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|
/*
* Copyright 2010 Christoph Bumiller
*
* 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
* THE AUTHORS 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.
*/
#include <unistd.h>
#define NOUVEAU_DEBUG 1
#include "pipe/p_shader_tokens.h"
#include "tgsi/tgsi_parse.h"
#include "tgsi/tgsi_util.h"
#include "tgsi/tgsi_dump.h"
#include "util/u_dynarray.h"
#include "nvc0_pc.h"
#include "nvc0_program.h"
/* Arbitrary internal limits. */
#define BLD_MAX_TEMPS 64
#define BLD_MAX_ADDRS 4
#define BLD_MAX_PREDS 4
#define BLD_MAX_IMMDS 128
#define BLD_MAX_OUTPS PIPE_MAX_SHADER_OUTPUTS
#define BLD_MAX_COND_NESTING 8
#define BLD_MAX_LOOP_NESTING 4
#define BLD_MAX_CALL_NESTING 2
/* This structure represents a TGSI register. */
struct bld_register {
struct nv_value *current;
/* collect all SSA values assigned to it */
struct util_dynarray vals;
/* 1 bit per loop level, indicates if used/defd, reset when loop ends */
uint16_t loop_use;
uint16_t loop_def;
};
static INLINE struct nv_value **
bld_register_access(struct bld_register *reg, unsigned i)
{
return util_dynarray_element(®->vals, struct nv_value *, i);
}
static INLINE void
bld_register_add_val(struct bld_register *reg, struct nv_value *val)
{
struct nv_basic_block *bb = val->insn->bb;
if (reg->vals.size &&
(util_dynarray_top(®->vals, struct nv_value *))->insn->bb == bb)
*(util_dynarray_top_ptr(®->vals, struct nv_value *)) = val;
else
util_dynarray_append(®->vals, struct nv_value *, val);
}
static INLINE boolean
bld_register_del_val(struct bld_register *reg, struct nv_value *val)
{
unsigned i;
for (i = reg->vals.size / sizeof(struct nv_value *); i > 0; --i)
if (*bld_register_access(reg, i - 1) == val)
break;
if (!i)
return FALSE;
if (i != reg->vals.size / sizeof(struct nv_value *))
*bld_register_access(reg, i - 1) = util_dynarray_pop(®->vals,
struct nv_value *);
else
reg->vals.size -= sizeof(struct nv_value *);
return TRUE;
}
struct bld_context {
struct nvc0_translation_info *ti;
struct nv_pc *pc;
struct nv_basic_block *b;
struct tgsi_parse_context parse[BLD_MAX_CALL_NESTING];
int call_lvl;
struct nv_basic_block *cond_bb[BLD_MAX_COND_NESTING];
struct nv_basic_block *join_bb[BLD_MAX_COND_NESTING];
struct nv_basic_block *else_bb[BLD_MAX_COND_NESTING];
int cond_lvl;
struct nv_basic_block *loop_bb[BLD_MAX_LOOP_NESTING];
struct nv_basic_block *brkt_bb[BLD_MAX_LOOP_NESTING];
int loop_lvl;
ubyte out_kind; /* CFG_EDGE_FORWARD, or FAKE in case of BREAK/CONT */
struct bld_register tvs[BLD_MAX_TEMPS][4]; /* TGSI_FILE_TEMPORARY */
struct bld_register avs[BLD_MAX_ADDRS][4]; /* TGSI_FILE_ADDRESS */
struct bld_register pvs[BLD_MAX_PREDS][4]; /* TGSI_FILE_PREDICATE */
struct bld_register ovs[BLD_MAX_OUTPS][4]; /* TGSI_FILE_OUTPUT, FP only */
uint32_t outputs_written[(PIPE_MAX_SHADER_OUTPUTS + 7) / 8];
int hpos_index;
struct nv_value *zero;
struct nv_value *frag_coord[4];
/* wipe on new BB */
struct nv_value *saved_sysvals[4];
struct nv_value *saved_addr[4][2];
struct nv_value *saved_inputs[PIPE_MAX_SHADER_INPUTS][4];
struct nv_value *saved_immd[BLD_MAX_IMMDS];
uint num_immds;
};
static INLINE ubyte
bld_register_file(struct bld_context *bld, struct bld_register *reg)
{
if (reg >= &bld->pvs[0][0] &&
reg < &bld->ovs[0][0])
return NV_FILE_PRED;
return NV_FILE_GPR;
}
static INLINE struct nv_value *
bld_fetch(struct bld_context *bld, struct bld_register *regs, int i, int c)
{
regs[i * 4 + c].loop_use |= 1 << bld->loop_lvl;
return regs[i * 4 + c].current;
}
static struct nv_value *
bld_loop_phi(struct bld_context *, struct bld_register *, struct nv_value *);
/* If a variable is defined in a loop without prior use, we don't need
* a phi in the loop header to account for backwards flow.
*
* However, if this variable is then also used outside the loop, we do
* need a phi after all. But we must not use this phi's def inside the
* loop, so we can eliminate the phi if it is unused later.
*/
static INLINE void
bld_store(struct bld_context *bld,
struct bld_register *regs, int i, int c, struct nv_value *val)
{
const uint16_t m = 1 << bld->loop_lvl;
struct bld_register *reg = ®s[i * 4 + c];
if (bld->loop_lvl && !(m & (reg->loop_def | reg->loop_use)))
bld_loop_phi(bld, reg, val);
reg->current = val;
bld_register_add_val(reg, reg->current);
reg->loop_def |= 1 << bld->loop_lvl;
}
#define FETCH_TEMP(i, c) bld_fetch(bld, &bld->tvs[0][0], i, c)
#define STORE_TEMP(i, c, v) bld_store(bld, &bld->tvs[0][0], i, c, (v))
#define FETCH_ADDR(i, c) bld_fetch(bld, &bld->avs[0][0], i, c)
#define STORE_ADDR(i, c, v) bld_store(bld, &bld->avs[0][0], i, c, (v))
#define FETCH_PRED(i, c) bld_fetch(bld, &bld->pvs[0][0], i, c)
#define STORE_PRED(i, c, v) bld_store(bld, &bld->pvs[0][0], i, c, (v))
#define STORE_OUTP(i, c, v) \
do { \
bld_store(bld, &bld->ovs[0][0], i, c, (v)); \
bld->outputs_written[(i) / 8] |= 1 << (((i) * 4 + (c)) % 32); \
} while (0)
static INLINE void
bld_clear_def_use(struct bld_register *regs, int n, int lvl)
{
int i;
const uint16_t mask = ~(1 << lvl);
for (i = 0; i < n * 4; ++i) {
regs[i].loop_def &= mask;
regs[i].loop_use &= mask;
}
}
static INLINE void
bld_warn_uninitialized(struct bld_context *bld, int kind,
struct bld_register *reg, struct nv_basic_block *b)
{
#ifdef NOUVEAU_DEBUG
long i = (reg - &bld->tvs[0][0]) / 4;
long c = (reg - &bld->tvs[0][0]) & 3;
if (c == 3)
c = -1;
debug_printf("WARNING: TEMP[%li].%c %s used uninitialized in BB:%i\n",
i, (int)('x' + c), kind ? "may be" : "is", b->id);
#endif
}
static INLINE struct nv_value *
bld_def(struct nv_instruction *i, int c, struct nv_value *value)
{
i->def[c] = value;
value->insn = i;
return value;
}
static INLINE struct nv_value *
find_by_bb(struct bld_register *reg, struct nv_basic_block *b)
{
int i;
if (reg->current && reg->current->insn->bb == b)
return reg->current;
for (i = 0; i < reg->vals.size / sizeof(struct nv_value *); ++i)
if ((*bld_register_access(reg, i))->insn->bb == b)
return *bld_register_access(reg, i);
return NULL;
}
/* Fetch value from register that was defined in the specified BB,
* or search for first definitions in all of its predecessors.
*/
static void
fetch_by_bb(struct bld_register *reg,
struct nv_value **vals, int *n,
struct nv_basic_block *b)
{
int i;
struct nv_value *val;
assert(*n < 16); /* MAX_COND_NESTING */
val = find_by_bb(reg, b);
if (val) {
for (i = 0; i < *n; ++i)
if (vals[i] == val)
return;
vals[(*n)++] = val;
return;
}
for (i = 0; i < b->num_in; ++i)
if (!IS_WALL_EDGE(b->in_kind[i]))
fetch_by_bb(reg, vals, n, b->in[i]);
}
static INLINE struct nv_value *
bld_load_imm_u32(struct bld_context *bld, uint32_t u);
static INLINE struct nv_value *
bld_undef(struct bld_context *bld, ubyte file)
{
struct nv_instruction *nvi = new_instruction(bld->pc, NV_OP_UNDEF);
return bld_def(nvi, 0, new_value(bld->pc, file, 4));
}
static struct nv_value *
bld_phi(struct bld_context *bld, struct nv_basic_block *b,
struct bld_register *reg)
{
struct nv_basic_block *in;
struct nv_value *vals[16] = { NULL };
struct nv_value *val;
struct nv_instruction *phi;
int i, j, n;
do {
i = n = 0;
fetch_by_bb(reg, vals, &n, b);
if (!n) {
bld_warn_uninitialized(bld, 0, reg, b);
return NULL;
}
if (n == 1) {
if (nvc0_bblock_dominated_by(b, vals[0]->insn->bb))
break;
bld_warn_uninitialized(bld, 1, reg, b);
/* back-tracking to insert missing value of other path */
in = b;
while (in->in[0]) {
if (in->num_in == 1) {
in = in->in[0];
} else {
if (!nvc0_bblock_reachable_by(in->in[0], vals[0]->insn->bb, b))
in = in->in[0];
else
if (!nvc0_bblock_reachable_by(in->in[1], vals[0]->insn->bb, b))
in = in->in[1];
else
in = in->in[0];
}
}
bld->pc->current_block = in;
/* should make this a no-op */
bld_register_add_val(reg, bld_undef(bld, vals[0]->reg.file));
continue;
}
for (i = 0; i < n; ++i) {
/* if value dominates b, continue to the redefinitions */
if (nvc0_bblock_dominated_by(b, vals[i]->insn->bb))
continue;
/* if value dominates any in-block, b should be the dom frontier */
for (j = 0; j < b->num_in; ++j)
if (nvc0_bblock_dominated_by(b->in[j], vals[i]->insn->bb))
break;
/* otherwise, find the dominance frontier and put the phi there */
if (j == b->num_in) {
in = nvc0_bblock_dom_frontier(vals[i]->insn->bb);
val = bld_phi(bld, in, reg);
bld_register_add_val(reg, val);
break;
}
}
} while(i < n);
bld->pc->current_block = b;
if (n == 1)
return vals[0];
phi = new_instruction(bld->pc, NV_OP_PHI);
bld_def(phi, 0, new_value(bld->pc, vals[0]->reg.file, vals[0]->reg.size));
for (i = 0; i < n; ++i)
nv_reference(bld->pc, phi, i, vals[i]);
return phi->def[0];
}
/* Insert a phi function in the loop header.
* For nested loops, we need to insert phi functions in all the outer
* loop headers if they don't have one yet.
*
* @def: redefinition from inside loop, or NULL if to be replaced later
*/
static struct nv_value *
bld_loop_phi(struct bld_context *bld, struct bld_register *reg,
struct nv_value *def)
{
struct nv_instruction *phi;
struct nv_basic_block *bb = bld->pc->current_block;
struct nv_value *val = NULL;
if (bld->ti->require_stores) /* XXX: actually only for INDEXABLE_TEMP */
return NULL;
if (bld->loop_lvl > 1) {
--bld->loop_lvl;
if (!((reg->loop_def | reg->loop_use) & (1 << bld->loop_lvl)))
val = bld_loop_phi(bld, reg, NULL);
++bld->loop_lvl;
}
if (!val)
val = bld_phi(bld, bld->pc->current_block, reg); /* old definition */
if (!val) {
bld->pc->current_block = bld->loop_bb[bld->loop_lvl - 1]->in[0];
val = bld_undef(bld, bld_register_file(bld, reg));
}
bld->pc->current_block = bld->loop_bb[bld->loop_lvl - 1];
phi = new_instruction(bld->pc, NV_OP_PHI);
bld_def(phi, 0, new_value_like(bld->pc, val));
if (!def)
def = phi->def[0];
bld_register_add_val(reg, phi->def[0]);
phi->target = (struct nv_basic_block *)reg; /* cheat */
nv_reference(bld->pc, phi, 0, val);
nv_reference(bld->pc, phi, 1, def);
bld->pc->current_block = bb;
return phi->def[0];
}
static INLINE struct nv_value *
bld_fetch_global(struct bld_context *bld, struct bld_register *reg)
{
const uint16_t m = 1 << bld->loop_lvl;
const uint16_t use = reg->loop_use;
reg->loop_use |= m;
/* If neither used nor def'd inside the loop, build a phi in foresight,
* so we don't have to replace stuff later on, which requires tracking.
*/
if (bld->loop_lvl && !((use | reg->loop_def) & m))
return bld_loop_phi(bld, reg, NULL);
return bld_phi(bld, bld->pc->current_block, reg);
}
static INLINE struct nv_value *
bld_imm_u32(struct bld_context *bld, uint32_t u)
{
int i;
unsigned n = bld->num_immds;
for (i = 0; i < n; ++i)
if (bld->saved_immd[i]->reg.imm.u32 == u)
return bld->saved_immd[i];
assert(n < BLD_MAX_IMMDS);
bld->num_immds++;
bld->saved_immd[n] = new_value(bld->pc, NV_FILE_IMM, 4);
bld->saved_immd[n]->reg.imm.u32 = u;
return bld->saved_immd[n];
}
static void
bld_replace_value(struct nv_pc *, struct nv_basic_block *, struct nv_value *,
struct nv_value *);
/* Replace the source of the phi in the loop header by the last assignment,
* or eliminate the phi function if there is no assignment inside the loop.
*
* Redundancy situation 1 - (used) but (not redefined) value:
* %3 = phi %0, %3 = %3 is used
* %3 = phi %0, %4 = is new definition
*
* Redundancy situation 2 - (not used) but (redefined) value:
* %3 = phi %0, %2 = %2 is used, %3 could be used outside, deleted by DCE
*/
static void
bld_loop_end(struct bld_context *bld, struct nv_basic_block *bb)
{
struct nv_basic_block *save = bld->pc->current_block;
struct nv_instruction *phi, *next;
struct nv_value *val;
struct bld_register *reg;
int i, s, n;
for (phi = bb->phi; phi && phi->opcode == NV_OP_PHI; phi = next) {
next = phi->next;
reg = (struct bld_register *)phi->target;
phi->target = NULL;
/* start with s == 1, src[0] is from outside the loop */
for (s = 1, n = 0; n < bb->num_in; ++n) {
if (bb->in_kind[n] != CFG_EDGE_BACK)
continue;
assert(s < 4);
bld->pc->current_block = bb->in[n];
val = bld_fetch_global(bld, reg);
for (i = 0; i < 4; ++i)
if (phi->src[i] && phi->src[i]->value == val)
break;
if (i == 4) {
/* skip values we do not want to replace */
for (; phi->src[s] && phi->src[s]->value != phi->def[0]; ++s);
nv_reference(bld->pc, phi, s++, val);
}
}
bld->pc->current_block = save;
if (phi->src[0]->value == phi->def[0] ||
phi->src[0]->value == phi->src[1]->value)
s = 1;
else
if (phi->src[1]->value == phi->def[0])
s = 0;
else
continue;
if (s >= 0) {
/* eliminate the phi */
bld_register_del_val(reg, phi->def[0]);
++bld->pc->pass_seq;
bld_replace_value(bld->pc, bb, phi->def[0], phi->src[s]->value);
nvc0_insn_delete(phi);
}
}
}
static INLINE struct nv_value *
bld_imm_f32(struct bld_context *bld, float f)
{
return bld_imm_u32(bld, fui(f));
}
static struct nv_value *
bld_insn_1(struct bld_context *bld, uint opcode, struct nv_value *src0)
{
struct nv_instruction *insn = new_instruction(bld->pc, opcode);
nv_reference(bld->pc, insn, 0, src0);
return bld_def(insn, 0, new_value(bld->pc, NV_FILE_GPR, src0->reg.size));
}
static struct nv_value *
bld_insn_2(struct bld_context *bld, uint opcode,
struct nv_value *src0, struct nv_value *src1)
{
struct nv_instruction *insn = new_instruction(bld->pc, opcode);
nv_reference(bld->pc, insn, 0, src0);
nv_reference(bld->pc, insn, 1, src1);
return bld_def(insn, 0, new_value(bld->pc, NV_FILE_GPR, src0->reg.size));
}
static struct nv_value *
bld_insn_3(struct bld_context *bld, uint opcode,
struct nv_value *src0, struct nv_value *src1,
struct nv_value *src2)
{
struct nv_instruction *insn = new_instruction(bld->pc, opcode);
nv_reference(bld->pc, insn, 0, src0);
nv_reference(bld->pc, insn, 1, src1);
nv_reference(bld->pc, insn, 2, src2);
return bld_def(insn, 0, new_value(bld->pc, NV_FILE_GPR, src0->reg.size));
}
static INLINE void
bld_src_predicate(struct bld_context *bld,
struct nv_instruction *nvi, int s, struct nv_value *val)
{
nvi->predicate = s;
nv_reference(bld->pc, nvi, s, val);
}
static INLINE void
bld_src_pointer(struct bld_context *bld,
struct nv_instruction *nvi, int s, struct nv_value *val)
{
nvi->indirect = s;
nv_reference(bld->pc, nvi, s, val);
}
static void
bld_lmem_store(struct bld_context *bld, struct nv_value *ptr, int ofst,
struct nv_value *val)
{
struct nv_instruction *insn = new_instruction(bld->pc, NV_OP_ST);
struct nv_value *loc;
loc = new_value(bld->pc, NV_FILE_MEM_L, nv_type_sizeof(NV_TYPE_U32));
loc->reg.address = ofst * 4;
nv_reference(bld->pc, insn, 0, loc);
nv_reference(bld->pc, insn, 1, val);
if (ptr)
bld_src_pointer(bld, insn, 2, ptr);
}
static struct nv_value *
bld_lmem_load(struct bld_context *bld, struct nv_value *ptr, int ofst)
{
struct nv_value *loc, *val;
loc = new_value(bld->pc, NV_FILE_MEM_L, nv_type_sizeof(NV_TYPE_U32));
loc->reg.address = ofst * 4;
val = bld_insn_1(bld, NV_OP_LD, loc);
if (ptr)
bld_src_pointer(bld, val->insn, 1, ptr);
return val;
}
static struct nv_value *
bld_pow(struct bld_context *bld, struct nv_value *x, struct nv_value *e)
{
struct nv_value *val;
val = bld_insn_1(bld, NV_OP_LG2, x);
val = bld_insn_2(bld, NV_OP_MUL_F32, e, val);
val = bld_insn_1(bld, NV_OP_PREEX2, val);
val = bld_insn_1(bld, NV_OP_EX2, val);
return val;
}
static INLINE struct nv_value *
bld_load_imm_f32(struct bld_context *bld, float f)
{
if (f == 0.0f)
return bld->zero;
return bld_insn_1(bld, NV_OP_MOV, bld_imm_f32(bld, f));
}
static INLINE struct nv_value *
bld_load_imm_u32(struct bld_context *bld, uint32_t u)
{
if (u == 0)
return bld->zero;
return bld_insn_1(bld, NV_OP_MOV, bld_imm_u32(bld, u));
}
static INLINE struct nv_value *
bld_setp(struct bld_context *bld, uint op, uint8_t cc,
struct nv_value *src0, struct nv_value *src1)
{
struct nv_value *val = bld_insn_2(bld, op, src0, src1);
val->reg.file = NV_FILE_PRED;
val->reg.size = 1;
val->insn->set_cond = cc & 0xf;
return val;
}
static INLINE struct nv_value *
bld_cvt(struct bld_context *bld, uint8_t dt, uint8_t st, struct nv_value *src)
{
struct nv_value *val = bld_insn_1(bld, NV_OP_CVT, src);
val->insn->ext.cvt.d = dt;
val->insn->ext.cvt.s = st;
return val;
}
static void
bld_kil(struct bld_context *bld, struct nv_value *src)
{
struct nv_instruction *nvi;
src = bld_setp(bld, NV_OP_SET_F32, NV_CC_LT, src, bld->zero);
nvi = new_instruction(bld->pc, NV_OP_KIL);
nvi->fixed = 1;
bld_src_predicate(bld, nvi, 0, src);
}
static void
bld_flow(struct bld_context *bld, uint opcode,
struct nv_value *pred, uint8_t cc, struct nv_basic_block *target,
boolean reconverge)
{
struct nv_instruction *nvi;
if (reconverge)
new_instruction(bld->pc, NV_OP_JOINAT)->fixed = 1;
nvi = new_instruction(bld->pc, opcode);
nvi->target = target;
nvi->terminator = 1;
if (pred) {
nvi->cc = cc;
bld_src_predicate(bld, nvi, 0, pred);
}
}
static ubyte
translate_setcc(unsigned opcode)
{
switch (opcode) {
case TGSI_OPCODE_SLT: return NV_CC_LT;
case TGSI_OPCODE_SGE: return NV_CC_GE;
case TGSI_OPCODE_SEQ: return NV_CC_EQ;
case TGSI_OPCODE_SGT: return NV_CC_GT;
case TGSI_OPCODE_SLE: return NV_CC_LE;
case TGSI_OPCODE_SNE: return NV_CC_NE | NV_CC_U;
case TGSI_OPCODE_STR: return NV_CC_TR;
case TGSI_OPCODE_SFL: return NV_CC_FL;
case TGSI_OPCODE_ISLT: return NV_CC_LT;
case TGSI_OPCODE_ISGE: return NV_CC_GE;
case TGSI_OPCODE_USEQ: return NV_CC_EQ;
case TGSI_OPCODE_USGE: return NV_CC_GE;
case TGSI_OPCODE_USLT: return NV_CC_LT;
case TGSI_OPCODE_USNE: return NV_CC_NE;
default:
assert(0);
return NV_CC_FL;
}
}
static uint
translate_opcode(uint opcode)
{
switch (opcode) {
case TGSI_OPCODE_ABS: return NV_OP_ABS_F32;
case TGSI_OPCODE_ADD: return NV_OP_ADD_F32;
case TGSI_OPCODE_SUB: return NV_OP_SUB_F32;
case TGSI_OPCODE_UADD: return NV_OP_ADD_B32;
case TGSI_OPCODE_AND: return NV_OP_AND;
case TGSI_OPCODE_EX2: return NV_OP_EX2;
case TGSI_OPCODE_CEIL: return NV_OP_CEIL;
case TGSI_OPCODE_FLR: return NV_OP_FLOOR;
case TGSI_OPCODE_TRUNC: return NV_OP_TRUNC;
case TGSI_OPCODE_COS: return NV_OP_COS;
case TGSI_OPCODE_SIN: return NV_OP_SIN;
case TGSI_OPCODE_DDX: return NV_OP_DFDX;
case TGSI_OPCODE_DDY: return NV_OP_DFDY;
case TGSI_OPCODE_F2I:
case TGSI_OPCODE_F2U:
case TGSI_OPCODE_I2F:
case TGSI_OPCODE_U2F: return NV_OP_CVT;
case TGSI_OPCODE_INEG: return NV_OP_NEG_S32;
case TGSI_OPCODE_LG2: return NV_OP_LG2;
case TGSI_OPCODE_ISHR: return NV_OP_SAR;
case TGSI_OPCODE_USHR: return NV_OP_SHR;
case TGSI_OPCODE_MAD: return NV_OP_MAD_F32;
case TGSI_OPCODE_MAX: return NV_OP_MAX_F32;
case TGSI_OPCODE_IMAX: return NV_OP_MAX_S32;
case TGSI_OPCODE_UMAX: return NV_OP_MAX_U32;
case TGSI_OPCODE_MIN: return NV_OP_MIN_F32;
case TGSI_OPCODE_IMIN: return NV_OP_MIN_S32;
case TGSI_OPCODE_UMIN: return NV_OP_MIN_U32;
case TGSI_OPCODE_MUL: return NV_OP_MUL_F32;
case TGSI_OPCODE_UMUL: return NV_OP_MUL_B32;
case TGSI_OPCODE_OR: return NV_OP_OR;
case TGSI_OPCODE_RCP: return NV_OP_RCP;
case TGSI_OPCODE_RSQ: return NV_OP_RSQ;
case TGSI_OPCODE_SAD: return NV_OP_SAD;
case TGSI_OPCODE_SHL: return NV_OP_SHL;
case TGSI_OPCODE_SLT:
case TGSI_OPCODE_SGE:
case TGSI_OPCODE_SEQ:
case TGSI_OPCODE_SGT:
case TGSI_OPCODE_SLE:
case TGSI_OPCODE_SNE: return NV_OP_FSET_F32;
case TGSI_OPCODE_ISLT:
case TGSI_OPCODE_ISGE: return NV_OP_SET_S32;
case TGSI_OPCODE_USEQ:
case TGSI_OPCODE_USGE:
case TGSI_OPCODE_USLT:
case TGSI_OPCODE_USNE: return NV_OP_SET_U32;
case TGSI_OPCODE_TEX: return NV_OP_TEX;
case TGSI_OPCODE_TXP: return NV_OP_TEX;
case TGSI_OPCODE_TXB: return NV_OP_TXB;
case TGSI_OPCODE_TXL: return NV_OP_TXL;
case TGSI_OPCODE_XOR: return NV_OP_XOR;
default:
return NV_OP_NOP;
}
}
#if 0
static ubyte
infer_src_type(unsigned opcode)
{
switch (opcode) {
case TGSI_OPCODE_MOV:
case TGSI_OPCODE_AND:
case TGSI_OPCODE_OR:
case TGSI_OPCODE_XOR:
case TGSI_OPCODE_SAD:
case TGSI_OPCODE_U2F:
case TGSI_OPCODE_UADD:
case TGSI_OPCODE_UDIV:
case TGSI_OPCODE_UMOD:
case TGSI_OPCODE_UMAD:
case TGSI_OPCODE_UMUL:
case TGSI_OPCODE_UMAX:
case TGSI_OPCODE_UMIN:
case TGSI_OPCODE_USEQ:
case TGSI_OPCODE_USGE:
case TGSI_OPCODE_USLT:
case TGSI_OPCODE_USNE:
case TGSI_OPCODE_USHR:
return NV_TYPE_U32;
case TGSI_OPCODE_I2F:
case TGSI_OPCODE_IDIV:
case TGSI_OPCODE_IMAX:
case TGSI_OPCODE_IMIN:
case TGSI_OPCODE_INEG:
case TGSI_OPCODE_ISGE:
case TGSI_OPCODE_ISHR:
case TGSI_OPCODE_ISLT:
return NV_TYPE_S32;
default:
return NV_TYPE_F32;
}
}
static ubyte
infer_dst_type(unsigned opcode)
{
switch (opcode) {
case TGSI_OPCODE_MOV:
case TGSI_OPCODE_F2U:
case TGSI_OPCODE_AND:
case TGSI_OPCODE_OR:
case TGSI_OPCODE_XOR:
case TGSI_OPCODE_SAD:
case TGSI_OPCODE_UADD:
case TGSI_OPCODE_UDIV:
case TGSI_OPCODE_UMOD:
case TGSI_OPCODE_UMAD:
case TGSI_OPCODE_UMUL:
case TGSI_OPCODE_UMAX:
case TGSI_OPCODE_UMIN:
case TGSI_OPCODE_USEQ:
case TGSI_OPCODE_USGE:
case TGSI_OPCODE_USLT:
case TGSI_OPCODE_USNE:
case TGSI_OPCODE_USHR:
return NV_TYPE_U32;
case TGSI_OPCODE_F2I:
case TGSI_OPCODE_IDIV:
case TGSI_OPCODE_IMAX:
case TGSI_OPCODE_IMIN:
case TGSI_OPCODE_INEG:
case TGSI_OPCODE_ISGE:
case TGSI_OPCODE_ISHR:
case TGSI_OPCODE_ISLT:
return NV_TYPE_S32;
default:
return NV_TYPE_F32;
}
}
#endif
static void
emit_store(struct bld_context *bld, const struct tgsi_full_instruction *inst,
unsigned chan, struct nv_value *res)
{
const struct tgsi_full_dst_register *reg = &inst->Dst[0];
struct nv_instruction *nvi;
struct nv_value *mem;
struct nv_value *ptr = NULL;
int idx;
idx = reg->Register.Index;
assert(chan < 4);
if (reg->Register.Indirect)
ptr = FETCH_ADDR(reg->Indirect.Index,
tgsi_util_get_src_register_swizzle(®->Indirect, 0));
switch (inst->Instruction.Saturate) {
case TGSI_SAT_NONE:
break;
case TGSI_SAT_ZERO_ONE:
res = bld_insn_1(bld, NV_OP_SAT, res);
break;
case TGSI_SAT_MINUS_PLUS_ONE:
res = bld_insn_2(bld, NV_OP_MAX_F32, res, bld_load_imm_f32(bld, -1.0f));
res = bld_insn_2(bld, NV_OP_MIN_F32, res, bld_load_imm_f32(bld, 1.0f));
break;
}
switch (reg->Register.File) {
case TGSI_FILE_OUTPUT:
if (!res->insn)
res = bld_insn_1(bld, NV_OP_MOV, res);
if (bld->pc->is_fragprog) {
assert(!ptr);
STORE_OUTP(idx, chan, res);
} else {
nvi = new_instruction(bld->pc, NV_OP_EXPORT);
mem = new_value(bld->pc, bld->ti->output_file, res->reg.size);
nv_reference(bld->pc, nvi, 0, mem);
nv_reference(bld->pc, nvi, 1, res);
if (!ptr)
mem->reg.address = bld->ti->output_loc[idx][chan];
else
mem->reg.address = 0x80 + idx * 16 + chan * 4;
nvi->fixed = 1;
}
break;
case TGSI_FILE_TEMPORARY:
assert(idx < BLD_MAX_TEMPS);
if (!res->insn || res->insn->bb != bld->pc->current_block)
res = bld_insn_1(bld, NV_OP_MOV, res);
assert(res->reg.file == NV_FILE_GPR);
if (bld->ti->require_stores)
bld_lmem_store(bld, ptr, idx * 4 + chan, res);
else
STORE_TEMP(idx, chan, res);
break;
case TGSI_FILE_ADDRESS:
assert(idx < BLD_MAX_ADDRS);
STORE_ADDR(idx, chan, res);
break;
}
}
static INLINE uint32_t
bld_is_output_written(struct bld_context *bld, int i, int c)
{
if (c < 0)
return bld->outputs_written[i / 8] & (0xf << ((i * 4) % 32));
return bld->outputs_written[i / 8] & (1 << ((i * 4 + c) % 32));
}
static void
bld_append_vp_ucp(struct bld_context *bld)
{
struct nv_value *res[6];
struct nv_value *ucp, *vtx, *out;
struct nv_instruction *insn;
int i, c;
assert(bld->ti->prog->vp.num_ucps <= 6);
for (c = 0; c < 4; ++c) {
vtx = bld_fetch_global(bld, &bld->ovs[bld->hpos_index][c]);
for (i = 0; i < bld->ti->prog->vp.num_ucps; ++i) {
ucp = new_value(bld->pc, NV_FILE_MEM_C(15), 4);
ucp->reg.address = i * 16 + c * 4;
if (c == 0)
res[i] = bld_insn_2(bld, NV_OP_MUL_F32, vtx, ucp);
else
res[i] = bld_insn_3(bld, NV_OP_MAD_F32, vtx, ucp, res[i]);
}
}
for (i = 0; i < bld->ti->prog->vp.num_ucps; ++i) {
(out = new_value(bld->pc, NV_FILE_MEM_V, 4))->reg.address = 0x2c0 + i * 4;
(insn = new_instruction(bld->pc, NV_OP_EXPORT))->fixed = 1;
nv_reference(bld->pc, insn, 0, out);
nv_reference(bld->pc, insn, 1, res[i]);
}
}
static void
bld_export_fp_outputs(struct bld_context *bld)
{
struct nv_value *vals[4];
struct nv_instruction *nvi;
int i, c, n;
for (i = 0; i < PIPE_MAX_SHADER_OUTPUTS; ++i) {
if (!bld_is_output_written(bld, i, -1))
continue;
for (n = 0, c = 0; c < 4; ++c) {
if (!bld_is_output_written(bld, i, c))
continue;
vals[n] = bld_fetch_global(bld, &bld->ovs[i][c]);
assert(vals[n]);
vals[n] = bld_insn_1(bld, NV_OP_MOV, vals[n]);
vals[n++]->reg.id = bld->ti->output_loc[i][c];
}
assert(n);
(nvi = new_instruction(bld->pc, NV_OP_EXPORT))->fixed = 1;
for (c = 0; c < n; ++c)
nv_reference(bld->pc, nvi, c, vals[c]);
}
}
static void
bld_new_block(struct bld_context *bld, struct nv_basic_block *b)
{
int i, c;
bld->pc->current_block = b;
for (i = 0; i < 4; ++i)
bld->saved_addr[i][0] = NULL;
for (i = 0; i < PIPE_MAX_SHADER_INPUTS; ++i)
for (c = 0; c < 4; ++c)
bld->saved_inputs[i][c] = NULL;
bld->out_kind = CFG_EDGE_FORWARD;
}
static struct nv_value *
bld_interp(struct bld_context *bld, unsigned mode, struct nv_value *val)
{
unsigned cent = mode & NVC0_INTERP_CENTROID;
mode &= ~NVC0_INTERP_CENTROID;
if (val->reg.address == 0x3fc) {
/* gl_FrontFacing: 0/~0 to -1.0/+1.0 */
val = bld_insn_1(bld, NV_OP_LINTERP, val);
val->insn->flat = 1;
val = bld_insn_2(bld, NV_OP_SHL, val, bld_imm_u32(bld, 31));
val = bld_insn_2(bld, NV_OP_XOR, val, bld_imm_f32(bld, -1.0f));
return val;
} else
if (mode == NVC0_INTERP_PERSPECTIVE) {
val = bld_insn_2(bld, NV_OP_PINTERP, val, bld->frag_coord[3]);
} else {
val = bld_insn_1(bld, NV_OP_LINTERP, val);
}
val->insn->flat = mode == NVC0_INTERP_FLAT ? 1 : 0;
val->insn->centroid = cent ? 1 : 0;
return val;
}
static struct nv_value *
emit_fetch(struct bld_context *bld, const struct tgsi_full_instruction *insn,
const unsigned s, const unsigned chan)
{
const struct tgsi_full_src_register *src = &insn->Src[s];
struct nv_value *res = NULL;
struct nv_value *ptr = NULL;
int idx, ind_idx, dim_idx;
unsigned swz, ind_swz, sgn;
idx = src->Register.Index;
swz = tgsi_util_get_full_src_register_swizzle(src, chan);
if (src->Register.Indirect) {
ind_idx = src->Indirect.Index;
ind_swz = tgsi_util_get_src_register_swizzle(&src->Indirect, 0);
ptr = FETCH_ADDR(ind_idx, ind_swz);
}
if (src->Register.Dimension)
dim_idx = src->Dimension.Index;
else
dim_idx = 0;
switch (src->Register.File) {
case TGSI_FILE_CONSTANT:
assert(dim_idx < 14);
res = new_value(bld->pc, NV_FILE_MEM_C(dim_idx), 4);
res->reg.address = idx * 16 + swz * 4;
res = bld_insn_1(bld, NV_OP_LD, res);
if (ptr)
bld_src_pointer(bld, res->insn, 1, ptr);
break;
case TGSI_FILE_IMMEDIATE: /* XXX: type for MOV TEMP[0], -IMM[0] */
assert(idx < bld->ti->immd32_nr);
res = bld_load_imm_u32(bld, bld->ti->immd32[idx * 4 + swz]);
break;
case TGSI_FILE_INPUT:
assert(!src->Register.Dimension);
if (!ptr) {
res = bld->saved_inputs[idx][swz];
if (res)
break;
}
res = new_value(bld->pc, bld->ti->input_file, 4);
if (ptr)
res->reg.address = 0x80 + idx * 16 + swz * 4;
else
res->reg.address = bld->ti->input_loc[idx][swz];
if (bld->pc->is_fragprog)
res = bld_interp(bld, bld->ti->interp_mode[idx], res);
else
res = bld_insn_1(bld, NV_OP_VFETCH, res);
if (ptr)
bld_src_pointer(bld, res->insn, res->insn->src[1] ? 2 : 1, ptr);
else
bld->saved_inputs[idx][swz] = res;
break;
case TGSI_FILE_TEMPORARY:
if (bld->ti->require_stores)
res = bld_lmem_load(bld, ptr, idx * 4 + swz);
else
res = bld_fetch_global(bld, &bld->tvs[idx][swz]);
break;
case TGSI_FILE_ADDRESS:
res = bld_fetch_global(bld, &bld->avs[idx][swz]);
break;
case TGSI_FILE_PREDICATE:
res = bld_fetch_global(bld, &bld->pvs[idx][swz]);
break;
case TGSI_FILE_SYSTEM_VALUE:
assert(bld->ti->sysval_loc[idx] < 0xf00); /* >= would mean special reg */
res = new_value(bld->pc,
bld->pc->is_fragprog ? NV_FILE_MEM_V : NV_FILE_MEM_A, 4);
res->reg.address = bld->ti->sysval_loc[idx];
if (res->reg.file == NV_FILE_MEM_A)
res = bld_insn_1(bld, NV_OP_VFETCH, res);
else
res = bld_interp(bld, NVC0_INTERP_FLAT, res);
/* mesa doesn't do real integers yet :-(and in GL this should be S32) */
res = bld_cvt(bld, NV_TYPE_F32, NV_TYPE_U32, res);
break;
default:
NOUVEAU_ERR("illegal/unhandled src reg file: %d\n", src->Register.File);
abort();
break;
}
if (!res)
return bld_undef(bld, NV_FILE_GPR);
sgn = tgsi_util_get_full_src_register_sign_mode(src, chan);
switch (sgn) {
case TGSI_UTIL_SIGN_KEEP:
break;
case TGSI_UTIL_SIGN_CLEAR:
res = bld_insn_1(bld, NV_OP_ABS_F32, res);
break;
case TGSI_UTIL_SIGN_TOGGLE:
res = bld_insn_1(bld, NV_OP_NEG_F32, res);
break;
case TGSI_UTIL_SIGN_SET:
res = bld_insn_1(bld, NV_OP_ABS_F32, res);
res = bld_insn_1(bld, NV_OP_NEG_F32, res);
break;
default:
NOUVEAU_ERR("illegal/unhandled src reg sign mode\n");
abort();
break;
}
return res;
}
static void
bld_lit(struct bld_context *bld, struct nv_value *dst0[4],
const struct tgsi_full_instruction *insn)
{
struct nv_value *val0 = NULL;
unsigned mask = insn->Dst[0].Register.WriteMask;
if (mask & ((1 << 0) | (1 << 3)))
dst0[3] = dst0[0] = bld_load_imm_f32(bld, 1.0f);
if (mask & (3 << 1)) {
val0 = bld_insn_2(bld, NV_OP_MAX, emit_fetch(bld, insn, 0, 0), bld->zero);
if (mask & (1 << 1))
dst0[1] = val0;
}
if (mask & (1 << 2)) {
struct nv_value *val1, *val3, *src1, *src3, *pred;
struct nv_value *pos128 = bld_load_imm_f32(bld, 127.999999f);
struct nv_value *neg128 = bld_load_imm_f32(bld, -127.999999f);
src1 = emit_fetch(bld, insn, 0, 1);
src3 = emit_fetch(bld, insn, 0, 3);
pred = bld_setp(bld, NV_OP_SET_F32, NV_CC_LE, val0, bld->zero);
val1 = bld_insn_2(bld, NV_OP_MAX_F32, src1, bld->zero);
val3 = bld_insn_2(bld, NV_OP_MAX_F32, src3, neg128);
val3 = bld_insn_2(bld, NV_OP_MIN_F32, val3, pos128);
val3 = bld_pow(bld, val1, val3);
dst0[2] = bld_insn_1(bld, NV_OP_MOV, bld->zero);
bld_src_predicate(bld, dst0[2]->insn, 1, pred);
dst0[2] = bld_insn_2(bld, NV_OP_SELECT, val3, dst0[2]);
}
}
static INLINE void
describe_texture_target(unsigned target, int *dim,
int *array, int *cube, int *shadow)
{
*dim = *array = *cube = *shadow = 0;
switch (target) {
case TGSI_TEXTURE_1D:
*dim = 1;
break;
case TGSI_TEXTURE_SHADOW1D:
*dim = *shadow = 1;
break;
case TGSI_TEXTURE_UNKNOWN:
case TGSI_TEXTURE_2D:
case TGSI_TEXTURE_RECT:
*dim = 2;
break;
case TGSI_TEXTURE_SHADOW2D:
case TGSI_TEXTURE_SHADOWRECT:
*dim = 2;
*shadow = 1;
break;
case TGSI_TEXTURE_3D:
*dim = 3;
break;
case TGSI_TEXTURE_CUBE:
*dim = 2;
*cube = 1;
break;
case TGSI_TEXTURE_1D_ARRAY:
*dim = *array = 1;
break;
case TGSI_TEXTURE_2D_ARRAY:
*dim = 2;
*array = 1;
break;
/*
case TGSI_TEXTURE_SHADOW1D_ARRAY:
*dim = *array = *shadow = 1;
break;
case TGSI_TEXTURE_SHADOW2D_ARRAY:
*dim = 2;
*array = *shadow = 1;
break;
case TGSI_TEXTURE_CUBE_ARRAY:
*dim = 2;
*cube = *array = 1;
break;
*/
default:
assert(0);
break;
}
}
static struct nv_value *
bld_clone(struct bld_context *bld, struct nv_instruction *nvi)
{
struct nv_instruction *dupi = new_instruction(bld->pc, nvi->opcode);
struct nv_instruction *next, *prev;
int c;
next = dupi->next;
prev = dupi->prev;
*dupi = *nvi;
dupi->next = next;
dupi->prev = prev;
for (c = 0; c < 5 && nvi->def[c]; ++c)
bld_def(dupi, c, new_value_like(bld->pc, nvi->def[c]));
for (c = 0; c < 6 && nvi->src[c]; ++c) {
dupi->src[c] = NULL;
nv_reference(bld->pc, dupi, c, nvi->src[c]->value);
}
return dupi->def[0];
}
/* NOTE: proj(t0) = (t0 / w) / (tc3 / w) = tc0 / tc2 handled by optimizer */
static void
load_proj_tex_coords(struct bld_context *bld,
struct nv_value *t[4], int dim, int shadow,
const struct tgsi_full_instruction *insn)
{
int c;
unsigned mask = (1 << dim) - 1;
if (shadow)
mask |= 4; /* depth comparison value */
t[3] = emit_fetch(bld, insn, 0, 3);
if (t[3]->insn->opcode == NV_OP_PINTERP) {
t[3] = bld_clone(bld, t[3]->insn);
t[3]->insn->opcode = NV_OP_LINTERP;
nv_reference(bld->pc, t[3]->insn, 1, NULL);
}
t[3] = bld_insn_1(bld, NV_OP_RCP, t[3]);
for (c = 0; c < 4; ++c) {
if (!(mask & (1 << c)))
continue;
t[c] = emit_fetch(bld, insn, 0, c);
if (t[c]->insn->opcode != NV_OP_PINTERP)
continue;
mask &= ~(1 << c);
t[c] = bld_clone(bld, t[c]->insn);
nv_reference(bld->pc, t[c]->insn, 1, t[3]);
}
if (mask == 0)
return;
t[3] = emit_fetch(bld, insn, 0, 3);
t[3] = bld_insn_1(bld, NV_OP_RCP, t[3]);
for (c = 0; c < 4; ++c)
if (mask & (1 << c))
t[c] = bld_insn_2(bld, NV_OP_MUL_F32, t[c], t[3]);
}
/* For a quad of threads / top left, top right, bottom left, bottom right
* pixels, do a different operation, and take src0 from a specific thread.
*/
#define QOP_ADD 0
#define QOP_SUBR 1
#define QOP_SUB 2
#define QOP_MOV1 3
#define QOP(a, b, c, d) \
((QOP_##a << 0) | (QOP_##b << 2) | (QOP_##c << 4) | (QOP_##d << 6))
static INLINE struct nv_value *
bld_quadop(struct bld_context *bld, ubyte qop, struct nv_value *src0, int lane,
struct nv_value *src1, boolean wp)
{
struct nv_value *val = bld_insn_2(bld, NV_OP_QUADOP, src0, src1);
val->insn->lanes = lane;
val->insn->quadop = qop;
if (wp) {
assert(!"quadop predicate write");
}
return val;
}
/* order of TGSI operands: x y z layer shadow lod/bias */
/* order of native operands: layer x y z | lod/bias shadow */
static struct nv_instruction *
emit_tex(struct bld_context *bld, uint opcode, int tic, int tsc,
struct nv_value *dst[4], struct nv_value *arg[4],
int dim, int array, int cube, int shadow)
{
struct nv_value *src[4];
struct nv_instruction *nvi, *bnd;
int c;
int s = 0;
boolean lodbias = opcode == NV_OP_TXB || opcode == NV_OP_TXL;
if (array)
arg[dim] = bld_cvt(bld, NV_TYPE_U32, NV_TYPE_F32, arg[dim]);
/* bind { layer x y z } and { lod/bias shadow } to adjacent regs */
bnd = new_instruction(bld->pc, NV_OP_BIND);
if (array) {
src[s] = new_value(bld->pc, NV_FILE_GPR, 4);
bld_def(bnd, s, src[s]);
nv_reference(bld->pc, bnd, s++, arg[dim + cube]);
}
for (c = 0; c < dim + cube; ++c, ++s) {
src[s] = bld_def(bnd, s, new_value(bld->pc, NV_FILE_GPR, 4));
nv_reference(bld->pc, bnd, s, arg[c]);
}
if (shadow || lodbias) {
bnd = new_instruction(bld->pc, NV_OP_BIND);
if (lodbias) {
src[s] = new_value(bld->pc, NV_FILE_GPR, 4);
bld_def(bnd, 0, src[s++]);
nv_reference(bld->pc, bnd, 0, arg[dim + cube + array + shadow]);
}
if (shadow) {
src[s] = new_value(bld->pc, NV_FILE_GPR, 4);
bld_def(bnd, lodbias, src[s++]);
nv_reference(bld->pc, bnd, lodbias, arg[dim + cube + array]);
}
}
nvi = new_instruction(bld->pc, opcode);
for (c = 0; c < 4; ++c)
dst[c] = bld_def(nvi, c, new_value(bld->pc, NV_FILE_GPR, 4));
for (c = 0; c < s; ++c)
nv_reference(bld->pc, nvi, c, src[c]);
nvi->ext.tex.t = tic;
nvi->ext.tex.s = tsc;
nvi->tex_mask = 0xf;
nvi->tex_cube = cube;
nvi->tex_dim = dim;
nvi->tex_cube = cube;
nvi->tex_shadow = shadow;
nvi->tex_array = array;
nvi->tex_live = 0;
return nvi;
}
static void
bld_tex(struct bld_context *bld, struct nv_value *dst0[4],
const struct tgsi_full_instruction *insn)
{
struct nv_value *t[4], *s[3];
uint opcode = translate_opcode(insn->Instruction.Opcode);
int c, dim, array, cube, shadow;
const int lodbias = opcode == NV_OP_TXB || opcode == NV_OP_TXL;
const int tic = insn->Src[1].Register.Index;
const int tsc = tic;
describe_texture_target(insn->Texture.Texture, &dim, &array, &cube, &shadow);
assert(dim + array + shadow + lodbias <= 5);
if (!cube && !array && insn->Instruction.Opcode == TGSI_OPCODE_TXP)
load_proj_tex_coords(bld, t, dim, shadow, insn);
else {
for (c = 0; c < dim + cube + array; ++c)
t[c] = emit_fetch(bld, insn, 0, c);
if (shadow)
t[c] = emit_fetch(bld, insn, 0, MAX2(c, 2));
}
if (cube) {
for (c = 0; c < 3; ++c)
s[c] = bld_insn_1(bld, NV_OP_ABS_F32, t[c]);
s[0] = bld_insn_2(bld, NV_OP_MAX_F32, s[0], s[1]);
s[0] = bld_insn_2(bld, NV_OP_MAX_F32, s[0], s[2]);
s[0] = bld_insn_1(bld, NV_OP_RCP, s[0]);
for (c = 0; c < 3; ++c)
t[c] = bld_insn_2(bld, NV_OP_MUL_F32, t[c], s[0]);
}
if (lodbias)
t[dim + cube + array + shadow] = emit_fetch(bld, insn, 0, 3);
emit_tex(bld, opcode, tic, tsc, dst0, t, dim, array, cube, shadow);
}
static INLINE struct nv_value *
bld_dot(struct bld_context *bld, const struct tgsi_full_instruction *insn,
int n)
{
struct nv_value *dotp, *src0, *src1;
int c;
src0 = emit_fetch(bld, insn, 0, 0);
src1 = emit_fetch(bld, insn, 1, 0);
dotp = bld_insn_2(bld, NV_OP_MUL_F32, src0, src1);
for (c = 1; c < n; ++c) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
dotp = bld_insn_3(bld, NV_OP_MAD_F32, src0, src1, dotp);
}
return dotp;
}
#define FOR_EACH_DST0_ENABLED_CHANNEL(chan, inst) \
for (chan = 0; chan < 4; ++chan) \
if ((inst)->Dst[0].Register.WriteMask & (1 << chan))
static void
bld_instruction(struct bld_context *bld,
const struct tgsi_full_instruction *insn)
{
struct nv_value *src0;
struct nv_value *src1;
struct nv_value *src2;
struct nv_value *dst0[4] = { NULL };
struct nv_value *temp;
int c;
uint opcode = translate_opcode(insn->Instruction.Opcode);
uint8_t mask = insn->Dst[0].Register.WriteMask;
#ifdef NOUVEAU_DEBUG
debug_printf("bld_instruction:"); tgsi_dump_instruction(insn, 1);
#endif
switch (insn->Instruction.Opcode) {
case TGSI_OPCODE_ADD:
case TGSI_OPCODE_MAX:
case TGSI_OPCODE_MIN:
case TGSI_OPCODE_MUL:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
dst0[c] = bld_insn_2(bld, opcode, src0, src1);
}
break;
case TGSI_OPCODE_ARL:
src1 = bld_imm_u32(bld, 4);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src0 = bld_insn_1(bld, NV_OP_FLOOR, src0);
src0->insn->ext.cvt.d = NV_TYPE_S32;
src0->insn->ext.cvt.s = NV_TYPE_F32;
dst0[c] = bld_insn_2(bld, NV_OP_SHL, src0, src1);
}
break;
case TGSI_OPCODE_CMP:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
src2 = emit_fetch(bld, insn, 2, c);
dst0[c] = bld_insn_3(bld, NV_OP_SLCT_F32, src1, src2, src0);
dst0[c]->insn->set_cond = NV_CC_LT;
}
break;
case TGSI_OPCODE_COS:
case TGSI_OPCODE_SIN:
src0 = emit_fetch(bld, insn, 0, 0);
temp = bld_insn_1(bld, NV_OP_PRESIN, src0);
if (insn->Dst[0].Register.WriteMask & 7)
temp = bld_insn_1(bld, opcode, temp);
for (c = 0; c < 3; ++c)
if (insn->Dst[0].Register.WriteMask & (1 << c))
dst0[c] = temp;
if (!(insn->Dst[0].Register.WriteMask & (1 << 3)))
break;
src0 = emit_fetch(bld, insn, 0, 3);
temp = bld_insn_1(bld, NV_OP_PRESIN, src0);
dst0[3] = bld_insn_1(bld, opcode, temp);
break;
case TGSI_OPCODE_DP2:
temp = bld_dot(bld, insn, 2);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_DP3:
temp = bld_dot(bld, insn, 3);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_DP4:
temp = bld_dot(bld, insn, 4);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_DPH:
src0 = bld_dot(bld, insn, 3);
src1 = emit_fetch(bld, insn, 1, 3);
temp = bld_insn_2(bld, NV_OP_ADD_F32, src0, src1);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_DST:
if (insn->Dst[0].Register.WriteMask & 1)
dst0[0] = bld_imm_f32(bld, 1.0f);
if (insn->Dst[0].Register.WriteMask & 2) {
src0 = emit_fetch(bld, insn, 0, 1);
src1 = emit_fetch(bld, insn, 1, 1);
dst0[1] = bld_insn_2(bld, NV_OP_MUL_F32, src0, src1);
}
if (insn->Dst[0].Register.WriteMask & 4)
dst0[2] = emit_fetch(bld, insn, 0, 2);
if (insn->Dst[0].Register.WriteMask & 8)
dst0[3] = emit_fetch(bld, insn, 1, 3);
break;
case TGSI_OPCODE_EXP:
src0 = emit_fetch(bld, insn, 0, 0);
temp = bld_insn_1(bld, NV_OP_FLOOR, src0);
if (insn->Dst[0].Register.WriteMask & 2)
dst0[1] = bld_insn_2(bld, NV_OP_SUB_F32, src0, temp);
if (insn->Dst[0].Register.WriteMask & 1) {
temp = bld_insn_1(bld, NV_OP_PREEX2, temp);
dst0[0] = bld_insn_1(bld, NV_OP_EX2, temp);
}
if (insn->Dst[0].Register.WriteMask & 4) {
temp = bld_insn_1(bld, NV_OP_PREEX2, src0);
dst0[2] = bld_insn_1(bld, NV_OP_EX2, temp);
}
if (insn->Dst[0].Register.WriteMask & 8)
dst0[3] = bld_imm_f32(bld, 1.0f);
break;
case TGSI_OPCODE_EX2:
src0 = emit_fetch(bld, insn, 0, 0);
temp = bld_insn_1(bld, NV_OP_PREEX2, src0);
temp = bld_insn_1(bld, NV_OP_EX2, temp);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_FRC:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
dst0[c] = bld_insn_1(bld, NV_OP_FLOOR, src0);
dst0[c] = bld_insn_2(bld, NV_OP_SUB_F32, src0, dst0[c]);
}
break;
case TGSI_OPCODE_KIL:
for (c = 0; c < 4; ++c)
bld_kil(bld, emit_fetch(bld, insn, 0, c));
break;
case TGSI_OPCODE_KILP:
(new_instruction(bld->pc, NV_OP_KIL))->fixed = 1;
break;
case TGSI_OPCODE_IF:
{
struct nv_basic_block *b = new_basic_block(bld->pc);
struct nv_value *pred = emit_fetch(bld, insn, 0, 0);
assert(bld->cond_lvl < BLD_MAX_COND_NESTING);
nvc0_bblock_attach(bld->pc->current_block, b, CFG_EDGE_FORWARD);
bld->join_bb[bld->cond_lvl] = bld->pc->current_block;
bld->cond_bb[bld->cond_lvl] = bld->pc->current_block;
if (pred->insn && NV_BASEOP(pred->insn->opcode) == NV_OP_SET) {
pred = bld_clone(bld, pred->insn);
pred->reg.size = 1;
pred->reg.file = NV_FILE_PRED;
if (pred->insn->opcode == NV_OP_FSET_F32)
pred->insn->opcode = NV_OP_SET_F32;
} else {
pred = bld_setp(bld, NV_OP_SET_U32, NV_CC_NE | NV_CC_U,
pred, bld->zero);
}
assert(!mask);
bld_flow(bld, NV_OP_BRA, pred, NV_CC_NOT_P, NULL, (bld->cond_lvl == 0));
++bld->cond_lvl;
bld_new_block(bld, b);
}
break;
case TGSI_OPCODE_ELSE:
{
struct nv_basic_block *b = new_basic_block(bld->pc);
--bld->cond_lvl;
nvc0_bblock_attach(bld->join_bb[bld->cond_lvl], b, CFG_EDGE_FORWARD);
bld->cond_bb[bld->cond_lvl]->exit->target = b;
bld->cond_bb[bld->cond_lvl] = bld->pc->current_block;
new_instruction(bld->pc, NV_OP_BRA)->terminator = 1;
++bld->cond_lvl;
bld_new_block(bld, b);
}
break;
case TGSI_OPCODE_ENDIF:
{
struct nv_basic_block *b = new_basic_block(bld->pc);
if (bld->pc->current_block->exit &&
!bld->pc->current_block->exit->terminator)
bld_flow(bld, NV_OP_BRA, NULL, NV_CC_P, b, FALSE);
--bld->cond_lvl;
nvc0_bblock_attach(bld->pc->current_block, b, bld->out_kind);
nvc0_bblock_attach(bld->cond_bb[bld->cond_lvl], b, CFG_EDGE_FORWARD);
bld->cond_bb[bld->cond_lvl]->exit->target = b;
bld_new_block(bld, b);
if (!bld->cond_lvl && bld->join_bb[bld->cond_lvl]) {
bld->join_bb[bld->cond_lvl]->exit->prev->target = b;
new_instruction(bld->pc, NV_OP_JOIN)->join = 1;
}
}
break;
case TGSI_OPCODE_BGNLOOP:
{
struct nv_basic_block *bl = new_basic_block(bld->pc);
struct nv_basic_block *bb = new_basic_block(bld->pc);
assert(bld->loop_lvl < BLD_MAX_LOOP_NESTING);
bld->loop_bb[bld->loop_lvl] = bl;
bld->brkt_bb[bld->loop_lvl] = bb;
nvc0_bblock_attach(bld->pc->current_block, bl, CFG_EDGE_LOOP_ENTER);
bld_new_block(bld, bld->loop_bb[bld->loop_lvl++]);
if (bld->loop_lvl == bld->pc->loop_nesting_bound)
bld->pc->loop_nesting_bound++;
bld_clear_def_use(&bld->tvs[0][0], BLD_MAX_TEMPS, bld->loop_lvl);
bld_clear_def_use(&bld->avs[0][0], BLD_MAX_ADDRS, bld->loop_lvl);
bld_clear_def_use(&bld->pvs[0][0], BLD_MAX_PREDS, bld->loop_lvl);
}
break;
case TGSI_OPCODE_BRK:
{
struct nv_basic_block *bb = bld->brkt_bb[bld->loop_lvl - 1];
bld_flow(bld, NV_OP_BRA, NULL, NV_CC_P, bb, FALSE);
if (bld->out_kind == CFG_EDGE_FORWARD) /* else we already had BRK/CONT */
nvc0_bblock_attach(bld->pc->current_block, bb, CFG_EDGE_LOOP_LEAVE);
bld->out_kind = CFG_EDGE_FAKE;
}
break;
case TGSI_OPCODE_CONT:
{
struct nv_basic_block *bb = bld->loop_bb[bld->loop_lvl - 1];
bld_flow(bld, NV_OP_BRA, NULL, NV_CC_P, bb, FALSE);
nvc0_bblock_attach(bld->pc->current_block, bb, CFG_EDGE_BACK);
if ((bb = bld->join_bb[bld->cond_lvl - 1])) {
bld->join_bb[bld->cond_lvl - 1] = NULL;
nvc0_insn_delete(bb->exit->prev);
}
bld->out_kind = CFG_EDGE_FAKE;
}
break;
case TGSI_OPCODE_ENDLOOP:
{
struct nv_basic_block *bb = bld->loop_bb[bld->loop_lvl - 1];
if (bld->out_kind != CFG_EDGE_FAKE) { /* else we already had BRK/CONT */
bld_flow(bld, NV_OP_BRA, NULL, NV_CC_P, bb, FALSE);
nvc0_bblock_attach(bld->pc->current_block, bb, CFG_EDGE_BACK);
}
bld_loop_end(bld, bb); /* replace loop-side operand of the phis */
bld_new_block(bld, bld->brkt_bb[--bld->loop_lvl]);
}
break;
case TGSI_OPCODE_ABS:
case TGSI_OPCODE_CEIL:
case TGSI_OPCODE_FLR:
case TGSI_OPCODE_TRUNC:
case TGSI_OPCODE_DDX:
case TGSI_OPCODE_DDY:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
dst0[c] = bld_insn_1(bld, opcode, src0);
}
break;
case TGSI_OPCODE_LIT:
bld_lit(bld, dst0, insn);
break;
case TGSI_OPCODE_LRP:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
src2 = emit_fetch(bld, insn, 2, c);
dst0[c] = bld_insn_2(bld, NV_OP_SUB_F32, src1, src2);
dst0[c] = bld_insn_3(bld, NV_OP_MAD_F32, dst0[c], src0, src2);
}
break;
case TGSI_OPCODE_MOV:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = emit_fetch(bld, insn, 0, c);
break;
case TGSI_OPCODE_MAD:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
src2 = emit_fetch(bld, insn, 2, c);
dst0[c] = bld_insn_3(bld, opcode, src0, src1, src2);
}
break;
case TGSI_OPCODE_POW:
src0 = emit_fetch(bld, insn, 0, 0);
src1 = emit_fetch(bld, insn, 1, 0);
temp = bld_pow(bld, src0, src1);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_LOG:
src0 = emit_fetch(bld, insn, 0, 0);
src0 = bld_insn_1(bld, NV_OP_ABS_F32, src0);
temp = bld_insn_1(bld, NV_OP_LG2, src0);
dst0[2] = temp;
if (insn->Dst[0].Register.WriteMask & 3) {
temp = bld_insn_1(bld, NV_OP_FLOOR, temp);
dst0[0] = temp;
}
if (insn->Dst[0].Register.WriteMask & 2) {
temp = bld_insn_1(bld, NV_OP_PREEX2, temp);
temp = bld_insn_1(bld, NV_OP_EX2, temp);
temp = bld_insn_1(bld, NV_OP_RCP, temp);
dst0[1] = bld_insn_2(bld, NV_OP_MUL_F32, src0, temp);
}
if (insn->Dst[0].Register.WriteMask & 8)
dst0[3] = bld_imm_f32(bld, 1.0f);
break;
case TGSI_OPCODE_RCP:
case TGSI_OPCODE_LG2:
src0 = emit_fetch(bld, insn, 0, 0);
temp = bld_insn_1(bld, opcode, src0);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_RSQ:
src0 = emit_fetch(bld, insn, 0, 0);
temp = bld_insn_1(bld, NV_OP_ABS_F32, src0);
temp = bld_insn_1(bld, NV_OP_RSQ, temp);
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn)
dst0[c] = temp;
break;
case TGSI_OPCODE_SLT:
case TGSI_OPCODE_SGE:
case TGSI_OPCODE_SEQ:
case TGSI_OPCODE_SGT:
case TGSI_OPCODE_SLE:
case TGSI_OPCODE_SNE:
case TGSI_OPCODE_ISLT:
case TGSI_OPCODE_ISGE:
case TGSI_OPCODE_USEQ:
case TGSI_OPCODE_USGE:
case TGSI_OPCODE_USLT:
case TGSI_OPCODE_USNE:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
dst0[c] = bld_insn_2(bld, opcode, src0, src1);
dst0[c]->insn->set_cond = translate_setcc(insn->Instruction.Opcode);
}
break;
case TGSI_OPCODE_SCS:
if (insn->Dst[0].Register.WriteMask & 0x3) {
src0 = emit_fetch(bld, insn, 0, 0);
temp = bld_insn_1(bld, NV_OP_PRESIN, src0);
if (insn->Dst[0].Register.WriteMask & 0x1)
dst0[0] = bld_insn_1(bld, NV_OP_COS, temp);
if (insn->Dst[0].Register.WriteMask & 0x2)
dst0[1] = bld_insn_1(bld, NV_OP_SIN, temp);
}
if (insn->Dst[0].Register.WriteMask & 0x4)
dst0[2] = bld_imm_f32(bld, 0.0f);
if (insn->Dst[0].Register.WriteMask & 0x8)
dst0[3] = bld_imm_f32(bld, 1.0f);
break;
case TGSI_OPCODE_SSG:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) { /* XXX: set lt, set gt, sub */
src0 = emit_fetch(bld, insn, 0, c);
src1 = bld_insn_2(bld, NV_OP_FSET_F32, src0, bld->zero);
src2 = bld_insn_2(bld, NV_OP_FSET_F32, src0, bld->zero);
src1->insn->set_cond = NV_CC_GT;
src2->insn->set_cond = NV_CC_LT;
dst0[c] = bld_insn_2(bld, NV_OP_SUB_F32, src1, src2);
}
break;
case TGSI_OPCODE_SUB:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
src0 = emit_fetch(bld, insn, 0, c);
src1 = emit_fetch(bld, insn, 1, c);
dst0[c] = bld_insn_2(bld, NV_OP_SUB_F32, src0, src1);
}
break;
case TGSI_OPCODE_TEX:
case TGSI_OPCODE_TXB:
case TGSI_OPCODE_TXL:
case TGSI_OPCODE_TXP:
bld_tex(bld, dst0, insn);
break;
case TGSI_OPCODE_XPD:
FOR_EACH_DST0_ENABLED_CHANNEL(c, insn) {
if (c == 3) {
dst0[3] = bld_imm_f32(bld, 1.0f);
break;
}
src0 = emit_fetch(bld, insn, 1, (c + 1) % 3);
src1 = emit_fetch(bld, insn, 0, (c + 2) % 3);
dst0[c] = bld_insn_2(bld, NV_OP_MUL_F32, src0, src1);
src0 = emit_fetch(bld, insn, 0, (c + 1) % 3);
src1 = emit_fetch(bld, insn, 1, (c + 2) % 3);
dst0[c] = bld_insn_3(bld, NV_OP_MAD_F32, src0, src1, dst0[c]);
dst0[c]->insn->src[2]->mod ^= NV_MOD_NEG;
}
break;
case TGSI_OPCODE_RET:
(new_instruction(bld->pc, NV_OP_RET))->fixed = 1;
break;
case TGSI_OPCODE_END:
/* VP outputs are exported in-place as scalars, optimization later */
if (bld->pc->is_fragprog)
bld_export_fp_outputs(bld);
if (bld->ti->append_ucp)
bld_append_vp_ucp(bld);
return;
default:
NOUVEAU_ERR("unhandled opcode %u\n", insn->Instruction.Opcode);
abort();
return;
}
if (insn->Dst[0].Register.File == TGSI_FILE_OUTPUT &&
!bld->pc->is_fragprog) {
struct nv_instruction *mi = NULL;
uint size;
if (bld->ti->append_ucp) {
if (bld->ti->output_loc[insn->Dst[0].Register.Index][0] == 0x70) {
bld->hpos_index = insn->Dst[0].Register.Index;
for (c = 0; c < 4; ++c)
if (mask & (1 << c))
STORE_OUTP(insn->Dst[0].Register.Index, c, dst0[c]);
}
}
for (c = 0; c < 4; ++c)
if (mask & (1 << c))
if ((dst0[c]->reg.file == NV_FILE_IMM) ||
(dst0[c]->reg.file == NV_FILE_GPR && dst0[c]->reg.id == 63))
dst0[c] = bld_insn_1(bld, NV_OP_MOV, dst0[c]);
c = 0;
if ((mask & 0x3) == 0x3) {
mask &= ~0x3;
size = 8;
mi = bld_insn_2(bld, NV_OP_BIND, dst0[0], dst0[1])->insn;
}
if ((mask & 0xc) == 0xc) {
mask &= ~0xc;
if (mi) {
size = 16;
nv_reference(bld->pc, mi, 2, dst0[2]);
nv_reference(bld->pc, mi, 3, dst0[3]);
} else {
c = 2;
size = 8;
mi = bld_insn_2(bld, NV_OP_BIND, dst0[2], dst0[3])->insn;
}
} else
if (mi && (mask & 0x4)) {
size = 12;
mask &= ~0x4;
nv_reference(bld->pc, mi, 2, dst0[2]);
}
if (mi) {
struct nv_instruction *ex = new_instruction(bld->pc, NV_OP_EXPORT);
int s;
nv_reference(bld->pc, ex, 0, new_value(bld->pc, NV_FILE_MEM_V, 4));
nv_reference(bld->pc, ex, 1, mi->def[0]);
for (s = 1; s < size / 4; ++s) {
bld_def(mi, s, new_value(bld->pc, NV_FILE_GPR, 4));
nv_reference(bld->pc, ex, s + 1, mi->def[s]);
}
ex->fixed = 1;
ex->src[0]->value->reg.size = size;
ex->src[0]->value->reg.address =
bld->ti->output_loc[insn->Dst[0].Register.Index][c];
}
}
for (c = 0; c < 4; ++c)
if (mask & (1 << c))
emit_store(bld, insn, c, dst0[c]);
}
static INLINE void
bld_free_registers(struct bld_register *base, int n)
{
int i, c;
for (i = 0; i < n; ++i)
for (c = 0; c < 4; ++c)
util_dynarray_fini(&base[i * 4 + c].vals);
}
int
nvc0_tgsi_to_nc(struct nv_pc *pc, struct nvc0_translation_info *ti)
{
struct bld_context *bld = CALLOC_STRUCT(bld_context);
unsigned ip;
pc->root[0] = pc->current_block = new_basic_block(pc);
bld->pc = pc;
bld->ti = ti;
pc->loop_nesting_bound = 1;
bld->zero = new_value(pc, NV_FILE_GPR, 4);
bld->zero->reg.id = 63;
if (pc->is_fragprog) {
struct nv_value *mem = new_value(pc, NV_FILE_MEM_V, 4);
mem->reg.address = 0x7c;
bld->frag_coord[3] = bld_insn_1(bld, NV_OP_LINTERP, mem);
bld->frag_coord[3] = bld_insn_1(bld, NV_OP_RCP, bld->frag_coord[3]);
}
for (ip = 0; ip < ti->num_insns; ++ip)
bld_instruction(bld, &ti->insns[ip]);
bld_free_registers(&bld->tvs[0][0], BLD_MAX_TEMPS);
bld_free_registers(&bld->avs[0][0], BLD_MAX_ADDRS);
bld_free_registers(&bld->pvs[0][0], BLD_MAX_PREDS);
bld_free_registers(&bld->ovs[0][0], PIPE_MAX_SHADER_OUTPUTS);
FREE(bld);
return 0;
}
/* If a variable is assigned in a loop, replace all references to the value
* from outside the loop with a phi value.
*/
static void
bld_replace_value(struct nv_pc *pc, struct nv_basic_block *b,
struct nv_value *old_val,
struct nv_value *new_val)
{
struct nv_instruction *nvi;
for (nvi = b->phi ? b->phi : b->entry; nvi; nvi = nvi->next) {
int s;
for (s = 0; s < 6 && nvi->src[s]; ++s)
if (nvi->src[s]->value == old_val)
nv_reference(pc, nvi, s, new_val);
}
b->pass_seq = pc->pass_seq;
if (b->out[0] && b->out[0]->pass_seq < pc->pass_seq)
bld_replace_value(pc, b->out[0], old_val, new_val);
if (b->out[1] && b->out[1]->pass_seq < pc->pass_seq)
bld_replace_value(pc, b->out[1], old_val, new_val);
}
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