// 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 "double.h" #include "factory.h" #include "hydrogen-infer-representation.h" #if V8_TARGET_ARCH_IA32 #include "ia32/lithium-ia32.h" #elif V8_TARGET_ARCH_X64 #include "x64/lithium-x64.h" #elif V8_TARGET_ARCH_ARM #include "arm/lithium-arm.h" #elif V8_TARGET_ARCH_MIPS #include "mips/lithium-mips.h" #else #error Unsupported target architecture. #endif namespace v8 { namespace internal { #define DEFINE_COMPILE(type) \ LInstruction* H##type::CompileToLithium(LChunkBuilder* builder) { \ return builder->Do##type(this); \ } HYDROGEN_CONCRETE_INSTRUCTION_LIST(DEFINE_COMPILE) #undef DEFINE_COMPILE int HValue::LoopWeight() const { const int w = FLAG_loop_weight; static const int weights[] = { 1, w, w*w, w*w*w, w*w*w*w }; return weights[Min(block()->LoopNestingDepth(), static_cast(ARRAY_SIZE(weights)-1))]; } Isolate* HValue::isolate() const { ASSERT(block() != NULL); return block()->isolate(); } void HValue::AssumeRepresentation(Representation r) { if (CheckFlag(kFlexibleRepresentation)) { ChangeRepresentation(r); // The representation of the value is dictated by type feedback and // will not be changed later. ClearFlag(kFlexibleRepresentation); } } void HValue::InferRepresentation(HInferRepresentationPhase* h_infer) { ASSERT(CheckFlag(kFlexibleRepresentation)); Representation new_rep = RepresentationFromInputs(); UpdateRepresentation(new_rep, h_infer, "inputs"); new_rep = RepresentationFromUses(); UpdateRepresentation(new_rep, h_infer, "uses"); if (representation().IsSmi() && HasNonSmiUse()) { UpdateRepresentation( Representation::Integer32(), h_infer, "use requirements"); } } Representation HValue::RepresentationFromUses() { if (HasNoUses()) return Representation::None(); // Array of use counts for each representation. int use_count[Representation::kNumRepresentations] = { 0 }; for (HUseIterator it(uses()); !it.Done(); it.Advance()) { HValue* use = it.value(); Representation rep = use->observed_input_representation(it.index()); if (rep.IsNone()) continue; if (FLAG_trace_representation) { PrintF("#%d %s is used by #%d %s as %s%s\n", id(), Mnemonic(), use->id(), use->Mnemonic(), rep.Mnemonic(), (use->CheckFlag(kTruncatingToInt32) ? "-trunc" : "")); } use_count[rep.kind()] += use->LoopWeight(); } if (IsPhi()) HPhi::cast(this)->AddIndirectUsesTo(&use_count[0]); int tagged_count = use_count[Representation::kTagged]; int double_count = use_count[Representation::kDouble]; int int32_count = use_count[Representation::kInteger32]; int smi_count = use_count[Representation::kSmi]; if (tagged_count > 0) return Representation::Tagged(); if (double_count > 0) return Representation::Double(); if (int32_count > 0) return Representation::Integer32(); if (smi_count > 0) return Representation::Smi(); return Representation::None(); } void HValue::UpdateRepresentation(Representation new_rep, HInferRepresentationPhase* h_infer, const char* reason) { Representation r = representation(); if (new_rep.is_more_general_than(r)) { if (CheckFlag(kCannotBeTagged) && new_rep.IsTagged()) return; if (FLAG_trace_representation) { PrintF("Changing #%d %s representation %s -> %s based on %s\n", id(), Mnemonic(), r.Mnemonic(), new_rep.Mnemonic(), reason); } ChangeRepresentation(new_rep); AddDependantsToWorklist(h_infer); } } void HValue::AddDependantsToWorklist(HInferRepresentationPhase* h_infer) { for (HUseIterator it(uses()); !it.Done(); it.Advance()) { h_infer->AddToWorklist(it.value()); } for (int i = 0; i < OperandCount(); ++i) { h_infer->AddToWorklist(OperandAt(i)); } } static int32_t ConvertAndSetOverflow(Representation r, int64_t result, bool* overflow) { if (r.IsSmi()) { if (result > Smi::kMaxValue) { *overflow = true; return Smi::kMaxValue; } if (result < Smi::kMinValue) { *overflow = true; return Smi::kMinValue; } } else { if (result > kMaxInt) { *overflow = true; return kMaxInt; } if (result < kMinInt) { *overflow = true; return kMinInt; } } return static_cast(result); } static int32_t AddWithoutOverflow(Representation r, int32_t a, int32_t b, bool* overflow) { int64_t result = static_cast(a) + static_cast(b); return ConvertAndSetOverflow(r, result, overflow); } static int32_t SubWithoutOverflow(Representation r, int32_t a, int32_t b, bool* overflow) { int64_t result = static_cast(a) - static_cast(b); return ConvertAndSetOverflow(r, result, overflow); } static int32_t MulWithoutOverflow(const Representation& r, int32_t a, int32_t b, bool* overflow) { int64_t result = static_cast(a) * static_cast(b); return ConvertAndSetOverflow(r, result, overflow); } int32_t Range::Mask() const { if (lower_ == upper_) return lower_; if (lower_ >= 0) { int32_t res = 1; while (res < upper_) { res = (res << 1) | 1; } return res; } return 0xffffffff; } void Range::AddConstant(int32_t value) { if (value == 0) return; bool may_overflow = false; // Overflow is ignored here. Representation r = Representation::Integer32(); lower_ = AddWithoutOverflow(r, lower_, value, &may_overflow); upper_ = AddWithoutOverflow(r, upper_, value, &may_overflow); #ifdef DEBUG Verify(); #endif } void Range::Intersect(Range* other) { upper_ = Min(upper_, other->upper_); lower_ = Max(lower_, other->lower_); bool b = CanBeMinusZero() && other->CanBeMinusZero(); set_can_be_minus_zero(b); } void Range::Union(Range* other) { upper_ = Max(upper_, other->upper_); lower_ = Min(lower_, other->lower_); bool b = CanBeMinusZero() || other->CanBeMinusZero(); set_can_be_minus_zero(b); } void Range::CombinedMax(Range* other) { upper_ = Max(upper_, other->upper_); lower_ = Max(lower_, other->lower_); set_can_be_minus_zero(CanBeMinusZero() || other->CanBeMinusZero()); } void Range::CombinedMin(Range* other) { upper_ = Min(upper_, other->upper_); lower_ = Min(lower_, other->lower_); set_can_be_minus_zero(CanBeMinusZero() || other->CanBeMinusZero()); } void Range::Sar(int32_t value) { int32_t bits = value & 0x1F; lower_ = lower_ >> bits; upper_ = upper_ >> bits; set_can_be_minus_zero(false); } void Range::Shl(int32_t value) { int32_t bits = value & 0x1F; int old_lower = lower_; int old_upper = upper_; lower_ = lower_ << bits; upper_ = upper_ << bits; if (old_lower != lower_ >> bits || old_upper != upper_ >> bits) { upper_ = kMaxInt; lower_ = kMinInt; } set_can_be_minus_zero(false); } bool Range::AddAndCheckOverflow(const Representation& r, Range* other) { bool may_overflow = false; lower_ = AddWithoutOverflow(r, lower_, other->lower(), &may_overflow); upper_ = AddWithoutOverflow(r, upper_, other->upper(), &may_overflow); KeepOrder(); #ifdef DEBUG Verify(); #endif return may_overflow; } bool Range::SubAndCheckOverflow(const Representation& r, Range* other) { bool may_overflow = false; lower_ = SubWithoutOverflow(r, lower_, other->upper(), &may_overflow); upper_ = SubWithoutOverflow(r, upper_, other->lower(), &may_overflow); KeepOrder(); #ifdef DEBUG Verify(); #endif return may_overflow; } void Range::KeepOrder() { if (lower_ > upper_) { int32_t tmp = lower_; lower_ = upper_; upper_ = tmp; } } #ifdef DEBUG void Range::Verify() const { ASSERT(lower_ <= upper_); } #endif bool Range::MulAndCheckOverflow(const Representation& r, Range* other) { bool may_overflow = false; int v1 = MulWithoutOverflow(r, lower_, other->lower(), &may_overflow); int v2 = MulWithoutOverflow(r, lower_, other->upper(), &may_overflow); int v3 = MulWithoutOverflow(r, upper_, other->lower(), &may_overflow); int v4 = MulWithoutOverflow(r, upper_, other->upper(), &may_overflow); lower_ = Min(Min(v1, v2), Min(v3, v4)); upper_ = Max(Max(v1, v2), Max(v3, v4)); #ifdef DEBUG Verify(); #endif return may_overflow; } const char* HType::ToString() { // Note: The c1visualizer syntax for locals allows only a sequence of the // following characters: A-Za-z0-9_-|: switch (type_) { case kNone: return "none"; case kTagged: return "tagged"; case kTaggedPrimitive: return "primitive"; case kTaggedNumber: return "number"; case kSmi: return "smi"; case kHeapNumber: return "heap-number"; case kString: return "string"; case kBoolean: return "boolean"; case kNonPrimitive: return "non-primitive"; case kJSArray: return "array"; case kJSObject: return "object"; } UNREACHABLE(); return "unreachable"; } HType HType::TypeFromValue(Handle value) { HType result = HType::Tagged(); if (value->IsSmi()) { result = HType::Smi(); } else if (value->IsHeapNumber()) { result = HType::HeapNumber(); } else if (value->IsString()) { result = HType::String(); } else if (value->IsBoolean()) { result = HType::Boolean(); } else if (value->IsJSObject()) { result = HType::JSObject(); } else if (value->IsJSArray()) { result = HType::JSArray(); } return result; } bool HValue::IsDefinedAfter(HBasicBlock* other) const { return block()->block_id() > other->block_id(); } HUseListNode* HUseListNode::tail() { // Skip and remove dead items in the use list. while (tail_ != NULL && tail_->value()->CheckFlag(HValue::kIsDead)) { tail_ = tail_->tail_; } return tail_; } bool HValue::CheckUsesForFlag(Flag f) const { for (HUseIterator it(uses()); !it.Done(); it.Advance()) { if (it.value()->IsSimulate()) continue; if (!it.value()->CheckFlag(f)) return false; } return true; } bool HValue::CheckUsesForFlag(Flag f, HValue** value) const { for (HUseIterator it(uses()); !it.Done(); it.Advance()) { if (it.value()->IsSimulate()) continue; if (!it.value()->CheckFlag(f)) { *value = it.value(); return false; } } return true; } bool HValue::HasAtLeastOneUseWithFlagAndNoneWithout(Flag f) const { bool return_value = false; for (HUseIterator it(uses()); !it.Done(); it.Advance()) { if (it.value()->IsSimulate()) continue; if (!it.value()->CheckFlag(f)) return false; return_value = true; } return return_value; } HUseIterator::HUseIterator(HUseListNode* head) : next_(head) { Advance(); } void HUseIterator::Advance() { current_ = next_; if (current_ != NULL) { next_ = current_->tail(); value_ = current_->value(); index_ = current_->index(); } } int HValue::UseCount() const { int count = 0; for (HUseIterator it(uses()); !it.Done(); it.Advance()) ++count; return count; } HUseListNode* HValue::RemoveUse(HValue* value, int index) { HUseListNode* previous = NULL; HUseListNode* current = use_list_; while (current != NULL) { if (current->value() == value && current->index() == index) { if (previous == NULL) { use_list_ = current->tail(); } else { previous->set_tail(current->tail()); } break; } previous = current; current = current->tail(); } #ifdef DEBUG // Do not reuse use list nodes in debug mode, zap them. if (current != NULL) { HUseListNode* temp = new(block()->zone()) HUseListNode(current->value(), current->index(), NULL); current->Zap(); current = temp; } #endif return current; } bool HValue::Equals(HValue* other) { if (other->opcode() != opcode()) return false; if (!other->representation().Equals(representation())) return false; if (!other->type_.Equals(type_)) return false; if (other->flags() != flags()) return false; if (OperandCount() != other->OperandCount()) return false; for (int i = 0; i < OperandCount(); ++i) { if (OperandAt(i)->id() != other->OperandAt(i)->id()) return false; } bool result = DataEquals(other); ASSERT(!result || Hashcode() == other->Hashcode()); return result; } intptr_t HValue::Hashcode() { intptr_t result = opcode(); int count = OperandCount(); for (int i = 0; i < count; ++i) { result = result * 19 + OperandAt(i)->id() + (result >> 7); } return result; } const char* HValue::Mnemonic() const { switch (opcode()) { #define MAKE_CASE(type) case k##type: return #type; HYDROGEN_CONCRETE_INSTRUCTION_LIST(MAKE_CASE) #undef MAKE_CASE case kPhi: return "Phi"; default: return ""; } } bool HValue::CanReplaceWithDummyUses() { return FLAG_unreachable_code_elimination && !(block()->IsReachable() || IsBlockEntry() || IsControlInstruction() || IsSimulate() || IsEnterInlined() || IsLeaveInlined()); } bool HValue::IsInteger32Constant() { return IsConstant() && HConstant::cast(this)->HasInteger32Value(); } int32_t HValue::GetInteger32Constant() { return HConstant::cast(this)->Integer32Value(); } bool HValue::EqualsInteger32Constant(int32_t value) { return IsInteger32Constant() && GetInteger32Constant() == value; } void HValue::SetOperandAt(int index, HValue* value) { RegisterUse(index, value); InternalSetOperandAt(index, value); } void HValue::DeleteAndReplaceWith(HValue* other) { // We replace all uses first, so Delete can assert that there are none. if (other != NULL) ReplaceAllUsesWith(other); Kill(); DeleteFromGraph(); } void HValue::ReplaceAllUsesWith(HValue* other) { while (use_list_ != NULL) { HUseListNode* list_node = use_list_; HValue* value = list_node->value(); ASSERT(!value->block()->IsStartBlock()); value->InternalSetOperandAt(list_node->index(), other); use_list_ = list_node->tail(); list_node->set_tail(other->use_list_); other->use_list_ = list_node; } } void HValue::Kill() { // Instead of going through the entire use list of each operand, we only // check the first item in each use list and rely on the tail() method to // skip dead items, removing them lazily next time we traverse the list. SetFlag(kIsDead); for (int i = 0; i < OperandCount(); ++i) { HValue* operand = OperandAt(i); if (operand == NULL) continue; HUseListNode* first = operand->use_list_; if (first != NULL && first->value()->CheckFlag(kIsDead)) { operand->use_list_ = first->tail(); } } } void HValue::SetBlock(HBasicBlock* block) { ASSERT(block_ == NULL || block == NULL); block_ = block; if (id_ == kNoNumber && block != NULL) { id_ = block->graph()->GetNextValueID(this); } } void HValue::PrintTypeTo(StringStream* stream) { if (!representation().IsTagged() || type().Equals(HType::Tagged())) return; stream->Add(" type:%s", type().ToString()); } void HValue::PrintRangeTo(StringStream* stream) { if (range() == NULL || range()->IsMostGeneric()) return; // Note: The c1visualizer syntax for locals allows only a sequence of the // following characters: A-Za-z0-9_-|: stream->Add(" range:%d_%d%s", range()->lower(), range()->upper(), range()->CanBeMinusZero() ? "_m0" : ""); } void HValue::PrintChangesTo(StringStream* stream) { GVNFlagSet changes_flags = ChangesFlags(); if (changes_flags.IsEmpty()) return; stream->Add(" changes["); if (changes_flags == AllSideEffectsFlagSet()) { stream->Add("*"); } else { bool add_comma = false; #define PRINT_DO(type) \ if (changes_flags.Contains(kChanges##type)) { \ if (add_comma) stream->Add(","); \ add_comma = true; \ stream->Add(#type); \ } GVN_TRACKED_FLAG_LIST(PRINT_DO); GVN_UNTRACKED_FLAG_LIST(PRINT_DO); #undef PRINT_DO } stream->Add("]"); } void HValue::PrintNameTo(StringStream* stream) { stream->Add("%s%d", representation_.Mnemonic(), id()); } bool HValue::HasMonomorphicJSObjectType() { return !GetMonomorphicJSObjectMap().is_null(); } bool HValue::UpdateInferredType() { HType type = CalculateInferredType(); bool result = (!type.Equals(type_)); type_ = type; return result; } void HValue::RegisterUse(int index, HValue* new_value) { HValue* old_value = OperandAt(index); if (old_value == new_value) return; HUseListNode* removed = NULL; if (old_value != NULL) { removed = old_value->RemoveUse(this, index); } if (new_value != NULL) { if (removed == NULL) { new_value->use_list_ = new(new_value->block()->zone()) HUseListNode( this, index, new_value->use_list_); } else { removed->set_tail(new_value->use_list_); new_value->use_list_ = removed; } } } void HValue::AddNewRange(Range* r, Zone* zone) { if (!HasRange()) ComputeInitialRange(zone); if (!HasRange()) range_ = new(zone) Range(); ASSERT(HasRange()); r->StackUpon(range_); range_ = r; } void HValue::RemoveLastAddedRange() { ASSERT(HasRange()); ASSERT(range_->next() != NULL); range_ = range_->next(); } void HValue::ComputeInitialRange(Zone* zone) { ASSERT(!HasRange()); range_ = InferRange(zone); ASSERT(HasRange()); } void HInstruction::PrintTo(StringStream* stream) { PrintMnemonicTo(stream); PrintDataTo(stream); PrintRangeTo(stream); PrintChangesTo(stream); PrintTypeTo(stream); if (CheckFlag(HValue::kHasNoObservableSideEffects)) { stream->Add(" [noOSE]"); } } void HInstruction::PrintDataTo(StringStream *stream) { for (int i = 0; i < OperandCount(); ++i) { if (i > 0) stream->Add(" "); OperandAt(i)->PrintNameTo(stream); } } void HInstruction::PrintMnemonicTo(StringStream* stream) { stream->Add("%s ", Mnemonic()); } void HInstruction::Unlink() { ASSERT(IsLinked()); ASSERT(!IsControlInstruction()); // Must never move control instructions. ASSERT(!IsBlockEntry()); // Doesn't make sense to delete these. ASSERT(previous_ != NULL); previous_->next_ = next_; if (next_ == NULL) { ASSERT(block()->last() == this); block()->set_last(previous_); } else { next_->previous_ = previous_; } clear_block(); } void HInstruction::InsertBefore(HInstruction* next) { ASSERT(!IsLinked()); ASSERT(!next->IsBlockEntry()); ASSERT(!IsControlInstruction()); ASSERT(!next->block()->IsStartBlock()); ASSERT(next->previous_ != NULL); HInstruction* prev = next->previous(); prev->next_ = this; next->previous_ = this; next_ = next; previous_ = prev; SetBlock(next->block()); if (position() == RelocInfo::kNoPosition && next->position() != RelocInfo::kNoPosition) { set_position(next->position()); } } void HInstruction::InsertAfter(HInstruction* previous) { ASSERT(!IsLinked()); ASSERT(!previous->IsControlInstruction()); ASSERT(!IsControlInstruction() || previous->next_ == NULL); HBasicBlock* block = previous->block(); // Never insert anything except constants into the start block after finishing // it. if (block->IsStartBlock() && block->IsFinished() && !IsConstant()) { ASSERT(block->end()->SecondSuccessor() == NULL); InsertAfter(block->end()->FirstSuccessor()->first()); return; } // If we're inserting after an instruction with side-effects that is // followed by a simulate instruction, we need to insert after the // simulate instruction instead. HInstruction* next = previous->next_; if (previous->HasObservableSideEffects() && next != NULL) { ASSERT(next->IsSimulate()); previous = next; next = previous->next_; } previous_ = previous; next_ = next; SetBlock(block); previous->next_ = this; if (next != NULL) next->previous_ = this; if (block->last() == previous) { block->set_last(this); } if (position() == RelocInfo::kNoPosition && previous->position() != RelocInfo::kNoPosition) { set_position(previous->position()); } } #ifdef DEBUG void HInstruction::Verify() { // Verify that input operands are defined before use. HBasicBlock* cur_block = block(); for (int i = 0; i < OperandCount(); ++i) { HValue* other_operand = OperandAt(i); if (other_operand == NULL) continue; HBasicBlock* other_block = other_operand->block(); if (cur_block == other_block) { if (!other_operand->IsPhi()) { HInstruction* cur = this->previous(); while (cur != NULL) { if (cur == other_operand) break; cur = cur->previous(); } // Must reach other operand in the same block! ASSERT(cur == other_operand); } } else { // If the following assert fires, you may have forgotten an // AddInstruction. ASSERT(other_block->Dominates(cur_block)); } } // Verify that instructions that may have side-effects are followed // by a simulate instruction. if (HasObservableSideEffects() && !IsOsrEntry()) { ASSERT(next()->IsSimulate()); } // Verify that instructions that can be eliminated by GVN have overridden // HValue::DataEquals. The default implementation is UNREACHABLE. We // don't actually care whether DataEquals returns true or false here. if (CheckFlag(kUseGVN)) DataEquals(this); // Verify that all uses are in the graph. for (HUseIterator use = uses(); !use.Done(); use.Advance()) { if (use.value()->IsInstruction()) { ASSERT(HInstruction::cast(use.value())->IsLinked()); } } } #endif void HDummyUse::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); } void HEnvironmentMarker::PrintDataTo(StringStream* stream) { stream->Add("%s var[%d]", kind() == BIND ? "bind" : "lookup", index()); } void HUnaryCall::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" "); stream->Add("#%d", argument_count()); } void HBinaryCall::PrintDataTo(StringStream* stream) { first()->PrintNameTo(stream); stream->Add(" "); second()->PrintNameTo(stream); stream->Add(" "); stream->Add("#%d", argument_count()); } void HBoundsCheck::ApplyIndexChange() { if (skip_check()) return; DecompositionResult decomposition; bool index_is_decomposable = index()->TryDecompose(&decomposition); if (index_is_decomposable) { ASSERT(decomposition.base() == base()); if (decomposition.offset() == offset() && decomposition.scale() == scale()) return; } else { return; } ReplaceAllUsesWith(index()); HValue* current_index = decomposition.base(); int actual_offset = decomposition.offset() + offset(); int actual_scale = decomposition.scale() + scale(); Zone* zone = block()->graph()->zone(); HValue* context = block()->graph()->GetInvalidContext(); if (actual_offset != 0) { HConstant* add_offset = HConstant::New(zone, context, actual_offset); add_offset->InsertBefore(this); HInstruction* add = HAdd::New(zone, context, current_index, add_offset); add->InsertBefore(this); add->AssumeRepresentation(index()->representation()); add->ClearFlag(kCanOverflow); current_index = add; } if (actual_scale != 0) { HConstant* sar_scale = HConstant::New(zone, context, actual_scale); sar_scale->InsertBefore(this); HInstruction* sar = HSar::New(zone, context, current_index, sar_scale); sar->InsertBefore(this); sar->AssumeRepresentation(index()->representation()); current_index = sar; } SetOperandAt(0, current_index); base_ = NULL; offset_ = 0; scale_ = 0; } void HBoundsCheck::PrintDataTo(StringStream* stream) { index()->PrintNameTo(stream); stream->Add(" "); length()->PrintNameTo(stream); if (base() != NULL && (offset() != 0 || scale() != 0)) { stream->Add(" base: (("); if (base() != index()) { index()->PrintNameTo(stream); } else { stream->Add("index"); } stream->Add(" + %d) >> %d)", offset(), scale()); } if (skip_check()) { stream->Add(" [DISABLED]"); } } void HBoundsCheck::InferRepresentation(HInferRepresentationPhase* h_infer) { ASSERT(CheckFlag(kFlexibleRepresentation)); HValue* actual_index = index()->ActualValue(); HValue* actual_length = length()->ActualValue(); Representation index_rep = actual_index->representation(); Representation length_rep = actual_length->representation(); if (index_rep.IsTagged() && actual_index->type().IsSmi()) { index_rep = Representation::Smi(); } if (length_rep.IsTagged() && actual_length->type().IsSmi()) { length_rep = Representation::Smi(); } Representation r = index_rep.generalize(length_rep); if (r.is_more_general_than(Representation::Integer32())) { r = Representation::Integer32(); } UpdateRepresentation(r, h_infer, "boundscheck"); } Range* HBoundsCheck::InferRange(Zone* zone) { Representation r = representation(); if (r.IsSmiOrInteger32() && length()->HasRange()) { int upper = length()->range()->upper() - (allow_equality() ? 0 : 1); int lower = 0; Range* result = new(zone) Range(lower, upper); if (index()->HasRange()) { result->Intersect(index()->range()); } // In case of Smi representation, clamp result to Smi::kMaxValue. if (r.IsSmi()) result->ClampToSmi(); return result; } return HValue::InferRange(zone); } void HBoundsCheckBaseIndexInformation::PrintDataTo(StringStream* stream) { stream->Add("base: "); base_index()->PrintNameTo(stream); stream->Add(", check: "); base_index()->PrintNameTo(stream); } void HCallConstantFunction::PrintDataTo(StringStream* stream) { if (IsApplyFunction()) { stream->Add("optimized apply "); } else { stream->Add("%o ", function()->shared()->DebugName()); } stream->Add("#%d", argument_count()); } void HCallNamed::PrintDataTo(StringStream* stream) { stream->Add("%o ", *name()); HUnaryCall::PrintDataTo(stream); } void HCallGlobal::PrintDataTo(StringStream* stream) { stream->Add("%o ", *name()); HUnaryCall::PrintDataTo(stream); } void HCallKnownGlobal::PrintDataTo(StringStream* stream) { stream->Add("%o ", target()->shared()->DebugName()); stream->Add("#%d", argument_count()); } void HCallNewArray::PrintDataTo(StringStream* stream) { stream->Add(ElementsKindToString(elements_kind())); stream->Add(" "); HBinaryCall::PrintDataTo(stream); } void HCallRuntime::PrintDataTo(StringStream* stream) { stream->Add("%o ", *name()); if (save_doubles() == kSaveFPRegs) { stream->Add("[save doubles] "); } stream->Add("#%d", argument_count()); } void HClassOfTestAndBranch::PrintDataTo(StringStream* stream) { stream->Add("class_of_test("); value()->PrintNameTo(stream); stream->Add(", \"%o\")", *class_name()); } void HWrapReceiver::PrintDataTo(StringStream* stream) { receiver()->PrintNameTo(stream); stream->Add(" "); function()->PrintNameTo(stream); } void HAccessArgumentsAt::PrintDataTo(StringStream* stream) { arguments()->PrintNameTo(stream); stream->Add("["); index()->PrintNameTo(stream); stream->Add("], length "); length()->PrintNameTo(stream); } void HControlInstruction::PrintDataTo(StringStream* stream) { stream->Add(" goto ("); bool first_block = true; for (HSuccessorIterator it(this); !it.Done(); it.Advance()) { stream->Add(first_block ? "B%d" : ", B%d", it.Current()->block_id()); first_block = false; } stream->Add(")"); } void HUnaryControlInstruction::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); HControlInstruction::PrintDataTo(stream); } void HReturn::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" (pop "); parameter_count()->PrintNameTo(stream); stream->Add(" values)"); } Representation HBranch::observed_input_representation(int index) { static const ToBooleanStub::Types tagged_types( ToBooleanStub::NULL_TYPE | ToBooleanStub::SPEC_OBJECT | ToBooleanStub::STRING | ToBooleanStub::SYMBOL); if (expected_input_types_.ContainsAnyOf(tagged_types)) { return Representation::Tagged(); } if (expected_input_types_.Contains(ToBooleanStub::UNDEFINED)) { if (expected_input_types_.Contains(ToBooleanStub::HEAP_NUMBER)) { return Representation::Double(); } return Representation::Tagged(); } if (expected_input_types_.Contains(ToBooleanStub::HEAP_NUMBER)) { return Representation::Double(); } if (expected_input_types_.Contains(ToBooleanStub::SMI)) { return Representation::Smi(); } return Representation::None(); } bool HBranch::KnownSuccessorBlock(HBasicBlock** block) { HValue* value = this->value(); if (value->EmitAtUses()) { ASSERT(value->IsConstant()); ASSERT(!value->representation().IsDouble()); *block = HConstant::cast(value)->BooleanValue() ? FirstSuccessor() : SecondSuccessor(); return true; } *block = NULL; return false; } void HCompareMap::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" (%p)", *map().handle()); HControlInstruction::PrintDataTo(stream); } const char* HUnaryMathOperation::OpName() const { switch (op()) { case kMathFloor: return "floor"; case kMathRound: return "round"; case kMathAbs: return "abs"; case kMathLog: return "log"; case kMathSin: return "sin"; case kMathCos: return "cos"; case kMathTan: return "tan"; case kMathExp: return "exp"; case kMathSqrt: return "sqrt"; case kMathPowHalf: return "pow-half"; default: UNREACHABLE(); return NULL; } } Range* HUnaryMathOperation::InferRange(Zone* zone) { Representation r = representation(); if (r.IsSmiOrInteger32() && value()->HasRange()) { if (op() == kMathAbs) { int upper = value()->range()->upper(); int lower = value()->range()->lower(); bool spans_zero = value()->range()->CanBeZero(); // Math.abs(kMinInt) overflows its representation, on which the // instruction deopts. Hence clamp it to kMaxInt. int abs_upper = upper == kMinInt ? kMaxInt : abs(upper); int abs_lower = lower == kMinInt ? kMaxInt : abs(lower); Range* result = new(zone) Range(spans_zero ? 0 : Min(abs_lower, abs_upper), Max(abs_lower, abs_upper)); // In case of Smi representation, clamp Math.abs(Smi::kMinValue) to // Smi::kMaxValue. if (r.IsSmi()) result->ClampToSmi(); return result; } } return HValue::InferRange(zone); } void HUnaryMathOperation::PrintDataTo(StringStream* stream) { const char* name = OpName(); stream->Add("%s ", name); value()->PrintNameTo(stream); } void HUnaryOperation::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); } void HHasInstanceTypeAndBranch::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); switch (from_) { case FIRST_JS_RECEIVER_TYPE: if (to_ == LAST_TYPE) stream->Add(" spec_object"); break; case JS_REGEXP_TYPE: if (to_ == JS_REGEXP_TYPE) stream->Add(" reg_exp"); break; case JS_ARRAY_TYPE: if (to_ == JS_ARRAY_TYPE) stream->Add(" array"); break; case JS_FUNCTION_TYPE: if (to_ == JS_FUNCTION_TYPE) stream->Add(" function"); break; default: break; } } void HTypeofIsAndBranch::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" == %o", *type_literal_); HControlInstruction::PrintDataTo(stream); } bool HTypeofIsAndBranch::KnownSuccessorBlock(HBasicBlock** block) { if (value()->representation().IsSpecialization()) { if (compares_number_type()) { *block = FirstSuccessor(); } else { *block = SecondSuccessor(); } return true; } *block = NULL; return false; } void HCheckMapValue::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" "); map()->PrintNameTo(stream); } void HForInPrepareMap::PrintDataTo(StringStream* stream) { enumerable()->PrintNameTo(stream); } void HForInCacheArray::PrintDataTo(StringStream* stream) { enumerable()->PrintNameTo(stream); stream->Add(" "); map()->PrintNameTo(stream); stream->Add("[%d]", idx_); } void HLoadFieldByIndex::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); stream->Add(" "); index()->PrintNameTo(stream); } static bool MatchLeftIsOnes(HValue* l, HValue* r, HValue** negated) { if (!l->EqualsInteger32Constant(~0)) return false; *negated = r; return true; } static bool MatchNegationViaXor(HValue* instr, HValue** negated) { if (!instr->IsBitwise()) return false; HBitwise* b = HBitwise::cast(instr); return (b->op() == Token::BIT_XOR) && (MatchLeftIsOnes(b->left(), b->right(), negated) || MatchLeftIsOnes(b->right(), b->left(), negated)); } static bool MatchDoubleNegation(HValue* instr, HValue** arg) { HValue* negated; return MatchNegationViaXor(instr, &negated) && MatchNegationViaXor(negated, arg); } HValue* HBitwise::Canonicalize() { if (!representation().IsSmiOrInteger32()) return this; // If x is an int32, then x & -1 == x, x | 0 == x and x ^ 0 == x. int32_t nop_constant = (op() == Token::BIT_AND) ? -1 : 0; if (left()->EqualsInteger32Constant(nop_constant) && !right()->CheckFlag(kUint32)) { return right(); } if (right()->EqualsInteger32Constant(nop_constant) && !left()->CheckFlag(kUint32)) { return left(); } // Optimize double negation, a common pattern used for ToInt32(x). HValue* arg; if (MatchDoubleNegation(this, &arg) && !arg->CheckFlag(kUint32)) { return arg; } return this; } Representation HAdd::RepresentationFromInputs() { Representation left_rep = left()->representation(); if (left_rep.IsExternal()) { return Representation::External(); } return HArithmeticBinaryOperation::RepresentationFromInputs(); } Representation HAdd::RequiredInputRepresentation(int index) { if (index == 2) { Representation left_rep = left()->representation(); if (left_rep.IsExternal()) { return Representation::Integer32(); } } return HArithmeticBinaryOperation::RequiredInputRepresentation(index); } static bool IsIdentityOperation(HValue* arg1, HValue* arg2, int32_t identity) { return arg1->representation().IsSpecialization() && arg2->EqualsInteger32Constant(identity); } HValue* HAdd::Canonicalize() { // Adding 0 is an identity operation except in case of -0: -0 + 0 = +0 if (IsIdentityOperation(left(), right(), 0) && !left()->representation().IsDouble()) { // Left could be -0. return left(); } if (IsIdentityOperation(right(), left(), 0) && !left()->representation().IsDouble()) { // Right could be -0. return right(); } return this; } HValue* HSub::Canonicalize() { if (IsIdentityOperation(left(), right(), 0)) return left(); return this; } HValue* HMul::Canonicalize() { if (IsIdentityOperation(left(), right(), 1)) return left(); if (IsIdentityOperation(right(), left(), 1)) return right(); return this; } bool HMul::MulMinusOne() { if (left()->EqualsInteger32Constant(-1) || right()->EqualsInteger32Constant(-1)) { return true; } return false; } HValue* HMod::Canonicalize() { return this; } HValue* HDiv::Canonicalize() { if (IsIdentityOperation(left(), right(), 1)) return left(); return this; } HValue* HChange::Canonicalize() { return (from().Equals(to())) ? value() : this; } HValue* HWrapReceiver::Canonicalize() { if (HasNoUses()) return NULL; if (receiver()->type().IsJSObject()) { return receiver(); } return this; } void HTypeof::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); } HInstruction* HForceRepresentation::New(Zone* zone, HValue* context, HValue* value, Representation required_representation) { if (FLAG_fold_constants && value->IsConstant()) { HConstant* c = HConstant::cast(value); if (c->HasNumberValue()) { double double_res = c->DoubleValue(); if (TypeInfo::IsInt32Double(double_res)) { return HConstant::New(zone, context, static_cast(double_res), required_representation); } } } return new(zone) HForceRepresentation(value, required_representation); } void HForceRepresentation::PrintDataTo(StringStream* stream) { stream->Add("%s ", representation().Mnemonic()); value()->PrintNameTo(stream); } void HChange::PrintDataTo(StringStream* stream) { HUnaryOperation::PrintDataTo(stream); stream->Add(" %s to %s", from().Mnemonic(), to().Mnemonic()); if (CanTruncateToInt32()) stream->Add(" truncating-int32"); if (CheckFlag(kBailoutOnMinusZero)) stream->Add(" -0?"); if (CheckFlag(kAllowUndefinedAsNaN)) stream->Add(" allow-undefined-as-nan"); } static HValue* SimplifiedDividendForMathFloorOfDiv(HValue* dividend) { // A value with an integer representation does not need to be transformed. if (dividend->representation().IsInteger32()) { return dividend; } // A change from an integer32 can be replaced by the integer32 value. if (dividend->IsChange() && HChange::cast(dividend)->from().IsInteger32()) { return HChange::cast(dividend)->value(); } return NULL; } HValue* HUnaryMathOperation::Canonicalize() { if (op() == kMathRound || op() == kMathFloor) { HValue* val = value(); if (val->IsChange()) val = HChange::cast(val)->value(); // If the input is smi or integer32 then we replace the instruction with its // input. if (val->representation().IsSmiOrInteger32()) { if (!val->representation().Equals(representation())) { HChange* result = new(block()->zone()) HChange( val, representation(), false, false); result->InsertBefore(this); return result; } return val; } } if (op() == kMathFloor) { HValue* val = value(); if (val->IsDiv() && (val->UseCount() == 1)) { HDiv* hdiv = HDiv::cast(val); HValue* left = hdiv->left(); HValue* right = hdiv->right(); // Try to simplify left and right values of the division. HValue* new_left = SimplifiedDividendForMathFloorOfDiv(left); if (new_left == NULL && hdiv->observed_input_representation(1).IsSmiOrInteger32()) { new_left = new(block()->zone()) HChange( left, Representation::Integer32(), false, false); HChange::cast(new_left)->InsertBefore(this); } HValue* new_right = LChunkBuilder::SimplifiedDivisorForMathFloorOfDiv(right); if (new_right == NULL && #if V8_TARGET_ARCH_ARM CpuFeatures::IsSupported(SUDIV) && #endif hdiv->observed_input_representation(2).IsSmiOrInteger32()) { new_right = new(block()->zone()) HChange( right, Representation::Integer32(), false, false); HChange::cast(new_right)->InsertBefore(this); } // Return if left or right are not optimizable. if ((new_left == NULL) || (new_right == NULL)) return this; // Insert the new values in the graph. if (new_left->IsInstruction() && !HInstruction::cast(new_left)->IsLinked()) { HInstruction::cast(new_left)->InsertBefore(this); } if (new_right->IsInstruction() && !HInstruction::cast(new_right)->IsLinked()) { HInstruction::cast(new_right)->InsertBefore(this); } HMathFloorOfDiv* instr = HMathFloorOfDiv::New(block()->zone(), context(), new_left, new_right); instr->InsertBefore(this); return instr; } } return this; } HValue* HCheckInstanceType::Canonicalize() { if (check_ == IS_STRING && value()->type().IsString()) { return value(); } if (check_ == IS_INTERNALIZED_STRING && value()->IsConstant()) { if (HConstant::cast(value())->HasInternalizedStringValue()) { return value(); } } return this; } void HCheckInstanceType::GetCheckInterval(InstanceType* first, InstanceType* last) { ASSERT(is_interval_check()); switch (check_) { case IS_SPEC_OBJECT: *first = FIRST_SPEC_OBJECT_TYPE; *last = LAST_SPEC_OBJECT_TYPE; return; case IS_JS_ARRAY: *first = *last = JS_ARRAY_TYPE; return; default: UNREACHABLE(); } } void HCheckInstanceType::GetCheckMaskAndTag(uint8_t* mask, uint8_t* tag) { ASSERT(!is_interval_check()); switch (check_) { case IS_STRING: *mask = kIsNotStringMask; *tag = kStringTag; return; case IS_INTERNALIZED_STRING: *mask = kIsNotInternalizedMask; *tag = kInternalizedTag; return; default: UNREACHABLE(); } } void HCheckMaps::HandleSideEffectDominator(GVNFlag side_effect, HValue* dominator) { ASSERT(side_effect == kChangesMaps); // TODO(mstarzinger): For now we specialize on HStoreNamedField, but once // type information is rich enough we should generalize this to any HType // for which the map is known. if (HasNoUses() && dominator->IsStoreNamedField()) { HStoreNamedField* store = HStoreNamedField::cast(dominator); if (!store->has_transition() || store->object() != value()) return; HConstant* transition = HConstant::cast(store->transition()); if (map_set_.Contains(transition->GetUnique())) { DeleteAndReplaceWith(NULL); return; } } } void HCheckMaps::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" [%p", *map_set_.at(0).handle()); for (int i = 1; i < map_set_.size(); ++i) { stream->Add(",%p", *map_set_.at(i).handle()); } stream->Add("]%s", CanOmitMapChecks() ? "(omitted)" : ""); } void HCheckValue::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add(" "); object().handle()->ShortPrint(stream); } HValue* HCheckValue::Canonicalize() { return (value()->IsConstant() && HConstant::cast(value())->GetUnique() == object_) ? NULL : this; } const char* HCheckInstanceType::GetCheckName() { switch (check_) { case IS_SPEC_OBJECT: return "object"; case IS_JS_ARRAY: return "array"; case IS_STRING: return "string"; case IS_INTERNALIZED_STRING: return "internalized_string"; } UNREACHABLE(); return ""; } void HCheckInstanceType::PrintDataTo(StringStream* stream) { stream->Add("%s ", GetCheckName()); HUnaryOperation::PrintDataTo(stream); } void HCallStub::PrintDataTo(StringStream* stream) { stream->Add("%s ", CodeStub::MajorName(major_key_, false)); HUnaryCall::PrintDataTo(stream); } void HUnknownOSRValue::PrintDataTo(StringStream *stream) { const char* type = "expression"; if (environment_->is_local_index(index_)) type = "local"; if (environment_->is_special_index(index_)) type = "special"; if (environment_->is_parameter_index(index_)) type = "parameter"; stream->Add("%s @ %d", type, index_); } void HInstanceOf::PrintDataTo(StringStream* stream) { left()->PrintNameTo(stream); stream->Add(" "); right()->PrintNameTo(stream); stream->Add(" "); context()->PrintNameTo(stream); } Range* HValue::InferRange(Zone* zone) { Range* result; if (representation().IsSmi() || type().IsSmi()) { result = new(zone) Range(Smi::kMinValue, Smi::kMaxValue); result->set_can_be_minus_zero(false); } else { result = new(zone) Range(); result->set_can_be_minus_zero(!CheckFlag(kAllUsesTruncatingToInt32)); // TODO(jkummerow): The range cannot be minus zero when the upper type // bound is Integer32. } return result; } Range* HChange::InferRange(Zone* zone) { Range* input_range = value()->range(); if (from().IsInteger32() && !value()->CheckFlag(HInstruction::kUint32) && (to().IsSmi() || (to().IsTagged() && input_range != NULL && input_range->IsInSmiRange()))) { set_type(HType::Smi()); ClearGVNFlag(kChangesNewSpacePromotion); } Range* result = (input_range != NULL) ? input_range->Copy(zone) : HValue::InferRange(zone); result->set_can_be_minus_zero(!to().IsSmiOrInteger32() || !(CheckFlag(kAllUsesTruncatingToInt32) || CheckFlag(kAllUsesTruncatingToSmi))); if (to().IsSmi()) result->ClampToSmi(); return result; } Range* HConstant::InferRange(Zone* zone) { if (has_int32_value_) { Range* result = new(zone) Range(int32_value_, int32_value_); result->set_can_be_minus_zero(false); return result; } return HValue::InferRange(zone); } int HPhi::position() const { return block()->first()->position(); } Range* HPhi::InferRange(Zone* zone) { Representation r = representation(); if (r.IsSmiOrInteger32()) { if (block()->IsLoopHeader()) { Range* range = r.IsSmi() ? new(zone) Range(Smi::kMinValue, Smi::kMaxValue) : new(zone) Range(kMinInt, kMaxInt); return range; } else { Range* range = OperandAt(0)->range()->Copy(zone); for (int i = 1; i < OperandCount(); ++i) { range->Union(OperandAt(i)->range()); } return range; } } else { return HValue::InferRange(zone); } } Range* HAdd::InferRange(Zone* zone) { Representation r = representation(); if (r.IsSmiOrInteger32()) { Range* a = left()->range(); Range* b = right()->range(); Range* res = a->Copy(zone); if (!res->AddAndCheckOverflow(r, b) || (r.IsInteger32() && CheckFlag(kAllUsesTruncatingToInt32)) || (r.IsSmi() && CheckFlag(kAllUsesTruncatingToSmi))) { ClearFlag(kCanOverflow); } res->set_can_be_minus_zero(!CheckFlag(kAllUsesTruncatingToSmi) && !CheckFlag(kAllUsesTruncatingToInt32) && a->CanBeMinusZero() && b->CanBeMinusZero()); return res; } else { return HValue::InferRange(zone); } } Range* HSub::InferRange(Zone* zone) { Representation r = representation(); if (r.IsSmiOrInteger32()) { Range* a = left()->range(); Range* b = right()->range(); Range* res = a->Copy(zone); if (!res->SubAndCheckOverflow(r, b) || (r.IsInteger32() && CheckFlag(kAllUsesTruncatingToInt32)) || (r.IsSmi() && CheckFlag(kAllUsesTruncatingToSmi))) { ClearFlag(kCanOverflow); } res->set_can_be_minus_zero(!CheckFlag(kAllUsesTruncatingToSmi) && !CheckFlag(kAllUsesTruncatingToInt32) && a->CanBeMinusZero() && b->CanBeZero()); return res; } else { return HValue::InferRange(zone); } } Range* HMul::InferRange(Zone* zone) { Representation r = representation(); if (r.IsSmiOrInteger32()) { Range* a = left()->range(); Range* b = right()->range(); Range* res = a->Copy(zone); if (!res->MulAndCheckOverflow(r, b) || (((r.IsInteger32() && CheckFlag(kAllUsesTruncatingToInt32)) || (r.IsSmi() && CheckFlag(kAllUsesTruncatingToSmi))) && MulMinusOne())) { // Truncated int multiplication is too precise and therefore not the // same as converting to Double and back. // Handle truncated integer multiplication by -1 special. ClearFlag(kCanOverflow); } res->set_can_be_minus_zero(!CheckFlag(kAllUsesTruncatingToSmi) && !CheckFlag(kAllUsesTruncatingToInt32) && ((a->CanBeZero() && b->CanBeNegative()) || (a->CanBeNegative() && b->CanBeZero()))); return res; } else { return HValue::InferRange(zone); } } Range* HDiv::InferRange(Zone* zone) { if (representation().IsInteger32()) { Range* a = left()->range(); Range* b = right()->range(); Range* result = new(zone) Range(); result->set_can_be_minus_zero(!CheckFlag(kAllUsesTruncatingToInt32) && (a->CanBeMinusZero() || (a->CanBeZero() && b->CanBeNegative()))); if (!a->Includes(kMinInt) || !b->Includes(-1) || CheckFlag(kAllUsesTruncatingToInt32)) { // It is safe to clear kCanOverflow when kAllUsesTruncatingToInt32. ClearFlag(HValue::kCanOverflow); } if (!b->CanBeZero()) { ClearFlag(HValue::kCanBeDivByZero); } return result; } else { return HValue::InferRange(zone); } } Range* HMod::InferRange(Zone* zone) { if (representation().IsInteger32()) { Range* a = left()->range(); Range* b = right()->range(); // The magnitude of the modulus is bounded by the right operand. Note that // apart for the cases involving kMinInt, the calculation below is the same // as Max(Abs(b->lower()), Abs(b->upper())) - 1. int32_t positive_bound = -(Min(NegAbs(b->lower()), NegAbs(b->upper())) + 1); // The result of the modulo operation has the sign of its left operand. bool left_can_be_negative = a->CanBeMinusZero() || a->CanBeNegative(); Range* result = new(zone) Range(left_can_be_negative ? -positive_bound : 0, a->CanBePositive() ? positive_bound : 0); result->set_can_be_minus_zero(!CheckFlag(kAllUsesTruncatingToInt32) && left_can_be_negative); if (!a->Includes(kMinInt) || !b->Includes(-1)) { ClearFlag(HValue::kCanOverflow); } if (!b->CanBeZero()) { ClearFlag(HValue::kCanBeDivByZero); } return result; } else { return HValue::InferRange(zone); } } InductionVariableData* InductionVariableData::ExaminePhi(HPhi* phi) { if (phi->block()->loop_information() == NULL) return NULL; if (phi->OperandCount() != 2) return NULL; int32_t candidate_increment; candidate_increment = ComputeIncrement(phi, phi->OperandAt(0)); if (candidate_increment != 0) { return new(phi->block()->graph()->zone()) InductionVariableData(phi, phi->OperandAt(1), candidate_increment); } candidate_increment = ComputeIncrement(phi, phi->OperandAt(1)); if (candidate_increment != 0) { return new(phi->block()->graph()->zone()) InductionVariableData(phi, phi->OperandAt(0), candidate_increment); } return NULL; } /* * This function tries to match the following patterns (and all the relevant * variants related to |, & and + being commutative): * base | constant_or_mask * base & constant_and_mask * (base + constant_offset) & constant_and_mask * (base - constant_offset) & constant_and_mask */ void InductionVariableData::DecomposeBitwise( HValue* value, BitwiseDecompositionResult* result) { HValue* base = IgnoreOsrValue(value); result->base = value; if (!base->representation().IsInteger32()) return; if (base->IsBitwise()) { bool allow_offset = false; int32_t mask = 0; HBitwise* bitwise = HBitwise::cast(base); if (bitwise->right()->IsInteger32Constant()) { mask = bitwise->right()->GetInteger32Constant(); base = bitwise->left(); } else if (bitwise->left()->IsInteger32Constant()) { mask = bitwise->left()->GetInteger32Constant(); base = bitwise->right(); } else { return; } if (bitwise->op() == Token::BIT_AND) { result->and_mask = mask; allow_offset = true; } else if (bitwise->op() == Token::BIT_OR) { result->or_mask = mask; } else { return; } result->context = bitwise->context(); if (allow_offset) { if (base->IsAdd()) { HAdd* add = HAdd::cast(base); if (add->right()->IsInteger32Constant()) { base = add->left(); } else if (add->left()->IsInteger32Constant()) { base = add->right(); } } else if (base->IsSub()) { HSub* sub = HSub::cast(base); if (sub->right()->IsInteger32Constant()) { base = sub->left(); } } } result->base = base; } } void InductionVariableData::AddCheck(HBoundsCheck* check, int32_t upper_limit) { ASSERT(limit_validity() != NULL); if (limit_validity() != check->block() && !limit_validity()->Dominates(check->block())) return; if (!phi()->block()->current_loop()->IsNestedInThisLoop( check->block()->current_loop())) return; ChecksRelatedToLength* length_checks = checks(); while (length_checks != NULL) { if (length_checks->length() == check->length()) break; length_checks = length_checks->next(); } if (length_checks == NULL) { length_checks = new(check->block()->zone()) ChecksRelatedToLength(check->length(), checks()); checks_ = length_checks; } length_checks->AddCheck(check, upper_limit); } void InductionVariableData::ChecksRelatedToLength::CloseCurrentBlock() { if (checks() != NULL) { InductionVariableCheck* c = checks(); HBasicBlock* current_block = c->check()->block(); while (c != NULL && c->check()->block() == current_block) { c->set_upper_limit(current_upper_limit_); c = c->next(); } } } void InductionVariableData::ChecksRelatedToLength::UseNewIndexInCurrentBlock( Token::Value token, int32_t mask, HValue* index_base, HValue* context) { ASSERT(first_check_in_block() != NULL); HValue* previous_index = first_check_in_block()->index(); ASSERT(context != NULL); Zone* zone = index_base->block()->graph()->zone(); set_added_constant(HConstant::New(zone, context, mask)); if (added_index() != NULL) { added_constant()->InsertBefore(added_index()); } else { added_constant()->InsertBefore(first_check_in_block()); } if (added_index() == NULL) { first_check_in_block()->ReplaceAllUsesWith(first_check_in_block()->index()); HInstruction* new_index = HBitwise::New(zone, context, token, index_base, added_constant()); ASSERT(new_index->IsBitwise()); new_index->ClearAllSideEffects(); new_index->AssumeRepresentation(Representation::Integer32()); set_added_index(HBitwise::cast(new_index)); added_index()->InsertBefore(first_check_in_block()); } ASSERT(added_index()->op() == token); added_index()->SetOperandAt(1, index_base); added_index()->SetOperandAt(2, added_constant()); first_check_in_block()->SetOperandAt(0, added_index()); if (previous_index->UseCount() == 0) { previous_index->DeleteAndReplaceWith(NULL); } } void InductionVariableData::ChecksRelatedToLength::AddCheck( HBoundsCheck* check, int32_t upper_limit) { BitwiseDecompositionResult decomposition; InductionVariableData::DecomposeBitwise(check->index(), &decomposition); if (first_check_in_block() == NULL || first_check_in_block()->block() != check->block()) { CloseCurrentBlock(); first_check_in_block_ = check; set_added_index(NULL); set_added_constant(NULL); current_and_mask_in_block_ = decomposition.and_mask; current_or_mask_in_block_ = decomposition.or_mask; current_upper_limit_ = upper_limit; InductionVariableCheck* new_check = new(check->block()->graph()->zone()) InductionVariableCheck(check, checks_, upper_limit); checks_ = new_check; return; } if (upper_limit > current_upper_limit()) { current_upper_limit_ = upper_limit; } if (decomposition.and_mask != 0 && current_or_mask_in_block() == 0) { if (current_and_mask_in_block() == 0 || decomposition.and_mask > current_and_mask_in_block()) { UseNewIndexInCurrentBlock(Token::BIT_AND, decomposition.and_mask, decomposition.base, decomposition.context); current_and_mask_in_block_ = decomposition.and_mask; } check->set_skip_check(); } if (current_and_mask_in_block() == 0) { if (decomposition.or_mask > current_or_mask_in_block()) { UseNewIndexInCurrentBlock(Token::BIT_OR, decomposition.or_mask, decomposition.base, decomposition.context); current_or_mask_in_block_ = decomposition.or_mask; } check->set_skip_check(); } if (!check->skip_check()) { InductionVariableCheck* new_check = new(check->block()->graph()->zone()) InductionVariableCheck(check, checks_, upper_limit); checks_ = new_check; } } /* * This method detects if phi is an induction variable, with phi_operand as * its "incremented" value (the other operand would be the "base" value). * * It cheks is phi_operand has the form "phi + constant". * If yes, the constant is the increment that the induction variable gets at * every loop iteration. * Otherwise it returns 0. */ int32_t InductionVariableData::ComputeIncrement(HPhi* phi, HValue* phi_operand) { if (!phi_operand->representation().IsInteger32()) return 0; if (phi_operand->IsAdd()) { HAdd* operation = HAdd::cast(phi_operand); if (operation->left() == phi && operation->right()->IsInteger32Constant()) { return operation->right()->GetInteger32Constant(); } else if (operation->right() == phi && operation->left()->IsInteger32Constant()) { return operation->left()->GetInteger32Constant(); } } else if (phi_operand->IsSub()) { HSub* operation = HSub::cast(phi_operand); if (operation->left() == phi && operation->right()->IsInteger32Constant()) { return -operation->right()->GetInteger32Constant(); } } return 0; } /* * Swaps the information in "update" with the one contained in "this". * The swapping is important because this method is used while doing a * dominator tree traversal, and "update" will retain the old data that * will be restored while backtracking. */ void InductionVariableData::UpdateAdditionalLimit( InductionVariableLimitUpdate* update) { ASSERT(update->updated_variable == this); if (update->limit_is_upper) { swap(&additional_upper_limit_, &update->limit); swap(&additional_upper_limit_is_included_, &update->limit_is_included); } else { swap(&additional_lower_limit_, &update->limit); swap(&additional_lower_limit_is_included_, &update->limit_is_included); } } int32_t InductionVariableData::ComputeUpperLimit(int32_t and_mask, int32_t or_mask) { // Should be Smi::kMaxValue but it must fit 32 bits; lower is safe anyway. const int32_t MAX_LIMIT = 1 << 30; int32_t result = MAX_LIMIT; if (limit() != NULL && limit()->IsInteger32Constant()) { int32_t limit_value = limit()->GetInteger32Constant(); if (!limit_included()) { limit_value--; } if (limit_value < result) result = limit_value; } if (additional_upper_limit() != NULL && additional_upper_limit()->IsInteger32Constant()) { int32_t limit_value = additional_upper_limit()->GetInteger32Constant(); if (!additional_upper_limit_is_included()) { limit_value--; } if (limit_value < result) result = limit_value; } if (and_mask > 0 && and_mask < MAX_LIMIT) { if (and_mask < result) result = and_mask; return result; } // Add the effect of the or_mask. result |= or_mask; return result >= MAX_LIMIT ? kNoLimit : result; } HValue* InductionVariableData::IgnoreOsrValue(HValue* v) { if (!v->IsPhi()) return v; HPhi* phi = HPhi::cast(v); if (phi->OperandCount() != 2) return v; if (phi->OperandAt(0)->block()->is_osr_entry()) { return phi->OperandAt(1); } else if (phi->OperandAt(1)->block()->is_osr_entry()) { return phi->OperandAt(0); } else { return v; } } InductionVariableData* InductionVariableData::GetInductionVariableData( HValue* v) { v = IgnoreOsrValue(v); if (v->IsPhi()) { return HPhi::cast(v)->induction_variable_data(); } return NULL; } /* * Check if a conditional branch to "current_branch" with token "token" is * the branch that keeps the induction loop running (and, conversely, will * terminate it if the "other_branch" is taken). * * Three conditions must be met: * - "current_branch" must be in the induction loop. * - "other_branch" must be out of the induction loop. * - "token" and the induction increment must be "compatible": the token should * be a condition that keeps the execution inside the loop until the limit is * reached. */ bool InductionVariableData::CheckIfBranchIsLoopGuard( Token::Value token, HBasicBlock* current_branch, HBasicBlock* other_branch) { if (!phi()->block()->current_loop()->IsNestedInThisLoop( current_branch->current_loop())) { return false; } if (phi()->block()->current_loop()->IsNestedInThisLoop( other_branch->current_loop())) { return false; } if (increment() > 0 && (token == Token::LT || token == Token::LTE)) { return true; } if (increment() < 0 && (token == Token::GT || token == Token::GTE)) { return true; } if (Token::IsInequalityOp(token) && (increment() == 1 || increment() == -1)) { return true; } return false; } void InductionVariableData::ComputeLimitFromPredecessorBlock( HBasicBlock* block, LimitFromPredecessorBlock* result) { if (block->predecessors()->length() != 1) return; HBasicBlock* predecessor = block->predecessors()->at(0); HInstruction* end = predecessor->last(); if (!end->IsCompareNumericAndBranch()) return; HCompareNumericAndBranch* branch = HCompareNumericAndBranch::cast(end); Token::Value token = branch->token(); if (!Token::IsArithmeticCompareOp(token)) return; HBasicBlock* other_target; if (block == branch->SuccessorAt(0)) { other_target = branch->SuccessorAt(1); } else { other_target = branch->SuccessorAt(0); token = Token::NegateCompareOp(token); ASSERT(block == branch->SuccessorAt(1)); } InductionVariableData* data; data = GetInductionVariableData(branch->left()); HValue* limit = branch->right(); if (data == NULL) { data = GetInductionVariableData(branch->right()); token = Token::ReverseCompareOp(token); limit = branch->left(); } if (data != NULL) { result->variable = data; result->token = token; result->limit = limit; result->other_target = other_target; } } /* * Compute the limit that is imposed on an induction variable when entering * "block" (if any). * If the limit is the "proper" induction limit (the one that makes the loop * terminate when the induction variable reaches it) it is stored directly in * the induction variable data. * Otherwise the limit is written in "additional_limit" and the method * returns true. */ bool InductionVariableData::ComputeInductionVariableLimit( HBasicBlock* block, InductionVariableLimitUpdate* additional_limit) { LimitFromPredecessorBlock limit; ComputeLimitFromPredecessorBlock(block, &limit); if (!limit.LimitIsValid()) return false; if (limit.variable->CheckIfBranchIsLoopGuard(limit.token, block, limit.other_target)) { limit.variable->limit_ = limit.limit; limit.variable->limit_included_ = limit.LimitIsIncluded(); limit.variable->limit_validity_ = block; limit.variable->induction_exit_block_ = block->predecessors()->at(0); limit.variable->induction_exit_target_ = limit.other_target; return false; } else { additional_limit->updated_variable = limit.variable; additional_limit->limit = limit.limit; additional_limit->limit_is_upper = limit.LimitIsUpper(); additional_limit->limit_is_included = limit.LimitIsIncluded(); return true; } } Range* HMathMinMax::InferRange(Zone* zone) { if (representation().IsSmiOrInteger32()) { Range* a = left()->range(); Range* b = right()->range(); Range* res = a->Copy(zone); if (operation_ == kMathMax) { res->CombinedMax(b); } else { ASSERT(operation_ == kMathMin); res->CombinedMin(b); } return res; } else { return HValue::InferRange(zone); } } void HPhi::PrintTo(StringStream* stream) { stream->Add("["); for (int i = 0; i < OperandCount(); ++i) { HValue* value = OperandAt(i); stream->Add(" "); value->PrintNameTo(stream); stream->Add(" "); } stream->Add(" uses:%d_%ds_%di_%dd_%dt", UseCount(), smi_non_phi_uses() + smi_indirect_uses(), int32_non_phi_uses() + int32_indirect_uses(), double_non_phi_uses() + double_indirect_uses(), tagged_non_phi_uses() + tagged_indirect_uses()); PrintRangeTo(stream); PrintTypeTo(stream); stream->Add("]"); } void HPhi::AddInput(HValue* value) { inputs_.Add(NULL, value->block()->zone()); SetOperandAt(OperandCount() - 1, value); // Mark phis that may have 'arguments' directly or indirectly as an operand. if (!CheckFlag(kIsArguments) && value->CheckFlag(kIsArguments)) { SetFlag(kIsArguments); } } bool HPhi::HasRealUses() { for (HUseIterator it(uses()); !it.Done(); it.Advance()) { if (!it.value()->IsPhi()) return true; } return false; } HValue* HPhi::GetRedundantReplacement() { HValue* candidate = NULL; int count = OperandCount(); int position = 0; while (position < count && candidate == NULL) { HValue* current = OperandAt(position++); if (current != this) candidate = current; } while (position < count) { HValue* current = OperandAt(position++); if (current != this && current != candidate) return NULL; } ASSERT(candidate != this); return candidate; } void HPhi::DeleteFromGraph() { ASSERT(block() != NULL); block()->RemovePhi(this); ASSERT(block() == NULL); } void HPhi::InitRealUses(int phi_id) { // Initialize real uses. phi_id_ = phi_id; // Compute a conservative approximation of truncating uses before inferring // representations. The proper, exact computation will be done later, when // inserting representation changes. SetFlag(kTruncatingToSmi); SetFlag(kTruncatingToInt32); for (HUseIterator it(uses()); !it.Done(); it.Advance()) { HValue* value = it.value(); if (!value->IsPhi()) { Representation rep = value->observed_input_representation(it.index()); non_phi_uses_[rep.kind()] += value->LoopWeight(); if (FLAG_trace_representation) { PrintF("#%d Phi is used by real #%d %s as %s\n", id(), value->id(), value->Mnemonic(), rep.Mnemonic()); } if (!value->IsSimulate()) { if (!value->CheckFlag(kTruncatingToSmi)) { ClearFlag(kTruncatingToSmi); } if (!value->CheckFlag(kTruncatingToInt32)) { ClearFlag(kTruncatingToInt32); } } } } } void HPhi::AddNonPhiUsesFrom(HPhi* other) { if (FLAG_trace_representation) { PrintF("adding to #%d Phi uses of #%d Phi: s%d i%d d%d t%d\n", id(), other->id(), other->non_phi_uses_[Representation::kSmi], other->non_phi_uses_[Representation::kInteger32], other->non_phi_uses_[Representation::kDouble], other->non_phi_uses_[Representation::kTagged]); } for (int i = 0; i < Representation::kNumRepresentations; i++) { indirect_uses_[i] += other->non_phi_uses_[i]; } } void HPhi::AddIndirectUsesTo(int* dest) { for (int i = 0; i < Representation::kNumRepresentations; i++) { dest[i] += indirect_uses_[i]; } } void HSimulate::MergeWith(ZoneList* list) { while (!list->is_empty()) { HSimulate* from = list->RemoveLast(); ZoneList* from_values = &from->values_; for (int i = 0; i < from_values->length(); ++i) { if (from->HasAssignedIndexAt(i)) { int index = from->GetAssignedIndexAt(i); if (HasValueForIndex(index)) continue; AddAssignedValue(index, from_values->at(i)); } else { if (pop_count_ > 0) { pop_count_--; } else { AddPushedValue(from_values->at(i)); } } } pop_count_ += from->pop_count_; from->DeleteAndReplaceWith(NULL); } } void HSimulate::PrintDataTo(StringStream* stream) { stream->Add("id=%d", ast_id().ToInt()); if (pop_count_ > 0) stream->Add(" pop %d", pop_count_); if (values_.length() > 0) { if (pop_count_ > 0) stream->Add(" /"); for (int i = values_.length() - 1; i >= 0; --i) { if (HasAssignedIndexAt(i)) { stream->Add(" var[%d] = ", GetAssignedIndexAt(i)); } else { stream->Add(" push "); } values_[i]->PrintNameTo(stream); if (i > 0) stream->Add(","); } } } void HSimulate::ReplayEnvironment(HEnvironment* env) { ASSERT(env != NULL); env->set_ast_id(ast_id()); env->Drop(pop_count()); for (int i = values()->length() - 1; i >= 0; --i) { HValue* value = values()->at(i); if (HasAssignedIndexAt(i)) { env->Bind(GetAssignedIndexAt(i), value); } else { env->Push(value); } } } static void ReplayEnvironmentNested(const ZoneList* values, HCapturedObject* other) { for (int i = 0; i < values->length(); ++i) { HValue* value = values->at(i); if (value->IsCapturedObject()) { if (HCapturedObject::cast(value)->capture_id() == other->capture_id()) { values->at(i) = other; } else { ReplayEnvironmentNested(HCapturedObject::cast(value)->values(), other); } } } } // Replay captured objects by replacing all captured objects with the // same capture id in the current and all outer environments. void HCapturedObject::ReplayEnvironment(HEnvironment* env) { ASSERT(env != NULL); while (env != NULL) { ReplayEnvironmentNested(env->values(), this); env = env->outer(); } } void HCapturedObject::PrintDataTo(StringStream* stream) { stream->Add("#%d ", capture_id()); HDematerializedObject::PrintDataTo(stream); } void HEnterInlined::RegisterReturnTarget(HBasicBlock* return_target, Zone* zone) { ASSERT(return_target->IsInlineReturnTarget()); return_targets_.Add(return_target, zone); } void HEnterInlined::PrintDataTo(StringStream* stream) { SmartArrayPointer name = function()->debug_name()->ToCString(); stream->Add("%s, id=%d", *name, function()->id().ToInt()); } static bool IsInteger32(double value) { double roundtrip_value = static_cast(static_cast(value)); return BitCast(roundtrip_value) == BitCast(value); } HConstant::HConstant(Handle handle, Representation r) : HTemplateInstruction<0>(HType::TypeFromValue(handle)), object_(Unique::CreateUninitialized(handle)), has_smi_value_(false), has_int32_value_(false), has_double_value_(false), has_external_reference_value_(false), is_internalized_string_(false), is_not_in_new_space_(true), is_cell_(false), boolean_value_(handle->BooleanValue()) { if (handle->IsHeapObject()) { Heap* heap = Handle::cast(handle)->GetHeap(); is_not_in_new_space_ = !heap->InNewSpace(*handle); } if (handle->IsNumber()) { double n = handle->Number(); has_int32_value_ = IsInteger32(n); int32_value_ = DoubleToInt32(n); has_smi_value_ = has_int32_value_ && Smi::IsValid(int32_value_); double_value_ = n; has_double_value_ = true; // TODO(titzer): if this heap number is new space, tenure a new one. } else { is_internalized_string_ = handle->IsInternalizedString(); } is_cell_ = !handle.is_null() && (handle->IsCell() || handle->IsPropertyCell()); Initialize(r); } HConstant::HConstant(Unique unique, Representation r, HType type, bool is_internalize_string, bool is_not_in_new_space, bool is_cell, bool boolean_value) : HTemplateInstruction<0>(type), object_(unique), has_smi_value_(false), has_int32_value_(false), has_double_value_(false), has_external_reference_value_(false), is_internalized_string_(is_internalize_string), is_not_in_new_space_(is_not_in_new_space), is_cell_(is_cell), boolean_value_(boolean_value) { ASSERT(!unique.handle().is_null()); ASSERT(!type.IsTaggedNumber()); Initialize(r); } HConstant::HConstant(int32_t integer_value, Representation r, bool is_not_in_new_space, Unique object) : object_(object), has_smi_value_(Smi::IsValid(integer_value)), has_int32_value_(true), has_double_value_(true), has_external_reference_value_(false), is_internalized_string_(false), is_not_in_new_space_(is_not_in_new_space), is_cell_(false), boolean_value_(integer_value != 0), int32_value_(integer_value), double_value_(FastI2D(integer_value)) { set_type(has_smi_value_ ? HType::Smi() : HType::TaggedNumber()); Initialize(r); } HConstant::HConstant(double double_value, Representation r, bool is_not_in_new_space, Unique object) : object_(object), has_int32_value_(IsInteger32(double_value)), has_double_value_(true), has_external_reference_value_(false), is_internalized_string_(false), is_not_in_new_space_(is_not_in_new_space), is_cell_(false), boolean_value_(double_value != 0 && !std::isnan(double_value)), int32_value_(DoubleToInt32(double_value)), double_value_(double_value) { has_smi_value_ = has_int32_value_ && Smi::IsValid(int32_value_); set_type(has_smi_value_ ? HType::Smi() : HType::TaggedNumber()); Initialize(r); } HConstant::HConstant(ExternalReference reference) : HTemplateInstruction<0>(HType::None()), object_(Unique(Handle::null())), has_smi_value_(false), has_int32_value_(false), has_double_value_(false), has_external_reference_value_(true), is_internalized_string_(false), is_not_in_new_space_(true), is_cell_(false), boolean_value_(true), external_reference_value_(reference) { Initialize(Representation::External()); } void HConstant::Initialize(Representation r) { if (r.IsNone()) { if (has_smi_value_ && SmiValuesAre31Bits()) { r = Representation::Smi(); } else if (has_int32_value_) { r = Representation::Integer32(); } else if (has_double_value_) { r = Representation::Double(); } else if (has_external_reference_value_) { r = Representation::External(); } else { Handle object = object_.handle(); if (object->IsJSObject()) { // Try to eagerly migrate JSObjects that have deprecated maps. Handle js_object = Handle::cast(object); if (js_object->map()->is_deprecated()) { JSObject::TryMigrateInstance(js_object); } } r = Representation::Tagged(); } } set_representation(r); SetFlag(kUseGVN); } bool HConstant::EmitAtUses() { ASSERT(IsLinked()); if (block()->graph()->has_osr() && block()->graph()->IsStandardConstant(this)) { // TODO(titzer): this seems like a hack that should be fixed by custom OSR. return true; } if (UseCount() == 0) return true; if (IsCell()) return false; if (representation().IsDouble()) return false; return true; } HConstant* HConstant::CopyToRepresentation(Representation r, Zone* zone) const { if (r.IsSmi() && !has_smi_value_) return NULL; if (r.IsInteger32() && !has_int32_value_) return NULL; if (r.IsDouble() && !has_double_value_) return NULL; if (r.IsExternal() && !has_external_reference_value_) return NULL; if (has_int32_value_) { return new(zone) HConstant(int32_value_, r, is_not_in_new_space_, object_); } if (has_double_value_) { return new(zone) HConstant(double_value_, r, is_not_in_new_space_, object_); } if (has_external_reference_value_) { return new(zone) HConstant(external_reference_value_); } ASSERT(!object_.handle().is_null()); return new(zone) HConstant(object_, r, type_, is_internalized_string_, is_not_in_new_space_, is_cell_, boolean_value_); } Maybe HConstant::CopyToTruncatedInt32(Zone* zone) { HConstant* res = NULL; if (has_int32_value_) { res = new(zone) HConstant(int32_value_, Representation::Integer32(), is_not_in_new_space_, object_); } else if (has_double_value_) { res = new(zone) HConstant(DoubleToInt32(double_value_), Representation::Integer32(), is_not_in_new_space_, object_); } return Maybe(res != NULL, res); } Maybe HConstant::CopyToTruncatedNumber(Zone* zone) { HConstant* res = NULL; Handle handle = this->handle(zone->isolate()); if (handle->IsBoolean()) { res = handle->BooleanValue() ? new(zone) HConstant(1) : new(zone) HConstant(0); } else if (handle->IsUndefined()) { res = new(zone) HConstant(OS::nan_value()); } else if (handle->IsNull()) { res = new(zone) HConstant(0); } return Maybe(res != NULL, res); } void HConstant::PrintDataTo(StringStream* stream) { if (has_int32_value_) { stream->Add("%d ", int32_value_); } else if (has_double_value_) { stream->Add("%f ", FmtElm(double_value_)); } else if (has_external_reference_value_) { stream->Add("%p ", reinterpret_cast( external_reference_value_.address())); } else { handle(Isolate::Current())->ShortPrint(stream); } if (!is_not_in_new_space_) { stream->Add("[new space] "); } } void HBinaryOperation::PrintDataTo(StringStream* stream) { left()->PrintNameTo(stream); stream->Add(" "); right()->PrintNameTo(stream); if (CheckFlag(kCanOverflow)) stream->Add(" !"); if (CheckFlag(kBailoutOnMinusZero)) stream->Add(" -0?"); } void HBinaryOperation::InferRepresentation(HInferRepresentationPhase* h_infer) { ASSERT(CheckFlag(kFlexibleRepresentation)); Representation new_rep = RepresentationFromInputs(); UpdateRepresentation(new_rep, h_infer, "inputs"); if (representation().IsSmi() && HasNonSmiUse()) { UpdateRepresentation( Representation::Integer32(), h_infer, "use requirements"); } if (observed_output_representation_.IsNone()) { new_rep = RepresentationFromUses(); UpdateRepresentation(new_rep, h_infer, "uses"); } else { new_rep = RepresentationFromOutput(); UpdateRepresentation(new_rep, h_infer, "output"); } } Representation HBinaryOperation::RepresentationFromInputs() { // Determine the worst case of observed input representations and // the currently assumed output representation. Representation rep = representation(); for (int i = 1; i <= 2; ++i) { rep = rep.generalize(observed_input_representation(i)); } // If any of the actual input representation is more general than what we // have so far but not Tagged, use that representation instead. Representation left_rep = left()->representation(); Representation right_rep = right()->representation(); if (!left_rep.IsTagged()) rep = rep.generalize(left_rep); if (!right_rep.IsTagged()) rep = rep.generalize(right_rep); return rep; } bool HBinaryOperation::IgnoreObservedOutputRepresentation( Representation current_rep) { return ((current_rep.IsInteger32() && CheckUsesForFlag(kTruncatingToInt32)) || (current_rep.IsSmi() && CheckUsesForFlag(kTruncatingToSmi))) && // Mul in Integer32 mode would be too precise. (!this->IsMul() || HMul::cast(this)->MulMinusOne()); } Representation HBinaryOperation::RepresentationFromOutput() { Representation rep = representation(); // Consider observed output representation, but ignore it if it's Double, // this instruction is not a division, and all its uses are truncating // to Integer32. if (observed_output_representation_.is_more_general_than(rep) && !IgnoreObservedOutputRepresentation(rep)) { return observed_output_representation_; } return Representation::None(); } void HBinaryOperation::AssumeRepresentation(Representation r) { set_observed_input_representation(1, r); set_observed_input_representation(2, r); HValue::AssumeRepresentation(r); } void HMathMinMax::InferRepresentation(HInferRepresentationPhase* h_infer) { ASSERT(CheckFlag(kFlexibleRepresentation)); Representation new_rep = RepresentationFromInputs(); UpdateRepresentation(new_rep, h_infer, "inputs"); // Do not care about uses. } Range* HBitwise::InferRange(Zone* zone) { if (op() == Token::BIT_XOR) { if (left()->HasRange() && right()->HasRange()) { // The maximum value has the high bit, and all bits below, set: // (1 << high) - 1. // If the range can be negative, the minimum int is a negative number with // the high bit, and all bits below, unset: // -(1 << high). // If it cannot be negative, conservatively choose 0 as minimum int. int64_t left_upper = left()->range()->upper(); int64_t left_lower = left()->range()->lower(); int64_t right_upper = right()->range()->upper(); int64_t right_lower = right()->range()->lower(); if (left_upper < 0) left_upper = ~left_upper; if (left_lower < 0) left_lower = ~left_lower; if (right_upper < 0) right_upper = ~right_upper; if (right_lower < 0) right_lower = ~right_lower; int high = MostSignificantBit( static_cast( left_upper | left_lower | right_upper | right_lower)); int64_t limit = 1; limit <<= high; int32_t min = (left()->range()->CanBeNegative() || right()->range()->CanBeNegative()) ? static_cast(-limit) : 0; return new(zone) Range(min, static_cast(limit - 1)); } Range* result = HValue::InferRange(zone); result->set_can_be_minus_zero(false); return result; } const int32_t kDefaultMask = static_cast(0xffffffff); int32_t left_mask = (left()->range() != NULL) ? left()->range()->Mask() : kDefaultMask; int32_t right_mask = (right()->range() != NULL) ? right()->range()->Mask() : kDefaultMask; int32_t result_mask = (op() == Token::BIT_AND) ? left_mask & right_mask : left_mask | right_mask; if (result_mask >= 0) return new(zone) Range(0, result_mask); Range* result = HValue::InferRange(zone); result->set_can_be_minus_zero(false); return result; } Range* HSar::InferRange(Zone* zone) { if (right()->IsConstant()) { HConstant* c = HConstant::cast(right()); if (c->HasInteger32Value()) { Range* result = (left()->range() != NULL) ? left()->range()->Copy(zone) : new(zone) Range(); result->Sar(c->Integer32Value()); return result; } } return HValue::InferRange(zone); } Range* HShr::InferRange(Zone* zone) { if (right()->IsConstant()) { HConstant* c = HConstant::cast(right()); if (c->HasInteger32Value()) { int shift_count = c->Integer32Value() & 0x1f; if (left()->range()->CanBeNegative()) { // Only compute bounds if the result always fits into an int32. return (shift_count >= 1) ? new(zone) Range(0, static_cast(0xffffffff) >> shift_count) : new(zone) Range(); } else { // For positive inputs we can use the >> operator. Range* result = (left()->range() != NULL) ? left()->range()->Copy(zone) : new(zone) Range(); result->Sar(c->Integer32Value()); return result; } } } return HValue::InferRange(zone); } Range* HShl::InferRange(Zone* zone) { if (right()->IsConstant()) { HConstant* c = HConstant::cast(right()); if (c->HasInteger32Value()) { Range* result = (left()->range() != NULL) ? left()->range()->Copy(zone) : new(zone) Range(); result->Shl(c->Integer32Value()); return result; } } return HValue::InferRange(zone); } Range* HLoadNamedField::InferRange(Zone* zone) { if (access().representation().IsInteger8()) { return new(zone) Range(kMinInt8, kMaxInt8); } if (access().representation().IsUInteger8()) { return new(zone) Range(kMinUInt8, kMaxUInt8); } if (access().representation().IsInteger16()) { return new(zone) Range(kMinInt16, kMaxInt16); } if (access().representation().IsUInteger16()) { return new(zone) Range(kMinUInt16, kMaxUInt16); } if (access().IsStringLength()) { return new(zone) Range(0, String::kMaxLength); } return HValue::InferRange(zone); } Range* HLoadKeyed::InferRange(Zone* zone) { switch (elements_kind()) { case EXTERNAL_BYTE_ELEMENTS: return new(zone) Range(kMinInt8, kMaxInt8); case EXTERNAL_UNSIGNED_BYTE_ELEMENTS: case EXTERNAL_PIXEL_ELEMENTS: return new(zone) Range(kMinUInt8, kMaxUInt8); case EXTERNAL_SHORT_ELEMENTS: return new(zone) Range(kMinInt16, kMaxInt16); case EXTERNAL_UNSIGNED_SHORT_ELEMENTS: return new(zone) Range(kMinUInt16, kMaxUInt16); default: return HValue::InferRange(zone); } } void HCompareGeneric::PrintDataTo(StringStream* stream) { stream->Add(Token::Name(token())); stream->Add(" "); HBinaryOperation::PrintDataTo(stream); } void HStringCompareAndBranch::PrintDataTo(StringStream* stream) { stream->Add(Token::Name(token())); stream->Add(" "); HControlInstruction::PrintDataTo(stream); } void HCompareNumericAndBranch::PrintDataTo(StringStream* stream) { stream->Add(Token::Name(token())); stream->Add(" "); left()->PrintNameTo(stream); stream->Add(" "); right()->PrintNameTo(stream); HControlInstruction::PrintDataTo(stream); } void HCompareObjectEqAndBranch::PrintDataTo(StringStream* stream) { left()->PrintNameTo(stream); stream->Add(" "); right()->PrintNameTo(stream); HControlInstruction::PrintDataTo(stream); } bool HCompareObjectEqAndBranch::KnownSuccessorBlock(HBasicBlock** block) { if (left()->IsConstant() && right()->IsConstant()) { bool comparison_result = HConstant::cast(left())->Equals(HConstant::cast(right())); *block = comparison_result ? FirstSuccessor() : SecondSuccessor(); return true; } *block = NULL; return false; } void HCompareHoleAndBranch::InferRepresentation( HInferRepresentationPhase* h_infer) { ChangeRepresentation(value()->representation()); } bool HCompareMinusZeroAndBranch::KnownSuccessorBlock(HBasicBlock** block) { if (value()->representation().IsSmiOrInteger32()) { // A Smi or Integer32 cannot contain minus zero. *block = SecondSuccessor(); return true; } *block = NULL; return false; } void HCompareMinusZeroAndBranch::InferRepresentation( HInferRepresentationPhase* h_infer) { ChangeRepresentation(value()->representation()); } void HGoto::PrintDataTo(StringStream* stream) { stream->Add("B%d", SuccessorAt(0)->block_id()); } void HCompareNumericAndBranch::InferRepresentation( HInferRepresentationPhase* h_infer) { Representation left_rep = left()->representation(); Representation right_rep = right()->representation(); Representation observed_left = observed_input_representation(0); Representation observed_right = observed_input_representation(1); Representation rep = Representation::None(); rep = rep.generalize(observed_left); rep = rep.generalize(observed_right); if (rep.IsNone() || rep.IsSmiOrInteger32()) { if (!left_rep.IsTagged()) rep = rep.generalize(left_rep); if (!right_rep.IsTagged()) rep = rep.generalize(right_rep); } else { rep = Representation::Double(); } if (rep.IsDouble()) { // According to the ES5 spec (11.9.3, 11.8.5), Equality comparisons (==, === // and !=) have special handling of undefined, e.g. undefined == undefined // is 'true'. Relational comparisons have a different semantic, first // calling ToPrimitive() on their arguments. The standard Crankshaft // tagged-to-double conversion to ensure the HCompareNumericAndBranch's // inputs are doubles caused 'undefined' to be converted to NaN. That's // compatible out-of-the box with ordered relational comparisons (<, >, <=, // >=). However, for equality comparisons (and for 'in' and 'instanceof'), // it is not consistent with the spec. For example, it would cause undefined // == undefined (should be true) to be evaluated as NaN == NaN // (false). Therefore, any comparisons other than ordered relational // comparisons must cause a deopt when one of their arguments is undefined. // See also v8:1434 if (Token::IsOrderedRelationalCompareOp(token_)) { SetFlag(kAllowUndefinedAsNaN); } } ChangeRepresentation(rep); } void HParameter::PrintDataTo(StringStream* stream) { stream->Add("%u", index()); } void HLoadNamedField::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); access_.PrintTo(stream); } HCheckMaps* HCheckMaps::New(Zone* zone, HValue* context, HValue* value, Handle map, CompilationInfo* info, HValue* typecheck) { HCheckMaps* check_map = new(zone) HCheckMaps(value, zone, typecheck); check_map->Add(map, zone); if (map->CanOmitMapChecks() && value->IsConstant() && HConstant::cast(value)->HasMap(map)) { // TODO(titzer): collect dependent map checks into a list. check_map->omit_ = true; if (map->CanTransition()) { map->AddDependentCompilationInfo( DependentCode::kPrototypeCheckGroup, info); } } return check_map; } void HLoadNamedGeneric::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); stream->Add("."); stream->Add(*String::cast(*name())->ToCString()); } void HLoadKeyed::PrintDataTo(StringStream* stream) { if (!is_external()) { elements()->PrintNameTo(stream); } else { ASSERT(elements_kind() >= FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND && elements_kind() <= LAST_EXTERNAL_ARRAY_ELEMENTS_KIND); elements()->PrintNameTo(stream); stream->Add("."); stream->Add(ElementsKindToString(elements_kind())); } stream->Add("["); key()->PrintNameTo(stream); if (IsDehoisted()) { stream->Add(" + %d]", index_offset()); } else { stream->Add("]"); } if (HasDependency()) { stream->Add(" "); dependency()->PrintNameTo(stream); } if (RequiresHoleCheck()) { stream->Add(" check_hole"); } } bool HLoadKeyed::UsesMustHandleHole() const { if (IsFastPackedElementsKind(elements_kind())) { return false; } if (IsExternalArrayElementsKind(elements_kind())) { return false; } if (hole_mode() == ALLOW_RETURN_HOLE) { if (IsFastDoubleElementsKind(elements_kind())) { return AllUsesCanTreatHoleAsNaN(); } return true; } if (IsFastDoubleElementsKind(elements_kind())) { return false; } // Holes are only returned as tagged values. if (!representation().IsTagged()) { return false; } for (HUseIterator it(uses()); !it.Done(); it.Advance()) { HValue* use = it.value(); if (!use->IsChange()) return false; } return true; } bool HLoadKeyed::AllUsesCanTreatHoleAsNaN() const { return IsFastDoubleElementsKind(elements_kind()) && CheckUsesForFlag(HValue::kAllowUndefinedAsNaN); } bool HLoadKeyed::RequiresHoleCheck() const { if (IsFastPackedElementsKind(elements_kind())) { return false; } if (IsExternalArrayElementsKind(elements_kind())) { return false; } return !UsesMustHandleHole(); } void HLoadKeyedGeneric::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); stream->Add("["); key()->PrintNameTo(stream); stream->Add("]"); } HValue* HLoadKeyedGeneric::Canonicalize() { // Recognize generic keyed loads that use property name generated // by for-in statement as a key and rewrite them into fast property load // by index. if (key()->IsLoadKeyed()) { HLoadKeyed* key_load = HLoadKeyed::cast(key()); if (key_load->elements()->IsForInCacheArray()) { HForInCacheArray* names_cache = HForInCacheArray::cast(key_load->elements()); if (names_cache->enumerable() == object()) { HForInCacheArray* index_cache = names_cache->index_cache(); HCheckMapValue* map_check = HCheckMapValue::New(block()->graph()->zone(), block()->graph()->GetInvalidContext(), object(), names_cache->map()); HInstruction* index = HLoadKeyed::New( block()->graph()->zone(), block()->graph()->GetInvalidContext(), index_cache, key_load->key(), key_load->key(), key_load->elements_kind()); map_check->InsertBefore(this); index->InsertBefore(this); HLoadFieldByIndex* load = new(block()->zone()) HLoadFieldByIndex( object(), index); load->InsertBefore(this); return load; } } } return this; } void HStoreNamedGeneric::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); stream->Add("."); ASSERT(name()->IsString()); stream->Add(*String::cast(*name())->ToCString()); stream->Add(" = "); value()->PrintNameTo(stream); } void HStoreNamedField::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); access_.PrintTo(stream); stream->Add(" = "); value()->PrintNameTo(stream); if (NeedsWriteBarrier()) { stream->Add(" (write-barrier)"); } if (has_transition()) { stream->Add(" (transition map %p)", *transition_map()); } } void HStoreKeyed::PrintDataTo(StringStream* stream) { if (!is_external()) { elements()->PrintNameTo(stream); } else { elements()->PrintNameTo(stream); stream->Add("."); stream->Add(ElementsKindToString(elements_kind())); ASSERT(elements_kind() >= FIRST_EXTERNAL_ARRAY_ELEMENTS_KIND && elements_kind() <= LAST_EXTERNAL_ARRAY_ELEMENTS_KIND); } stream->Add("["); key()->PrintNameTo(stream); if (IsDehoisted()) { stream->Add(" + %d] = ", index_offset()); } else { stream->Add("] = "); } value()->PrintNameTo(stream); } void HStoreKeyedGeneric::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); stream->Add("["); key()->PrintNameTo(stream); stream->Add("] = "); value()->PrintNameTo(stream); } void HTransitionElementsKind::PrintDataTo(StringStream* stream) { object()->PrintNameTo(stream); ElementsKind from_kind = original_map().handle()->elements_kind(); ElementsKind to_kind = transitioned_map().handle()->elements_kind(); stream->Add(" %p [%s] -> %p [%s]", *original_map().handle(), ElementsAccessor::ForKind(from_kind)->name(), *transitioned_map().handle(), ElementsAccessor::ForKind(to_kind)->name()); if (IsSimpleMapChangeTransition(from_kind, to_kind)) stream->Add(" (simple)"); } void HLoadGlobalCell::PrintDataTo(StringStream* stream) { stream->Add("[%p]", *cell().handle()); if (!details_.IsDontDelete()) stream->Add(" (deleteable)"); if (details_.IsReadOnly()) stream->Add(" (read-only)"); } bool HLoadGlobalCell::RequiresHoleCheck() const { if (details_.IsDontDelete() && !details_.IsReadOnly()) return false; for (HUseIterator it(uses()); !it.Done(); it.Advance()) { HValue* use = it.value(); if (!use->IsChange()) return true; } return false; } void HLoadGlobalGeneric::PrintDataTo(StringStream* stream) { stream->Add("%o ", *name()); } void HInnerAllocatedObject::PrintDataTo(StringStream* stream) { base_object()->PrintNameTo(stream); stream->Add(" offset %d", offset()); } void HStoreGlobalCell::PrintDataTo(StringStream* stream) { stream->Add("[%p] = ", *cell().handle()); value()->PrintNameTo(stream); if (!details_.IsDontDelete()) stream->Add(" (deleteable)"); if (details_.IsReadOnly()) stream->Add(" (read-only)"); } void HStoreGlobalGeneric::PrintDataTo(StringStream* stream) { stream->Add("%o = ", *name()); value()->PrintNameTo(stream); } void HLoadContextSlot::PrintDataTo(StringStream* stream) { value()->PrintNameTo(stream); stream->Add("[%d]", slot_index()); } void HStoreContextSlot::PrintDataTo(StringStream* stream) { context()->PrintNameTo(stream); stream->Add("[%d] = ", slot_index()); value()->PrintNameTo(stream); } // Implementation of type inference and type conversions. Calculates // the inferred type of this instruction based on the input operands. HType HValue::CalculateInferredType() { return type_; } HType HPhi::CalculateInferredType() { if (OperandCount() == 0) return HType::Tagged(); HType result = OperandAt(0)->type(); for (int i = 1; i < OperandCount(); ++i) { HType current = OperandAt(i)->type(); result = result.Combine(current); } return result; } HType HChange::CalculateInferredType() { if (from().IsDouble() && to().IsTagged()) return HType::HeapNumber(); return type(); } Representation HUnaryMathOperation::RepresentationFromInputs() { Representation rep = representation(); // If any of the actual input representation is more general than what we // have so far but not Tagged, use that representation instead. Representation input_rep = value()->representation(); if (!input_rep.IsTagged()) { rep = rep.generalize(input_rep); } return rep; } void HAllocate::HandleSideEffectDominator(GVNFlag side_effect, HValue* dominator) { ASSERT(side_effect == kChangesNewSpacePromotion); Zone* zone = block()->zone(); if (!FLAG_use_allocation_folding) return; // Try to fold allocations together with their dominating allocations. if (!dominator->IsAllocate()) { if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) cannot fold into #%d (%s)\n", id(), Mnemonic(), dominator->id(), dominator->Mnemonic()); } return; } HAllocate* dominator_allocate = HAllocate::cast(dominator); HValue* dominator_size = dominator_allocate->size(); HValue* current_size = size(); // TODO(hpayer): Add support for non-constant allocation in dominator. if (!current_size->IsInteger32Constant() || !dominator_size->IsInteger32Constant()) { if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) cannot fold into #%d (%s), dynamic allocation size\n", id(), Mnemonic(), dominator->id(), dominator->Mnemonic()); } return; } dominator_allocate = GetFoldableDominator(dominator_allocate); if (dominator_allocate == NULL) { return; } ASSERT((IsNewSpaceAllocation() && dominator_allocate->IsNewSpaceAllocation()) || (IsOldDataSpaceAllocation() && dominator_allocate->IsOldDataSpaceAllocation()) || (IsOldPointerSpaceAllocation() && dominator_allocate->IsOldPointerSpaceAllocation())); // First update the size of the dominator allocate instruction. dominator_size = dominator_allocate->size(); int32_t original_object_size = HConstant::cast(dominator_size)->GetInteger32Constant(); int32_t dominator_size_constant = original_object_size; int32_t current_size_constant = HConstant::cast(current_size)->GetInteger32Constant(); int32_t new_dominator_size = dominator_size_constant + current_size_constant; if (MustAllocateDoubleAligned()) { if (!dominator_allocate->MustAllocateDoubleAligned()) { dominator_allocate->MakeDoubleAligned(); } if ((dominator_size_constant & kDoubleAlignmentMask) != 0) { dominator_size_constant += kDoubleSize / 2; new_dominator_size += kDoubleSize / 2; } } if (new_dominator_size > isolate()->heap()->MaxRegularSpaceAllocationSize()) { if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) cannot fold into #%d (%s) due to size: %d\n", id(), Mnemonic(), dominator_allocate->id(), dominator_allocate->Mnemonic(), new_dominator_size); } return; } HInstruction* new_dominator_size_constant = HConstant::CreateAndInsertBefore( zone, context(), new_dominator_size, Representation::None(), dominator_allocate); dominator_allocate->UpdateSize(new_dominator_size_constant); #ifdef VERIFY_HEAP if (FLAG_verify_heap && dominator_allocate->IsNewSpaceAllocation()) { dominator_allocate->MakePrefillWithFiller(); } else { // TODO(hpayer): This is a short-term hack to make allocation mementos // work again in new space. dominator_allocate->ClearNextMapWord(original_object_size); } #else // TODO(hpayer): This is a short-term hack to make allocation mementos // work again in new space. dominator_allocate->ClearNextMapWord(original_object_size); #endif dominator_allocate->clear_next_map_word_ = clear_next_map_word_; // After that replace the dominated allocate instruction. HInstruction* dominated_allocate_instr = HInnerAllocatedObject::New(zone, context(), dominator_allocate, dominator_size, type()); dominated_allocate_instr->InsertBefore(this); DeleteAndReplaceWith(dominated_allocate_instr); if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) folded into #%d (%s)\n", id(), Mnemonic(), dominator_allocate->id(), dominator_allocate->Mnemonic()); } } HAllocate* HAllocate::GetFoldableDominator(HAllocate* dominator) { if (!IsFoldable(dominator)) { // We cannot hoist old space allocations over new space allocations. if (IsNewSpaceAllocation() || dominator->IsNewSpaceAllocation()) { if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) cannot fold into #%d (%s), new space hoisting\n", id(), Mnemonic(), dominator->id(), dominator->Mnemonic()); } return NULL; } HAllocate* dominator_dominator = dominator->dominating_allocate_; // We can hoist old data space allocations over an old pointer space // allocation and vice versa. For that we have to check the dominator // of the dominator allocate instruction. if (dominator_dominator == NULL) { dominating_allocate_ = dominator; if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) cannot fold into #%d (%s), different spaces\n", id(), Mnemonic(), dominator->id(), dominator->Mnemonic()); } return NULL; } // We can just fold old space allocations that are in the same basic block, // since it is not guaranteed that we fill up the whole allocated old // space memory. // TODO(hpayer): Remove this limitation and add filler maps for each each // allocation as soon as we have store elimination. if (block()->block_id() != dominator_dominator->block()->block_id()) { if (FLAG_trace_allocation_folding) { PrintF("#%d (%s) cannot fold into #%d (%s), different basic blocks\n", id(), Mnemonic(), dominator_dominator->id(), dominator_dominator->Mnemonic()); } return NULL; } ASSERT((IsOldDataSpaceAllocation() && dominator_dominator->IsOldDataSpaceAllocation()) || (IsOldPointerSpaceAllocation() && dominator_dominator->IsOldPointerSpaceAllocation())); int32_t current_size = HConstant::cast(size())->GetInteger32Constant(); HStoreNamedField* dominator_free_space_size = dominator->filler_free_space_size_; if (dominator_free_space_size != NULL) { // We already hoisted one old space allocation, i.e., we already installed // a filler map. Hence, we just have to update the free space size. dominator->UpdateFreeSpaceFiller(current_size); } else { // This is the first old space allocation that gets hoisted. We have to // install a filler map since the follwing allocation may cause a GC. dominator->CreateFreeSpaceFiller(current_size); } // We can hoist the old space allocation over the actual dominator. return dominator_dominator; } return dominator; } void HAllocate::UpdateFreeSpaceFiller(int32_t free_space_size) { ASSERT(filler_free_space_size_ != NULL); Zone* zone = block()->zone(); // We must explicitly force Smi representation here because on x64 we // would otherwise automatically choose int32, but the actual store // requires a Smi-tagged value. HConstant* new_free_space_size = HConstant::CreateAndInsertBefore( zone, context(), filler_free_space_size_->value()->GetInteger32Constant() + free_space_size, Representation::Smi(), filler_free_space_size_); filler_free_space_size_->UpdateValue(new_free_space_size); } void HAllocate::CreateFreeSpaceFiller(int32_t free_space_size) { ASSERT(filler_free_space_size_ == NULL); Zone* zone = block()->zone(); HInstruction* free_space_instr = HInnerAllocatedObject::New(zone, context(), dominating_allocate_, dominating_allocate_->size(), type()); free_space_instr->InsertBefore(this); HConstant* filler_map = HConstant::New( zone, context(), isolate()->factory()->free_space_map()); filler_map->FinalizeUniqueness(); // TODO(titzer): should be init'd a'ready filler_map->InsertAfter(free_space_instr); HInstruction* store_map = HStoreNamedField::New(zone, context(), free_space_instr, HObjectAccess::ForMap(), filler_map); store_map->SetFlag(HValue::kHasNoObservableSideEffects); store_map->InsertAfter(filler_map); // We must explicitly force Smi representation here because on x64 we // would otherwise automatically choose int32, but the actual store // requires a Smi-tagged value. HConstant* filler_size = HConstant::CreateAndInsertAfter( zone, context(), free_space_size, Representation::Smi(), store_map); // Must force Smi representation for x64 (see comment above). HObjectAccess access = HObjectAccess::ForJSObjectOffset(FreeSpace::kSizeOffset, Representation::Smi()); HStoreNamedField* store_size = HStoreNamedField::New(zone, context(), free_space_instr, access, filler_size); store_size->SetFlag(HValue::kHasNoObservableSideEffects); store_size->InsertAfter(filler_size); filler_free_space_size_ = store_size; } void HAllocate::ClearNextMapWord(int offset) { if (clear_next_map_word_) { Zone* zone = block()->zone(); HObjectAccess access = HObjectAccess::ForJSObjectOffset(offset); HStoreNamedField* clear_next_map = HStoreNamedField::New(zone, context(), this, access, block()->graph()->GetConstantNull()); clear_next_map->ClearAllSideEffects(); clear_next_map->InsertAfter(this); } } void HAllocate::PrintDataTo(StringStream* stream) { size()->PrintNameTo(stream); stream->Add(" ("); if (IsNewSpaceAllocation()) stream->Add("N"); if (IsOldPointerSpaceAllocation()) stream->Add("P"); if (IsOldDataSpaceAllocation()) stream->Add("D"); if (MustAllocateDoubleAligned()) stream->Add("A"); if (MustPrefillWithFiller()) stream->Add("F"); stream->Add(")"); } HValue* HUnaryMathOperation::EnsureAndPropagateNotMinusZero( BitVector* visited) { visited->Add(id()); if (representation().IsSmiOrInteger32() && !value()->representation().Equals(representation())) { if (value()->range() == NULL || value()->range()->CanBeMinusZero()) { SetFlag(kBailoutOnMinusZero); } } if (RequiredInputRepresentation(0).IsSmiOrInteger32() && representation().Equals(RequiredInputRepresentation(0))) { return value(); } return NULL; } HValue* HChange::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); if (from().IsSmiOrInteger32()) return NULL; if (CanTruncateToInt32()) return NULL; if (value()->range() == NULL || value()->range()->CanBeMinusZero()) { SetFlag(kBailoutOnMinusZero); } ASSERT(!from().IsSmiOrInteger32() || !to().IsSmiOrInteger32()); return NULL; } HValue* HForceRepresentation::EnsureAndPropagateNotMinusZero( BitVector* visited) { visited->Add(id()); return value(); } HValue* HMod::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); if (range() == NULL || range()->CanBeMinusZero()) { SetFlag(kBailoutOnMinusZero); return left(); } return NULL; } HValue* HDiv::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); if (range() == NULL || range()->CanBeMinusZero()) { SetFlag(kBailoutOnMinusZero); } return NULL; } HValue* HMathFloorOfDiv::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); SetFlag(kBailoutOnMinusZero); return NULL; } HValue* HMul::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); if (range() == NULL || range()->CanBeMinusZero()) { SetFlag(kBailoutOnMinusZero); } return NULL; } HValue* HSub::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); // Propagate to the left argument. If the left argument cannot be -0, then // the result of the add operation cannot be either. if (range() == NULL || range()->CanBeMinusZero()) { return left(); } return NULL; } HValue* HAdd::EnsureAndPropagateNotMinusZero(BitVector* visited) { visited->Add(id()); // Propagate to the left argument. If the left argument cannot be -0, then // the result of the sub operation cannot be either. if (range() == NULL || range()->CanBeMinusZero()) { return left(); } return NULL; } bool HStoreKeyed::NeedsCanonicalization() { // If value is an integer or smi or comes from the result of a keyed load or // constant then it is either be a non-hole value or in the case of a constant // the hole is only being stored explicitly: no need for canonicalization. // // The exception to that is keyed loads from external float or double arrays: // these can load arbitrary representation of NaN. if (value()->IsConstant()) { return false; } if (value()->IsLoadKeyed()) { return IsExternalFloatOrDoubleElementsKind( HLoadKeyed::cast(value())->elements_kind()); } if (value()->IsChange()) { if (HChange::cast(value())->from().IsSmiOrInteger32()) { return false; } if (HChange::cast(value())->value()->type().IsSmi()) { return false; } } return true; } #define H_CONSTANT_INT(val) \ HConstant::New(zone, context, static_cast(val)) #define H_CONSTANT_DOUBLE(val) \ HConstant::New(zone, context, static_cast(val)) #define DEFINE_NEW_H_SIMPLE_ARITHMETIC_INSTR(HInstr, op) \ HInstruction* HInstr::New( \ Zone* zone, HValue* context, HValue* left, HValue* right) { \ if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { \ HConstant* c_left = HConstant::cast(left); \ HConstant* c_right = HConstant::cast(right); \ if ((c_left->HasNumberValue() && c_right->HasNumberValue())) { \ double double_res = c_left->DoubleValue() op c_right->DoubleValue(); \ if (TypeInfo::IsInt32Double(double_res)) { \ return H_CONSTANT_INT(double_res); \ } \ return H_CONSTANT_DOUBLE(double_res); \ } \ } \ return new(zone) HInstr(context, left, right); \ } DEFINE_NEW_H_SIMPLE_ARITHMETIC_INSTR(HAdd, +) DEFINE_NEW_H_SIMPLE_ARITHMETIC_INSTR(HMul, *) DEFINE_NEW_H_SIMPLE_ARITHMETIC_INSTR(HSub, -) #undef DEFINE_NEW_H_SIMPLE_ARITHMETIC_INSTR HInstruction* HStringAdd::New(Zone* zone, HValue* context, HValue* left, HValue* right, StringAddFlags flags) { if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_right = HConstant::cast(right); HConstant* c_left = HConstant::cast(left); if (c_left->HasStringValue() && c_right->HasStringValue()) { Handle concat = zone->isolate()->factory()->NewFlatConcatString( c_left->StringValue(), c_right->StringValue()); return HConstant::New(zone, context, concat); } } return new(zone) HStringAdd(context, left, right, flags); } HInstruction* HStringCharFromCode::New( Zone* zone, HValue* context, HValue* char_code) { if (FLAG_fold_constants && char_code->IsConstant()) { HConstant* c_code = HConstant::cast(char_code); Isolate* isolate = zone->isolate(); if (c_code->HasNumberValue()) { if (std::isfinite(c_code->DoubleValue())) { uint32_t code = c_code->NumberValueAsInteger32() & 0xffff; return HConstant::New(zone, context, LookupSingleCharacterStringFromCode(isolate, code)); } return HConstant::New(zone, context, isolate->factory()->empty_string()); } } return new(zone) HStringCharFromCode(context, char_code); } HInstruction* HUnaryMathOperation::New( Zone* zone, HValue* context, HValue* value, BuiltinFunctionId op) { do { if (!FLAG_fold_constants) break; if (!value->IsConstant()) break; HConstant* constant = HConstant::cast(value); if (!constant->HasNumberValue()) break; double d = constant->DoubleValue(); if (std::isnan(d)) { // NaN poisons everything. return H_CONSTANT_DOUBLE(OS::nan_value()); } if (std::isinf(d)) { // +Infinity and -Infinity. switch (op) { case kMathSin: case kMathCos: case kMathTan: return H_CONSTANT_DOUBLE(OS::nan_value()); case kMathExp: return H_CONSTANT_DOUBLE((d > 0.0) ? d : 0.0); case kMathLog: case kMathSqrt: return H_CONSTANT_DOUBLE((d > 0.0) ? d : OS::nan_value()); case kMathPowHalf: case kMathAbs: return H_CONSTANT_DOUBLE((d > 0.0) ? d : -d); case kMathRound: case kMathFloor: return H_CONSTANT_DOUBLE(d); default: UNREACHABLE(); break; } } switch (op) { case kMathSin: return H_CONSTANT_DOUBLE(fast_sin(d)); case kMathCos: return H_CONSTANT_DOUBLE(fast_cos(d)); case kMathTan: return H_CONSTANT_DOUBLE(fast_tan(d)); case kMathExp: return H_CONSTANT_DOUBLE(fast_exp(d)); case kMathLog: return H_CONSTANT_DOUBLE(fast_log(d)); case kMathSqrt: return H_CONSTANT_DOUBLE(fast_sqrt(d)); case kMathPowHalf: return H_CONSTANT_DOUBLE(power_double_double(d, 0.5)); case kMathAbs: return H_CONSTANT_DOUBLE((d >= 0.0) ? d + 0.0 : -d); case kMathRound: // -0.5 .. -0.0 round to -0.0. if ((d >= -0.5 && Double(d).Sign() < 0)) return H_CONSTANT_DOUBLE(-0.0); // Doubles are represented as Significant * 2 ^ Exponent. If the // Exponent is not negative, the double value is already an integer. if (Double(d).Exponent() >= 0) return H_CONSTANT_DOUBLE(d); return H_CONSTANT_DOUBLE(floor(d + 0.5)); case kMathFloor: return H_CONSTANT_DOUBLE(floor(d)); default: UNREACHABLE(); break; } } while (false); return new(zone) HUnaryMathOperation(context, value, op); } HInstruction* HPower::New(Zone* zone, HValue* context, HValue* left, HValue* right) { if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_left = HConstant::cast(left); HConstant* c_right = HConstant::cast(right); if (c_left->HasNumberValue() && c_right->HasNumberValue()) { double result = power_helper(c_left->DoubleValue(), c_right->DoubleValue()); return H_CONSTANT_DOUBLE(std::isnan(result) ? OS::nan_value() : result); } } return new(zone) HPower(left, right); } HInstruction* HMathMinMax::New( Zone* zone, HValue* context, HValue* left, HValue* right, Operation op) { if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_left = HConstant::cast(left); HConstant* c_right = HConstant::cast(right); if (c_left->HasNumberValue() && c_right->HasNumberValue()) { double d_left = c_left->DoubleValue(); double d_right = c_right->DoubleValue(); if (op == kMathMin) { if (d_left > d_right) return H_CONSTANT_DOUBLE(d_right); if (d_left < d_right) return H_CONSTANT_DOUBLE(d_left); if (d_left == d_right) { // Handle +0 and -0. return H_CONSTANT_DOUBLE((Double(d_left).Sign() == -1) ? d_left : d_right); } } else { if (d_left < d_right) return H_CONSTANT_DOUBLE(d_right); if (d_left > d_right) return H_CONSTANT_DOUBLE(d_left); if (d_left == d_right) { // Handle +0 and -0. return H_CONSTANT_DOUBLE((Double(d_left).Sign() == -1) ? d_right : d_left); } } // All comparisons failed, must be NaN. return H_CONSTANT_DOUBLE(OS::nan_value()); } } return new(zone) HMathMinMax(context, left, right, op); } HInstruction* HMod::New(Zone* zone, HValue* context, HValue* left, HValue* right) { if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_left = HConstant::cast(left); HConstant* c_right = HConstant::cast(right); if (c_left->HasInteger32Value() && c_right->HasInteger32Value()) { int32_t dividend = c_left->Integer32Value(); int32_t divisor = c_right->Integer32Value(); if (dividend == kMinInt && divisor == -1) { return H_CONSTANT_DOUBLE(-0.0); } if (divisor != 0) { int32_t res = dividend % divisor; if ((res == 0) && (dividend < 0)) { return H_CONSTANT_DOUBLE(-0.0); } return H_CONSTANT_INT(res); } } } return new(zone) HMod(context, left, right); } HInstruction* HDiv::New( Zone* zone, HValue* context, HValue* left, HValue* right) { // If left and right are constant values, try to return a constant value. if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_left = HConstant::cast(left); HConstant* c_right = HConstant::cast(right); if ((c_left->HasNumberValue() && c_right->HasNumberValue())) { if (c_right->DoubleValue() != 0) { double double_res = c_left->DoubleValue() / c_right->DoubleValue(); if (TypeInfo::IsInt32Double(double_res)) { return H_CONSTANT_INT(double_res); } return H_CONSTANT_DOUBLE(double_res); } else { int sign = Double(c_left->DoubleValue()).Sign() * Double(c_right->DoubleValue()).Sign(); // Right could be -0. return H_CONSTANT_DOUBLE(sign * V8_INFINITY); } } } return new(zone) HDiv(context, left, right); } HInstruction* HBitwise::New( Zone* zone, HValue* context, Token::Value op, HValue* left, HValue* right) { if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_left = HConstant::cast(left); HConstant* c_right = HConstant::cast(right); if ((c_left->HasNumberValue() && c_right->HasNumberValue())) { int32_t result; int32_t v_left = c_left->NumberValueAsInteger32(); int32_t v_right = c_right->NumberValueAsInteger32(); switch (op) { case Token::BIT_XOR: result = v_left ^ v_right; break; case Token::BIT_AND: result = v_left & v_right; break; case Token::BIT_OR: result = v_left | v_right; break; default: result = 0; // Please the compiler. UNREACHABLE(); } return H_CONSTANT_INT(result); } } return new(zone) HBitwise(context, op, left, right); } #define DEFINE_NEW_H_BITWISE_INSTR(HInstr, result) \ HInstruction* HInstr::New( \ Zone* zone, HValue* context, HValue* left, HValue* right) { \ if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { \ HConstant* c_left = HConstant::cast(left); \ HConstant* c_right = HConstant::cast(right); \ if ((c_left->HasNumberValue() && c_right->HasNumberValue())) { \ return H_CONSTANT_INT(result); \ } \ } \ return new(zone) HInstr(context, left, right); \ } DEFINE_NEW_H_BITWISE_INSTR(HSar, c_left->NumberValueAsInteger32() >> (c_right->NumberValueAsInteger32() & 0x1f)) DEFINE_NEW_H_BITWISE_INSTR(HShl, c_left->NumberValueAsInteger32() << (c_right->NumberValueAsInteger32() & 0x1f)) #undef DEFINE_NEW_H_BITWISE_INSTR HInstruction* HShr::New( Zone* zone, HValue* context, HValue* left, HValue* right) { if (FLAG_fold_constants && left->IsConstant() && right->IsConstant()) { HConstant* c_left = HConstant::cast(left); HConstant* c_right = HConstant::cast(right); if ((c_left->HasNumberValue() && c_right->HasNumberValue())) { int32_t left_val = c_left->NumberValueAsInteger32(); int32_t right_val = c_right->NumberValueAsInteger32() & 0x1f; if ((right_val == 0) && (left_val < 0)) { return H_CONSTANT_DOUBLE(static_cast(left_val)); } return H_CONSTANT_INT(static_cast(left_val) >> right_val); } } return new(zone) HShr(context, left, right); } HInstruction* HSeqStringGetChar::New(Zone* zone, HValue* context, String::Encoding encoding, HValue* string, HValue* index) { if (FLAG_fold_constants && string->IsConstant() && index->IsConstant()) { HConstant* c_string = HConstant::cast(string); HConstant* c_index = HConstant::cast(index); if (c_string->HasStringValue() && c_index->HasInteger32Value()) { Handle s = c_string->StringValue(); int32_t i = c_index->Integer32Value(); ASSERT_LE(0, i); ASSERT_LT(i, s->length()); return H_CONSTANT_INT(s->Get(i)); } } return new(zone) HSeqStringGetChar(encoding, string, index); } #undef H_CONSTANT_INT #undef H_CONSTANT_DOUBLE void HBitwise::PrintDataTo(StringStream* stream) { stream->Add(Token::Name(op_)); stream->Add(" "); HBitwiseBinaryOperation::PrintDataTo(stream); } void HPhi::SimplifyConstantInputs() { // Convert constant inputs to integers when all uses are truncating. // This must happen before representation inference takes place. if (!CheckUsesForFlag(kTruncatingToInt32)) return; for (int i = 0; i < OperandCount(); ++i) { if (!OperandAt(i)->IsConstant()) return; } HGraph* graph = block()->graph(); for (int i = 0; i < OperandCount(); ++i) { HConstant* operand = HConstant::cast(OperandAt(i)); if (operand->HasInteger32Value()) { continue; } else if (operand->HasDoubleValue()) { HConstant* integer_input = HConstant::New(graph->zone(), graph->GetInvalidContext(), DoubleToInt32(operand->DoubleValue())); integer_input->InsertAfter(operand); SetOperandAt(i, integer_input); } else if (operand->HasBooleanValue()) { SetOperandAt(i, operand->BooleanValue() ? graph->GetConstant1() : graph->GetConstant0()); } else if (operand->ImmortalImmovable()) { SetOperandAt(i, graph->GetConstant0()); } } // Overwrite observed input representations because they are likely Tagged. for (HUseIterator it(uses()); !it.Done(); it.Advance()) { HValue* use = it.value(); if (use->IsBinaryOperation()) { HBinaryOperation::cast(use)->set_observed_input_representation( it.index(), Representation::Smi()); } } } void HPhi::InferRepresentation(HInferRepresentationPhase* h_infer) { ASSERT(CheckFlag(kFlexibleRepresentation)); Representation new_rep = RepresentationFromInputs(); UpdateRepresentation(new_rep, h_infer, "inputs"); new_rep = RepresentationFromUses(); UpdateRepresentation(new_rep, h_infer, "uses"); new_rep = RepresentationFromUseRequirements(); UpdateRepresentation(new_rep, h_infer, "use requirements"); } Representation HPhi::RepresentationFromInputs() { Representation r = Representation::None(); for (int i = 0; i < OperandCount(); ++i) { r = r.generalize(OperandAt(i)->KnownOptimalRepresentation()); } return r; } // Returns a representation if all uses agree on the same representation. // Integer32 is also returned when some uses are Smi but others are Integer32. Representation HValue::RepresentationFromUseRequirements() { Representation rep = Representation::None(); for (HUseIterator it(uses()); !it.Done(); it.Advance()) { // Ignore the use requirement from never run code if (it.value()->block()->IsUnreachable()) continue; // We check for observed_input_representation elsewhere. Representation use_rep = it.value()->RequiredInputRepresentation(it.index()); if (rep.IsNone()) { rep = use_rep; continue; } if (use_rep.IsNone() || rep.Equals(use_rep)) continue; if (rep.generalize(use_rep).IsInteger32()) { rep = Representation::Integer32(); continue; } return Representation::None(); } return rep; } bool HValue::HasNonSmiUse() { for (HUseIterator it(uses()); !it.Done(); it.Advance()) { // We check for observed_input_representation elsewhere. Representation use_rep = it.value()->RequiredInputRepresentation(it.index()); if (!use_rep.IsNone() && !use_rep.IsSmi() && !use_rep.IsTagged()) { return true; } } return false; } // Node-specific verification code is only included in debug mode. #ifdef DEBUG void HPhi::Verify() { ASSERT(OperandCount() == block()->predecessors()->length()); for (int i = 0; i < OperandCount(); ++i) { HValue* value = OperandAt(i); HBasicBlock* defining_block = value->block(); HBasicBlock* predecessor_block = block()->predecessors()->at(i); ASSERT(defining_block == predecessor_block || defining_block->Dominates(predecessor_block)); } } void HSimulate::Verify() { HInstruction::Verify(); ASSERT(HasAstId()); } void HCheckHeapObject::Verify() { HInstruction::Verify(); ASSERT(HasNoUses()); } void HCheckValue::Verify() { HInstruction::Verify(); ASSERT(HasNoUses()); } #endif HObjectAccess HObjectAccess::ForFixedArrayHeader(int offset) { ASSERT(offset >= 0); ASSERT(offset < FixedArray::kHeaderSize); if (offset == FixedArray::kLengthOffset) return ForFixedArrayLength(); return HObjectAccess(kInobject, offset); } HObjectAccess HObjectAccess::ForJSObjectOffset(int offset, Representation representation) { ASSERT(offset >= 0); Portion portion = kInobject; if (offset == JSObject::kElementsOffset) { portion = kElementsPointer; } else if (offset == JSObject::kMapOffset) { portion = kMaps; } return HObjectAccess(portion, offset, representation); } HObjectAccess HObjectAccess::ForContextSlot(int index) { ASSERT(index >= 0); Portion portion = kInobject; int offset = Context::kHeaderSize + index * kPointerSize; ASSERT_EQ(offset, Context::SlotOffset(index) + kHeapObjectTag); return HObjectAccess(portion, offset, Representation::Tagged()); } HObjectAccess HObjectAccess::ForJSArrayOffset(int offset) { ASSERT(offset >= 0); Portion portion = kInobject; if (offset == JSObject::kElementsOffset) { portion = kElementsPointer; } else if (offset == JSArray::kLengthOffset) { portion = kArrayLengths; } else if (offset == JSObject::kMapOffset) { portion = kMaps; } return HObjectAccess(portion, offset); } HObjectAccess HObjectAccess::ForBackingStoreOffset(int offset, Representation representation) { ASSERT(offset >= 0); return HObjectAccess(kBackingStore, offset, representation); } HObjectAccess HObjectAccess::ForField(Handle map, LookupResult *lookup, Handle name) { ASSERT(lookup->IsField() || lookup->IsTransitionToField()); int index; Representation representation; if (lookup->IsField()) { index = lookup->GetLocalFieldIndexFromMap(*map); representation = lookup->representation(); } else { Map* transition = lookup->GetTransitionTarget(); int descriptor = transition->LastAdded(); index = transition->instance_descriptors()->GetFieldIndex(descriptor) - map->inobject_properties(); PropertyDetails details = transition->instance_descriptors()->GetDetails(descriptor); representation = details.representation(); } 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) + map->instance_size(); return HObjectAccess(kInobject, offset, representation); } else { // Non-negative property indices are in the properties array. int offset = (index * kPointerSize) + FixedArray::kHeaderSize; return HObjectAccess(kBackingStore, offset, representation, name); } } HObjectAccess HObjectAccess::ForCellPayload(Isolate* isolate) { return HObjectAccess( kInobject, Cell::kValueOffset, Representation::Tagged(), Handle(isolate->heap()->cell_value_string())); } void HObjectAccess::SetGVNFlags(HValue *instr, bool is_store) { // set the appropriate GVN flags for a given load or store instruction if (is_store) { // track dominating allocations in order to eliminate write barriers instr->SetGVNFlag(kDependsOnNewSpacePromotion); instr->SetFlag(HValue::kTrackSideEffectDominators); } else { // try to GVN loads, but don't hoist above map changes instr->SetFlag(HValue::kUseGVN); instr->SetGVNFlag(kDependsOnMaps); } switch (portion()) { case kArrayLengths: instr->SetGVNFlag(is_store ? kChangesArrayLengths : kDependsOnArrayLengths); break; case kStringLengths: instr->SetGVNFlag(is_store ? kChangesStringLengths : kDependsOnStringLengths); break; case kInobject: instr->SetGVNFlag(is_store ? kChangesInobjectFields : kDependsOnInobjectFields); break; case kDouble: instr->SetGVNFlag(is_store ? kChangesDoubleFields : kDependsOnDoubleFields); break; case kBackingStore: instr->SetGVNFlag(is_store ? kChangesBackingStoreFields : kDependsOnBackingStoreFields); break; case kElementsPointer: instr->SetGVNFlag(is_store ? kChangesElementsPointer : kDependsOnElementsPointer); break; case kMaps: instr->SetGVNFlag(is_store ? kChangesMaps : kDependsOnMaps); break; case kExternalMemory: instr->SetGVNFlag(is_store ? kChangesExternalMemory : kDependsOnExternalMemory); break; } } void HObjectAccess::PrintTo(StringStream* stream) { stream->Add("."); switch (portion()) { case kArrayLengths: case kStringLengths: stream->Add("%length"); break; case kElementsPointer: stream->Add("%elements"); break; case kMaps: stream->Add("%map"); break; case kDouble: // fall through case kInobject: if (!name_.is_null()) stream->Add(*String::cast(*name_)->ToCString()); stream->Add("[in-object]"); break; case kBackingStore: if (!name_.is_null()) stream->Add(*String::cast(*name_)->ToCString()); stream->Add("[backing-store]"); break; case kExternalMemory: stream->Add("[external-memory]"); break; } stream->Add("@%d", offset()); } } } // namespace v8::internal