// Copyright 2012 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "v8.h"
#include "hydrogen.h"
#include "codegen.h"
#include "full-codegen.h"
#include "hashmap.h"
#include "lithium-allocator.h"
#include "parser.h"
#include "scopeinfo.h"
#include "scopes.h"
#include "stub-cache.h"
#if V8_TARGET_ARCH_IA32
#include "ia32/lithium-codegen-ia32.h"
#elif V8_TARGET_ARCH_X64
#include "x64/lithium-codegen-x64.h"
#elif V8_TARGET_ARCH_ARM
#include "arm/lithium-codegen-arm.h"
#elif V8_TARGET_ARCH_MIPS
#include "mips/lithium-codegen-mips.h"
#else
#error Unsupported target architecture.
#endif
namespace v8 {
namespace internal {
HBasicBlock::HBasicBlock(HGraph* graph)
: block_id_(graph->GetNextBlockID()),
graph_(graph),
phis_(4),
first_(NULL),
last_(NULL),
end_(NULL),
loop_information_(NULL),
predecessors_(2),
dominator_(NULL),
dominated_blocks_(4),
last_environment_(NULL),
argument_count_(-1),
first_instruction_index_(-1),
last_instruction_index_(-1),
deleted_phis_(4),
parent_loop_header_(NULL),
is_inline_return_target_(false),
is_deoptimizing_(false),
dominates_loop_successors_(false) { }
void HBasicBlock::AttachLoopInformation() {
ASSERT(!IsLoopHeader());
loop_information_ = new(zone()) HLoopInformation(this);
}
void HBasicBlock::DetachLoopInformation() {
ASSERT(IsLoopHeader());
loop_information_ = NULL;
}
void HBasicBlock::AddPhi(HPhi* phi) {
ASSERT(!IsStartBlock());
phis_.Add(phi);
phi->SetBlock(this);
}
void HBasicBlock::RemovePhi(HPhi* phi) {
ASSERT(phi->block() == this);
ASSERT(phis_.Contains(phi));
ASSERT(phi->HasNoUses() || !phi->is_live());
phi->Kill();
phis_.RemoveElement(phi);
phi->SetBlock(NULL);
}
void HBasicBlock::AddInstruction(HInstruction* instr) {
ASSERT(!IsStartBlock() || !IsFinished());
ASSERT(!instr->IsLinked());
ASSERT(!IsFinished());
if (first_ == NULL) {
HBlockEntry* entry = new(zone()) HBlockEntry();
entry->InitializeAsFirst(this);
first_ = last_ = entry;
}
instr->InsertAfter(last_);
last_ = instr;
}
HDeoptimize* HBasicBlock::CreateDeoptimize(
HDeoptimize::UseEnvironment has_uses) {
ASSERT(HasEnvironment());
if (has_uses == HDeoptimize::kNoUses) return new(zone()) HDeoptimize(0);
HEnvironment* environment = last_environment();
HDeoptimize* instr = new(zone()) HDeoptimize(environment->length());
for (int i = 0; i < environment->length(); i++) {
HValue* val = environment->values()->at(i);
instr->AddEnvironmentValue(val);
}
return instr;
}
HSimulate* HBasicBlock::CreateSimulate(int ast_id) {
ASSERT(HasEnvironment());
HEnvironment* environment = last_environment();
ASSERT(ast_id == AstNode::kNoNumber ||
environment->closure()->shared()->VerifyBailoutId(ast_id));
int push_count = environment->push_count();
int pop_count = environment->pop_count();
HSimulate* instr = new(zone()) HSimulate(ast_id, pop_count);
for (int i = push_count - 1; i >= 0; --i) {
instr->AddPushedValue(environment->ExpressionStackAt(i));
}
for (int i = 0; i < environment->assigned_variables()->length(); ++i) {
int index = environment->assigned_variables()->at(i);
instr->AddAssignedValue(index, environment->Lookup(index));
}
environment->ClearHistory();
return instr;
}
void HBasicBlock::Finish(HControlInstruction* end) {
ASSERT(!IsFinished());
AddInstruction(end);
end_ = end;
for (HSuccessorIterator it(end); !it.Done(); it.Advance()) {
it.Current()->RegisterPredecessor(this);
}
}
void HBasicBlock::Goto(HBasicBlock* block, bool drop_extra) {
if (block->IsInlineReturnTarget()) {
AddInstruction(new(zone()) HLeaveInlined);
last_environment_ = last_environment()->DiscardInlined(drop_extra);
}
AddSimulate(AstNode::kNoNumber);
HGoto* instr = new(zone()) HGoto(block);
Finish(instr);
}
void HBasicBlock::AddLeaveInlined(HValue* return_value,
HBasicBlock* target,
bool drop_extra) {
ASSERT(target->IsInlineReturnTarget());
ASSERT(return_value != NULL);
AddInstruction(new(zone()) HLeaveInlined);
last_environment_ = last_environment()->DiscardInlined(drop_extra);
last_environment()->Push(return_value);
AddSimulate(AstNode::kNoNumber);
HGoto* instr = new(zone()) HGoto(target);
Finish(instr);
}
void HBasicBlock::SetInitialEnvironment(HEnvironment* env) {
ASSERT(!HasEnvironment());
ASSERT(first() == NULL);
UpdateEnvironment(env);
}
void HBasicBlock::SetJoinId(int ast_id) {
int length = predecessors_.length();
ASSERT(length > 0);
for (int i = 0; i < length; i++) {
HBasicBlock* predecessor = predecessors_[i];
ASSERT(predecessor->end()->IsGoto());
HSimulate* simulate = HSimulate::cast(predecessor->end()->previous());
// We only need to verify the ID once.
ASSERT(i != 0 ||
predecessor->last_environment()->closure()->shared()
->VerifyBailoutId(ast_id));
simulate->set_ast_id(ast_id);
}
}
bool HBasicBlock::Dominates(HBasicBlock* other) const {
HBasicBlock* current = other->dominator();
while (current != NULL) {
if (current == this) return true;
current = current->dominator();
}
return false;
}
int HBasicBlock::LoopNestingDepth() const {
const HBasicBlock* current = this;
int result = (current->IsLoopHeader()) ? 1 : 0;
while (current->parent_loop_header() != NULL) {
current = current->parent_loop_header();
result++;
}
return result;
}
void HBasicBlock::PostProcessLoopHeader(IterationStatement* stmt) {
ASSERT(IsLoopHeader());
SetJoinId(stmt->EntryId());
if (predecessors()->length() == 1) {
// This is a degenerated loop.
DetachLoopInformation();
return;
}
// Only the first entry into the loop is from outside the loop. All other
// entries must be back edges.
for (int i = 1; i < predecessors()->length(); ++i) {
loop_information()->RegisterBackEdge(predecessors()->at(i));
}
}
void HBasicBlock::RegisterPredecessor(HBasicBlock* pred) {
if (HasPredecessor()) {
// Only loop header blocks can have a predecessor added after
// instructions have been added to the block (they have phis for all
// values in the environment, these phis may be eliminated later).
ASSERT(IsLoopHeader() || first_ == NULL);
HEnvironment* incoming_env = pred->last_environment();
if (IsLoopHeader()) {
ASSERT(phis()->length() == incoming_env->length());
for (int i = 0; i < phis_.length(); ++i) {
phis_[i]->AddInput(incoming_env->values()->at(i));
}
} else {
last_environment()->AddIncomingEdge(this, pred->last_environment());
}
} else if (!HasEnvironment() && !IsFinished()) {
ASSERT(!IsLoopHeader());
SetInitialEnvironment(pred->last_environment()->Copy());
}
predecessors_.Add(pred);
}
void HBasicBlock::AddDominatedBlock(HBasicBlock* block) {
ASSERT(!dominated_blocks_.Contains(block));
// Keep the list of dominated blocks sorted such that if there is two
// succeeding block in this list, the predecessor is before the successor.
int index = 0;
while (index < dominated_blocks_.length() &&
dominated_blocks_[index]->block_id() < block->block_id()) {
++index;
}
dominated_blocks_.InsertAt(index, block);
}
void HBasicBlock::AssignCommonDominator(HBasicBlock* other) {
if (dominator_ == NULL) {
dominator_ = other;
other->AddDominatedBlock(this);
} else if (other->dominator() != NULL) {
HBasicBlock* first = dominator_;
HBasicBlock* second = other;
while (first != second) {
if (first->block_id() > second->block_id()) {
first = first->dominator();
} else {
second = second->dominator();
}
ASSERT(first != NULL && second != NULL);
}
if (dominator_ != first) {
ASSERT(dominator_->dominated_blocks_.Contains(this));
dominator_->dominated_blocks_.RemoveElement(this);
dominator_ = first;
first->AddDominatedBlock(this);
}
}
}
void HBasicBlock::AssignLoopSuccessorDominators() {
// Mark blocks that dominate all subsequent reachable blocks inside their
// loop. Exploit the fact that blocks are sorted in reverse post order. When
// the loop is visited in increasing block id order, if the number of
// non-loop-exiting successor edges at the dominator_candidate block doesn't
// exceed the number of previously encountered predecessor edges, there is no
// path from the loop header to any block with higher id that doesn't go
// through the dominator_candidate block. In this case, the
// dominator_candidate block is guaranteed to dominate all blocks reachable
// from it with higher ids.
HBasicBlock* last = loop_information()->GetLastBackEdge();
int outstanding_successors = 1; // one edge from the pre-header
// Header always dominates everything.
MarkAsLoopSuccessorDominator();
for (int j = block_id(); j <= last->block_id(); ++j) {
HBasicBlock* dominator_candidate = graph_->blocks()->at(j);
for (HPredecessorIterator it(dominator_candidate); !it.Done();
it.Advance()) {
HBasicBlock* predecessor = it.Current();
// Don't count back edges.
if (predecessor->block_id() < dominator_candidate->block_id()) {
outstanding_successors--;
}
}
// If more successors than predecessors have been seen in the loop up to
// now, it's not possible to guarantee that the current block dominates
// all of the blocks with higher IDs. In this case, assume conservatively
// that those paths through loop that don't go through the current block
// contain all of the loop's dependencies. Also be careful to record
// dominator information about the current loop that's being processed,
// and not nested loops, which will be processed when
// AssignLoopSuccessorDominators gets called on their header.
ASSERT(outstanding_successors >= 0);
HBasicBlock* parent_loop_header = dominator_candidate->parent_loop_header();
if (outstanding_successors == 0 &&
(parent_loop_header == this && !dominator_candidate->IsLoopHeader())) {
dominator_candidate->MarkAsLoopSuccessorDominator();
}
HControlInstruction* end = dominator_candidate->end();
for (HSuccessorIterator it(end); !it.Done(); it.Advance()) {
HBasicBlock* successor = it.Current();
// Only count successors that remain inside the loop and don't loop back
// to a loop header.
if (successor->block_id() > dominator_candidate->block_id() &&
successor->block_id() <= last->block_id()) {
// Backwards edges must land on loop headers.
ASSERT(successor->block_id() > dominator_candidate->block_id() ||
successor->IsLoopHeader());
outstanding_successors++;
}
}
}
}
int HBasicBlock::PredecessorIndexOf(HBasicBlock* predecessor) const {
for (int i = 0; i < predecessors_.length(); ++i) {
if (predecessors_[i] == predecessor) return i;
}
UNREACHABLE();
return -1;
}
#ifdef DEBUG
void HBasicBlock::Verify() {
// Check that every block is finished.
ASSERT(IsFinished());
ASSERT(block_id() >= 0);
// Check that the incoming edges are in edge split form.
if (predecessors_.length() > 1) {
for (int i = 0; i < predecessors_.length(); ++i) {
ASSERT(predecessors_[i]->end()->SecondSuccessor() == NULL);
}
}
}
#endif
void HLoopInformation::RegisterBackEdge(HBasicBlock* block) {
this->back_edges_.Add(block);
AddBlock(block);
}
HBasicBlock* HLoopInformation::GetLastBackEdge() const {
int max_id = -1;
HBasicBlock* result = NULL;
for (int i = 0; i < back_edges_.length(); ++i) {
HBasicBlock* cur = back_edges_[i];
if (cur->block_id() > max_id) {
max_id = cur->block_id();
result = cur;
}
}
return result;
}
void HLoopInformation::AddBlock(HBasicBlock* block) {
if (block == loop_header()) return;
if (block->parent_loop_header() == loop_header()) return;
if (block->parent_loop_header() != NULL) {
AddBlock(block->parent_loop_header());
} else {
block->set_parent_loop_header(loop_header());
blocks_.Add(block);
for (int i = 0; i < block->predecessors()->length(); ++i) {
AddBlock(block->predecessors()->at(i));
}
}
}
#ifdef DEBUG
// Checks reachability of the blocks in this graph and stores a bit in
// the BitVector "reachable()" for every block that can be reached
// from the start block of the graph. If "dont_visit" is non-null, the given
// block is treated as if it would not be part of the graph. "visited_count()"
// returns the number of reachable blocks.
class ReachabilityAnalyzer BASE_EMBEDDED {
public:
ReachabilityAnalyzer(HBasicBlock* entry_block,
int block_count,
HBasicBlock* dont_visit)
: visited_count_(0),
stack_(16),
reachable_(block_count, ZONE),
dont_visit_(dont_visit) {
PushBlock(entry_block);
Analyze();
}
int visited_count() const { return visited_count_; }
const BitVector* reachable() const { return &reachable_; }
private:
void PushBlock(HBasicBlock* block) {
if (block != NULL && block != dont_visit_ &&
!reachable_.Contains(block->block_id())) {
reachable_.Add(block->block_id());
stack_.Add(block);
visited_count_++;
}
}
void Analyze() {
while (!stack_.is_empty()) {
HControlInstruction* end = stack_.RemoveLast()->end();
for (HSuccessorIterator it(end); !it.Done(); it.Advance()) {
PushBlock(it.Current());
}
}
}
int visited_count_;
ZoneList<HBasicBlock*> stack_;
BitVector reachable_;
HBasicBlock* dont_visit_;
};
void HGraph::Verify(bool do_full_verify) const {
for (int i = 0; i < blocks_.length(); i++) {
HBasicBlock* block = blocks_.at(i);
block->Verify();
// Check that every block contains at least one node and that only the last
// node is a control instruction.
HInstruction* current = block->first();
ASSERT(current != NULL && current->IsBlockEntry());
while (current != NULL) {
ASSERT((current->next() == NULL) == current->IsControlInstruction());
ASSERT(current->block() == block);
current->Verify();
current = current->next();
}
// Check that successors are correctly set.
HBasicBlock* first = block->end()->FirstSuccessor();
HBasicBlock* second = block->end()->SecondSuccessor();
ASSERT(second == NULL || first != NULL);
// Check that the predecessor array is correct.
if (first != NULL) {
ASSERT(first->predecessors()->Contains(block));
if (second != NULL) {
ASSERT(second->predecessors()->Contains(block));
}
}
// Check that phis have correct arguments.
for (int j = 0; j < block->phis()->length(); j++) {
HPhi* phi = block->phis()->at(j);
phi->Verify();
}
// Check that all join blocks have predecessors that end with an
// unconditional goto and agree on their environment node id.
if (block->predecessors()->length() >= 2) {
int id = block->predecessors()->first()->last_environment()->ast_id();
for (int k = 0; k < block->predecessors()->length(); k++) {
HBasicBlock* predecessor = block->predecessors()->at(k);
ASSERT(predecessor->end()->IsGoto());
ASSERT(predecessor->last_environment()->ast_id() == id);
}
}
}
// Check special property of first block to have no predecessors.
ASSERT(blocks_.at(0)->predecessors()->is_empty());
if (do_full_verify) {
// Check that the graph is fully connected.
ReachabilityAnalyzer analyzer(entry_block_, blocks_.length(), NULL);
ASSERT(analyzer.visited_count() == blocks_.length());
// Check that entry block dominator is NULL.
ASSERT(entry_block_->dominator() == NULL);
// Check dominators.
for (int i = 0; i < blocks_.length(); ++i) {
HBasicBlock* block = blocks_.at(i);
if (block->dominator() == NULL) {
// Only start block may have no dominator assigned to.
ASSERT(i == 0);
} else {
// Assert that block is unreachable if dominator must not be visited.
ReachabilityAnalyzer dominator_analyzer(entry_block_,
blocks_.length(),
block->dominator());
ASSERT(!dominator_analyzer.reachable()->Contains(block->block_id()));
}
}
}
}
#endif
HConstant* HGraph::GetConstant(SetOncePointer<HConstant>* pointer,
Object* value) {
if (!pointer->is_set()) {
HConstant* constant = new(zone()) HConstant(Handle<Object>(value),
Representation::Tagged());
constant->InsertAfter(GetConstantUndefined());
pointer->set(constant);
}
return pointer->get();
}
HConstant* HGraph::GetConstant1() {
return GetConstant(&constant_1_, Smi::FromInt(1));
}
HConstant* HGraph::GetConstantMinus1() {
return GetConstant(&constant_minus1_, Smi::FromInt(-1));
}
HConstant* HGraph::GetConstantTrue() {
return GetConstant(&constant_true_, isolate()->heap()->true_value());
}
HConstant* HGraph::GetConstantFalse() {
return GetConstant(&constant_false_, isolate()->heap()->false_value());
}
HConstant* HGraph::GetConstantHole() {
return GetConstant(&constant_hole_, isolate()->heap()->the_hole_value());
}
HGraphBuilder::HGraphBuilder(CompilationInfo* info,
TypeFeedbackOracle* oracle)
: function_state_(NULL),
initial_function_state_(this, info, oracle, NORMAL_RETURN),
ast_context_(NULL),
break_scope_(NULL),
graph_(NULL),
current_block_(NULL),
inlined_count_(0),
zone_(info->isolate()->zone()),
inline_bailout_(false) {
// This is not initialized in the initializer list because the
// constructor for the initial state relies on function_state_ == NULL
// to know it's the initial state.
function_state_= &initial_function_state_;
}
HBasicBlock* HGraphBuilder::CreateJoin(HBasicBlock* first,
HBasicBlock* second,
int join_id) {
if (first == NULL) {
return second;
} else if (second == NULL) {
return first;
} else {
HBasicBlock* join_block = graph_->CreateBasicBlock();
first->Goto(join_block);
second->Goto(join_block);
join_block->SetJoinId(join_id);
return join_block;
}
}
HBasicBlock* HGraphBuilder::JoinContinue(IterationStatement* statement,
HBasicBlock* exit_block,
HBasicBlock* continue_block) {
if (continue_block != NULL) {
if (exit_block != NULL) exit_block->Goto(continue_block);
continue_block->SetJoinId(statement->ContinueId());
return continue_block;
}
return exit_block;
}
HBasicBlock* HGraphBuilder::CreateLoop(IterationStatement* statement,
HBasicBlock* loop_entry,
HBasicBlock* body_exit,
HBasicBlock* loop_successor,
HBasicBlock* break_block) {
if (body_exit != NULL) body_exit->Goto(loop_entry);
loop_entry->PostProcessLoopHeader(statement);
if (break_block != NULL) {
if (loop_successor != NULL) loop_successor->Goto(break_block);
break_block->SetJoinId(statement->ExitId());
return break_block;
}
return loop_successor;
}
void HBasicBlock::FinishExit(HControlInstruction* instruction) {
Finish(instruction);
ClearEnvironment();
}
HGraph::HGraph(CompilationInfo* info)
: isolate_(info->isolate()),
next_block_id_(0),
entry_block_(NULL),
blocks_(8),
values_(16),
phi_list_(NULL) {
start_environment_ =
new(zone()) HEnvironment(NULL, info->scope(), info->closure());
start_environment_->set_ast_id(AstNode::kFunctionEntryId);
entry_block_ = CreateBasicBlock();
entry_block_->SetInitialEnvironment(start_environment_);
}
Handle<Code> HGraph::Compile(CompilationInfo* info) {
int values = GetMaximumValueID();
if (values > LUnallocated::kMaxVirtualRegisters) {
if (FLAG_trace_bailout) {
PrintF("Not enough virtual registers for (values).\n");
}
return Handle<Code>::null();
}
LAllocator allocator(values, this);
LChunkBuilder builder(info, this, &allocator);
LChunk* chunk = builder.Build();
if (chunk == NULL) return Handle<Code>::null();
if (!allocator.Allocate(chunk)) {
if (FLAG_trace_bailout) {
PrintF("Not enough virtual registers (regalloc).\n");
}
return Handle<Code>::null();
}
MacroAssembler assembler(info->isolate(), NULL, 0);
LCodeGen generator(chunk, &assembler, info);
chunk->MarkEmptyBlocks();
if (generator.GenerateCode()) {
if (FLAG_trace_codegen) {
PrintF("Crankshaft Compiler - ");
}
CodeGenerator::MakeCodePrologue(info);
Code::Flags flags = Code::ComputeFlags(Code::OPTIMIZED_FUNCTION);
Handle<Code> code =
CodeGenerator::MakeCodeEpilogue(&assembler, flags, info);
generator.FinishCode(code);
CodeGenerator::PrintCode(code, info);
return code;
}
return Handle<Code>::null();
}
HBasicBlock* HGraph::CreateBasicBlock() {
HBasicBlock* result = new(zone()) HBasicBlock(this);
blocks_.Add(result);
return result;
}
void HGraph::Canonicalize() {
if (!FLAG_use_canonicalizing) return;
HPhase phase("H_Canonicalize", this);
for (int i = 0; i < blocks()->length(); ++i) {
HInstruction* instr = blocks()->at(i)->first();
while (instr != NULL) {
HValue* value = instr->Canonicalize();
if (value != instr) instr->DeleteAndReplaceWith(value);
instr = instr->next();
}
}
}
void HGraph::OrderBlocks() {
HPhase phase("H_Block ordering");
BitVector visited(blocks_.length(), zone());
ZoneList<HBasicBlock*> reverse_result(8);
HBasicBlock* start = blocks_[0];
Postorder(start, &visited, &reverse_result, NULL);
blocks_.Rewind(0);
int index = 0;
for (int i = reverse_result.length() - 1; i >= 0; --i) {
HBasicBlock* b = reverse_result[i];
blocks_.Add(b);
b->set_block_id(index++);
}
}
void HGraph::PostorderLoopBlocks(HLoopInformation* loop,
BitVector* visited,
ZoneList<HBasicBlock*>* order,
HBasicBlock* loop_header) {
for (int i = 0; i < loop->blocks()->length(); ++i) {
HBasicBlock* b = loop->blocks()->at(i);
for (HSuccessorIterator it(b->end()); !it.Done(); it.Advance()) {
Postorder(it.Current(), visited, order, loop_header);
}
if (b->IsLoopHeader() && b != loop->loop_header()) {
PostorderLoopBlocks(b->loop_information(), visited, order, loop_header);
}
}
}
void HGraph::Postorder(HBasicBlock* block,
BitVector* visited,
ZoneList<HBasicBlock*>* order,
HBasicBlock* loop_header) {
if (block == NULL || visited->Contains(block->block_id())) return;
if (block->parent_loop_header() != loop_header) return;
visited->Add(block->block_id());
if (block->IsLoopHeader()) {
PostorderLoopBlocks(block->loop_information(), visited, order, loop_header);
for (HSuccessorIterator it(block->end()); !it.Done(); it.Advance()) {
Postorder(it.Current(), visited, order, block);
}
} else {
ASSERT(block->IsFinished());
for (HSuccessorIterator it(block->end()); !it.Done(); it.Advance()) {
Postorder(it.Current(), visited, order, loop_header);
}
}
ASSERT(block->end()->FirstSuccessor() == NULL ||
order->Contains(block->end()->FirstSuccessor()) ||
block->end()->FirstSuccessor()->IsLoopHeader());
ASSERT(block->end()->SecondSuccessor() == NULL ||
order->Contains(block->end()->SecondSuccessor()) ||
block->end()->SecondSuccessor()->IsLoopHeader());
order->Add(block);
}
void HGraph::AssignDominators() {
HPhase phase("H_Assign dominators", this);
for (int i = 0; i < blocks_.length(); ++i) {
HBasicBlock* block = blocks_[i];
if (block->IsLoopHeader()) {
// Only the first predecessor of a loop header is from outside the loop.
// All others are back edges, and thus cannot dominate the loop header.
block->AssignCommonDominator(block->predecessors()->first());
block->AssignLoopSuccessorDominators();
} else {
for (int j = blocks_[i]->predecessors()->length() - 1; j >= 0; --j) {
blocks_[i]->AssignCommonDominator(blocks_[i]->predecessors()->at(j));
}
}
}
}
// Mark all blocks that are dominated by an unconditional soft deoptimize to
// prevent code motion across those blocks.
void HGraph::PropagateDeoptimizingMark() {
HPhase phase("H_Propagate deoptimizing mark", this);
MarkAsDeoptimizingRecursively(entry_block());
}
void HGraph::MarkAsDeoptimizingRecursively(HBasicBlock* block) {
for (int i = 0; i < block->dominated_blocks()->length(); ++i) {
HBasicBlock* dominated = block->dominated_blocks()->at(i);
if (block->IsDeoptimizing()) dominated->MarkAsDeoptimizing();
MarkAsDeoptimizingRecursively(dominated);
}
}
void HGraph::EliminateRedundantPhis() {
HPhase phase("H_Redundant phi elimination", this);
// Worklist of phis that can potentially be eliminated. Initialized with
// all phi nodes. When elimination of a phi node modifies another phi node
// the modified phi node is added to the worklist.
ZoneList<HPhi*> worklist(blocks_.length());
for (int i = 0; i < blocks_.length(); ++i) {
worklist.AddAll(*blocks_[i]->phis());
}
while (!worklist.is_empty()) {
HPhi* phi = worklist.RemoveLast();
HBasicBlock* block = phi->block();
// Skip phi node if it was already replaced.
if (block == NULL) continue;
// Get replacement value if phi is redundant.
HValue* replacement = phi->GetRedundantReplacement();
if (replacement != NULL) {
// Iterate through the uses and replace them all.
for (HUseIterator it(phi->uses()); !it.Done(); it.Advance()) {
HValue* value = it.value();
value->SetOperandAt(it.index(), replacement);
if (value->IsPhi()) worklist.Add(HPhi::cast(value));
}
block->RemovePhi(phi);
}
}
}
void HGraph::EliminateUnreachablePhis() {
HPhase phase("H_Unreachable phi elimination", this);
// Initialize worklist.
ZoneList<HPhi*> phi_list(blocks_.length());
ZoneList<HPhi*> worklist(blocks_.length());
for (int i = 0; i < blocks_.length(); ++i) {
for (int j = 0; j < blocks_[i]->phis()->length(); j++) {
HPhi* phi = blocks_[i]->phis()->at(j);
phi_list.Add(phi);
// We can't eliminate phis in the receiver position in the environment
// because in case of throwing an error we need this value to
// construct a stack trace.
if (phi->HasRealUses() || phi->IsReceiver()) {
phi->set_is_live(true);
worklist.Add(phi);
}
}
}
// Iteratively mark live phis.
while (!worklist.is_empty()) {
HPhi* phi = worklist.RemoveLast();
for (int i = 0; i < phi->OperandCount(); i++) {
HValue* operand = phi->OperandAt(i);
if (operand->IsPhi() && !HPhi::cast(operand)->is_live()) {
HPhi::cast(operand)->set_is_live(true);
worklist.Add(HPhi::cast(operand));
}
}
}
// Remove unreachable phis.
for (int i = 0; i < phi_list.length(); i++) {
HPhi* phi = phi_list[i];
if (!phi->is_live()) {
HBasicBlock* block = phi->block();
block->RemovePhi(phi);
block->RecordDeletedPhi(phi->merged_index());
}
}
}
bool HGraph::CheckArgumentsPhiUses() {
int block_count = blocks_.length();
for (int i = 0; i < block_count; ++i) {
for (int j = 0; j < blocks_[i]->phis()->length(); ++j) {
HPhi* phi = blocks_[i]->phis()->at(j);
// We don't support phi uses of arguments for now.
if (phi->CheckFlag(HValue::kIsArguments)) return false;
}
}
return true;
}
bool HGraph::CheckConstPhiUses() {
int block_count = blocks_.length();
for (int i = 0; i < block_count; ++i) {
for (int j = 0; j < blocks_[i]->phis()->length(); ++j) {
HPhi* phi = blocks_[i]->phis()->at(j);
// Check for the hole value (from an uninitialized const).
for (int k = 0; k < phi->OperandCount(); k++) {
if (phi->OperandAt(k) == GetConstantHole()) return false;
}
}
}
return true;
}
void HGraph::CollectPhis() {
int block_count = blocks_.length();
phi_list_ = new ZoneList<HPhi*>(block_count);
for (int i = 0; i < block_count; ++i) {
for (int j = 0; j < blocks_[i]->phis()->length(); ++j) {
HPhi* phi = blocks_[i]->phis()->at(j);
phi_list_->Add(phi);
}
}
}
void HGraph::InferTypes(ZoneList<HValue*>* worklist) {
BitVector in_worklist(GetMaximumValueID(), zone());
for (int i = 0; i < worklist->length(); ++i) {
ASSERT(!in_worklist.Contains(worklist->at(i)->id()));
in_worklist.Add(worklist->at(i)->id());
}
while (!worklist->is_empty()) {
HValue* current = worklist->RemoveLast();
in_worklist.Remove(current->id());
if (current->UpdateInferredType()) {
for (HUseIterator it(current->uses()); !it.Done(); it.Advance()) {
HValue* use = it.value();
if (!in_worklist.Contains(use->id())) {
in_worklist.Add(use->id());
worklist->Add(use);
}
}
}
}
}
class HRangeAnalysis BASE_EMBEDDED {
public:
explicit HRangeAnalysis(HGraph* graph) :
graph_(graph), zone_(graph->isolate()->zone()), changed_ranges_(16) { }
void Analyze();
private:
void TraceRange(const char* msg, ...);
void Analyze(HBasicBlock* block);
void InferControlFlowRange(HCompareIDAndBranch* test, HBasicBlock* dest);
void UpdateControlFlowRange(Token::Value op, HValue* value, HValue* other);
void InferRange(HValue* value);
void RollBackTo(int index);
void AddRange(HValue* value, Range* range);
HGraph* graph_;
Zone* zone_;
ZoneList<HValue*> changed_ranges_;
};
void HRangeAnalysis::TraceRange(const char* msg, ...) {
if (FLAG_trace_range) {
va_list arguments;
va_start(arguments, msg);
OS::VPrint(msg, arguments);
va_end(arguments);
}
}
void HRangeAnalysis::Analyze() {
HPhase phase("H_Range analysis", graph_);
Analyze(graph_->entry_block());
}
void HRangeAnalysis::Analyze(HBasicBlock* block) {
TraceRange("Analyzing block B%d\n", block->block_id());
int last_changed_range = changed_ranges_.length() - 1;
// Infer range based on control flow.
if (block->predecessors()->length() == 1) {
HBasicBlock* pred = block->predecessors()->first();
if (pred->end()->IsCompareIDAndBranch()) {
InferControlFlowRange(HCompareIDAndBranch::cast(pred->end()), block);
}
}
// Process phi instructions.
for (int i = 0; i < block->phis()->length(); ++i) {
HPhi* phi = block->phis()->at(i);
InferRange(phi);
}
// Go through all instructions of the current block.
HInstruction* instr = block->first();
while (instr != block->end()) {
InferRange(instr);
instr = instr->next();
}
// Continue analysis in all dominated blocks.
for (int i = 0; i < block->dominated_blocks()->length(); ++i) {
Analyze(block->dominated_blocks()->at(i));
}
RollBackTo(last_changed_range);
}
void HRangeAnalysis::InferControlFlowRange(HCompareIDAndBranch* test,
HBasicBlock* dest) {
ASSERT((test->FirstSuccessor() == dest) == (test->SecondSuccessor() != dest));
if (test->GetInputRepresentation().IsInteger32()) {
Token::Value op = test->token();
if (test->SecondSuccessor() == dest) {
op = Token::NegateCompareOp(op);
}
Token::Value inverted_op = Token::InvertCompareOp(op);
UpdateControlFlowRange(op, test->left(), test->right());
UpdateControlFlowRange(inverted_op, test->right(), test->left());
}
}
// We know that value [op] other. Use this information to update the range on
// value.
void HRangeAnalysis::UpdateControlFlowRange(Token::Value op,
HValue* value,
HValue* other) {
Range temp_range;
Range* range = other->range() != NULL ? other->range() : &temp_range;
Range* new_range = NULL;
TraceRange("Control flow range infer %d %s %d\n",
value->id(),
Token::Name(op),
other->id());
if (op == Token::EQ || op == Token::EQ_STRICT) {
// The same range has to apply for value.
new_range = range->Copy(zone_);
} else if (op == Token::LT || op == Token::LTE) {
new_range = range->CopyClearLower(zone_);
if (op == Token::LT) {
new_range->AddConstant(-1);
}
} else if (op == Token::GT || op == Token::GTE) {
new_range = range->CopyClearUpper(zone_);
if (op == Token::GT) {
new_range->AddConstant(1);
}
}
if (new_range != NULL && !new_range->IsMostGeneric()) {
AddRange(value, new_range);
}
}
void HRangeAnalysis::InferRange(HValue* value) {
ASSERT(!value->HasRange());
if (!value->representation().IsNone()) {
value->ComputeInitialRange(zone_);
Range* range = value->range();
TraceRange("Initial inferred range of %d (%s) set to [%d,%d]\n",
value->id(),
value->Mnemonic(),
range->lower(),
range->upper());
}
}
void HRangeAnalysis::RollBackTo(int index) {
for (int i = index + 1; i < changed_ranges_.length(); ++i) {
changed_ranges_[i]->RemoveLastAddedRange();
}
changed_ranges_.Rewind(index + 1);
}
void HRangeAnalysis::AddRange(HValue* value, Range* range) {
Range* original_range = value->range();
value->AddNewRange(range, zone_);
changed_ranges_.Add(value);
Range* new_range = value->range();
TraceRange("Updated range of %d set to [%d,%d]\n",
value->id(),
new_range->lower(),
new_range->upper());
if (original_range != NULL) {
TraceRange("Original range was [%d,%d]\n",
original_range->lower(),
original_range->upper());
}
TraceRange("New information was [%d,%d]\n",
range->lower(),
range->upper());
}
void TraceGVN(const char* msg, ...) {
if (FLAG_trace_gvn) {
va_list arguments;
va_start(arguments, msg);
OS::VPrint(msg, arguments);
va_end(arguments);
}
}
HValueMap::HValueMap(Zone* zone, const HValueMap* other)
: array_size_(other->array_size_),
lists_size_(other->lists_size_),
count_(other->count_),
present_flags_(other->present_flags_),
array_(zone->NewArray<HValueMapListElement>(other->array_size_)),
lists_(zone->NewArray<HValueMapListElement>(other->lists_size_)),
free_list_head_(other->free_list_head_) {
memcpy(array_, other->array_, array_size_ * sizeof(HValueMapListElement));
memcpy(lists_, other->lists_, lists_size_ * sizeof(HValueMapListElement));
}
void HValueMap::Kill(GVNFlagSet flags) {
GVNFlagSet depends_flags = HValue::ConvertChangesToDependsFlags(flags);
if (!present_flags_.ContainsAnyOf(depends_flags)) return;
present_flags_.RemoveAll();
for (int i = 0; i < array_size_; ++i) {
HValue* value = array_[i].value;
if (value != NULL) {
// Clear list of collisions first, so we know if it becomes empty.
int kept = kNil; // List of kept elements.
int next;
for (int current = array_[i].next; current != kNil; current = next) {
next = lists_[current].next;
HValue* value = lists_[current].value;
if (value->gvn_flags().ContainsAnyOf(depends_flags)) {
// Drop it.
count_--;
lists_[current].next = free_list_head_;
free_list_head_ = current;
} else {
// Keep it.
lists_[current].next = kept;
kept = current;
present_flags_.Add(value->gvn_flags());
}
}
array_[i].next = kept;
// Now possibly drop directly indexed element.
value = array_[i].value;
if (value->gvn_flags().ContainsAnyOf(depends_flags)) { // Drop it.
count_--;
int head = array_[i].next;
if (head == kNil) {
array_[i].value = NULL;
} else {
array_[i].value = lists_[head].value;
array_[i].next = lists_[head].next;
lists_[head].next = free_list_head_;
free_list_head_ = head;
}
} else {
present_flags_.Add(value->gvn_flags()); // Keep it.
}
}
}
}
HValue* HValueMap::Lookup(HValue* value) const {
uint32_t hash = static_cast<uint32_t>(value->Hashcode());
uint32_t pos = Bound(hash);
if (array_[pos].value != NULL) {
if (array_[pos].value->Equals(value)) return array_[pos].value;
int next = array_[pos].next;
while (next != kNil) {
if (lists_[next].value->Equals(value)) return lists_[next].value;
next = lists_[next].next;
}
}
return NULL;
}
void HValueMap::Resize(int new_size) {
ASSERT(new_size > count_);
// Hashing the values into the new array has no more collisions than in the
// old hash map, so we can use the existing lists_ array, if we are careful.
// Make sure we have at least one free element.
if (free_list_head_ == kNil) {
ResizeLists(lists_size_ << 1);
}
HValueMapListElement* new_array =
ZONE->NewArray<HValueMapListElement>(new_size);
memset(new_array, 0, sizeof(HValueMapListElement) * new_size);
HValueMapListElement* old_array = array_;
int old_size = array_size_;
int old_count = count_;
count_ = 0;
// Do not modify present_flags_. It is currently correct.
array_size_ = new_size;
array_ = new_array;
if (old_array != NULL) {
// Iterate over all the elements in lists, rehashing them.
for (int i = 0; i < old_size; ++i) {
if (old_array[i].value != NULL) {
int current = old_array[i].next;
while (current != kNil) {
Insert(lists_[current].value);
int next = lists_[current].next;
lists_[current].next = free_list_head_;
free_list_head_ = current;
current = next;
}
// Rehash the directly stored value.
Insert(old_array[i].value);
}
}
}
USE(old_count);
ASSERT(count_ == old_count);
}
void HValueMap::ResizeLists(int new_size) {
ASSERT(new_size > lists_size_);
HValueMapListElement* new_lists =
ZONE->NewArray<HValueMapListElement>(new_size);
memset(new_lists, 0, sizeof(HValueMapListElement) * new_size);
HValueMapListElement* old_lists = lists_;
int old_size = lists_size_;
lists_size_ = new_size;
lists_ = new_lists;
if (old_lists != NULL) {
memcpy(lists_, old_lists, old_size * sizeof(HValueMapListElement));
}
for (int i = old_size; i < lists_size_; ++i) {
lists_[i].next = free_list_head_;
free_list_head_ = i;
}
}
void HValueMap::Insert(HValue* value) {
ASSERT(value != NULL);
// Resizing when half of the hashtable is filled up.
if (count_ >= array_size_ >> 1) Resize(array_size_ << 1);
ASSERT(count_ < array_size_);
count_++;
uint32_t pos = Bound(static_cast<uint32_t>(value->Hashcode()));
if (array_[pos].value == NULL) {
array_[pos].value = value;
array_[pos].next = kNil;
} else {
if (free_list_head_ == kNil) {
ResizeLists(lists_size_ << 1);
}
int new_element_pos = free_list_head_;
ASSERT(new_element_pos != kNil);
free_list_head_ = lists_[free_list_head_].next;
lists_[new_element_pos].value = value;
lists_[new_element_pos].next = array_[pos].next;
ASSERT(array_[pos].next == kNil || lists_[array_[pos].next].value != NULL);
array_[pos].next = new_element_pos;
}
}
class HStackCheckEliminator BASE_EMBEDDED {
public:
explicit HStackCheckEliminator(HGraph* graph) : graph_(graph) { }
void Process();
private:
HGraph* graph_;
};
void HStackCheckEliminator::Process() {
// For each loop block walk the dominator tree from the backwards branch to
// the loop header. If a call instruction is encountered the backwards branch
// is dominated by a call and the stack check in the backwards branch can be
// removed.
for (int i = 0; i < graph_->blocks()->length(); i++) {
HBasicBlock* block = graph_->blocks()->at(i);
if (block->IsLoopHeader()) {
HBasicBlock* back_edge = block->loop_information()->GetLastBackEdge();
HBasicBlock* dominator = back_edge;
while (true) {
HInstruction* instr = dominator->first();
while (instr != NULL) {
if (instr->IsCall()) {
block->loop_information()->stack_check()->Eliminate();
break;
}
instr = instr->next();
}
// Done when the loop header is processed.
if (dominator == block) break;
// Move up the dominator tree.
dominator = dominator->dominator();
}
}
}
}
// Simple sparse set with O(1) add, contains, and clear.
class SparseSet {
public:
SparseSet(Zone* zone, int capacity)
: capacity_(capacity),
length_(0),
dense_(zone->NewArray<int>(capacity)),
sparse_(zone->NewArray<int>(capacity)) {
#ifndef NVALGRIND
// Initialize the sparse array to make valgrind happy.
memset(sparse_, 0, sizeof(sparse_[0]) * capacity);
#endif
}
bool Contains(int n) const {
ASSERT(0 <= n && n < capacity_);
int d = sparse_[n];
return 0 <= d && d < length_ && dense_[d] == n;
}
bool Add(int n) {
if (Contains(n)) return false;
dense_[length_] = n;
sparse_[n] = length_;
++length_;
return true;
}
void Clear() { length_ = 0; }
private:
int capacity_;
int length_;
int* dense_;
int* sparse_;
DISALLOW_COPY_AND_ASSIGN(SparseSet);
};
class HGlobalValueNumberer BASE_EMBEDDED {
public:
explicit HGlobalValueNumberer(HGraph* graph, CompilationInfo* info)
: graph_(graph),
info_(info),
removed_side_effects_(false),
block_side_effects_(graph->blocks()->length()),
loop_side_effects_(graph->blocks()->length()),
visited_on_paths_(graph->zone(), graph->blocks()->length()) {
ASSERT(info->isolate()->heap()->allow_allocation(false));
block_side_effects_.AddBlock(GVNFlagSet(), graph_->blocks()->length());
loop_side_effects_.AddBlock(GVNFlagSet(), graph_->blocks()->length());
}
~HGlobalValueNumberer() {
ASSERT(!info_->isolate()->heap()->allow_allocation(true));
}
// Returns true if values with side effects are removed.
bool Analyze();
private:
GVNFlagSet CollectSideEffectsOnPathsToDominatedBlock(
HBasicBlock* dominator,
HBasicBlock* dominated);
void AnalyzeBlock(HBasicBlock* block, HValueMap* map);
void ComputeBlockSideEffects();
void LoopInvariantCodeMotion();
void ProcessLoopBlock(HBasicBlock* block,
HBasicBlock* before_loop,
GVNFlagSet loop_kills,
GVNFlagSet* accumulated_first_time_depends,
GVNFlagSet* accumulated_first_time_changes);
bool AllowCodeMotion();
bool ShouldMove(HInstruction* instr, HBasicBlock* loop_header);
HGraph* graph() { return graph_; }
CompilationInfo* info() { return info_; }
Zone* zone() { return graph_->zone(); }
HGraph* graph_;
CompilationInfo* info_;
bool removed_side_effects_;
// A map of block IDs to their side effects.
ZoneList<GVNFlagSet> block_side_effects_;
// A map of loop header block IDs to their loop's side effects.
ZoneList<GVNFlagSet> loop_side_effects_;
// Used when collecting side effects on paths from dominator to
// dominated.
SparseSet visited_on_paths_;
};
bool HGlobalValueNumberer::Analyze() {
removed_side_effects_ = false;
ComputeBlockSideEffects();
if (FLAG_loop_invariant_code_motion) {
LoopInvariantCodeMotion();
}
HValueMap* map = new(zone()) HValueMap();
AnalyzeBlock(graph_->entry_block(), map);
return removed_side_effects_;
}
void HGlobalValueNumberer::ComputeBlockSideEffects() {
// The Analyze phase of GVN can be called multiple times. Clear loop side
// effects before computing them to erase the contents from previous Analyze
// passes.
for (int i = 0; i < loop_side_effects_.length(); ++i) {
loop_side_effects_[i].RemoveAll();
}
for (int i = graph_->blocks()->length() - 1; i >= 0; --i) {
// Compute side effects for the block.
HBasicBlock* block = graph_->blocks()->at(i);
HInstruction* instr = block->first();
int id = block->block_id();
GVNFlagSet side_effects;
while (instr != NULL) {
side_effects.Add(instr->ChangesFlags());
if (instr->IsSoftDeoptimize()) {
block_side_effects_[id].RemoveAll();
side_effects.RemoveAll();
break;
}
instr = instr->next();
}
block_side_effects_[id].Add(side_effects);
// Loop headers are part of their loop.
if (block->IsLoopHeader()) {
loop_side_effects_[id].Add(side_effects);
}
// Propagate loop side effects upwards.
if (block->HasParentLoopHeader()) {
int header_id = block->parent_loop_header()->block_id();
loop_side_effects_[header_id].Add(block->IsLoopHeader()
? loop_side_effects_[id]
: side_effects);
}
}
}
void HGlobalValueNumberer::LoopInvariantCodeMotion() {
for (int i = graph_->blocks()->length() - 1; i >= 0; --i) {
HBasicBlock* block = graph_->blocks()->at(i);
if (block->IsLoopHeader()) {
GVNFlagSet side_effects = loop_side_effects_[block->block_id()];
TraceGVN("Try loop invariant motion for block B%d effects=0x%x\n",
block->block_id(),
side_effects.ToIntegral());
GVNFlagSet accumulated_first_time_depends;
GVNFlagSet accumulated_first_time_changes;
HBasicBlock* last = block->loop_information()->GetLastBackEdge();
for (int j = block->block_id(); j <= last->block_id(); ++j) {
ProcessLoopBlock(graph_->blocks()->at(j), block, side_effects,
&accumulated_first_time_depends,
&accumulated_first_time_changes);
}
}
}
}
void HGlobalValueNumberer::ProcessLoopBlock(
HBasicBlock* block,
HBasicBlock* loop_header,
GVNFlagSet loop_kills,
GVNFlagSet* first_time_depends,
GVNFlagSet* first_time_changes) {
HBasicBlock* pre_header = loop_header->predecessors()->at(0);
GVNFlagSet depends_flags = HValue::ConvertChangesToDependsFlags(loop_kills);
TraceGVN("Loop invariant motion for B%d depends_flags=0x%x\n",
block->block_id(),
depends_flags.ToIntegral());
HInstruction* instr = block->first();
while (instr != NULL) {
HInstruction* next = instr->next();
bool hoisted = false;
if (instr->CheckFlag(HValue::kUseGVN)) {
TraceGVN("Checking instruction %d (%s) instruction GVN flags 0x%X, "
"loop kills 0x%X\n",
instr->id(),
instr->Mnemonic(),
instr->gvn_flags().ToIntegral(),
depends_flags.ToIntegral());
bool can_hoist = !instr->gvn_flags().ContainsAnyOf(depends_flags);
if (instr->IsTransitionElementsKind()) {
// It's possible to hoist transitions out of a loop as long as the
// hoisting wouldn't move the transition past a DependsOn of one of it's
// changes or any instructions that might change an objects map or
// elements contents.
GVNFlagSet changes = instr->ChangesFlags();
GVNFlagSet hoist_depends_blockers =
HValue::ConvertChangesToDependsFlags(changes);
// In addition to not hoisting transitions above other instructions that
// change dependencies that the transition changes, it must not be
// hoisted above map changes and stores to an elements backing store
// that the transition might change.
GVNFlagSet hoist_change_blockers = changes;
hoist_change_blockers.Add(kChangesMaps);
HTransitionElementsKind* trans = HTransitionElementsKind::cast(instr);
if (trans->original_map()->has_fast_double_elements()) {
hoist_change_blockers.Add(kChangesDoubleArrayElements);
}
if (trans->transitioned_map()->has_fast_double_elements()) {
hoist_change_blockers.Add(kChangesArrayElements);
}
TraceGVN("Checking dependencies on HTransitionElementsKind %d (%s) "
"hoist depends blockers 0x%X, hoist change blockers 0x%X, "
"accumulated depends 0x%X, accumulated changes 0x%X\n",
instr->id(),
instr->Mnemonic(),
hoist_depends_blockers.ToIntegral(),
hoist_change_blockers.ToIntegral(),
first_time_depends->ToIntegral(),
first_time_changes->ToIntegral());
// It's possible to hoist transition from the current loop loop only if
// they dominate all of the successor blocks in the same loop and there
// are not any instructions that have Changes/DependsOn that intervene
// between it and the beginning of the loop header.
bool in_nested_loop = block != loop_header &&
((block->parent_loop_header() != loop_header) ||
block->IsLoopHeader());
can_hoist = !in_nested_loop &&
block->IsLoopSuccessorDominator() &&
!first_time_depends->ContainsAnyOf(hoist_depends_blockers) &&
!first_time_changes->ContainsAnyOf(hoist_change_blockers);
}
if (can_hoist) {
bool inputs_loop_invariant = true;
for (int i = 0; i < instr->OperandCount(); ++i) {
if (instr->OperandAt(i)->IsDefinedAfter(pre_header)) {
inputs_loop_invariant = false;
}
}
if (inputs_loop_invariant && ShouldMove(instr, loop_header)) {
TraceGVN("Hoisting loop invariant instruction %d\n", instr->id());
// Move the instruction out of the loop.
instr->Unlink();
instr->InsertBefore(pre_header->end());
if (instr->HasSideEffects()) removed_side_effects_ = true;
hoisted = true;
}
}
}
if (!hoisted) {
// If an instruction is not hoisted, we have to account for its side
// effects when hoisting later HTransitionElementsKind instructions.
first_time_depends->Add(instr->DependsOnFlags());
first_time_changes->Add(instr->ChangesFlags());
}
instr = next;
}
}
bool HGlobalValueNumberer::AllowCodeMotion() {
return info()->shared_info()->opt_count() + 1 < Compiler::kDefaultMaxOptCount;
}
bool HGlobalValueNumberer::ShouldMove(HInstruction* instr,
HBasicBlock* loop_header) {
// If we've disabled code motion or we're in a block that unconditionally
// deoptimizes, don't move any instructions.
return AllowCodeMotion() && !instr->block()->IsDeoptimizing();
}
GVNFlagSet HGlobalValueNumberer::CollectSideEffectsOnPathsToDominatedBlock(
HBasicBlock* dominator, HBasicBlock* dominated) {
GVNFlagSet side_effects;
for (int i = 0; i < dominated->predecessors()->length(); ++i) {
HBasicBlock* block = dominated->predecessors()->at(i);
if (dominator->block_id() < block->block_id() &&
block->block_id() < dominated->block_id() &&
visited_on_paths_.Add(block->block_id())) {
side_effects.Add(block_side_effects_[block->block_id()]);
if (block->IsLoopHeader()) {
side_effects.Add(loop_side_effects_[block->block_id()]);
}
side_effects.Add(CollectSideEffectsOnPathsToDominatedBlock(
dominator, block));
}
}
return side_effects;
}
void HGlobalValueNumberer::AnalyzeBlock(HBasicBlock* block, HValueMap* map) {
TraceGVN("Analyzing block B%d%s\n",
block->block_id(),
block->IsLoopHeader() ? " (loop header)" : "");
// If this is a loop header kill everything killed by the loop.
if (block->IsLoopHeader()) {
map->Kill(loop_side_effects_[block->block_id()]);
}
// Go through all instructions of the current block.
HInstruction* instr = block->first();
while (instr != NULL) {
HInstruction* next = instr->next();
GVNFlagSet flags = instr->ChangesFlags();
if (!flags.IsEmpty()) {
// Clear all instructions in the map that are affected by side effects.
map->Kill(flags);
TraceGVN("Instruction %d kills\n", instr->id());
}
if (instr->CheckFlag(HValue::kUseGVN)) {
ASSERT(!instr->HasObservableSideEffects());
HValue* other = map->Lookup(instr);
if (other != NULL) {
ASSERT(instr->Equals(other) && other->Equals(instr));
TraceGVN("Replacing value %d (%s) with value %d (%s)\n",
instr->id(),
instr->Mnemonic(),
other->id(),
other->Mnemonic());
if (instr->HasSideEffects()) removed_side_effects_ = true;
instr->DeleteAndReplaceWith(other);
} else {
map->Add(instr);
}
}
instr = next;
}
// Recursively continue analysis for all immediately dominated blocks.
int length = block->dominated_blocks()->length();
for (int i = 0; i < length; ++i) {
HBasicBlock* dominated = block->dominated_blocks()->at(i);
// No need to copy the map for the last child in the dominator tree.
HValueMap* successor_map = (i == length - 1) ? map : map->Copy(zone());
// Kill everything killed on any path between this block and the
// dominated block.
// We don't have to traverse these paths if the value map is
// already empty.
// If the range of block ids (block_id, dominated_id) is empty
// there are no such paths.
if (!successor_map->IsEmpty() &&
block->block_id() + 1 < dominated->block_id()) {
visited_on_paths_.Clear();
successor_map->Kill(CollectSideEffectsOnPathsToDominatedBlock(block,
dominated));
}
AnalyzeBlock(dominated, successor_map);
}
}
class HInferRepresentation BASE_EMBEDDED {
public:
explicit HInferRepresentation(HGraph* graph)
: graph_(graph),
worklist_(8),
in_worklist_(graph->GetMaximumValueID(), graph->zone()) { }
void Analyze();
private:
Representation TryChange(HValue* current);
void AddToWorklist(HValue* current);
void InferBasedOnInputs(HValue* current);
void AddDependantsToWorklist(HValue* current);
void InferBasedOnUses(HValue* current);
Zone* zone() { return graph_->zone(); }
HGraph* graph_;
ZoneList<HValue*> worklist_;
BitVector in_worklist_;
};
void HInferRepresentation::AddToWorklist(HValue* current) {
if (current->representation().IsSpecialization()) return;
if (!current->CheckFlag(HValue::kFlexibleRepresentation)) return;
if (in_worklist_.Contains(current->id())) return;
worklist_.Add(current);
in_worklist_.Add(current->id());
}
// This method tries to specialize the representation type of the value
// given as a parameter. The value is asked to infer its representation type
// based on its inputs. If the inferred type is more specialized, then this
// becomes the new representation type of the node.
void HInferRepresentation::InferBasedOnInputs(HValue* current) {
Representation r = current->representation();
if (r.IsSpecialization()) return;
ASSERT(current->CheckFlag(HValue::kFlexibleRepresentation));
Representation inferred = current->InferredRepresentation();
if (inferred.IsSpecialization()) {
if (FLAG_trace_representation) {
PrintF("Changing #%d representation %s -> %s based on inputs\n",
current->id(),
r.Mnemonic(),
inferred.Mnemonic());
}
current->ChangeRepresentation(inferred);
AddDependantsToWorklist(current);
}
}
void HInferRepresentation::AddDependantsToWorklist(HValue* value) {
for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
AddToWorklist(it.value());
}
for (int i = 0; i < value->OperandCount(); ++i) {
AddToWorklist(value->OperandAt(i));
}
}
// This method calculates whether specializing the representation of the value
// given as the parameter has a benefit in terms of less necessary type
// conversions. If there is a benefit, then the representation of the value is
// specialized.
void HInferRepresentation::InferBasedOnUses(HValue* value) {
Representation r = value->representation();
if (r.IsSpecialization() || value->HasNoUses()) return;
ASSERT(value->CheckFlag(HValue::kFlexibleRepresentation));
Representation new_rep = TryChange(value);
if (!new_rep.IsNone()) {
if (!value->representation().Equals(new_rep)) {
if (FLAG_trace_representation) {
PrintF("Changing #%d representation %s -> %s based on uses\n",
value->id(),
r.Mnemonic(),
new_rep.Mnemonic());
}
value->ChangeRepresentation(new_rep);
AddDependantsToWorklist(value);
}
}
}
Representation HInferRepresentation::TryChange(HValue* value) {
// Array of use counts for each representation.
int use_count[Representation::kNumRepresentations] = { 0 };
for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
HValue* use = it.value();
Representation rep = use->RequiredInputRepresentation(it.index());
if (rep.IsNone()) continue;
if (use->IsPhi()) HPhi::cast(use)->AddIndirectUsesTo(&use_count[0]);
use_count[rep.kind()] += use->LoopWeight();
}
int tagged_count = use_count[Representation::kTagged];
int double_count = use_count[Representation::kDouble];
int int32_count = use_count[Representation::kInteger32];
int non_tagged_count = double_count + int32_count;
// If a non-loop phi has tagged uses, don't convert it to untagged.
if (value->IsPhi() && !value->block()->IsLoopHeader() && tagged_count > 0) {
return Representation::None();
}
// Prefer unboxing over boxing, the latter is more expensive.
if (tagged_count > non_tagged_count) return Representation::None();
// Prefer Integer32 over Double, if possible.
if (int32_count > 0 && value->IsConvertibleToInteger()) {
return Representation::Integer32();
}
if (double_count > 0) return Representation::Double();
return Representation::None();
}
void HInferRepresentation::Analyze() {
HPhase phase("H_Infer representations", graph_);
// (1) Initialize bit vectors and count real uses. Each phi gets a
// bit-vector of length <number of phis>.
const ZoneList<HPhi*>* phi_list = graph_->phi_list();
int phi_count = phi_list->length();
ZoneList<BitVector*> connected_phis(phi_count);
for (int i = 0; i < phi_count; ++i) {
phi_list->at(i)->InitRealUses(i);
BitVector* connected_set = new(zone()) BitVector(phi_count, graph_->zone());
connected_set->Add(i);
connected_phis.Add(connected_set);
}
// (2) Do a fixed point iteration to find the set of connected phis. A
// phi is connected to another phi if its value is used either directly or
// indirectly through a transitive closure of the def-use relation.
bool change = true;
while (change) {
change = false;
// We normally have far more "forward edges" than "backward edges",
// so we terminate faster when we walk backwards.
for (int i = phi_count - 1; i >= 0; --i) {
HPhi* phi = phi_list->at(i);
for (HUseIterator it(phi->uses()); !it.Done(); it.Advance()) {
HValue* use = it.value();
if (use->IsPhi()) {
int id = HPhi::cast(use)->phi_id();
if (connected_phis[i]->UnionIsChanged(*connected_phis[id]))
change = true;
}
}
}
}
// (3) Use the phi reachability information from step 2 to
// (a) sum up the non-phi use counts of all connected phis.
// (b) push information about values which can't be converted to integer
// without deoptimization through the phi use-def chains, avoiding
// unnecessary deoptimizations later.
for (int i = 0; i < phi_count; ++i) {
HPhi* phi = phi_list->at(i);
bool cti = phi->AllOperandsConvertibleToInteger();
for (BitVector::Iterator it(connected_phis.at(i));
!it.Done();
it.Advance()) {
int index = it.Current();
HPhi* it_use = phi_list->at(it.Current());
if (index != i) phi->AddNonPhiUsesFrom(it_use); // Don't count twice!
if (!cti) it_use->set_is_convertible_to_integer(false);
}
}
// Initialize work list
for (int i = 0; i < graph_->blocks()->length(); ++i) {
HBasicBlock* block = graph_->blocks()->at(i);
const ZoneList<HPhi*>* phis = block->phis();
for (int j = 0; j < phis->length(); ++j) {
AddToWorklist(phis->at(j));
}
HInstruction* current = block->first();
while (current != NULL) {
AddToWorklist(current);
current = current->next();
}
}
// Do a fixed point iteration, trying to improve representations
while (!worklist_.is_empty()) {
HValue* current = worklist_.RemoveLast();
in_worklist_.Remove(current->id());
InferBasedOnInputs(current);
InferBasedOnUses(current);
}
}
void HGraph::InitializeInferredTypes() {
HPhase phase("H_Inferring types", this);
InitializeInferredTypes(0, this->blocks_.length() - 1);
}
void HGraph::InitializeInferredTypes(int from_inclusive, int to_inclusive) {
for (int i = from_inclusive; i <= to_inclusive; ++i) {
HBasicBlock* block = blocks_[i];
const ZoneList<HPhi*>* phis = block->phis();
for (int j = 0; j < phis->length(); j++) {
phis->at(j)->UpdateInferredType();
}
HInstruction* current = block->first();
while (current != NULL) {
current->UpdateInferredType();
current = current->next();
}
if (block->IsLoopHeader()) {
HBasicBlock* last_back_edge =
block->loop_information()->GetLastBackEdge();
InitializeInferredTypes(i + 1, last_back_edge->block_id());
// Skip all blocks already processed by the recursive call.
i = last_back_edge->block_id();
// Update phis of the loop header now after the whole loop body is
// guaranteed to be processed.
ZoneList<HValue*> worklist(block->phis()->length());
for (int j = 0; j < block->phis()->length(); ++j) {
worklist.Add(block->phis()->at(j));
}
InferTypes(&worklist);
}
}
}
void HGraph::PropagateMinusZeroChecks(HValue* value, BitVector* visited) {
HValue* current = value;
while (current != NULL) {
if (visited->Contains(current->id())) return;
// For phis, we must propagate the check to all of its inputs.
if (current->IsPhi()) {
visited->Add(current->id());
HPhi* phi = HPhi::cast(current);
for (int i = 0; i < phi->OperandCount(); ++i) {
PropagateMinusZeroChecks(phi->OperandAt(i), visited);
}
break;
}
// For multiplication and division, we must propagate to the left and
// the right side.
if (current->IsMul()) {
HMul* mul = HMul::cast(current);
mul->EnsureAndPropagateNotMinusZero(visited);
PropagateMinusZeroChecks(mul->left(), visited);
PropagateMinusZeroChecks(mul->right(), visited);
} else if (current->IsDiv()) {
HDiv* div = HDiv::cast(current);
div->EnsureAndPropagateNotMinusZero(visited);
PropagateMinusZeroChecks(div->left(), visited);
PropagateMinusZeroChecks(div->right(), visited);
}
current = current->EnsureAndPropagateNotMinusZero(visited);
}
}
void HGraph::InsertRepresentationChangeForUse(HValue* value,
HValue* use_value,
int use_index,
Representation to) {
// Insert the representation change right before its use. For phi-uses we
// insert at the end of the corresponding predecessor.
HInstruction* next = NULL;
if (use_value->IsPhi()) {
next = use_value->block()->predecessors()->at(use_index)->end();
} else {
next = HInstruction::cast(use_value);
}
// For constants we try to make the representation change at compile
// time. When a representation change is not possible without loss of
// information we treat constants like normal instructions and insert the
// change instructions for them.
HInstruction* new_value = NULL;
bool is_truncating = use_value->CheckFlag(HValue::kTruncatingToInt32);
bool deoptimize_on_undefined =
use_value->CheckFlag(HValue::kDeoptimizeOnUndefined);
if (value->IsConstant()) {
HConstant* constant = HConstant::cast(value);
// Try to create a new copy of the constant with the new representation.
new_value = is_truncating
? constant->CopyToTruncatedInt32()
: constant->CopyToRepresentation(to);
}
if (new_value == NULL) {
new_value = new(zone()) HChange(value, to,
is_truncating, deoptimize_on_undefined);
}
new_value->InsertBefore(next);
use_value->SetOperandAt(use_index, new_value);
}
void HGraph::InsertRepresentationChangesForValue(HValue* value) {
Representation r = value->representation();
if (r.IsNone()) return;
if (value->HasNoUses()) return;
for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
HValue* use_value = it.value();
int use_index = it.index();
Representation req = use_value->RequiredInputRepresentation(use_index);
if (req.IsNone() || req.Equals(r)) continue;
InsertRepresentationChangeForUse(value, use_value, use_index, req);
}
if (value->HasNoUses()) {
ASSERT(value->IsConstant());
value->DeleteAndReplaceWith(NULL);
}
// The only purpose of a HForceRepresentation is to represent the value
// after the (possible) HChange instruction. We make it disappear.
if (value->IsForceRepresentation()) {
value->DeleteAndReplaceWith(HForceRepresentation::cast(value)->value());
}
}
void HGraph::InsertRepresentationChanges() {
HPhase phase("H_Representation changes", this);
// Compute truncation flag for phis: Initially assume that all
// int32-phis allow truncation and iteratively remove the ones that
// are used in an operation that does not allow a truncating
// conversion.
// TODO(fschneider): Replace this with a worklist-based iteration.
for (int i = 0; i < phi_list()->length(); i++) {
HPhi* phi = phi_list()->at(i);
if (phi->representation().IsInteger32()) {
phi->SetFlag(HValue::kTruncatingToInt32);
}
}
bool change = true;
while (change) {
change = false;
for (int i = 0; i < phi_list()->length(); i++) {
HPhi* phi = phi_list()->at(i);
if (!phi->CheckFlag(HValue::kTruncatingToInt32)) continue;
if (!phi->CheckUsesForFlag(HValue::kTruncatingToInt32)) {
phi->ClearFlag(HValue::kTruncatingToInt32);
change = true;
}
}
}
for (int i = 0; i < blocks_.length(); ++i) {
// Process phi instructions first.
const ZoneList<HPhi*>* phis = blocks_[i]->phis();
for (int j = 0; j < phis->length(); j++) {
InsertRepresentationChangesForValue(phis->at(j));
}
// Process normal instructions.
HInstruction* current = blocks_[i]->first();
while (current != NULL) {
InsertRepresentationChangesForValue(current);
current = current->next();
}
}
}
void HGraph::RecursivelyMarkPhiDeoptimizeOnUndefined(HPhi* phi) {
if (phi->CheckFlag(HValue::kDeoptimizeOnUndefined)) return;
phi->SetFlag(HValue::kDeoptimizeOnUndefined);
for (int i = 0; i < phi->OperandCount(); ++i) {
HValue* input = phi->OperandAt(i);
if (input->IsPhi()) {
RecursivelyMarkPhiDeoptimizeOnUndefined(HPhi::cast(input));
}
}
}
void HGraph::MarkDeoptimizeOnUndefined() {
HPhase phase("H_MarkDeoptimizeOnUndefined", this);
// Compute DeoptimizeOnUndefined flag for phis.
// Any phi that can reach a use with DeoptimizeOnUndefined set must
// have DeoptimizeOnUndefined set. Currently only HCompareIDAndBranch, with
// double input representation, has this flag set.
// The flag is used by HChange tagged->double, which must deoptimize
// if one of its uses has this flag set.
for (int i = 0; i < phi_list()->length(); i++) {
HPhi* phi = phi_list()->at(i);
if (phi->representation().IsDouble()) {
for (HUseIterator it(phi->uses()); !it.Done(); it.Advance()) {
if (it.value()->CheckFlag(HValue::kDeoptimizeOnUndefined)) {
RecursivelyMarkPhiDeoptimizeOnUndefined(phi);
break;
}
}
}
}
}
void HGraph::ComputeMinusZeroChecks() {
BitVector visited(GetMaximumValueID(), zone());
for (int i = 0; i < blocks_.length(); ++i) {
for (HInstruction* current = blocks_[i]->first();
current != NULL;
current = current->next()) {
if (current->IsChange()) {
HChange* change = HChange::cast(current);
// Propagate flags for negative zero checks upwards from conversions
// int32-to-tagged and int32-to-double.
Representation from = change->value()->representation();
ASSERT(from.Equals(change->from()));
if (from.IsInteger32()) {
ASSERT(change->to().IsTagged() || change->to().IsDouble());
ASSERT(visited.IsEmpty());
PropagateMinusZeroChecks(change->value(), &visited);
visited.Clear();
}
}
}
}
}
// Implementation of utility class to encapsulate the translation state for
// a (possibly inlined) function.
FunctionState::FunctionState(HGraphBuilder* owner,
CompilationInfo* info,
TypeFeedbackOracle* oracle,
ReturnHandlingFlag return_handling)
: owner_(owner),
compilation_info_(info),
oracle_(oracle),
call_context_(NULL),
return_handling_(return_handling),
function_return_(NULL),
test_context_(NULL),
outer_(owner->function_state()) {
if (outer_ != NULL) {
// State for an inline function.
if (owner->ast_context()->IsTest()) {
HBasicBlock* if_true = owner->graph()->CreateBasicBlock();
HBasicBlock* if_false = owner->graph()->CreateBasicBlock();
if_true->MarkAsInlineReturnTarget();
if_false->MarkAsInlineReturnTarget();
Expression* cond = TestContext::cast(owner->ast_context())->condition();
// The AstContext constructor pushed on the context stack. This newed
// instance is the reason that AstContext can't be BASE_EMBEDDED.
test_context_ = new TestContext(owner, cond, if_true, if_false);
} else {
function_return_ = owner->graph()->CreateBasicBlock();
function_return()->MarkAsInlineReturnTarget();
}
// Set this after possibly allocating a new TestContext above.
call_context_ = owner->ast_context();
}
// Push on the state stack.
owner->set_function_state(this);
}
FunctionState::~FunctionState() {
delete test_context_;
owner_->set_function_state(outer_);
}
// Implementation of utility classes to represent an expression's context in
// the AST.
AstContext::AstContext(HGraphBuilder* owner, Expression::Context kind)
: owner_(owner),
kind_(kind),
outer_(owner->ast_context()),
for_typeof_(false) {
owner->set_ast_context(this); // Push.
#ifdef DEBUG
ASSERT(owner->environment()->frame_type() == JS_FUNCTION);
original_length_ = owner->environment()->length();
#endif
}
AstContext::~AstContext() {
owner_->set_ast_context(outer_); // Pop.
}
EffectContext::~EffectContext() {
ASSERT(owner()->HasStackOverflow() ||
owner()->current_block() == NULL ||
(owner()->environment()->length() == original_length_ &&
owner()->environment()->frame_type() == JS_FUNCTION));
}
ValueContext::~ValueContext() {
ASSERT(owner()->HasStackOverflow() ||
owner()->current_block() == NULL ||
(owner()->environment()->length() == original_length_ + 1 &&
owner()->environment()->frame_type() == JS_FUNCTION));
}
void EffectContext::ReturnValue(HValue* value) {
// The value is simply ignored.
}
void ValueContext::ReturnValue(HValue* value) {
// The value is tracked in the bailout environment, and communicated
// through the environment as the result of the expression.
if (!arguments_allowed() && value->CheckFlag(HValue::kIsArguments)) {
owner()->Bailout("bad value context for arguments value");
}
owner()->Push(value);
}
void TestContext::ReturnValue(HValue* value) {
BuildBranch(value);
}
void EffectContext::ReturnInstruction(HInstruction* instr, int ast_id) {
ASSERT(!instr->IsControlInstruction());
owner()->AddInstruction(instr);
if (instr->HasObservableSideEffects()) owner()->AddSimulate(ast_id);
}
void EffectContext::ReturnControl(HControlInstruction* instr, int ast_id) {
ASSERT(!instr->HasObservableSideEffects());
HBasicBlock* empty_true = owner()->graph()->CreateBasicBlock();
HBasicBlock* empty_false = owner()->graph()->CreateBasicBlock();
instr->SetSuccessorAt(0, empty_true);
instr->SetSuccessorAt(1, empty_false);
owner()->current_block()->Finish(instr);
HBasicBlock* join = owner()->CreateJoin(empty_true, empty_false, ast_id);
owner()->set_current_block(join);
}
void ValueContext::ReturnInstruction(HInstruction* instr, int ast_id) {
ASSERT(!instr->IsControlInstruction());
if (!arguments_allowed() && instr->CheckFlag(HValue::kIsArguments)) {
return owner()->Bailout("bad value context for arguments object value");
}
owner()->AddInstruction(instr);
owner()->Push(instr);
if (instr->HasObservableSideEffects()) owner()->AddSimulate(ast_id);
}
void ValueContext::ReturnControl(HControlInstruction* instr, int ast_id) {
ASSERT(!instr->HasObservableSideEffects());
if (!arguments_allowed() && instr->CheckFlag(HValue::kIsArguments)) {
return owner()->Bailout("bad value context for arguments object value");
}
HBasicBlock* materialize_false = owner()->graph()->CreateBasicBlock();
HBasicBlock* materialize_true = owner()->graph()->CreateBasicBlock();
instr->SetSuccessorAt(0, materialize_true);
instr->SetSuccessorAt(1, materialize_false);
owner()->current_block()->Finish(instr);
owner()->set_current_block(materialize_true);
owner()->Push(owner()->graph()->GetConstantTrue());
owner()->set_current_block(materialize_false);
owner()->Push(owner()->graph()->GetConstantFalse());
HBasicBlock* join =
owner()->CreateJoin(materialize_true, materialize_false, ast_id);
owner()->set_current_block(join);
}
void TestContext::ReturnInstruction(HInstruction* instr, int ast_id) {
ASSERT(!instr->IsControlInstruction());
HGraphBuilder* builder = owner();
builder->AddInstruction(instr);
// We expect a simulate after every expression with side effects, though
// this one isn't actually needed (and wouldn't work if it were targeted).
if (instr->HasObservableSideEffects()) {
builder->Push(instr);
builder->AddSimulate(ast_id);
builder->Pop();
}
BuildBranch(instr);
}
void TestContext::ReturnControl(HControlInstruction* instr, int ast_id) {
ASSERT(!instr->HasObservableSideEffects());
HBasicBlock* empty_true = owner()->graph()->CreateBasicBlock();
HBasicBlock* empty_false = owner()->graph()->CreateBasicBlock();
instr->SetSuccessorAt(0, empty_true);
instr->SetSuccessorAt(1, empty_false);
owner()->current_block()->Finish(instr);
empty_true->Goto(if_true(), owner()->function_state()->drop_extra());
empty_false->Goto(if_false(), owner()->function_state()->drop_extra());
owner()->set_current_block(NULL);
}
void TestContext::BuildBranch(HValue* value) {
// We expect the graph to be in edge-split form: there is no edge that
// connects a branch node to a join node. We conservatively ensure that
// property by always adding an empty block on the outgoing edges of this
// branch.
HGraphBuilder* builder = owner();
if (value != NULL && value->CheckFlag(HValue::kIsArguments)) {
builder->Bailout("arguments object value in a test context");
}
HBasicBlock* empty_true = builder->graph()->CreateBasicBlock();
HBasicBlock* empty_false = builder->graph()->CreateBasicBlock();
unsigned test_id = condition()->test_id();
ToBooleanStub::Types expected(builder->oracle()->ToBooleanTypes(test_id));
HBranch* test = new(zone()) HBranch(value, empty_true, empty_false, expected);
builder->current_block()->Finish(test);
empty_true->Goto(if_true(), owner()->function_state()->drop_extra());
empty_false->Goto(if_false(), owner()->function_state()->drop_extra());
builder->set_current_block(NULL);
}
// HGraphBuilder infrastructure for bailing out and checking bailouts.
#define CHECK_BAILOUT(call) \
do { \
call; \
if (HasStackOverflow()) return; \
} while (false)
#define CHECK_ALIVE(call) \
do { \
call; \
if (HasStackOverflow() || current_block() == NULL) return; \
} while (false)
void HGraphBuilder::Bailout(const char* reason) {
if (FLAG_trace_bailout) {
SmartArrayPointer<char> name(
info()->shared_info()->DebugName()->ToCString());
PrintF("Bailout in HGraphBuilder: @\"%s\": %s\n", *name, reason);
}
SetStackOverflow();
}
void HGraphBuilder::VisitForEffect(Expression* expr) {
EffectContext for_effect(this);
Visit(expr);
}
void HGraphBuilder::VisitForValue(Expression* expr, ArgumentsAllowedFlag flag) {
ValueContext for_value(this, flag);
Visit(expr);
}
void HGraphBuilder::VisitForTypeOf(Expression* expr) {
ValueContext for_value(this, ARGUMENTS_NOT_ALLOWED);
for_value.set_for_typeof(true);
Visit(expr);
}
void HGraphBuilder::VisitForControl(Expression* expr,
HBasicBlock* true_block,
HBasicBlock* false_block) {
TestContext for_test(this, expr, true_block, false_block);
Visit(expr);
}
HValue* HGraphBuilder::VisitArgument(Expression* expr) {
VisitForValue(expr);
if (HasStackOverflow() || current_block() == NULL) return NULL;
HValue* value = Pop();
Push(AddInstruction(new(zone()) HPushArgument(value)));
return value;
}
void HGraphBuilder::VisitArgumentList(ZoneList<Expression*>* arguments) {
for (int i = 0; i < arguments->length(); i++) {
CHECK_ALIVE(VisitArgument(arguments->at(i)));
}
}
void HGraphBuilder::VisitExpressions(ZoneList<Expression*>* exprs) {
for (int i = 0; i < exprs->length(); ++i) {
CHECK_ALIVE(VisitForValue(exprs->at(i)));
}
}
HGraph* HGraphBuilder::CreateGraph() {
graph_ = new(zone()) HGraph(info());
if (FLAG_hydrogen_stats) HStatistics::Instance()->Initialize(info());
{
HPhase phase("H_Block building");
current_block_ = graph()->entry_block();
Scope* scope = info()->scope();
if (scope->HasIllegalRedeclaration()) {
Bailout("function with illegal redeclaration");
return NULL;
}
if (scope->calls_eval()) {
Bailout("function calls eval");
return NULL;
}
SetUpScope(scope);
// Add an edge to the body entry. This is warty: the graph's start
// environment will be used by the Lithium translation as the initial
// environment on graph entry, but it has now been mutated by the
// Hydrogen translation of the instructions in the start block. This
// environment uses values which have not been defined yet. These
// Hydrogen instructions will then be replayed by the Lithium
// translation, so they cannot have an environment effect. The edge to
// the body's entry block (along with some special logic for the start
// block in HInstruction::InsertAfter) seals the start block from
// getting unwanted instructions inserted.
//
// TODO(kmillikin): Fix this. Stop mutating the initial environment.
// Make the Hydrogen instructions in the initial block into Hydrogen
// values (but not instructions), present in the initial environment and
// not replayed by the Lithium translation.
HEnvironment* initial_env = environment()->CopyWithoutHistory();
HBasicBlock* body_entry = CreateBasicBlock(initial_env);
current_block()->Goto(body_entry);
body_entry->SetJoinId(AstNode::kFunctionEntryId);
set_current_block(body_entry);
// Handle implicit declaration of the function name in named function
// expressions before other declarations.
if (scope->is_function_scope() && scope->function() != NULL) {
HandleDeclaration(scope->function(), CONST, NULL, NULL);
}
VisitDeclarations(scope->declarations());
AddSimulate(AstNode::kDeclarationsId);
HValue* context = environment()->LookupContext();
AddInstruction(
new(zone()) HStackCheck(context, HStackCheck::kFunctionEntry));
VisitStatements(info()->function()->body());
if (HasStackOverflow()) return NULL;
if (current_block() != NULL) {
HReturn* instr = new(zone()) HReturn(graph()->GetConstantUndefined());
current_block()->FinishExit(instr);
set_current_block(NULL);
}
}
graph()->OrderBlocks();
graph()->AssignDominators();
#ifdef DEBUG
// Do a full verify after building the graph and computing dominators.
graph()->Verify(true);
#endif
graph()->PropagateDeoptimizingMark();
if (!graph()->CheckConstPhiUses()) {
Bailout("Unsupported phi use of const variable");
return NULL;
}
graph()->EliminateRedundantPhis();
if (!graph()->CheckArgumentsPhiUses()) {
Bailout("Unsupported phi use of arguments");
return NULL;
}
if (FLAG_eliminate_dead_phis) graph()->EliminateUnreachablePhis();
graph()->CollectPhis();
if (graph()->has_osr_loop_entry()) {
const ZoneList<HPhi*>* phis = graph()->osr_loop_entry()->phis();
for (int j = 0; j < phis->length(); j++) {
HPhi* phi = phis->at(j);
graph()->osr_values()->at(phi->merged_index())->set_incoming_value(phi);
}
}
HInferRepresentation rep(graph());
rep.Analyze();
graph()->MarkDeoptimizeOnUndefined();
graph()->InsertRepresentationChanges();
graph()->InitializeInferredTypes();
graph()->Canonicalize();
// Perform common subexpression elimination and loop-invariant code motion.
if (FLAG_use_gvn) {
HPhase phase("H_Global value numbering", graph());
HGlobalValueNumberer gvn(graph(), info());
bool removed_side_effects = gvn.Analyze();
// Trigger a second analysis pass to further eliminate duplicate values that
// could only be discovered by removing side-effect-generating instructions
// during the first pass.
if (FLAG_smi_only_arrays && removed_side_effects) {
removed_side_effects = gvn.Analyze();
ASSERT(!removed_side_effects);
}
}
if (FLAG_use_range) {
HRangeAnalysis rangeAnalysis(graph());
rangeAnalysis.Analyze();
}
graph()->ComputeMinusZeroChecks();
// Eliminate redundant stack checks on backwards branches.
HStackCheckEliminator sce(graph());
sce.Process();
// Replace the results of check instructions with the original value, if the
// result is used. This is safe now, since we don't do code motion after this
// point. It enables better register allocation since the value produced by
// check instructions is really a copy of the original value.
graph()->ReplaceCheckedValues();
return graph();
}
void HGraph::ReplaceCheckedValues() {
HPhase phase("H_Replace checked values", this);
for (int i = 0; i < blocks()->length(); ++i) {
HInstruction* instr = blocks()->at(i)->first();
while (instr != NULL) {
if (instr->IsBoundsCheck()) {
// Replace all uses of the checked value with the original input.
ASSERT(instr->UseCount() > 0);
instr->ReplaceAllUsesWith(HBoundsCheck::cast(instr)->index());
}
instr = instr->next();
}
}
}
HInstruction* HGraphBuilder::AddInstruction(HInstruction* instr) {
ASSERT(current_block() != NULL);
current_block()->AddInstruction(instr);
return instr;
}
void HGraphBuilder::AddSimulate(int ast_id) {
ASSERT(current_block() != NULL);
current_block()->AddSimulate(ast_id);
}
void HGraphBuilder::AddPhi(HPhi* instr) {
ASSERT(current_block() != NULL);
current_block()->AddPhi(instr);
}
void HGraphBuilder::PushAndAdd(HInstruction* instr) {
Push(instr);
AddInstruction(instr);
}
template <class Instruction>
HInstruction* HGraphBuilder::PreProcessCall(Instruction* call) {
int count = call->argument_count();
ZoneList<HValue*> arguments(count);
for (int i = 0; i < count; ++i) {
arguments.Add(Pop());
}
while (!arguments.is_empty()) {
AddInstruction(new(zone()) HPushArgument(arguments.RemoveLast()));
}
return call;
}
void HGraphBuilder::SetUpScope(Scope* scope) {
HConstant* undefined_constant = new(zone()) HConstant(
isolate()->factory()->undefined_value(), Representation::Tagged());
AddInstruction(undefined_constant);
graph_->set_undefined_constant(undefined_constant);
HArgumentsObject* object = new(zone()) HArgumentsObject;
AddInstruction(object);
graph()->SetArgumentsObject(object);
// Set the initial values of parameters including "this". "This" has
// parameter index 0.
ASSERT_EQ(scope->num_parameters() + 1, environment()->parameter_count());
for (int i = 0; i < environment()->parameter_count(); ++i) {
HInstruction* parameter = AddInstruction(new(zone()) HParameter(i));
environment()->Bind(i, parameter);
}
// First special is HContext.
HInstruction* context = AddInstruction(new(zone()) HContext);
environment()->BindContext(context);
// Initialize specials and locals to undefined.
for (int i = environment()->parameter_count() + 1;
i < environment()->length();
++i) {
environment()->Bind(i, undefined_constant);
}
// Handle the arguments and arguments shadow variables specially (they do
// not have declarations).
if (scope->arguments() != NULL) {
if (!scope->arguments()->IsStackAllocated()) {
return Bailout("context-allocated arguments");
}
environment()->Bind(scope->arguments(),
graph()->GetArgumentsObject());
}
}
void HGraphBuilder::VisitStatements(ZoneList<Statement*>* statements) {
for (int i = 0; i < statements->length(); i++) {
CHECK_ALIVE(Visit(statements->at(i)));
}
}
HBasicBlock* HGraphBuilder::CreateBasicBlock(HEnvironment* env) {
HBasicBlock* b = graph()->CreateBasicBlock();
b->SetInitialEnvironment(env);
return b;
}
HBasicBlock* HGraphBuilder::CreateLoopHeaderBlock() {
HBasicBlock* header = graph()->CreateBasicBlock();
HEnvironment* entry_env = environment()->CopyAsLoopHeader(header);
header->SetInitialEnvironment(entry_env);
header->AttachLoopInformation();
return header;
}
void HGraphBuilder::VisitBlock(Block* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
if (stmt->block_scope() != NULL) {
return Bailout("ScopedBlock");
}
BreakAndContinueInfo break_info(stmt);
{ BreakAndContinueScope push(&break_info, this);
CHECK_BAILOUT(VisitStatements(stmt->statements()));
}
HBasicBlock* break_block = break_info.break_block();
if (break_block != NULL) {
if (current_block() != NULL) current_block()->Goto(break_block);
break_block->SetJoinId(stmt->ExitId());
set_current_block(break_block);
}
}
void HGraphBuilder::VisitExpressionStatement(ExpressionStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
VisitForEffect(stmt->expression());
}
void HGraphBuilder::VisitEmptyStatement(EmptyStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
}
void HGraphBuilder::VisitIfStatement(IfStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
if (stmt->condition()->ToBooleanIsTrue()) {
AddSimulate(stmt->ThenId());
Visit(stmt->then_statement());
} else if (stmt->condition()->ToBooleanIsFalse()) {
AddSimulate(stmt->ElseId());
Visit(stmt->else_statement());
} else {
HBasicBlock* cond_true = graph()->CreateBasicBlock();
HBasicBlock* cond_false = graph()->CreateBasicBlock();
CHECK_BAILOUT(VisitForControl(stmt->condition(), cond_true, cond_false));
if (cond_true->HasPredecessor()) {
cond_true->SetJoinId(stmt->ThenId());
set_current_block(cond_true);
CHECK_BAILOUT(Visit(stmt->then_statement()));
cond_true = current_block();
} else {
cond_true = NULL;
}
if (cond_false->HasPredecessor()) {
cond_false->SetJoinId(stmt->ElseId());
set_current_block(cond_false);
CHECK_BAILOUT(Visit(stmt->else_statement()));
cond_false = current_block();
} else {
cond_false = NULL;
}
HBasicBlock* join = CreateJoin(cond_true, cond_false, stmt->IfId());
set_current_block(join);
}
}
HBasicBlock* HGraphBuilder::BreakAndContinueScope::Get(
BreakableStatement* stmt,
BreakType type,
int* drop_extra) {
*drop_extra = 0;
BreakAndContinueScope* current = this;
while (current != NULL && current->info()->target() != stmt) {
*drop_extra += current->info()->drop_extra();
current = current->next();
}
ASSERT(current != NULL); // Always found (unless stack is malformed).
if (type == BREAK) {
*drop_extra += current->info()->drop_extra();
}
HBasicBlock* block = NULL;
switch (type) {
case BREAK:
block = current->info()->break_block();
if (block == NULL) {
block = current->owner()->graph()->CreateBasicBlock();
current->info()->set_break_block(block);
}
break;
case CONTINUE:
block = current->info()->continue_block();
if (block == NULL) {
block = current->owner()->graph()->CreateBasicBlock();
current->info()->set_continue_block(block);
}
break;
}
return block;
}
void HGraphBuilder::VisitContinueStatement(ContinueStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
int drop_extra = 0;
HBasicBlock* continue_block = break_scope()->Get(stmt->target(),
CONTINUE,
&drop_extra);
Drop(drop_extra);
current_block()->Goto(continue_block);
set_current_block(NULL);
}
void HGraphBuilder::VisitBreakStatement(BreakStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
int drop_extra = 0;
HBasicBlock* break_block = break_scope()->Get(stmt->target(),
BREAK,
&drop_extra);
Drop(drop_extra);
current_block()->Goto(break_block);
set_current_block(NULL);
}
void HGraphBuilder::VisitReturnStatement(ReturnStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
AstContext* context = call_context();
if (context == NULL) {
// Not an inlined return, so an actual one.
CHECK_ALIVE(VisitForValue(stmt->expression()));
HValue* result = environment()->Pop();
current_block()->FinishExit(new(zone()) HReturn(result));
} else if (function_state()->is_construct()) {
// Return from an inlined construct call. In a test context the return
// value will always evaluate to true, in a value context the return value
// needs to be a JSObject.
if (context->IsTest()) {
TestContext* test = TestContext::cast(context);
CHECK_ALIVE(VisitForEffect(stmt->expression()));
current_block()->Goto(test->if_true(), function_state()->drop_extra());
} else if (context->IsEffect()) {
CHECK_ALIVE(VisitForEffect(stmt->expression()));
current_block()->Goto(function_return(), function_state()->drop_extra());
} else {
ASSERT(context->IsValue());
CHECK_ALIVE(VisitForValue(stmt->expression()));
HValue* return_value = Pop();
HValue* receiver = environment()->Lookup(0);
HHasInstanceTypeAndBranch* typecheck =
new(zone()) HHasInstanceTypeAndBranch(return_value,
FIRST_SPEC_OBJECT_TYPE,
LAST_SPEC_OBJECT_TYPE);
HBasicBlock* if_spec_object = graph()->CreateBasicBlock();
HBasicBlock* not_spec_object = graph()->CreateBasicBlock();
typecheck->SetSuccessorAt(0, if_spec_object);
typecheck->SetSuccessorAt(1, not_spec_object);
current_block()->Finish(typecheck);
if_spec_object->AddLeaveInlined(return_value,
function_return(),
function_state()->drop_extra());
not_spec_object->AddLeaveInlined(receiver,
function_return(),
function_state()->drop_extra());
}
} else {
// Return from an inlined function, visit the subexpression in the
// expression context of the call.
if (context->IsTest()) {
TestContext* test = TestContext::cast(context);
VisitForControl(stmt->expression(),
test->if_true(),
test->if_false());
} else if (context->IsEffect()) {
CHECK_ALIVE(VisitForEffect(stmt->expression()));
current_block()->Goto(function_return(), function_state()->drop_extra());
} else {
ASSERT(context->IsValue());
CHECK_ALIVE(VisitForValue(stmt->expression()));
HValue* return_value = Pop();
current_block()->AddLeaveInlined(return_value,
function_return(),
function_state()->drop_extra());
}
}
set_current_block(NULL);
}
void HGraphBuilder::VisitWithStatement(WithStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
return Bailout("WithStatement");
}
void HGraphBuilder::VisitSwitchStatement(SwitchStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
// We only optimize switch statements with smi-literal smi comparisons,
// with a bounded number of clauses.
const int kCaseClauseLimit = 128;
ZoneList<CaseClause*>* clauses = stmt->cases();
int clause_count = clauses->length();
if (clause_count > kCaseClauseLimit) {
return Bailout("SwitchStatement: too many clauses");
}
HValue* context = environment()->LookupContext();
CHECK_ALIVE(VisitForValue(stmt->tag()));
AddSimulate(stmt->EntryId());
HValue* tag_value = Pop();
HBasicBlock* first_test_block = current_block();
SwitchType switch_type = UNKNOWN_SWITCH;
// 1. Extract clause type
for (int i = 0; i < clause_count; ++i) {
CaseClause* clause = clauses->at(i);
if (clause->is_default()) continue;
if (switch_type == UNKNOWN_SWITCH) {
if (clause->label()->IsSmiLiteral()) {
switch_type = SMI_SWITCH;
} else if (clause->label()->IsStringLiteral()) {
switch_type = STRING_SWITCH;
} else {
return Bailout("SwitchStatement: non-literal switch label");
}
} else if ((switch_type == STRING_SWITCH &&
!clause->label()->IsStringLiteral()) ||
(switch_type == SMI_SWITCH &&
!clause->label()->IsSmiLiteral())) {
return Bailout("SwitchStatemnt: mixed label types are not supported");
}
}
HUnaryControlInstruction* string_check = NULL;
HBasicBlock* not_string_block = NULL;
// Test switch's tag value if all clauses are string literals
if (switch_type == STRING_SWITCH) {
string_check = new(zone()) HIsStringAndBranch(tag_value);
first_test_block = graph()->CreateBasicBlock();
not_string_block = graph()->CreateBasicBlock();
string_check->SetSuccessorAt(0, first_test_block);
string_check->SetSuccessorAt(1, not_string_block);
current_block()->Finish(string_check);
set_current_block(first_test_block);
}
// 2. Build all the tests, with dangling true branches
int default_id = AstNode::kNoNumber;
for (int i = 0; i < clause_count; ++i) {
CaseClause* clause = clauses->at(i);
if (clause->is_default()) {
default_id = clause->EntryId();
continue;
}
if (switch_type == SMI_SWITCH) {
clause->RecordTypeFeedback(oracle());
}
// Generate a compare and branch.
CHECK_ALIVE(VisitForValue(clause->label()));
HValue* label_value = Pop();
HBasicBlock* next_test_block = graph()->CreateBasicBlock();
HBasicBlock* body_block = graph()->CreateBasicBlock();
HControlInstruction* compare;
if (switch_type == SMI_SWITCH) {
if (!clause->IsSmiCompare()) {
// Finish with deoptimize and add uses of enviroment values to
// account for invisible uses.
current_block()->FinishExitWithDeoptimization(HDeoptimize::kUseAll);
set_current_block(NULL);
break;
}
HCompareIDAndBranch* compare_ =
new(zone()) HCompareIDAndBranch(tag_value,
label_value,
Token::EQ_STRICT);
compare_->SetInputRepresentation(Representation::Integer32());
compare = compare_;
} else {
compare = new(zone()) HStringCompareAndBranch(context, tag_value,
label_value,
Token::EQ_STRICT);
}
compare->SetSuccessorAt(0, body_block);
compare->SetSuccessorAt(1, next_test_block);
current_block()->Finish(compare);
set_current_block(next_test_block);
}
// Save the current block to use for the default or to join with the
// exit. This block is NULL if we deoptimized.
HBasicBlock* last_block = current_block();
if (not_string_block != NULL) {
int join_id = (default_id != AstNode::kNoNumber)
? default_id
: stmt->ExitId();
last_block = CreateJoin(last_block, not_string_block, join_id);
}
// 3. Loop over the clauses and the linked list of tests in lockstep,
// translating the clause bodies.
HBasicBlock* curr_test_block = first_test_block;
HBasicBlock* fall_through_block = NULL;
BreakAndContinueInfo break_info(stmt);
{ BreakAndContinueScope push(&break_info, this);
for (int i = 0; i < clause_count; ++i) {
CaseClause* clause = clauses->at(i);
// Identify the block where normal (non-fall-through) control flow
// goes to.
HBasicBlock* normal_block = NULL;
if (clause->is_default()) {
if (last_block != NULL) {
normal_block = last_block;
last_block = NULL; // Cleared to indicate we've handled it.
}
} else if (!curr_test_block->end()->IsDeoptimize()) {
normal_block = curr_test_block->end()->FirstSuccessor();
curr_test_block = curr_test_block->end()->SecondSuccessor();
}
// Identify a block to emit the body into.
if (normal_block == NULL) {
if (fall_through_block == NULL) {
// (a) Unreachable.
if (clause->is_default()) {
continue; // Might still be reachable clause bodies.
} else {
break;
}
} else {
// (b) Reachable only as fall through.
set_current_block(fall_through_block);
}
} else if (fall_through_block == NULL) {
// (c) Reachable only normally.
set_current_block(normal_block);
} else {
// (d) Reachable both ways.
HBasicBlock* join = CreateJoin(fall_through_block,
normal_block,
clause->EntryId());
set_current_block(join);
}
CHECK_BAILOUT(VisitStatements(clause->statements()));
fall_through_block = current_block();
}
}
// Create an up-to-3-way join. Use the break block if it exists since
// it's already a join block.
HBasicBlock* break_block = break_info.break_block();
if (break_block == NULL) {
set_current_block(CreateJoin(fall_through_block,
last_block,
stmt->ExitId()));
} else {
if (fall_through_block != NULL) fall_through_block->Goto(break_block);
if (last_block != NULL) last_block->Goto(break_block);
break_block->SetJoinId(stmt->ExitId());
set_current_block(break_block);
}
}
bool HGraphBuilder::HasOsrEntryAt(IterationStatement* statement) {
return statement->OsrEntryId() == info()->osr_ast_id();
}
bool HGraphBuilder::PreProcessOsrEntry(IterationStatement* statement) {
if (!HasOsrEntryAt(statement)) return false;
HBasicBlock* non_osr_entry = graph()->CreateBasicBlock();
HBasicBlock* osr_entry = graph()->CreateBasicBlock();
HValue* true_value = graph()->GetConstantTrue();
HBranch* test = new(zone()) HBranch(true_value, non_osr_entry, osr_entry);
current_block()->Finish(test);
HBasicBlock* loop_predecessor = graph()->CreateBasicBlock();
non_osr_entry->Goto(loop_predecessor);
set_current_block(osr_entry);
int osr_entry_id = statement->OsrEntryId();
int first_expression_index = environment()->first_expression_index();
int length = environment()->length();
ZoneList<HUnknownOSRValue*>* osr_values =
new(zone()) ZoneList<HUnknownOSRValue*>(length);
for (int i = 0; i < first_expression_index; ++i) {
HUnknownOSRValue* osr_value = new(zone()) HUnknownOSRValue;
AddInstruction(osr_value);
environment()->Bind(i, osr_value);
osr_values->Add(osr_value);
}
if (first_expression_index != length) {
environment()->Drop(length - first_expression_index);
for (int i = first_expression_index; i < length; ++i) {
HUnknownOSRValue* osr_value = new(zone()) HUnknownOSRValue;
AddInstruction(osr_value);
environment()->Push(osr_value);
osr_values->Add(osr_value);
}
}
graph()->set_osr_values(osr_values);
AddSimulate(osr_entry_id);
AddInstruction(new(zone()) HOsrEntry(osr_entry_id));
HContext* context = new(zone()) HContext;
AddInstruction(context);
environment()->BindContext(context);
current_block()->Goto(loop_predecessor);
loop_predecessor->SetJoinId(statement->EntryId());
set_current_block(loop_predecessor);
return true;
}
void HGraphBuilder::VisitLoopBody(IterationStatement* stmt,
HBasicBlock* loop_entry,
BreakAndContinueInfo* break_info) {
BreakAndContinueScope push(break_info, this);
AddSimulate(stmt->StackCheckId());
HValue* context = environment()->LookupContext();
HStackCheck* stack_check =
new(zone()) HStackCheck(context, HStackCheck::kBackwardsBranch);
AddInstruction(stack_check);
ASSERT(loop_entry->IsLoopHeader());
loop_entry->loop_information()->set_stack_check(stack_check);
CHECK_BAILOUT(Visit(stmt->body()));
}
void HGraphBuilder::VisitDoWhileStatement(DoWhileStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
ASSERT(current_block() != NULL);
bool osr_entry = PreProcessOsrEntry(stmt);
HBasicBlock* loop_entry = CreateLoopHeaderBlock();
current_block()->Goto(loop_entry);
set_current_block(loop_entry);
if (osr_entry) graph()->set_osr_loop_entry(loop_entry);
BreakAndContinueInfo break_info(stmt);
CHECK_BAILOUT(VisitLoopBody(stmt, loop_entry, &break_info));
HBasicBlock* body_exit =
JoinContinue(stmt, current_block(), break_info.continue_block());
HBasicBlock* loop_successor = NULL;
if (body_exit != NULL && !stmt->cond()->ToBooleanIsTrue()) {
set_current_block(body_exit);
// The block for a true condition, the actual predecessor block of the
// back edge.
body_exit = graph()->CreateBasicBlock();
loop_successor = graph()->CreateBasicBlock();
CHECK_BAILOUT(VisitForControl(stmt->cond(), body_exit, loop_successor));
if (body_exit->HasPredecessor()) {
body_exit->SetJoinId(stmt->BackEdgeId());
} else {
body_exit = NULL;
}
if (loop_successor->HasPredecessor()) {
loop_successor->SetJoinId(stmt->ExitId());
} else {
loop_successor = NULL;
}
}
HBasicBlock* loop_exit = CreateLoop(stmt,
loop_entry,
body_exit,
loop_successor,
break_info.break_block());
set_current_block(loop_exit);
}
void HGraphBuilder::VisitWhileStatement(WhileStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
ASSERT(current_block() != NULL);
bool osr_entry = PreProcessOsrEntry(stmt);
HBasicBlock* loop_entry = CreateLoopHeaderBlock();
current_block()->Goto(loop_entry);
set_current_block(loop_entry);
if (osr_entry) graph()->set_osr_loop_entry(loop_entry);
// If the condition is constant true, do not generate a branch.
HBasicBlock* loop_successor = NULL;
if (!stmt->cond()->ToBooleanIsTrue()) {
HBasicBlock* body_entry = graph()->CreateBasicBlock();
loop_successor = graph()->CreateBasicBlock();
CHECK_BAILOUT(VisitForControl(stmt->cond(), body_entry, loop_successor));
if (body_entry->HasPredecessor()) {
body_entry->SetJoinId(stmt->BodyId());
set_current_block(body_entry);
}
if (loop_successor->HasPredecessor()) {
loop_successor->SetJoinId(stmt->ExitId());
} else {
loop_successor = NULL;
}
}
BreakAndContinueInfo break_info(stmt);
if (current_block() != NULL) {
CHECK_BAILOUT(VisitLoopBody(stmt, loop_entry, &break_info));
}
HBasicBlock* body_exit =
JoinContinue(stmt, current_block(), break_info.continue_block());
HBasicBlock* loop_exit = CreateLoop(stmt,
loop_entry,
body_exit,
loop_successor,
break_info.break_block());
set_current_block(loop_exit);
}
void HGraphBuilder::VisitForStatement(ForStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
if (stmt->init() != NULL) {
CHECK_ALIVE(Visit(stmt->init()));
}
ASSERT(current_block() != NULL);
bool osr_entry = PreProcessOsrEntry(stmt);
HBasicBlock* loop_entry = CreateLoopHeaderBlock();
current_block()->Goto(loop_entry);
set_current_block(loop_entry);
if (osr_entry) graph()->set_osr_loop_entry(loop_entry);
HBasicBlock* loop_successor = NULL;
if (stmt->cond() != NULL) {
HBasicBlock* body_entry = graph()->CreateBasicBlock();
loop_successor = graph()->CreateBasicBlock();
CHECK_BAILOUT(VisitForControl(stmt->cond(), body_entry, loop_successor));
if (body_entry->HasPredecessor()) {
body_entry->SetJoinId(stmt->BodyId());
set_current_block(body_entry);
}
if (loop_successor->HasPredecessor()) {
loop_successor->SetJoinId(stmt->ExitId());
} else {
loop_successor = NULL;
}
}
BreakAndContinueInfo break_info(stmt);
if (current_block() != NULL) {
CHECK_BAILOUT(VisitLoopBody(stmt, loop_entry, &break_info));
}
HBasicBlock* body_exit =
JoinContinue(stmt, current_block(), break_info.continue_block());
if (stmt->next() != NULL && body_exit != NULL) {
set_current_block(body_exit);
CHECK_BAILOUT(Visit(stmt->next()));
body_exit = current_block();
}
HBasicBlock* loop_exit = CreateLoop(stmt,
loop_entry,
body_exit,
loop_successor,
break_info.break_block());
set_current_block(loop_exit);
}
void HGraphBuilder::VisitForInStatement(ForInStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
if (!FLAG_optimize_for_in) {
return Bailout("ForInStatement optimization is disabled");
}
if (!oracle()->IsForInFastCase(stmt)) {
return Bailout("ForInStatement is not fast case");
}
if (!stmt->each()->IsVariableProxy() ||
!stmt->each()->AsVariableProxy()->var()->IsStackLocal()) {
return Bailout("ForInStatement with non-local each variable");
}
Variable* each_var = stmt->each()->AsVariableProxy()->var();
CHECK_ALIVE(VisitForValue(stmt->enumerable()));
HValue* enumerable = Top(); // Leave enumerable at the top.
HInstruction* map = AddInstruction(new(zone()) HForInPrepareMap(
environment()->LookupContext(), enumerable));
AddSimulate(stmt->PrepareId());
HInstruction* array = AddInstruction(
new(zone()) HForInCacheArray(
enumerable,
map,
DescriptorArray::kEnumCacheBridgeCacheIndex));
HInstruction* array_length = AddInstruction(
new(zone()) HFixedArrayBaseLength(array));
HInstruction* start_index = AddInstruction(new(zone()) HConstant(
Handle<Object>(Smi::FromInt(0)), Representation::Integer32()));
Push(map);
Push(array);
Push(array_length);
Push(start_index);
HInstruction* index_cache = AddInstruction(
new(zone()) HForInCacheArray(
enumerable,
map,
DescriptorArray::kEnumCacheBridgeIndicesCacheIndex));
HForInCacheArray::cast(array)->set_index_cache(
HForInCacheArray::cast(index_cache));
bool osr_entry = PreProcessOsrEntry(stmt);
HBasicBlock* loop_entry = CreateLoopHeaderBlock();
current_block()->Goto(loop_entry);
set_current_block(loop_entry);
if (osr_entry) graph()->set_osr_loop_entry(loop_entry);
HValue* index = environment()->ExpressionStackAt(0);
HValue* limit = environment()->ExpressionStackAt(1);
// Check that we still have more keys.
HCompareIDAndBranch* compare_index =
new(zone()) HCompareIDAndBranch(index, limit, Token::LT);
compare_index->SetInputRepresentation(Representation::Integer32());
HBasicBlock* loop_body = graph()->CreateBasicBlock();
HBasicBlock* loop_successor = graph()->CreateBasicBlock();
compare_index->SetSuccessorAt(0, loop_body);
compare_index->SetSuccessorAt(1, loop_successor);
current_block()->Finish(compare_index);
set_current_block(loop_successor);
Drop(5);
set_current_block(loop_body);
HValue* key = AddInstruction(
new(zone()) HLoadKeyedFastElement(
environment()->ExpressionStackAt(2), // Enum cache.
environment()->ExpressionStackAt(0), // Iteration index.
HLoadKeyedFastElement::OMIT_HOLE_CHECK));
// Check if the expected map still matches that of the enumerable.
// If not just deoptimize.
AddInstruction(new(zone()) HCheckMapValue(
environment()->ExpressionStackAt(4),
environment()->ExpressionStackAt(3)));
Bind(each_var, key);
BreakAndContinueInfo break_info(stmt, 5);
CHECK_BAILOUT(VisitLoopBody(stmt, loop_entry, &break_info));
HBasicBlock* body_exit =
JoinContinue(stmt, current_block(), break_info.continue_block());
if (body_exit != NULL) {
set_current_block(body_exit);
HValue* current_index = Pop();
HInstruction* new_index = new(zone()) HAdd(environment()->LookupContext(),
current_index,
graph()->GetConstant1());
new_index->AssumeRepresentation(Representation::Integer32());
PushAndAdd(new_index);
body_exit = current_block();
}
HBasicBlock* loop_exit = CreateLoop(stmt,
loop_entry,
body_exit,
loop_successor,
break_info.break_block());
set_current_block(loop_exit);
}
void HGraphBuilder::VisitTryCatchStatement(TryCatchStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
return Bailout("TryCatchStatement");
}
void HGraphBuilder::VisitTryFinallyStatement(TryFinallyStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
return Bailout("TryFinallyStatement");
}
void HGraphBuilder::VisitDebuggerStatement(DebuggerStatement* stmt) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
return Bailout("DebuggerStatement");
}
static Handle<SharedFunctionInfo> SearchSharedFunctionInfo(
Code* unoptimized_code, FunctionLiteral* expr) {
int start_position = expr->start_position();
RelocIterator it(unoptimized_code);
for (;!it.done(); it.next()) {
RelocInfo* rinfo = it.rinfo();
if (rinfo->rmode() != RelocInfo::EMBEDDED_OBJECT) continue;
Object* obj = rinfo->target_object();
if (obj->IsSharedFunctionInfo()) {
SharedFunctionInfo* shared = SharedFunctionInfo::cast(obj);
if (shared->start_position() == start_position) {
return Handle<SharedFunctionInfo>(shared);
}
}
}
return Handle<SharedFunctionInfo>();
}
void HGraphBuilder::VisitFunctionLiteral(FunctionLiteral* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
Handle<SharedFunctionInfo> shared_info =
SearchSharedFunctionInfo(info()->shared_info()->code(),
expr);
if (shared_info.is_null()) {
shared_info = Compiler::BuildFunctionInfo(expr, info()->script());
}
// We also have a stack overflow if the recursive compilation did.
if (HasStackOverflow()) return;
HValue* context = environment()->LookupContext();
HFunctionLiteral* instr =
new(zone()) HFunctionLiteral(context, shared_info, expr->pretenure());
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::VisitSharedFunctionInfoLiteral(
SharedFunctionInfoLiteral* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
return Bailout("SharedFunctionInfoLiteral");
}
void HGraphBuilder::VisitConditional(Conditional* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
HBasicBlock* cond_true = graph()->CreateBasicBlock();
HBasicBlock* cond_false = graph()->CreateBasicBlock();
CHECK_BAILOUT(VisitForControl(expr->condition(), cond_true, cond_false));
// Visit the true and false subexpressions in the same AST context as the
// whole expression.
if (cond_true->HasPredecessor()) {
cond_true->SetJoinId(expr->ThenId());
set_current_block(cond_true);
CHECK_BAILOUT(Visit(expr->then_expression()));
cond_true = current_block();
} else {
cond_true = NULL;
}
if (cond_false->HasPredecessor()) {
cond_false->SetJoinId(expr->ElseId());
set_current_block(cond_false);
CHECK_BAILOUT(Visit(expr->else_expression()));
cond_false = current_block();
} else {
cond_false = NULL;
}
if (!ast_context()->IsTest()) {
HBasicBlock* join = CreateJoin(cond_true, cond_false, expr->id());
set_current_block(join);
if (join != NULL && !ast_context()->IsEffect()) {
return ast_context()->ReturnValue(Pop());
}
}
}
HGraphBuilder::GlobalPropertyAccess HGraphBuilder::LookupGlobalProperty(
Variable* var, LookupResult* lookup, bool is_store) {
if (var->is_this() || !info()->has_global_object()) {
return kUseGeneric;
}
Handle<GlobalObject> global(info()->global_object());
global->Lookup(*var->name(), lookup);
if (!lookup->IsFound() ||
lookup->type() != NORMAL ||
(is_store && lookup->IsReadOnly()) ||
lookup->holder() != *global) {
return kUseGeneric;
}
return kUseCell;
}
HValue* HGraphBuilder::BuildContextChainWalk(Variable* var) {
ASSERT(var->IsContextSlot());
HValue* context = environment()->LookupContext();
int length = info()->scope()->ContextChainLength(var->scope());
while (length-- > 0) {
HInstruction* context_instruction = new(zone()) HOuterContext(context);
AddInstruction(context_instruction);
context = context_instruction;
}
return context;
}
void HGraphBuilder::VisitVariableProxy(VariableProxy* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
Variable* variable = expr->var();
switch (variable->location()) {
case Variable::UNALLOCATED: {
if (variable->mode() == LET || variable->mode() == CONST_HARMONY) {
return Bailout("reference to global harmony declared variable");
}
// Handle known global constants like 'undefined' specially to avoid a
// load from a global cell for them.
Handle<Object> constant_value =
isolate()->factory()->GlobalConstantFor(variable->name());
if (!constant_value.is_null()) {
HConstant* instr =
new(zone()) HConstant(constant_value, Representation::Tagged());
return ast_context()->ReturnInstruction(instr, expr->id());
}
LookupResult lookup(isolate());
GlobalPropertyAccess type =
LookupGlobalProperty(variable, &lookup, false);
if (type == kUseCell &&
info()->global_object()->IsAccessCheckNeeded()) {
type = kUseGeneric;
}
if (type == kUseCell) {
Handle<GlobalObject> global(info()->global_object());
Handle<JSGlobalPropertyCell> cell(global->GetPropertyCell(&lookup));
HLoadGlobalCell* instr =
new(zone()) HLoadGlobalCell(cell, lookup.GetPropertyDetails());
return ast_context()->ReturnInstruction(instr, expr->id());
} else {
HValue* context = environment()->LookupContext();
HGlobalObject* global_object = new(zone()) HGlobalObject(context);
AddInstruction(global_object);
HLoadGlobalGeneric* instr =
new(zone()) HLoadGlobalGeneric(context,
global_object,
variable->name(),
ast_context()->is_for_typeof());
instr->set_position(expr->position());
return ast_context()->ReturnInstruction(instr, expr->id());
}
}
case Variable::PARAMETER:
case Variable::LOCAL: {
HValue* value = environment()->Lookup(variable);
if (value == graph()->GetConstantHole()) {
ASSERT(variable->mode() == CONST ||
variable->mode() == CONST_HARMONY ||
variable->mode() == LET);
return Bailout("reference to uninitialized variable");
}
return ast_context()->ReturnValue(value);
}
case Variable::CONTEXT: {
HValue* context = BuildContextChainWalk(variable);
HLoadContextSlot* instr = new(zone()) HLoadContextSlot(context, variable);
return ast_context()->ReturnInstruction(instr, expr->id());
}
case Variable::LOOKUP:
return Bailout("reference to a variable which requires dynamic lookup");
}
}
void HGraphBuilder::VisitLiteral(Literal* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
HConstant* instr =
new(zone()) HConstant(expr->handle(), Representation::Tagged());
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::VisitRegExpLiteral(RegExpLiteral* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
HValue* context = environment()->LookupContext();
HRegExpLiteral* instr = new(zone()) HRegExpLiteral(context,
expr->pattern(),
expr->flags(),
expr->literal_index());
return ast_context()->ReturnInstruction(instr, expr->id());
}
// Determines whether the given array or object literal boilerplate satisfies
// all limits to be considered for fast deep-copying and computes the total
// size of all objects that are part of the graph.
static bool IsFastLiteral(Handle<JSObject> boilerplate,
int max_depth,
int* max_properties,
int* total_size) {
ASSERT(max_depth >= 0 && *max_properties >= 0);
if (max_depth == 0) return false;
Handle<FixedArrayBase> elements(boilerplate->elements());
if (elements->length() > 0 &&
elements->map() != boilerplate->GetHeap()->fixed_cow_array_map()) {
if (boilerplate->HasFastDoubleElements()) {
*total_size += FixedDoubleArray::SizeFor(elements->length());
} else if (boilerplate->HasFastElements()) {
int length = elements->length();
for (int i = 0; i < length; i++) {
if ((*max_properties)-- == 0) return false;
Handle<Object> value = JSObject::GetElement(boilerplate, i);
if (value->IsJSObject()) {
Handle<JSObject> value_object = Handle<JSObject>::cast(value);
if (!IsFastLiteral(value_object,
max_depth - 1,
max_properties,
total_size)) {
return false;
}
}
}
*total_size += FixedArray::SizeFor(length);
} else {
return false;
}
}
Handle<FixedArray> properties(boilerplate->properties());
if (properties->length() > 0) {
return false;
} else {
int nof = boilerplate->map()->inobject_properties();
for (int i = 0; i < nof; i++) {
if ((*max_properties)-- == 0) return false;
Handle<Object> value(boilerplate->InObjectPropertyAt(i));
if (value->IsJSObject()) {
Handle<JSObject> value_object = Handle<JSObject>::cast(value);
if (!IsFastLiteral(value_object,
max_depth - 1,
max_properties,
total_size)) {
return false;
}
}
}
}
*total_size += boilerplate->map()->instance_size();
return true;
}
void HGraphBuilder::VisitObjectLiteral(ObjectLiteral* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
Handle<JSFunction> closure = function_state()->compilation_info()->closure();
HValue* context = environment()->LookupContext();
HInstruction* literal;
// Check whether to use fast or slow deep-copying for boilerplate.
int total_size = 0;
int max_properties = HFastLiteral::kMaxLiteralProperties;
Handle<Object> boilerplate(closure->literals()->get(expr->literal_index()));
if (boilerplate->IsJSObject() &&
IsFastLiteral(Handle<JSObject>::cast(boilerplate),
HFastLiteral::kMaxLiteralDepth,
&max_properties,
&total_size)) {
Handle<JSObject> boilerplate_object = Handle<JSObject>::cast(boilerplate);
literal = new(zone()) HFastLiteral(context,
boilerplate_object,
total_size,
expr->literal_index(),
expr->depth());
} else {
literal = new(zone()) HObjectLiteral(context,
expr->constant_properties(),
expr->fast_elements(),
expr->literal_index(),
expr->depth(),
expr->has_function());
}
// The object is expected in the bailout environment during computation
// of the property values and is the value of the entire expression.
PushAndAdd(literal);
expr->CalculateEmitStore();
for (int i = 0; i < expr->properties()->length(); i++) {
ObjectLiteral::Property* property = expr->properties()->at(i);
if (property->IsCompileTimeValue()) continue;
Literal* key = property->key();
Expression* value = property->value();
switch (property->kind()) {
case ObjectLiteral::Property::MATERIALIZED_LITERAL:
ASSERT(!CompileTimeValue::IsCompileTimeValue(value));
// Fall through.
case ObjectLiteral::Property::COMPUTED:
if (key->handle()->IsSymbol()) {
if (property->emit_store()) {
property->RecordTypeFeedback(oracle());
CHECK_ALIVE(VisitForValue(value));
HValue* value = Pop();
HInstruction* store = BuildStoreNamed(literal, value, property);
AddInstruction(store);
if (store->HasObservableSideEffects()) AddSimulate(key->id());
} else {
CHECK_ALIVE(VisitForEffect(value));
}
break;
}
// Fall through.
case ObjectLiteral::Property::PROTOTYPE:
case ObjectLiteral::Property::SETTER:
case ObjectLiteral::Property::GETTER:
return Bailout("Object literal with complex property");
default: UNREACHABLE();
}
}
if (expr->has_function()) {
// Return the result of the transformation to fast properties
// instead of the original since this operation changes the map
// of the object. This makes sure that the original object won't
// be used by other optimized code before it is transformed
// (e.g. because of code motion).
HToFastProperties* result = new(zone()) HToFastProperties(Pop());
AddInstruction(result);
return ast_context()->ReturnValue(result);
} else {
return ast_context()->ReturnValue(Pop());
}
}
void HGraphBuilder::VisitArrayLiteral(ArrayLiteral* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
ZoneList<Expression*>* subexprs = expr->values();
int length = subexprs->length();
HValue* context = environment()->LookupContext();
HInstruction* literal;
Handle<FixedArray> literals(environment()->closure()->literals());
Handle<Object> raw_boilerplate(literals->get(expr->literal_index()));
if (raw_boilerplate->IsUndefined()) {
raw_boilerplate = Runtime::CreateArrayLiteralBoilerplate(
isolate(), literals, expr->constant_elements());
if (raw_boilerplate.is_null()) {
return Bailout("array boilerplate creation failed");
}
literals->set(expr->literal_index(), *raw_boilerplate);
if (JSObject::cast(*raw_boilerplate)->elements()->map() ==
isolate()->heap()->fixed_cow_array_map()) {
isolate()->counters()->cow_arrays_created_runtime()->Increment();
}
}
Handle<JSObject> boilerplate = Handle<JSObject>::cast(raw_boilerplate);
ElementsKind boilerplate_elements_kind =
Handle<JSObject>::cast(boilerplate)->GetElementsKind();
// Check whether to use fast or slow deep-copying for boilerplate.
int total_size = 0;
int max_properties = HFastLiteral::kMaxLiteralProperties;
if (IsFastLiteral(boilerplate,
HFastLiteral::kMaxLiteralDepth,
&max_properties,
&total_size)) {
literal = new(zone()) HFastLiteral(context,
boilerplate,
total_size,
expr->literal_index(),
expr->depth());
} else {
literal = new(zone()) HArrayLiteral(context,
boilerplate,
length,
expr->literal_index(),
expr->depth());
}
// The array is expected in the bailout environment during computation
// of the property values and is the value of the entire expression.
PushAndAdd(literal);
HLoadElements* elements = NULL;
for (int i = 0; i < length; i++) {
Expression* subexpr = subexprs->at(i);
// If the subexpression is a literal or a simple materialized literal it
// is already set in the cloned array.
if (CompileTimeValue::IsCompileTimeValue(subexpr)) continue;
CHECK_ALIVE(VisitForValue(subexpr));
HValue* value = Pop();
if (!Smi::IsValid(i)) return Bailout("Non-smi key in array literal");
elements = new(zone()) HLoadElements(literal);
AddInstruction(elements);
HValue* key = AddInstruction(
new(zone()) HConstant(Handle<Object>(Smi::FromInt(i)),
Representation::Integer32()));
switch (boilerplate_elements_kind) {
case FAST_SMI_ONLY_ELEMENTS:
// Smi-only arrays need a smi check.
AddInstruction(new(zone()) HCheckSmi(value));
// Fall through.
case FAST_ELEMENTS:
AddInstruction(new(zone()) HStoreKeyedFastElement(
elements,
key,
value,
boilerplate_elements_kind));
break;
case FAST_DOUBLE_ELEMENTS:
AddInstruction(new(zone()) HStoreKeyedFastDoubleElement(elements,
key,
value));
break;
default:
UNREACHABLE();
break;
}
AddSimulate(expr->GetIdForElement(i));
}
return ast_context()->ReturnValue(Pop());
}
// Sets the lookup result and returns true if the store can be inlined.
static bool ComputeStoredField(Handle<Map> type,
Handle<String> name,
LookupResult* lookup) {
type->LookupInDescriptors(NULL, *name, lookup);
if (!lookup->IsFound()) return false;
if (lookup->type() == FIELD) return true;
return (lookup->type() == MAP_TRANSITION) &&
(type->unused_property_fields() > 0);
}
static int ComputeStoredFieldIndex(Handle<Map> type,
Handle<String> name,
LookupResult* lookup) {
ASSERT(lookup->type() == FIELD || lookup->type() == MAP_TRANSITION);
if (lookup->type() == FIELD) {
return lookup->GetLocalFieldIndexFromMap(*type);
} else {
Map* transition = lookup->GetTransitionMapFromMap(*type);
return transition->PropertyIndexFor(*name) - type->inobject_properties();
}
}
HInstruction* HGraphBuilder::BuildStoreNamedField(HValue* object,
Handle<String> name,
HValue* value,
Handle<Map> type,
LookupResult* lookup,
bool smi_and_map_check) {
if (smi_and_map_check) {
AddInstruction(new(zone()) HCheckNonSmi(object));
AddInstruction(new(zone()) HCheckMap(object, type, NULL,
ALLOW_ELEMENT_TRANSITION_MAPS));
}
int index = ComputeStoredFieldIndex(type, name, lookup);
bool is_in_object = index < 0;
int offset = index * kPointerSize;
if (index < 0) {
// Negative property indices are in-object properties, indexed
// from the end of the fixed part of the object.
offset += type->instance_size();
} else {
offset += FixedArray::kHeaderSize;
}
HStoreNamedField* instr =
new(zone()) HStoreNamedField(object, name, value, is_in_object, offset);
if (lookup->type() == MAP_TRANSITION) {
Handle<Map> transition(lookup->GetTransitionMapFromMap(*type));
instr->set_transition(transition);
// TODO(fschneider): Record the new map type of the object in the IR to
// enable elimination of redundant checks after the transition store.
instr->SetGVNFlag(kChangesMaps);
}
return instr;
}
HInstruction* HGraphBuilder::BuildStoreNamedGeneric(HValue* object,
Handle<String> name,
HValue* value) {
HValue* context = environment()->LookupContext();
return new(zone()) HStoreNamedGeneric(
context,
object,
name,
value,
function_strict_mode_flag());
}
HInstruction* HGraphBuilder::BuildStoreNamed(HValue* object,
HValue* value,
ObjectLiteral::Property* prop) {
Literal* key = prop->key()->AsLiteral();
Handle<String> name = Handle<String>::cast(key->handle());
ASSERT(!name.is_null());
LookupResult lookup(isolate());
Handle<Map> type = prop->GetReceiverType();
bool is_monomorphic = prop->IsMonomorphic() &&
ComputeStoredField(type, name, &lookup);
return is_monomorphic
? BuildStoreNamedField(object, name, value, type, &lookup,
true) // Needs smi and map check.
: BuildStoreNamedGeneric(object, name, value);
}
HInstruction* HGraphBuilder::BuildStoreNamed(HValue* object,
HValue* value,
Expression* expr) {
Property* prop = (expr->AsProperty() != NULL)
? expr->AsProperty()
: expr->AsAssignment()->target()->AsProperty();
Literal* key = prop->key()->AsLiteral();
Handle<String> name = Handle<String>::cast(key->handle());
ASSERT(!name.is_null());
LookupResult lookup(isolate());
SmallMapList* types = expr->GetReceiverTypes();
bool is_monomorphic = expr->IsMonomorphic() &&
ComputeStoredField(types->first(), name, &lookup);
return is_monomorphic
? BuildStoreNamedField(object, name, value, types->first(), &lookup,
true) // Needs smi and map check.
: BuildStoreNamedGeneric(object, name, value);
}
void HGraphBuilder::HandlePolymorphicStoreNamedField(Assignment* expr,
HValue* object,
HValue* value,
SmallMapList* types,
Handle<String> name) {
// TODO(ager): We should recognize when the prototype chains for different
// maps are identical. In that case we can avoid repeatedly generating the
// same prototype map checks.
int count = 0;
HBasicBlock* join = NULL;
for (int i = 0; i < types->length() && count < kMaxStorePolymorphism; ++i) {
Handle<Map> map = types->at(i);
LookupResult lookup(isolate());
if (ComputeStoredField(map, name, &lookup)) {
if (count == 0) {
AddInstruction(new(zone()) HCheckNonSmi(object)); // Only needed once.
join = graph()->CreateBasicBlock();
}
++count;
HBasicBlock* if_true = graph()->CreateBasicBlock();
HBasicBlock* if_false = graph()->CreateBasicBlock();
HCompareMap* compare =
new(zone()) HCompareMap(object, map, if_true, if_false);
current_block()->Finish(compare);
set_current_block(if_true);
HInstruction* instr =
BuildStoreNamedField(object, name, value, map, &lookup, false);
instr->set_position(expr->position());
// Goto will add the HSimulate for the store.
AddInstruction(instr);
if (!ast_context()->IsEffect()) Push(value);
current_block()->Goto(join);
set_current_block(if_false);
}
}
// Finish up. Unconditionally deoptimize if we've handled all the maps we
// know about and do not want to handle ones we've never seen. Otherwise
// use a generic IC.
if (count == types->length() && FLAG_deoptimize_uncommon_cases) {
current_block()->FinishExitWithDeoptimization(HDeoptimize::kNoUses);
} else {
HInstruction* instr = BuildStoreNamedGeneric(object, name, value);
instr->set_position(expr->position());
AddInstruction(instr);
if (join != NULL) {
if (!ast_context()->IsEffect()) Push(value);
current_block()->Goto(join);
} else {
// The HSimulate for the store should not see the stored value in
// effect contexts (it is not materialized at expr->id() in the
// unoptimized code).
if (instr->HasObservableSideEffects()) {
if (ast_context()->IsEffect()) {
AddSimulate(expr->id());
} else {
Push(value);
AddSimulate(expr->id());
Drop(1);
}
}
return ast_context()->ReturnValue(value);
}
}
ASSERT(join != NULL);
join->SetJoinId(expr->id());
set_current_block(join);
if (!ast_context()->IsEffect()) return ast_context()->ReturnValue(Pop());
}
void HGraphBuilder::HandlePropertyAssignment(Assignment* expr) {
Property* prop = expr->target()->AsProperty();
ASSERT(prop != NULL);
expr->RecordTypeFeedback(oracle());
CHECK_ALIVE(VisitForValue(prop->obj()));
HValue* value = NULL;
HInstruction* instr = NULL;
if (prop->key()->IsPropertyName()) {
// Named store.
CHECK_ALIVE(VisitForValue(expr->value()));
value = Pop();
HValue* object = Pop();
Literal* key = prop->key()->AsLiteral();
Handle<String> name = Handle<String>::cast(key->handle());
ASSERT(!name.is_null());
SmallMapList* types = expr->GetReceiverTypes();
LookupResult lookup(isolate());
if (expr->IsMonomorphic()) {
instr = BuildStoreNamed(object, value, expr);
} else if (types != NULL && types->length() > 1) {
HandlePolymorphicStoreNamedField(expr, object, value, types, name);
return;
} else {
instr = BuildStoreNamedGeneric(object, name, value);
}
} else {
// Keyed store.
CHECK_ALIVE(VisitForValue(prop->key()));
CHECK_ALIVE(VisitForValue(expr->value()));
value = Pop();
HValue* key = Pop();
HValue* object = Pop();
bool has_side_effects = false;
HandleKeyedElementAccess(object, key, value, expr, expr->AssignmentId(),
expr->position(),
true, // is_store
&has_side_effects);
Push(value);
ASSERT(has_side_effects); // Stores always have side effects.
AddSimulate(expr->AssignmentId());
return ast_context()->ReturnValue(Pop());
}
Push(value);
instr->set_position(expr->position());
AddInstruction(instr);
if (instr->HasObservableSideEffects()) AddSimulate(expr->AssignmentId());
return ast_context()->ReturnValue(Pop());
}
// Because not every expression has a position and there is not common
// superclass of Assignment and CountOperation, we cannot just pass the
// owning expression instead of position and ast_id separately.
void HGraphBuilder::HandleGlobalVariableAssignment(Variable* var,
HValue* value,
int position,
int ast_id) {
LookupResult lookup(isolate());
GlobalPropertyAccess type = LookupGlobalProperty(var, &lookup, true);
if (type == kUseCell) {
Handle<GlobalObject> global(info()->global_object());
Handle<JSGlobalPropertyCell> cell(global->GetPropertyCell(&lookup));
HInstruction* instr =
new(zone()) HStoreGlobalCell(value, cell, lookup.GetPropertyDetails());
instr->set_position(position);
AddInstruction(instr);
if (instr->HasObservableSideEffects()) AddSimulate(ast_id);
} else {
HValue* context = environment()->LookupContext();
HGlobalObject* global_object = new(zone()) HGlobalObject(context);
AddInstruction(global_object);
HStoreGlobalGeneric* instr =
new(zone()) HStoreGlobalGeneric(context,
global_object,
var->name(),
value,
function_strict_mode_flag());
instr->set_position(position);
AddInstruction(instr);
ASSERT(instr->HasObservableSideEffects());
if (instr->HasObservableSideEffects()) AddSimulate(ast_id);
}
}
void HGraphBuilder::HandleCompoundAssignment(Assignment* expr) {
Expression* target = expr->target();
VariableProxy* proxy = target->AsVariableProxy();
Property* prop = target->AsProperty();
ASSERT(proxy == NULL || prop == NULL);
// We have a second position recorded in the FullCodeGenerator to have
// type feedback for the binary operation.
BinaryOperation* operation = expr->binary_operation();
if (proxy != NULL) {
Variable* var = proxy->var();
if (var->mode() == LET) {
return Bailout("unsupported let compound assignment");
}
CHECK_ALIVE(VisitForValue(operation));
switch (var->location()) {
case Variable::UNALLOCATED:
HandleGlobalVariableAssignment(var,
Top(),
expr->position(),
expr->AssignmentId());
break;
case Variable::PARAMETER:
case Variable::LOCAL:
if (var->mode() == CONST) {
return Bailout("unsupported const compound assignment");
}
Bind(var, Top());
break;
case Variable::CONTEXT: {
// Bail out if we try to mutate a parameter value in a function
// using the arguments object. We do not (yet) correctly handle the
// arguments property of the function.
if (info()->scope()->arguments() != NULL) {
// Parameters will be allocated to context slots. We have no
// direct way to detect that the variable is a parameter so we do
// a linear search of the parameter variables.
int count = info()->scope()->num_parameters();
for (int i = 0; i < count; ++i) {
if (var == info()->scope()->parameter(i)) {
Bailout(
"assignment to parameter, function uses arguments object");
}
}
}
HStoreContextSlot::Mode mode;
switch (var->mode()) {
case LET:
mode = HStoreContextSlot::kCheckDeoptimize;
break;
case CONST:
return ast_context()->ReturnValue(Pop());
case CONST_HARMONY:
// This case is checked statically so no need to
// perform checks here
UNREACHABLE();
default:
mode = HStoreContextSlot::kNoCheck;
}
HValue* context = BuildContextChainWalk(var);
HStoreContextSlot* instr =
new(zone()) HStoreContextSlot(context, var->index(), mode, Top());
AddInstruction(instr);
if (instr->HasObservableSideEffects()) {
AddSimulate(expr->AssignmentId());
}
break;
}
case Variable::LOOKUP:
return Bailout("compound assignment to lookup slot");
}
return ast_context()->ReturnValue(Pop());
} else if (prop != NULL) {
prop->RecordTypeFeedback(oracle());
if (prop->key()->IsPropertyName()) {
// Named property.
CHECK_ALIVE(VisitForValue(prop->obj()));
HValue* obj = Top();
HInstruction* load = NULL;
if (prop->IsMonomorphic()) {
Handle<String> name = prop->key()->AsLiteral()->AsPropertyName();
Handle<Map> map = prop->GetReceiverTypes()->first();
load = BuildLoadNamed(obj, prop, map, name);
} else {
load = BuildLoadNamedGeneric(obj, prop);
}
PushAndAdd(load);
if (load->HasObservableSideEffects()) AddSimulate(expr->CompoundLoadId());
CHECK_ALIVE(VisitForValue(expr->value()));
HValue* right = Pop();
HValue* left = Pop();
HInstruction* instr = BuildBinaryOperation(operation, left, right);
PushAndAdd(instr);
if (instr->HasObservableSideEffects()) AddSimulate(operation->id());
HInstruction* store = BuildStoreNamed(obj, instr, prop);
AddInstruction(store);
// Drop the simulated receiver and value. Return the value.
Drop(2);
Push(instr);
if (store->HasObservableSideEffects()) AddSimulate(expr->AssignmentId());
return ast_context()->ReturnValue(Pop());
} else {
// Keyed property.
CHECK_ALIVE(VisitForValue(prop->obj()));
CHECK_ALIVE(VisitForValue(prop->key()));
HValue* obj = environment()->ExpressionStackAt(1);
HValue* key = environment()->ExpressionStackAt(0);
bool has_side_effects = false;
HValue* load = HandleKeyedElementAccess(
obj, key, NULL, prop, expr->CompoundLoadId(), RelocInfo::kNoPosition,
false, // is_store
&has_side_effects);
Push(load);
if (has_side_effects) AddSimulate(expr->CompoundLoadId());
CHECK_ALIVE(VisitForValue(expr->value()));
HValue* right = Pop();
HValue* left = Pop();
HInstruction* instr = BuildBinaryOperation(operation, left, right);
PushAndAdd(instr);
if (instr->HasObservableSideEffects()) AddSimulate(operation->id());
expr->RecordTypeFeedback(oracle());
HandleKeyedElementAccess(obj, key, instr, expr, expr->AssignmentId(),
RelocInfo::kNoPosition,
true, // is_store
&has_side_effects);
// Drop the simulated receiver, key, and value. Return the value.
Drop(3);
Push(instr);
ASSERT(has_side_effects); // Stores always have side effects.
AddSimulate(expr->AssignmentId());
return ast_context()->ReturnValue(Pop());
}
} else {
return Bailout("invalid lhs in compound assignment");
}
}
void HGraphBuilder::VisitAssignment(Assignment* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
VariableProxy* proxy = expr->target()->AsVariableProxy();
Property* prop = expr->target()->AsProperty();
ASSERT(proxy == NULL || prop == NULL);
if (expr->is_compound()) {
HandleCompoundAssignment(expr);
return;
}
if (prop != NULL) {
HandlePropertyAssignment(expr);
} else if (proxy != NULL) {
Variable* var = proxy->var();
if (var->mode() == CONST) {
if (expr->op() != Token::INIT_CONST) {
CHECK_ALIVE(VisitForValue(expr->value()));
return ast_context()->ReturnValue(Pop());
}
if (var->IsStackAllocated()) {
// We insert a use of the old value to detect unsupported uses of const
// variables (e.g. initialization inside a loop).
HValue* old_value = environment()->Lookup(var);
AddInstruction(new HUseConst(old_value));
}
} else if (var->mode() == CONST_HARMONY) {
if (expr->op() != Token::INIT_CONST_HARMONY) {
return Bailout("non-initializer assignment to const");
}
}
if (proxy->IsArguments()) return Bailout("assignment to arguments");
// Handle the assignment.
switch (var->location()) {
case Variable::UNALLOCATED:
CHECK_ALIVE(VisitForValue(expr->value()));
HandleGlobalVariableAssignment(var,
Top(),
expr->position(),
expr->AssignmentId());
return ast_context()->ReturnValue(Pop());
case Variable::PARAMETER:
case Variable::LOCAL: {
// Perform an initialization check for let declared variables
// or parameters.
if (var->mode() == LET && expr->op() == Token::ASSIGN) {
HValue* env_value = environment()->Lookup(var);
if (env_value == graph()->GetConstantHole()) {
return Bailout("assignment to let variable before initialization");
}
}
// We do not allow the arguments object to occur in a context where it
// may escape, but assignments to stack-allocated locals are
// permitted.
CHECK_ALIVE(VisitForValue(expr->value(), ARGUMENTS_ALLOWED));
HValue* value = Pop();
Bind(var, value);
return ast_context()->ReturnValue(value);
}
case Variable::CONTEXT: {
// Bail out if we try to mutate a parameter value in a function using
// the arguments object. We do not (yet) correctly handle the
// arguments property of the function.
if (info()->scope()->arguments() != NULL) {
// Parameters will rewrite to context slots. We have no direct way
// to detect that the variable is a parameter.
int count = info()->scope()->num_parameters();
for (int i = 0; i < count; ++i) {
if (var == info()->scope()->parameter(i)) {
return Bailout("assignment to parameter in arguments object");
}
}
}
CHECK_ALIVE(VisitForValue(expr->value()));
HStoreContextSlot::Mode mode;
if (expr->op() == Token::ASSIGN) {
switch (var->mode()) {
case LET:
mode = HStoreContextSlot::kCheckDeoptimize;
break;
case CONST:
return ast_context()->ReturnValue(Pop());
case CONST_HARMONY:
// This case is checked statically so no need to
// perform checks here
UNREACHABLE();
default:
mode = HStoreContextSlot::kNoCheck;
}
} else if (expr->op() == Token::INIT_VAR ||
expr->op() == Token::INIT_LET ||
expr->op() == Token::INIT_CONST_HARMONY) {
mode = HStoreContextSlot::kNoCheck;
} else {
ASSERT(expr->op() == Token::INIT_CONST);
mode = HStoreContextSlot::kCheckIgnoreAssignment;
}
HValue* context = BuildContextChainWalk(var);
HStoreContextSlot* instr = new(zone()) HStoreContextSlot(
context, var->index(), mode, Top());
AddInstruction(instr);
if (instr->HasObservableSideEffects()) {
AddSimulate(expr->AssignmentId());
}
return ast_context()->ReturnValue(Pop());
}
case Variable::LOOKUP:
return Bailout("assignment to LOOKUP variable");
}
} else {
return Bailout("invalid left-hand side in assignment");
}
}
void HGraphBuilder::VisitThrow(Throw* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
// We don't optimize functions with invalid left-hand sides in
// assignments, count operations, or for-in. Consequently throw can
// currently only occur in an effect context.
ASSERT(ast_context()->IsEffect());
CHECK_ALIVE(VisitForValue(expr->exception()));
HValue* context = environment()->LookupContext();
HValue* value = environment()->Pop();
HThrow* instr = new(zone()) HThrow(context, value);
instr->set_position(expr->position());
AddInstruction(instr);
AddSimulate(expr->id());
current_block()->FinishExit(new(zone()) HAbnormalExit);
set_current_block(NULL);
}
HLoadNamedField* HGraphBuilder::BuildLoadNamedField(HValue* object,
Property* expr,
Handle<Map> type,
LookupResult* lookup,
bool smi_and_map_check) {
if (smi_and_map_check) {
AddInstruction(new(zone()) HCheckNonSmi(object));
AddInstruction(new(zone()) HCheckMap(object, type, NULL,
ALLOW_ELEMENT_TRANSITION_MAPS));
}
int index = lookup->GetLocalFieldIndexFromMap(*type);
if (index < 0) {
// Negative property indices are in-object properties, indexed
// from the end of the fixed part of the object.
int offset = (index * kPointerSize) + type->instance_size();
return new(zone()) HLoadNamedField(object, true, offset);
} else {
// Non-negative property indices are in the properties array.
int offset = (index * kPointerSize) + FixedArray::kHeaderSize;
return new(zone()) HLoadNamedField(object, false, offset);
}
}
HInstruction* HGraphBuilder::BuildLoadNamedGeneric(HValue* obj,
Property* expr) {
if (expr->IsUninitialized() && !FLAG_always_opt) {
AddInstruction(new(zone()) HSoftDeoptimize);
current_block()->MarkAsDeoptimizing();
}
ASSERT(expr->key()->IsPropertyName());
Handle<Object> name = expr->key()->AsLiteral()->handle();
HValue* context = environment()->LookupContext();
return new(zone()) HLoadNamedGeneric(context, obj, name);
}
HInstruction* HGraphBuilder::BuildLoadNamed(HValue* obj,
Property* expr,
Handle<Map> map,
Handle<String> name) {
LookupResult lookup(isolate());
map->LookupInDescriptors(NULL, *name, &lookup);
if (lookup.IsFound() && lookup.type() == FIELD) {
return BuildLoadNamedField(obj,
expr,
map,
&lookup,
true);
} else if (lookup.IsFound() && lookup.type() == CONSTANT_FUNCTION) {
AddInstruction(new(zone()) HCheckNonSmi(obj));
AddInstruction(new(zone()) HCheckMap(obj, map, NULL,
ALLOW_ELEMENT_TRANSITION_MAPS));
Handle<JSFunction> function(lookup.GetConstantFunctionFromMap(*map));
return new(zone()) HConstant(function, Representation::Tagged());
} else {
return BuildLoadNamedGeneric(obj, expr);
}
}
HInstruction* HGraphBuilder::BuildLoadKeyedGeneric(HValue* object,
HValue* key) {
HValue* context = environment()->LookupContext();
return new(zone()) HLoadKeyedGeneric(context, object, key);
}
HInstruction* HGraphBuilder::BuildExternalArrayElementAccess(
HValue* external_elements,
HValue* checked_key,
HValue* val,
ElementsKind elements_kind,
bool is_store) {
if (is_store) {
ASSERT(val != NULL);
switch (elements_kind) {
case EXTERNAL_PIXEL_ELEMENTS: {
val = AddInstruction(new(zone()) HClampToUint8(val));
break;
}
case EXTERNAL_BYTE_ELEMENTS:
case EXTERNAL_UNSIGNED_BYTE_ELEMENTS:
case EXTERNAL_SHORT_ELEMENTS:
case EXTERNAL_UNSIGNED_SHORT_ELEMENTS:
case EXTERNAL_INT_ELEMENTS:
case EXTERNAL_UNSIGNED_INT_ELEMENTS: {
if (!val->representation().IsInteger32()) {
val = AddInstruction(new(zone()) HChange(
val,
Representation::Integer32(),
true, // Truncate to int32.
false)); // Don't deoptimize undefined (irrelevant here).
}
break;
}
case EXTERNAL_FLOAT_ELEMENTS:
case EXTERNAL_DOUBLE_ELEMENTS:
break;
case FAST_SMI_ONLY_ELEMENTS:
case FAST_ELEMENTS:
case FAST_DOUBLE_ELEMENTS:
case DICTIONARY_ELEMENTS:
case NON_STRICT_ARGUMENTS_ELEMENTS:
UNREACHABLE();
break;
}
return new(zone()) HStoreKeyedSpecializedArrayElement(
external_elements, checked_key, val, elements_kind);
} else {
ASSERT(val == NULL);
return new(zone()) HLoadKeyedSpecializedArrayElement(
external_elements, checked_key, elements_kind);
}
}
HInstruction* HGraphBuilder::BuildFastElementAccess(HValue* elements,
HValue* checked_key,
HValue* val,
ElementsKind elements_kind,
bool is_store) {
if (is_store) {
ASSERT(val != NULL);
switch (elements_kind) {
case FAST_DOUBLE_ELEMENTS:
return new(zone()) HStoreKeyedFastDoubleElement(
elements, checked_key, val);
case FAST_SMI_ONLY_ELEMENTS:
// Smi-only arrays need a smi check.
AddInstruction(new(zone()) HCheckSmi(val));
// Fall through.
case FAST_ELEMENTS:
return new(zone()) HStoreKeyedFastElement(
elements, checked_key, val, elements_kind);
default:
UNREACHABLE();
return NULL;
}
}
// It's an element load (!is_store).
if (elements_kind == FAST_DOUBLE_ELEMENTS) {
return new(zone()) HLoadKeyedFastDoubleElement(elements, checked_key);
} else { // FAST_ELEMENTS or FAST_SMI_ONLY_ELEMENTS.
return new(zone()) HLoadKeyedFastElement(elements, checked_key);
}
}
HInstruction* HGraphBuilder::BuildMonomorphicElementAccess(HValue* object,
HValue* key,
HValue* val,
Handle<Map> map,
bool is_store) {
HInstruction* mapcheck = AddInstruction(new(zone()) HCheckMap(object, map));
bool fast_smi_only_elements = map->has_fast_smi_only_elements();
bool fast_elements = map->has_fast_elements();
HInstruction* elements = AddInstruction(new(zone()) HLoadElements(object));
if (is_store && (fast_elements || fast_smi_only_elements)) {
AddInstruction(new(zone()) HCheckMap(
elements, isolate()->factory()->fixed_array_map()));
}
HInstruction* length = NULL;
HInstruction* checked_key = NULL;
if (map->has_external_array_elements()) {
length = AddInstruction(new(zone()) HFixedArrayBaseLength(elements));
checked_key = AddInstruction(new(zone()) HBoundsCheck(key, length));
HLoadExternalArrayPointer* external_elements =
new(zone()) HLoadExternalArrayPointer(elements);
AddInstruction(external_elements);
return BuildExternalArrayElementAccess(external_elements, checked_key,
val, map->elements_kind(), is_store);
}
ASSERT(fast_smi_only_elements ||
fast_elements ||
map->has_fast_double_elements());
if (map->instance_type() == JS_ARRAY_TYPE) {
length = AddInstruction(new(zone()) HJSArrayLength(object, mapcheck));
} else {
length = AddInstruction(new(zone()) HFixedArrayBaseLength(elements));
}
checked_key = AddInstruction(new(zone()) HBoundsCheck(key, length));
return BuildFastElementAccess(elements, checked_key, val,
map->elements_kind(), is_store);
}
HValue* HGraphBuilder::HandlePolymorphicElementAccess(HValue* object,
HValue* key,
HValue* val,
Expression* prop,
int ast_id,
int position,
bool is_store,
bool* has_side_effects) {
*has_side_effects = false;
AddInstruction(new(zone()) HCheckNonSmi(object));
SmallMapList* maps = prop->GetReceiverTypes();
bool todo_external_array = false;
static const int kNumElementTypes = kElementsKindCount;
bool type_todo[kNumElementTypes];
for (int i = 0; i < kNumElementTypes; ++i) {
type_todo[i] = false;
}
// Elements_kind transition support.
MapHandleList transition_target(maps->length());
// Collect possible transition targets.
MapHandleList possible_transitioned_maps(maps->length());
for (int i = 0; i < maps->length(); ++i) {
Handle<Map> map = maps->at(i);
ElementsKind elements_kind = map->elements_kind();
if (elements_kind == FAST_DOUBLE_ELEMENTS ||
elements_kind == FAST_ELEMENTS) {
possible_transitioned_maps.Add(map);
}
}
// Get transition target for each map (NULL == no transition).
for (int i = 0; i < maps->length(); ++i) {
Handle<Map> map = maps->at(i);
Handle<Map> transitioned_map =
map->FindTransitionedMap(&possible_transitioned_maps);
transition_target.Add(transitioned_map);
}
int num_untransitionable_maps = 0;
Handle<Map> untransitionable_map;
for (int i = 0; i < maps->length(); ++i) {
Handle<Map> map = maps->at(i);
ASSERT(map->IsMap());
if (!transition_target.at(i).is_null()) {
AddInstruction(new(zone()) HTransitionElementsKind(
object, map, transition_target.at(i)));
} else {
type_todo[map->elements_kind()] = true;
if (map->elements_kind() >= FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND) {
todo_external_array = true;
}
num_untransitionable_maps++;
untransitionable_map = map;
}
}
// If only one map is left after transitioning, handle this case
// monomorphically.
if (num_untransitionable_maps == 1) {
HInstruction* instr = NULL;
if (untransitionable_map->has_slow_elements_kind()) {
instr = AddInstruction(is_store ? BuildStoreKeyedGeneric(object, key, val)
: BuildLoadKeyedGeneric(object, key));
} else {
instr = AddInstruction(BuildMonomorphicElementAccess(
object, key, val, untransitionable_map, is_store));
}
*has_side_effects |= instr->HasObservableSideEffects();
instr->set_position(position);
return is_store ? NULL : instr;
}
AddInstruction(HCheckInstanceType::NewIsSpecObject(object));
HBasicBlock* join = graph()->CreateBasicBlock();
HInstruction* elements_kind_instr =
AddInstruction(new(zone()) HElementsKind(object));
HCompareConstantEqAndBranch* elements_kind_branch = NULL;
HInstruction* elements = AddInstruction(new(zone()) HLoadElements(object));
HLoadExternalArrayPointer* external_elements = NULL;
HInstruction* checked_key = NULL;
// Generated code assumes that FAST_SMI_ONLY_ELEMENTS, FAST_ELEMENTS,
// FAST_DOUBLE_ELEMENTS and DICTIONARY_ELEMENTS are handled before external
// arrays.
STATIC_ASSERT(FAST_SMI_ONLY_ELEMENTS < FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND);
STATIC_ASSERT(FAST_ELEMENTS < FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND);
STATIC_ASSERT(FAST_DOUBLE_ELEMENTS < FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND);
STATIC_ASSERT(DICTIONARY_ELEMENTS < FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND);
for (ElementsKind elements_kind = FIRST_ELEMENTS_KIND;
elements_kind <= LAST_ELEMENTS_KIND;
elements_kind = ElementsKind(elements_kind + 1)) {
// After having handled FAST_ELEMENTS, FAST_SMI_ONLY_ELEMENTS,
// FAST_DOUBLE_ELEMENTS and DICTIONARY_ELEMENTS, we need to add some code
// that's executed for all external array cases.
STATIC_ASSERT(LAST_EXTERNAL_ARRAY_ELEMENTS_KIND ==
LAST_ELEMENTS_KIND);
if (elements_kind == FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND
&& todo_external_array) {
HInstruction* length =
AddInstruction(new(zone()) HFixedArrayBaseLength(elements));
checked_key = AddInstruction(new(zone()) HBoundsCheck(key, length));
external_elements = new(zone()) HLoadExternalArrayPointer(elements);
AddInstruction(external_elements);
}
if (type_todo[elements_kind]) {
HBasicBlock* if_true = graph()->CreateBasicBlock();
HBasicBlock* if_false = graph()->CreateBasicBlock();
elements_kind_branch = new(zone()) HCompareConstantEqAndBranch(
elements_kind_instr, elements_kind, Token::EQ_STRICT);
elements_kind_branch->SetSuccessorAt(0, if_true);
elements_kind_branch->SetSuccessorAt(1, if_false);
current_block()->Finish(elements_kind_branch);
set_current_block(if_true);
HInstruction* access;
if (elements_kind == FAST_SMI_ONLY_ELEMENTS ||
elements_kind == FAST_ELEMENTS ||
elements_kind == FAST_DOUBLE_ELEMENTS) {
if (is_store && elements_kind != FAST_DOUBLE_ELEMENTS) {
AddInstruction(new(zone()) HCheckMap(
elements, isolate()->factory()->fixed_array_map(),
elements_kind_branch));
}
// TODO(jkummerow): The need for these two blocks could be avoided
// in one of two ways:
// (1) Introduce ElementsKinds for JSArrays that are distinct from
// those for fast objects.
// (2) Put the common instructions into a third "join" block. This
// requires additional AST IDs that we can deopt to from inside
// that join block. They must be added to the Property class (when
// it's a keyed property) and registered in the full codegen.
HBasicBlock* if_jsarray = graph()->CreateBasicBlock();
HBasicBlock* if_fastobject = graph()->CreateBasicBlock();
HHasInstanceTypeAndBranch* typecheck =
new(zone()) HHasInstanceTypeAndBranch(object, JS_ARRAY_TYPE);
typecheck->SetSuccessorAt(0, if_jsarray);
typecheck->SetSuccessorAt(1, if_fastobject);
current_block()->Finish(typecheck);
set_current_block(if_jsarray);
HInstruction* length;
length = AddInstruction(new(zone()) HJSArrayLength(object, typecheck));
checked_key = AddInstruction(new(zone()) HBoundsCheck(key, length));
access = AddInstruction(BuildFastElementAccess(
elements, checked_key, val, elements_kind, is_store));
if (!is_store) {
Push(access);
}
*has_side_effects |= access->HasObservableSideEffects();
if (position != -1) {
access->set_position(position);
}
if_jsarray->Goto(join);
set_current_block(if_fastobject);
length = AddInstruction(new(zone()) HFixedArrayBaseLength(elements));
checked_key = AddInstruction(new(zone()) HBoundsCheck(key, length));
access = AddInstruction(BuildFastElementAccess(
elements, checked_key, val, elements_kind, is_store));
} else if (elements_kind == DICTIONARY_ELEMENTS) {
if (is_store) {
access = AddInstruction(BuildStoreKeyedGeneric(object, key, val));
} else {
access = AddInstruction(BuildLoadKeyedGeneric(object, key));
}
} else { // External array elements.
access = AddInstruction(BuildExternalArrayElementAccess(
external_elements, checked_key, val, elements_kind, is_store));
}
*has_side_effects |= access->HasObservableSideEffects();
access->set_position(position);
if (!is_store) {
Push(access);
}
current_block()->Goto(join);
set_current_block(if_false);
}
}
// Deopt if none of the cases matched.
current_block()->FinishExitWithDeoptimization(HDeoptimize::kNoUses);
join->SetJoinId(ast_id);
set_current_block(join);
return is_store ? NULL : Pop();
}
HValue* HGraphBuilder::HandleKeyedElementAccess(HValue* obj,
HValue* key,
HValue* val,
Expression* expr,
int ast_id,
int position,
bool is_store,
bool* has_side_effects) {
ASSERT(!expr->IsPropertyName());
HInstruction* instr = NULL;
if (expr->IsMonomorphic()) {
Handle<Map> map = expr->GetMonomorphicReceiverType();
if (map->has_slow_elements_kind()) {
instr = is_store ? BuildStoreKeyedGeneric(obj, key, val)
: BuildLoadKeyedGeneric(obj, key);
} else {
AddInstruction(new(zone()) HCheckNonSmi(obj));
instr = BuildMonomorphicElementAccess(obj, key, val, map, is_store);
}
} else if (expr->GetReceiverTypes() != NULL &&
!expr->GetReceiverTypes()->is_empty()) {
return HandlePolymorphicElementAccess(
obj, key, val, expr, ast_id, position, is_store, has_side_effects);
} else {
if (is_store) {
instr = BuildStoreKeyedGeneric(obj, key, val);
} else {
instr = BuildLoadKeyedGeneric(obj, key);
}
}
instr->set_position(position);
AddInstruction(instr);
*has_side_effects = instr->HasObservableSideEffects();
return instr;
}
HInstruction* HGraphBuilder::BuildStoreKeyedGeneric(HValue* object,
HValue* key,
HValue* value) {
HValue* context = environment()->LookupContext();
return new(zone()) HStoreKeyedGeneric(
context,
object,
key,
value,
function_strict_mode_flag());
}
bool HGraphBuilder::TryArgumentsAccess(Property* expr) {
VariableProxy* proxy = expr->obj()->AsVariableProxy();
if (proxy == NULL) return false;
if (!proxy->var()->IsStackAllocated()) return false;
if (!environment()->Lookup(proxy->var())->CheckFlag(HValue::kIsArguments)) {
return false;
}
// Our implementation of arguments (based on this stack frame or an
// adapter below it) does not work for inlined functions.
if (function_state()->outer() != NULL) {
Bailout("arguments access in inlined function");
return true;
}
HInstruction* result = NULL;
if (expr->key()->IsPropertyName()) {
Handle<String> name = expr->key()->AsLiteral()->AsPropertyName();
if (!name->IsEqualTo(CStrVector("length"))) return false;
HInstruction* elements = AddInstruction(new(zone()) HArgumentsElements);
result = new(zone()) HArgumentsLength(elements);
} else {
Push(graph()->GetArgumentsObject());
VisitForValue(expr->key());
if (HasStackOverflow() || current_block() == NULL) return true;
HValue* key = Pop();
Drop(1); // Arguments object.
HInstruction* elements = AddInstruction(new(zone()) HArgumentsElements);
HInstruction* length = AddInstruction(
new(zone()) HArgumentsLength(elements));
HInstruction* checked_key =
AddInstruction(new(zone()) HBoundsCheck(key, length));
result = new(zone()) HAccessArgumentsAt(elements, length, checked_key);
}
ast_context()->ReturnInstruction(result, expr->id());
return true;
}
void HGraphBuilder::VisitProperty(Property* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
expr->RecordTypeFeedback(oracle());
if (TryArgumentsAccess(expr)) return;
CHECK_ALIVE(VisitForValue(expr->obj()));
HInstruction* instr = NULL;
if (expr->AsProperty()->IsArrayLength()) {
HValue* array = Pop();
AddInstruction(new(zone()) HCheckNonSmi(array));
HInstruction* mapcheck =
AddInstruction(HCheckInstanceType::NewIsJSArray(array));
instr = new(zone()) HJSArrayLength(array, mapcheck);
} else if (expr->IsStringLength()) {
HValue* string = Pop();
AddInstruction(new(zone()) HCheckNonSmi(string));
AddInstruction(HCheckInstanceType::NewIsString(string));
instr = new(zone()) HStringLength(string);
} else if (expr->IsStringAccess()) {
CHECK_ALIVE(VisitForValue(expr->key()));
HValue* index = Pop();
HValue* string = Pop();
HValue* context = environment()->LookupContext();
HStringCharCodeAt* char_code =
BuildStringCharCodeAt(context, string, index);
AddInstruction(char_code);
instr = new(zone()) HStringCharFromCode(context, char_code);
} else if (expr->IsFunctionPrototype()) {
HValue* function = Pop();
AddInstruction(new(zone()) HCheckNonSmi(function));
instr = new(zone()) HLoadFunctionPrototype(function);
} else if (expr->key()->IsPropertyName()) {
Handle<String> name = expr->key()->AsLiteral()->AsPropertyName();
SmallMapList* types = expr->GetReceiverTypes();
HValue* obj = Pop();
if (expr->IsMonomorphic()) {
instr = BuildLoadNamed(obj, expr, types->first(), name);
} else if (types != NULL && types->length() > 1) {
AddInstruction(new(zone()) HCheckNonSmi(obj));
HValue* context = environment()->LookupContext();
instr = new(zone()) HLoadNamedFieldPolymorphic(context, obj, types, name);
} else {
instr = BuildLoadNamedGeneric(obj, expr);
}
} else {
CHECK_ALIVE(VisitForValue(expr->key()));
HValue* key = Pop();
HValue* obj = Pop();
bool has_side_effects = false;
HValue* load = HandleKeyedElementAccess(
obj, key, NULL, expr, expr->id(), expr->position(),
false, // is_store
&has_side_effects);
if (has_side_effects) {
if (ast_context()->IsEffect()) {
AddSimulate(expr->id());
} else {
Push(load);
AddSimulate(expr->id());
Drop(1);
}
}
return ast_context()->ReturnValue(load);
}
instr->set_position(expr->position());
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::AddCheckConstantFunction(Call* expr,
HValue* receiver,
Handle<Map> receiver_map,
bool smi_and_map_check) {
// Constant functions have the nice property that the map will change if they
// are overwritten. Therefore it is enough to check the map of the holder and
// its prototypes.
if (smi_and_map_check) {
AddInstruction(new(zone()) HCheckNonSmi(receiver));
AddInstruction(new(zone()) HCheckMap(receiver, receiver_map, NULL,
ALLOW_ELEMENT_TRANSITION_MAPS));
}
if (!expr->holder().is_null()) {
AddInstruction(new(zone()) HCheckPrototypeMaps(
Handle<JSObject>(JSObject::cast(receiver_map->prototype())),
expr->holder()));
}
}
void HGraphBuilder::HandlePolymorphicCallNamed(Call* expr,
HValue* receiver,
SmallMapList* types,
Handle<String> name) {
// TODO(ager): We should recognize when the prototype chains for different
// maps are identical. In that case we can avoid repeatedly generating the
// same prototype map checks.
int argument_count = expr->arguments()->length() + 1; // Includes receiver.
int count = 0;
HBasicBlock* join = NULL;
for (int i = 0; i < types->length() && count < kMaxCallPolymorphism; ++i) {
Handle<Map> map = types->at(i);
if (expr->ComputeTarget(map, name)) {
if (count == 0) {
// Only needed once.
AddInstruction(new(zone()) HCheckNonSmi(receiver));
join = graph()->CreateBasicBlock();
}
++count;
HBasicBlock* if_true = graph()->CreateBasicBlock();
HBasicBlock* if_false = graph()->CreateBasicBlock();
HCompareMap* compare =
new(zone()) HCompareMap(receiver, map, if_true, if_false);
current_block()->Finish(compare);
set_current_block(if_true);
AddCheckConstantFunction(expr, receiver, map, false);
if (FLAG_trace_inlining && FLAG_polymorphic_inlining) {
PrintF("Trying to inline the polymorphic call to %s\n",
*name->ToCString());
}
if (FLAG_polymorphic_inlining && TryInlineCall(expr)) {
// Trying to inline will signal that we should bailout from the
// entire compilation by setting stack overflow on the visitor.
if (HasStackOverflow()) return;
} else {
HCallConstantFunction* call =
new(zone()) HCallConstantFunction(expr->target(), argument_count);
call->set_position(expr->position());
PreProcessCall(call);
AddInstruction(call);
if (!ast_context()->IsEffect()) Push(call);
}
if (current_block() != NULL) current_block()->Goto(join);
set_current_block(if_false);
}
}
// Finish up. Unconditionally deoptimize if we've handled all the maps we
// know about and do not want to handle ones we've never seen. Otherwise
// use a generic IC.
if (count == types->length() && FLAG_deoptimize_uncommon_cases) {
current_block()->FinishExitWithDeoptimization(HDeoptimize::kNoUses);
} else {
HValue* context = environment()->LookupContext();
HCallNamed* call = new(zone()) HCallNamed(context, name, argument_count);
call->set_position(expr->position());
PreProcessCall(call);
if (join != NULL) {
AddInstruction(call);
if (!ast_context()->IsEffect()) Push(call);
current_block()->Goto(join);
} else {
return ast_context()->ReturnInstruction(call, expr->id());
}
}
// We assume that control flow is always live after an expression. So
// even without predecessors to the join block, we set it as the exit
// block and continue by adding instructions there.
ASSERT(join != NULL);
if (join->HasPredecessor()) {
set_current_block(join);
join->SetJoinId(expr->id());
if (!ast_context()->IsEffect()) return ast_context()->ReturnValue(Pop());
} else {
set_current_block(NULL);
}
}
void HGraphBuilder::TraceInline(Handle<JSFunction> target,
Handle<JSFunction> caller,
const char* reason) {
if (FLAG_trace_inlining) {
SmartArrayPointer<char> target_name =
target->shared()->DebugName()->ToCString();
SmartArrayPointer<char> caller_name =
caller->shared()->DebugName()->ToCString();
if (reason == NULL) {
PrintF("Inlined %s called from %s.\n", *target_name, *caller_name);
} else {
PrintF("Did not inline %s called from %s (%s).\n",
*target_name, *caller_name, reason);
}
}
}
bool HGraphBuilder::TryInline(CallKind call_kind,
Handle<JSFunction> target,
ZoneList<Expression*>* arguments,
HValue* receiver,
int ast_id,
int return_id,
ReturnHandlingFlag return_handling) {
if (!FLAG_use_inlining) return false;
// Precondition: call is monomorphic and we have found a target with the
// appropriate arity.
Handle<JSFunction> caller = info()->closure();
Handle<SharedFunctionInfo> target_shared(target->shared());
// Do a quick check on source code length to avoid parsing large
// inlining candidates.
if ((FLAG_limit_inlining && target_shared->SourceSize() > kMaxSourceSize)
|| target_shared->SourceSize() > kUnlimitedMaxSourceSize) {
TraceInline(target, caller, "target text too big");
return false;
}
// Target must be inlineable.
if (!target->IsInlineable()) {
TraceInline(target, caller, "target not inlineable");
return false;
}
if (target_shared->dont_inline() || target_shared->dont_optimize()) {
TraceInline(target, caller, "target contains unsupported syntax [early]");
return false;
}
int nodes_added = target_shared->ast_node_count();
if ((FLAG_limit_inlining && nodes_added > kMaxInlinedSize) ||
nodes_added > kUnlimitedMaxInlinedSize) {
TraceInline(target, caller, "target AST is too large [early]");
return false;
}
#if !defined(V8_TARGET_ARCH_IA32)
// Target must be able to use caller's context.
CompilationInfo* outer_info = info();
if (target->context() != outer_info->closure()->context() ||
outer_info->scope()->contains_with() ||
outer_info->scope()->num_heap_slots() > 0) {
TraceInline(target, caller, "target requires context change");
return false;
}
#endif
// Don't inline deeper than kMaxInliningLevels calls.
HEnvironment* env = environment();
int current_level = 1;
while (env->outer() != NULL) {
if (current_level == Compiler::kMaxInliningLevels) {
TraceInline(target, caller, "inline depth limit reached");
return false;
}
if (env->outer()->frame_type() == JS_FUNCTION) {
current_level++;
}
env = env->outer();
}
// Don't inline recursive functions.
for (FunctionState* state = function_state();
state != NULL;
state = state->outer()) {
if (state->compilation_info()->closure()->shared() == *target_shared) {
TraceInline(target, caller, "target is recursive");
return false;
}
}
// We don't want to add more than a certain number of nodes from inlining.
if ((FLAG_limit_inlining && inlined_count_ > kMaxInlinedNodes) ||
inlined_count_ > kUnlimitedMaxInlinedNodes) {
TraceInline(target, caller, "cumulative AST node limit reached");
return false;
}
// Parse and allocate variables.
CompilationInfo target_info(target);
if (!ParserApi::Parse(&target_info, kNoParsingFlags) ||
!Scope::Analyze(&target_info)) {
if (target_info.isolate()->has_pending_exception()) {
// Parse or scope error, never optimize this function.
SetStackOverflow();
target_shared->DisableOptimization();
}
TraceInline(target, caller, "parse failure");
return false;
}
if (target_info.scope()->num_heap_slots() > 0) {
TraceInline(target, caller, "target has context-allocated variables");
return false;
}
FunctionLiteral* function = target_info.function();
// The following conditions must be checked again after re-parsing, because
// earlier the information might not have been complete due to lazy parsing.
nodes_added = function->ast_node_count();
if ((FLAG_limit_inlining && nodes_added > kMaxInlinedSize) ||
nodes_added > kUnlimitedMaxInlinedSize) {
TraceInline(target, caller, "target AST is too large [late]");
return false;
}
AstProperties::Flags* flags(function->flags());
if (flags->Contains(kDontInline) || flags->Contains(kDontOptimize)) {
TraceInline(target, caller, "target contains unsupported syntax [late]");
return false;
}
// If the function uses the arguments object check that inlining of functions
// with arguments object is enabled and the arguments-variable is
// stack allocated.
if (function->scope()->arguments() != NULL) {
if (!FLAG_inline_arguments) {
TraceInline(target, caller, "target uses arguments object");
return false;
}
if (!function->scope()->arguments()->IsStackAllocated()) {
TraceInline(target,
caller,
"target uses non-stackallocated arguments object");
return false;
}
}
// All declarations must be inlineable.
ZoneList<Declaration*>* decls = target_info.scope()->declarations();
int decl_count = decls->length();
for (int i = 0; i < decl_count; ++i) {
if (!decls->at(i)->IsInlineable()) {
TraceInline(target, caller, "target has non-trivial declaration");
return false;
}
}
// Generate the deoptimization data for the unoptimized version of
// the target function if we don't already have it.
if (!target_shared->has_deoptimization_support()) {
// Note that we compile here using the same AST that we will use for
// generating the optimized inline code.
target_info.EnableDeoptimizationSupport();
if (!FullCodeGenerator::MakeCode(&target_info)) {
TraceInline(target, caller, "could not generate deoptimization info");
return false;
}
if (target_shared->scope_info() == ScopeInfo::Empty()) {
// The scope info might not have been set if a lazily compiled
// function is inlined before being called for the first time.
Handle<ScopeInfo> target_scope_info =
ScopeInfo::Create(target_info.scope());
target_shared->set_scope_info(*target_scope_info);
}
target_shared->EnableDeoptimizationSupport(*target_info.code());
Compiler::RecordFunctionCompilation(Logger::FUNCTION_TAG,
&target_info,
target_shared);
}
// ----------------------------------------------------------------
// After this point, we've made a decision to inline this function (so
// TryInline should always return true).
// Save the pending call context and type feedback oracle. Set up new ones
// for the inlined function.
ASSERT(target_shared->has_deoptimization_support());
TypeFeedbackOracle target_oracle(
Handle<Code>(target_shared->code()),
Handle<Context>(target->context()->global_context()),
isolate());
// The function state is new-allocated because we need to delete it
// in two different places.
FunctionState* target_state = new FunctionState(
this, &target_info, &target_oracle, return_handling);
HConstant* undefined = graph()->GetConstantUndefined();
HEnvironment* inner_env =
environment()->CopyForInlining(target,
arguments->length(),
function,
undefined,
call_kind,
function_state()->is_construct());
#ifdef V8_TARGET_ARCH_IA32
// IA32 only, overwrite the caller's context in the deoptimization
// environment with the correct one.
//
// TODO(kmillikin): implement the same inlining on other platforms so we
// can remove the unsightly ifdefs in this function.
HConstant* context = new HConstant(Handle<Context>(target->context()),
Representation::Tagged());
AddInstruction(context);
inner_env->BindContext(context);
#endif
AddSimulate(return_id);
current_block()->UpdateEnvironment(inner_env);
AddInstruction(new(zone()) HEnterInlined(target,
arguments->length(),
function,
call_kind,
function_state()->is_construct(),
function->scope()->arguments()));
// If the function uses arguments object create and bind one.
if (function->scope()->arguments() != NULL) {
ASSERT(function->scope()->arguments()->IsStackAllocated());
environment()->Bind(function->scope()->arguments(),
graph()->GetArgumentsObject());
}
VisitDeclarations(target_info.scope()->declarations());
VisitStatements(function->body());
if (HasStackOverflow()) {
// Bail out if the inline function did, as we cannot residualize a call
// instead.
TraceInline(target, caller, "inline graph construction failed");
target_shared->DisableOptimization();
inline_bailout_ = true;
delete target_state;
return true;
}
// Update inlined nodes count.
inlined_count_ += nodes_added;
TraceInline(target, caller, NULL);
if (current_block() != NULL) {
// Add default return value (i.e. undefined for normals calls or the newly
// allocated receiver for construct calls) if control can fall off the
// body. In a test context, undefined is false and any JSObject is true.
if (call_context()->IsValue()) {
ASSERT(function_return() != NULL);
HValue* return_value = function_state()->is_construct()
? receiver
: undefined;
current_block()->AddLeaveInlined(return_value,
function_return(),
function_state()->drop_extra());
} else if (call_context()->IsEffect()) {
ASSERT(function_return() != NULL);
current_block()->Goto(function_return(), function_state()->drop_extra());
} else {
ASSERT(call_context()->IsTest());
ASSERT(inlined_test_context() != NULL);
HBasicBlock* target = function_state()->is_construct()
? inlined_test_context()->if_true()
: inlined_test_context()->if_false();
current_block()->Goto(target, function_state()->drop_extra());
}
}
// Fix up the function exits.
if (inlined_test_context() != NULL) {
HBasicBlock* if_true = inlined_test_context()->if_true();
HBasicBlock* if_false = inlined_test_context()->if_false();
// Pop the return test context from the expression context stack.
ASSERT(ast_context() == inlined_test_context());
ClearInlinedTestContext();
delete target_state;
// Forward to the real test context.
if (if_true->HasPredecessor()) {
if_true->SetJoinId(ast_id);
HBasicBlock* true_target = TestContext::cast(ast_context())->if_true();
if_true->Goto(true_target, function_state()->drop_extra());
}
if (if_false->HasPredecessor()) {
if_false->SetJoinId(ast_id);
HBasicBlock* false_target = TestContext::cast(ast_context())->if_false();
if_false->Goto(false_target, function_state()->drop_extra());
}
set_current_block(NULL);
return true;
} else if (function_return()->HasPredecessor()) {
function_return()->SetJoinId(ast_id);
set_current_block(function_return());
} else {
set_current_block(NULL);
}
delete target_state;
return true;
}
bool HGraphBuilder::TryInlineCall(Call* expr, bool drop_extra) {
// The function call we are inlining is a method call if the call
// is a property call.
CallKind call_kind = (expr->expression()->AsProperty() == NULL)
? CALL_AS_FUNCTION
: CALL_AS_METHOD;
return TryInline(call_kind,
expr->target(),
expr->arguments(),
NULL,
expr->id(),
expr->ReturnId(),
drop_extra ? DROP_EXTRA_ON_RETURN : NORMAL_RETURN);
}
bool HGraphBuilder::TryInlineConstruct(CallNew* expr, HValue* receiver) {
return TryInline(CALL_AS_FUNCTION,
expr->target(),
expr->arguments(),
receiver,
expr->id(),
expr->ReturnId(),
CONSTRUCT_CALL_RETURN);
}
bool HGraphBuilder::TryInlineBuiltinFunctionCall(Call* expr, bool drop_extra) {
if (!expr->target()->shared()->HasBuiltinFunctionId()) return false;
BuiltinFunctionId id = expr->target()->shared()->builtin_function_id();
switch (id) {
case kMathRound:
case kMathAbs:
case kMathSqrt:
case kMathLog:
case kMathSin:
case kMathCos:
case kMathTan:
if (expr->arguments()->length() == 1) {
HValue* argument = Pop();
HValue* context = environment()->LookupContext();
Drop(1); // Receiver.
HUnaryMathOperation* op =
new(zone()) HUnaryMathOperation(context, argument, id);
op->set_position(expr->position());
if (drop_extra) Drop(1); // Optionally drop the function.
ast_context()->ReturnInstruction(op, expr->id());
return true;
}
break;
default:
// Not supported for inlining yet.
break;
}
return false;
}
bool HGraphBuilder::TryInlineBuiltinMethodCall(Call* expr,
HValue* receiver,
Handle<Map> receiver_map,
CheckType check_type) {
ASSERT(check_type != RECEIVER_MAP_CHECK || !receiver_map.is_null());
// Try to inline calls like Math.* as operations in the calling function.
if (!expr->target()->shared()->HasBuiltinFunctionId()) return false;
BuiltinFunctionId id = expr->target()->shared()->builtin_function_id();
int argument_count = expr->arguments()->length() + 1; // Plus receiver.
switch (id) {
case kStringCharCodeAt:
case kStringCharAt:
if (argument_count == 2 && check_type == STRING_CHECK) {
HValue* index = Pop();
HValue* string = Pop();
HValue* context = environment()->LookupContext();
ASSERT(!expr->holder().is_null());
AddInstruction(new(zone()) HCheckPrototypeMaps(
oracle()->GetPrototypeForPrimitiveCheck(STRING_CHECK),
expr->holder()));
HStringCharCodeAt* char_code =
BuildStringCharCodeAt(context, string, index);
if (id == kStringCharCodeAt) {
ast_context()->ReturnInstruction(char_code, expr->id());
return true;
}
AddInstruction(char_code);
HStringCharFromCode* result =
new(zone()) HStringCharFromCode(context, char_code);
ast_context()->ReturnInstruction(result, expr->id());
return true;
}
break;
case kMathRound:
case kMathFloor:
case kMathAbs:
case kMathSqrt:
case kMathLog:
case kMathSin:
case kMathCos:
case kMathTan:
if (argument_count == 2 && check_type == RECEIVER_MAP_CHECK) {
AddCheckConstantFunction(expr, receiver, receiver_map, true);
HValue* argument = Pop();
HValue* context = environment()->LookupContext();
Drop(1); // Receiver.
HUnaryMathOperation* op =
new(zone()) HUnaryMathOperation(context, argument, id);
op->set_position(expr->position());
ast_context()->ReturnInstruction(op, expr->id());
return true;
}
break;
case kMathPow:
if (argument_count == 3 && check_type == RECEIVER_MAP_CHECK) {
AddCheckConstantFunction(expr, receiver, receiver_map, true);
HValue* right = Pop();
HValue* left = Pop();
Pop(); // Pop receiver.
HValue* context = environment()->LookupContext();
HInstruction* result = NULL;
// Use sqrt() if exponent is 0.5 or -0.5.
if (right->IsConstant() && HConstant::cast(right)->HasDoubleValue()) {
double exponent = HConstant::cast(right)->DoubleValue();
if (exponent == 0.5) {
result =
new(zone()) HUnaryMathOperation(context, left, kMathPowHalf);
} else if (exponent == -0.5) {
HConstant* double_one =
new(zone()) HConstant(Handle<Object>(Smi::FromInt(1)),
Representation::Double());
AddInstruction(double_one);
HUnaryMathOperation* square_root =
new(zone()) HUnaryMathOperation(context, left, kMathPowHalf);
AddInstruction(square_root);
// MathPowHalf doesn't have side effects so there's no need for
// an environment simulation here.
ASSERT(!square_root->HasObservableSideEffects());
result = new(zone()) HDiv(context, double_one, square_root);
} else if (exponent == 2.0) {
result = new(zone()) HMul(context, left, left);
}
} else if (right->IsConstant() &&
HConstant::cast(right)->HasInteger32Value() &&
HConstant::cast(right)->Integer32Value() == 2) {
result = new(zone()) HMul(context, left, left);
}
if (result == NULL) {
result = new(zone()) HPower(left, right);
}
ast_context()->ReturnInstruction(result, expr->id());
return true;
}
break;
case kMathRandom:
if (argument_count == 1 && check_type == RECEIVER_MAP_CHECK) {
AddCheckConstantFunction(expr, receiver, receiver_map, true);
Drop(1); // Receiver.
HValue* context = environment()->LookupContext();
HGlobalObject* global_object = new(zone()) HGlobalObject(context);
AddInstruction(global_object);
HRandom* result = new(zone()) HRandom(global_object);
ast_context()->ReturnInstruction(result, expr->id());
return true;
}
break;
case kMathMax:
case kMathMin:
if (argument_count == 3 && check_type == RECEIVER_MAP_CHECK) {
AddCheckConstantFunction(expr, receiver, receiver_map, true);
HValue* right = Pop();
HValue* left = Pop();
Pop(); // Pop receiver.
HValue* left_operand = left;
HValue* right_operand = right;
// If we do not have two integers, we convert to double for comparison.
if (!left->representation().IsInteger32() ||
!right->representation().IsInteger32()) {
if (!left->representation().IsDouble()) {
HChange* left_convert = new(zone()) HChange(
left,
Representation::Double(),
false, // Do not truncate when converting to double.
true); // Deoptimize for undefined.
left_convert->SetFlag(HValue::kBailoutOnMinusZero);
left_operand = AddInstruction(left_convert);
}
if (!right->representation().IsDouble()) {
HChange* right_convert = new(zone()) HChange(
right,
Representation::Double(),
false, // Do not truncate when converting to double.
true); // Deoptimize for undefined.
right_convert->SetFlag(HValue::kBailoutOnMinusZero);
right_operand = AddInstruction(right_convert);
}
}
ASSERT(left_operand->representation().Equals(
right_operand->representation()));
ASSERT(!left_operand->representation().IsTagged());
Token::Value op = (id == kMathMin) ? Token::LT : Token::GT;
HCompareIDAndBranch* compare =
new(zone()) HCompareIDAndBranch(left_operand, right_operand, op);
compare->SetInputRepresentation(left_operand->representation());
HBasicBlock* return_left = graph()->CreateBasicBlock();
HBasicBlock* return_right = graph()->CreateBasicBlock();
compare->SetSuccessorAt(0, return_left);
compare->SetSuccessorAt(1, return_right);
current_block()->Finish(compare);
set_current_block(return_left);
Push(left);
set_current_block(return_right);
// The branch above always returns the right operand if either of
// them is NaN, but the spec requires that max/min(NaN, X) = NaN.
// We add another branch that checks if the left operand is NaN or not.
if (left_operand->representation().IsDouble()) {
// If left_operand != left_operand then it is NaN.
HCompareIDAndBranch* compare_nan = new(zone()) HCompareIDAndBranch(
left_operand, left_operand, Token::EQ);
compare_nan->SetInputRepresentation(left_operand->representation());
HBasicBlock* left_is_number = graph()->CreateBasicBlock();
HBasicBlock* left_is_nan = graph()->CreateBasicBlock();
compare_nan->SetSuccessorAt(0, left_is_number);
compare_nan->SetSuccessorAt(1, left_is_nan);
current_block()->Finish(compare_nan);
set_current_block(left_is_nan);
Push(left);
set_current_block(left_is_number);
Push(right);
return_right = CreateJoin(left_is_number, left_is_nan, expr->id());
} else {
Push(right);
}
HBasicBlock* join = CreateJoin(return_left, return_right, expr->id());
set_current_block(join);
ast_context()->ReturnValue(Pop());
return true;
}
break;
default:
// Not yet supported for inlining.
break;
}
return false;
}
bool HGraphBuilder::TryCallApply(Call* expr) {
Expression* callee = expr->expression();
Property* prop = callee->AsProperty();
ASSERT(prop != NULL);
if (!expr->IsMonomorphic() || expr->check_type() != RECEIVER_MAP_CHECK) {
return false;
}
Handle<Map> function_map = expr->GetReceiverTypes()->first();
if (function_map->instance_type() != JS_FUNCTION_TYPE ||
!expr->target()->shared()->HasBuiltinFunctionId() ||
expr->target()->shared()->builtin_function_id() != kFunctionApply) {
return false;
}
if (info()->scope()->arguments() == NULL) return false;
ZoneList<Expression*>* args = expr->arguments();
if (args->length() != 2) return false;
VariableProxy* arg_two = args->at(1)->AsVariableProxy();
if (arg_two == NULL || !arg_two->var()->IsStackAllocated()) return false;
HValue* arg_two_value = environment()->Lookup(arg_two->var());
if (!arg_two_value->CheckFlag(HValue::kIsArguments)) return false;
// Found pattern f.apply(receiver, arguments).
VisitForValue(prop->obj());
if (HasStackOverflow() || current_block() == NULL) return true;
HValue* function = Top();
AddCheckConstantFunction(expr, function, function_map, true);
Drop(1);
VisitForValue(args->at(0));
if (HasStackOverflow() || current_block() == NULL) return true;
HValue* receiver = Pop();
if (function_state()->outer() == NULL) {
HInstruction* elements = AddInstruction(new(zone()) HArgumentsElements);
HInstruction* length =
AddInstruction(new(zone()) HArgumentsLength(elements));
HValue* wrapped_receiver =
AddInstruction(new(zone()) HWrapReceiver(receiver, function));
HInstruction* result =
new(zone()) HApplyArguments(function,
wrapped_receiver,
length,
elements);
result->set_position(expr->position());
ast_context()->ReturnInstruction(result, expr->id());
return true;
} else {
// We are inside inlined function and we know exactly what is inside
// arguments object.
HValue* context = environment()->LookupContext();
HValue* wrapped_receiver =
AddInstruction(new(zone()) HWrapReceiver(receiver, function));
PushAndAdd(new(zone()) HPushArgument(wrapped_receiver));
HEnvironment* arguments_env = environment()->arguments_environment();
int parameter_count = arguments_env->parameter_count();
for (int i = 1; i < arguments_env->parameter_count(); i++) {
PushAndAdd(new(zone()) HPushArgument(arguments_env->Lookup(i)));
}
HInvokeFunction* call = new(zone()) HInvokeFunction(
context,
function,
parameter_count);
Drop(parameter_count);
call->set_position(expr->position());
ast_context()->ReturnInstruction(call, expr->id());
return true;
}
}
void HGraphBuilder::VisitCall(Call* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
Expression* callee = expr->expression();
int argument_count = expr->arguments()->length() + 1; // Plus receiver.
HInstruction* call = NULL;
Property* prop = callee->AsProperty();
if (prop != NULL) {
if (!prop->key()->IsPropertyName()) {
// Keyed function call.
CHECK_ALIVE(VisitArgument(prop->obj()));
CHECK_ALIVE(VisitForValue(prop->key()));
// Push receiver and key like the non-optimized code generator expects it.
HValue* key = Pop();
HValue* receiver = Pop();
Push(key);
Push(receiver);
CHECK_ALIVE(VisitArgumentList(expr->arguments()));
HValue* context = environment()->LookupContext();
call = new(zone()) HCallKeyed(context, key, argument_count);
call->set_position(expr->position());
Drop(argument_count + 1); // 1 is the key.
return ast_context()->ReturnInstruction(call, expr->id());
}
// Named function call.
expr->RecordTypeFeedback(oracle(), CALL_AS_METHOD);
if (TryCallApply(expr)) return;
CHECK_ALIVE(VisitForValue(prop->obj()));
CHECK_ALIVE(VisitExpressions(expr->arguments()));
Handle<String> name = prop->key()->AsLiteral()->AsPropertyName();
SmallMapList* types = expr->GetReceiverTypes();
HValue* receiver =
environment()->ExpressionStackAt(expr->arguments()->length());
if (expr->IsMonomorphic()) {
Handle<Map> receiver_map = (types == NULL || types->is_empty())
? Handle<Map>::null()
: types->first();
if (TryInlineBuiltinMethodCall(expr,
receiver,
receiver_map,
expr->check_type())) {
if (FLAG_trace_inlining) {
PrintF("Inlining builtin ");
expr->target()->ShortPrint();
PrintF("\n");
}
return;
}
if (CallStubCompiler::HasCustomCallGenerator(expr->target()) ||
expr->check_type() != RECEIVER_MAP_CHECK) {
// When the target has a custom call IC generator, use the IC,
// because it is likely to generate better code. Also use the IC
// when a primitive receiver check is required.
HValue* context = environment()->LookupContext();
call = PreProcessCall(
new(zone()) HCallNamed(context, name, argument_count));
} else {
AddCheckConstantFunction(expr, receiver, receiver_map, true);
if (TryInlineCall(expr)) return;
call = PreProcessCall(
new(zone()) HCallConstantFunction(expr->target(),
argument_count));
}
} else if (types != NULL && types->length() > 1) {
ASSERT(expr->check_type() == RECEIVER_MAP_CHECK);
HandlePolymorphicCallNamed(expr, receiver, types, name);
return;
} else {
HValue* context = environment()->LookupContext();
call = PreProcessCall(
new(zone()) HCallNamed(context, name, argument_count));
}
} else {
expr->RecordTypeFeedback(oracle(), CALL_AS_FUNCTION);
VariableProxy* proxy = expr->expression()->AsVariableProxy();
bool global_call = proxy != NULL && proxy->var()->IsUnallocated();
if (proxy != NULL && proxy->var()->is_possibly_eval()) {
return Bailout("possible direct call to eval");
}
if (global_call) {
Variable* var = proxy->var();
bool known_global_function = false;
// If there is a global property cell for the name at compile time and
// access check is not enabled we assume that the function will not change
// and generate optimized code for calling the function.
LookupResult lookup(isolate());
GlobalPropertyAccess type = LookupGlobalProperty(var, &lookup, false);
if (type == kUseCell &&
!info()->global_object()->IsAccessCheckNeeded()) {
Handle<GlobalObject> global(info()->global_object());
known_global_function = expr->ComputeGlobalTarget(global, &lookup);
}
if (known_global_function) {
// Push the global object instead of the global receiver because
// code generated by the full code generator expects it.
HValue* context = environment()->LookupContext();
HGlobalObject* global_object = new(zone()) HGlobalObject(context);
PushAndAdd(global_object);
CHECK_ALIVE(VisitExpressions(expr->arguments()));
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* function = Pop();
AddInstruction(new(zone()) HCheckFunction(function, expr->target()));
// Replace the global object with the global receiver.
HGlobalReceiver* global_receiver =
new(zone()) HGlobalReceiver(global_object);
// Index of the receiver from the top of the expression stack.
const int receiver_index = argument_count - 1;
AddInstruction(global_receiver);
ASSERT(environment()->ExpressionStackAt(receiver_index)->
IsGlobalObject());
environment()->SetExpressionStackAt(receiver_index, global_receiver);
if (TryInlineBuiltinFunctionCall(expr, false)) { // Nothing to drop.
if (FLAG_trace_inlining) {
PrintF("Inlining builtin ");
expr->target()->ShortPrint();
PrintF("\n");
}
return;
}
if (TryInlineCall(expr)) return;
call = PreProcessCall(new(zone()) HCallKnownGlobal(expr->target(),
argument_count));
} else {
HValue* context = environment()->LookupContext();
HGlobalObject* receiver = new(zone()) HGlobalObject(context);
AddInstruction(receiver);
PushAndAdd(new(zone()) HPushArgument(receiver));
CHECK_ALIVE(VisitArgumentList(expr->arguments()));
call = new(zone()) HCallGlobal(context, var->name(), argument_count);
Drop(argument_count);
}
} else if (expr->IsMonomorphic()) {
// The function is on the stack in the unoptimized code during
// evaluation of the arguments.
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* function = Top();
HValue* context = environment()->LookupContext();
HGlobalObject* global = new(zone()) HGlobalObject(context);
HGlobalReceiver* receiver = new(zone()) HGlobalReceiver(global);
AddInstruction(global);
PushAndAdd(receiver);
CHECK_ALIVE(VisitExpressions(expr->arguments()));
AddInstruction(new(zone()) HCheckFunction(function, expr->target()));
if (TryInlineBuiltinFunctionCall(expr, true)) { // Drop the function.
if (FLAG_trace_inlining) {
PrintF("Inlining builtin ");
expr->target()->ShortPrint();
PrintF("\n");
}
return;
}
if (TryInlineCall(expr, true)) { // Drop function from environment.
return;
} else {
call = PreProcessCall(new(zone()) HInvokeFunction(context,
function,
argument_count));
Drop(1); // The function.
}
} else {
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* function = Top();
HValue* context = environment()->LookupContext();
HGlobalObject* global_object = new(zone()) HGlobalObject(context);
HGlobalReceiver* receiver = new(zone()) HGlobalReceiver(global_object);
AddInstruction(global_object);
AddInstruction(receiver);
PushAndAdd(new(zone()) HPushArgument(receiver));
CHECK_ALIVE(VisitArgumentList(expr->arguments()));
call = new(zone()) HCallFunction(context, function, argument_count);
Drop(argument_count + 1);
}
}
call->set_position(expr->position());
return ast_context()->ReturnInstruction(call, expr->id());
}
// Checks whether allocation using the given constructor can be inlined.
static bool IsAllocationInlineable(Handle<JSFunction> constructor) {
return constructor->has_initial_map() &&
constructor->initial_map()->instance_type() == JS_OBJECT_TYPE;
}
void HGraphBuilder::VisitCallNew(CallNew* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
expr->RecordTypeFeedback(oracle());
int argument_count = expr->arguments()->length() + 1; // Plus constructor.
HValue* context = environment()->LookupContext();
if (FLAG_inline_construct &&
expr->IsMonomorphic() &&
IsAllocationInlineable(expr->target())) {
// The constructor function is on the stack in the unoptimized code
// during evaluation of the arguments.
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* function = Top();
CHECK_ALIVE(VisitExpressions(expr->arguments()));
Handle<JSFunction> constructor = expr->target();
HValue* check = AddInstruction(
new(zone()) HCheckFunction(function, constructor));
// Force completion of inobject slack tracking before generating
// allocation code to finalize instance size.
if (constructor->shared()->IsInobjectSlackTrackingInProgress()) {
constructor->shared()->CompleteInobjectSlackTracking();
}
// Replace the constructor function with a newly allocated receiver.
HInstruction* receiver = new(zone()) HAllocateObject(context, constructor);
// Index of the receiver from the top of the expression stack.
const int receiver_index = argument_count - 1;
AddInstruction(receiver);
ASSERT(environment()->ExpressionStackAt(receiver_index) == function);
environment()->SetExpressionStackAt(receiver_index, receiver);
if (TryInlineConstruct(expr, receiver)) return;
// TODO(mstarzinger): For now we remove the previous HAllocateObject and
// add HPushArgument for the arguments in case inlining failed. What we
// actually should do is emit HInvokeFunction on the constructor instead
// of using HCallNew as a fallback.
receiver->DeleteAndReplaceWith(NULL);
check->DeleteAndReplaceWith(NULL);
environment()->SetExpressionStackAt(receiver_index, function);
HInstruction* call = PreProcessCall(
new(zone()) HCallNew(context, function, argument_count));
call->set_position(expr->position());
return ast_context()->ReturnInstruction(call, expr->id());
} else {
// The constructor function is both an operand to the instruction and an
// argument to the construct call.
HValue* constructor = NULL;
CHECK_ALIVE(constructor = VisitArgument(expr->expression()));
CHECK_ALIVE(VisitArgumentList(expr->arguments()));
HInstruction* call =
new(zone()) HCallNew(context, constructor, argument_count);
Drop(argument_count);
call->set_position(expr->position());
return ast_context()->ReturnInstruction(call, expr->id());
}
}
// Support for generating inlined runtime functions.
// Lookup table for generators for runtime calls that are generated inline.
// Elements of the table are member pointers to functions of HGraphBuilder.
#define INLINE_FUNCTION_GENERATOR_ADDRESS(Name, argc, ressize) \
&HGraphBuilder::Generate##Name,
const HGraphBuilder::InlineFunctionGenerator
HGraphBuilder::kInlineFunctionGenerators[] = {
INLINE_FUNCTION_LIST(INLINE_FUNCTION_GENERATOR_ADDRESS)
INLINE_RUNTIME_FUNCTION_LIST(INLINE_FUNCTION_GENERATOR_ADDRESS)
};
#undef INLINE_FUNCTION_GENERATOR_ADDRESS
void HGraphBuilder::VisitCallRuntime(CallRuntime* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
if (expr->is_jsruntime()) {
return Bailout("call to a JavaScript runtime function");
}
const Runtime::Function* function = expr->function();
ASSERT(function != NULL);
if (function->intrinsic_type == Runtime::INLINE) {
ASSERT(expr->name()->length() > 0);
ASSERT(expr->name()->Get(0) == '_');
// Call to an inline function.
int lookup_index = static_cast<int>(function->function_id) -
static_cast<int>(Runtime::kFirstInlineFunction);
ASSERT(lookup_index >= 0);
ASSERT(static_cast<size_t>(lookup_index) <
ARRAY_SIZE(kInlineFunctionGenerators));
InlineFunctionGenerator generator = kInlineFunctionGenerators[lookup_index];
// Call the inline code generator using the pointer-to-member.
(this->*generator)(expr);
} else {
ASSERT(function->intrinsic_type == Runtime::RUNTIME);
CHECK_ALIVE(VisitArgumentList(expr->arguments()));
HValue* context = environment()->LookupContext();
Handle<String> name = expr->name();
int argument_count = expr->arguments()->length();
HCallRuntime* call =
new(zone()) HCallRuntime(context, name, function, argument_count);
call->set_position(RelocInfo::kNoPosition);
Drop(argument_count);
return ast_context()->ReturnInstruction(call, expr->id());
}
}
void HGraphBuilder::VisitUnaryOperation(UnaryOperation* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
switch (expr->op()) {
case Token::DELETE: return VisitDelete(expr);
case Token::VOID: return VisitVoid(expr);
case Token::TYPEOF: return VisitTypeof(expr);
case Token::ADD: return VisitAdd(expr);
case Token::SUB: return VisitSub(expr);
case Token::BIT_NOT: return VisitBitNot(expr);
case Token::NOT: return VisitNot(expr);
default: UNREACHABLE();
}
}
void HGraphBuilder::VisitDelete(UnaryOperation* expr) {
Property* prop = expr->expression()->AsProperty();
VariableProxy* proxy = expr->expression()->AsVariableProxy();
if (prop != NULL) {
CHECK_ALIVE(VisitForValue(prop->obj()));
CHECK_ALIVE(VisitForValue(prop->key()));
HValue* key = Pop();
HValue* obj = Pop();
HValue* context = environment()->LookupContext();
HDeleteProperty* instr = new(zone()) HDeleteProperty(context, obj, key);
return ast_context()->ReturnInstruction(instr, expr->id());
} else if (proxy != NULL) {
Variable* var = proxy->var();
if (var->IsUnallocated()) {
Bailout("delete with global variable");
} else if (var->IsStackAllocated() || var->IsContextSlot()) {
// Result of deleting non-global variables is false. 'this' is not
// really a variable, though we implement it as one. The
// subexpression does not have side effects.
HValue* value = var->is_this()
? graph()->GetConstantTrue()
: graph()->GetConstantFalse();
return ast_context()->ReturnValue(value);
} else {
Bailout("delete with non-global variable");
}
} else {
// Result of deleting non-property, non-variable reference is true.
// Evaluate the subexpression for side effects.
CHECK_ALIVE(VisitForEffect(expr->expression()));
return ast_context()->ReturnValue(graph()->GetConstantTrue());
}
}
void HGraphBuilder::VisitVoid(UnaryOperation* expr) {
CHECK_ALIVE(VisitForEffect(expr->expression()));
return ast_context()->ReturnValue(graph()->GetConstantUndefined());
}
void HGraphBuilder::VisitTypeof(UnaryOperation* expr) {
CHECK_ALIVE(VisitForTypeOf(expr->expression()));
HValue* value = Pop();
HValue* context = environment()->LookupContext();
HInstruction* instr = new(zone()) HTypeof(context, value);
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::VisitAdd(UnaryOperation* expr) {
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* value = Pop();
HValue* context = environment()->LookupContext();
HInstruction* instr =
new(zone()) HMul(context, value, graph_->GetConstant1());
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::VisitSub(UnaryOperation* expr) {
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* value = Pop();
HValue* context = environment()->LookupContext();
HInstruction* instr =
new(zone()) HMul(context, value, graph_->GetConstantMinus1());
TypeInfo info = oracle()->UnaryType(expr);
if (info.IsUninitialized()) {
AddInstruction(new(zone()) HSoftDeoptimize);
current_block()->MarkAsDeoptimizing();
info = TypeInfo::Unknown();
}
Representation rep = ToRepresentation(info);
TraceRepresentation(expr->op(), info, instr, rep);
instr->AssumeRepresentation(rep);
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::VisitBitNot(UnaryOperation* expr) {
CHECK_ALIVE(VisitForValue(expr->expression()));
HValue* value = Pop();
TypeInfo info = oracle()->UnaryType(expr);
if (info.IsUninitialized()) {
AddInstruction(new(zone()) HSoftDeoptimize);
current_block()->MarkAsDeoptimizing();
}
HInstruction* instr = new(zone()) HBitNot(value);
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::VisitNot(UnaryOperation* expr) {
if (ast_context()->IsTest()) {
TestContext* context = TestContext::cast(ast_context());
VisitForControl(expr->expression(),
context->if_false(),
context->if_true());
return;
}
if (ast_context()->IsEffect()) {
VisitForEffect(expr->expression());
return;
}
ASSERT(ast_context()->IsValue());
HBasicBlock* materialize_false = graph()->CreateBasicBlock();
HBasicBlock* materialize_true = graph()->CreateBasicBlock();
CHECK_BAILOUT(VisitForControl(expr->expression(),
materialize_false,
materialize_true));
if (materialize_false->HasPredecessor()) {
materialize_false->SetJoinId(expr->MaterializeFalseId());
set_current_block(materialize_false);
Push(graph()->GetConstantFalse());
} else {
materialize_false = NULL;
}
if (materialize_true->HasPredecessor()) {
materialize_true->SetJoinId(expr->MaterializeTrueId());
set_current_block(materialize_true);
Push(graph()->GetConstantTrue());
} else {
materialize_true = NULL;
}
HBasicBlock* join =
CreateJoin(materialize_false, materialize_true, expr->id());
set_current_block(join);
if (join != NULL) return ast_context()->ReturnValue(Pop());
}
HInstruction* HGraphBuilder::BuildIncrement(bool returns_original_input,
CountOperation* expr) {
// The input to the count operation is on top of the expression stack.
TypeInfo info = oracle()->IncrementType(expr);
Representation rep = ToRepresentation(info);
if (rep.IsTagged()) {
rep = Representation::Integer32();
}
if (returns_original_input) {
// We need an explicit HValue representing ToNumber(input). The
// actual HChange instruction we need is (sometimes) added in a later
// phase, so it is not available now to be used as an input to HAdd and
// as the return value.
HInstruction* number_input = new(zone()) HForceRepresentation(Pop(), rep);
AddInstruction(number_input);
Push(number_input);
}
// The addition has no side effects, so we do not need
// to simulate the expression stack after this instruction.
// Any later failures deopt to the load of the input or earlier.
HConstant* delta = (expr->op() == Token::INC)
? graph_->GetConstant1()
: graph_->GetConstantMinus1();
HValue* context = environment()->LookupContext();
HInstruction* instr = new(zone()) HAdd(context, Top(), delta);
TraceRepresentation(expr->op(), info, instr, rep);
instr->AssumeRepresentation(rep);
AddInstruction(instr);
return instr;
}
void HGraphBuilder::VisitCountOperation(CountOperation* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
Expression* target = expr->expression();
VariableProxy* proxy = target->AsVariableProxy();
Property* prop = target->AsProperty();
if (proxy == NULL && prop == NULL) {
return Bailout("invalid lhs in count operation");
}
// Match the full code generator stack by simulating an extra stack
// element for postfix operations in a non-effect context. The return
// value is ToNumber(input).
bool returns_original_input =
expr->is_postfix() && !ast_context()->IsEffect();
HValue* input = NULL; // ToNumber(original_input).
HValue* after = NULL; // The result after incrementing or decrementing.
if (proxy != NULL) {
Variable* var = proxy->var();
if (var->mode() == CONST) {
return Bailout("unsupported count operation with const");
}
// Argument of the count operation is a variable, not a property.
ASSERT(prop == NULL);
CHECK_ALIVE(VisitForValue(target));
after = BuildIncrement(returns_original_input, expr);
input = returns_original_input ? Top() : Pop();
Push(after);
switch (var->location()) {
case Variable::UNALLOCATED:
HandleGlobalVariableAssignment(var,
after,
expr->position(),
expr->AssignmentId());
break;
case Variable::PARAMETER:
case Variable::LOCAL:
Bind(var, after);
break;
case Variable::CONTEXT: {
// Bail out if we try to mutate a parameter value in a function
// using the arguments object. We do not (yet) correctly handle the
// arguments property of the function.
if (info()->scope()->arguments() != NULL) {
// Parameters will rewrite to context slots. We have no direct
// way to detect that the variable is a parameter so we use a
// linear search of the parameter list.
int count = info()->scope()->num_parameters();
for (int i = 0; i < count; ++i) {
if (var == info()->scope()->parameter(i)) {
return Bailout("assignment to parameter in arguments object");
}
}
}
HValue* context = BuildContextChainWalk(var);
HStoreContextSlot::Mode mode =
(var->mode() == LET || var->mode() == CONST_HARMONY)
? HStoreContextSlot::kCheckDeoptimize : HStoreContextSlot::kNoCheck;
HStoreContextSlot* instr =
new(zone()) HStoreContextSlot(context, var->index(), mode, after);
AddInstruction(instr);
if (instr->HasObservableSideEffects()) {
AddSimulate(expr->AssignmentId());
}
break;
}
case Variable::LOOKUP:
return Bailout("lookup variable in count operation");
}
} else {
// Argument of the count operation is a property.
ASSERT(prop != NULL);
prop->RecordTypeFeedback(oracle());
if (prop->key()->IsPropertyName()) {
// Named property.
if (returns_original_input) Push(graph_->GetConstantUndefined());
CHECK_ALIVE(VisitForValue(prop->obj()));
HValue* obj = Top();
HInstruction* load = NULL;
if (prop->IsMonomorphic()) {
Handle<String> name = prop->key()->AsLiteral()->AsPropertyName();
Handle<Map> map = prop->GetReceiverTypes()->first();
load = BuildLoadNamed(obj, prop, map, name);
} else {
load = BuildLoadNamedGeneric(obj, prop);
}
PushAndAdd(load);
if (load->HasObservableSideEffects()) AddSimulate(expr->CountId());
after = BuildIncrement(returns_original_input, expr);
input = Pop();
HInstruction* store = BuildStoreNamed(obj, after, prop);
AddInstruction(store);
// Overwrite the receiver in the bailout environment with the result
// of the operation, and the placeholder with the original value if
// necessary.
environment()->SetExpressionStackAt(0, after);
if (returns_original_input) environment()->SetExpressionStackAt(1, input);
if (store->HasObservableSideEffects()) AddSimulate(expr->AssignmentId());
} else {
// Keyed property.
if (returns_original_input) Push(graph_->GetConstantUndefined());
CHECK_ALIVE(VisitForValue(prop->obj()));
CHECK_ALIVE(VisitForValue(prop->key()));
HValue* obj = environment()->ExpressionStackAt(1);
HValue* key = environment()->ExpressionStackAt(0);
bool has_side_effects = false;
HValue* load = HandleKeyedElementAccess(
obj, key, NULL, prop, expr->CountId(), RelocInfo::kNoPosition,
false, // is_store
&has_side_effects);
Push(load);
if (has_side_effects) AddSimulate(expr->CountId());
after = BuildIncrement(returns_original_input, expr);
input = Pop();
expr->RecordTypeFeedback(oracle());
HandleKeyedElementAccess(obj, key, after, expr, expr->AssignmentId(),
RelocInfo::kNoPosition,
true, // is_store
&has_side_effects);
// Drop the key from the bailout environment. Overwrite the receiver
// with the result of the operation, and the placeholder with the
// original value if necessary.
Drop(1);
environment()->SetExpressionStackAt(0, after);
if (returns_original_input) environment()->SetExpressionStackAt(1, input);
ASSERT(has_side_effects); // Stores always have side effects.
AddSimulate(expr->AssignmentId());
}
}
Drop(returns_original_input ? 2 : 1);
return ast_context()->ReturnValue(expr->is_postfix() ? input : after);
}
HStringCharCodeAt* HGraphBuilder::BuildStringCharCodeAt(HValue* context,
HValue* string,
HValue* index) {
AddInstruction(new(zone()) HCheckNonSmi(string));
AddInstruction(HCheckInstanceType::NewIsString(string));
HStringLength* length = new(zone()) HStringLength(string);
AddInstruction(length);
HInstruction* checked_index =
AddInstruction(new(zone()) HBoundsCheck(index, length));
return new(zone()) HStringCharCodeAt(context, string, checked_index);
}
HInstruction* HGraphBuilder::BuildBinaryOperation(BinaryOperation* expr,
HValue* left,
HValue* right) {
HValue* context = environment()->LookupContext();
TypeInfo info = oracle()->BinaryType(expr);
if (info.IsUninitialized()) {
AddInstruction(new(zone()) HSoftDeoptimize);
current_block()->MarkAsDeoptimizing();
info = TypeInfo::Unknown();
}
HInstruction* instr = NULL;
switch (expr->op()) {
case Token::ADD:
if (info.IsString()) {
AddInstruction(new(zone()) HCheckNonSmi(left));
AddInstruction(HCheckInstanceType::NewIsString(left));
AddInstruction(new(zone()) HCheckNonSmi(right));
AddInstruction(HCheckInstanceType::NewIsString(right));
instr = new(zone()) HStringAdd(context, left, right);
} else {
instr = HAdd::NewHAdd(zone(), context, left, right);
}
break;
case Token::SUB:
instr = HSub::NewHSub(zone(), context, left, right);
break;
case Token::MUL:
instr = HMul::NewHMul(zone(), context, left, right);
break;
case Token::MOD:
instr = HMod::NewHMod(zone(), context, left, right);
break;
case Token::DIV:
instr = HDiv::NewHDiv(zone(), context, left, right);
break;
case Token::BIT_XOR:
case Token::BIT_AND:
case Token::BIT_OR:
instr = HBitwise::NewHBitwise(zone(), expr->op(), context, left, right);
break;
case Token::SAR:
instr = HSar::NewHSar(zone(), context, left, right);
break;
case Token::SHR:
instr = HShr::NewHShr(zone(), context, left, right);
break;
case Token::SHL:
instr = HShl::NewHShl(zone(), context, left, right);
break;
default:
UNREACHABLE();
}
// If we hit an uninitialized binary op stub we will get type info
// for a smi operation. If one of the operands is a constant string
// do not generate code assuming it is a smi operation.
if (info.IsSmi() &&
((left->IsConstant() && HConstant::cast(left)->HasStringValue()) ||
(right->IsConstant() && HConstant::cast(right)->HasStringValue()))) {
return instr;
}
Representation rep = ToRepresentation(info);
// We only generate either int32 or generic tagged bitwise operations.
if (instr->IsBitwiseBinaryOperation() && rep.IsDouble()) {
rep = Representation::Integer32();
}
TraceRepresentation(expr->op(), info, instr, rep);
instr->AssumeRepresentation(rep);
return instr;
}
// Check for the form (%_ClassOf(foo) === 'BarClass').
static bool IsClassOfTest(CompareOperation* expr) {
if (expr->op() != Token::EQ_STRICT) return false;
CallRuntime* call = expr->left()->AsCallRuntime();
if (call == NULL) return false;
Literal* literal = expr->right()->AsLiteral();
if (literal == NULL) return false;
if (!literal->handle()->IsString()) return false;
if (!call->name()->IsEqualTo(CStrVector("_ClassOf"))) return false;
ASSERT(call->arguments()->length() == 1);
return true;
}
void HGraphBuilder::VisitBinaryOperation(BinaryOperation* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
switch (expr->op()) {
case Token::COMMA:
return VisitComma(expr);
case Token::OR:
case Token::AND:
return VisitLogicalExpression(expr);
default:
return VisitArithmeticExpression(expr);
}
}
void HGraphBuilder::VisitComma(BinaryOperation* expr) {
CHECK_ALIVE(VisitForEffect(expr->left()));
// Visit the right subexpression in the same AST context as the entire
// expression.
Visit(expr->right());
}
void HGraphBuilder::VisitLogicalExpression(BinaryOperation* expr) {
bool is_logical_and = expr->op() == Token::AND;
if (ast_context()->IsTest()) {
TestContext* context = TestContext::cast(ast_context());
// Translate left subexpression.
HBasicBlock* eval_right = graph()->CreateBasicBlock();
if (is_logical_and) {
CHECK_BAILOUT(VisitForControl(expr->left(),
eval_right,
context->if_false()));
} else {
CHECK_BAILOUT(VisitForControl(expr->left(),
context->if_true(),
eval_right));
}
// Translate right subexpression by visiting it in the same AST
// context as the entire expression.
if (eval_right->HasPredecessor()) {
eval_right->SetJoinId(expr->RightId());
set_current_block(eval_right);
Visit(expr->right());
}
} else if (ast_context()->IsValue()) {
CHECK_ALIVE(VisitForValue(expr->left()));
ASSERT(current_block() != NULL);
// We need an extra block to maintain edge-split form.
HBasicBlock* empty_block = graph()->CreateBasicBlock();
HBasicBlock* eval_right = graph()->CreateBasicBlock();
unsigned test_id = expr->left()->test_id();
ToBooleanStub::Types expected(oracle()->ToBooleanTypes(test_id));
HBranch* test = is_logical_and
? new(zone()) HBranch(Top(), eval_right, empty_block, expected)
: new(zone()) HBranch(Top(), empty_block, eval_right, expected);
current_block()->Finish(test);
set_current_block(eval_right);
Drop(1); // Value of the left subexpression.
CHECK_BAILOUT(VisitForValue(expr->right()));
HBasicBlock* join_block =
CreateJoin(empty_block, current_block(), expr->id());
set_current_block(join_block);
return ast_context()->ReturnValue(Pop());
} else {
ASSERT(ast_context()->IsEffect());
// In an effect context, we don't need the value of the left subexpression,
// only its control flow and side effects. We need an extra block to
// maintain edge-split form.
HBasicBlock* empty_block = graph()->CreateBasicBlock();
HBasicBlock* right_block = graph()->CreateBasicBlock();
if (is_logical_and) {
CHECK_BAILOUT(VisitForControl(expr->left(), right_block, empty_block));
} else {
CHECK_BAILOUT(VisitForControl(expr->left(), empty_block, right_block));
}
// TODO(kmillikin): Find a way to fix this. It's ugly that there are
// actually two empty blocks (one here and one inserted by
// TestContext::BuildBranch, and that they both have an HSimulate though the
// second one is not a merge node, and that we really have no good AST ID to
// put on that first HSimulate.
if (empty_block->HasPredecessor()) {
empty_block->SetJoinId(expr->id());
} else {
empty_block = NULL;
}
if (right_block->HasPredecessor()) {
right_block->SetJoinId(expr->RightId());
set_current_block(right_block);
CHECK_BAILOUT(VisitForEffect(expr->right()));
right_block = current_block();
} else {
right_block = NULL;
}
HBasicBlock* join_block =
CreateJoin(empty_block, right_block, expr->id());
set_current_block(join_block);
// We did not materialize any value in the predecessor environments,
// so there is no need to handle it here.
}
}
void HGraphBuilder::VisitArithmeticExpression(BinaryOperation* expr) {
CHECK_ALIVE(VisitForValue(expr->left()));
CHECK_ALIVE(VisitForValue(expr->right()));
HValue* right = Pop();
HValue* left = Pop();
HInstruction* instr = BuildBinaryOperation(expr, left, right);
instr->set_position(expr->position());
return ast_context()->ReturnInstruction(instr, expr->id());
}
void HGraphBuilder::TraceRepresentation(Token::Value op,
TypeInfo info,
HValue* value,
Representation rep) {
if (!FLAG_trace_representation) return;
// TODO(svenpanne) Under which circumstances are we actually not flexible?
// At first glance, this looks a bit weird...
bool flexible = value->CheckFlag(HValue::kFlexibleRepresentation);
PrintF("Operation %s has type info %s, %schange representation assumption "
"for %s (ID %d) from %s to %s\n",
Token::Name(op),
info.ToString(),
flexible ? "" : " DO NOT ",
value->Mnemonic(),
graph_->GetMaximumValueID(),
value->representation().Mnemonic(),
rep.Mnemonic());
}
Representation HGraphBuilder::ToRepresentation(TypeInfo info) {
if (info.IsSmi()) return Representation::Integer32();
if (info.IsInteger32()) return Representation::Integer32();
if (info.IsDouble()) return Representation::Double();
if (info.IsNumber()) return Representation::Double();
return Representation::Tagged();
}
void HGraphBuilder::HandleLiteralCompareTypeof(CompareOperation* expr,
HTypeof* typeof_expr,
Handle<String> check) {
// Note: The HTypeof itself is removed during canonicalization, if possible.
HValue* value = typeof_expr->value();
HTypeofIsAndBranch* instr = new(zone()) HTypeofIsAndBranch(value, check);
instr->set_position(expr->position());
return ast_context()->ReturnControl(instr, expr->id());
}
static bool MatchLiteralCompareNil(HValue* left,
Token::Value op,
HValue* right,
Handle<Object> nil,
HValue** expr) {
if (left->IsConstant() &&
HConstant::cast(left)->handle().is_identical_to(nil) &&
Token::IsEqualityOp(op)) {
*expr = right;
return true;
}
return false;
}
static bool MatchLiteralCompareTypeof(HValue* left,
Token::Value op,
HValue* right,
HTypeof** typeof_expr,
Handle<String>* check) {
if (left->IsTypeof() &&
Token::IsEqualityOp(op) &&
right->IsConstant() &&
HConstant::cast(right)->HasStringValue()) {
*typeof_expr = HTypeof::cast(left);
*check = Handle<String>::cast(HConstant::cast(right)->handle());
return true;
}
return false;
}
static bool IsLiteralCompareTypeof(HValue* left,
Token::Value op,
HValue* right,
HTypeof** typeof_expr,
Handle<String>* check) {
return MatchLiteralCompareTypeof(left, op, right, typeof_expr, check) ||
MatchLiteralCompareTypeof(right, op, left, typeof_expr, check);
}
static bool IsLiteralCompareNil(HValue* left,
Token::Value op,
HValue* right,
Handle<Object> nil,
HValue** expr) {
return MatchLiteralCompareNil(left, op, right, nil, expr) ||
MatchLiteralCompareNil(right, op, left, nil, expr);
}
static bool IsLiteralCompareBool(HValue* left,
Token::Value op,
HValue* right) {
return op == Token::EQ_STRICT &&
((left->IsConstant() && HConstant::cast(left)->handle()->IsBoolean()) ||
(right->IsConstant() && HConstant::cast(right)->handle()->IsBoolean()));
}
void HGraphBuilder::VisitCompareOperation(CompareOperation* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
if (IsClassOfTest(expr)) {
CallRuntime* call = expr->left()->AsCallRuntime();
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
Literal* literal = expr->right()->AsLiteral();
Handle<String> rhs = Handle<String>::cast(literal->handle());
HClassOfTestAndBranch* instr =
new(zone()) HClassOfTestAndBranch(value, rhs);
instr->set_position(expr->position());
return ast_context()->ReturnControl(instr, expr->id());
}
TypeInfo type_info = oracle()->CompareType(expr);
// Check if this expression was ever executed according to type feedback.
// Note that for the special typeof/null/undefined cases we get unknown here.
if (type_info.IsUninitialized()) {
AddInstruction(new(zone()) HSoftDeoptimize);
current_block()->MarkAsDeoptimizing();
type_info = TypeInfo::Unknown();
}
CHECK_ALIVE(VisitForValue(expr->left()));
CHECK_ALIVE(VisitForValue(expr->right()));
HValue* context = environment()->LookupContext();
HValue* right = Pop();
HValue* left = Pop();
Token::Value op = expr->op();
HTypeof* typeof_expr = NULL;
Handle<String> check;
if (IsLiteralCompareTypeof(left, op, right, &typeof_expr, &check)) {
return HandleLiteralCompareTypeof(expr, typeof_expr, check);
}
HValue* sub_expr = NULL;
Factory* f = graph()->isolate()->factory();
if (IsLiteralCompareNil(left, op, right, f->undefined_value(), &sub_expr)) {
return HandleLiteralCompareNil(expr, sub_expr, kUndefinedValue);
}
if (IsLiteralCompareNil(left, op, right, f->null_value(), &sub_expr)) {
return HandleLiteralCompareNil(expr, sub_expr, kNullValue);
}
if (IsLiteralCompareBool(left, op, right)) {
HCompareObjectEqAndBranch* result =
new(zone()) HCompareObjectEqAndBranch(left, right);
result->set_position(expr->position());
return ast_context()->ReturnControl(result, expr->id());
}
if (op == Token::INSTANCEOF) {
// Check to see if the rhs of the instanceof is a global function not
// residing in new space. If it is we assume that the function will stay the
// same.
Handle<JSFunction> target = Handle<JSFunction>::null();
VariableProxy* proxy = expr->right()->AsVariableProxy();
bool global_function = (proxy != NULL) && proxy->var()->IsUnallocated();
if (global_function &&
info()->has_global_object() &&
!info()->global_object()->IsAccessCheckNeeded()) {
Handle<String> name = proxy->name();
Handle<GlobalObject> global(info()->global_object());
LookupResult lookup(isolate());
global->Lookup(*name, &lookup);
if (lookup.IsFound() &&
lookup.type() == NORMAL &&
lookup.GetValue()->IsJSFunction()) {
Handle<JSFunction> candidate(JSFunction::cast(lookup.GetValue()));
// If the function is in new space we assume it's more likely to
// change and thus prefer the general IC code.
if (!isolate()->heap()->InNewSpace(*candidate)) {
target = candidate;
}
}
}
// If the target is not null we have found a known global function that is
// assumed to stay the same for this instanceof.
if (target.is_null()) {
HInstanceOf* result = new(zone()) HInstanceOf(context, left, right);
result->set_position(expr->position());
return ast_context()->ReturnInstruction(result, expr->id());
} else {
AddInstruction(new(zone()) HCheckFunction(right, target));
HInstanceOfKnownGlobal* result =
new(zone()) HInstanceOfKnownGlobal(context, left, target);
result->set_position(expr->position());
return ast_context()->ReturnInstruction(result, expr->id());
}
} else if (op == Token::IN) {
HIn* result = new(zone()) HIn(context, left, right);
result->set_position(expr->position());
return ast_context()->ReturnInstruction(result, expr->id());
} else if (type_info.IsNonPrimitive()) {
switch (op) {
case Token::EQ:
case Token::EQ_STRICT: {
// Can we get away with map check and not instance type check?
Handle<Map> map = oracle()->GetCompareMap(expr);
if (!map.is_null()) {
AddInstruction(new(zone()) HCheckNonSmi(left));
AddInstruction(new(zone()) HCheckMap(left, map, NULL,
ALLOW_ELEMENT_TRANSITION_MAPS));
AddInstruction(new(zone()) HCheckNonSmi(right));
AddInstruction(new(zone()) HCheckMap(right, map, NULL,
ALLOW_ELEMENT_TRANSITION_MAPS));
HCompareObjectEqAndBranch* result =
new(zone()) HCompareObjectEqAndBranch(left, right);
result->set_position(expr->position());
return ast_context()->ReturnControl(result, expr->id());
} else {
AddInstruction(new(zone()) HCheckNonSmi(left));
AddInstruction(HCheckInstanceType::NewIsSpecObject(left));
AddInstruction(new(zone()) HCheckNonSmi(right));
AddInstruction(HCheckInstanceType::NewIsSpecObject(right));
HCompareObjectEqAndBranch* result =
new(zone()) HCompareObjectEqAndBranch(left, right);
result->set_position(expr->position());
return ast_context()->ReturnControl(result, expr->id());
}
}
default:
return Bailout("Unsupported non-primitive compare");
}
} else if (type_info.IsString() && oracle()->IsSymbolCompare(expr) &&
(op == Token::EQ || op == Token::EQ_STRICT)) {
AddInstruction(new(zone()) HCheckNonSmi(left));
AddInstruction(HCheckInstanceType::NewIsSymbol(left));
AddInstruction(new(zone()) HCheckNonSmi(right));
AddInstruction(HCheckInstanceType::NewIsSymbol(right));
HCompareObjectEqAndBranch* result =
new(zone()) HCompareObjectEqAndBranch(left, right);
result->set_position(expr->position());
return ast_context()->ReturnControl(result, expr->id());
} else {
Representation r = ToRepresentation(type_info);
if (r.IsTagged()) {
HCompareGeneric* result =
new(zone()) HCompareGeneric(context, left, right, op);
result->set_position(expr->position());
return ast_context()->ReturnInstruction(result, expr->id());
} else {
HCompareIDAndBranch* result =
new(zone()) HCompareIDAndBranch(left, right, op);
result->set_position(expr->position());
result->SetInputRepresentation(r);
return ast_context()->ReturnControl(result, expr->id());
}
}
}
void HGraphBuilder::HandleLiteralCompareNil(CompareOperation* expr,
HValue* value,
NilValue nil) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
EqualityKind kind =
expr->op() == Token::EQ_STRICT ? kStrictEquality : kNonStrictEquality;
HIsNilAndBranch* instr = new(zone()) HIsNilAndBranch(value, kind, nil);
instr->set_position(expr->position());
return ast_context()->ReturnControl(instr, expr->id());
}
void HGraphBuilder::VisitThisFunction(ThisFunction* expr) {
ASSERT(!HasStackOverflow());
ASSERT(current_block() != NULL);
ASSERT(current_block()->HasPredecessor());
HThisFunction* self = new(zone()) HThisFunction(
function_state()->compilation_info()->closure());
return ast_context()->ReturnInstruction(self, expr->id());
}
void HGraphBuilder::VisitDeclarations(ZoneList<Declaration*>* declarations) {
int length = declarations->length();
int global_count = 0;
for (int i = 0; i < declarations->length(); i++) {
Declaration* decl = declarations->at(i);
FunctionDeclaration* fun_decl = decl->AsFunctionDeclaration();
HandleDeclaration(decl->proxy(),
decl->mode(),
fun_decl != NULL ? fun_decl->fun() : NULL,
&global_count);
}
// Batch declare global functions and variables.
if (global_count > 0) {
Handle<FixedArray> array =
isolate()->factory()->NewFixedArray(2 * global_count, TENURED);
for (int j = 0, i = 0; i < length; i++) {
Declaration* decl = declarations->at(i);
Variable* var = decl->proxy()->var();
if (var->IsUnallocated()) {
array->set(j++, *(var->name()));
FunctionDeclaration* fun_decl = decl->AsFunctionDeclaration();
if (fun_decl == NULL) {
if (var->binding_needs_init()) {
// In case this binding needs initialization use the hole.
array->set_the_hole(j++);
} else {
array->set_undefined(j++);
}
} else {
Handle<SharedFunctionInfo> function =
Compiler::BuildFunctionInfo(fun_decl->fun(), info()->script());
// Check for stack-overflow exception.
if (function.is_null()) {
SetStackOverflow();
return;
}
array->set(j++, *function);
}
}
}
int flags = DeclareGlobalsEvalFlag::encode(info()->is_eval()) |
DeclareGlobalsNativeFlag::encode(info()->is_native()) |
DeclareGlobalsLanguageMode::encode(info()->language_mode());
HInstruction* result =
new(zone()) HDeclareGlobals(environment()->LookupContext(),
array,
flags);
AddInstruction(result);
}
}
void HGraphBuilder::HandleDeclaration(VariableProxy* proxy,
VariableMode mode,
FunctionLiteral* function,
int* global_count) {
Variable* var = proxy->var();
bool binding_needs_init =
(mode == CONST || mode == CONST_HARMONY || mode == LET);
switch (var->location()) {
case Variable::UNALLOCATED:
++(*global_count);
return;
case Variable::PARAMETER:
case Variable::LOCAL:
case Variable::CONTEXT:
if (binding_needs_init || function != NULL) {
HValue* value = NULL;
if (function != NULL) {
CHECK_ALIVE(VisitForValue(function));
value = Pop();
} else {
value = graph()->GetConstantHole();
}
if (var->IsContextSlot()) {
HValue* context = environment()->LookupContext();
HStoreContextSlot* store = new HStoreContextSlot(
context, var->index(), HStoreContextSlot::kNoCheck, value);
AddInstruction(store);
if (store->HasObservableSideEffects()) AddSimulate(proxy->id());
} else {
environment()->Bind(var, value);
}
}
break;
case Variable::LOOKUP:
return Bailout("unsupported lookup slot in declaration");
}
}
void HGraphBuilder::VisitVariableDeclaration(VariableDeclaration* decl) {
UNREACHABLE();
}
void HGraphBuilder::VisitFunctionDeclaration(FunctionDeclaration* decl) {
UNREACHABLE();
}
void HGraphBuilder::VisitModuleDeclaration(ModuleDeclaration* decl) {
UNREACHABLE();
}
void HGraphBuilder::VisitImportDeclaration(ImportDeclaration* decl) {
UNREACHABLE();
}
void HGraphBuilder::VisitExportDeclaration(ExportDeclaration* decl) {
UNREACHABLE();
}
void HGraphBuilder::VisitModuleLiteral(ModuleLiteral* module) {
// TODO(rossberg)
}
void HGraphBuilder::VisitModuleVariable(ModuleVariable* module) {
// TODO(rossberg)
}
void HGraphBuilder::VisitModulePath(ModulePath* module) {
// TODO(rossberg)
}
void HGraphBuilder::VisitModuleUrl(ModuleUrl* module) {
// TODO(rossberg)
}
// Generators for inline runtime functions.
// Support for types.
void HGraphBuilder::GenerateIsSmi(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HIsSmiAndBranch* result = new(zone()) HIsSmiAndBranch(value);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsSpecObject(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HHasInstanceTypeAndBranch* result =
new(zone()) HHasInstanceTypeAndBranch(value,
FIRST_SPEC_OBJECT_TYPE,
LAST_SPEC_OBJECT_TYPE);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsFunction(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HHasInstanceTypeAndBranch* result =
new(zone()) HHasInstanceTypeAndBranch(value, JS_FUNCTION_TYPE);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateHasCachedArrayIndex(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HHasCachedArrayIndexAndBranch* result =
new(zone()) HHasCachedArrayIndexAndBranch(value);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsArray(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HHasInstanceTypeAndBranch* result =
new(zone()) HHasInstanceTypeAndBranch(value, JS_ARRAY_TYPE);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsRegExp(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HHasInstanceTypeAndBranch* result =
new(zone()) HHasInstanceTypeAndBranch(value, JS_REGEXP_TYPE);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsObject(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HIsObjectAndBranch* result = new(zone()) HIsObjectAndBranch(value);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsNonNegativeSmi(CallRuntime* call) {
return Bailout("inlined runtime function: IsNonNegativeSmi");
}
void HGraphBuilder::GenerateIsUndetectableObject(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HIsUndetectableAndBranch* result =
new(zone()) HIsUndetectableAndBranch(value);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateIsStringWrapperSafeForDefaultValueOf(
CallRuntime* call) {
return Bailout(
"inlined runtime function: IsStringWrapperSafeForDefaultValueOf");
}
// Support for construct call checks.
void HGraphBuilder::GenerateIsConstructCall(CallRuntime* call) {
ASSERT(call->arguments()->length() == 0);
if (function_state()->outer() != NULL) {
// We are generating graph for inlined function.
HValue* value = function_state()->is_construct()
? graph()->GetConstantTrue()
: graph()->GetConstantFalse();
return ast_context()->ReturnValue(value);
} else {
return ast_context()->ReturnControl(new(zone()) HIsConstructCallAndBranch,
call->id());
}
}
// Support for arguments.length and arguments[?].
void HGraphBuilder::GenerateArgumentsLength(CallRuntime* call) {
// Our implementation of arguments (based on this stack frame or an
// adapter below it) does not work for inlined functions. This runtime
// function is blacklisted by AstNode::IsInlineable.
ASSERT(function_state()->outer() == NULL);
ASSERT(call->arguments()->length() == 0);
HInstruction* elements = AddInstruction(new(zone()) HArgumentsElements);
HArgumentsLength* result = new(zone()) HArgumentsLength(elements);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateArguments(CallRuntime* call) {
// Our implementation of arguments (based on this stack frame or an
// adapter below it) does not work for inlined functions. This runtime
// function is blacklisted by AstNode::IsInlineable.
ASSERT(function_state()->outer() == NULL);
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* index = Pop();
HInstruction* elements = AddInstruction(new(zone()) HArgumentsElements);
HInstruction* length = AddInstruction(new(zone()) HArgumentsLength(elements));
HAccessArgumentsAt* result =
new(zone()) HAccessArgumentsAt(elements, length, index);
return ast_context()->ReturnInstruction(result, call->id());
}
// Support for accessing the class and value fields of an object.
void HGraphBuilder::GenerateClassOf(CallRuntime* call) {
// The special form detected by IsClassOfTest is detected before we get here
// and does not cause a bailout.
return Bailout("inlined runtime function: ClassOf");
}
void HGraphBuilder::GenerateValueOf(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HValueOf* result = new(zone()) HValueOf(value);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateDateField(CallRuntime* call) {
ASSERT(call->arguments()->length() == 2);
ASSERT_NE(NULL, call->arguments()->at(1)->AsLiteral());
Smi* index = Smi::cast(*(call->arguments()->at(1)->AsLiteral()->handle()));
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* date = Pop();
HDateField* result = new(zone()) HDateField(date, index);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateSetValueOf(CallRuntime* call) {
ASSERT(call->arguments()->length() == 2);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
CHECK_ALIVE(VisitForValue(call->arguments()->at(1)));
HValue* value = Pop();
HValue* object = Pop();
// Check if object is a not a smi.
HIsSmiAndBranch* smicheck = new(zone()) HIsSmiAndBranch(object);
HBasicBlock* if_smi = graph()->CreateBasicBlock();
HBasicBlock* if_heap_object = graph()->CreateBasicBlock();
HBasicBlock* join = graph()->CreateBasicBlock();
smicheck->SetSuccessorAt(0, if_smi);
smicheck->SetSuccessorAt(1, if_heap_object);
current_block()->Finish(smicheck);
if_smi->Goto(join);
// Check if object is a JSValue.
set_current_block(if_heap_object);
HHasInstanceTypeAndBranch* typecheck =
new(zone()) HHasInstanceTypeAndBranch(object, JS_VALUE_TYPE);
HBasicBlock* if_js_value = graph()->CreateBasicBlock();
HBasicBlock* not_js_value = graph()->CreateBasicBlock();
typecheck->SetSuccessorAt(0, if_js_value);
typecheck->SetSuccessorAt(1, not_js_value);
current_block()->Finish(typecheck);
not_js_value->Goto(join);
// Create in-object property store to kValueOffset.
set_current_block(if_js_value);
Handle<String> name = isolate()->factory()->undefined_symbol();
AddInstruction(new HStoreNamedField(object,
name,
value,
true, // in-object store.
JSValue::kValueOffset));
if_js_value->Goto(join);
join->SetJoinId(call->id());
set_current_block(join);
return ast_context()->ReturnValue(value);
}
// Fast support for charCodeAt(n).
void HGraphBuilder::GenerateStringCharCodeAt(CallRuntime* call) {
ASSERT(call->arguments()->length() == 2);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
CHECK_ALIVE(VisitForValue(call->arguments()->at(1)));
HValue* index = Pop();
HValue* string = Pop();
HValue* context = environment()->LookupContext();
HStringCharCodeAt* result = BuildStringCharCodeAt(context, string, index);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast support for string.charAt(n) and string[n].
void HGraphBuilder::GenerateStringCharFromCode(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* char_code = Pop();
HValue* context = environment()->LookupContext();
HStringCharFromCode* result =
new(zone()) HStringCharFromCode(context, char_code);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast support for string.charAt(n) and string[n].
void HGraphBuilder::GenerateStringCharAt(CallRuntime* call) {
ASSERT(call->arguments()->length() == 2);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
CHECK_ALIVE(VisitForValue(call->arguments()->at(1)));
HValue* index = Pop();
HValue* string = Pop();
HValue* context = environment()->LookupContext();
HStringCharCodeAt* char_code = BuildStringCharCodeAt(context, string, index);
AddInstruction(char_code);
HStringCharFromCode* result =
new(zone()) HStringCharFromCode(context, char_code);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast support for object equality testing.
void HGraphBuilder::GenerateObjectEquals(CallRuntime* call) {
ASSERT(call->arguments()->length() == 2);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
CHECK_ALIVE(VisitForValue(call->arguments()->at(1)));
HValue* right = Pop();
HValue* left = Pop();
HCompareObjectEqAndBranch* result =
new(zone()) HCompareObjectEqAndBranch(left, right);
return ast_context()->ReturnControl(result, call->id());
}
void HGraphBuilder::GenerateLog(CallRuntime* call) {
// %_Log is ignored in optimized code.
return ast_context()->ReturnValue(graph()->GetConstantUndefined());
}
// Fast support for Math.random().
void HGraphBuilder::GenerateRandomHeapNumber(CallRuntime* call) {
HValue* context = environment()->LookupContext();
HGlobalObject* global_object = new(zone()) HGlobalObject(context);
AddInstruction(global_object);
HRandom* result = new(zone()) HRandom(global_object);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast support for StringAdd.
void HGraphBuilder::GenerateStringAdd(CallRuntime* call) {
ASSERT_EQ(2, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result = new(zone()) HCallStub(context, CodeStub::StringAdd, 2);
Drop(2);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast support for SubString.
void HGraphBuilder::GenerateSubString(CallRuntime* call) {
ASSERT_EQ(3, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result = new(zone()) HCallStub(context, CodeStub::SubString, 3);
Drop(3);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast support for StringCompare.
void HGraphBuilder::GenerateStringCompare(CallRuntime* call) {
ASSERT_EQ(2, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::StringCompare, 2);
Drop(2);
return ast_context()->ReturnInstruction(result, call->id());
}
// Support for direct calls from JavaScript to native RegExp code.
void HGraphBuilder::GenerateRegExpExec(CallRuntime* call) {
ASSERT_EQ(4, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result = new(zone()) HCallStub(context, CodeStub::RegExpExec, 4);
Drop(4);
return ast_context()->ReturnInstruction(result, call->id());
}
// Construct a RegExp exec result with two in-object properties.
void HGraphBuilder::GenerateRegExpConstructResult(CallRuntime* call) {
ASSERT_EQ(3, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::RegExpConstructResult, 3);
Drop(3);
return ast_context()->ReturnInstruction(result, call->id());
}
// Support for fast native caches.
void HGraphBuilder::GenerateGetFromCache(CallRuntime* call) {
return Bailout("inlined runtime function: GetFromCache");
}
// Fast support for number to string.
void HGraphBuilder::GenerateNumberToString(CallRuntime* call) {
ASSERT_EQ(1, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::NumberToString, 1);
Drop(1);
return ast_context()->ReturnInstruction(result, call->id());
}
// Fast call for custom callbacks.
void HGraphBuilder::GenerateCallFunction(CallRuntime* call) {
// 1 ~ The function to call is not itself an argument to the call.
int arg_count = call->arguments()->length() - 1;
ASSERT(arg_count >= 1); // There's always at least a receiver.
for (int i = 0; i < arg_count; ++i) {
CHECK_ALIVE(VisitArgument(call->arguments()->at(i)));
}
CHECK_ALIVE(VisitForValue(call->arguments()->last()));
HValue* function = Pop();
HValue* context = environment()->LookupContext();
// Branch for function proxies, or other non-functions.
HHasInstanceTypeAndBranch* typecheck =
new(zone()) HHasInstanceTypeAndBranch(function, JS_FUNCTION_TYPE);
HBasicBlock* if_jsfunction = graph()->CreateBasicBlock();
HBasicBlock* if_nonfunction = graph()->CreateBasicBlock();
HBasicBlock* join = graph()->CreateBasicBlock();
typecheck->SetSuccessorAt(0, if_jsfunction);
typecheck->SetSuccessorAt(1, if_nonfunction);
current_block()->Finish(typecheck);
set_current_block(if_jsfunction);
HInstruction* invoke_result = AddInstruction(
new(zone()) HInvokeFunction(context, function, arg_count));
Drop(arg_count);
Push(invoke_result);
if_jsfunction->Goto(join);
set_current_block(if_nonfunction);
HInstruction* call_result = AddInstruction(
new(zone()) HCallFunction(context, function, arg_count));
Drop(arg_count);
Push(call_result);
if_nonfunction->Goto(join);
set_current_block(join);
join->SetJoinId(call->id());
return ast_context()->ReturnValue(Pop());
}
// Fast call to math functions.
void HGraphBuilder::GenerateMathPow(CallRuntime* call) {
ASSERT_EQ(2, call->arguments()->length());
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
CHECK_ALIVE(VisitForValue(call->arguments()->at(1)));
HValue* right = Pop();
HValue* left = Pop();
HPower* result = new(zone()) HPower(left, right);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateMathSin(CallRuntime* call) {
ASSERT_EQ(1, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::TranscendentalCache, 1);
result->set_transcendental_type(TranscendentalCache::SIN);
Drop(1);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateMathCos(CallRuntime* call) {
ASSERT_EQ(1, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::TranscendentalCache, 1);
result->set_transcendental_type(TranscendentalCache::COS);
Drop(1);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateMathTan(CallRuntime* call) {
ASSERT_EQ(1, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::TranscendentalCache, 1);
result->set_transcendental_type(TranscendentalCache::TAN);
Drop(1);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateMathLog(CallRuntime* call) {
ASSERT_EQ(1, call->arguments()->length());
CHECK_ALIVE(VisitArgumentList(call->arguments()));
HValue* context = environment()->LookupContext();
HCallStub* result =
new(zone()) HCallStub(context, CodeStub::TranscendentalCache, 1);
result->set_transcendental_type(TranscendentalCache::LOG);
Drop(1);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateMathSqrt(CallRuntime* call) {
return Bailout("inlined runtime function: MathSqrt");
}
// Check whether two RegExps are equivalent
void HGraphBuilder::GenerateIsRegExpEquivalent(CallRuntime* call) {
return Bailout("inlined runtime function: IsRegExpEquivalent");
}
void HGraphBuilder::GenerateGetCachedArrayIndex(CallRuntime* call) {
ASSERT(call->arguments()->length() == 1);
CHECK_ALIVE(VisitForValue(call->arguments()->at(0)));
HValue* value = Pop();
HGetCachedArrayIndex* result = new(zone()) HGetCachedArrayIndex(value);
return ast_context()->ReturnInstruction(result, call->id());
}
void HGraphBuilder::GenerateFastAsciiArrayJoin(CallRuntime* call) {
return Bailout("inlined runtime function: FastAsciiArrayJoin");
}
#undef CHECK_BAILOUT
#undef CHECK_ALIVE
HEnvironment::HEnvironment(HEnvironment* outer,
Scope* scope,
Handle<JSFunction> closure)
: closure_(closure),
values_(0),
assigned_variables_(4),
frame_type_(JS_FUNCTION),
parameter_count_(0),
specials_count_(1),
local_count_(0),
outer_(outer),
pop_count_(0),
push_count_(0),
ast_id_(AstNode::kNoNumber) {
Initialize(scope->num_parameters() + 1, scope->num_stack_slots(), 0);
}
HEnvironment::HEnvironment(const HEnvironment* other)
: values_(0),
assigned_variables_(0),
frame_type_(JS_FUNCTION),
parameter_count_(0),
specials_count_(1),
local_count_(0),
outer_(NULL),
pop_count_(0),
push_count_(0),
ast_id_(other->ast_id()) {
Initialize(other);
}
HEnvironment::HEnvironment(HEnvironment* outer,
Handle<JSFunction> closure,
FrameType frame_type,
int arguments)
: closure_(closure),
values_(arguments),
assigned_variables_(0),
frame_type_(frame_type),
parameter_count_(arguments),
local_count_(0),
outer_(outer),
pop_count_(0),
push_count_(0),
ast_id_(AstNode::kNoNumber) {
}
void HEnvironment::Initialize(int parameter_count,
int local_count,
int stack_height) {
parameter_count_ = parameter_count;
local_count_ = local_count;
// Avoid reallocating the temporaries' backing store on the first Push.
int total = parameter_count + specials_count_ + local_count + stack_height;
values_.Initialize(total + 4);
for (int i = 0; i < total; ++i) values_.Add(NULL);
}
void HEnvironment::Initialize(const HEnvironment* other) {
closure_ = other->closure();
values_.AddAll(other->values_);
assigned_variables_.AddAll(other->assigned_variables_);
frame_type_ = other->frame_type_;
parameter_count_ = other->parameter_count_;
local_count_ = other->local_count_;
if (other->outer_ != NULL) outer_ = other->outer_->Copy(); // Deep copy.
pop_count_ = other->pop_count_;
push_count_ = other->push_count_;
ast_id_ = other->ast_id_;
}
void HEnvironment::AddIncomingEdge(HBasicBlock* block, HEnvironment* other) {
ASSERT(!block->IsLoopHeader());
ASSERT(values_.length() == other->values_.length());
int length = values_.length();
for (int i = 0; i < length; ++i) {
HValue* value = values_[i];
if (value != NULL && value->IsPhi() && value->block() == block) {
// There is already a phi for the i'th value.
HPhi* phi = HPhi::cast(value);
// Assert index is correct and that we haven't missed an incoming edge.
ASSERT(phi->merged_index() == i);
ASSERT(phi->OperandCount() == block->predecessors()->length());
phi->AddInput(other->values_[i]);
} else if (values_[i] != other->values_[i]) {
// There is a fresh value on the incoming edge, a phi is needed.
ASSERT(values_[i] != NULL && other->values_[i] != NULL);
HPhi* phi = new(block->zone()) HPhi(i);
HValue* old_value = values_[i];
for (int j = 0; j < block->predecessors()->length(); j++) {
phi->AddInput(old_value);
}
phi->AddInput(other->values_[i]);
this->values_[i] = phi;
block->AddPhi(phi);
}
}
}
void HEnvironment::Bind(int index, HValue* value) {
ASSERT(value != NULL);
if (!assigned_variables_.Contains(index)) {
assigned_variables_.Add(index);
}
values_[index] = value;
}
bool HEnvironment::HasExpressionAt(int index) const {
return index >= parameter_count_ + specials_count_ + local_count_;
}
bool HEnvironment::ExpressionStackIsEmpty() const {
ASSERT(length() >= first_expression_index());
return length() == first_expression_index();
}
void HEnvironment::SetExpressionStackAt(int index_from_top, HValue* value) {
int count = index_from_top + 1;
int index = values_.length() - count;
ASSERT(HasExpressionAt(index));
// The push count must include at least the element in question or else
// the new value will not be included in this environment's history.
if (push_count_ < count) {
// This is the same effect as popping then re-pushing 'count' elements.
pop_count_ += (count - push_count_);
push_count_ = count;
}
values_[index] = value;
}
void HEnvironment::Drop(int count) {
for (int i = 0; i < count; ++i) {
Pop();
}
}
HEnvironment* HEnvironment::Copy() const {
return new(closure()->GetIsolate()->zone()) HEnvironment(this);
}
HEnvironment* HEnvironment::CopyWithoutHistory() const {
HEnvironment* result = Copy();
result->ClearHistory();
return result;
}
HEnvironment* HEnvironment::CopyAsLoopHeader(HBasicBlock* loop_header) const {
HEnvironment* new_env = Copy();
for (int i = 0; i < values_.length(); ++i) {
HPhi* phi = new(loop_header->zone()) HPhi(i);
phi->AddInput(values_[i]);
new_env->values_[i] = phi;
loop_header->AddPhi(phi);
}
new_env->ClearHistory();
return new_env;
}
HEnvironment* HEnvironment::CreateStubEnvironment(HEnvironment* outer,
Handle<JSFunction> target,
FrameType frame_type,
int arguments) const {
HEnvironment* new_env = new(closure()->GetIsolate()->zone())
HEnvironment(outer, target, frame_type, arguments + 1);
for (int i = 0; i <= arguments; ++i) { // Include receiver.
new_env->Push(ExpressionStackAt(arguments - i));
}
new_env->ClearHistory();
return new_env;
}
HEnvironment* HEnvironment::CopyForInlining(
Handle<JSFunction> target,
int arguments,
FunctionLiteral* function,
HConstant* undefined,
CallKind call_kind,
bool is_construct) const {
ASSERT(frame_type() == JS_FUNCTION);
Zone* zone = closure()->GetIsolate()->zone();
// Outer environment is a copy of this one without the arguments.
int arity = function->scope()->num_parameters();
HEnvironment* outer = Copy();
outer->Drop(arguments + 1); // Including receiver.
outer->ClearHistory();
if (is_construct) {
// Create artificial constructor stub environment. The receiver should
// actually be the constructor function, but we pass the newly allocated
// object instead, DoComputeConstructStubFrame() relies on that.
outer = CreateStubEnvironment(outer, target, JS_CONSTRUCT, arguments);
}
if (arity != arguments) {
// Create artificial arguments adaptation environment.
outer = CreateStubEnvironment(outer, target, ARGUMENTS_ADAPTOR, arguments);
}
HEnvironment* inner =
new(zone) HEnvironment(outer, function->scope(), target);
// Get the argument values from the original environment.
for (int i = 0; i <= arity; ++i) { // Include receiver.
HValue* push = (i <= arguments) ?
ExpressionStackAt(arguments - i) : undefined;
inner->SetValueAt(i, push);
}
// If the function we are inlining is a strict mode function or a
// builtin function, pass undefined as the receiver for function
// calls (instead of the global receiver).
if ((target->shared()->native() || !function->is_classic_mode()) &&
call_kind == CALL_AS_FUNCTION && !is_construct) {
inner->SetValueAt(0, undefined);
}
inner->SetValueAt(arity + 1, LookupContext());
for (int i = arity + 2; i < inner->length(); ++i) {
inner->SetValueAt(i, undefined);
}
inner->set_ast_id(AstNode::kFunctionEntryId);
return inner;
}
void HEnvironment::PrintTo(StringStream* stream) {
for (int i = 0; i < length(); i++) {
if (i == 0) stream->Add("parameters\n");
if (i == parameter_count()) stream->Add("specials\n");
if (i == parameter_count() + specials_count()) stream->Add("locals\n");
if (i == parameter_count() + specials_count() + local_count()) {
stream->Add("expressions\n");
}
HValue* val = values_.at(i);
stream->Add("%d: ", i);
if (val != NULL) {
val->PrintNameTo(stream);
} else {
stream->Add("NULL");
}
stream->Add("\n");
}
PrintF("\n");
}
void HEnvironment::PrintToStd() {
HeapStringAllocator string_allocator;
StringStream trace(&string_allocator);
PrintTo(&trace);
PrintF("%s", *trace.ToCString());
}
void HTracer::TraceCompilation(FunctionLiteral* function) {
Tag tag(this, "compilation");
Handle<String> name = function->debug_name();
PrintStringProperty("name", *name->ToCString());
PrintStringProperty("method", *name->ToCString());
PrintLongProperty("date", static_cast<int64_t>(OS::TimeCurrentMillis()));
}
void HTracer::TraceLithium(const char* name, LChunk* chunk) {
Trace(name, chunk->graph(), chunk);
}
void HTracer::TraceHydrogen(const char* name, HGraph* graph) {
Trace(name, graph, NULL);
}
void HTracer::Trace(const char* name, HGraph* graph, LChunk* chunk) {
Tag tag(this, "cfg");
PrintStringProperty("name", name);
const ZoneList<HBasicBlock*>* blocks = graph->blocks();
for (int i = 0; i < blocks->length(); i++) {
HBasicBlock* current = blocks->at(i);
Tag block_tag(this, "block");
PrintBlockProperty("name", current->block_id());
PrintIntProperty("from_bci", -1);
PrintIntProperty("to_bci", -1);
if (!current->predecessors()->is_empty()) {
PrintIndent();
trace_.Add("predecessors");
for (int j = 0; j < current->predecessors()->length(); ++j) {
trace_.Add(" \"B%d\"", current->predecessors()->at(j)->block_id());
}
trace_.Add("\n");
} else {
PrintEmptyProperty("predecessors");
}
if (current->end()->SuccessorCount() == 0) {
PrintEmptyProperty("successors");
} else {
PrintIndent();
trace_.Add("successors");
for (HSuccessorIterator it(current->end()); !it.Done(); it.Advance()) {
trace_.Add(" \"B%d\"", it.Current()->block_id());
}
trace_.Add("\n");
}
PrintEmptyProperty("xhandlers");
const char* flags = current->IsLoopSuccessorDominator()
? "dom-loop-succ"
: "";
PrintStringProperty("flags", flags);
if (current->dominator() != NULL) {
PrintBlockProperty("dominator", current->dominator()->block_id());
}
PrintIntProperty("loop_depth", current->LoopNestingDepth());
if (chunk != NULL) {
int first_index = current->first_instruction_index();
int last_index = current->last_instruction_index();
PrintIntProperty(
"first_lir_id",
LifetimePosition::FromInstructionIndex(first_index).Value());
PrintIntProperty(
"last_lir_id",
LifetimePosition::FromInstructionIndex(last_index).Value());
}
{
Tag states_tag(this, "states");
Tag locals_tag(this, "locals");
int total = current->phis()->length();
PrintIntProperty("size", current->phis()->length());
PrintStringProperty("method", "None");
for (int j = 0; j < total; ++j) {
HPhi* phi = current->phis()->at(j);
PrintIndent();
trace_.Add("%d ", phi->merged_index());
phi->PrintNameTo(&trace_);
trace_.Add(" ");
phi->PrintTo(&trace_);
trace_.Add("\n");
}
}
{
Tag HIR_tag(this, "HIR");
HInstruction* instruction = current->first();
while (instruction != NULL) {
int bci = 0;
int uses = instruction->UseCount();
PrintIndent();
trace_.Add("%d %d ", bci, uses);
instruction->PrintNameTo(&trace_);
trace_.Add(" ");
instruction->PrintTo(&trace_);
trace_.Add(" <|@\n");
instruction = instruction->next();
}
}
if (chunk != NULL) {
Tag LIR_tag(this, "LIR");
int first_index = current->first_instruction_index();
int last_index = current->last_instruction_index();
if (first_index != -1 && last_index != -1) {
const ZoneList<LInstruction*>* instructions = chunk->instructions();
for (int i = first_index; i <= last_index; ++i) {
LInstruction* linstr = instructions->at(i);
if (linstr != NULL) {
PrintIndent();
trace_.Add("%d ",
LifetimePosition::FromInstructionIndex(i).Value());
linstr->PrintTo(&trace_);
trace_.Add(" <|@\n");
}
}
}
}
}
}
void HTracer::TraceLiveRanges(const char* name, LAllocator* allocator) {
Tag tag(this, "intervals");
PrintStringProperty("name", name);
const Vector<LiveRange*>* fixed_d = allocator->fixed_double_live_ranges();
for (int i = 0; i < fixed_d->length(); ++i) {
TraceLiveRange(fixed_d->at(i), "fixed");
}
const Vector<LiveRange*>* fixed = allocator->fixed_live_ranges();
for (int i = 0; i < fixed->length(); ++i) {
TraceLiveRange(fixed->at(i), "fixed");
}
const ZoneList<LiveRange*>* live_ranges = allocator->live_ranges();
for (int i = 0; i < live_ranges->length(); ++i) {
TraceLiveRange(live_ranges->at(i), "object");
}
}
void HTracer::TraceLiveRange(LiveRange* range, const char* type) {
if (range != NULL && !range->IsEmpty()) {
PrintIndent();
trace_.Add("%d %s", range->id(), type);
if (range->HasRegisterAssigned()) {
LOperand* op = range->CreateAssignedOperand(ZONE);
int assigned_reg = op->index();
if (op->IsDoubleRegister()) {
trace_.Add(" \"%s\"",
DoubleRegister::AllocationIndexToString(assigned_reg));
} else {
ASSERT(op->IsRegister());
trace_.Add(" \"%s\"", Register::AllocationIndexToString(assigned_reg));
}
} else if (range->IsSpilled()) {
LOperand* op = range->TopLevel()->GetSpillOperand();
if (op->IsDoubleStackSlot()) {
trace_.Add(" \"double_stack:%d\"", op->index());
} else {
ASSERT(op->IsStackSlot());
trace_.Add(" \"stack:%d\"", op->index());
}
}
int parent_index = -1;
if (range->IsChild()) {
parent_index = range->parent()->id();
} else {
parent_index = range->id();
}
LOperand* op = range->FirstHint();
int hint_index = -1;
if (op != NULL && op->IsUnallocated()) {
hint_index = LUnallocated::cast(op)->virtual_register();
}
trace_.Add(" %d %d", parent_index, hint_index);
UseInterval* cur_interval = range->first_interval();
while (cur_interval != NULL && range->Covers(cur_interval->start())) {
trace_.Add(" [%d, %d[",
cur_interval->start().Value(),
cur_interval->end().Value());
cur_interval = cur_interval->next();
}
UsePosition* current_pos = range->first_pos();
while (current_pos != NULL) {
if (current_pos->RegisterIsBeneficial() || FLAG_trace_all_uses) {
trace_.Add(" %d M", current_pos->pos().Value());
}
current_pos = current_pos->next();
}
trace_.Add(" \"\"\n");
}
}
void HTracer::FlushToFile() {
AppendChars(filename_, *trace_.ToCString(), trace_.length(), false);
trace_.Reset();
}
void HStatistics::Initialize(CompilationInfo* info) {
source_size_ += info->shared_info()->SourceSize();
}
void HStatistics::Print() {
PrintF("Timing results:\n");
int64_t sum = 0;
for (int i = 0; i < timing_.length(); ++i) {
sum += timing_[i];
}
for (int i = 0; i < names_.length(); ++i) {
PrintF("%30s", names_[i]);
double ms = static_cast<double>(timing_[i]) / 1000;
double percent = static_cast<double>(timing_[i]) * 100 / sum;
PrintF(" - %7.3f ms / %4.1f %% ", ms, percent);
unsigned size = sizes_[i];
double size_percent = static_cast<double>(size) * 100 / total_size_;
PrintF(" %8u bytes / %4.1f %%\n", size, size_percent);
}
double source_size_in_kb = static_cast<double>(source_size_) / 1024;
double normalized_time = source_size_in_kb > 0
? (static_cast<double>(sum) / 1000) / source_size_in_kb
: 0;
double normalized_bytes = source_size_in_kb > 0
? total_size_ / source_size_in_kb
: 0;
PrintF("%30s - %7.3f ms %7.3f bytes\n", "Sum",
normalized_time, normalized_bytes);
PrintF("---------------------------------------------------------------\n");
PrintF("%30s - %7.3f ms (%.1f times slower than full code gen)\n",
"Total",
static_cast<double>(total_) / 1000,
static_cast<double>(total_) / full_code_gen_);
}
void HStatistics::SaveTiming(const char* name, int64_t ticks, unsigned size) {
if (name == HPhase::kFullCodeGen) {
full_code_gen_ += ticks;
} else if (name == HPhase::kTotal) {
total_ += ticks;
} else {
total_size_ += size;
for (int i = 0; i < names_.length(); ++i) {
if (names_[i] == name) {
timing_[i] += ticks;
sizes_[i] += size;
return;
}
}
names_.Add(name);
timing_.Add(ticks);
sizes_.Add(size);
}
}
const char* const HPhase::kFullCodeGen = "Full code generator";
const char* const HPhase::kTotal = "Total";
void HPhase::Begin(const char* name,
HGraph* graph,
LChunk* chunk,
LAllocator* allocator) {
name_ = name;
graph_ = graph;
chunk_ = chunk;
allocator_ = allocator;
if (allocator != NULL && chunk_ == NULL) {
chunk_ = allocator->chunk();
}
if (FLAG_hydrogen_stats) start_ = OS::Ticks();
start_allocation_size_ = Zone::allocation_size_;
}
void HPhase::End() const {
if (FLAG_hydrogen_stats) {
int64_t end = OS::Ticks();
unsigned size = Zone::allocation_size_ - start_allocation_size_;
HStatistics::Instance()->SaveTiming(name_, end - start_, size);
}
// Produce trace output if flag is set so that the first letter of the
// phase name matches the command line parameter FLAG_trace_phase.
if (FLAG_trace_hydrogen &&
OS::StrChr(const_cast<char*>(FLAG_trace_phase), name_[0]) != NULL) {
if (graph_ != NULL) HTracer::Instance()->TraceHydrogen(name_, graph_);
if (chunk_ != NULL) HTracer::Instance()->TraceLithium(name_, chunk_);
if (allocator_ != NULL) {
HTracer::Instance()->TraceLiveRanges(name_, allocator_);
}
}
#ifdef DEBUG
if (graph_ != NULL) graph_->Verify(false); // No full verify.
if (allocator_ != NULL) allocator_->Verify();
#endif
}
} } // namespace v8::internal