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// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_COMPILER_GRAPH_ASSEMBLER_H_
#define V8_COMPILER_GRAPH_ASSEMBLER_H_
#include "src/compiler/js-graph.h"
#include "src/compiler/node.h"
#include "src/compiler/simplified-operator.h"
#include "src/compiler/vector-slot-pair.h"
namespace v8 {
namespace internal {
class JSGraph;
class Graph;
namespace compiler {
#define PURE_ASSEMBLER_MACH_UNOP_LIST(V) \
V(ChangeInt32ToInt64) \
V(ChangeInt32ToFloat64) \
V(ChangeInt64ToFloat64) \
V(ChangeUint32ToFloat64) \
V(ChangeUint32ToUint64) \
V(ChangeFloat64ToInt32) \
V(ChangeFloat64ToInt64) \
V(ChangeFloat64ToUint32) \
V(TruncateInt64ToInt32) \
V(RoundFloat64ToInt32) \
V(TruncateFloat64ToInt64) \
V(TruncateFloat64ToWord32) \
V(Float64ExtractLowWord32) \
V(Float64ExtractHighWord32) \
V(BitcastInt32ToFloat32) \
V(BitcastInt64ToFloat64) \
V(BitcastFloat32ToInt32) \
V(BitcastFloat64ToInt64) \
V(Float64Abs) \
V(Word32ReverseBytes) \
V(Word64ReverseBytes) \
V(Float64SilenceNaN) \
V(ChangeCompressedToTagged) \
V(ChangeTaggedToCompressed) \
V(ChangeTaggedSignedToCompressedSigned) \
V(ChangeCompressedSignedToTaggedSigned) \
V(ChangeTaggedPointerToCompressedPointer) \
V(ChangeCompressedPointerToTaggedPointer)
#define PURE_ASSEMBLER_MACH_BINOP_LIST(V) \
V(WordShl) \
V(WordSar) \
V(WordAnd) \
V(Word32Or) \
V(Word32And) \
V(Word32Xor) \
V(Word32Shr) \
V(Word32Shl) \
V(Word32Sar) \
V(Word64And) \
V(IntAdd) \
V(IntSub) \
V(IntMul) \
V(IntLessThan) \
V(UintLessThan) \
V(Int32Add) \
V(Int32Sub) \
V(Int32Mul) \
V(Int32LessThanOrEqual) \
V(Uint32LessThan) \
V(Uint32LessThanOrEqual) \
V(Uint64LessThan) \
V(Uint64LessThanOrEqual) \
V(Int32LessThan) \
V(Int64Sub) \
V(Float64Add) \
V(Float64Sub) \
V(Float64Div) \
V(Float64Mod) \
V(Float64Equal) \
V(Float64LessThan) \
V(Float64LessThanOrEqual) \
V(Float64InsertLowWord32) \
V(Float64InsertHighWord32) \
V(Word32Equal) \
V(Word64Equal) \
V(WordEqual)
#define CHECKED_ASSEMBLER_MACH_BINOP_LIST(V) \
V(Int32AddWithOverflow) \
V(Int32SubWithOverflow) \
V(Int32MulWithOverflow) \
V(Int32Mod) \
V(Int32Div) \
V(Uint32Mod) \
V(Uint32Div)
#define JSGRAPH_SINGLETON_CONSTANT_LIST(V) \
V(TrueConstant) \
V(FalseConstant) \
V(NullConstant) \
V(BigIntMapConstant) \
V(BooleanMapConstant) \
V(HeapNumberMapConstant) \
V(NoContextConstant) \
V(EmptyStringConstant) \
V(UndefinedConstant) \
V(TheHoleConstant) \
V(FixedArrayMapConstant) \
V(FixedDoubleArrayMapConstant) \
V(ToNumberBuiltinConstant) \
V(AllocateInYoungGenerationStubConstant) \
V(AllocateRegularInYoungGenerationStubConstant) \
V(AllocateInOldGenerationStubConstant) \
V(AllocateRegularInOldGenerationStubConstant)
class GraphAssembler;
enum class GraphAssemblerLabelType { kDeferred, kNonDeferred, kLoop };
// Label with statically known count of incoming branches and phis.
template <size_t VarCount>
class GraphAssemblerLabel {
public:
Node* PhiAt(size_t index);
template <typename... Reps>
explicit GraphAssemblerLabel(GraphAssemblerLabelType type, Reps... reps)
: type_(type) {
STATIC_ASSERT(VarCount == sizeof...(reps));
MachineRepresentation reps_array[] = {MachineRepresentation::kNone,
reps...};
for (size_t i = 0; i < VarCount; i++) {
representations_[i] = reps_array[i + 1];
}
}
~GraphAssemblerLabel() { DCHECK(IsBound() || merged_count_ == 0); }
private:
friend class GraphAssembler;
void SetBound() {
DCHECK(!IsBound());
is_bound_ = true;
}
bool IsBound() const { return is_bound_; }
bool IsDeferred() const {
return type_ == GraphAssemblerLabelType::kDeferred;
}
bool IsLoop() const { return type_ == GraphAssemblerLabelType::kLoop; }
bool is_bound_ = false;
GraphAssemblerLabelType const type_;
size_t merged_count_ = 0;
Node* effect_;
Node* control_;
Node* bindings_[VarCount + 1];
MachineRepresentation representations_[VarCount + 1];
};
class GraphAssembler {
public:
GraphAssembler(JSGraph* jsgraph, Node* effect, Node* control, Zone* zone);
void Reset(Node* effect, Node* control);
// Create label.
template <typename... Reps>
static GraphAssemblerLabel<sizeof...(Reps)> MakeLabelFor(
GraphAssemblerLabelType type, Reps... reps) {
return GraphAssemblerLabel<sizeof...(Reps)>(type, reps...);
}
// Convenience wrapper for creating non-deferred labels.
template <typename... Reps>
static GraphAssemblerLabel<sizeof...(Reps)> MakeLabel(Reps... reps) {
return MakeLabelFor(GraphAssemblerLabelType::kNonDeferred, reps...);
}
// Convenience wrapper for creating loop labels.
template <typename... Reps>
static GraphAssemblerLabel<sizeof...(Reps)> MakeLoopLabel(Reps... reps) {
return MakeLabelFor(GraphAssemblerLabelType::kLoop, reps...);
}
// Convenience wrapper for creating deferred labels.
template <typename... Reps>
static GraphAssemblerLabel<sizeof...(Reps)> MakeDeferredLabel(Reps... reps) {
return MakeLabelFor(GraphAssemblerLabelType::kDeferred, reps...);
}
// Value creation.
Node* IntPtrConstant(intptr_t value);
Node* Uint32Constant(int32_t value);
Node* Int32Constant(int32_t value);
Node* Int64Constant(int64_t value);
Node* UniqueIntPtrConstant(intptr_t value);
Node* SmiConstant(int32_t value);
Node* Float64Constant(double value);
Node* Projection(int index, Node* value);
Node* HeapConstant(Handle<HeapObject> object);
Node* NumberConstant(double value);
Node* CEntryStubConstant(int result_size);
Node* ExternalConstant(ExternalReference ref);
Node* LoadFramePointer();
#define SINGLETON_CONST_DECL(Name) Node* Name();
JSGRAPH_SINGLETON_CONSTANT_LIST(SINGLETON_CONST_DECL)
#undef SINGLETON_CONST_DECL
#define PURE_UNOP_DECL(Name) Node* Name(Node* input);
PURE_ASSEMBLER_MACH_UNOP_LIST(PURE_UNOP_DECL)
#undef PURE_UNOP_DECL
#define BINOP_DECL(Name) Node* Name(Node* left, Node* right);
PURE_ASSEMBLER_MACH_BINOP_LIST(BINOP_DECL)
CHECKED_ASSEMBLER_MACH_BINOP_LIST(BINOP_DECL)
#undef BINOP_DECL
// Debugging
Node* DebugBreak();
Node* Unreachable();
Node* Float64RoundDown(Node* value);
Node* Float64RoundTruncate(Node* value);
Node* ToNumber(Node* value);
Node* BitcastWordToTagged(Node* value);
Node* BitcastTaggedToWord(Node* value);
Node* BitcastTaggedSignedToWord(Node* value);
Node* Allocate(AllocationType allocation, Node* size);
Node* LoadField(FieldAccess const&, Node* object);
Node* LoadElement(ElementAccess const&, Node* object, Node* index);
Node* StoreField(FieldAccess const&, Node* object, Node* value);
Node* StoreElement(ElementAccess const&, Node* object, Node* index,
Node* value);
Node* Store(StoreRepresentation rep, Node* object, Node* offset, Node* value);
Node* Load(MachineType type, Node* object, Node* offset);
Node* StoreUnaligned(MachineRepresentation rep, Node* object, Node* offset,
Node* value);
Node* LoadUnaligned(MachineType type, Node* object, Node* offset);
Node* Retain(Node* buffer);
Node* UnsafePointerAdd(Node* base, Node* external);
Node* Word32PoisonOnSpeculation(Node* value);
Node* DeoptimizeIf(
DeoptimizeReason reason, VectorSlotPair const& feedback, Node* condition,
Node* frame_state,
IsSafetyCheck is_safety_check = IsSafetyCheck::kSafetyCheck);
Node* DeoptimizeIfNot(
DeoptimizeReason reason, VectorSlotPair const& feedback, Node* condition,
Node* frame_state,
IsSafetyCheck is_safety_check = IsSafetyCheck::kSafetyCheck);
template <typename... Args>
Node* Call(const CallDescriptor* call_descriptor, Args... args);
template <typename... Args>
Node* Call(const Operator* op, Args... args);
// Basic control operations.
template <size_t VarCount>
void Bind(GraphAssemblerLabel<VarCount>* label);
template <typename... Vars>
void Goto(GraphAssemblerLabel<sizeof...(Vars)>* label, Vars...);
void Branch(Node* condition, GraphAssemblerLabel<0u>* if_true,
GraphAssemblerLabel<0u>* if_false,
IsSafetyCheck is_safety_check = IsSafetyCheck::kNoSafetyCheck);
// Control helpers.
// {GotoIf(c, l)} is equivalent to {Branch(c, l, templ);Bind(templ)}.
template <typename... Vars>
void GotoIf(Node* condition, GraphAssemblerLabel<sizeof...(Vars)>* label,
Vars...);
// {GotoIfNot(c, l)} is equivalent to {Branch(c, templ, l);Bind(templ)}.
template <typename... Vars>
void GotoIfNot(Node* condition, GraphAssemblerLabel<sizeof...(Vars)>* label,
Vars...);
// Extractors (should be only used when destructing/resetting the assembler).
Node* ExtractCurrentControl();
Node* ExtractCurrentEffect();
private:
// Adds a decompression node if pointer compression is enabled and the
// representation loaded is a compressed one. To be used after loads.
Node* InsertDecompressionIfNeeded(MachineRepresentation rep, Node* value);
// Adds a compression node if pointer compression is enabled and the
// representation to be stored is a compressed one. To be used before stores.
Node* InsertCompressionIfNeeded(MachineRepresentation rep, Node* value);
template <typename... Vars>
void MergeState(GraphAssemblerLabel<sizeof...(Vars)>* label, Vars... vars);
Operator const* ToNumberOperator();
JSGraph* jsgraph() const { return jsgraph_; }
Isolate* isolate() const { return jsgraph_->isolate(); }
Graph* graph() const { return jsgraph_->graph(); }
Zone* temp_zone() const { return temp_zone_; }
CommonOperatorBuilder* common() const { return jsgraph()->common(); }
MachineOperatorBuilder* machine() const { return jsgraph()->machine(); }
SimplifiedOperatorBuilder* simplified() const {
return jsgraph()->simplified();
}
SetOncePointer<Operator const> to_number_operator_;
Zone* temp_zone_;
JSGraph* jsgraph_;
Node* current_effect_;
Node* current_control_;
};
template <size_t VarCount>
Node* GraphAssemblerLabel<VarCount>::PhiAt(size_t index) {
DCHECK(IsBound());
DCHECK_LT(index, VarCount);
return bindings_[index];
}
template <typename... Vars>
void GraphAssembler::MergeState(GraphAssemblerLabel<sizeof...(Vars)>* label,
Vars... vars) {
int merged_count = static_cast<int>(label->merged_count_);
Node* var_array[] = {nullptr, vars...};
if (label->IsLoop()) {
if (merged_count == 0) {
DCHECK(!label->IsBound());
label->control_ = graph()->NewNode(common()->Loop(2), current_control_,
current_control_);
label->effect_ = graph()->NewNode(common()->EffectPhi(2), current_effect_,
current_effect_, label->control_);
Node* terminate = graph()->NewNode(common()->Terminate(), label->effect_,
label->control_);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
for (size_t i = 0; i < sizeof...(vars); i++) {
label->bindings_[i] = graph()->NewNode(
common()->Phi(label->representations_[i], 2), var_array[i + 1],
var_array[i + 1], label->control_);
}
} else {
DCHECK(label->IsBound());
DCHECK_EQ(1, merged_count);
label->control_->ReplaceInput(1, current_control_);
label->effect_->ReplaceInput(1, current_effect_);
for (size_t i = 0; i < sizeof...(vars); i++) {
label->bindings_[i]->ReplaceInput(1, var_array[i + 1]);
}
}
} else {
DCHECK(!label->IsBound());
if (merged_count == 0) {
// Just set the control, effect and variables directly.
DCHECK(!label->IsBound());
label->control_ = current_control_;
label->effect_ = current_effect_;
for (size_t i = 0; i < sizeof...(vars); i++) {
label->bindings_[i] = var_array[i + 1];
}
} else if (merged_count == 1) {
// Create merge, effect phi and a phi for each variable.
label->control_ = graph()->NewNode(common()->Merge(2), label->control_,
current_control_);
label->effect_ = graph()->NewNode(common()->EffectPhi(2), label->effect_,
current_effect_, label->control_);
for (size_t i = 0; i < sizeof...(vars); i++) {
label->bindings_[i] = graph()->NewNode(
common()->Phi(label->representations_[i], 2), label->bindings_[i],
var_array[i + 1], label->control_);
}
} else {
// Append to the merge, effect phi and phis.
DCHECK_EQ(IrOpcode::kMerge, label->control_->opcode());
label->control_->AppendInput(graph()->zone(), current_control_);
NodeProperties::ChangeOp(label->control_,
common()->Merge(merged_count + 1));
DCHECK_EQ(IrOpcode::kEffectPhi, label->effect_->opcode());
label->effect_->ReplaceInput(merged_count, current_effect_);
label->effect_->AppendInput(graph()->zone(), label->control_);
NodeProperties::ChangeOp(label->effect_,
common()->EffectPhi(merged_count + 1));
for (size_t i = 0; i < sizeof...(vars); i++) {
DCHECK_EQ(IrOpcode::kPhi, label->bindings_[i]->opcode());
label->bindings_[i]->ReplaceInput(merged_count, var_array[i + 1]);
label->bindings_[i]->AppendInput(graph()->zone(), label->control_);
NodeProperties::ChangeOp(
label->bindings_[i],
common()->Phi(label->representations_[i], merged_count + 1));
}
}
}
label->merged_count_++;
}
template <size_t VarCount>
void GraphAssembler::Bind(GraphAssemblerLabel<VarCount>* label) {
DCHECK_NULL(current_control_);
DCHECK_NULL(current_effect_);
DCHECK_LT(0, label->merged_count_);
current_control_ = label->control_;
current_effect_ = label->effect_;
label->SetBound();
}
template <typename... Vars>
void GraphAssembler::Goto(GraphAssemblerLabel<sizeof...(Vars)>* label,
Vars... vars) {
DCHECK_NOT_NULL(current_control_);
DCHECK_NOT_NULL(current_effect_);
MergeState(label, vars...);
current_control_ = nullptr;
current_effect_ = nullptr;
}
template <typename... Vars>
void GraphAssembler::GotoIf(Node* condition,
GraphAssemblerLabel<sizeof...(Vars)>* label,
Vars... vars) {
BranchHint hint =
label->IsDeferred() ? BranchHint::kFalse : BranchHint::kNone;
Node* branch =
graph()->NewNode(common()->Branch(hint), condition, current_control_);
current_control_ = graph()->NewNode(common()->IfTrue(), branch);
MergeState(label, vars...);
current_control_ = graph()->NewNode(common()->IfFalse(), branch);
}
template <typename... Vars>
void GraphAssembler::GotoIfNot(Node* condition,
GraphAssemblerLabel<sizeof...(Vars)>* label,
Vars... vars) {
BranchHint hint = label->IsDeferred() ? BranchHint::kTrue : BranchHint::kNone;
Node* branch =
graph()->NewNode(common()->Branch(hint), condition, current_control_);
current_control_ = graph()->NewNode(common()->IfFalse(), branch);
MergeState(label, vars...);
current_control_ = graph()->NewNode(common()->IfTrue(), branch);
}
template <typename... Args>
Node* GraphAssembler::Call(const CallDescriptor* call_descriptor,
Args... args) {
const Operator* op = common()->Call(call_descriptor);
return Call(op, args...);
}
template <typename... Args>
Node* GraphAssembler::Call(const Operator* op, Args... args) {
DCHECK_EQ(IrOpcode::kCall, op->opcode());
Node* args_array[] = {args..., current_effect_, current_control_};
int size = static_cast<int>(sizeof...(args)) + op->EffectInputCount() +
op->ControlInputCount();
Node* call = graph()->NewNode(op, size, args_array);
DCHECK_EQ(0, op->ControlOutputCount());
current_effect_ = call;
return call;
}
} // namespace compiler
} // namespace internal
} // namespace v8
#endif // V8_COMPILER_GRAPH_ASSEMBLER_H_