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gerrit-public.fairphone.software / fp2-dev / platform / external / v8 / refs/tags/fp2-sibon-18.03.1 / . / src / compiler / escape-analysis.cc
blob: 9409a271daaffb7bbd87caa73c6684022a550bc8 [file] [log] [blame]
// Copyright 2015 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/compiler/escape-analysis.h"
#include <limits>
#include "src/base/flags.h"
#include "src/bootstrapper.h"
#include "src/compilation-dependencies.h"
#include "src/compiler/common-operator.h"
#include "src/compiler/graph-reducer.h"
#include "src/compiler/js-operator.h"
#include "src/compiler/node.h"
#include "src/compiler/node-matchers.h"
#include "src/compiler/node-properties.h"
#include "src/compiler/operator-properties.h"
#include "src/compiler/simplified-operator.h"
#include "src/objects-inl.h"
#include "src/type-cache.h"
namespace v8 {
namespace internal {
namespace compiler {
typedef NodeId Alias;
#ifdef DEBUG
#define TRACE(...) \
do { \
if (FLAG_trace_turbo_escape) PrintF(__VA_ARGS__); \
} while (false)
#else
#define TRACE(...)
#endif
// EscapeStatusAnalysis determines for each allocation whether it escapes.
class EscapeStatusAnalysis : public ZoneObject {
public:
enum Status {
kUnknown = 0u,
kTracked = 1u << 0,
kEscaped = 1u << 1,
kOnStack = 1u << 2,
kVisited = 1u << 3,
// A node is dangling, if it is a load of some kind, and does not have
// an effect successor.
kDanglingComputed = 1u << 4,
kDangling = 1u << 5,
// A node is is an effect branch point, if it has more than 2 non-dangling
// effect successors.
kBranchPointComputed = 1u << 6,
kBranchPoint = 1u << 7,
kInQueue = 1u << 8
};
typedef base::Flags<Status, uint16_t> StatusFlags;
void RunStatusAnalysis();
bool IsVirtual(Node* node);
bool IsEscaped(Node* node);
bool IsAllocation(Node* node);
bool IsInQueue(NodeId id);
void SetInQueue(NodeId id, bool on_stack);
void DebugPrint();
EscapeStatusAnalysis(EscapeAnalysis* object_analysis, Graph* graph,
Zone* zone);
void EnqueueForStatusAnalysis(Node* node);
bool SetEscaped(Node* node);
bool IsEffectBranchPoint(Node* node);
bool IsDanglingEffectNode(Node* node);
void ResizeStatusVector();
size_t GetStatusVectorSize();
bool IsVirtual(NodeId id);
Graph* graph() const { return graph_; }
void AssignAliases();
Alias GetAlias(NodeId id) const { return aliases_[id]; }
const ZoneVector<Alias>& GetAliasMap() const { return aliases_; }
Alias AliasCount() const { return next_free_alias_; }
static const Alias kNotReachable;
static const Alias kUntrackable;
bool IsNotReachable(Node* node);
private:
void Process(Node* node);
void ProcessAllocate(Node* node);
void ProcessFinishRegion(Node* node);
void ProcessStoreField(Node* node);
void ProcessStoreElement(Node* node);
bool CheckUsesForEscape(Node* node, bool phi_escaping = false) {
return CheckUsesForEscape(node, node, phi_escaping);
}
bool CheckUsesForEscape(Node* node, Node* rep, bool phi_escaping = false);
void RevisitUses(Node* node);
void RevisitInputs(Node* node);
Alias NextAlias() { return next_free_alias_++; }
bool HasEntry(Node* node);
bool IsAllocationPhi(Node* node);
ZoneVector<Node*> stack_;
EscapeAnalysis* object_analysis_;
Graph* const graph_;
ZoneVector<StatusFlags> status_;
Alias next_free_alias_;
ZoneVector<Node*> status_stack_;
ZoneVector<Alias> aliases_;
DISALLOW_COPY_AND_ASSIGN(EscapeStatusAnalysis);
};
DEFINE_OPERATORS_FOR_FLAGS(EscapeStatusAnalysis::StatusFlags)
const Alias EscapeStatusAnalysis::kNotReachable =
std::numeric_limits<Alias>::max();
const Alias EscapeStatusAnalysis::kUntrackable =
std::numeric_limits<Alias>::max() - 1;
class VirtualObject : public ZoneObject {
public:
enum Status {
kInitial = 0,
kTracked = 1u << 0,
kInitialized = 1u << 1,
kCopyRequired = 1u << 2,
};
typedef base::Flags<Status, unsigned char> StatusFlags;
VirtualObject(NodeId id, VirtualState* owner, Zone* zone)
: id_(id),
status_(kInitial),
fields_(zone),
phi_(zone),
object_state_(nullptr),
owner_(owner) {}
VirtualObject(VirtualState* owner, const VirtualObject& other)
: id_(other.id_),
status_(other.status_ & ~kCopyRequired),
fields_(other.fields_),
phi_(other.phi_),
object_state_(other.object_state_),
owner_(owner) {}
VirtualObject(NodeId id, VirtualState* owner, Zone* zone, size_t field_number,
bool initialized)
: id_(id),
status_(kTracked | (initialized ? kInitialized : kInitial)),
fields_(zone),
phi_(zone),
object_state_(nullptr),
owner_(owner) {
fields_.resize(field_number);
phi_.resize(field_number, false);
}
Node* GetField(size_t offset) { return fields_[offset]; }
bool IsCreatedPhi(size_t offset) { return phi_[offset]; }
void SetField(size_t offset, Node* node, bool created_phi = false) {
fields_[offset] = node;
phi_[offset] = created_phi;
}
bool IsTracked() const { return status_ & kTracked; }
bool IsInitialized() const { return status_ & kInitialized; }
bool SetInitialized() { return status_ |= kInitialized; }
VirtualState* owner() const { return owner_; }
Node** fields_array() { return &fields_.front(); }
size_t field_count() { return fields_.size(); }
bool ResizeFields(size_t field_count) {
if (field_count > fields_.size()) {
fields_.resize(field_count);
phi_.resize(field_count);
return true;
}
return false;
}
void ClearAllFields() {
for (size_t i = 0; i < fields_.size(); ++i) {
fields_[i] = nullptr;
phi_[i] = false;
}
}
bool AllFieldsClear() {
for (size_t i = 0; i < fields_.size(); ++i) {
if (fields_[i] != nullptr) {
return false;
}
}
return true;
}
bool UpdateFrom(const VirtualObject& other);
bool MergeFrom(MergeCache* cache, Node* at, Graph* graph,
CommonOperatorBuilder* common);
void SetObjectState(Node* node) { object_state_ = node; }
Node* GetObjectState() const { return object_state_; }
bool IsCopyRequired() const { return status_ & kCopyRequired; }
void SetCopyRequired() { status_ |= kCopyRequired; }
bool NeedCopyForModification() {
if (!IsCopyRequired() || !IsInitialized()) {
return false;
}
return true;
}
NodeId id() const { return id_; }
void id(NodeId id) { id_ = id; }
private:
bool MergeFields(size_t i, Node* at, MergeCache* cache, Graph* graph,
CommonOperatorBuilder* common);
NodeId id_;
StatusFlags status_;
ZoneVector<Node*> fields_;
ZoneVector<bool> phi_;
Node* object_state_;
VirtualState* owner_;
DISALLOW_COPY_AND_ASSIGN(VirtualObject);
};
DEFINE_OPERATORS_FOR_FLAGS(VirtualObject::StatusFlags)
bool VirtualObject::UpdateFrom(const VirtualObject& other) {
bool changed = status_ != other.status_;
status_ = other.status_;
phi_ = other.phi_;
if (fields_.size() != other.fields_.size()) {
fields_ = other.fields_;
return true;
}
for (size_t i = 0; i < fields_.size(); ++i) {
if (fields_[i] != other.fields_[i]) {
changed = true;
fields_[i] = other.fields_[i];
}
}
return changed;
}
class VirtualState : public ZoneObject {
public:
VirtualState(Node* owner, Zone* zone, size_t size)
: info_(size, nullptr, zone), owner_(owner) {}
VirtualState(Node* owner, const VirtualState& state)
: info_(state.info_.size(), nullptr, state.info_.get_allocator().zone()),
owner_(owner) {
for (size_t i = 0; i < info_.size(); ++i) {
if (state.info_[i]) {
info_[i] = state.info_[i];
}
}
}
VirtualObject* VirtualObjectFromAlias(size_t alias);
void SetVirtualObject(Alias alias, VirtualObject* state);
bool UpdateFrom(VirtualState* state, Zone* zone);
bool MergeFrom(MergeCache* cache, Zone* zone, Graph* graph,
CommonOperatorBuilder* common, Node* at);
size_t size() const { return info_.size(); }
Node* owner() const { return owner_; }
VirtualObject* Copy(VirtualObject* obj, Alias alias);
void SetCopyRequired() {
for (VirtualObject* obj : info_) {
if (obj) obj->SetCopyRequired();
}
}
private:
ZoneVector<VirtualObject*> info_;
Node* owner_;
DISALLOW_COPY_AND_ASSIGN(VirtualState);
};
class MergeCache : public ZoneObject {
public:
explicit MergeCache(Zone* zone)
: states_(zone), objects_(zone), fields_(zone) {
states_.reserve(5);
objects_.reserve(5);
fields_.reserve(5);
}
ZoneVector<VirtualState*>& states() { return states_; }
ZoneVector<VirtualObject*>& objects() { return objects_; }
ZoneVector<Node*>& fields() { return fields_; }
void Clear() {
states_.clear();
objects_.clear();
fields_.clear();
}
size_t LoadVirtualObjectsFromStatesFor(Alias alias);
void LoadVirtualObjectsForFieldsFrom(VirtualState* state,
const ZoneVector<Alias>& aliases);
Node* GetFields(size_t pos);
private:
ZoneVector<VirtualState*> states_;
ZoneVector<VirtualObject*> objects_;
ZoneVector<Node*> fields_;
DISALLOW_COPY_AND_ASSIGN(MergeCache);
};
size_t MergeCache::LoadVirtualObjectsFromStatesFor(Alias alias) {
objects_.clear();
DCHECK_GT(states_.size(), 0u);
size_t min = std::numeric_limits<size_t>::max();
for (VirtualState* state : states_) {
if (VirtualObject* obj = state->VirtualObjectFromAlias(alias)) {
objects_.push_back(obj);
min = std::min(obj->field_count(), min);
}
}
return min;
}
void MergeCache::LoadVirtualObjectsForFieldsFrom(
VirtualState* state, const ZoneVector<Alias>& aliases) {
objects_.clear();
size_t max_alias = state->size();
for (Node* field : fields_) {
Alias alias = aliases[field->id()];
if (alias >= max_alias) continue;
if (VirtualObject* obj = state->VirtualObjectFromAlias(alias)) {
objects_.push_back(obj);
}
}
}
Node* MergeCache::GetFields(size_t pos) {
fields_.clear();
Node* rep = pos >= objects_.front()->field_count()
? nullptr
: objects_.front()->GetField(pos);
for (VirtualObject* obj : objects_) {
if (pos >= obj->field_count()) continue;
Node* field = obj->GetField(pos);
if (field) {
fields_.push_back(field);
}
if (field != rep) {
rep = nullptr;
}
}
return rep;
}
VirtualObject* VirtualState::Copy(VirtualObject* obj, Alias alias) {
if (obj->owner() == this) return obj;
VirtualObject* new_obj =
new (info_.get_allocator().zone()) VirtualObject(this, *obj);
TRACE("At state %p, alias @%d (#%d), copying virtual object from %p to %p\n",
static_cast<void*>(this), alias, obj->id(), static_cast<void*>(obj),
static_cast<void*>(new_obj));
info_[alias] = new_obj;
return new_obj;
}
VirtualObject* VirtualState::VirtualObjectFromAlias(size_t alias) {
return info_[alias];
}
void VirtualState::SetVirtualObject(Alias alias, VirtualObject* obj) {
info_[alias] = obj;
}
bool VirtualState::UpdateFrom(VirtualState* from, Zone* zone) {
if (from == this) return false;
bool changed = false;
for (Alias alias = 0; alias < size(); ++alias) {
VirtualObject* ls = VirtualObjectFromAlias(alias);
VirtualObject* rs = from->VirtualObjectFromAlias(alias);
if (ls == rs || rs == nullptr) continue;
if (ls == nullptr) {
ls = new (zone) VirtualObject(this, *rs);
SetVirtualObject(alias, ls);
changed = true;
continue;
}
TRACE(" Updating fields of @%d\n", alias);
changed = ls->UpdateFrom(*rs) || changed;
}
return false;
}
namespace {
bool IsEquivalentPhi(Node* node1, Node* node2) {
if (node1 == node2) return true;
if (node1->opcode() != IrOpcode::kPhi || node2->opcode() != IrOpcode::kPhi ||
node1->op()->ValueInputCount() != node2->op()->ValueInputCount()) {
return false;
}
for (int i = 0; i < node1->op()->ValueInputCount(); ++i) {
Node* input1 = NodeProperties::GetValueInput(node1, i);
Node* input2 = NodeProperties::GetValueInput(node2, i);
if (!IsEquivalentPhi(input1, input2)) {
return false;
}
}
return true;
}
bool IsEquivalentPhi(Node* phi, ZoneVector<Node*>& inputs) {
if (phi->opcode() != IrOpcode::kPhi) return false;
if (phi->op()->ValueInputCount() != inputs.size()) {
return false;
}
for (size_t i = 0; i < inputs.size(); ++i) {
Node* input = NodeProperties::GetValueInput(phi, static_cast<int>(i));
if (!IsEquivalentPhi(input, inputs[i])) {
return false;
}
}
return true;
}
} // namespace
bool VirtualObject::MergeFields(size_t i, Node* at, MergeCache* cache,
Graph* graph, CommonOperatorBuilder* common) {
bool changed = false;
int value_input_count = static_cast<int>(cache->fields().size());
Node* rep = GetField(i);
if (!rep || !IsCreatedPhi(i)) {
Node* control = NodeProperties::GetControlInput(at);
cache->fields().push_back(control);
Node* phi = graph->NewNode(
common->Phi(MachineRepresentation::kTagged, value_input_count),
value_input_count + 1, &cache->fields().front());
SetField(i, phi, true);
#ifdef DEBUG
if (FLAG_trace_turbo_escape) {
PrintF(" Creating Phi #%d as merge of", phi->id());
for (int i = 0; i < value_input_count; i++) {
PrintF(" #%d (%s)", cache->fields()[i]->id(),
cache->fields()[i]->op()->mnemonic());
}
PrintF("\n");
}
#endif
changed = true;
} else {
DCHECK(rep->opcode() == IrOpcode::kPhi);
for (int n = 0; n < value_input_count; ++n) {
Node* old = NodeProperties::GetValueInput(rep, n);
if (old != cache->fields()[n]) {
changed = true;
NodeProperties::ReplaceValueInput(rep, cache->fields()[n], n);
}
}
}
return changed;
}
bool VirtualObject::MergeFrom(MergeCache* cache, Node* at, Graph* graph,
CommonOperatorBuilder* common) {
DCHECK(at->opcode() == IrOpcode::kEffectPhi ||
at->opcode() == IrOpcode::kPhi);
bool changed = false;
for (size_t i = 0; i < field_count(); ++i) {
if (Node* field = cache->GetFields(i)) {
changed = changed || GetField(i) != field;
SetField(i, field);
TRACE(" Field %zu agree on rep #%d\n", i, field->id());
} else {
int arity = at->opcode() == IrOpcode::kEffectPhi
? at->op()->EffectInputCount()
: at->op()->ValueInputCount();
if (cache->fields().size() == arity) {
changed = MergeFields(i, at, cache, graph, common) || changed;
} else {
if (GetField(i) != nullptr) {
TRACE(" Field %zu cleared\n", i);
changed = true;
}
SetField(i, nullptr);
}
}
}
return changed;
}
bool VirtualState::MergeFrom(MergeCache* cache, Zone* zone, Graph* graph,
CommonOperatorBuilder* common, Node* at) {
DCHECK_GT(cache->states().size(), 0u);
bool changed = false;
for (Alias alias = 0; alias < size(); ++alias) {
cache->objects().clear();
VirtualObject* mergeObject = VirtualObjectFromAlias(alias);
bool copy_merge_object = false;
size_t fields = std::numeric_limits<size_t>::max();
for (VirtualState* state : cache->states()) {
if (VirtualObject* obj = state->VirtualObjectFromAlias(alias)) {
cache->objects().push_back(obj);
if (mergeObject == obj) {
copy_merge_object = true;
}
fields = std::min(obj->field_count(), fields);
}
}
if (cache->objects().size() == cache->states().size()) {
if (!mergeObject) {
VirtualObject* obj = new (zone)
VirtualObject(cache->objects().front()->id(), this, zone, fields,
cache->objects().front()->IsInitialized());
SetVirtualObject(alias, obj);
mergeObject = obj;
changed = true;
} else if (copy_merge_object) {
VirtualObject* obj = new (zone) VirtualObject(this, *mergeObject);
SetVirtualObject(alias, obj);
mergeObject = obj;
changed = true;
} else {
changed = mergeObject->ResizeFields(fields) || changed;
}
#ifdef DEBUG
if (FLAG_trace_turbo_escape) {
PrintF(" Alias @%d, merging into %p virtual objects", alias,
static_cast<void*>(mergeObject));
for (size_t i = 0; i < cache->objects().size(); i++) {
PrintF(" %p", static_cast<void*>(cache->objects()[i]));
}
PrintF("\n");
}
#endif // DEBUG
changed = mergeObject->MergeFrom(cache, at, graph, common) || changed;
} else {
if (mergeObject) {
TRACE(" Alias %d, virtual object removed\n", alias);
changed = true;
}
SetVirtualObject(alias, nullptr);
}
}
return changed;
}
EscapeStatusAnalysis::EscapeStatusAnalysis(EscapeAnalysis* object_analysis,
Graph* graph, Zone* zone)
: stack_(zone),
object_analysis_(object_analysis),
graph_(graph),
status_(zone),
next_free_alias_(0),
status_stack_(zone),
aliases_(zone) {}
bool EscapeStatusAnalysis::HasEntry(Node* node) {
return status_[node->id()] & (kTracked | kEscaped);
}
bool EscapeStatusAnalysis::IsVirtual(Node* node) {
return IsVirtual(node->id());
}
bool EscapeStatusAnalysis::IsVirtual(NodeId id) {
return (status_[id] & kTracked) && !(status_[id] & kEscaped);
}
bool EscapeStatusAnalysis::IsEscaped(Node* node) {
return status_[node->id()] & kEscaped;
}
bool EscapeStatusAnalysis::IsAllocation(Node* node) {
return node->opcode() == IrOpcode::kAllocate ||
node->opcode() == IrOpcode::kFinishRegion;
}
bool EscapeStatusAnalysis::SetEscaped(Node* node) {
bool changed = !(status_[node->id()] & kEscaped);
status_[node->id()] |= kEscaped | kTracked;
return changed;
}
bool EscapeStatusAnalysis::IsInQueue(NodeId id) {
return status_[id] & kInQueue;
}
void EscapeStatusAnalysis::SetInQueue(NodeId id, bool on_stack) {
if (on_stack) {
status_[id] |= kInQueue;
} else {
status_[id] &= ~kInQueue;
}
}
void EscapeStatusAnalysis::ResizeStatusVector() {
if (status_.size() <= graph()->NodeCount()) {
status_.resize(graph()->NodeCount() * 1.1, kUnknown);
}
}
size_t EscapeStatusAnalysis::GetStatusVectorSize() { return status_.size(); }
void EscapeStatusAnalysis::RunStatusAnalysis() {
ResizeStatusVector();
while (!status_stack_.empty()) {
Node* node = status_stack_.back();
status_stack_.pop_back();
status_[node->id()] &= ~kOnStack;
Process(node);
status_[node->id()] |= kVisited;
}
}
void EscapeStatusAnalysis::EnqueueForStatusAnalysis(Node* node) {
DCHECK_NOT_NULL(node);
if (!(status_[node->id()] & kOnStack)) {
status_stack_.push_back(node);
status_[node->id()] |= kOnStack;
}
}
void EscapeStatusAnalysis::RevisitInputs(Node* node) {
for (Edge edge : node->input_edges()) {
Node* input = edge.to();
if (!(status_[input->id()] & kOnStack)) {
status_stack_.push_back(input);
status_[input->id()] |= kOnStack;
}
}
}
void EscapeStatusAnalysis::RevisitUses(Node* node) {
for (Edge edge : node->use_edges()) {
Node* use = edge.from();
if (!(status_[use->id()] & kOnStack) && !IsNotReachable(use)) {
status_stack_.push_back(use);
status_[use->id()] |= kOnStack;
}
}
}
void EscapeStatusAnalysis::Process(Node* node) {
switch (node->opcode()) {
case IrOpcode::kAllocate:
ProcessAllocate(node);
break;
case IrOpcode::kFinishRegion:
ProcessFinishRegion(node);
break;
case IrOpcode::kStoreField:
ProcessStoreField(node);
break;
case IrOpcode::kStoreElement:
ProcessStoreElement(node);
break;
case IrOpcode::kLoadField:
case IrOpcode::kLoadElement: {
if (Node* rep = object_analysis_->GetReplacement(node)) {
if (IsAllocation(rep) && CheckUsesForEscape(node, rep)) {
RevisitInputs(rep);
RevisitUses(rep);
}
}
RevisitUses(node);
break;
}
case IrOpcode::kPhi:
if (!HasEntry(node)) {
status_[node->id()] |= kTracked;
RevisitUses(node);
}
if (!IsAllocationPhi(node) && SetEscaped(node)) {
RevisitInputs(node);
RevisitUses(node);
}
CheckUsesForEscape(node);
default:
break;
}
}
bool EscapeStatusAnalysis::IsAllocationPhi(Node* node) {
for (Edge edge : node->input_edges()) {
Node* input = edge.to();
if (input->opcode() == IrOpcode::kPhi && !IsEscaped(input)) continue;
if (IsAllocation(input)) continue;
return false;
}
return true;
}
void EscapeStatusAnalysis::ProcessStoreField(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kStoreField);
Node* to = NodeProperties::GetValueInput(node, 0);
Node* val = NodeProperties::GetValueInput(node, 1);
if ((IsEscaped(to) || !IsAllocation(to)) && SetEscaped(val)) {
RevisitUses(val);
RevisitInputs(val);
TRACE("Setting #%d (%s) to escaped because of store to field of #%d\n",
val->id(), val->op()->mnemonic(), to->id());
}
}
void EscapeStatusAnalysis::ProcessStoreElement(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kStoreElement);
Node* to = NodeProperties::GetValueInput(node, 0);
Node* val = NodeProperties::GetValueInput(node, 2);
if ((IsEscaped(to) || !IsAllocation(to)) && SetEscaped(val)) {
RevisitUses(val);
RevisitInputs(val);
TRACE("Setting #%d (%s) to escaped because of store to field of #%d\n",
val->id(), val->op()->mnemonic(), to->id());
}
}
void EscapeStatusAnalysis::ProcessAllocate(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kAllocate);
if (!HasEntry(node)) {
status_[node->id()] |= kTracked;
TRACE("Created status entry for node #%d (%s)\n", node->id(),
node->op()->mnemonic());
NumberMatcher size(node->InputAt(0));
DCHECK(node->InputAt(0)->opcode() != IrOpcode::kInt32Constant &&
node->InputAt(0)->opcode() != IrOpcode::kInt64Constant &&
node->InputAt(0)->opcode() != IrOpcode::kFloat32Constant &&
node->InputAt(0)->opcode() != IrOpcode::kFloat64Constant);
RevisitUses(node);
if (!size.HasValue() && SetEscaped(node)) {
TRACE("Setting #%d to escaped because of non-const alloc\n", node->id());
// This node is already known to escape, uses do not have to be checked
// for escape.
return;
}
}
if (CheckUsesForEscape(node, true)) {
RevisitUses(node);
}
}
bool EscapeStatusAnalysis::CheckUsesForEscape(Node* uses, Node* rep,
bool phi_escaping) {
for (Edge edge : uses->use_edges()) {
Node* use = edge.from();
if (IsNotReachable(use)) continue;
if (edge.index() >= use->op()->ValueInputCount() +
OperatorProperties::GetContextInputCount(use->op()))
continue;
switch (use->opcode()) {
case IrOpcode::kPhi:
if (phi_escaping && SetEscaped(rep)) {
TRACE(
"Setting #%d (%s) to escaped because of use by phi node "
"#%d (%s)\n",
rep->id(), rep->op()->mnemonic(), use->id(),
use->op()->mnemonic());
return true;
}
// Fallthrough.
case IrOpcode::kStoreField:
case IrOpcode::kLoadField:
case IrOpcode::kStoreElement:
case IrOpcode::kLoadElement:
case IrOpcode::kFrameState:
case IrOpcode::kStateValues:
case IrOpcode::kReferenceEqual:
case IrOpcode::kFinishRegion:
if (IsEscaped(use) && SetEscaped(rep)) {
TRACE(
"Setting #%d (%s) to escaped because of use by escaping node "
"#%d (%s)\n",
rep->id(), rep->op()->mnemonic(), use->id(),
use->op()->mnemonic());
return true;
}
break;
case IrOpcode::kObjectIsSmi:
if (!IsAllocation(rep) && SetEscaped(rep)) {
TRACE("Setting #%d (%s) to escaped because of use by #%d (%s)\n",
rep->id(), rep->op()->mnemonic(), use->id(),
use->op()->mnemonic());
return true;
}
break;
case IrOpcode::kSelect:
case IrOpcode::kTypeGuard:
// TODO(mstarzinger): The following list of operators will eventually be
// handled by the EscapeAnalysisReducer (similar to ObjectIsSmi).
case IrOpcode::kObjectIsCallable:
case IrOpcode::kObjectIsNumber:
case IrOpcode::kObjectIsString:
case IrOpcode::kObjectIsUndetectable:
if (SetEscaped(rep)) {
TRACE("Setting #%d (%s) to escaped because of use by #%d (%s)\n",
rep->id(), rep->op()->mnemonic(), use->id(),
use->op()->mnemonic());
return true;
}
break;
default:
if (use->op()->EffectInputCount() == 0 &&
uses->op()->EffectInputCount() > 0 &&
!IrOpcode::IsJsOpcode(use->opcode())) {
TRACE("Encountered unaccounted use by #%d (%s)\n", use->id(),
use->op()->mnemonic());
UNREACHABLE();
}
if (SetEscaped(rep)) {
TRACE("Setting #%d (%s) to escaped because of use by #%d (%s)\n",
rep->id(), rep->op()->mnemonic(), use->id(),
use->op()->mnemonic());
return true;
}
}
}
return false;
}
void EscapeStatusAnalysis::ProcessFinishRegion(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kFinishRegion);
if (!HasEntry(node)) {
status_[node->id()] |= kTracked;
RevisitUses(node);
}
if (CheckUsesForEscape(node, true)) {
RevisitInputs(node);
}
}
void EscapeStatusAnalysis::DebugPrint() {
for (NodeId id = 0; id < status_.size(); id++) {
if (status_[id] & kTracked) {
PrintF("Node #%d is %s\n", id,
(status_[id] & kEscaped) ? "escaping" : "virtual");
}
}
}
EscapeAnalysis::EscapeAnalysis(Graph* graph, CommonOperatorBuilder* common,
Zone* zone)
: zone_(zone),
slot_not_analyzed_(graph->NewNode(common->NumberConstant(0x1c0debad))),
common_(common),
status_analysis_(new (zone) EscapeStatusAnalysis(this, graph, zone)),
virtual_states_(zone),
replacements_(zone),
cache_(nullptr) {}
EscapeAnalysis::~EscapeAnalysis() {}
void EscapeAnalysis::Run() {
replacements_.resize(graph()->NodeCount());
status_analysis_->AssignAliases();
if (status_analysis_->AliasCount() > 0) {
cache_ = new (zone()) MergeCache(zone());
replacements_.resize(graph()->NodeCount());
status_analysis_->ResizeStatusVector();
RunObjectAnalysis();
status_analysis_->RunStatusAnalysis();
}
}
void EscapeStatusAnalysis::AssignAliases() {
size_t max_size = 1024;
size_t min_size = 32;
size_t stack_size =
std::min(std::max(graph()->NodeCount() / 5, min_size), max_size);
stack_.reserve(stack_size);
ResizeStatusVector();
stack_.push_back(graph()->end());
CHECK_LT(graph()->NodeCount(), kUntrackable);
aliases_.resize(graph()->NodeCount(), kNotReachable);
aliases_[graph()->end()->id()] = kUntrackable;
status_stack_.reserve(8);
TRACE("Discovering trackable nodes");
while (!stack_.empty()) {
Node* node = stack_.back();
stack_.pop_back();
switch (node->opcode()) {
case IrOpcode::kAllocate:
if (aliases_[node->id()] >= kUntrackable) {
aliases_[node->id()] = NextAlias();
TRACE(" @%d:%s#%u", aliases_[node->id()], node->op()->mnemonic(),
node->id());
EnqueueForStatusAnalysis(node);
}
break;
case IrOpcode::kFinishRegion: {
Node* allocate = NodeProperties::GetValueInput(node, 0);
DCHECK_NOT_NULL(allocate);
if (allocate->opcode() == IrOpcode::kAllocate) {
if (aliases_[allocate->id()] >= kUntrackable) {
if (aliases_[allocate->id()] == kNotReachable) {
stack_.push_back(allocate);
}
aliases_[allocate->id()] = NextAlias();
TRACE(" @%d:%s#%u", aliases_[allocate->id()],
allocate->op()->mnemonic(), allocate->id());
EnqueueForStatusAnalysis(allocate);
}
aliases_[node->id()] = aliases_[allocate->id()];
TRACE(" @%d:%s#%u", aliases_[node->id()], node->op()->mnemonic(),
node->id());
}
break;
}
default:
DCHECK_EQ(aliases_[node->id()], kUntrackable);
break;
}
for (Edge edge : node->input_edges()) {
Node* input = edge.to();
if (aliases_[input->id()] == kNotReachable) {
stack_.push_back(input);
aliases_[input->id()] = kUntrackable;
}
}
}
TRACE("\n");
}
bool EscapeStatusAnalysis::IsNotReachable(Node* node) {
if (node->id() >= aliases_.size()) {
return false;
}
return aliases_[node->id()] == kNotReachable;
}
void EscapeAnalysis::RunObjectAnalysis() {
virtual_states_.resize(graph()->NodeCount());
ZoneDeque<Node*> queue(zone());
queue.push_back(graph()->start());
ZoneVector<Node*> danglers(zone());
while (!queue.empty()) {
Node* node = queue.back();
queue.pop_back();
status_analysis_->SetInQueue(node->id(), false);
if (Process(node)) {
for (Edge edge : node->use_edges()) {
Node* use = edge.from();
if (status_analysis_->IsNotReachable(use)) {
continue;
}
if (NodeProperties::IsEffectEdge(edge)) {
// Iteration order: depth first, but delay phis.
// We need DFS do avoid some duplication of VirtualStates and
// VirtualObjects, and we want to delay phis to improve performance.
if (use->opcode() == IrOpcode::kEffectPhi) {
if (!status_analysis_->IsInQueue(use->id())) {
queue.push_front(use);
}
} else if ((use->opcode() != IrOpcode::kLoadField &&
use->opcode() != IrOpcode::kLoadElement) ||
!status_analysis_->IsDanglingEffectNode(use)) {
if (!status_analysis_->IsInQueue(use->id())) {
status_analysis_->SetInQueue(use->id(), true);
queue.push_back(use);
}
} else {
danglers.push_back(use);
}
}
}
// Danglers need to be processed immediately, even if they are
// on the stack. Since they do not have effect outputs,
// we don't have to track whether they are on the stack.
queue.insert(queue.end(), danglers.begin(), danglers.end());
danglers.clear();
}
}
#ifdef DEBUG
if (FLAG_trace_turbo_escape) {
DebugPrint();
}
#endif
}
bool EscapeStatusAnalysis::IsDanglingEffectNode(Node* node) {
if (status_[node->id()] & kDanglingComputed) {
return status_[node->id()] & kDangling;
}
if (node->op()->EffectInputCount() == 0 ||
node->op()->EffectOutputCount() == 0 ||
(node->op()->EffectInputCount() == 1 &&
NodeProperties::GetEffectInput(node)->opcode() == IrOpcode::kStart)) {
// The start node is used as sentinel for nodes that are in general
// effectful, but of which an analysis has determined that they do not
// produce effects in this instance. We don't consider these nodes dangling.
status_[node->id()] |= kDanglingComputed;
return false;
}
for (Edge edge : node->use_edges()) {
Node* use = edge.from();
if (aliases_[use->id()] == kNotReachable) continue;
if (NodeProperties::IsEffectEdge(edge)) {
status_[node->id()] |= kDanglingComputed;
return false;
}
}
status_[node->id()] |= kDanglingComputed | kDangling;
return true;
}
bool EscapeStatusAnalysis::IsEffectBranchPoint(Node* node) {
if (status_[node->id()] & kBranchPointComputed) {
return status_[node->id()] & kBranchPoint;
}
int count = 0;
for (Edge edge : node->use_edges()) {
Node* use = edge.from();
if (aliases_[use->id()] == kNotReachable) continue;
if (NodeProperties::IsEffectEdge(edge)) {
if ((use->opcode() == IrOpcode::kLoadField ||
use->opcode() == IrOpcode::kLoadElement ||
use->opcode() == IrOpcode::kLoad) &&
IsDanglingEffectNode(use))
continue;
if (++count > 1) {
status_[node->id()] |= kBranchPointComputed | kBranchPoint;
return true;
}
}
}
status_[node->id()] |= kBranchPointComputed;
return false;
}
bool EscapeAnalysis::Process(Node* node) {
switch (node->opcode()) {
case IrOpcode::kAllocate:
ProcessAllocation(node);
break;
case IrOpcode::kBeginRegion:
ForwardVirtualState(node);
break;
case IrOpcode::kFinishRegion:
ProcessFinishRegion(node);
break;
case IrOpcode::kStoreField:
ProcessStoreField(node);
break;
case IrOpcode::kLoadField:
ProcessLoadField(node);
break;
case IrOpcode::kStoreElement:
ProcessStoreElement(node);
break;
case IrOpcode::kLoadElement:
ProcessLoadElement(node);
break;
case IrOpcode::kStart:
ProcessStart(node);
break;
case IrOpcode::kEffectPhi:
return ProcessEffectPhi(node);
break;
default:
if (node->op()->EffectInputCount() > 0) {
ForwardVirtualState(node);
}
ProcessAllocationUsers(node);
break;
}
return true;
}
void EscapeAnalysis::ProcessAllocationUsers(Node* node) {
for (Edge edge : node->input_edges()) {
Node* input = edge.to();
Node* use = edge.from();
if (edge.index() >= use->op()->ValueInputCount() +
OperatorProperties::GetContextInputCount(use->op()))
continue;
switch (node->opcode()) {
case IrOpcode::kStoreField:
case IrOpcode::kLoadField:
case IrOpcode::kStoreElement:
case IrOpcode::kLoadElement:
case IrOpcode::kFrameState:
case IrOpcode::kStateValues:
case IrOpcode::kReferenceEqual:
case IrOpcode::kFinishRegion:
case IrOpcode::kObjectIsSmi:
break;
default:
VirtualState* state = virtual_states_[node->id()];
if (VirtualObject* obj =
GetVirtualObject(state, ResolveReplacement(input))) {
if (!obj->AllFieldsClear()) {
obj = CopyForModificationAt(obj, state, node);
obj->ClearAllFields();
TRACE("Cleared all fields of @%d:#%d\n",
status_analysis_->GetAlias(obj->id()), obj->id());
}
}
break;
}
}
}
VirtualState* EscapeAnalysis::CopyForModificationAt(VirtualState* state,
Node* node) {
if (state->owner() != node) {
VirtualState* new_state = new (zone()) VirtualState(node, *state);
virtual_states_[node->id()] = new_state;
TRACE("Copying virtual state %p to new state %p at node %s#%d\n",
static_cast<void*>(state), static_cast<void*>(new_state),
node->op()->mnemonic(), node->id());
return new_state;
}
return state;
}
VirtualObject* EscapeAnalysis::CopyForModificationAt(VirtualObject* obj,
VirtualState* state,
Node* node) {
if (obj->NeedCopyForModification()) {
state = CopyForModificationAt(state, node);
return state->Copy(obj, status_analysis_->GetAlias(obj->id()));
}
return obj;
}
void EscapeAnalysis::ForwardVirtualState(Node* node) {
DCHECK_EQ(node->op()->EffectInputCount(), 1);
#ifdef DEBUG
if (node->opcode() != IrOpcode::kLoadField &&
node->opcode() != IrOpcode::kLoadElement &&
node->opcode() != IrOpcode::kLoad &&
status_analysis_->IsDanglingEffectNode(node)) {
PrintF("Dangeling effect node: #%d (%s)\n", node->id(),
node->op()->mnemonic());
UNREACHABLE();
}
#endif // DEBUG
Node* effect = NodeProperties::GetEffectInput(node);
DCHECK_NOT_NULL(virtual_states_[effect->id()]);
if (virtual_states_[node->id()]) {
virtual_states_[node->id()]->UpdateFrom(virtual_states_[effect->id()],
zone());
} else {
virtual_states_[node->id()] = virtual_states_[effect->id()];
TRACE("Forwarding object state %p from %s#%d to %s#%d",
static_cast<void*>(virtual_states_[effect->id()]),
effect->op()->mnemonic(), effect->id(), node->op()->mnemonic(),
node->id());
if (status_analysis_->IsEffectBranchPoint(effect) ||
OperatorProperties::GetFrameStateInputCount(node->op()) > 0) {
virtual_states_[node->id()]->SetCopyRequired();
TRACE(", effect input %s#%d is branch point", effect->op()->mnemonic(),
effect->id());
}
TRACE("\n");
}
}
void EscapeAnalysis::ProcessStart(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kStart);
virtual_states_[node->id()] =
new (zone()) VirtualState(node, zone(), status_analysis_->AliasCount());
}
bool EscapeAnalysis::ProcessEffectPhi(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kEffectPhi);
bool changed = false;
VirtualState* mergeState = virtual_states_[node->id()];
if (!mergeState) {
mergeState =
new (zone()) VirtualState(node, zone(), status_analysis_->AliasCount());
virtual_states_[node->id()] = mergeState;
changed = true;
TRACE("Effect Phi #%d got new virtual state %p.\n", node->id(),
static_cast<void*>(mergeState));
}
cache_->Clear();
TRACE("At Effect Phi #%d, merging states into %p:", node->id(),
static_cast<void*>(mergeState));
for (int i = 0; i < node->op()->EffectInputCount(); ++i) {
Node* input = NodeProperties::GetEffectInput(node, i);
VirtualState* state = virtual_states_[input->id()];
if (state) {
cache_->states().push_back(state);
if (state == mergeState) {
mergeState = new (zone())
VirtualState(node, zone(), status_analysis_->AliasCount());
virtual_states_[node->id()] = mergeState;
changed = true;
}
}
TRACE(" %p (from %d %s)", static_cast<void*>(state), input->id(),
input->op()->mnemonic());
}
TRACE("\n");
if (cache_->states().size() == 0) {
return changed;
}
changed =
mergeState->MergeFrom(cache_, zone(), graph(), common(), node) || changed;
TRACE("Merge %s the node.\n", changed ? "changed" : "did not change");
if (changed) {
status_analysis_->ResizeStatusVector();
}
return changed;
}
void EscapeAnalysis::ProcessAllocation(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kAllocate);
ForwardVirtualState(node);
VirtualState* state = virtual_states_[node->id()];
Alias alias = status_analysis_->GetAlias(node->id());
// Check if we have already processed this node.
if (state->VirtualObjectFromAlias(alias)) {
return;
}
if (state->owner()->opcode() == IrOpcode::kEffectPhi) {
state = CopyForModificationAt(state, node);
}
NumberMatcher size(node->InputAt(0));
DCHECK(node->InputAt(0)->opcode() != IrOpcode::kInt32Constant &&
node->InputAt(0)->opcode() != IrOpcode::kInt64Constant &&
node->InputAt(0)->opcode() != IrOpcode::kFloat32Constant &&
node->InputAt(0)->opcode() != IrOpcode::kFloat64Constant);
if (size.HasValue()) {
VirtualObject* obj = new (zone()) VirtualObject(
node->id(), state, zone(), size.Value() / kPointerSize, false);
state->SetVirtualObject(alias, obj);
} else {
state->SetVirtualObject(
alias, new (zone()) VirtualObject(node->id(), state, zone()));
}
}
void EscapeAnalysis::ProcessFinishRegion(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kFinishRegion);
ForwardVirtualState(node);
Node* allocation = NodeProperties::GetValueInput(node, 0);
if (allocation->opcode() == IrOpcode::kAllocate) {
VirtualState* state = virtual_states_[node->id()];
VirtualObject* obj =
state->VirtualObjectFromAlias(status_analysis_->GetAlias(node->id()));
DCHECK_NOT_NULL(obj);
obj->SetInitialized();
}
}
Node* EscapeAnalysis::replacement(Node* node) {
if (node->id() >= replacements_.size()) return nullptr;
return replacements_[node->id()];
}
bool EscapeAnalysis::SetReplacement(Node* node, Node* rep) {
bool changed = replacements_[node->id()] != rep;
replacements_[node->id()] = rep;
return changed;
}
bool EscapeAnalysis::UpdateReplacement(VirtualState* state, Node* node,
Node* rep) {
if (SetReplacement(node, rep)) {
if (rep) {
TRACE("Replacement of #%d is #%d (%s)\n", node->id(), rep->id(),
rep->op()->mnemonic());
} else {
TRACE("Replacement of #%d cleared\n", node->id());
}
return true;
}
return false;
}
Node* EscapeAnalysis::ResolveReplacement(Node* node) {
while (replacement(node)) {
node = replacement(node);
}
return node;
}
Node* EscapeAnalysis::GetReplacement(Node* node) {
Node* result = nullptr;
while (replacement(node)) {
node = result = replacement(node);
}
return result;
}
bool EscapeAnalysis::IsVirtual(Node* node) {
if (node->id() >= status_analysis_->GetStatusVectorSize()) {
return false;
}
return status_analysis_->IsVirtual(node);
}
bool EscapeAnalysis::IsEscaped(Node* node) {
if (node->id() >= status_analysis_->GetStatusVectorSize()) {
return false;
}
return status_analysis_->IsEscaped(node);
}
bool EscapeAnalysis::CompareVirtualObjects(Node* left, Node* right) {
DCHECK(IsVirtual(left) && IsVirtual(right));
left = ResolveReplacement(left);
right = ResolveReplacement(right);
if (IsEquivalentPhi(left, right)) {
return true;
}
return false;
}
namespace {
int OffsetForFieldAccess(Node* node) {
FieldAccess access = FieldAccessOf(node->op());
DCHECK_EQ(access.offset % kPointerSize, 0);
return access.offset / kPointerSize;
}
int OffsetForElementAccess(Node* node, int index) {
ElementAccess access = ElementAccessOf(node->op());
DCHECK_GE(ElementSizeLog2Of(access.machine_type.representation()),
kPointerSizeLog2);
DCHECK_EQ(access.header_size % kPointerSize, 0);
return access.header_size / kPointerSize + index;
}
} // namespace
void EscapeAnalysis::ProcessLoadFromPhi(int offset, Node* from, Node* load,
VirtualState* state) {
TRACE("Load #%d from phi #%d", load->id(), from->id());
cache_->fields().clear();
for (int i = 0; i < load->op()->ValueInputCount(); ++i) {
Node* input = NodeProperties::GetValueInput(load, i);
cache_->fields().push_back(input);
}
cache_->LoadVirtualObjectsForFieldsFrom(state,
status_analysis_->GetAliasMap());
if (cache_->objects().size() == cache_->fields().size()) {
cache_->GetFields(offset);
if (cache_->fields().size() == cache_->objects().size()) {
Node* rep = replacement(load);
if (!rep || !IsEquivalentPhi(rep, cache_->fields())) {
int value_input_count = static_cast<int>(cache_->fields().size());
cache_->fields().push_back(NodeProperties::GetControlInput(from));
Node* phi = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, value_input_count),
value_input_count + 1, &cache_->fields().front());
status_analysis_->ResizeStatusVector();
SetReplacement(load, phi);
TRACE(" got phi created.\n");
} else {
TRACE(" has already phi #%d.\n", rep->id());
}
} else {
TRACE(" has incomplete field info.\n");
}
} else {
TRACE(" has incomplete virtual object info.\n");
}
}
void EscapeAnalysis::ProcessLoadField(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kLoadField);
ForwardVirtualState(node);
Node* from = ResolveReplacement(NodeProperties::GetValueInput(node, 0));
VirtualState* state = virtual_states_[node->id()];
if (VirtualObject* object = GetVirtualObject(state, from)) {
if (!object->IsTracked()) return;
int offset = OffsetForFieldAccess(node);
if (static_cast<size_t>(offset) >= object->field_count()) return;
Node* value = object->GetField(offset);
if (value) {
value = ResolveReplacement(value);
}
// Record that the load has this alias.
UpdateReplacement(state, node, value);
} else if (from->opcode() == IrOpcode::kPhi &&
FieldAccessOf(node->op()).offset % kPointerSize == 0) {
int offset = OffsetForFieldAccess(node);
// Only binary phis are supported for now.
ProcessLoadFromPhi(offset, from, node, state);
} else {
UpdateReplacement(state, node, nullptr);
}
}
void EscapeAnalysis::ProcessLoadElement(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kLoadElement);
ForwardVirtualState(node);
Node* from = ResolveReplacement(NodeProperties::GetValueInput(node, 0));
VirtualState* state = virtual_states_[node->id()];
Node* index_node = node->InputAt(1);
NumberMatcher index(index_node);
DCHECK(index_node->opcode() != IrOpcode::kInt32Constant &&
index_node->opcode() != IrOpcode::kInt64Constant &&
index_node->opcode() != IrOpcode::kFloat32Constant &&
index_node->opcode() != IrOpcode::kFloat64Constant);
if (index.HasValue()) {
if (VirtualObject* object = GetVirtualObject(state, from)) {
if (!object->IsTracked()) return;
int offset = OffsetForElementAccess(node, index.Value());
if (static_cast<size_t>(offset) >= object->field_count()) return;
Node* value = object->GetField(offset);
if (value) {
value = ResolveReplacement(value);
}
// Record that the load has this alias.
UpdateReplacement(state, node, value);
} else if (from->opcode() == IrOpcode::kPhi) {
int offset = OffsetForElementAccess(node, index.Value());
ProcessLoadFromPhi(offset, from, node, state);
} else {
UpdateReplacement(state, node, nullptr);
}
} else {
// We have a load from a non-const index, cannot eliminate object.
if (status_analysis_->SetEscaped(from)) {
TRACE(
"Setting #%d (%s) to escaped because load element #%d from non-const "
"index #%d (%s)\n",
from->id(), from->op()->mnemonic(), node->id(), index_node->id(),
index_node->op()->mnemonic());
}
}
}
void EscapeAnalysis::ProcessStoreField(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kStoreField);
ForwardVirtualState(node);
Node* to = ResolveReplacement(NodeProperties::GetValueInput(node, 0));
VirtualState* state = virtual_states_[node->id()];
if (VirtualObject* object = GetVirtualObject(state, to)) {
if (!object->IsTracked()) return;
int offset = OffsetForFieldAccess(node);
if (static_cast<size_t>(offset) >= object->field_count()) return;
Node* val = ResolveReplacement(NodeProperties::GetValueInput(node, 1));
// TODO(mstarzinger): The following is a workaround to not track the code
// entry field in virtual JSFunction objects. We only ever store the inner
// pointer into the compile lazy stub in this field and the deoptimizer has
// this assumption hard-coded in {TranslatedState::MaterializeAt} as well.
if (val->opcode() == IrOpcode::kInt32Constant ||
val->opcode() == IrOpcode::kInt64Constant) {
DCHECK_EQ(JSFunction::kCodeEntryOffset, FieldAccessOf(node->op()).offset);
val = slot_not_analyzed_;
}
if (object->GetField(offset) != val) {
object = CopyForModificationAt(object, state, node);
object->SetField(offset, val);
}
}
}
void EscapeAnalysis::ProcessStoreElement(Node* node) {
DCHECK_EQ(node->opcode(), IrOpcode::kStoreElement);
ForwardVirtualState(node);
Node* to = ResolveReplacement(NodeProperties::GetValueInput(node, 0));
Node* index_node = node->InputAt(1);
NumberMatcher index(index_node);
DCHECK(index_node->opcode() != IrOpcode::kInt32Constant &&
index_node->opcode() != IrOpcode::kInt64Constant &&
index_node->opcode() != IrOpcode::kFloat32Constant &&
index_node->opcode() != IrOpcode::kFloat64Constant);
VirtualState* state = virtual_states_[node->id()];
if (index.HasValue()) {
if (VirtualObject* object = GetVirtualObject(state, to)) {
if (!object->IsTracked()) return;
int offset = OffsetForElementAccess(node, index.Value());
if (static_cast<size_t>(offset) >= object->field_count()) return;
Node* val = ResolveReplacement(NodeProperties::GetValueInput(node, 2));
if (object->GetField(offset) != val) {
object = CopyForModificationAt(object, state, node);
object->SetField(offset, val);
}
}
} else {
// We have a store to a non-const index, cannot eliminate object.
if (status_analysis_->SetEscaped(to)) {
TRACE(
"Setting #%d (%s) to escaped because store element #%d to non-const "
"index #%d (%s)\n",
to->id(), to->op()->mnemonic(), node->id(), index_node->id(),
index_node->op()->mnemonic());
}
if (VirtualObject* object = GetVirtualObject(state, to)) {
if (!object->IsTracked()) return;
if (!object->AllFieldsClear()) {
object = CopyForModificationAt(object, state, node);
object->ClearAllFields();
TRACE("Cleared all fields of @%d:#%d\n",
status_analysis_->GetAlias(object->id()), object->id());
}
}
}
}
Node* EscapeAnalysis::GetOrCreateObjectState(Node* effect, Node* node) {
if ((node->opcode() == IrOpcode::kFinishRegion ||
node->opcode() == IrOpcode::kAllocate) &&
IsVirtual(node)) {
if (VirtualObject* vobj = GetVirtualObject(virtual_states_[effect->id()],
ResolveReplacement(node))) {
if (Node* object_state = vobj->GetObjectState()) {
return object_state;
} else {
cache_->fields().clear();
for (size_t i = 0; i < vobj->field_count(); ++i) {
if (Node* field = vobj->GetField(i)) {
cache_->fields().push_back(field);
}
}
int input_count = static_cast<int>(cache_->fields().size());
Node* new_object_state =
graph()->NewNode(common()->ObjectState(input_count, vobj->id()),
input_count, &cache_->fields().front());
vobj->SetObjectState(new_object_state);
TRACE(
"Creating object state #%d for vobj %p (from node #%d) at effect "
"#%d\n",
new_object_state->id(), static_cast<void*>(vobj), node->id(),
effect->id());
// Now fix uses of other objects.
for (size_t i = 0; i < vobj->field_count(); ++i) {
if (Node* field = vobj->GetField(i)) {
if (Node* field_object_state =
GetOrCreateObjectState(effect, field)) {
NodeProperties::ReplaceValueInput(
new_object_state, field_object_state, static_cast<int>(i));
}
}
}
return new_object_state;
}
}
}
return nullptr;
}
void EscapeAnalysis::DebugPrintState(VirtualState* state) {
PrintF("Dumping virtual state %p\n", static_cast<void*>(state));
for (Alias alias = 0; alias < status_analysis_->AliasCount(); ++alias) {
if (VirtualObject* object = state->VirtualObjectFromAlias(alias)) {
PrintF(" Alias @%d: Object #%d with %zu fields\n", alias, object->id(),
object->field_count());
for (size_t i = 0; i < object->field_count(); ++i) {
if (Node* f = object->GetField(i)) {
PrintF(" Field %zu = #%d (%s)\n", i, f->id(), f->op()->mnemonic());
}
}
}
}
}
void EscapeAnalysis::DebugPrint() {
ZoneVector<VirtualState*> object_states(zone());
for (NodeId id = 0; id < virtual_states_.size(); id++) {
if (VirtualState* states = virtual_states_[id]) {
if (std::find(object_states.begin(), object_states.end(), states) ==
object_states.end()) {
object_states.push_back(states);
}
}
}
for (size_t n = 0; n < object_states.size(); n++) {
DebugPrintState(object_states[n]);
}
}
VirtualObject* EscapeAnalysis::GetVirtualObject(VirtualState* state,
Node* node) {
if (node->id() >= status_analysis_->GetAliasMap().size()) return nullptr;
Alias alias = status_analysis_->GetAlias(node->id());
if (alias >= state->size()) return nullptr;
return state->VirtualObjectFromAlias(alias);
}
bool EscapeAnalysis::ExistsVirtualAllocate() {
for (size_t id = 0; id < status_analysis_->GetAliasMap().size(); ++id) {
Alias alias = status_analysis_->GetAlias(static_cast<NodeId>(id));
if (alias < EscapeStatusAnalysis::kUntrackable) {
if (status_analysis_->IsVirtual(static_cast<int>(id))) {
return true;
}
}
}
return false;
}
Graph* EscapeAnalysis::graph() const { return status_analysis_->graph(); }
} // namespace compiler
} // namespace internal
} // namespace v8