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ir_emit.c
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ir_emit.c
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/*
* IR - Lightweight JIT Compilation Framework
* (Native code generator based on DynAsm)
* Copyright (C) 2022 Zend by Perforce.
* Authors: Dmitry Stogov <[email protected]>
*/
#include "ir.h"
#if defined(IR_TARGET_X86) || defined(IR_TARGET_X64)
# include "ir_x86.h"
#elif defined(IR_TARGET_AARCH64)
# include "ir_aarch64.h"
#else
# error "Unknown IR target"
#endif
#include "ir_private.h"
#ifndef _WIN32
# include <dlfcn.h>
#else
# define WIN32_LEAN_AND_MEAN
# include <windows.h>
# include <psapi.h>
#endif
#if defined(__linux__) || defined(__sun)
# include <alloca.h>
#endif
#define DASM_M_GROW(ctx, t, p, sz, need) \
do { \
size_t _sz = (sz), _need = (need); \
if (_sz < _need) { \
if (_sz < 16) _sz = 16; \
while (_sz < _need) _sz += _sz; \
(p) = (t *)ir_mem_realloc((p), _sz); \
(sz) = _sz; \
} \
} while(0)
#define DASM_M_FREE(ctx, p, sz) ir_mem_free(p)
#ifdef IR_DEBUG
# define DASM_CHECKS
#endif
typedef struct _ir_copy {
ir_type type;
ir_reg from;
ir_reg to;
} ir_copy;
typedef struct _ir_dessa_copy {
ir_type type;
int32_t from; /* negative - constant ref, [0..IR_REG_NUM) - CPU reg, [IR_REG_NUM...) - virtual reg */
int32_t to; /* [0..IR_REG_NUM) - CPU reg, [IR_REG_NUM...) - virtual reg */
} ir_dessa_copy;
#if IR_REG_INT_ARGS
static const int8_t _ir_int_reg_params[IR_REG_INT_ARGS];
#else
static const int8_t *_ir_int_reg_params;
#endif
#if IR_REG_FP_ARGS
static const int8_t _ir_fp_reg_params[IR_REG_FP_ARGS];
#else
static const int8_t *_ir_fp_reg_params;
#endif
static const ir_proto_t *ir_call_proto(const ir_ctx *ctx, ir_insn *insn)
{
if (IR_IS_CONST_REF(insn->op2)) {
const ir_insn *func = &ctx->ir_base[insn->op2];
if (func->op == IR_FUNC || func->op == IR_FUNC_ADDR) {
if (func->proto) {
return (const ir_proto_t *)ir_get_str(ctx, func->proto);
}
}
} else if (ctx->ir_base[insn->op2].op == IR_PROTO) {
return (const ir_proto_t *)ir_get_str(ctx, ctx->ir_base[insn->op2].op2);
}
return NULL;
}
#ifdef IR_HAVE_FASTCALL
static const int8_t _ir_int_fc_reg_params[IR_REG_INT_FCARGS];
static const int8_t *_ir_fp_fc_reg_params;
bool ir_is_fastcall(const ir_ctx *ctx, const ir_insn *insn)
{
if (sizeof(void*) == 4) {
if (IR_IS_CONST_REF(insn->op2)) {
const ir_insn *func = &ctx->ir_base[insn->op2];
if (func->op == IR_FUNC || func->op == IR_FUNC_ADDR) {
if (func->proto) {
const ir_proto_t *proto = (const ir_proto_t *)ir_get_str(ctx, func->proto);
return (proto->flags & IR_FASTCALL_FUNC) != 0;
}
}
} else if (ctx->ir_base[insn->op2].op == IR_PROTO) {
const ir_proto_t *proto = (const ir_proto_t *)ir_get_str(ctx, ctx->ir_base[insn->op2].op2);
return (proto->flags & IR_FASTCALL_FUNC) != 0;
}
return 0;
}
return 0;
}
#else
bool ir_is_fastcall(const ir_ctx *ctx, const ir_insn *insn)
{
return 0;
}
#endif
bool ir_is_vararg(const ir_ctx *ctx, ir_insn *insn)
{
const ir_proto_t *proto = ir_call_proto(ctx, insn);
if (proto) {
return (proto->flags & IR_VARARG_FUNC) != 0;
}
return 0;
}
IR_ALWAYS_INLINE uint32_t ir_rule(const ir_ctx *ctx, ir_ref ref)
{
IR_ASSERT(!IR_IS_CONST_REF(ref));
return ctx->rules[ref];
}
IR_ALWAYS_INLINE bool ir_in_same_block(ir_ctx *ctx, ir_ref ref)
{
return ref > ctx->bb_start;
}
static ir_reg ir_get_param_reg(const ir_ctx *ctx, ir_ref ref)
{
ir_use_list *use_list = &ctx->use_lists[1];
int i;
ir_ref use, *p;
ir_insn *insn;
int int_param = 0;
int fp_param = 0;
int int_reg_params_count = IR_REG_INT_ARGS;
int fp_reg_params_count = IR_REG_FP_ARGS;
const int8_t *int_reg_params = _ir_int_reg_params;
const int8_t *fp_reg_params = _ir_fp_reg_params;
#ifdef IR_HAVE_FASTCALL
if (sizeof(void*) == 4 && (ctx->flags & IR_FASTCALL_FUNC)) {
int_reg_params_count = IR_REG_INT_FCARGS;
fp_reg_params_count = IR_REG_FP_FCARGS;
int_reg_params = _ir_int_fc_reg_params;
fp_reg_params = _ir_fp_fc_reg_params;
}
#endif
for (i = 0, p = &ctx->use_edges[use_list->refs]; i < use_list->count; i++, p++) {
use = *p;
insn = &ctx->ir_base[use];
if (insn->op == IR_PARAM) {
if (IR_IS_TYPE_INT(insn->type)) {
if (use == ref) {
if (int_param < int_reg_params_count) {
return int_reg_params[int_param];
} else {
return IR_REG_NONE;
}
}
int_param++;
#ifdef _WIN64
/* WIN64 calling convention use common couter for int and fp registers */
fp_param++;
#endif
} else {
IR_ASSERT(IR_IS_TYPE_FP(insn->type));
if (use == ref) {
if (fp_param < fp_reg_params_count) {
return fp_reg_params[fp_param];
} else {
return IR_REG_NONE;
}
}
fp_param++;
#ifdef _WIN64
/* WIN64 calling convention use common couter for int and fp registers */
int_param++;
#endif
}
}
}
return IR_REG_NONE;
}
static int ir_get_args_regs(const ir_ctx *ctx, const ir_insn *insn, int8_t *regs)
{
int j, n;
ir_type type;
int int_param = 0;
int fp_param = 0;
int count = 0;
int int_reg_params_count = IR_REG_INT_ARGS;
int fp_reg_params_count = IR_REG_FP_ARGS;
const int8_t *int_reg_params = _ir_int_reg_params;
const int8_t *fp_reg_params = _ir_fp_reg_params;
#ifdef IR_HAVE_FASTCALL
if (sizeof(void*) == 4 && ir_is_fastcall(ctx, insn)) {
int_reg_params_count = IR_REG_INT_FCARGS;
fp_reg_params_count = IR_REG_FP_FCARGS;
int_reg_params = _ir_int_fc_reg_params;
fp_reg_params = _ir_fp_fc_reg_params;
}
#endif
n = insn->inputs_count;
n = IR_MIN(n, IR_MAX_REG_ARGS + 2);
for (j = 3; j <= n; j++) {
type = ctx->ir_base[ir_insn_op(insn, j)].type;
if (IR_IS_TYPE_INT(type)) {
if (int_param < int_reg_params_count) {
regs[j] = int_reg_params[int_param];
count = j + 1;
} else {
regs[j] = IR_REG_NONE;
}
int_param++;
#ifdef _WIN64
/* WIN64 calling convention use common couter for int and fp registers */
fp_param++;
#endif
} else {
IR_ASSERT(IR_IS_TYPE_FP(type));
if (fp_param < fp_reg_params_count) {
regs[j] = fp_reg_params[fp_param];
count = j + 1;
} else {
regs[j] = IR_REG_NONE;
}
fp_param++;
#ifdef _WIN64
/* WIN64 calling convention use common couter for int and fp registers */
int_param++;
#endif
}
}
return count;
}
static bool ir_is_same_mem_var(const ir_ctx *ctx, ir_ref r1, int32_t offset)
{
ir_live_interval *ival1;
int32_t o1;
if (IR_IS_CONST_REF(r1)) {
return 0;
}
IR_ASSERT(ctx->vregs[r1]);
ival1 = ctx->live_intervals[ctx->vregs[r1]];
IR_ASSERT(ival1);
o1 = ival1->stack_spill_pos;
IR_ASSERT(o1 != -1);
return o1 == offset;
}
void *ir_resolve_sym_name(const char *name)
{
void *handle = NULL;
void *addr;
#ifndef _WIN32
# ifdef RTLD_DEFAULT
handle = RTLD_DEFAULT;
# endif
addr = dlsym(handle, name);
#else
HMODULE mods[256];
DWORD cbNeeded;
uint32_t i = 0;
addr = NULL;
EnumProcessModules(GetCurrentProcess(), mods, sizeof(mods), &cbNeeded);
while(i < (cbNeeded / sizeof(HMODULE))) {
addr = GetProcAddress(mods[i], name);
if (addr) {
return addr;
}
i++;
}
#endif
return addr;
}
#ifdef IR_SNAPSHOT_HANDLER_DCL
IR_SNAPSHOT_HANDLER_DCL();
#endif
#if defined(IR_TARGET_X86) || defined(IR_TARGET_X64)
static void* ir_sym_addr(ir_ctx *ctx, const ir_insn *addr_insn)
{
const char *name = ir_get_str(ctx, addr_insn->val.name);
void *addr = (ctx->loader && ctx->loader->resolve_sym_name) ?
ctx->loader->resolve_sym_name(ctx->loader, name, 0) :
ir_resolve_sym_name(name);
return addr;
}
#endif
static void* ir_sym_val(ir_ctx *ctx, const ir_insn *addr_insn)
{
const char *name = ir_get_str(ctx, addr_insn->val.name);
void *addr = (ctx->loader && ctx->loader->resolve_sym_name) ?
ctx->loader->resolve_sym_name(ctx->loader, name, addr_insn->op == IR_FUNC) :
ir_resolve_sym_name(name);
IR_ASSERT(addr);
return addr;
}
static void *ir_call_addr(ir_ctx *ctx, ir_insn *insn, ir_insn *addr_insn)
{
void *addr;
IR_ASSERT(addr_insn->type == IR_ADDR);
if (addr_insn->op == IR_FUNC) {
addr = ir_sym_val(ctx, addr_insn);
} else {
IR_ASSERT(addr_insn->op == IR_ADDR || addr_insn->op == IR_FUNC_ADDR);
addr = (void*)addr_insn->val.addr;
}
return addr;
}
static void *ir_jmp_addr(ir_ctx *ctx, ir_insn *insn, ir_insn *addr_insn)
{
void *addr = ir_call_addr(ctx, insn, addr_insn);
#ifdef IR_SNAPSHOT_HANDLER
if (ctx->ir_base[insn->op1].op == IR_SNAPSHOT) {
addr = IR_SNAPSHOT_HANDLER(ctx, insn->op1, &ctx->ir_base[insn->op1], addr);
}
#endif
return addr;
}
static int8_t ir_get_fused_reg(ir_ctx *ctx, ir_ref root, ir_ref ref_and_op)
{
if (ctx->fused_regs) {
char key[10];
ir_ref val;
memcpy(key, &root, sizeof(ir_ref));
memcpy(key + 4, &ref_and_op, sizeof(ir_ref));
val = ir_strtab_find(ctx->fused_regs, key, 8);
if (val) {
return val;
}
}
return ((int8_t*)ctx->regs)[ref_and_op];
}
#if defined(__GNUC__)
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Warray-bounds"
# pragma GCC diagnostic ignored "-Wimplicit-fallthrough"
#endif
#if defined(IR_TARGET_X86) || defined(IR_TARGET_X64)
# include "dynasm/dasm_proto.h"
# include "dynasm/dasm_x86.h"
#elif defined(IR_TARGET_AARCH64)
# include "dynasm/dasm_proto.h"
static int ir_add_veneer(dasm_State *Dst, void *buffer, uint32_t ins, int *b, uint32_t *cp, ptrdiff_t offset);
# define DASM_ADD_VENEER ir_add_veneer
# include "dynasm/dasm_arm64.h"
#else
# error "Unknown IR target"
#endif
#if defined(__GNUC__)
# pragma GCC diagnostic pop
#endif
/* Forward Declarations */
static void ir_emit_osr_entry_loads(ir_ctx *ctx, int b, ir_block *bb);
static int ir_parallel_copy(ir_ctx *ctx, ir_copy *copies, int count, ir_reg tmp_reg, ir_reg tmp_fp_reg);
static void ir_emit_dessa_moves(ir_ctx *ctx, int b, ir_block *bb);
typedef struct _ir_common_backend_data {
ir_reg_alloc_data ra_data;
uint32_t dessa_from_block;
dasm_State *dasm_state;
ir_bitset emit_constants;
} ir_common_backend_data;
static int ir_const_label(ir_ctx *ctx, ir_ref ref)
{
ir_common_backend_data *data = ctx->data;
int label = ctx->cfg_blocks_count - ref;
IR_ASSERT(IR_IS_CONST_REF(ref));
ir_bitset_incl(data->emit_constants, -ref);
return label;
}
#if defined(IR_TARGET_X86) || defined(IR_TARGET_X64)
# include "ir_emit_x86.h"
#elif defined(IR_TARGET_AARCH64)
# include "ir_emit_aarch64.h"
#else
# error "Unknown IR target"
#endif
static IR_NEVER_INLINE void ir_emit_osr_entry_loads(ir_ctx *ctx, int b, ir_block *bb)
{
ir_list *list = (ir_list*)ctx->osr_entry_loads;
int pos = 0, count, i;
ir_ref ref;
IR_ASSERT(ctx->binding);
IR_ASSERT(list);
while (1) {
i = ir_list_at(list, pos);
if (b == i) {
break;
}
IR_ASSERT(i != 0); /* end marker */
pos++;
count = ir_list_at(list, pos);
pos += count + 1;
}
pos++;
count = ir_list_at(list, pos);
pos++;
for (i = 0; i < count; i++, pos++) {
ref = ir_list_at(list, pos);
IR_ASSERT(ref >= 0 && ctx->vregs[ref] && ctx->live_intervals[ctx->vregs[ref]]);
if (!(ctx->live_intervals[ctx->vregs[ref]]->flags & IR_LIVE_INTERVAL_SPILLED)) {
/* not spilled */
ir_reg reg = ctx->live_intervals[ctx->vregs[ref]]->reg;
ir_type type = ctx->ir_base[ref].type;
int32_t offset = -ir_binding_find(ctx, ref);
IR_ASSERT(offset > 0);
ir_emit_load_mem(ctx, type, reg, IR_MEM_BO(ctx->spill_base, offset));
} else {
IR_ASSERT(ctx->live_intervals[ctx->vregs[ref]]->flags & IR_LIVE_INTERVAL_SPILL_SPECIAL);
}
}
}
/*
* Parallel copy sequentialization algorithm
*
* The implementation is based on algorithm 1 desriebed in
* "Revisiting Out-of-SSA Translation for Correctness, Code Quality and Efficiency",
* Benoit Boissinot, Alain Darte, Fabrice Rastello, Benoit Dupont de Dinechin, Christophe Guillon.
* 2009 International Symposium on Code Generation and Optimization, Seattle, WA, USA, 2009,
* pp. 114-125, doi: 10.1109/CGO.2009.19.
*/
static int ir_parallel_copy(ir_ctx *ctx, ir_copy *copies, int count, ir_reg tmp_reg, ir_reg tmp_fp_reg)
{
int i;
int8_t *pred, *loc, *types;
ir_reg to, from;
ir_type type;
ir_regset todo, ready, srcs;
if (count == 1) {
to = copies[0].to;
from = copies[0].from;
IR_ASSERT(from != to);
type = copies[0].type;
if (IR_IS_TYPE_INT(type)) {
ir_emit_mov(ctx, type, to, from);
} else {
ir_emit_fp_mov(ctx, type, to, from);
}
return 1;
}
loc = alloca(IR_REG_NUM * 3 * sizeof(int8_t));
pred = loc + IR_REG_NUM;
types = pred + IR_REG_NUM;
todo = IR_REGSET_EMPTY;
srcs = IR_REGSET_EMPTY;
for (i = 0; i < count; i++) {
from = copies[i].from;
to = copies[i].to;
IR_ASSERT(from != to);
IR_REGSET_INCL(srcs, from);
loc[from] = from;
pred[to] = from;
types[from] = copies[i].type;
IR_ASSERT(!IR_REGSET_IN(todo, to));
IR_REGSET_INCL(todo, to);
}
ready = IR_REGSET_DIFFERENCE(todo, srcs);
if (ready == todo) {
for (i = 0; i < count; i++) {
from = copies[i].from;
to = copies[i].to;
IR_ASSERT(from != to);
type = copies[i].type;
if (IR_IS_TYPE_INT(type)) {
ir_emit_mov(ctx, type, to, from);
} else {
ir_emit_fp_mov(ctx, type, to, from);
}
}
return 1;
}
/* temporary registers can't be the same as some of the destinations */
IR_ASSERT(tmp_reg == IR_REG_NONE || !IR_REGSET_IN(todo, tmp_reg));
IR_ASSERT(tmp_fp_reg == IR_REG_NONE || !IR_REGSET_IN(todo, tmp_fp_reg));
/* first we resolve all "windmill blades" - trees (this doesn't requre temporary registers) */
while (ready != IR_REGSET_EMPTY) {
ir_reg r;
to = ir_regset_pop_first(&ready);
from = pred[to];
r = loc[from];
type = types[from];
if (IR_IS_TYPE_INT(type)) {
ir_emit_mov_ext(ctx, type, to, r);
} else {
ir_emit_fp_mov(ctx, type, to, r);
}
IR_REGSET_EXCL(todo, to);
loc[from] = to;
if (from == r && IR_REGSET_IN(todo, from)) {
IR_REGSET_INCL(ready, from);
}
}
if (todo == IR_REGSET_EMPTY) {
return 1;
}
/* at this point the sources that are the same as temoraries are already moved */
IR_ASSERT(tmp_reg == IR_REG_NONE || !IR_REGSET_IN(srcs, tmp_reg) || pred[loc[tmp_reg]] == tmp_reg);
IR_ASSERT(tmp_fp_reg == IR_REG_NONE || !IR_REGSET_IN(srcs, tmp_fp_reg) || pred[loc[tmp_fp_reg]] == tmp_fp_reg);
/* now we resolve all "windmill axles" - cycles (this reuires temporary registers) */
while (todo != IR_REGSET_EMPTY) {
to = ir_regset_pop_first(&todo);
from = pred[to];
IR_ASSERT(to != loc[from]);
type = types[from];
if (IR_IS_TYPE_INT(type)) {
#ifdef IR_HAVE_SWAP_INT
if (pred[from] == to) {
ir_emit_swap(ctx, type, to, from);
IR_REGSET_EXCL(todo, from);
loc[to] = from;
loc[from] = to;
continue;
}
#endif
IR_ASSERT(tmp_reg != IR_REG_NONE);
IR_ASSERT(tmp_reg >= IR_REG_GP_FIRST && tmp_reg <= IR_REG_GP_LAST);
ir_emit_mov(ctx, type, tmp_reg, to);
loc[to] = tmp_reg;
} else {
#ifdef IR_HAVE_SWAP_FP
if (pred[from] == to) {
ir_emit_swap_fp(ctx, type, to, from);
IR_REGSET_EXCL(todo, from);
loc[to] = from;
loc[from] = to;
continue;
}
#endif
IR_ASSERT(tmp_fp_reg != IR_REG_NONE);
IR_ASSERT(tmp_fp_reg >= IR_REG_FP_FIRST && tmp_fp_reg <= IR_REG_FP_LAST);
ir_emit_fp_mov(ctx, type, tmp_fp_reg, to);
loc[to] = tmp_fp_reg;
}
while (1) {
ir_reg r;
from = pred[to];
r = loc[from];
type = types[from];
if (IR_IS_TYPE_INT(type)) {
ir_emit_mov_ext(ctx, type, to, r);
} else {
ir_emit_fp_mov(ctx, type, to, r);
}
IR_REGSET_EXCL(todo, to);
loc[from] = to;
if (from == r && IR_REGSET_IN(todo, from)) {
to = from;
} else {
break;
}
}
}
return 1;
}
static void ir_emit_dessa_move(ir_ctx *ctx, ir_type type, ir_ref to, ir_ref from, ir_reg tmp_reg, ir_reg tmp_fp_reg)
{
ir_mem mem_from, mem_to;
IR_ASSERT(from != to);
if (to < IR_REG_NUM) {
if (IR_IS_CONST_REF(from)) {
if (-from < ctx->consts_count) {
/* constant reference */
ir_emit_load(ctx, type, to, from);
} else {
/* local variable address */
ir_load_local_addr(ctx, to, -from - ctx->consts_count);
}
} else if (from < IR_REG_NUM) {
if (IR_IS_TYPE_INT(type)) {
ir_emit_mov(ctx, type, to, from);
} else {
ir_emit_fp_mov(ctx, type, to, from);
}
} else {
mem_from = ir_vreg_spill_slot(ctx, from - IR_REG_NUM);
ir_emit_load_mem(ctx, type, to, mem_from);
}
} else {
mem_to = ir_vreg_spill_slot(ctx, to - IR_REG_NUM);
if (IR_IS_CONST_REF(from)) {
if (-from < ctx->consts_count) {
/* constant reference */
#if defined(IR_TARGET_X86) || defined(IR_TARGET_X64)
if (IR_IS_TYPE_INT(type)
&& !IR_IS_SYM_CONST(ctx->ir_base[from].op)
&& (ir_type_size[type] != 8 || IR_IS_SIGNED_32BIT(ctx->ir_base[from].val.i64))) {
ir_emit_store_mem_imm(ctx, type, mem_to, ctx->ir_base[from].val.i32);
return;
}
#endif
ir_reg tmp = IR_IS_TYPE_INT(type) ? tmp_reg : tmp_fp_reg;
IR_ASSERT(tmp != IR_REG_NONE);
ir_emit_load(ctx, type, tmp, from);
ir_emit_store_mem(ctx, type, mem_to, tmp);
} else {
/* local variable address */
IR_ASSERT(IR_IS_TYPE_INT(type));
IR_ASSERT(tmp_reg != IR_REG_NONE);
ir_load_local_addr(ctx, tmp_reg, -from - ctx->consts_count);
ir_emit_store_mem(ctx, type, mem_to, tmp_reg);
}
} else if (from < IR_REG_NUM) {
ir_emit_store_mem(ctx, type, mem_to, from);
} else {
mem_from = ir_vreg_spill_slot(ctx, from - IR_REG_NUM);
IR_ASSERT(IR_MEM_VAL(mem_to) != IR_MEM_VAL(mem_from));
ir_reg tmp = IR_IS_TYPE_INT(type) ? tmp_reg : tmp_fp_reg;
IR_ASSERT(tmp != IR_REG_NONE);
ir_emit_load_mem(ctx, type, tmp, mem_from);
ir_emit_store_mem(ctx, type, mem_to, tmp);
}
}
}
IR_ALWAYS_INLINE void ir_dessa_resolve_cycle(ir_ctx *ctx, int32_t *pred, int32_t *loc, int8_t *types, ir_bitset todo, int32_t to, ir_reg tmp_reg, ir_reg tmp_fp_reg)
{
ir_ref from;
ir_mem tmp_spill_slot;
ir_type type;
IR_MEM_VAL(tmp_spill_slot) = 0;
IR_ASSERT(!IR_IS_CONST_REF(to));
from = pred[to];
type = types[from];
IR_ASSERT(!IR_IS_CONST_REF(from));
IR_ASSERT(from != to);
IR_ASSERT(loc[from] == from);
if (IR_IS_TYPE_INT(type)) {
#ifdef IR_HAVE_SWAP_INT
if (pred[from] == to && to < IR_REG_NUM && from < IR_REG_NUM) {
/* a simple cycle from 2 elements */
if (ir_type_size[types[to]] > ir_type_size[type]) {
type = types[to];
}
ir_emit_swap(ctx, type, to, from);
ir_bitset_excl(todo, from);
ir_bitset_excl(todo, to);
loc[to] = from;
loc[from] = to;
return;
}
#endif
IR_ASSERT(tmp_reg != IR_REG_NONE);
IR_ASSERT(tmp_reg >= IR_REG_GP_FIRST && tmp_reg <= IR_REG_GP_LAST);
loc[to] = tmp_reg;
if (to < IR_REG_NUM) {
ir_emit_mov(ctx, type, tmp_reg, to);
} else {
ir_emit_load_mem_int(ctx, type, tmp_reg, ir_vreg_spill_slot(ctx, to - IR_REG_NUM));
}
} else {
#ifdef IR_HAVE_SWAP_FP
if (pred[from] == to && to < IR_REG_NUM && from < IR_REG_NUM && types[to] == type) {
/* a simple cycle from 2 elements */
ir_emit_swap_fp(ctx, type, to, from);
IR_REGSET_EXCL(todo, from);
IR_REGSET_EXCL(todo, to);
loc[to] = from;
loc[from] = to;
return;
}
#endif
IR_ASSERT(tmp_fp_reg != IR_REG_NONE);
IR_ASSERT(tmp_fp_reg >= IR_REG_FP_FIRST && tmp_fp_reg <= IR_REG_FP_LAST);
loc[to] = tmp_fp_reg;
if (to < IR_REG_NUM) {
ir_emit_fp_mov(ctx, type, tmp_fp_reg, to);
} else {
ir_emit_load_mem_fp(ctx, type, tmp_fp_reg, ir_vreg_spill_slot(ctx, to - IR_REG_NUM));
}
}
while (1) {
int32_t r;
from = pred[to];
r = loc[from];
type = types[to];
if (from == r && ir_bitset_in(todo, from)) {
/* Memory to memory move inside an isolated or "blocked" cycle requres an additional temporary register */
if (to >= IR_REG_NUM && r >= IR_REG_NUM) {
ir_reg tmp = IR_IS_TYPE_INT(type) ? tmp_reg : tmp_fp_reg;
if (!IR_MEM_VAL(tmp_spill_slot)) {
/* Free a register, saving it in a temporary spill slot */
tmp_spill_slot = IR_MEM_BO(IR_REG_STACK_POINTER, -16);
ir_emit_store_mem(ctx, type, tmp_spill_slot, tmp);
}
ir_emit_dessa_move(ctx, type, to, r, tmp_reg, tmp_fp_reg);
} else {
ir_emit_dessa_move(ctx, type, to, r, IR_REG_NONE, IR_REG_NONE);
}
ir_bitset_excl(todo, to);
loc[from] = to;
to = from;
} else {
break;
}
}
type = types[to];
if (IR_MEM_VAL(tmp_spill_slot)) {
ir_emit_load_mem(ctx, type, IR_IS_TYPE_INT(type) ? tmp_reg : tmp_fp_reg, tmp_spill_slot);
}
ir_emit_dessa_move(ctx, type, to, loc[from], IR_REG_NONE, IR_REG_NONE);
ir_bitset_excl(todo, to);
loc[from] = to;
}
static int ir_dessa_parallel_copy(ir_ctx *ctx, ir_dessa_copy *copies, int count, ir_reg tmp_reg, ir_reg tmp_fp_reg)
{
int i;
int32_t *pred, *loc, to, from;
int8_t *types;
ir_type type;
uint32_t len;
ir_bitset todo, ready, srcs, visited;
if (count == 1) {
to = copies[0].to;
from = copies[0].from;
IR_ASSERT(from != to);
type = copies[0].type;
ir_emit_dessa_move(ctx, type, to, from, tmp_reg, tmp_fp_reg);
return 1;
}
len = IR_REG_NUM + ctx->vregs_count + 1;
todo = ir_bitset_malloc(len);
srcs = ir_bitset_malloc(len);
loc = ir_mem_malloc(len * 2 * sizeof(int32_t) + len * sizeof(int8_t));
pred = loc + len;
types = (int8_t*)(pred + len);
for (i = 0; i < count; i++) {
from = copies[i].from;
to = copies[i].to;
IR_ASSERT(from != to);
if (!IR_IS_CONST_REF(from)) {
ir_bitset_incl(srcs, from);
loc[from] = from;
}
pred[to] = from;
types[to] = copies[i].type;
IR_ASSERT(!ir_bitset_in(todo, to));
ir_bitset_incl(todo, to);
}
/* temporary registers can't be the same as some of the sources */
IR_ASSERT(tmp_reg == IR_REG_NONE || !ir_bitset_in(srcs, tmp_reg));
IR_ASSERT(tmp_fp_reg == IR_REG_NONE || !ir_bitset_in(srcs, tmp_fp_reg));
/* first we resolve all "windmill blades" - trees, that don't set temporary registers */
ready = ir_bitset_malloc(len);
ir_bitset_copy(ready, todo, ir_bitset_len(len));
ir_bitset_difference(ready, srcs, ir_bitset_len(len));
if (tmp_reg != IR_REG_NONE) {
ir_bitset_excl(ready, tmp_reg);
}
if (tmp_fp_reg != IR_REG_NONE) {
ir_bitset_excl(ready, tmp_fp_reg);
}
while ((to = ir_bitset_pop_first(ready, ir_bitset_len(len))) >= 0) {
ir_bitset_excl(todo, to);
type = types[to];
from = pred[to];
if (IR_IS_CONST_REF(from)) {
ir_emit_dessa_move(ctx, type, to, from, tmp_reg, tmp_fp_reg);
} else {
int32_t r = loc[from];
ir_emit_dessa_move(ctx, type, to, r, tmp_reg, tmp_fp_reg);
loc[from] = to;
if (from == r && ir_bitset_in(todo, from) && from != tmp_reg && from != tmp_fp_reg) {
ir_bitset_incl(ready, from);
}
}
}
/* then we resolve all "windmill axles" - cycles (this requres temporary registers) */
visited = ir_bitset_malloc(len);
ir_bitset_copy(ready, todo, ir_bitset_len(len));
ir_bitset_intersection(ready, srcs, ir_bitset_len(len));
while ((to = ir_bitset_first(ready, ir_bitset_len(len))) >= 0) {
ir_bitset_clear(visited, ir_bitset_len(len));
ir_bitset_incl(visited, to);
to = pred[to];
while (!IR_IS_CONST_REF(to) && ir_bitset_in(ready, to)) {
to = pred[to];
if (IR_IS_CONST_REF(to)) {
break;
} else if (ir_bitset_in(visited, to)) {
/* We found a cycle. Resolve it. */
ir_bitset_incl(visited, to);
ir_dessa_resolve_cycle(ctx, pred, loc, types, todo, to, tmp_reg, tmp_fp_reg);
break;
}
ir_bitset_incl(visited, to);
}
ir_bitset_difference(ready, visited, ir_bitset_len(len));
}
/* finally we resolve remaining "windmill blades" - trees that set temporary registers */
ir_bitset_copy(ready, todo, ir_bitset_len(len));
ir_bitset_difference(ready, srcs, ir_bitset_len(len));
while ((to = ir_bitset_pop_first(ready, ir_bitset_len(len))) >= 0) {
ir_bitset_excl(todo, to);
type = types[to];
from = pred[to];
if (IR_IS_CONST_REF(from)) {
ir_emit_dessa_move(ctx, type, to, from, tmp_reg, tmp_fp_reg);
} else {
int32_t r = loc[from];
ir_emit_dessa_move(ctx, type, to, r, tmp_reg, tmp_fp_reg);
loc[from] = to;
if (from == r && ir_bitset_in(todo, from)) {
ir_bitset_incl(ready, from);
}
}
}
IR_ASSERT(ir_bitset_empty(todo, ir_bitset_len(len)));
ir_mem_free(visited);
ir_mem_free(ready);
ir_mem_free(loc);
ir_mem_free(srcs);
ir_mem_free(todo);
return 1;
}
static void ir_emit_dessa_moves(ir_ctx *ctx, int b, ir_block *bb)
{
uint32_t succ, k, n = 0;
ir_block *succ_bb;
ir_use_list *use_list;
ir_ref i, *p;
ir_dessa_copy *copies;
ir_reg tmp_reg = ctx->regs[bb->end][0];
ir_reg tmp_fp_reg = ctx->regs[bb->end][1];
IR_ASSERT(bb->successors_count == 1);
succ = ctx->cfg_edges[bb->successors];
succ_bb = &ctx->cfg_blocks[succ];
IR_ASSERT(succ_bb->predecessors_count > 1);
use_list = &ctx->use_lists[succ_bb->start];
k = ir_phi_input_number(ctx, succ_bb, b);
copies = alloca(use_list->count * sizeof(ir_dessa_copy));
for (i = 0, p = &ctx->use_edges[use_list->refs]; i < use_list->count; i++, p++) {
ir_ref ref = *p;
ir_insn *insn = &ctx->ir_base[ref];
if (insn->op == IR_PHI) {
ir_ref input = ir_insn_op(insn, k);
ir_reg src = ir_get_alocated_reg(ctx, ref, k);
ir_reg dst = ctx->regs[ref][0];
ir_ref from, to;
IR_ASSERT(dst == IR_REG_NONE || !IR_REG_SPILLED(dst));
if (IR_IS_CONST_REF(input)) {
from = input;
} else if (ir_rule(ctx, input) == IR_STATIC_ALLOCA) {
/* encode local variable address */
from = -(ctx->consts_count + input);
} else {
from = (src != IR_REG_NONE && !IR_REG_SPILLED(src)) ?
(ir_ref)src : (ir_ref)(IR_REG_NUM + ctx->vregs[input]);
}
to = (dst != IR_REG_NONE) ?
(ir_ref)dst : (ir_ref)(IR_REG_NUM + ctx->vregs[ref]);
if (to != from) {
if (to >= IR_REG_NUM
&& from >= IR_REG_NUM
&& IR_MEM_VAL(ir_vreg_spill_slot(ctx, from - IR_REG_NUM)) ==
IR_MEM_VAL(ir_vreg_spill_slot(ctx, to - IR_REG_NUM))) {
/* It's possible that different virtual registers share the same special spill slot */
// TODO: See ext/opcache/tests/jit/gh11917.phpt failure on Linux 32-bit
continue;
}
copies[n].type = insn->type;
copies[n].from = from;
copies[n].to = to;
n++;
}
}
}
if (n > 0) {
ir_dessa_parallel_copy(ctx, copies, n, tmp_reg, tmp_fp_reg);
}
}
int ir_match(ir_ctx *ctx)
{
uint32_t b;
ir_ref start, ref, *prev_ref;
ir_block *bb;
ir_insn *insn;
uint32_t entries_count = 0;
ctx->rules = ir_mem_calloc(ctx->insns_count, sizeof(uint32_t));
prev_ref = ctx->prev_ref;
if (!prev_ref) {
ir_build_prev_refs(ctx);
prev_ref = ctx->prev_ref;
}
if (ctx->entries_count) {
ctx->entries = ir_mem_malloc(ctx->entries_count * sizeof(ir_ref));
}
for (b = ctx->cfg_blocks_count, bb = ctx->cfg_blocks + b; b > 0; b--, bb--) {
IR_ASSERT(!(bb->flags & IR_BB_UNREACHABLE));
start = bb->start;
if (UNEXPECTED(bb->flags & IR_BB_ENTRY)) {
IR_ASSERT(entries_count < ctx->entries_count);
insn = &ctx->ir_base[start];
IR_ASSERT(insn->op == IR_ENTRY);
insn->op3 = entries_count;
ctx->entries[entries_count] = b;
entries_count++;
}
ctx->rules[start] = IR_SKIPPED | IR_NOP;
ref = bb->end;
if (bb->successors_count == 1) {
insn = &ctx->ir_base[ref];
if (insn->op == IR_END || insn->op == IR_LOOP_END) {
ctx->rules[ref] = insn->op;
ref = prev_ref[ref];
if (ref == start && ctx->cfg_edges[bb->successors] != b) {
if (EXPECTED(!(bb->flags & IR_BB_ENTRY))) {