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|
#include "pipe/p_context.h"
#include "pipe/p_defines.h"
#include "pipe/p_state.h"
#include "util/u_inlines.h"
#include "pipe/p_shader_tokens.h"
#include "tgsi/tgsi_parse.h"
#include "tgsi/tgsi_util.h"
#include "nvfx_context.h"
#include "nvfx_shader.h"
#define MAX_CONSTS 128
#define MAX_IMM 32
struct nvfx_fpc {
struct nvfx_fragment_program *fp;
uint attrib_map[PIPE_MAX_SHADER_INPUTS];
unsigned r_temps;
unsigned r_temps_discard;
struct nvfx_sreg r_result[PIPE_MAX_SHADER_OUTPUTS];
struct nvfx_sreg *r_temp;
int num_regs;
unsigned inst_offset;
unsigned have_const;
struct {
int pipe;
float vals[4];
} consts[MAX_CONSTS];
int nr_consts;
struct nvfx_sreg imm[MAX_IMM];
unsigned nr_imm;
};
static INLINE struct nvfx_sreg
temp(struct nvfx_fpc *fpc)
{
int idx = ffs(~fpc->r_temps) - 1;
if (idx < 0) {
NOUVEAU_ERR("out of temps!!\n");
assert(0);
return nvfx_sr(NVFXSR_TEMP, 0);
}
fpc->r_temps |= (1 << idx);
fpc->r_temps_discard |= (1 << idx);
return nvfx_sr(NVFXSR_TEMP, idx);
}
static INLINE void
release_temps(struct nvfx_fpc *fpc)
{
fpc->r_temps &= ~fpc->r_temps_discard;
fpc->r_temps_discard = 0;
}
static INLINE struct nvfx_sreg
constant(struct nvfx_fpc *fpc, int pipe, float vals[4])
{
int idx;
if (fpc->nr_consts == MAX_CONSTS)
assert(0);
idx = fpc->nr_consts++;
fpc->consts[idx].pipe = pipe;
if (pipe == -1)
memcpy(fpc->consts[idx].vals, vals, 4 * sizeof(float));
return nvfx_sr(NVFXSR_CONST, idx);
}
#define arith(cc,s,o,d,m,s0,s1,s2) \
nvfx_fp_arith((cc), (s), NVFX_FP_OP_OPCODE_##o, \
(d), (m), (s0), (s1), (s2))
#define tex(cc,s,o,u,d,m,s0,s1,s2) \
nvfx_fp_tex((cc), (s), NVFX_FP_OP_OPCODE_##o, (u), \
(d), (m), (s0), none, none)
static void
grow_insns(struct nvfx_fpc *fpc, int size)
{
struct nvfx_fragment_program *fp = fpc->fp;
fp->insn_len += size;
fp->insn = realloc(fp->insn, sizeof(uint32_t) * fp->insn_len);
}
static void
emit_src(struct nvfx_fpc *fpc, int pos, struct nvfx_sreg src)
{
struct nvfx_fragment_program *fp = fpc->fp;
uint32_t *hw = &fp->insn[fpc->inst_offset];
uint32_t sr = 0;
switch (src.type) {
case NVFXSR_INPUT:
sr |= (NVFX_FP_REG_TYPE_INPUT << NVFX_FP_REG_TYPE_SHIFT);
hw[0] |= (src.index << NVFX_FP_OP_INPUT_SRC_SHIFT);
break;
case NVFXSR_OUTPUT:
sr |= NVFX_FP_REG_SRC_HALF;
/* fall-through */
case NVFXSR_TEMP:
sr |= (NVFX_FP_REG_TYPE_TEMP << NVFX_FP_REG_TYPE_SHIFT);
sr |= (src.index << NVFX_FP_REG_SRC_SHIFT);
break;
case NVFXSR_CONST:
if (!fpc->have_const) {
grow_insns(fpc, 4);
fpc->have_const = 1;
}
hw = &fp->insn[fpc->inst_offset];
if (fpc->consts[src.index].pipe >= 0) {
struct nvfx_fragment_program_data *fpd;
fp->consts = realloc(fp->consts, ++fp->nr_consts *
sizeof(*fpd));
fpd = &fp->consts[fp->nr_consts - 1];
fpd->offset = fpc->inst_offset + 4;
fpd->index = fpc->consts[src.index].pipe;
memset(&fp->insn[fpd->offset], 0, sizeof(uint32_t) * 4);
} else {
memcpy(&fp->insn[fpc->inst_offset + 4],
fpc->consts[src.index].vals,
sizeof(uint32_t) * 4);
}
sr |= (NVFX_FP_REG_TYPE_CONST << NVFX_FP_REG_TYPE_SHIFT);
break;
case NVFXSR_NONE:
sr |= (NVFX_FP_REG_TYPE_INPUT << NVFX_FP_REG_TYPE_SHIFT);
break;
default:
assert(0);
}
if (src.negate)
sr |= NVFX_FP_REG_NEGATE;
if (src.abs)
hw[1] |= (1 << (29 + pos));
sr |= ((src.swz[0] << NVFX_FP_REG_SWZ_X_SHIFT) |
(src.swz[1] << NVFX_FP_REG_SWZ_Y_SHIFT) |
(src.swz[2] << NVFX_FP_REG_SWZ_Z_SHIFT) |
(src.swz[3] << NVFX_FP_REG_SWZ_W_SHIFT));
hw[pos + 1] |= sr;
}
static void
emit_dst(struct nvfx_fpc *fpc, struct nvfx_sreg dst)
{
struct nvfx_fragment_program *fp = fpc->fp;
uint32_t *hw = &fp->insn[fpc->inst_offset];
switch (dst.type) {
case NVFXSR_TEMP:
if (fpc->num_regs < (dst.index + 1))
fpc->num_regs = dst.index + 1;
break;
case NVFXSR_OUTPUT:
if (dst.index == 1) {
fp->fp_control |= 0xe;
} else {
hw[0] |= NVFX_FP_OP_OUT_REG_HALF;
}
break;
case NVFXSR_NONE:
hw[0] |= (1 << 30);
break;
default:
assert(0);
}
hw[0] |= (dst.index << NVFX_FP_OP_OUT_REG_SHIFT);
}
static void
nvfx_fp_arith(struct nvfx_fpc *fpc, int sat, int op,
struct nvfx_sreg dst, int mask,
struct nvfx_sreg s0, struct nvfx_sreg s1, struct nvfx_sreg s2)
{
struct nvfx_fragment_program *fp = fpc->fp;
uint32_t *hw;
fpc->inst_offset = fp->insn_len;
fpc->have_const = 0;
grow_insns(fpc, 4);
hw = &fp->insn[fpc->inst_offset];
memset(hw, 0, sizeof(uint32_t) * 4);
if (op == NVFX_FP_OP_OPCODE_KIL)
fp->fp_control |= NV34TCL_FP_CONTROL_USES_KIL;
hw[0] |= (op << NVFX_FP_OP_OPCODE_SHIFT);
hw[0] |= (mask << NVFX_FP_OP_OUTMASK_SHIFT);
hw[2] |= (dst.dst_scale << NVFX_FP_OP_DST_SCALE_SHIFT);
if (sat)
hw[0] |= NVFX_FP_OP_OUT_SAT;
if (dst.cc_update)
hw[0] |= NVFX_FP_OP_COND_WRITE_ENABLE;
hw[1] |= (dst.cc_test << NVFX_FP_OP_COND_SHIFT);
hw[1] |= ((dst.cc_swz[0] << NVFX_FP_OP_COND_SWZ_X_SHIFT) |
(dst.cc_swz[1] << NVFX_FP_OP_COND_SWZ_Y_SHIFT) |
(dst.cc_swz[2] << NVFX_FP_OP_COND_SWZ_Z_SHIFT) |
(dst.cc_swz[3] << NVFX_FP_OP_COND_SWZ_W_SHIFT));
emit_dst(fpc, dst);
emit_src(fpc, 0, s0);
emit_src(fpc, 1, s1);
emit_src(fpc, 2, s2);
}
static void
nvfx_fp_tex(struct nvfx_fpc *fpc, int sat, int op, int unit,
struct nvfx_sreg dst, int mask,
struct nvfx_sreg s0, struct nvfx_sreg s1, struct nvfx_sreg s2)
{
struct nvfx_fragment_program *fp = fpc->fp;
nvfx_fp_arith(fpc, sat, op, dst, mask, s0, s1, s2);
fp->insn[fpc->inst_offset] |= (unit << NVFX_FP_OP_TEX_UNIT_SHIFT);
fp->samplers |= (1 << unit);
}
static INLINE struct nvfx_sreg
tgsi_src(struct nvfx_fpc *fpc, const struct tgsi_full_src_register *fsrc)
{
struct nvfx_sreg src;
switch (fsrc->Register.File) {
case TGSI_FILE_INPUT:
src = nvfx_sr(NVFXSR_INPUT,
fpc->attrib_map[fsrc->Register.Index]);
break;
case TGSI_FILE_CONSTANT:
src = constant(fpc, fsrc->Register.Index, NULL);
break;
case TGSI_FILE_IMMEDIATE:
assert(fsrc->Register.Index < fpc->nr_imm);
src = fpc->imm[fsrc->Register.Index];
break;
case TGSI_FILE_TEMPORARY:
src = fpc->r_temp[fsrc->Register.Index];
break;
/* NV40 fragprog result regs are just temps, so this is simple */
case TGSI_FILE_OUTPUT:
src = fpc->r_result[fsrc->Register.Index];
break;
default:
NOUVEAU_ERR("bad src file\n");
break;
}
src.abs = fsrc->Register.Absolute;
src.negate = fsrc->Register.Negate;
src.swz[0] = fsrc->Register.SwizzleX;
src.swz[1] = fsrc->Register.SwizzleY;
src.swz[2] = fsrc->Register.SwizzleZ;
src.swz[3] = fsrc->Register.SwizzleW;
return src;
}
static INLINE struct nvfx_sreg
tgsi_dst(struct nvfx_fpc *fpc, const struct tgsi_full_dst_register *fdst) {
switch (fdst->Register.File) {
case TGSI_FILE_OUTPUT:
return fpc->r_result[fdst->Register.Index];
case TGSI_FILE_TEMPORARY:
return fpc->r_temp[fdst->Register.Index];
case TGSI_FILE_NULL:
return nvfx_sr(NVFXSR_NONE, 0);
default:
NOUVEAU_ERR("bad dst file %d\n", fdst->Register.File);
return nvfx_sr(NVFXSR_NONE, 0);
}
}
static INLINE int
tgsi_mask(uint tgsi)
{
int mask = 0;
if (tgsi & TGSI_WRITEMASK_X) mask |= NVFX_FP_MASK_X;
if (tgsi & TGSI_WRITEMASK_Y) mask |= NVFX_FP_MASK_Y;
if (tgsi & TGSI_WRITEMASK_Z) mask |= NVFX_FP_MASK_Z;
if (tgsi & TGSI_WRITEMASK_W) mask |= NVFX_FP_MASK_W;
return mask;
}
static boolean
nvfx_fragprog_parse_instruction(struct nvfx_context* nvfx, struct nvfx_fpc *fpc,
const struct tgsi_full_instruction *finst)
{
const struct nvfx_sreg none = nvfx_sr(NVFXSR_NONE, 0);
struct nvfx_sreg src[3], dst, tmp;
int mask, sat, unit;
int ai = -1, ci = -1, ii = -1;
int i;
if (finst->Instruction.Opcode == TGSI_OPCODE_END)
return TRUE;
for (i = 0; i < finst->Instruction.NumSrcRegs; i++) {
const struct tgsi_full_src_register *fsrc;
fsrc = &finst->Src[i];
if (fsrc->Register.File == TGSI_FILE_TEMPORARY) {
src[i] = tgsi_src(fpc, fsrc);
}
}
for (i = 0; i < finst->Instruction.NumSrcRegs; i++) {
const struct tgsi_full_src_register *fsrc;
fsrc = &finst->Src[i];
switch (fsrc->Register.File) {
case TGSI_FILE_INPUT:
if (ai == -1 || ai == fsrc->Register.Index) {
ai = fsrc->Register.Index;
src[i] = tgsi_src(fpc, fsrc);
} else {
src[i] = temp(fpc);
arith(fpc, 0, MOV, src[i], NVFX_FP_MASK_ALL,
tgsi_src(fpc, fsrc), none, none);
}
break;
case TGSI_FILE_CONSTANT:
if ((ci == -1 && ii == -1) ||
ci == fsrc->Register.Index) {
ci = fsrc->Register.Index;
src[i] = tgsi_src(fpc, fsrc);
} else {
src[i] = temp(fpc);
arith(fpc, 0, MOV, src[i], NVFX_FP_MASK_ALL,
tgsi_src(fpc, fsrc), none, none);
}
break;
case TGSI_FILE_IMMEDIATE:
if ((ci == -1 && ii == -1) ||
ii == fsrc->Register.Index) {
ii = fsrc->Register.Index;
src[i] = tgsi_src(fpc, fsrc);
} else {
src[i] = temp(fpc);
arith(fpc, 0, MOV, src[i], NVFX_FP_MASK_ALL,
tgsi_src(fpc, fsrc), none, none);
}
break;
case TGSI_FILE_TEMPORARY:
/* handled above */
break;
case TGSI_FILE_SAMPLER:
unit = fsrc->Register.Index;
break;
case TGSI_FILE_OUTPUT:
break;
default:
NOUVEAU_ERR("bad src file\n");
return FALSE;
}
}
dst = tgsi_dst(fpc, &finst->Dst[0]);
mask = tgsi_mask(finst->Dst[0].Register.WriteMask);
sat = (finst->Instruction.Saturate == TGSI_SAT_ZERO_ONE);
switch (finst->Instruction.Opcode) {
case TGSI_OPCODE_ABS:
arith(fpc, sat, MOV, dst, mask, abs(src[0]), none, none);
break;
case TGSI_OPCODE_ADD:
arith(fpc, sat, ADD, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_CMP:
tmp = nvfx_sr(NVFXSR_NONE, 0);
tmp.cc_update = 1;
arith(fpc, 0, MOV, tmp, 0xf, src[0], none, none);
dst.cc_test = NVFX_COND_GE;
arith(fpc, sat, MOV, dst, mask, src[2], none, none);
dst.cc_test = NVFX_COND_LT;
arith(fpc, sat, MOV, dst, mask, src[1], none, none);
break;
case TGSI_OPCODE_COS:
arith(fpc, sat, COS, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_DDX:
if (mask & (NVFX_FP_MASK_Z | NVFX_FP_MASK_W)) {
tmp = temp(fpc);
arith(fpc, sat, DDX, tmp, NVFX_FP_MASK_X | NVFX_FP_MASK_Y,
swz(src[0], Z, W, Z, W), none, none);
arith(fpc, 0, MOV, tmp, NVFX_FP_MASK_Z | NVFX_FP_MASK_W,
swz(tmp, X, Y, X, Y), none, none);
arith(fpc, sat, DDX, tmp, NVFX_FP_MASK_X | NVFX_FP_MASK_Y, src[0],
none, none);
arith(fpc, 0, MOV, dst, mask, tmp, none, none);
} else {
arith(fpc, sat, DDX, dst, mask, src[0], none, none);
}
break;
case TGSI_OPCODE_DDY:
if (mask & (NVFX_FP_MASK_Z | NVFX_FP_MASK_W)) {
tmp = temp(fpc);
arith(fpc, sat, DDY, tmp, NVFX_FP_MASK_X | NVFX_FP_MASK_Y,
swz(src[0], Z, W, Z, W), none, none);
arith(fpc, 0, MOV, tmp, NVFX_FP_MASK_Z | NVFX_FP_MASK_W,
swz(tmp, X, Y, X, Y), none, none);
arith(fpc, sat, DDY, tmp, NVFX_FP_MASK_X | NVFX_FP_MASK_Y, src[0],
none, none);
arith(fpc, 0, MOV, dst, mask, tmp, none, none);
} else {
arith(fpc, sat, DDY, dst, mask, src[0], none, none);
}
break;
case TGSI_OPCODE_DP3:
arith(fpc, sat, DP3, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_DP4:
arith(fpc, sat, DP4, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_DPH:
tmp = temp(fpc);
arith(fpc, 0, DP3, tmp, NVFX_FP_MASK_X, src[0], src[1], none);
arith(fpc, sat, ADD, dst, mask, swz(tmp, X, X, X, X),
swz(src[1], W, W, W, W), none);
break;
case TGSI_OPCODE_DST:
arith(fpc, sat, DST, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_EX2:
arith(fpc, sat, EX2, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_FLR:
arith(fpc, sat, FLR, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_FRC:
arith(fpc, sat, FRC, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_KILP:
arith(fpc, 0, KIL, none, 0, none, none, none);
break;
case TGSI_OPCODE_KIL:
dst = nvfx_sr(NVFXSR_NONE, 0);
dst.cc_update = 1;
arith(fpc, 0, MOV, dst, NVFX_FP_MASK_ALL, src[0], none, none);
dst.cc_update = 0; dst.cc_test = NVFX_COND_LT;
arith(fpc, 0, KIL, dst, 0, none, none, none);
break;
case TGSI_OPCODE_LG2:
arith(fpc, sat, LG2, dst, mask, src[0], none, none);
break;
// case TGSI_OPCODE_LIT:
case TGSI_OPCODE_LRP:
if(!nvfx->is_nv4x)
arith(fpc, sat, LRP_NV30, dst, mask, src[0], src[1], src[2]);
else {
tmp = temp(fpc);
arith(fpc, 0, MAD, tmp, mask, neg(src[0]), src[2], src[2]);
arith(fpc, sat, MAD, dst, mask, src[0], src[1], tmp);
}
break;
case TGSI_OPCODE_MAD:
arith(fpc, sat, MAD, dst, mask, src[0], src[1], src[2]);
break;
case TGSI_OPCODE_MAX:
arith(fpc, sat, MAX, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_MIN:
arith(fpc, sat, MIN, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_MOV:
arith(fpc, sat, MOV, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_MUL:
arith(fpc, sat, MUL, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_POW:
if(!nvfx->is_nv4x)
arith(fpc, sat, POW_NV30, dst, mask, src[0], src[1], none);
else {
tmp = temp(fpc);
arith(fpc, 0, LG2, tmp, NVFX_FP_MASK_X,
swz(src[0], X, X, X, X), none, none);
arith(fpc, 0, MUL, tmp, NVFX_FP_MASK_X, swz(tmp, X, X, X, X),
swz(src[1], X, X, X, X), none);
arith(fpc, sat, EX2, dst, mask,
swz(tmp, X, X, X, X), none, none);
}
break;
case TGSI_OPCODE_RCP:
arith(fpc, sat, RCP, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_RET:
assert(0);
break;
case TGSI_OPCODE_RFL:
if(!nvfx->is_nv4x)
arith(fpc, 0, RFL_NV30, dst, mask, src[0], src[1], none);
else {
tmp = temp(fpc);
arith(fpc, 0, DP3, tmp, NVFX_FP_MASK_X, src[0], src[0], none);
arith(fpc, 0, DP3, tmp, NVFX_FP_MASK_Y, src[0], src[1], none);
arith(fpc, 0, DIV, scale(tmp, 2X), NVFX_FP_MASK_Z,
swz(tmp, Y, Y, Y, Y), swz(tmp, X, X, X, X), none);
arith(fpc, sat, MAD, dst, mask,
swz(tmp, Z, Z, Z, Z), src[0], neg(src[1]));
}
break;
case TGSI_OPCODE_RSQ:
if(!nvfx->is_nv4x)
arith(fpc, sat, RSQ_NV30, dst, mask, abs(swz(src[0], X, X, X, X)), none, none);
else {
tmp = temp(fpc);
arith(fpc, 0, LG2, scale(tmp, INV_2X), NVFX_FP_MASK_X,
abs(swz(src[0], X, X, X, X)), none, none);
arith(fpc, sat, EX2, dst, mask,
neg(swz(tmp, X, X, X, X)), none, none);
}
break;
case TGSI_OPCODE_SCS:
/* avoid overwriting the source */
if(src[0].swz[NVFX_SWZ_X] != NVFX_SWZ_X)
{
if (mask & NVFX_FP_MASK_X) {
arith(fpc, sat, COS, dst, NVFX_FP_MASK_X,
swz(src[0], X, X, X, X), none, none);
}
if (mask & NVFX_FP_MASK_Y) {
arith(fpc, sat, SIN, dst, NVFX_FP_MASK_Y,
swz(src[0], X, X, X, X), none, none);
}
}
else
{
if (mask & NVFX_FP_MASK_Y) {
arith(fpc, sat, SIN, dst, NVFX_FP_MASK_Y,
swz(src[0], X, X, X, X), none, none);
}
if (mask & NVFX_FP_MASK_X) {
arith(fpc, sat, COS, dst, NVFX_FP_MASK_X,
swz(src[0], X, X, X, X), none, none);
}
}
break;
case TGSI_OPCODE_SEQ:
arith(fpc, sat, SEQ, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SFL:
arith(fpc, sat, SFL, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SGE:
arith(fpc, sat, SGE, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SGT:
arith(fpc, sat, SGT, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SIN:
arith(fpc, sat, SIN, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_SLE:
arith(fpc, sat, SLE, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SLT:
arith(fpc, sat, SLT, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SNE:
arith(fpc, sat, SNE, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_STR:
arith(fpc, sat, STR, dst, mask, src[0], src[1], none);
break;
case TGSI_OPCODE_SUB:
arith(fpc, sat, ADD, dst, mask, src[0], neg(src[1]), none);
break;
case TGSI_OPCODE_TEX:
tex(fpc, sat, TEX, unit, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_TXB:
tex(fpc, sat, TXB, unit, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_TXP:
tex(fpc, sat, TXP, unit, dst, mask, src[0], none, none);
break;
case TGSI_OPCODE_XPD:
tmp = temp(fpc);
arith(fpc, 0, MUL, tmp, mask,
swz(src[0], Z, X, Y, Y), swz(src[1], Y, Z, X, X), none);
arith(fpc, sat, MAD, dst, (mask & ~NVFX_FP_MASK_W),
swz(src[0], Y, Z, X, X), swz(src[1], Z, X, Y, Y),
neg(tmp));
break;
default:
NOUVEAU_ERR("invalid opcode %d\n", finst->Instruction.Opcode);
return FALSE;
}
release_temps(fpc);
return TRUE;
}
static boolean
nvfx_fragprog_parse_decl_attrib(struct nvfx_context* nvfx, struct nvfx_fpc *fpc,
const struct tgsi_full_declaration *fdec)
{
int hw;
switch (fdec->Semantic.Name) {
case TGSI_SEMANTIC_POSITION:
hw = NVFX_FP_OP_INPUT_SRC_POSITION;
break;
case TGSI_SEMANTIC_COLOR:
if (fdec->Semantic.Index == 0) {
hw = NVFX_FP_OP_INPUT_SRC_COL0;
} else
if (fdec->Semantic.Index == 1) {
hw = NVFX_FP_OP_INPUT_SRC_COL1;
} else {
NOUVEAU_ERR("bad colour semantic index\n");
return FALSE;
}
break;
case TGSI_SEMANTIC_FOG:
hw = NVFX_FP_OP_INPUT_SRC_FOGC;
break;
case TGSI_SEMANTIC_GENERIC:
if (fdec->Semantic.Index <= 7) {
hw = NVFX_FP_OP_INPUT_SRC_TC(fdec->Semantic.
Index);
} else {
NOUVEAU_ERR("bad generic semantic index\n");
return FALSE;
}
break;
default:
NOUVEAU_ERR("bad input semantic\n");
return FALSE;
}
fpc->attrib_map[fdec->Range.First] = hw;
return TRUE;
}
static boolean
nvfx_fragprog_parse_decl_output(struct nvfx_context* nvfx, struct nvfx_fpc *fpc,
const struct tgsi_full_declaration *fdec)
{
unsigned idx = fdec->Range.First;
unsigned hw;
switch (fdec->Semantic.Name) {
case TGSI_SEMANTIC_POSITION:
hw = 1;
break;
case TGSI_SEMANTIC_COLOR:
hw = ~0;
switch (fdec->Semantic.Index) {
case 0: hw = 0; break;
case 1: hw = 2; break;
case 2: hw = 3; break;
case 3: hw = 4; break;
}
if(hw > ((nvfx->is_nv4x) ? 4 : 2)) {
NOUVEAU_ERR("bad rcol index\n");
return FALSE;
}
break;
default:
NOUVEAU_ERR("bad output semantic\n");
return FALSE;
}
fpc->r_result[idx] = nvfx_sr(NVFXSR_OUTPUT, hw);
fpc->r_temps |= (1 << hw);
return TRUE;
}
static boolean
nvfx_fragprog_prepare(struct nvfx_context* nvfx, struct nvfx_fpc *fpc)
{
struct tgsi_parse_context p;
int high_temp = -1, i;
tgsi_parse_init(&p, fpc->fp->pipe.tokens);
while (!tgsi_parse_end_of_tokens(&p)) {
const union tgsi_full_token *tok = &p.FullToken;
tgsi_parse_token(&p);
switch(tok->Token.Type) {
case TGSI_TOKEN_TYPE_DECLARATION:
{
const struct tgsi_full_declaration *fdec;
fdec = &p.FullToken.FullDeclaration;
switch (fdec->Declaration.File) {
case TGSI_FILE_INPUT:
if (!nvfx_fragprog_parse_decl_attrib(nvfx, fpc, fdec))
goto out_err;
break;
case TGSI_FILE_OUTPUT:
if (!nvfx_fragprog_parse_decl_output(nvfx, fpc, fdec))
goto out_err;
break;
case TGSI_FILE_TEMPORARY:
if (fdec->Range.Last > high_temp) {
high_temp =
fdec->Range.Last;
}
break;
default:
break;
}
}
break;
case TGSI_TOKEN_TYPE_IMMEDIATE:
{
struct tgsi_full_immediate *imm;
float vals[4];
imm = &p.FullToken.FullImmediate;
assert(imm->Immediate.DataType == TGSI_IMM_FLOAT32);
assert(fpc->nr_imm < MAX_IMM);
vals[0] = imm->u[0].Float;
vals[1] = imm->u[1].Float;
vals[2] = imm->u[2].Float;
vals[3] = imm->u[3].Float;
fpc->imm[fpc->nr_imm++] = constant(fpc, -1, vals);
}
break;
default:
break;
}
}
tgsi_parse_free(&p);
if (++high_temp) {
fpc->r_temp = CALLOC(high_temp, sizeof(struct nvfx_sreg));
for (i = 0; i < high_temp; i++)
fpc->r_temp[i] = temp(fpc);
fpc->r_temps_discard = 0;
}
return TRUE;
out_err:
if (fpc->r_temp)
FREE(fpc->r_temp);
tgsi_parse_free(&p);
return FALSE;
}
static void
nvfx_fragprog_translate(struct nvfx_context *nvfx,
struct nvfx_fragment_program *fp)
{
struct tgsi_parse_context parse;
struct nvfx_fpc *fpc = NULL;
fpc = CALLOC(1, sizeof(struct nvfx_fpc));
if (!fpc)
return;
fpc->fp = fp;
fpc->num_regs = 2;
if (!nvfx_fragprog_prepare(nvfx, fpc)) {
FREE(fpc);
return;
}
tgsi_parse_init(&parse, fp->pipe.tokens);
while (!tgsi_parse_end_of_tokens(&parse)) {
tgsi_parse_token(&parse);
switch (parse.FullToken.Token.Type) {
case TGSI_TOKEN_TYPE_INSTRUCTION:
{
const struct tgsi_full_instruction *finst;
finst = &parse.FullToken.FullInstruction;
if (!nvfx_fragprog_parse_instruction(nvfx, fpc, finst))
goto out_err;
}
break;
default:
break;
}
}
if(!nvfx->is_nv4x)
fp->fp_control |= (fpc->num_regs-1)/2;
else
fp->fp_control |= fpc->num_regs << NV40TCL_FP_CONTROL_TEMP_COUNT_SHIFT;
/* Terminate final instruction */
if(fp->insn)
fp->insn[fpc->inst_offset] |= 0x00000001;
/* Append NOP + END instruction, may or may not be necessary. */
fpc->inst_offset = fp->insn_len;
grow_insns(fpc, 4);
fp->insn[fpc->inst_offset + 0] = 0x00000001;
fp->insn[fpc->inst_offset + 1] = 0x00000000;
fp->insn[fpc->inst_offset + 2] = 0x00000000;
fp->insn[fpc->inst_offset + 3] = 0x00000000;
fp->translated = TRUE;
out_err:
tgsi_parse_free(&parse);
if (fpc->r_temp)
FREE(fpc->r_temp);
FREE(fpc);
}
static inline void
nvfx_fp_memcpy(void* dst, const void* src, size_t len)
{
#ifndef WORDS_BIGENDIAN
memcpy(dst, src, len);
#else
size_t i;
for(i = 0; i < len; i += 4) {
uint32_t v = (uint32_t*)((char*)src + i);
*(uint32_t*)((char*)dst + i) = (v >> 16) | (v << 16);
}
#endif
}
void
nvfx_fragprog_validate(struct nvfx_context *nvfx)
{
struct nouveau_channel* chan = nvfx->screen->base.channel;
struct nvfx_fragment_program *fp = nvfx->fragprog;
int update = 0;
int i;
if (!fp->translated)
{
nvfx_fragprog_translate(nvfx, fp);
if (!fp->translated) {
static unsigned dummy[8] = {1, 0, 0, 0, 1, 0, 0, 0};
static int warned = 0;
if(!warned)
{
fprintf(stderr, "nvfx: failed to translate fragment program!\n");
warned = 1;
}
/* use dummy program: we cannot fail here */
fp->translated = TRUE;
fp->insn = malloc(sizeof(dummy));
memcpy(fp->insn, dummy, sizeof(dummy));
fp->insn_len = sizeof(dummy) / sizeof(dummy[0]);
}
update = TRUE;
fp->prog_size = (fp->insn_len * 4 + 63) & ~63;
int min_size = 4096;
if(fp->prog_size >= min_size)
fp->progs_per_bo = 1;
else
fp->progs_per_bo = min_size / fp->prog_size;
fp->bo_prog_idx = fp->progs_per_bo - 1;
}
if (nvfx->dirty & NVFX_NEW_FRAGCONST)
update = TRUE;
if(update) {
++fp->bo_prog_idx;
if(fp->bo_prog_idx >= fp->progs_per_bo)
{
if(fp->fpbo && !nouveau_bo_busy(fp->fpbo->next->bo, NOUVEAU_BO_WR))
{
fp->fpbo = fp->fpbo->next;
}
else
{
struct nvfx_fragment_program_bo* fpbo = os_malloc_aligned(sizeof(struct nvfx_fragment_program) + fp->prog_size * fp->progs_per_bo, 16);
if(fp->fpbo)
{
fpbo->next = fp->fpbo->next;
fp->fpbo->next = fpbo;
}
else
fpbo->next = fpbo;
fp->fpbo = fpbo;
fpbo->bo = 0;
nouveau_bo_new(nvfx->screen->base.device, NOUVEAU_BO_VRAM | NOUVEAU_BO_MAP, 64, fp->prog_size * fp->progs_per_bo, &fpbo->bo);
nouveau_bo_map(fpbo->bo, NOUVEAU_BO_NOSYNC);
char* map = fpbo->bo->map;
char* buf = fpbo->insn;
for(int i = 0; i < fp->progs_per_bo; ++i)
{
memcpy(buf, fp->insn, fp->insn_len * 4);
nvfx_fp_memcpy(map, fp->insn, fp->insn_len * 4);
map += fp->prog_size;
buf += fp->prog_size;
}
}
fp->bo_prog_idx = 0;
}
int offset = fp->bo_prog_idx * fp->prog_size;
if(nvfx->constbuf[PIPE_SHADER_FRAGMENT]) {
struct pipe_resource* constbuf = nvfx->constbuf[PIPE_SHADER_FRAGMENT];
// TODO: avoid using transfers, just directly the buffer
struct pipe_transfer* transfer;
// TODO: does this check make any sense, or should we do this unconditionally?
uint32_t* map = pipe_buffer_map(&nvfx->pipe, constbuf, PIPE_TRANSFER_READ, &transfer);
uint32_t* fpmap = (uint32_t*)((char*)fp->fpbo->bo->map + offset);
uint32_t* buf = (uint32_t*)((char*)fp->fpbo->insn + offset);
for (i = 0; i < fp->nr_consts; ++i) {
unsigned off = fp->consts[i].offset;
unsigned idx = fp->consts[i].index * 4;
/* TODO: is checking a good idea? */
if(memcmp(&buf[off], &map[idx], 4 * sizeof(uint32_t))) {
memcpy(&buf[off], &map[idx], 4 * sizeof(uint32_t));
nvfx_fp_memcpy(&fpmap[off], &map[idx], 4 * sizeof(uint32_t));
}
}
pipe_buffer_unmap(&nvfx->pipe, constbuf, transfer);
}
}
if(update || (nvfx->dirty & NVFX_NEW_FRAGPROG)) {
int offset = fp->bo_prog_idx * fp->prog_size;
MARK_RING(chan, 8, 1);
OUT_RING(chan, RING_3D(NV34TCL_FP_ACTIVE_PROGRAM, 1));
OUT_RELOC(chan, fp->fpbo->bo, offset, NOUVEAU_BO_VRAM |
NOUVEAU_BO_GART | NOUVEAU_BO_RD | NOUVEAU_BO_LOW |
NOUVEAU_BO_OR, NV34TCL_FP_ACTIVE_PROGRAM_DMA0,
NV34TCL_FP_ACTIVE_PROGRAM_DMA1);
OUT_RING(chan, RING_3D(NV34TCL_FP_CONTROL, 1));
OUT_RING(chan, fp->fp_control);
if(!nvfx->is_nv4x) {
OUT_RING(chan, RING_3D(NV34TCL_FP_REG_CONTROL, 1));
OUT_RING(chan, (1<<16)|0x4);
OUT_RING(chan, RING_3D(NV34TCL_TX_UNITS_ENABLE, 1));
OUT_RING(chan, fp->samplers);
}
}
}
void
nvfx_fragprog_relocate(struct nvfx_context *nvfx)
{
struct nouveau_channel* chan = nvfx->screen->base.channel;
struct nvfx_fragment_program *fp = nvfx->fragprog;
struct nouveau_bo* bo = fp->fpbo->bo;
int offset = fp->bo_prog_idx * fp->prog_size;
unsigned fp_flags = NOUVEAU_BO_VRAM | NOUVEAU_BO_RD; // TODO: GART?
fp_flags |= NOUVEAU_BO_DUMMY;
MARK_RING(chan, 2, 2);
OUT_RELOC(chan, bo, RING_3D(NV34TCL_FP_ACTIVE_PROGRAM, 1), fp_flags, 0, 0);
OUT_RELOC(chan, bo, offset, fp_flags | NOUVEAU_BO_LOW |
NOUVEAU_BO_OR, NV34TCL_FP_ACTIVE_PROGRAM_DMA0,
NV34TCL_FP_ACTIVE_PROGRAM_DMA1);
}
void
nvfx_fragprog_destroy(struct nvfx_context *nvfx,
struct nvfx_fragment_program *fp)
{
struct nvfx_fragment_program_bo* fpbo = fp->fpbo;
if(fpbo)
{
do
{
struct nvfx_fragment_program_bo* next = fpbo->next;
nouveau_bo_unmap(fpbo->bo);
nouveau_bo_ref(0, &fpbo->bo);
free(fpbo);
fpbo = next;
}
while(fpbo != fp->fpbo);
}
if (fp->insn_len)
FREE(fp->insn);
}
|