switch (reg->Register.File) {
case TGSI_FILE_OUTPUT:
{
int offset = (reg->Register.Index * 4 + chan_index) * 16;
int offset_reg = emit_li_offset(gen, offset);
ppc_stvx(gen->f, src_vec, gen->outputs_reg, offset_reg);
}
break;
case TGSI_FILE_TEMPORARY:
if (is_ppc_vec_temporary_dst(reg)) {
if (!free_vec) {
int dst_vec = gen->temps_map[reg->Register.Index][chan_index];
if (dst_vec != src_vec)
ppc_vmove(gen->f, dst_vec, src_vec);
}
free_vec = FALSE;
}
else {
int offset = (reg->Register.Index * 4 + chan_index) * 16;
int offset_reg = emit_li_offset(gen, offset);
ppc_stvx(gen->f, src_vec, gen->temps_reg, offset_reg);
}
break;
#if 0
case TGSI_FILE_ADDRESS:
emit_addrs(
func,
xmm,
reg->Register.Index,
chan_index );
break;
#endif
default:
assert( 0 );
}
#if 0
switch( inst->Instruction.Saturate ) {
case TGSI_SAT_NONE:
break;
case TGSI_SAT_ZERO_ONE:
/* assert( 0 ); */
break;
case TGSI_SAT_MINUS_PLUS_ONE:
assert( 0 );
break;
}
#endif
if (free_vec)
ppc_release_vec_register(gen->f, src_vec);
}
static void
emit_scalar_unaryop(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
int v0, v1;
uint chan_index;
v0 = get_src_vec(gen, inst, 0, CHAN_X);
v1 = ppc_allocate_vec_register(gen->f);
switch (inst->Instruction.Opcode) {
case TGSI_OPCODE_RSQ:
/* v1 = 1.0 / sqrt(v0) */
ppc_vrsqrtefp(gen->f, v1, v0);
break;
case TGSI_OPCODE_RCP:
/* v1 = 1.0 / v0 */
ppc_vrefp(gen->f, v1, v0);
break;
default:
assert(0);
}
FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) {
emit_store(gen, v1, inst, chan_index, FALSE);
}
release_src_vecs(gen);
ppc_release_vec_register(gen->f, v1);
}
static void
emit_unaryop(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
uint chan_index;
FOR_EACH_DST0_ENABLED_CHANNEL(*inst, chan_index) {
int v0 = get_src_vec(gen, inst, 0, chan_index); /* v0 = srcreg[0] */
int v1 = get_dst_vec(gen, inst, chan_index);
switch (inst->Instruction.Opcode) {
case TGSI_OPCODE_ABS:
/* turn off the most significant bit of each vector float word */
{
int bit31_vec = gen_get_bit31_vec(gen);
ppc_vandc(gen->f, v1, v0, bit31_vec); /* v1 = v0 & ~bit31 */
}
break;
case TGSI_OPCODE_FLR:
ppc_vrfim(gen->f, v1, v0); /* v1 = floor(v0) */
break;
case TGSI_OPCODE_FRC:
ppc_vrfim(gen->f, v1, v0); /* tmp = floor(v0) */
ppc_vsubfp(gen->f, v1, v0, v1); /* v1 = v0 - v1 */
break;
case TGSI_OPCODE_EX2:
ppc_vexptefp(gen->f, v1, v0); /* v1 = 2^v0 */
break;
case TGSI_OPCODE_LG2:
/* XXX this may be broken! */
ppc_vlogefp(gen->f, v1, v0); /* v1 = log2(v0) */
break;
case TGSI_OPCODE_MOV:
if (v0 != v1)
ppc_vmove(gen->f, v1, v0);
break;
default:
assert(0);
}
emit_store(gen, v1, inst, chan_index, TRUE); /* store v0 */
}
release_src_vecs(gen);
}
static void
emit_binop(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
int zero_vec = -1;
uint chan;
if (inst->Instruction.Opcode == TGSI_OPCODE_MUL) {
zero_vec = ppc_allocate_vec_register(gen->f);
ppc_vzero(gen->f, zero_vec);
}
FOR_EACH_DST0_ENABLED_CHANNEL(*inst, chan) {
/* fetch src operands */
int v0 = get_src_vec(gen, inst, 0, chan);
int v1 = get_src_vec(gen, inst, 1, chan);
int v2 = get_dst_vec(gen, inst, chan);
/* emit binop */
switch (inst->Instruction.Opcode) {
case TGSI_OPCODE_ADD:
ppc_vaddfp(gen->f, v2, v0, v1);
break;
case TGSI_OPCODE_SUB:
ppc_vsubfp(gen->f, v2, v0, v1);
break;
case TGSI_OPCODE_MUL:
ppc_vmaddfp(gen->f, v2, v0, v1, zero_vec);
break;
case TGSI_OPCODE_MIN:
ppc_vminfp(gen->f, v2, v0, v1);
break;
case TGSI_OPCODE_MAX:
ppc_vmaxfp(gen->f, v2, v0, v1);
break;
default:
assert(0);
}
/* store v2 */
emit_store(gen, v2, inst, chan, TRUE);
}
if (inst->Instruction.Opcode == TGSI_OPCODE_MUL)
ppc_release_vec_register(gen->f, zero_vec);
release_src_vecs(gen);
}
static void
emit_triop(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
uint chan;
FOR_EACH_DST0_ENABLED_CHANNEL(*inst, chan) {
/* fetch src operands */
int v0 = get_src_vec(gen, inst, 0, chan);
int v1 = get_src_vec(gen, inst, 1, chan);
int v2 = get_src_vec(gen, inst, 2, chan);
int v3 = get_dst_vec(gen, inst, chan);
/* emit ALU */
switch (inst->Instruction.Opcode) {
case TGSI_OPCODE_MAD:
ppc_vmaddfp(gen->f, v3, v0, v1, v2); /* v3 = v0 * v1 + v2 */
break;
case TGSI_OPCODE_LRP:
ppc_vsubfp(gen->f, v3, v1, v2); /* v3 = v1 - v2 */
ppc_vmaddfp(gen->f, v3, v0, v3, v2); /* v3 = v0 * v3 + v2 */
break;
default:
assert(0);
}
/* store v3 */
emit_store(gen, v3, inst, chan, TRUE);
}
release_src_vecs(gen);
}
/**
* Vector comparisons, resulting in 1.0 or 0.0 values.
*/
static void
emit_inequality(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
uint chan;
int one_vec = gen_one_vec(gen);
FOR_EACH_DST0_ENABLED_CHANNEL(*inst, chan) {
/* fetch src operands */
int v0 = get_src_vec(gen, inst, 0, chan);
int v1 = get_src_vec(gen, inst, 1, chan);
int v2 = get_dst_vec(gen, inst, chan);
boolean complement = FALSE;
switch (inst->Instruction.Opcode) {
case TGSI_OPCODE_SNE:
complement = TRUE;
/* fall-through */
case TGSI_OPCODE_SEQ:
ppc_vcmpeqfpx(gen->f, v2, v0, v1); /* v2 = v0 == v1 ? ~0 : 0 */
break;
case TGSI_OPCODE_SGE:
complement = TRUE;
/* fall-through */
case TGSI_OPCODE_SLT:
ppc_vcmpgtfpx(gen->f, v2, v1, v0); /* v2 = v1 > v0 ? ~0 : 0 */
break;
case TGSI_OPCODE_SLE:
complement = TRUE;
/* fall-through */
case TGSI_OPCODE_SGT:
ppc_vcmpgtfpx(gen->f, v2, v0, v1); /* v2 = v0 > v1 ? ~0 : 0 */
break;
default:
assert(0);
}
/* v2 is now {0,0,0,0} or {~0,~0,~0,~0} */
if (complement)
ppc_vandc(gen->f, v2, one_vec, v2); /* v2 = one_vec & ~v2 */
else
ppc_vand(gen->f, v2, one_vec, v2); /* v2 = one_vec & v2 */
/* store v2 */
emit_store(gen, v2, inst, chan, TRUE);
}
release_src_vecs(gen);
}
static void
emit_dotprod(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
int v0, v1, v2;
uint chan_index;
v2 = ppc_allocate_vec_register(gen->f);
ppc_vzero(gen->f, v2); /* v2 = {0, 0, 0, 0} */
v0 = get_src_vec(gen, inst, 0, CHAN_X); /* v0 = src0.XXXX */
v1 = get_src_vec(gen, inst, 1, CHAN_X); /* v1 = src1.XXXX */
ppc_vmaddfp(gen->f, v2, v0, v1, v2); /* v2 = v0 * v1 + v2 */
v0 = get_src_vec(gen, inst, 0, CHAN_Y); /* v0 = src0.YYYY */
v1 = get_src_vec(gen, inst, 1, CHAN_Y); /* v1 = src1.YYYY */
ppc_vmaddfp(gen->f, v2, v0, v1, v2); /* v2 = v0 * v1 + v2 */
v0 = get_src_vec(gen, inst, 0, CHAN_Z); /* v0 = src0.ZZZZ */
v1 = get_src_vec(gen, inst, 1, CHAN_Z); /* v1 = src1.ZZZZ */
ppc_vmaddfp(gen->f, v2, v0, v1, v2); /* v2 = v0 * v1 + v2 */
if (inst->Instruction.Opcode == TGSI_OPCODE_DP4) {
v0 = get_src_vec(gen, inst, 0, CHAN_W); /* v0 = src0.WWWW */
v1 = get_src_vec(gen, inst, 1, CHAN_W); /* v1 = src1.WWWW */
ppc_vmaddfp(gen->f, v2, v0, v1, v2); /* v2 = v0 * v1 + v2 */
}
else if (inst->Instruction.Opcode == TGSI_OPCODE_DPH) {
v1 = get_src_vec(gen, inst, 1, CHAN_W); /* v1 = src1.WWWW */
ppc_vaddfp(gen->f, v2, v2, v1); /* v2 = v2 + v1 */
}
FOR_EACH_DST0_ENABLED_CHANNEL(*inst, chan_index) {
emit_store(gen, v2, inst, chan_index, FALSE); /* store v2, free v2 later */
}
release_src_vecs(gen);
ppc_release_vec_register(gen->f, v2);
}
/** Approximation for vr = pow(va, vb) */
static void
ppc_vec_pow(struct ppc_function *f, int vr, int va, int vb)
{
/* pow(a,b) ~= exp2(log2(a) * b) */
int t_vec = ppc_allocate_vec_register(f);
int zero_vec = ppc_allocate_vec_register(f);
ppc_vzero(f, zero_vec);
ppc_vlogefp(f, t_vec, va); /* t = log2(va) */
ppc_vmaddfp(f, t_vec, t_vec, vb, zero_vec); /* t = t * vb + zero */
ppc_vexptefp(f, vr, t_vec); /* vr = 2^t */
ppc_release_vec_register(f, t_vec);
ppc_release_vec_register(f, zero_vec);
}
static void
emit_lit(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
int one_vec = gen_one_vec(gen);
/* Compute X */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X)) {
emit_store(gen, one_vec, inst, CHAN_X, FALSE);
}
/* Compute Y, Z */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y) ||
IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) {
int x_vec;
int zero_vec = ppc_allocate_vec_register(gen->f);
x_vec = get_src_vec(gen, inst, 0, CHAN_X); /* x_vec = src[0].x */
ppc_vzero(gen->f, zero_vec); /* zero = {0,0,0,0} */
ppc_vmaxfp(gen->f, x_vec, x_vec, zero_vec); /* x_vec = max(x_vec, 0) */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) {
emit_store(gen, x_vec, inst, CHAN_Y, FALSE);
}
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) {
int y_vec, w_vec;
int z_vec = ppc_allocate_vec_register(gen->f);
int pow_vec = ppc_allocate_vec_register(gen->f);
int pos_vec = ppc_allocate_vec_register(gen->f);
int p128_vec = ppc_allocate_vec_register(gen->f);
int n128_vec = ppc_allocate_vec_register(gen->f);
y_vec = get_src_vec(gen, inst, 0, CHAN_Y); /* y_vec = src[0].y */
ppc_vmaxfp(gen->f, y_vec, y_vec, zero_vec); /* y_vec = max(y_vec, 0) */
w_vec = get_src_vec(gen, inst, 0, CHAN_W); /* w_vec = src[0].w */
/* clamp W to [-128, 128] */
load_constant_vec(gen, p128_vec, 128.0f);
load_constant_vec(gen, n128_vec, -128.0f);
ppc_vmaxfp(gen->f, w_vec, w_vec, n128_vec); /* w = max(w, -128) */
ppc_vminfp(gen->f, w_vec, w_vec, p128_vec); /* w = min(w, 128) */
/* if temp.x > 0
* z = pow(tmp.y, tmp.w)
* else
* z = 0.0
*/
ppc_vec_pow(gen->f, pow_vec, y_vec, w_vec); /* pow = pow(y, w) */
ppc_vcmpgtfpx(gen->f, pos_vec, x_vec, zero_vec); /* pos = x > 0 */
ppc_vand(gen->f, z_vec, pow_vec, pos_vec); /* z = pow & pos */
emit_store(gen, z_vec, inst, CHAN_Z, FALSE);
ppc_release_vec_register(gen->f, z_vec);
ppc_release_vec_register(gen->f, pow_vec);
ppc_release_vec_register(gen->f, pos_vec);
ppc_release_vec_register(gen->f, p128_vec);
ppc_release_vec_register(gen->f, n128_vec);
}
ppc_release_vec_register(gen->f, zero_vec);
}
/* Compute W */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_W)) {
emit_store(gen, one_vec, inst, CHAN_W, FALSE);
}
release_src_vecs(gen);
}
static void
emit_exp(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
const int one_vec = gen_one_vec(gen);
int src_vec;
/* get src arg */
src_vec = get_src_vec(gen, inst, 0, CHAN_X);
/* Compute X = 2^floor(src) */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X)) {
int dst_vec = get_dst_vec(gen, inst, CHAN_X);
int tmp_vec = ppc_allocate_vec_register(gen->f);
ppc_vrfim(gen->f, tmp_vec, src_vec); /* tmp = floor(src); */
ppc_vexptefp(gen->f, dst_vec, tmp_vec); /* dst = 2 ^ tmp */
emit_store(gen, dst_vec, inst, CHAN_X, TRUE);
ppc_release_vec_register(gen->f, tmp_vec);
}
/* Compute Y = src - floor(src) */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) {
int dst_vec = get_dst_vec(gen, inst, CHAN_Y);
int tmp_vec = ppc_allocate_vec_register(gen->f);
ppc_vrfim(gen->f, tmp_vec, src_vec); /* tmp = floor(src); */
ppc_vsubfp(gen->f, dst_vec, src_vec, tmp_vec); /* dst = src - tmp */
emit_store(gen, dst_vec, inst, CHAN_Y, TRUE);
ppc_release_vec_register(gen->f, tmp_vec);
}
/* Compute Z = RoughApprox2ToX(src) */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) {
int dst_vec = get_dst_vec(gen, inst, CHAN_Z);
ppc_vexptefp(gen->f, dst_vec, src_vec); /* dst = 2 ^ src */
emit_store(gen, dst_vec, inst, CHAN_Z, TRUE);
}
/* Compute W = 1.0 */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_W)) {
emit_store(gen, one_vec, inst, CHAN_W, FALSE);
}
release_src_vecs(gen);
}
static void
emit_log(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
const int bit31_vec = gen_get_bit31_vec(gen);
const int one_vec = gen_one_vec(gen);
int src_vec, abs_vec;
/* get src arg */
src_vec = get_src_vec(gen, inst, 0, CHAN_X);
/* compute abs(src) */
abs_vec = ppc_allocate_vec_register(gen->f);
ppc_vandc(gen->f, abs_vec, src_vec, bit31_vec); /* abs = src & ~bit31 */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X) &&
IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) {
/* compute tmp = floor(log2(abs)) */
int tmp_vec = ppc_allocate_vec_register(gen->f);
ppc_vlogefp(gen->f, tmp_vec, abs_vec); /* tmp = log2(abs) */
ppc_vrfim(gen->f, tmp_vec, tmp_vec); /* tmp = floor(tmp); */
/* Compute X = tmp */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X)) {
emit_store(gen, tmp_vec, inst, CHAN_X, FALSE);
}
/* Compute Y = abs / 2^tmp */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) {
const int zero_vec = ppc_allocate_vec_register(gen->f);
ppc_vzero(gen->f, zero_vec);
ppc_vexptefp(gen->f, tmp_vec, tmp_vec); /* tmp = 2 ^ tmp */
ppc_vrefp(gen->f, tmp_vec, tmp_vec); /* tmp = 1 / tmp */
/* tmp = abs * tmp + zero */
ppc_vmaddfp(gen->f, tmp_vec, abs_vec, tmp_vec, zero_vec);
emit_store(gen, tmp_vec, inst, CHAN_Y, FALSE);
ppc_release_vec_register(gen->f, zero_vec);
}
ppc_release_vec_register(gen->f, tmp_vec);
}
/* Compute Z = RoughApproxLog2(abs) */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) {
int dst_vec = get_dst_vec(gen, inst, CHAN_Z);
ppc_vlogefp(gen->f, dst_vec, abs_vec); /* dst = log2(abs) */
emit_store(gen, dst_vec, inst, CHAN_Z, TRUE);
}
/* Compute W = 1.0 */
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_W)) {
emit_store(gen, one_vec, inst, CHAN_W, FALSE);
}
ppc_release_vec_register(gen->f, abs_vec);
release_src_vecs(gen);
}
static void
emit_pow(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
int s0_vec = get_src_vec(gen, inst, 0, CHAN_X);
int s1_vec = get_src_vec(gen, inst, 1, CHAN_X);
int pow_vec = ppc_allocate_vec_register(gen->f);
int chan;
ppc_vec_pow(gen->f, pow_vec, s0_vec, s1_vec);
FOR_EACH_DST0_ENABLED_CHANNEL(*inst, chan) {
emit_store(gen, pow_vec, inst, chan, FALSE);
}
ppc_release_vec_register(gen->f, pow_vec);
release_src_vecs(gen);
}
static void
emit_xpd(struct gen_context *gen, struct tgsi_full_instruction *inst)
{
int x0_vec, y0_vec, z0_vec;
int x1_vec, y1_vec, z1_vec;
int zero_vec, tmp_vec;
int tmp2_vec;
zero_vec = ppc_allocate_vec_register(gen->f);
ppc_vzero(gen->f, zero_vec);
tmp_vec = ppc_allocate_vec_register(gen->f);
tmp2_vec = ppc_allocate_vec_register(gen->f);
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y) ||
IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) {
x0_vec = get_src_vec(gen, inst, 0, CHAN_X);
x1_vec = get_src_vec(gen, inst, 1, CHAN_X);
}
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X) ||
IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) {
y0_vec = get_src_vec(gen, inst, 0, CHAN_Y);
y1_vec = get_src_vec(gen, inst, 1, CHAN_Y);
}
if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X) ||
IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) {
z0_vec = get_src_vec(gen, inst, 0, CHAN_Z);
z1_vec = get_src_vec(gen, inst, 1, CHAN_Z);
}
IF_IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X) {
/* tmp = y0 * z1 */
ppc_vmaddfp(gen->f, tmp_vec, y0_vec, z1_vec, zero_vec);
/* tmp = tmp - z0 * y1*/
ppc_vnmsubfp(gen->f, tmp_vec, tmp_vec, z0_vec, y1_vec);
emit_store(gen, tmp_vec, inst, CHAN_X, FALSE);
}
IF_IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y) {
/* tmp = z0 * x1 */
ppc_vmaddfp(gen->f, tmp_vec, z0_vec, x1_vec, zero_vec);
/* tmp = tmp - x0 * z1 */
ppc_vnmsubfp(gen->f, tmp_vec, tmp_vec, x0_vec, z1_vec);
emit_store(gen, tmp_vec, inst, CHAN_Y, FALSE);
}
IF_IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z) {
/* tmp = x0 * y1 */
ppc_vmaddfp(gen->f, tmp_vec, x0_vec, y1_vec, zero_vec);
/* tmp = tmp - y0 * x1 */
ppc_vnmsubfp(gen->f, tmp_vec, tmp_vec, y0_vec, x1_vec);
emit_store(gen, tmp_vec, inst, CHAN_Z, FALSE);
}
/* W is undefined */
ppc_release_vec_register(gen->f, tmp_vec);
ppc_release_vec_register(gen->f, zero_vec);
release_src_vecs(gen);
}
static int
emit_instruction(struct gen_context *gen,
struct tgsi_full_instruction *inst)
{
/* we don't handle saturation/clamping yet */
if (inst->Instruction.Saturate != TGSI_SAT_NONE)
return 0;
/* need to use extra temps to fix SOA dependencies : */
if (tgsi_check_soa_dependencies(inst))
return FALSE;
switch (inst->Instruction.Opcode) {
case TGSI_OPCODE_MOV:
case TGSI_OPCODE_ABS:
case TGSI_OPCODE_FLR:
case TGSI_OPCODE_FRC:
case TGSI_OPCODE_EX2:
case TGSI_OPCODE_LG2:
emit_unaryop(gen, inst);
break;
case TGSI_OPCODE_RSQ:
case TGSI_OPCODE_RCP:
emit_scalar_unaryop(gen, inst);
break;
case TGSI_OPCODE_ADD:
case TGSI_OPCODE_SUB:
case TGSI_OPCODE_MUL:
case TGSI_OPCODE_MIN:
case TGSI_OPCODE_MAX:
emit_binop(gen, inst);
break;
case TGSI_OPCODE_SEQ:
case TGSI_OPCODE_SNE:
case TGSI_OPCODE_SLT:
case TGSI_OPCODE_SGT:
case TGSI_OPCODE_SLE:
case TGSI_OPCODE_SGE:
emit_inequality(gen, inst);
break;
case TGSI_OPCODE_MAD:
case TGSI_OPCODE_LRP:
emit_triop(gen, inst);
break;
case TGSI_OPCODE_DP3:
case TGSI_OPCODE_DP4:
case TGSI_OPCODE_DPH:
emit_dotprod(gen, inst);
break;
case TGSI_OPCODE_LIT:
emit_lit(gen, inst);
break;
case TGSI_OPCODE_LOG:
emit_log(gen, inst);
break;
case TGSI_OPCODE_EXP:
emit_exp(gen, inst);
break;
case TGSI_OPCODE_POW:
emit_pow(gen, inst);
break;
case TGSI_OPCODE_XPD:
emit_xpd(gen, inst);
break;
case TGSI_OPCODE_END:
/* normal end */
return 1;
default:
return 0;
}
return 1;
}
static void
emit_declaration(
struct ppc_function *func,
struct tgsi_full_declaration *decl )
{
if( decl->Declaration.File == TGSI_FILE_INPUT ||
decl->Declaration.File == TGSI_FILE_SYSTEM_VALUE ) {
#if 0
unsigned first, last, mask;
unsigned i, j;
first = decl->Range.First;
last = decl->Range.Last;
mask = decl->Declaration.UsageMask;
for( i = first; i <= last; i++ ) {
for( j = 0; j < NUM_CHANNELS; j++ ) {
if( mask & (1 << j) ) {
switch( decl->Declaration.Interpolate ) {
case TGSI_INTERPOLATE_CONSTANT:
emit_coef_a0( func, 0, i, j );
emit_inputs( func, 0, i, j );
break;
case TGSI_INTERPOLATE_LINEAR:
emit_tempf( func, 0, 0, TGSI_SWIZZLE_X );
emit_coef_dadx( func, 1, i, j );
emit_tempf( func, 2, 0, TGSI_SWIZZLE_Y );
emit_coef_dady( func, 3, i, j );
emit_mul( func, 0, 1 ); /* x * dadx */
emit_coef_a0( func, 4, i, j );
emit_mul( func, 2, 3 ); /* y * dady */
emit_add( func, 0, 4 ); /* x * dadx + a0 */
emit_add( func, 0, 2 ); /* x * dadx + y * dady + a0 */
emit_inputs( func, 0, i, j );
break;
case TGSI_INTERPOLATE_PERSPECTIVE:
emit_tempf( func, 0, 0, TGSI_SWIZZLE_X );
emit_coef_dadx( func, 1, i, j );
emit_tempf( func, 2, 0, TGSI_SWIZZLE_Y );
emit_coef_dady( func, 3, i, j );
emit_mul( func, 0, 1 ); /* x * dadx */
emit_tempf( func, 4, 0, TGSI_SWIZZLE_W );
emit_coef_a0( func, 5, i, j );
emit_rcp( func, 4, 4 ); /* 1.0 / w */
emit_mul( func, 2, 3 ); /* y * dady */
emit_add( func, 0, 5 ); /* x * dadx + a0 */
emit_add( func, 0, 2 ); /* x * dadx + y * dady + a0 */
emit_mul( func, 0, 4 ); /* (x * dadx + y * dady + a0) / w */
emit_inputs( func, 0, i, j );
break;
default:
assert( 0 );
break;
}
}
}
}
#endif
}
}
static void
emit_prologue(struct ppc_function *func)
{
/* XXX set up stack frame */
}
static void
emit_epilogue(struct ppc_function *func)
{
ppc_comment(func, -4, "Epilogue:");
ppc_return(func);
/* XXX restore prev stack frame */
#if 0
debug_printf("PPC: Emitted %u instructions\n", func->num_inst);
#endif
}
/**
* Translate a TGSI vertex/fragment shader to PPC code.
*
* \param tokens the TGSI input shader
* \param func the output PPC code/function
* \param immediates buffer to place immediates, later passed to PPC func
* \return TRUE for success, FALSE if translation failed
*/
boolean
tgsi_emit_ppc(const struct tgsi_token *tokens,
struct ppc_function *func,
float (*immediates)[4],
boolean do_swizzles )
{
static int use_ppc_asm = -1;
struct tgsi_parse_context parse;
/*boolean instruction_phase = FALSE;*/
unsigned ok = 1;
uint num_immediates = 0;
struct gen_context gen;
uint ic = 0;
if (use_ppc_asm < 0) {
/* If GALLIUM_NOPPC is set, don't use PPC codegen */
use_ppc_asm = !debug_get_bool_option("GALLIUM_NOPPC", FALSE);
}
if (!use_ppc_asm)
return FALSE;
if (0) {
debug_printf("\n********* TGSI->PPC ********\n");
tgsi_dump(tokens, 0);
}
util_init_math();
init_gen_context(&gen, func);
emit_prologue(func);
tgsi_parse_init( &parse, tokens );
while (!tgsi_parse_end_of_tokens(&parse) && ok) {
tgsi_parse_token(&parse);
switch (parse.FullToken.Token.Type) {
case TGSI_TOKEN_TYPE_DECLARATION:
if (parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_FRAGMENT) {
emit_declaration(func, &parse.FullToken.FullDeclaration );
}
break;
case TGSI_TOKEN_TYPE_INSTRUCTION:
if (func->print) {
_debug_printf("# ");
ic++;
tgsi_dump_instruction(&parse.FullToken.FullInstruction, ic);
}
ok = emit_instruction(&gen, &parse.FullToken.FullInstruction);
if (!ok) {
uint opcode = parse.FullToken.FullInstruction.Instruction.Opcode;
debug_printf("failed to translate tgsi opcode %d (%s) to PPC (%s)\n",
opcode,
tgsi_get_opcode_name(opcode),
parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_VERTEX ?
"vertex shader" : "fragment shader");
}
break;
case TGSI_TOKEN_TYPE_IMMEDIATE:
/* splat each immediate component into a float[4] vector for SoA */
{
const uint size = parse.FullToken.FullImmediate.Immediate.NrTokens - 1;
uint i;
assert(size <= 4);
assert(num_immediates < TGSI_EXEC_NUM_IMMEDIATES);
for (i = 0; i < size; i++) {
immediates[num_immediates][i] =
parse.FullToken.FullImmediate.u[i].Float;
}
num_immediates++;
}
break;
case TGSI_TOKEN_TYPE_PROPERTY:
break;
default:
ok = 0;
assert( 0 );
}
}
emit_epilogue(func);
tgsi_parse_free( &parse );
if (ppc_num_instructions(func) == 0) {
/* ran out of memory for instructions */
ok = FALSE;
}
if (!ok)
debug_printf("TGSI->PPC translation failed\n");
return ok;
}
#endif /* PIPE_ARCH_PPC */
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