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cobalt / cobalt / 1bf8b4dd7753e80946b50c77b33fdf15f7df959b / . / src / v8 / src / interpreter / bytecode-register-optimizer.cc
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// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/interpreter/bytecode-register-optimizer.h"
namespace v8 {
namespace internal {
namespace interpreter {
const uint32_t BytecodeRegisterOptimizer::kInvalidEquivalenceId = kMaxUInt32;
// A class for tracking the state of a register. This class tracks
// which equivalence set a register is a member of and also whether a
// register is materialized in the bytecode stream.
class BytecodeRegisterOptimizer::RegisterInfo final : public ZoneObject {
public:
RegisterInfo(Register reg, uint32_t equivalence_id, bool materialized,
bool allocated)
: register_(reg),
equivalence_id_(equivalence_id),
materialized_(materialized),
allocated_(allocated),
needs_flush_(false),
next_(this),
prev_(this) {}
void AddToEquivalenceSetOf(RegisterInfo* info);
void MoveToNewEquivalenceSet(uint32_t equivalence_id, bool materialized);
bool IsOnlyMemberOfEquivalenceSet() const;
bool IsOnlyMaterializedMemberOfEquivalenceSet() const;
bool IsInSameEquivalenceSet(RegisterInfo* info) const;
// Get a member of the register's equivalence set that is allocated.
// Returns itself if allocated, and nullptr if there is no unallocated
// equivalent register.
RegisterInfo* GetAllocatedEquivalent();
// Get a member of this register's equivalence set that is
// materialized. The materialized equivalent will be this register
// if it is materialized. Returns nullptr if no materialized
// equivalent exists.
RegisterInfo* GetMaterializedEquivalent();
// Get a member of this register's equivalence set that is
// materialized and not register |reg|. The materialized equivalent
// will be this register if it is materialized. Returns nullptr if
// no materialized equivalent exists.
RegisterInfo* GetMaterializedEquivalentOtherThan(Register reg);
// Get a member of this register's equivalence set that is intended
// to be materialized in place of this register (which is currently
// materialized). The best candidate is deemed to be the register
// with the lowest index as this permits temporary registers to be
// removed from the bytecode stream. Returns nullptr if no candidate
// exists.
RegisterInfo* GetEquivalentToMaterialize();
// Marks all temporary registers of the equivalence set as unmaterialized.
void MarkTemporariesAsUnmaterialized(Register temporary_base);
// Get an equivalent register. Returns this if none exists.
RegisterInfo* GetEquivalent();
Register register_value() const { return register_; }
bool materialized() const { return materialized_; }
void set_materialized(bool materialized) { materialized_ = materialized; }
bool allocated() const { return allocated_; }
void set_allocated(bool allocated) { allocated_ = allocated; }
void set_equivalence_id(uint32_t equivalence_id) {
equivalence_id_ = equivalence_id;
}
uint32_t equivalence_id() const { return equivalence_id_; }
// Indicates if a register should be processed when calling Flush().
bool needs_flush() const { return needs_flush_; }
void set_needs_flush(bool needs_flush) { needs_flush_ = needs_flush; }
private:
Register register_;
uint32_t equivalence_id_;
bool materialized_;
bool allocated_;
bool needs_flush_;
// Equivalence set pointers.
RegisterInfo* next_;
RegisterInfo* prev_;
DISALLOW_COPY_AND_ASSIGN(RegisterInfo);
};
void BytecodeRegisterOptimizer::RegisterInfo::AddToEquivalenceSetOf(
RegisterInfo* info) {
DCHECK_NE(kInvalidEquivalenceId, info->equivalence_id());
// Fix old list
next_->prev_ = prev_;
prev_->next_ = next_;
// Add to new list.
next_ = info->next_;
prev_ = info;
prev_->next_ = this;
next_->prev_ = this;
set_equivalence_id(info->equivalence_id());
set_materialized(false);
}
void BytecodeRegisterOptimizer::RegisterInfo::MoveToNewEquivalenceSet(
uint32_t equivalence_id, bool materialized) {
next_->prev_ = prev_;
prev_->next_ = next_;
next_ = prev_ = this;
equivalence_id_ = equivalence_id;
materialized_ = materialized;
}
bool BytecodeRegisterOptimizer::RegisterInfo::IsOnlyMemberOfEquivalenceSet()
const {
return this->next_ == this;
}
bool BytecodeRegisterOptimizer::RegisterInfo::
IsOnlyMaterializedMemberOfEquivalenceSet() const {
DCHECK(materialized());
const RegisterInfo* visitor = this->next_;
while (visitor != this) {
if (visitor->materialized()) {
return false;
}
visitor = visitor->next_;
}
return true;
}
bool BytecodeRegisterOptimizer::RegisterInfo::IsInSameEquivalenceSet(
RegisterInfo* info) const {
return equivalence_id() == info->equivalence_id();
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::RegisterInfo::GetAllocatedEquivalent() {
RegisterInfo* visitor = this;
do {
if (visitor->allocated()) {
return visitor;
}
visitor = visitor->next_;
} while (visitor != this);
return nullptr;
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::RegisterInfo::GetMaterializedEquivalent() {
RegisterInfo* visitor = this;
do {
if (visitor->materialized()) {
return visitor;
}
visitor = visitor->next_;
} while (visitor != this);
return nullptr;
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::RegisterInfo::GetMaterializedEquivalentOtherThan(
Register reg) {
RegisterInfo* visitor = this;
do {
if (visitor->materialized() && visitor->register_value() != reg) {
return visitor;
}
visitor = visitor->next_;
} while (visitor != this);
return nullptr;
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::RegisterInfo::GetEquivalentToMaterialize() {
DCHECK(this->materialized());
RegisterInfo* visitor = this->next_;
RegisterInfo* best_info = nullptr;
while (visitor != this) {
if (visitor->materialized()) {
return nullptr;
}
if (visitor->allocated() &&
(best_info == nullptr ||
visitor->register_value() < best_info->register_value())) {
best_info = visitor;
}
visitor = visitor->next_;
}
return best_info;
}
void BytecodeRegisterOptimizer::RegisterInfo::MarkTemporariesAsUnmaterialized(
Register temporary_base) {
DCHECK(this->register_value() < temporary_base);
DCHECK(this->materialized());
RegisterInfo* visitor = this->next_;
while (visitor != this) {
if (visitor->register_value() >= temporary_base) {
visitor->set_materialized(false);
}
visitor = visitor->next_;
}
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::RegisterInfo::GetEquivalent() {
return next_;
}
BytecodeRegisterOptimizer::BytecodeRegisterOptimizer(
Zone* zone, BytecodeRegisterAllocator* register_allocator,
int fixed_registers_count, int parameter_count,
BytecodeWriter* bytecode_writer)
: accumulator_(Register::virtual_accumulator()),
temporary_base_(fixed_registers_count),
max_register_index_(fixed_registers_count - 1),
register_info_table_(zone),
registers_needing_flushed_(zone),
equivalence_id_(0),
bytecode_writer_(bytecode_writer),
flush_required_(false),
zone_(zone) {
register_allocator->set_observer(this);
// Calculate offset so register index values can be mapped into
// a vector of register metadata.
// There is at least one parameter, which is the JS receiver.
DCHECK(parameter_count != 0);
register_info_table_offset_ =
-Register::FromParameterIndex(0, parameter_count).index();
// Initialize register map for parameters, locals, and the
// accumulator.
register_info_table_.resize(register_info_table_offset_ +
static_cast<size_t>(temporary_base_.index()));
for (size_t i = 0; i < register_info_table_.size(); ++i) {
register_info_table_[i] = new (zone) RegisterInfo(
RegisterFromRegisterInfoTableIndex(i), NextEquivalenceId(), true, true);
DCHECK_EQ(register_info_table_[i]->register_value().index(),
RegisterFromRegisterInfoTableIndex(i).index());
}
accumulator_info_ = GetRegisterInfo(accumulator_);
DCHECK(accumulator_info_->register_value() == accumulator_);
}
void BytecodeRegisterOptimizer::PushToRegistersNeedingFlush(RegisterInfo* reg) {
if (!reg->needs_flush()) {
reg->set_needs_flush(true);
registers_needing_flushed_.push_back(reg);
}
}
bool BytecodeRegisterOptimizer::EnsureAllRegistersAreFlushed() const {
for (RegisterInfo* reg_info : register_info_table_) {
if (reg_info->needs_flush()) {
return false;
} else if (!reg_info->IsOnlyMemberOfEquivalenceSet()) {
return false;
} else if (reg_info->allocated() && !reg_info->materialized()) {
return false;
}
}
return true;
}
void BytecodeRegisterOptimizer::Flush() {
if (!flush_required_) {
return;
}
// Materialize all live registers and break equivalences.
for (RegisterInfo* reg_info : registers_needing_flushed_) {
if (!reg_info->needs_flush()) continue;
reg_info->set_needs_flush(false);
RegisterInfo* materialized = reg_info->materialized()
? reg_info
: reg_info->GetMaterializedEquivalent();
if (materialized != nullptr) {
// Walk equivalents of materialized registers, materializing
// each equivalent register as necessary and placing in their
// own equivalence set.
RegisterInfo* equivalent;
while ((equivalent = materialized->GetEquivalent()) != materialized) {
if (equivalent->allocated() && !equivalent->materialized()) {
OutputRegisterTransfer(materialized, equivalent);
}
equivalent->MoveToNewEquivalenceSet(NextEquivalenceId(), true);
equivalent->set_needs_flush(false);
}
} else {
// Equivalernce class containing only unallocated registers.
DCHECK(reg_info->GetAllocatedEquivalent() == nullptr);
reg_info->MoveToNewEquivalenceSet(NextEquivalenceId(), false);
}
}
registers_needing_flushed_.clear();
DCHECK(EnsureAllRegistersAreFlushed());
flush_required_ = false;
}
void BytecodeRegisterOptimizer::OutputRegisterTransfer(
RegisterInfo* input_info, RegisterInfo* output_info) {
Register input = input_info->register_value();
Register output = output_info->register_value();
DCHECK_NE(input.index(), output.index());
if (input == accumulator_) {
bytecode_writer_->EmitStar(output);
} else if (output == accumulator_) {
bytecode_writer_->EmitLdar(input);
} else {
bytecode_writer_->EmitMov(input, output);
}
if (output != accumulator_) {
max_register_index_ = std::max(max_register_index_, output.index());
}
output_info->set_materialized(true);
}
void BytecodeRegisterOptimizer::CreateMaterializedEquivalent(
RegisterInfo* info) {
DCHECK(info->materialized());
RegisterInfo* unmaterialized = info->GetEquivalentToMaterialize();
if (unmaterialized) {
OutputRegisterTransfer(info, unmaterialized);
}
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::GetMaterializedEquivalent(RegisterInfo* info) {
return info->materialized() ? info : info->GetMaterializedEquivalent();
}
BytecodeRegisterOptimizer::RegisterInfo*
BytecodeRegisterOptimizer::GetMaterializedEquivalentNotAccumulator(
RegisterInfo* info) {
if (info->materialized()) {
return info;
}
RegisterInfo* result = info->GetMaterializedEquivalentOtherThan(accumulator_);
if (result == nullptr) {
Materialize(info);
result = info;
}
DCHECK(result->register_value() != accumulator_);
return result;
}
void BytecodeRegisterOptimizer::Materialize(RegisterInfo* info) {
if (!info->materialized()) {
RegisterInfo* materialized = info->GetMaterializedEquivalent();
DCHECK_NOT_NULL(materialized);
OutputRegisterTransfer(materialized, info);
}
}
void BytecodeRegisterOptimizer::AddToEquivalenceSet(
RegisterInfo* set_member, RegisterInfo* non_set_member) {
// Equivalence class is now of size >= 2, so we make sure it will be flushed.
PushToRegistersNeedingFlush(non_set_member);
non_set_member->AddToEquivalenceSetOf(set_member);
// Flushing is only required when two or more registers are placed
// in the same equivalence set.
flush_required_ = true;
}
void BytecodeRegisterOptimizer::RegisterTransfer(RegisterInfo* input_info,
RegisterInfo* output_info) {
bool output_is_observable =
RegisterIsObservable(output_info->register_value());
bool in_same_equivalence_set =
output_info->IsInSameEquivalenceSet(input_info);
if (in_same_equivalence_set &&
(!output_is_observable || output_info->materialized())) {
return; // Nothing more to do.
}
// Materialize an alternate in the equivalence set that
// |output_info| is leaving.
if (output_info->materialized()) {
CreateMaterializedEquivalent(output_info);
}
// Add |output_info| to new equivalence set.
if (!in_same_equivalence_set) {
AddToEquivalenceSet(input_info, output_info);
}
if (output_is_observable) {
// Force store to be emitted when register is observable.
output_info->set_materialized(false);
RegisterInfo* materialized_info = input_info->GetMaterializedEquivalent();
OutputRegisterTransfer(materialized_info, output_info);
}
bool input_is_observable = RegisterIsObservable(input_info->register_value());
if (input_is_observable) {
// If input is observable by the debugger, mark all other temporaries
// registers as unmaterialized so that this register is used in preference.
input_info->MarkTemporariesAsUnmaterialized(temporary_base_);
}
}
void BytecodeRegisterOptimizer::PrepareOutputRegister(Register reg) {
RegisterInfo* reg_info = GetRegisterInfo(reg);
if (reg_info->materialized()) {
CreateMaterializedEquivalent(reg_info);
}
reg_info->MoveToNewEquivalenceSet(NextEquivalenceId(), true);
max_register_index_ =
std::max(max_register_index_, reg_info->register_value().index());
}
void BytecodeRegisterOptimizer::PrepareOutputRegisterList(
RegisterList reg_list) {
int start_index = reg_list.first_register().index();
for (int i = 0; i < reg_list.register_count(); ++i) {
Register current(start_index + i);
PrepareOutputRegister(current);
}
}
Register BytecodeRegisterOptimizer::GetInputRegister(Register reg) {
RegisterInfo* reg_info = GetRegisterInfo(reg);
if (reg_info->materialized()) {
return reg;
} else {
RegisterInfo* equivalent_info =
GetMaterializedEquivalentNotAccumulator(reg_info);
return equivalent_info->register_value();
}
}
RegisterList BytecodeRegisterOptimizer::GetInputRegisterList(
RegisterList reg_list) {
if (reg_list.register_count() == 1) {
// If there is only a single register, treat it as a normal input register.
Register reg(GetInputRegister(reg_list.first_register()));
return RegisterList(reg.index(), 1);
} else {
int start_index = reg_list.first_register().index();
for (int i = 0; i < reg_list.register_count(); ++i) {
Register current(start_index + i);
RegisterInfo* input_info = GetRegisterInfo(current);
Materialize(input_info);
}
return reg_list;
}
}
void BytecodeRegisterOptimizer::GrowRegisterMap(Register reg) {
DCHECK(RegisterIsTemporary(reg));
size_t index = GetRegisterInfoTableIndex(reg);
if (index >= register_info_table_.size()) {
size_t new_size = index + 1;
size_t old_size = register_info_table_.size();
register_info_table_.resize(new_size);
for (size_t i = old_size; i < new_size; ++i) {
register_info_table_[i] =
new (zone()) RegisterInfo(RegisterFromRegisterInfoTableIndex(i),
NextEquivalenceId(), true, false);
}
}
}
void BytecodeRegisterOptimizer::AllocateRegister(RegisterInfo* info) {
info->set_allocated(true);
if (!info->materialized()) {
info->MoveToNewEquivalenceSet(NextEquivalenceId(), true);
}
}
void BytecodeRegisterOptimizer::RegisterAllocateEvent(Register reg) {
AllocateRegister(GetOrCreateRegisterInfo(reg));
}
void BytecodeRegisterOptimizer::RegisterListAllocateEvent(
RegisterList reg_list) {
if (reg_list.register_count() != 0) {
int first_index = reg_list.first_register().index();
GrowRegisterMap(Register(first_index + reg_list.register_count() - 1));
for (int i = 0; i < reg_list.register_count(); i++) {
AllocateRegister(GetRegisterInfo(Register(first_index + i)));
}
}
}
void BytecodeRegisterOptimizer::RegisterListFreeEvent(RegisterList reg_list) {
int first_index = reg_list.first_register().index();
for (int i = 0; i < reg_list.register_count(); i++) {
GetRegisterInfo(Register(first_index + i))->set_allocated(false);
}
}
} // namespace interpreter
} // namespace internal
} // namespace v8