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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.
*/
/* #define NV50PC_DEBUG */
#include "nv50_pc.h"
#include "nv50_program.h"
#include <stdio.h>
/* returns TRUE if operands 0 and 1 can be swapped */
boolean
nv_op_commutative(uint opcode)
{
switch (opcode) {
case NV_OP_ADD:
case NV_OP_MUL:
case NV_OP_MAD:
case NV_OP_AND:
case NV_OP_OR:
case NV_OP_XOR:
case NV_OP_MIN:
case NV_OP_MAX:
case NV_OP_SAD:
return TRUE;
default:
return FALSE;
}
}
/* return operand to which the address register applies */
int
nv50_indirect_opnd(struct nv_instruction *i)
{
if (!i->src[4])
return -1;
switch (i->opcode) {
case NV_OP_MOV:
case NV_OP_LDA:
case NV_OP_STA:
return 0;
default:
return 1;
}
}
boolean
nv50_nvi_can_use_imm(struct nv_instruction *nvi, int s)
{
if (nvi->flags_src || nvi->flags_def)
return FALSE;
switch (nvi->opcode) {
case NV_OP_ADD:
case NV_OP_MUL:
case NV_OP_AND:
case NV_OP_OR:
case NV_OP_XOR:
case NV_OP_SHL:
case NV_OP_SHR:
return (s == 1) && (nvi->src[0]->value->reg.file == NV_FILE_GPR) &&
(nvi->def[0]->reg.file == NV_FILE_GPR);
case NV_OP_MOV:
assert(s == 0);
return (nvi->def[0]->reg.file == NV_FILE_GPR);
default:
return FALSE;
}
}
boolean
nv50_nvi_can_load(struct nv_instruction *nvi, int s, struct nv_value *value)
{
int i;
for (i = 0; i < 3 && nvi->src[i]; ++i)
if (nvi->src[i]->value->reg.file == NV_FILE_IMM)
return FALSE;
switch (nvi->opcode) {
case NV_OP_ABS:
case NV_OP_ADD:
case NV_OP_CEIL:
case NV_OP_FLOOR:
case NV_OP_TRUNC:
case NV_OP_CVT:
case NV_OP_NEG:
case NV_OP_MAD:
case NV_OP_MUL:
case NV_OP_SAT:
case NV_OP_SUB:
case NV_OP_MAX:
case NV_OP_MIN:
if (s == 0 && (value->reg.file == NV_FILE_MEM_S ||
value->reg.file == NV_FILE_MEM_P))
return TRUE;
if (value->reg.file < NV_FILE_MEM_C(0) ||
value->reg.file > NV_FILE_MEM_C(15))
return FALSE;
return (s == 1) ||
((s == 2) && (nvi->src[1]->value->reg.file == NV_FILE_GPR));
case NV_OP_MOV:
assert(s == 0);
return /* TRUE */ FALSE; /* don't turn MOVs into loads */
default:
return FALSE;
}
}
/* Return whether this instruction can be executed conditionally. */
boolean
nv50_nvi_can_predicate(struct nv_instruction *nvi)
{
int i;
if (nvi->flags_src)
return FALSE;
for (i = 0; i < 4 && nvi->src[i]; ++i)
if (nvi->src[i]->value->reg.file == NV_FILE_IMM)
return FALSE;
return TRUE;
}
ubyte
nv50_supported_src_mods(uint opcode, int s)
{
switch (opcode) {
case NV_OP_ABS:
return NV_MOD_NEG | NV_MOD_ABS; /* obviously */
case NV_OP_ADD:
case NV_OP_MUL:
case NV_OP_MAD:
return NV_MOD_NEG;
case NV_OP_DFDX:
case NV_OP_DFDY:
assert(s == 0);
return NV_MOD_NEG;
case NV_OP_MAX:
case NV_OP_MIN:
return NV_MOD_ABS;
case NV_OP_CVT:
case NV_OP_LG2:
case NV_OP_NEG:
case NV_OP_PREEX2:
case NV_OP_PRESIN:
case NV_OP_RCP:
case NV_OP_RSQ:
return NV_MOD_ABS | NV_MOD_NEG;
default:
return 0;
}
}
/* We may want an opcode table. */
boolean
nv50_op_can_write_flags(uint opcode)
{
if (nv_is_vector_op(opcode))
return FALSE;
switch (opcode) { /* obvious ones like KIL, CALL, etc. not included */
case NV_OP_PHI:
case NV_OP_MOV:
case NV_OP_LINTERP:
case NV_OP_PINTERP:
case NV_OP_LDA:
return FALSE;
default:
break;
}
if (opcode >= NV_OP_RCP && opcode <= NV_OP_PREEX2)
return FALSE;
return TRUE;
}
int
nv_nvi_refcount(struct nv_instruction *nvi)
{
int i, rc;
rc = nvi->flags_def ? nvi->flags_def->refc : 0;
for (i = 0; i < 4; ++i) {
if (!nvi->def[i])
return rc;
rc += nvi->def[i]->refc;
}
return rc;
}
int
nvcg_replace_value(struct nv_pc *pc, struct nv_value *old_val,
struct nv_value *new_val)
{
int i, n;
if (old_val == new_val)
return old_val->refc;
for (i = 0, n = 0; i < pc->num_refs; ++i) {
if (pc->refs[i]->value == old_val) {
++n;
nv_reference(pc, &pc->refs[i], new_val);
}
}
return n;
}
struct nv_value *
nvcg_find_constant(struct nv_ref *ref)
{
struct nv_value *src;
if (!ref)
return NULL;
src = ref->value;
while (src->insn && src->insn->opcode == NV_OP_MOV) {
assert(!src->insn->src[0]->mod);
src = src->insn->src[0]->value;
}
if ((src->reg.file == NV_FILE_IMM) ||
(src->insn && src->insn->opcode == NV_OP_LDA &&
src->insn->src[0]->value->reg.file >= NV_FILE_MEM_C(0) &&
src->insn->src[0]->value->reg.file <= NV_FILE_MEM_C(15)))
return src;
return NULL;
}
struct nv_value *
nvcg_find_immediate(struct nv_ref *ref)
{
struct nv_value *src = nvcg_find_constant(ref);
return (src && src->reg.file == NV_FILE_IMM) ? src : NULL;
}
static void
nv_pc_free_refs(struct nv_pc *pc)
{
int i;
for (i = 0; i < pc->num_refs; i += 64)
FREE(pc->refs[i]);
FREE(pc->refs);
}
static const char *
edge_name(ubyte type)
{
switch (type) {
case CFG_EDGE_FORWARD: return "forward";
case CFG_EDGE_BACK: return "back";
case CFG_EDGE_LOOP_ENTER: return "loop";
case CFG_EDGE_LOOP_LEAVE: return "break";
case CFG_EDGE_FAKE: return "fake";
default:
return "?";
}
}
void
nv_pc_pass_in_order(struct nv_basic_block *root, nv_pc_pass_func f, void *priv)
{
struct nv_basic_block *bb[64], *bbb[16], *b;
int j, p, pp;
bb[0] = root;
p = 1;
pp = 0;
while (p > 0) {
b = bb[--p];
b->priv = 0;
for (j = 1; j >= 0; --j) {
if (!b->out[j])
continue;
switch (b->out_kind[j]) {
case CFG_EDGE_BACK:
continue;
case CFG_EDGE_FORWARD:
case CFG_EDGE_FAKE:
if (++b->out[j]->priv == b->out[j]->num_in)
bb[p++] = b->out[j];
break;
case CFG_EDGE_LOOP_ENTER:
bb[p++] = b->out[j];
break;
case CFG_EDGE_LOOP_LEAVE:
bbb[pp++] = b->out[j];
break;
default:
assert(0);
break;
}
}
f(priv, b);
if (!p) {
p = pp;
for (; pp > 0; --pp)
bb[pp - 1] = bbb[pp - 1];
}
}
}
static void
nv_do_print_function(void *priv, struct nv_basic_block *b)
{
struct nv_instruction *i = b->phi;
debug_printf("=== BB %i ", b->id);
if (b->out[0])
debug_printf("[%s -> %i] ", edge_name(b->out_kind[0]), b->out[0]->id);
if (b->out[1])
debug_printf("[%s -> %i] ", edge_name(b->out_kind[1]), b->out[1]->id);
debug_printf("===\n");
i = b->phi;
if (!i)
i = b->entry;
for (; i; i = i->next)
nv_print_instruction(i);
}
void
nv_print_function(struct nv_basic_block *root)
{
if (root->subroutine)
debug_printf("SUBROUTINE %i\n", root->subroutine);
else
debug_printf("MAIN\n");
nv_pc_pass_in_order(root, nv_do_print_function, root);
}
void
nv_print_program(struct nv_pc *pc)
{
int i;
for (i = 0; i < pc->num_subroutines + 1; ++i)
if (pc->root[i])
nv_print_function(pc->root[i]);
}
#ifdef NV50PC_DEBUG
static void
nv_do_print_cfgraph(struct nv_pc *pc, FILE *f, struct nv_basic_block *b)
{
int i;
b->pass_seq = pc->pass_seq;
fprintf(f, "\t%i [shape=box]\n", b->id);
for (i = 0; i < 2; ++i) {
if (!b->out[i])
continue;
switch (b->out_kind[i]) {
case CFG_EDGE_FORWARD:
fprintf(f, "\t%i -> %i;\n", b->id, b->out[i]->id);
break;
case CFG_EDGE_LOOP_ENTER:
fprintf(f, "\t%i -> %i [color=green];\n", b->id, b->out[i]->id);
break;
case CFG_EDGE_LOOP_LEAVE:
fprintf(f, "\t%i -> %i [color=red];\n", b->id, b->out[i]->id);
break;
case CFG_EDGE_BACK:
fprintf(f, "\t%i -> %i;\n", b->id, b->out[i]->id);
continue;
case CFG_EDGE_FAKE:
fprintf(f, "\t%i -> %i [style=dotted];\n", b->id, b->out[i]->id);
break;
default:
assert(0);
break;
}
if (b->out[i]->pass_seq < pc->pass_seq)
nv_do_print_cfgraph(pc, f, b->out[i]);
}
}
/* Print the control flow graph of subroutine @subr (0 == MAIN) to a file. */
static void
nv_print_cfgraph(struct nv_pc *pc, const char *filepath, int subr)
{
FILE *f;
f = fopen(filepath, "a");
if (!f)
return;
fprintf(f, "digraph G {\n");
++pc->pass_seq;
nv_do_print_cfgraph(pc, f, pc->root[subr]);
fprintf(f, "}\n");
fclose(f);
}
#endif
static INLINE void
nvcg_show_bincode(struct nv_pc *pc)
{
unsigned i;
for (i = 0; i < pc->bin_size / 4; ++i) {
debug_printf("0x%08x ", pc->emit[i]);
if ((i % 16) == 15)
debug_printf("\n");
}
debug_printf("\n");
}
static int
nv50_emit_program(struct nv_pc *pc)
{
uint32_t *code = pc->emit;
int n;
NV50_DBGMSG("emitting program: size = %u\n", pc->bin_size);
for (n = 0; n < pc->num_blocks; ++n) {
struct nv_instruction *i;
struct nv_basic_block *b = pc->bb_list[n];
for (i = b->entry; i; i = i->next) {
nv50_emit_instruction(pc, i);
pc->bin_pos += 1 + (pc->emit[0] & 1);
pc->emit += 1 + (pc->emit[0] & 1);
}
}
assert(pc->emit == &code[pc->bin_size / 4]);
/* XXX: we can do better than this ... */
if (!(pc->emit[-2] & 1) || (pc->emit[-2] & 2) || (pc->emit[-1] & 3)) {
pc->emit[0] = 0xf0000001;
pc->emit[1] = 0xe0000000;
pc->bin_size += 8;
}
pc->emit = code;
code[pc->bin_size / 4 - 1] |= 1;
#ifdef NV50PC_DEBUG
nvcg_show_bincode(pc);
#endif
return 0;
}
int
nv50_generate_code(struct nv50_translation_info *ti)
{
struct nv_pc *pc;
int ret;
int i;
pc = CALLOC_STRUCT(nv_pc);
if (!pc)
return 1;
pc->root = CALLOC(ti->subr_nr + 1, sizeof(pc->root[0]));
if (!pc->root) {
FREE(pc);
return 1;
}
pc->num_subroutines = ti->subr_nr;
ret = nv50_tgsi_to_nc(pc, ti);
if (ret)
goto out;
#ifdef NV50PC_DEBUG
nv_print_program(pc);
#endif
pc->opt_reload_elim = ti->store_to_memory ? FALSE : TRUE;
/* optimization */
ret = nv_pc_exec_pass0(pc);
if (ret)
goto out;
#ifdef NV50PC_DEBUG
nv_print_program(pc);
#endif
/* register allocation */
ret = nv_pc_exec_pass1(pc);
if (ret)
goto out;
#ifdef NV50PC_DEBUG
nv_print_program(pc);
nv_print_cfgraph(pc, "nv50_shader_cfgraph.dot", 0);
#endif
/* prepare for emission */
ret = nv_pc_exec_pass2(pc);
if (ret)
goto out;
pc->emit = CALLOC(pc->bin_size / 4 + 2, 4);
if (!pc->emit) {
ret = 3;
goto out;
}
ret = nv50_emit_program(pc);
if (ret)
goto out;
ti->p->code_size = pc->bin_size;
ti->p->code = pc->emit;
ti->p->immd_size = pc->immd_count * 4;
ti->p->immd = pc->immd_buf;
/* highest 16 bit reg to num of 32 bit regs */
ti->p->max_gpr = (pc->max_reg[NV_FILE_GPR] >> 1) + 1;
ti->p->fixups = pc->fixups;
ti->p->num_fixups = pc->num_fixups;
NV50_DBGMSG("SHADER TRANSLATION - %s\n", ret ? "failure" : "success");
out:
nv_pc_free_refs(pc);
for (i = 0; i < pc->num_blocks; ++i)
FREE(pc->bb_list[i]);
if (pc->root)
FREE(pc->root);
if (ret) { /* on success, these will be referenced by nv50_program */
if (pc->emit)
FREE(pc->emit);
if (pc->immd_buf)
FREE(pc->immd_buf);
if (pc->fixups)
FREE(pc->fixups);
}
FREE(pc);
return ret;
}
static void
nvbb_insert_phi(struct nv_basic_block *b, struct nv_instruction *i)
{
if (!b->phi) {
i->prev = NULL;
b->phi = i;
i->next = b->entry;
if (b->entry) {
assert(!b->entry->prev && b->exit);
b->entry->prev = i;
} else {
b->entry = i;
b->exit = i;
}
} else {
assert(b->entry);
if (b->entry->opcode == NV_OP_PHI) { /* insert after entry */
assert(b->entry == b->exit);
b->entry->next = i;
i->prev = b->entry;
b->entry = i;
b->exit = i;
} else { /* insert before entry */
assert(b->entry->prev && b->exit);
i->next = b->entry;
i->prev = b->entry->prev;
b->entry->prev = i;
i->prev->next = i;
}
}
}
void
nvbb_insert_tail(struct nv_basic_block *b, struct nv_instruction *i)
{
if (i->opcode == NV_OP_PHI) {
nvbb_insert_phi(b, i);
} else {
i->prev = b->exit;
if (b->exit)
b->exit->next = i;
b->exit = i;
if (!b->entry)
b->entry = i;
else
if (i->prev && i->prev->opcode == NV_OP_PHI)
b->entry = i;
}
i->bb = b;
b->num_instructions++;
}
void
nvi_insert_after(struct nv_instruction *at, struct nv_instruction *ni)
{
if (!at->next) {
nvbb_insert_tail(at->bb, ni);
return;
}
ni->next = at->next;
ni->prev = at;
ni->next->prev = ni;
ni->prev->next = ni;
}
void
nv_nvi_delete(struct nv_instruction *nvi)
{
struct nv_basic_block *b = nvi->bb;
int j;
/* debug_printf("REM: "); nv_print_instruction(nvi); */
for (j = 0; j < 5; ++j)
nv_reference(NULL, &nvi->src[j], NULL);
nv_reference(NULL, &nvi->flags_src, NULL);
if (nvi->next)
nvi->next->prev = nvi->prev;
else {
assert(nvi == b->exit);
b->exit = nvi->prev;
}
if (nvi->prev)
nvi->prev->next = nvi->next;
if (nvi == b->entry) {
/* PHIs don't get hooked to b->entry */
b->entry = nvi->next;
assert(!nvi->prev || nvi->prev->opcode == NV_OP_PHI);
}
if (nvi == b->phi) {
if (nvi->opcode != NV_OP_PHI)
NV50_DBGMSG("NOTE: b->phi points to non-PHI instruction\n");
assert(!nvi->prev);
if (!nvi->next || nvi->next->opcode != NV_OP_PHI)
b->phi = NULL;
else
b->phi = nvi->next;
}
}
void
nv_nvi_permute(struct nv_instruction *i1, struct nv_instruction *i2)
{
struct nv_basic_block *b = i1->bb;
assert(i1->opcode != NV_OP_PHI &&
i2->opcode != NV_OP_PHI);
assert(i1->next == i2);
if (b->exit == i2)
b->exit = i1;
if (b->entry == i1)
b->entry = i2;
i2->prev = i1->prev;
i1->next = i2->next;
i2->next = i1;
i1->prev = i2;
if (i2->prev)
i2->prev->next = i2;
if (i1->next)
i1->next->prev = i1;
}
void
nvbb_attach_block(struct nv_basic_block *parent,
struct nv_basic_block *b, ubyte edge_kind)
{
assert(b->num_in < 8);
if (parent->out[0]) {
assert(!parent->out[1]);
parent->out[1] = b;
parent->out_kind[1] = edge_kind;
} else {
parent->out[0] = b;
parent->out_kind[0] = edge_kind;
}
b->in[b->num_in] = parent;
b->in_kind[b->num_in++] = edge_kind;
}
/* NOTE: all BRKs are treated as conditional, so there are 2 outgoing BBs */
boolean
nvbb_dominated_by(struct nv_basic_block *b, struct nv_basic_block *d)
{
int j;
if (b == d)
return TRUE;
for (j = 0; j < b->num_in; ++j)
if ((b->in_kind[j] != CFG_EDGE_BACK) && !nvbb_dominated_by(b->in[j], d))
return FALSE;
return j ? TRUE : FALSE;
}
/* check if @bf (future) can be reached from @bp (past), stop at @bt */
boolean
nvbb_reachable_by(struct nv_basic_block *bf, struct nv_basic_block *bp,
struct nv_basic_block *bt)
{
struct nv_basic_block *q[NV_PC_MAX_BASIC_BLOCKS], *b;
int i, p, n;
p = 0;
n = 1;
q[0] = bp;
while (p < n) {
b = q[p++];
if (b == bf)
break;
if (b == bt)
continue;
assert(n <= (1024 - 2));
for (i = 0; i < 2; ++i) {
if (b->out[i] && !IS_WALL_EDGE(b->out_kind[i]) && !b->out[i]->priv) {
q[n] = b->out[i];
q[n++]->priv = 1;
}
}
}
for (--n; n >= 0; --n)
q[n]->priv = 0;
return (b == bf);
}
static struct nv_basic_block *
nvbb_find_dom_frontier(struct nv_basic_block *b, struct nv_basic_block *df)
{
struct nv_basic_block *out;
int i;
if (!nvbb_dominated_by(df, b)) {
for (i = 0; i < df->num_in; ++i) {
if (df->in_kind[i] == CFG_EDGE_BACK)
continue;
if (nvbb_dominated_by(df->in[i], b))
return df;
}
}
for (i = 0; i < 2 && df->out[i]; ++i) {
if (df->out_kind[i] == CFG_EDGE_BACK)
continue;
if ((out = nvbb_find_dom_frontier(b, df->out[i])))
return out;
}
return NULL;
}
struct nv_basic_block *
nvbb_dom_frontier(struct nv_basic_block *b)
{
struct nv_basic_block *df;
int i;
for (i = 0; i < 2 && b->out[i]; ++i)
if ((df = nvbb_find_dom_frontier(b, b->out[i])))
return df;
return NULL;
}
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