| // 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_CODE_STUB_ASSEMBLER_H_ |
| #define V8_CODE_STUB_ASSEMBLER_H_ |
| |
| #include <functional> |
| |
| #include "src/compiler/code-assembler.h" |
| #include "src/globals.h" |
| #include "src/objects.h" |
| |
| namespace v8 { |
| namespace internal { |
| |
| class CallInterfaceDescriptor; |
| class CodeStubArguments; |
| class StatsCounter; |
| class StubCache; |
| |
| enum class PrimitiveType { kBoolean, kNumber, kString, kSymbol }; |
| |
| #define HEAP_CONSTANT_LIST(V) \ |
| V(AccessorInfoMap, AccessorInfoMap) \ |
| V(AccessorPairMap, AccessorPairMap) \ |
| V(AllocationSiteMap, AllocationSiteMap) \ |
| V(BooleanMap, BooleanMap) \ |
| V(CodeMap, CodeMap) \ |
| V(EmptyFixedArray, EmptyFixedArray) \ |
| V(empty_string, EmptyString) \ |
| V(EmptyWeakCell, EmptyWeakCell) \ |
| V(FalseValue, False) \ |
| V(FeedbackVectorMap, FeedbackVectorMap) \ |
| V(FixedArrayMap, FixedArrayMap) \ |
| V(FixedCOWArrayMap, FixedCOWArrayMap) \ |
| V(FixedDoubleArrayMap, FixedDoubleArrayMap) \ |
| V(FunctionTemplateInfoMap, FunctionTemplateInfoMap) \ |
| V(GlobalPropertyCellMap, PropertyCellMap) \ |
| V(has_instance_symbol, HasInstanceSymbol) \ |
| V(HeapNumberMap, HeapNumberMap) \ |
| V(length_string, LengthString) \ |
| V(ManyClosuresCellMap, ManyClosuresCellMap) \ |
| V(MetaMap, MetaMap) \ |
| V(MinusZeroValue, MinusZero) \ |
| V(MutableHeapNumberMap, MutableHeapNumberMap) \ |
| V(NanValue, Nan) \ |
| V(NoClosuresCellMap, NoClosuresCellMap) \ |
| V(NullValue, Null) \ |
| V(OneClosureCellMap, OneClosureCellMap) \ |
| V(prototype_string, PrototypeString) \ |
| V(SpeciesProtector, SpeciesProtector) \ |
| V(SymbolMap, SymbolMap) \ |
| V(TheHoleValue, TheHole) \ |
| V(TrueValue, True) \ |
| V(Tuple2Map, Tuple2Map) \ |
| V(Tuple3Map, Tuple3Map) \ |
| V(UndefinedValue, Undefined) \ |
| V(WeakCellMap, WeakCellMap) |
| |
| // Provides JavaScript-specific "macro-assembler" functionality on top of the |
| // CodeAssembler. By factoring the JavaScript-isms out of the CodeAssembler, |
| // it's possible to add JavaScript-specific useful CodeAssembler "macros" |
| // without modifying files in the compiler directory (and requiring a review |
| // from a compiler directory OWNER). |
| class V8_EXPORT_PRIVATE CodeStubAssembler : public compiler::CodeAssembler { |
| public: |
| typedef compiler::Node Node; |
| |
| CodeStubAssembler(compiler::CodeAssemblerState* state); |
| |
| enum AllocationFlag : uint8_t { |
| kNone = 0, |
| kDoubleAlignment = 1, |
| kPretenured = 1 << 1, |
| kAllowLargeObjectAllocation = 1 << 2, |
| }; |
| |
| typedef base::Flags<AllocationFlag> AllocationFlags; |
| |
| enum ParameterMode { SMI_PARAMETERS, INTPTR_PARAMETERS }; |
| // On 32-bit platforms, there is a slight performance advantage to doing all |
| // of the array offset/index arithmetic with SMIs, since it's possible |
| // to save a few tag/untag operations without paying an extra expense when |
| // calculating array offset (the smi math can be folded away) and there are |
| // fewer live ranges. Thus only convert indices to untagged value on 64-bit |
| // platforms. |
| ParameterMode OptimalParameterMode() const { |
| return Is64() ? INTPTR_PARAMETERS : SMI_PARAMETERS; |
| } |
| |
| MachineRepresentation ParameterRepresentation(ParameterMode mode) const { |
| return mode == INTPTR_PARAMETERS ? MachineType::PointerRepresentation() |
| : MachineRepresentation::kTaggedSigned; |
| } |
| |
| MachineRepresentation OptimalParameterRepresentation() const { |
| return ParameterRepresentation(OptimalParameterMode()); |
| } |
| |
| Node* ParameterToWord(Node* value, ParameterMode mode) { |
| if (mode == SMI_PARAMETERS) value = SmiUntag(value); |
| return value; |
| } |
| |
| Node* WordToParameter(Node* value, ParameterMode mode) { |
| if (mode == SMI_PARAMETERS) value = SmiTag(value); |
| return value; |
| } |
| |
| Node* Word32ToParameter(Node* value, ParameterMode mode) { |
| return WordToParameter(ChangeUint32ToWord(value), mode); |
| } |
| |
| Node* ParameterToTagged(Node* value, ParameterMode mode) { |
| if (mode != SMI_PARAMETERS) value = SmiTag(value); |
| return value; |
| } |
| |
| Node* TaggedToParameter(Node* value, ParameterMode mode) { |
| if (mode != SMI_PARAMETERS) value = SmiUntag(value); |
| return value; |
| } |
| |
| Node* MatchesParameterMode(Node* value, ParameterMode mode); |
| |
| #define PARAMETER_BINOP(OpName, IntPtrOpName, SmiOpName) \ |
| Node* OpName(Node* a, Node* b, ParameterMode mode) { \ |
| if (mode == SMI_PARAMETERS) { \ |
| return SmiOpName(a, b); \ |
| } else { \ |
| DCHECK_EQ(INTPTR_PARAMETERS, mode); \ |
| return IntPtrOpName(a, b); \ |
| } \ |
| } |
| PARAMETER_BINOP(IntPtrOrSmiMin, IntPtrMin, SmiMin) |
| PARAMETER_BINOP(IntPtrOrSmiAdd, IntPtrAdd, SmiAdd) |
| PARAMETER_BINOP(IntPtrOrSmiSub, IntPtrSub, SmiSub) |
| PARAMETER_BINOP(IntPtrOrSmiLessThan, IntPtrLessThan, SmiLessThan) |
| PARAMETER_BINOP(IntPtrOrSmiLessThanOrEqual, IntPtrLessThanOrEqual, |
| SmiLessThanOrEqual) |
| PARAMETER_BINOP(IntPtrOrSmiGreaterThan, IntPtrGreaterThan, SmiGreaterThan) |
| PARAMETER_BINOP(IntPtrOrSmiGreaterThanOrEqual, IntPtrGreaterThanOrEqual, |
| SmiGreaterThanOrEqual) |
| PARAMETER_BINOP(UintPtrOrSmiLessThan, UintPtrLessThan, SmiBelow) |
| PARAMETER_BINOP(UintPtrOrSmiGreaterThanOrEqual, UintPtrGreaterThanOrEqual, |
| SmiAboveOrEqual) |
| #undef PARAMETER_BINOP |
| |
| Node* NoContextConstant(); |
| #define HEAP_CONSTANT_ACCESSOR(rootName, name) Node* name##Constant(); |
| HEAP_CONSTANT_LIST(HEAP_CONSTANT_ACCESSOR) |
| #undef HEAP_CONSTANT_ACCESSOR |
| |
| #define HEAP_CONSTANT_TEST(rootName, name) \ |
| Node* Is##name(Node* value); \ |
| Node* IsNot##name(Node* value); |
| HEAP_CONSTANT_LIST(HEAP_CONSTANT_TEST) |
| #undef HEAP_CONSTANT_TEST |
| |
| Node* HashSeed(); |
| Node* StaleRegisterConstant(); |
| |
| Node* IntPtrOrSmiConstant(int value, ParameterMode mode); |
| |
| bool IsIntPtrOrSmiConstantZero(Node* test); |
| |
| // Round the 32bits payload of the provided word up to the next power of two. |
| Node* IntPtrRoundUpToPowerOfTwo32(Node* value); |
| // Select the maximum of the two provided IntPtr values. |
| Node* IntPtrMax(Node* left, Node* right); |
| // Select the minimum of the two provided IntPtr values. |
| Node* IntPtrMin(Node* left, Node* right); |
| |
| // Float64 operations. |
| Node* Float64Ceil(Node* x); |
| Node* Float64Floor(Node* x); |
| Node* Float64Round(Node* x); |
| Node* Float64RoundToEven(Node* x); |
| Node* Float64Trunc(Node* x); |
| |
| // Tag a Word as a Smi value. |
| Node* SmiTag(Node* value); |
| // Untag a Smi value as a Word. |
| Node* SmiUntag(Node* value); |
| |
| // Smi conversions. |
| Node* SmiToFloat64(Node* value); |
| Node* SmiFromWord(Node* value) { return SmiTag(value); } |
| Node* SmiFromWord32(Node* value); |
| Node* SmiToWord(Node* value) { return SmiUntag(value); } |
| Node* SmiToWord32(Node* value); |
| |
| // Smi operations. |
| #define SMI_ARITHMETIC_BINOP(SmiOpName, IntPtrOpName) \ |
| Node* SmiOpName(Node* a, Node* b) { \ |
| return BitcastWordToTaggedSigned( \ |
| IntPtrOpName(BitcastTaggedToWord(a), BitcastTaggedToWord(b))); \ |
| } |
| SMI_ARITHMETIC_BINOP(SmiAdd, IntPtrAdd) |
| SMI_ARITHMETIC_BINOP(SmiSub, IntPtrSub) |
| SMI_ARITHMETIC_BINOP(SmiAnd, WordAnd) |
| SMI_ARITHMETIC_BINOP(SmiOr, WordOr) |
| #undef SMI_ARITHMETIC_BINOP |
| |
| Node* SmiShl(Node* a, int shift) { |
| return BitcastWordToTaggedSigned(WordShl(BitcastTaggedToWord(a), shift)); |
| } |
| |
| Node* SmiShr(Node* a, int shift) { |
| return BitcastWordToTaggedSigned( |
| WordAnd(WordShr(BitcastTaggedToWord(a), shift), |
| BitcastTaggedToWord(SmiConstant(-1)))); |
| } |
| |
| Node* WordOrSmiShl(Node* a, int shift, ParameterMode mode) { |
| if (mode == SMI_PARAMETERS) { |
| return SmiShl(a, shift); |
| } else { |
| DCHECK_EQ(INTPTR_PARAMETERS, mode); |
| return WordShl(a, shift); |
| } |
| } |
| |
| Node* WordOrSmiShr(Node* a, int shift, ParameterMode mode) { |
| if (mode == SMI_PARAMETERS) { |
| return SmiShr(a, shift); |
| } else { |
| DCHECK_EQ(INTPTR_PARAMETERS, mode); |
| return WordShr(a, shift); |
| } |
| } |
| |
| #define SMI_COMPARISON_OP(SmiOpName, IntPtrOpName) \ |
| Node* SmiOpName(Node* a, Node* b) { \ |
| return IntPtrOpName(BitcastTaggedToWord(a), BitcastTaggedToWord(b)); \ |
| } |
| SMI_COMPARISON_OP(SmiEqual, WordEqual) |
| SMI_COMPARISON_OP(SmiNotEqual, WordNotEqual) |
| SMI_COMPARISON_OP(SmiAbove, UintPtrGreaterThan) |
| SMI_COMPARISON_OP(SmiAboveOrEqual, UintPtrGreaterThanOrEqual) |
| SMI_COMPARISON_OP(SmiBelow, UintPtrLessThan) |
| SMI_COMPARISON_OP(SmiLessThan, IntPtrLessThan) |
| SMI_COMPARISON_OP(SmiLessThanOrEqual, IntPtrLessThanOrEqual) |
| SMI_COMPARISON_OP(SmiGreaterThan, IntPtrGreaterThan) |
| SMI_COMPARISON_OP(SmiGreaterThanOrEqual, IntPtrGreaterThanOrEqual) |
| #undef SMI_COMPARISON_OP |
| Node* SmiMax(Node* a, Node* b); |
| Node* SmiMin(Node* a, Node* b); |
| // Computes a % b for Smi inputs a and b; result is not necessarily a Smi. |
| Node* SmiMod(Node* a, Node* b); |
| // Computes a * b for Smi inputs a and b; result is not necessarily a Smi. |
| Node* SmiMul(Node* a, Node* b); |
| // Tries to computes dividend / divisor for Smi inputs; branching to bailout |
| // if the division needs to be performed as a floating point operation. |
| Node* TrySmiDiv(Node* dividend, Node* divisor, Label* bailout); |
| |
| // Smi | HeapNumber operations. |
| Node* NumberInc(Node* value); |
| Node* NumberDec(Node* value); |
| void GotoIfNotNumber(Node* value, Label* is_not_number); |
| void GotoIfNumber(Node* value, Label* is_number); |
| |
| // Allocate an object of the given size. |
| Node* AllocateInNewSpace(Node* size, AllocationFlags flags = kNone); |
| Node* AllocateInNewSpace(int size, AllocationFlags flags = kNone); |
| Node* Allocate(Node* size, AllocationFlags flags = kNone); |
| Node* Allocate(int size, AllocationFlags flags = kNone); |
| Node* InnerAllocate(Node* previous, int offset); |
| Node* InnerAllocate(Node* previous, Node* offset); |
| Node* IsRegularHeapObjectSize(Node* size); |
| |
| typedef std::function<Node*()> NodeGenerator; |
| |
| void Assert(const NodeGenerator& condition_body, const char* string = nullptr, |
| const char* file = nullptr, int line = 0); |
| void Check(const NodeGenerator& condition_body, const char* string = nullptr, |
| const char* file = nullptr, int line = 0); |
| |
| Node* Select(Node* condition, const NodeGenerator& true_body, |
| const NodeGenerator& false_body, MachineRepresentation rep); |
| |
| Node* SelectConstant(Node* condition, Node* true_value, Node* false_value, |
| MachineRepresentation rep); |
| |
| Node* SelectInt32Constant(Node* condition, int true_value, int false_value); |
| Node* SelectIntPtrConstant(Node* condition, int true_value, int false_value); |
| Node* SelectBooleanConstant(Node* condition); |
| Node* SelectTaggedConstant(Node* condition, Node* true_value, |
| Node* false_value); |
| Node* SelectSmiConstant(Node* condition, Smi* true_value, Smi* false_value); |
| Node* SelectSmiConstant(Node* condition, int true_value, Smi* false_value) { |
| return SelectSmiConstant(condition, Smi::FromInt(true_value), false_value); |
| } |
| Node* SelectSmiConstant(Node* condition, Smi* true_value, int false_value) { |
| return SelectSmiConstant(condition, true_value, Smi::FromInt(false_value)); |
| } |
| Node* SelectSmiConstant(Node* condition, int true_value, int false_value) { |
| return SelectSmiConstant(condition, Smi::FromInt(true_value), |
| Smi::FromInt(false_value)); |
| } |
| |
| Node* TruncateWordToWord32(Node* value); |
| |
| // Check a value for smi-ness |
| Node* TaggedIsSmi(Node* a); |
| Node* TaggedIsNotSmi(Node* a); |
| // Check that the value is a non-negative smi. |
| Node* TaggedIsPositiveSmi(Node* a); |
| // Check that a word has a word-aligned address. |
| Node* WordIsWordAligned(Node* word); |
| Node* WordIsPowerOfTwo(Node* value); |
| |
| #if DEBUG |
| void Bind(Label* label, AssemblerDebugInfo debug_info); |
| #else |
| void Bind(Label* label); |
| #endif // DEBUG |
| |
| void BranchIfSmiEqual(Node* a, Node* b, Label* if_true, Label* if_false) { |
| Branch(SmiEqual(a, b), if_true, if_false); |
| } |
| |
| void BranchIfSmiLessThan(Node* a, Node* b, Label* if_true, Label* if_false) { |
| Branch(SmiLessThan(a, b), if_true, if_false); |
| } |
| |
| void BranchIfSmiLessThanOrEqual(Node* a, Node* b, Label* if_true, |
| Label* if_false) { |
| Branch(SmiLessThanOrEqual(a, b), if_true, if_false); |
| } |
| |
| void BranchIfFloat64IsNaN(Node* value, Label* if_true, Label* if_false) { |
| Branch(Float64Equal(value, value), if_false, if_true); |
| } |
| |
| // Branches to {if_true} if ToBoolean applied to {value} yields true, |
| // otherwise goes to {if_false}. |
| void BranchIfToBooleanIsTrue(Node* value, Label* if_true, Label* if_false); |
| |
| void BranchIfJSReceiver(Node* object, Label* if_true, Label* if_false); |
| void BranchIfJSObject(Node* object, Label* if_true, Label* if_false); |
| |
| enum class FastJSArrayAccessMode { INBOUNDS_READ, ANY_ACCESS }; |
| void BranchIfFastJSArray(Node* object, Node* context, |
| FastJSArrayAccessMode mode, Label* if_true, |
| Label* if_false); |
| |
| // Load value from current frame by given offset in bytes. |
| Node* LoadFromFrame(int offset, MachineType rep = MachineType::AnyTagged()); |
| // Load value from current parent frame by given offset in bytes. |
| Node* LoadFromParentFrame(int offset, |
| MachineType rep = MachineType::AnyTagged()); |
| |
| // Load an object pointer from a buffer that isn't in the heap. |
| Node* LoadBufferObject(Node* buffer, int offset, |
| MachineType rep = MachineType::AnyTagged()); |
| // Load a field from an object on the heap. |
| Node* LoadObjectField(Node* object, int offset, |
| MachineType rep = MachineType::AnyTagged()); |
| Node* LoadObjectField(Node* object, Node* offset, |
| MachineType rep = MachineType::AnyTagged()); |
| // Load a SMI field and untag it. |
| Node* LoadAndUntagObjectField(Node* object, int offset); |
| // Load a SMI field, untag it, and convert to Word32. |
| Node* LoadAndUntagToWord32ObjectField(Node* object, int offset); |
| // Load a SMI and untag it. |
| Node* LoadAndUntagSmi(Node* base, int index); |
| // Load a SMI root, untag it, and convert to Word32. |
| Node* LoadAndUntagToWord32Root(Heap::RootListIndex root_index); |
| |
| // Tag a smi and store it. |
| Node* StoreAndTagSmi(Node* base, int offset, Node* value); |
| |
| // Load the floating point value of a HeapNumber. |
| Node* LoadHeapNumberValue(Node* object); |
| // Load the Map of an HeapObject. |
| Node* LoadMap(Node* object); |
| // Load the instance type of an HeapObject. |
| Node* LoadInstanceType(Node* object); |
| // Compare the instance the type of the object against the provided one. |
| Node* HasInstanceType(Node* object, InstanceType type); |
| Node* DoesntHaveInstanceType(Node* object, InstanceType type); |
| // Load the properties backing store of a JSObject. |
| Node* LoadProperties(Node* object); |
| // Load the elements backing store of a JSObject. |
| Node* LoadElements(Node* object); |
| // Load the length of a JSArray instance. |
| Node* LoadJSArrayLength(Node* array); |
| // Load the length of a fixed array base instance. |
| Node* LoadFixedArrayBaseLength(Node* array); |
| // Load the length of a fixed array base instance. |
| Node* LoadAndUntagFixedArrayBaseLength(Node* array); |
| // Load the bit field of a Map. |
| Node* LoadMapBitField(Node* map); |
| // Load bit field 2 of a map. |
| Node* LoadMapBitField2(Node* map); |
| // Load bit field 3 of a map. |
| Node* LoadMapBitField3(Node* map); |
| // Load the instance type of a map. |
| Node* LoadMapInstanceType(Node* map); |
| // Load the ElementsKind of a map. |
| Node* LoadMapElementsKind(Node* map); |
| // Load the instance descriptors of a map. |
| Node* LoadMapDescriptors(Node* map); |
| // Load the prototype of a map. |
| Node* LoadMapPrototype(Node* map); |
| // Load the prototype info of a map. The result has to be checked if it is a |
| // prototype info object or not. |
| Node* LoadMapPrototypeInfo(Node* map, Label* if_has_no_proto_info); |
| // Load the instance size of a Map. |
| Node* LoadMapInstanceSize(Node* map); |
| // Load the inobject properties count of a Map (valid only for JSObjects). |
| Node* LoadMapInobjectProperties(Node* map); |
| // Load the constructor function index of a Map (only for primitive maps). |
| Node* LoadMapConstructorFunctionIndex(Node* map); |
| // Load the constructor of a Map (equivalent to |
| // Map::GetConstructor()). |
| Node* LoadMapConstructor(Node* map); |
| |
| // Check if the map is set for slow properties. |
| Node* IsDictionaryMap(Node* map); |
| |
| // Load the hash field of a name as an uint32 value. |
| Node* LoadNameHashField(Node* name); |
| // Load the hash value of a name as an uint32 value. |
| // If {if_hash_not_computed} label is specified then it also checks if |
| // hash is actually computed. |
| Node* LoadNameHash(Node* name, Label* if_hash_not_computed = nullptr); |
| |
| // Load length field of a String object. |
| Node* LoadStringLength(Node* object); |
| // Loads a pointer to the sequential String char array. |
| Node* PointerToSeqStringData(Node* seq_string); |
| // Load value field of a JSValue object. |
| Node* LoadJSValueValue(Node* object); |
| // Load value field of a WeakCell object. |
| Node* LoadWeakCellValueUnchecked(Node* weak_cell); |
| Node* LoadWeakCellValue(Node* weak_cell, Label* if_cleared = nullptr); |
| |
| // Get the offset of an element in a fixed array. |
| Node* GetFixedArrayElementOffset( |
| Node* index_node, int additional_offset = 0, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| |
| // Load an array element from a FixedArray. |
| Node* LoadFixedArrayElement(Node* object, Node* index, |
| int additional_offset = 0, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| Node* LoadFixedArrayElement(Node* object, int index, |
| int additional_offset = 0) { |
| return LoadFixedArrayElement(object, IntPtrConstant(index), |
| additional_offset); |
| } |
| // Load an array element from a FixedArray, untag it and return it as Word32. |
| Node* LoadAndUntagToWord32FixedArrayElement( |
| Node* object, Node* index, int additional_offset = 0, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| // Load an array element from a FixedDoubleArray. |
| Node* LoadFixedDoubleArrayElement( |
| Node* object, Node* index, MachineType machine_type, |
| int additional_offset = 0, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS, |
| Label* if_hole = nullptr); |
| |
| // Load Float64 value by |base| + |offset| address. If the value is a double |
| // hole then jump to |if_hole|. If |machine_type| is None then only the hole |
| // check is generated. |
| Node* LoadDoubleWithHoleCheck( |
| Node* base, Node* offset, Label* if_hole, |
| MachineType machine_type = MachineType::Float64()); |
| Node* LoadFixedTypedArrayElement( |
| Node* data_pointer, Node* index_node, ElementsKind elements_kind, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| Node* LoadFixedTypedArrayElementAsTagged( |
| Node* data_pointer, Node* index_node, ElementsKind elements_kind, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| |
| // Context manipulation |
| Node* LoadContextElement(Node* context, int slot_index); |
| Node* LoadContextElement(Node* context, Node* slot_index); |
| Node* StoreContextElement(Node* context, int slot_index, Node* value); |
| Node* StoreContextElement(Node* context, Node* slot_index, Node* value); |
| Node* StoreContextElementNoWriteBarrier(Node* context, int slot_index, |
| Node* value); |
| Node* LoadNativeContext(Node* context); |
| |
| Node* LoadJSArrayElementsMap(ElementsKind kind, Node* native_context); |
| |
| // Load the "prototype" property of a JSFunction. |
| Node* LoadJSFunctionPrototype(Node* function, Label* if_bailout); |
| |
| // Store the floating point value of a HeapNumber. |
| Node* StoreHeapNumberValue(Node* object, Node* value); |
| // Store a field to an object on the heap. |
| Node* StoreObjectField(Node* object, int offset, Node* value); |
| Node* StoreObjectField(Node* object, Node* offset, Node* value); |
| Node* StoreObjectFieldNoWriteBarrier( |
| Node* object, int offset, Node* value, |
| MachineRepresentation rep = MachineRepresentation::kTagged); |
| Node* StoreObjectFieldNoWriteBarrier( |
| Node* object, Node* offset, Node* value, |
| MachineRepresentation rep = MachineRepresentation::kTagged); |
| // Store the Map of an HeapObject. |
| Node* StoreMap(Node* object, Node* map); |
| Node* StoreMapNoWriteBarrier(Node* object, |
| Heap::RootListIndex map_root_index); |
| Node* StoreMapNoWriteBarrier(Node* object, Node* map); |
| Node* StoreObjectFieldRoot(Node* object, int offset, |
| Heap::RootListIndex root); |
| // Store an array element to a FixedArray. |
| Node* StoreFixedArrayElement( |
| Node* object, int index, Node* value, |
| WriteBarrierMode barrier_mode = UPDATE_WRITE_BARRIER) { |
| return StoreFixedArrayElement(object, IntPtrConstant(index), value, |
| barrier_mode); |
| } |
| |
| Node* StoreFixedArrayElement( |
| Node* object, Node* index, Node* value, |
| WriteBarrierMode barrier_mode = UPDATE_WRITE_BARRIER, |
| int additional_offset = 0, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| |
| Node* StoreFixedDoubleArrayElement( |
| Node* object, Node* index, Node* value, |
| ParameterMode parameter_mode = INTPTR_PARAMETERS); |
| |
| void EnsureArrayLengthWritable(Node* map, Label* bailout); |
| |
| // EnsureArrayPushable verifies that receiver is: |
| // 1. Is not a prototype. |
| // 2. Is not a dictionary. |
| // 3. Has a writeable length property. |
| // It returns ElementsKind as a node for further division into cases. |
| Node* EnsureArrayPushable(Node* receiver, Label* bailout); |
| |
| void TryStoreArrayElement(ElementsKind kind, ParameterMode mode, |
| Label* bailout, Node* elements, Node* index, |
| Node* value); |
| // Consumes args into the array, and returns tagged new length. |
| Node* BuildAppendJSArray(ElementsKind kind, Node* array, |
| CodeStubArguments& args, Variable& arg_index, |
| Label* bailout); |
| // Pushes value onto the end of array. |
| void BuildAppendJSArray(ElementsKind kind, Node* array, Node* value, |
| Label* bailout); |
| |
| void StoreFieldsNoWriteBarrier(Node* start_address, Node* end_address, |
| Node* value); |
| |
| Node* AllocateCellWithValue(Node* value, |
| WriteBarrierMode mode = UPDATE_WRITE_BARRIER); |
| Node* AllocateSmiCell(int value = 0) { |
| return AllocateCellWithValue(SmiConstant(value), SKIP_WRITE_BARRIER); |
| } |
| |
| Node* LoadCellValue(Node* cell); |
| |
| Node* StoreCellValue(Node* cell, Node* value, |
| WriteBarrierMode mode = UPDATE_WRITE_BARRIER); |
| |
| // Allocate a HeapNumber without initializing its value. |
| Node* AllocateHeapNumber(MutableMode mode = IMMUTABLE); |
| // Allocate a HeapNumber with a specific value. |
| Node* AllocateHeapNumberWithValue(Node* value, MutableMode mode = IMMUTABLE); |
| // Allocate a SeqOneByteString with the given length. |
| Node* AllocateSeqOneByteString(int length, AllocationFlags flags = kNone); |
| Node* AllocateSeqOneByteString(Node* context, Node* length, |
| ParameterMode mode = INTPTR_PARAMETERS, |
| AllocationFlags flags = kNone); |
| // Allocate a SeqTwoByteString with the given length. |
| Node* AllocateSeqTwoByteString(int length, AllocationFlags flags = kNone); |
| Node* AllocateSeqTwoByteString(Node* context, Node* length, |
| ParameterMode mode = INTPTR_PARAMETERS, |
| AllocationFlags flags = kNone); |
| |
| // Allocate a SlicedOneByteString with the given length, parent and offset. |
| // |length| and |offset| are expected to be tagged. |
| Node* AllocateSlicedOneByteString(Node* length, Node* parent, Node* offset); |
| // Allocate a SlicedTwoByteString with the given length, parent and offset. |
| // |length| and |offset| are expected to be tagged. |
| Node* AllocateSlicedTwoByteString(Node* length, Node* parent, Node* offset); |
| |
| // Allocate a one-byte ConsString with the given length, first and second |
| // parts. |length| is expected to be tagged, and |first| and |second| are |
| // expected to be one-byte strings. |
| Node* AllocateOneByteConsString(Node* length, Node* first, Node* second, |
| AllocationFlags flags = kNone); |
| // Allocate a two-byte ConsString with the given length, first and second |
| // parts. |length| is expected to be tagged, and |first| and |second| are |
| // expected to be two-byte strings. |
| Node* AllocateTwoByteConsString(Node* length, Node* first, Node* second, |
| AllocationFlags flags = kNone); |
| |
| // Allocate an appropriate one- or two-byte ConsString with the first and |
| // second parts specified by |first| and |second|. |
| Node* NewConsString(Node* context, Node* length, Node* left, Node* right, |
| AllocationFlags flags = kNone); |
| |
| // Allocate a RegExpResult with the given length (the number of captures, |
| // including the match itself), index (the index where the match starts), |
| // and input string. |length| and |index| are expected to be tagged, and |
| // |input| must be a string. |
| Node* AllocateRegExpResult(Node* context, Node* length, Node* index, |
| Node* input); |
| |
| Node* AllocateNameDictionary(int at_least_space_for); |
| Node* AllocateNameDictionary(Node* at_least_space_for); |
| Node* AllocateNameDictionaryWithCapacity(Node* capacity); |
| Node* CopyNameDictionary(Node* dictionary, Label* large_object_fallback); |
| |
| Node* AllocateJSObjectFromMap(Node* map, Node* properties = nullptr, |
| Node* elements = nullptr, |
| AllocationFlags flags = kNone); |
| |
| void InitializeJSObjectFromMap(Node* object, Node* map, Node* size, |
| Node* properties = nullptr, |
| Node* elements = nullptr); |
| |
| void InitializeJSObjectBody(Node* object, Node* map, Node* size, |
| int start_offset = JSObject::kHeaderSize); |
| |
| // Allocate a JSArray without elements and initialize the header fields. |
| Node* AllocateUninitializedJSArrayWithoutElements(ElementsKind kind, |
| Node* array_map, |
| Node* length, |
| Node* allocation_site); |
| // Allocate and return a JSArray with initialized header fields and its |
| // uninitialized elements. |
| // The ParameterMode argument is only used for the capacity parameter. |
| std::pair<Node*, Node*> AllocateUninitializedJSArrayWithElements( |
| ElementsKind kind, Node* array_map, Node* length, Node* allocation_site, |
| Node* capacity, ParameterMode capacity_mode = INTPTR_PARAMETERS); |
| // Allocate a JSArray and fill elements with the hole. |
| // The ParameterMode argument is only used for the capacity parameter. |
| Node* AllocateJSArray(ElementsKind kind, Node* array_map, Node* capacity, |
| Node* length, Node* allocation_site = nullptr, |
| ParameterMode capacity_mode = INTPTR_PARAMETERS); |
| |
| Node* AllocateFixedArray(ElementsKind kind, Node* capacity, |
| ParameterMode mode = INTPTR_PARAMETERS, |
| AllocationFlags flags = kNone); |
| |
| // Perform CreateArrayIterator (ES6 #sec-createarrayiterator). |
| Node* CreateArrayIterator(Node* array, Node* array_map, Node* array_type, |
| Node* context, IterationKind mode); |
| |
| Node* AllocateJSArrayIterator(Node* array, Node* array_map, Node* map); |
| |
| Node* TypedArraySpeciesCreateByLength(Node* context, Node* originalArray, |
| Node* len); |
| |
| void FillFixedArrayWithValue(ElementsKind kind, Node* array, Node* from_index, |
| Node* to_index, |
| Heap::RootListIndex value_root_index, |
| ParameterMode mode = INTPTR_PARAMETERS); |
| |
| // Copies all elements from |from_array| of |length| size to |
| // |to_array| of the same size respecting the elements kind. |
| void CopyFixedArrayElements( |
| ElementsKind kind, Node* from_array, Node* to_array, Node* length, |
| WriteBarrierMode barrier_mode = UPDATE_WRITE_BARRIER, |
| ParameterMode mode = INTPTR_PARAMETERS) { |
| CopyFixedArrayElements(kind, from_array, kind, to_array, length, length, |
| barrier_mode, mode); |
| } |
| |
| // Copies |element_count| elements from |from_array| to |to_array| of |
| // |capacity| size respecting both array's elements kinds. |
| void CopyFixedArrayElements( |
| ElementsKind from_kind, Node* from_array, ElementsKind to_kind, |
| Node* to_array, Node* element_count, Node* capacity, |
| WriteBarrierMode barrier_mode = UPDATE_WRITE_BARRIER, |
| ParameterMode mode = INTPTR_PARAMETERS); |
| |
| // Copies |character_count| elements from |from_string| to |to_string| |
| // starting at the |from_index|'th character. |from_string| and |to_string| |
| // can either be one-byte strings or two-byte strings, although if |
| // |from_string| is two-byte, then |to_string| must be two-byte. |
| // |from_index|, |to_index| and |character_count| must be either Smis or |
| // intptr_ts depending on |mode| s.t. 0 <= |from_index| <= |from_index| + |
| // |character_count| <= from_string.length and 0 <= |to_index| <= |to_index| + |
| // |character_count| <= to_string.length. |
| void CopyStringCharacters(Node* from_string, Node* to_string, |
| Node* from_index, Node* to_index, |
| Node* character_count, |
| String::Encoding from_encoding, |
| String::Encoding to_encoding, ParameterMode mode); |
| |
| // Loads an element from |array| of |from_kind| elements by given |offset| |
| // (NOTE: not index!), does a hole check if |if_hole| is provided and |
| // converts the value so that it becomes ready for storing to array of |
| // |to_kind| elements. |
| Node* LoadElementAndPrepareForStore(Node* array, Node* offset, |
| ElementsKind from_kind, |
| ElementsKind to_kind, Label* if_hole); |
| |
| Node* CalculateNewElementsCapacity(Node* old_capacity, |
| ParameterMode mode = INTPTR_PARAMETERS); |
| |
| // Tries to grow the |elements| array of given |object| to store the |key| |
| // or bails out if the growing gap is too big. Returns new elements. |
| Node* TryGrowElementsCapacity(Node* object, Node* elements, ElementsKind kind, |
| Node* key, Label* bailout); |
| |
| // Tries to grow the |capacity|-length |elements| array of given |object| |
| // to store the |key| or bails out if the growing gap is too big. Returns |
| // new elements. |
| Node* TryGrowElementsCapacity(Node* object, Node* elements, ElementsKind kind, |
| Node* key, Node* capacity, ParameterMode mode, |
| Label* bailout); |
| |
| // Grows elements capacity of given object. Returns new elements. |
| Node* GrowElementsCapacity(Node* object, Node* elements, |
| ElementsKind from_kind, ElementsKind to_kind, |
| Node* capacity, Node* new_capacity, |
| ParameterMode mode, Label* bailout); |
| |
| // Given a need to grow by |growth|, allocate an appropriate new capacity |
| // if necessary, and return a new elements FixedArray object. Label |bailout| |
| // is followed for allocation failure. |
| void PossiblyGrowElementsCapacity(ParameterMode mode, ElementsKind kind, |
| Node* array, Node* length, |
| Variable* var_elements, Node* growth, |
| Label* bailout); |
| |
| // Allocation site manipulation |
| void InitializeAllocationMemento(Node* base_allocation, |
| int base_allocation_size, |
| Node* allocation_site); |
| |
| Node* TryTaggedToFloat64(Node* value, Label* if_valueisnotnumber); |
| Node* TruncateTaggedToFloat64(Node* context, Node* value); |
| Node* TruncateTaggedToWord32(Node* context, Node* value); |
| // Truncate the floating point value of a HeapNumber to an Int32. |
| Node* TruncateHeapNumberValueToWord32(Node* object); |
| |
| // Conversions. |
| Node* ChangeFloat64ToTagged(Node* value); |
| Node* ChangeInt32ToTagged(Node* value); |
| Node* ChangeUint32ToTagged(Node* value); |
| Node* ChangeNumberToFloat64(Node* value); |
| Node* ChangeNumberToIntPtr(Node* value); |
| |
| Node* TimesPointerSize(Node* value); |
| |
| // Type conversions. |
| // Throws a TypeError for {method_name} if {value} is not coercible to Object, |
| // or returns the {value} converted to a String otherwise. |
| Node* ToThisString(Node* context, Node* value, char const* method_name); |
| // Throws a TypeError for {method_name} if {value} is neither of the given |
| // {primitive_type} nor a JSValue wrapping a value of {primitive_type}, or |
| // returns the {value} (or wrapped value) otherwise. |
| Node* ToThisValue(Node* context, Node* value, PrimitiveType primitive_type, |
| char const* method_name); |
| |
| // Throws a TypeError for {method_name} if {value} is not of the given |
| // instance type. Returns {value}'s map. |
| Node* ThrowIfNotInstanceType(Node* context, Node* value, |
| InstanceType instance_type, |
| char const* method_name); |
| |
| // Type checks. |
| // Check whether the map is for an object with special properties, such as a |
| // JSProxy or an object with interceptors. |
| Node* InstanceTypeEqual(Node* instance_type, int type); |
| Node* IsAccessorInfo(Node* object); |
| Node* IsAccessorPair(Node* object); |
| Node* IsAllocationSite(Node* object); |
| Node* IsAnyHeapNumber(Node* object); |
| Node* IsBoolean(Node* object); |
| Node* IsCallableMap(Node* map); |
| Node* IsCallable(Node* object); |
| Node* IsConsStringInstanceType(Node* instance_type); |
| Node* IsConstructorMap(Node* map); |
| Node* IsConstructor(Node* object); |
| Node* IsDeprecatedMap(Node* map); |
| Node* IsDictionary(Node* object); |
| Node* IsExternalStringInstanceType(Node* instance_type); |
| Node* IsFeedbackVector(Node* object); |
| Node* IsFixedArray(Node* object); |
| Node* IsFixedArrayWithKind(Node* object, ElementsKind kind); |
| Node* IsFixedArrayWithKindOrEmpty(Node* object, ElementsKind kind); |
| Node* IsFixedDoubleArray(Node* object); |
| Node* IsFixedTypedArray(Node* object); |
| Node* IsHashTable(Node* object); |
| Node* IsHeapNumber(Node* object); |
| Node* IsIndirectStringInstanceType(Node* instance_type); |
| Node* IsJSArrayBuffer(Node* object); |
| Node* IsJSArrayInstanceType(Node* instance_type); |
| Node* IsJSArrayMap(Node* object); |
| Node* IsJSArray(Node* object); |
| Node* IsJSFunctionInstanceType(Node* instance_type); |
| Node* IsJSFunctionMap(Node* object); |
| Node* IsJSFunction(Node* object); |
| Node* IsJSGlobalProxy(Node* object); |
| Node* IsJSObjectMap(Node* map); |
| Node* IsJSObject(Node* object); |
| Node* IsJSReceiverInstanceType(Node* instance_type); |
| Node* IsJSReceiverMap(Node* map); |
| Node* IsJSReceiver(Node* object); |
| Node* IsJSRegExp(Node* object); |
| Node* IsJSTypedArray(Node* object); |
| Node* IsJSValueInstanceType(Node* instance_type); |
| Node* IsJSValueMap(Node* map); |
| Node* IsJSValue(Node* object); |
| Node* IsMap(Node* object); |
| Node* IsMutableHeapNumber(Node* object); |
| Node* IsName(Node* object); |
| Node* IsNativeContext(Node* object); |
| Node* IsOneByteStringInstanceType(Node* instance_type); |
| Node* IsPrivateSymbol(Node* object); |
| Node* IsPropertyCell(Node* object); |
| Node* IsSequentialStringInstanceType(Node* instance_type); |
| Node* IsShortExternalStringInstanceType(Node* instance_type); |
| Node* IsSpecialReceiverInstanceType(Node* instance_type); |
| Node* IsSpecialReceiverMap(Node* map); |
| Node* IsStringInstanceType(Node* instance_type); |
| Node* IsString(Node* object); |
| Node* IsSymbolInstanceType(Node* instance_type); |
| Node* IsSymbol(Node* object); |
| Node* IsUnseededNumberDictionary(Node* object); |
| Node* IsWeakCell(Node* object); |
| Node* IsUndetectableMap(Node* map); |
| |
| // True iff |object| is a Smi or a HeapNumber. |
| Node* IsNumber(Node* object); |
| |
| // True iff |number| is either a Smi, or a HeapNumber whose value is not |
| // within Smi range. |
| Node* IsNumberNormalized(Node* number); |
| Node* IsNumberPositive(Node* number); |
| |
| // ElementsKind helpers: |
| Node* IsFastElementsKind(Node* elements_kind); |
| Node* IsHoleyFastElementsKind(Node* elements_kind); |
| Node* IsElementsKindGreaterThan(Node* target_kind, |
| ElementsKind reference_kind); |
| |
| // String helpers. |
| // Load a character from a String (might flatten a ConsString). |
| Node* StringCharCodeAt(Node* string, Node* index, |
| ParameterMode parameter_mode = SMI_PARAMETERS); |
| // Return the single character string with only {code}. |
| Node* StringFromCharCode(Node* code); |
| |
| enum class SubStringFlags { NONE, FROM_TO_ARE_BOUNDED }; |
| |
| // Return a new string object which holds a substring containing the range |
| // [from,to[ of string. |from| and |to| are expected to be tagged. |
| // If flags has the value FROM_TO_ARE_BOUNDED then from and to are in |
| // the range [0, string-length) |
| Node* SubString(Node* context, Node* string, Node* from, Node* to, |
| SubStringFlags flags = SubStringFlags::NONE); |
| |
| // Return a new string object produced by concatenating |first| with |second|. |
| Node* StringAdd(Node* context, Node* first, Node* second, |
| AllocationFlags flags = kNone); |
| |
| // Check if |string| is an indirect (thin or flat cons) string type that can |
| // be dereferenced by DerefIndirectString. |
| void BranchIfCanDerefIndirectString(Node* string, Node* instance_type, |
| Label* can_deref, Label* cannot_deref); |
| // Unpack an indirect (thin or flat cons) string type. |
| void DerefIndirectString(Variable* var_string, Node* instance_type); |
| // Check if |var_string| has an indirect (thin or flat cons) string type, |
| // and unpack it if so. |
| void MaybeDerefIndirectString(Variable* var_string, Node* instance_type, |
| Variable* var_did_something); |
| // Check if |var_left| or |var_right| has an indirect (thin or flat cons) |
| // string type, and unpack it/them if so. Fall through if nothing was done. |
| void MaybeDerefIndirectStrings(Variable* var_left, Node* left_instance_type, |
| Variable* var_right, Node* right_instance_type, |
| Label* did_something); |
| |
| Node* StringFromCodePoint(Node* codepoint, UnicodeEncoding encoding); |
| |
| // Type conversion helpers. |
| // Convert a String to a Number. |
| Node* StringToNumber(Node* context, Node* input); |
| Node* NumberToString(Node* context, Node* input); |
| // Convert an object to a name. |
| Node* ToName(Node* context, Node* input); |
| // Convert a Non-Number object to a Number. |
| Node* NonNumberToNumber(Node* context, Node* input); |
| // Convert any object to a Number. |
| Node* ToNumber(Node* context, Node* input); |
| |
| // Converts |input| to one of 2^32 integer values in the range 0 through |
| // 2^32-1, inclusive. |
| // ES#sec-touint32 |
| compiler::Node* ToUint32(compiler::Node* context, compiler::Node* input); |
| |
| // Convert any object to a String. |
| Node* ToString(Node* context, Node* input); |
| Node* ToString_Inline(Node* const context, Node* const input); |
| |
| // Convert any object to a Primitive. |
| Node* JSReceiverToPrimitive(Node* context, Node* input); |
| |
| enum ToIntegerTruncationMode { |
| kNoTruncation, |
| kTruncateMinusZero, |
| }; |
| |
| // ES6 7.1.17 ToIndex, but jumps to range_error if the result is not a Smi. |
| Node* ToSmiIndex(Node* const input, Node* const context, Label* range_error); |
| |
| // ES6 7.1.15 ToLength, but jumps to range_error if the result is not a Smi. |
| Node* ToSmiLength(Node* input, Node* const context, Label* range_error); |
| |
| // ES6 7.1.15 ToLength, but with inlined fast path. |
| Node* ToLength_Inline(Node* const context, Node* const input); |
| |
| // Convert any object to an Integer. |
| Node* ToInteger(Node* context, Node* input, |
| ToIntegerTruncationMode mode = kNoTruncation); |
| |
| // Returns a node that contains a decoded (unsigned!) value of a bit |
| // field |T| in |word32|. Returns result as an uint32 node. |
| template <typename T> |
| Node* DecodeWord32(Node* word32) { |
| return DecodeWord32(word32, T::kShift, T::kMask); |
| } |
| |
| // Returns a node that contains a decoded (unsigned!) value of a bit |
| // field |T| in |word|. Returns result as a word-size node. |
| template <typename T> |
| Node* DecodeWord(Node* word) { |
| return DecodeWord(word, T::kShift, T::kMask); |
| } |
| |
| // Returns a node that contains a decoded (unsigned!) value of a bit |
| // field |T| in |word32|. Returns result as a word-size node. |
| template <typename T> |
| Node* DecodeWordFromWord32(Node* word32) { |
| return DecodeWord<T>(ChangeUint32ToWord(word32)); |
| } |
| |
| // Returns a node that contains a decoded (unsigned!) value of a bit |
| // field |T| in |word|. Returns result as an uint32 node. |
| template <typename T> |
| Node* DecodeWord32FromWord(Node* word) { |
| return TruncateWordToWord32(DecodeWord<T>(word)); |
| } |
| |
| // Decodes an unsigned (!) value from |word32| to an uint32 node. |
| Node* DecodeWord32(Node* word32, uint32_t shift, uint32_t mask); |
| |
| // Decodes an unsigned (!) value from |word| to a word-size node. |
| Node* DecodeWord(Node* word, uint32_t shift, uint32_t mask); |
| |
| // Returns true if any of the |T|'s bits in given |word32| are set. |
| template <typename T> |
| Node* IsSetWord32(Node* word32) { |
| return IsSetWord32(word32, T::kMask); |
| } |
| |
| // Returns true if any of the mask's bits in given |word32| are set. |
| Node* IsSetWord32(Node* word32, uint32_t mask) { |
| return Word32NotEqual(Word32And(word32, Int32Constant(mask)), |
| Int32Constant(0)); |
| } |
| |
| // Returns true if any of the |T|'s bits in given |word| are set. |
| template <typename T> |
| Node* IsSetWord(Node* word) { |
| return IsSetWord(word, T::kMask); |
| } |
| |
| // Returns true if any of the mask's bits in given |word| are set. |
| Node* IsSetWord(Node* word, uint32_t mask) { |
| return WordNotEqual(WordAnd(word, IntPtrConstant(mask)), IntPtrConstant(0)); |
| } |
| |
| // Returns true if any of the mask's bit are set in the given Smi. |
| // Smi-encoding of the mask is performed implicitly! |
| Node* IsSetSmi(Node* smi, int untagged_mask) { |
| intptr_t mask_word = bit_cast<intptr_t>(Smi::FromInt(untagged_mask)); |
| return WordNotEqual( |
| WordAnd(BitcastTaggedToWord(smi), IntPtrConstant(mask_word)), |
| IntPtrConstant(0)); |
| } |
| |
| // Returns true if all of the |T|'s bits in given |word32| are clear. |
| template <typename T> |
| Node* IsClearWord32(Node* word32) { |
| return IsClearWord32(word32, T::kMask); |
| } |
| |
| // Returns true if all of the mask's bits in given |word32| are clear. |
| Node* IsClearWord32(Node* word32, uint32_t mask) { |
| return Word32Equal(Word32And(word32, Int32Constant(mask)), |
| Int32Constant(0)); |
| } |
| |
| // Returns true if all of the |T|'s bits in given |word| are clear. |
| template <typename T> |
| Node* IsClearWord(Node* word) { |
| return IsClearWord(word, T::kMask); |
| } |
| |
| // Returns true if all of the mask's bits in given |word| are clear. |
| Node* IsClearWord(Node* word, uint32_t mask) { |
| return WordEqual(WordAnd(word, IntPtrConstant(mask)), IntPtrConstant(0)); |
| } |
| |
| void SetCounter(StatsCounter* counter, int value); |
| void IncrementCounter(StatsCounter* counter, int delta); |
| void DecrementCounter(StatsCounter* counter, int delta); |
| |
| void Increment(Variable& variable, int value = 1, |
| ParameterMode mode = INTPTR_PARAMETERS); |
| |
| // Generates "if (false) goto label" code. Useful for marking a label as |
| // "live" to avoid assertion failures during graph building. In the resulting |
| // code this check will be eliminated. |
| void Use(Label* label); |
| |
| // Various building blocks for stubs doing property lookups. |
| |
| // |if_notinternalized| is optional; |if_bailout| will be used by default. |
| void TryToName(Node* key, Label* if_keyisindex, Variable* var_index, |
| Label* if_keyisunique, Variable* var_unique, Label* if_bailout, |
| Label* if_notinternalized = nullptr); |
| |
| // Performs a hash computation and string table lookup for the given string, |
| // and jumps to: |
| // - |if_index| if the string is an array index like "123"; |var_index| |
| // will contain the intptr representation of that index. |
| // - |if_internalized| if the string exists in the string table; the |
| // internalized version will be in |var_internalized|. |
| // - |if_not_internalized| if the string is not in the string table (but |
| // does not add it). |
| // - |if_bailout| for unsupported cases (e.g. uncachable array index). |
| void TryInternalizeString(Node* string, Label* if_index, Variable* var_index, |
| Label* if_internalized, Variable* var_internalized, |
| Label* if_not_internalized, Label* if_bailout); |
| |
| // Calculates array index for given dictionary entry and entry field. |
| // See Dictionary::EntryToIndex(). |
| template <typename Dictionary> |
| Node* EntryToIndex(Node* entry, int field_index); |
| template <typename Dictionary> |
| Node* EntryToIndex(Node* entry) { |
| return EntryToIndex<Dictionary>(entry, Dictionary::kEntryKeyIndex); |
| } |
| |
| // Loads the details for the entry with the given key_index. |
| // Returns an untagged int32. |
| template <class ContainerType> |
| Node* LoadDetailsByKeyIndex(Node* container, Node* key_index) { |
| const int kKeyToDetailsOffset = |
| (ContainerType::kEntryDetailsIndex - ContainerType::kEntryKeyIndex) * |
| kPointerSize; |
| return LoadAndUntagToWord32FixedArrayElement(container, key_index, |
| kKeyToDetailsOffset); |
| } |
| |
| // Loads the value for the entry with the given key_index. |
| // Returns a tagged value. |
| template <class ContainerType> |
| Node* LoadValueByKeyIndex(Node* container, Node* key_index) { |
| const int kKeyToValueOffset = |
| (ContainerType::kEntryValueIndex - ContainerType::kEntryKeyIndex) * |
| kPointerSize; |
| return LoadFixedArrayElement(container, key_index, kKeyToValueOffset); |
| } |
| |
| // Stores the details for the entry with the given key_index. |
| // |details| must be a Smi. |
| template <class ContainerType> |
| void StoreDetailsByKeyIndex(Node* container, Node* key_index, Node* details) { |
| const int kKeyToDetailsOffset = |
| (ContainerType::kEntryDetailsIndex - ContainerType::kEntryKeyIndex) * |
| kPointerSize; |
| StoreFixedArrayElement(container, key_index, details, SKIP_WRITE_BARRIER, |
| kKeyToDetailsOffset); |
| } |
| |
| // Stores the value for the entry with the given key_index. |
| template <class ContainerType> |
| void StoreValueByKeyIndex( |
| Node* container, Node* key_index, Node* value, |
| WriteBarrierMode write_barrier = UPDATE_WRITE_BARRIER) { |
| const int kKeyToValueOffset = |
| (ContainerType::kEntryValueIndex - ContainerType::kEntryKeyIndex) * |
| kPointerSize; |
| StoreFixedArrayElement(container, key_index, value, write_barrier, |
| kKeyToValueOffset); |
| } |
| |
| // Calculate a valid size for the a hash table. |
| Node* HashTableComputeCapacity(Node* at_least_space_for); |
| |
| template <class Dictionary> |
| Node* GetNumberOfElements(Node* dictionary) { |
| return LoadFixedArrayElement(dictionary, |
| Dictionary::kNumberOfElementsIndex); |
| } |
| |
| template <class Dictionary> |
| void SetNumberOfElements(Node* dictionary, Node* num_elements_smi) { |
| StoreFixedArrayElement(dictionary, Dictionary::kNumberOfElementsIndex, |
| num_elements_smi, SKIP_WRITE_BARRIER); |
| } |
| |
| template <class Dictionary> |
| Node* GetNumberOfDeletedElements(Node* dictionary) { |
| return LoadFixedArrayElement(dictionary, |
| Dictionary::kNumberOfDeletedElementsIndex); |
| } |
| |
| template <class Dictionary> |
| void SetNumberOfDeletedElements(Node* dictionary, Node* num_deleted_smi) { |
| StoreFixedArrayElement(dictionary, |
| Dictionary::kNumberOfDeletedElementsIndex, |
| num_deleted_smi, SKIP_WRITE_BARRIER); |
| } |
| |
| template <class Dictionary> |
| Node* GetCapacity(Node* dictionary) { |
| return LoadFixedArrayElement(dictionary, Dictionary::kCapacityIndex); |
| } |
| |
| template <class Dictionary> |
| Node* GetNextEnumerationIndex(Node* dictionary); |
| |
| template <class Dictionary> |
| void SetNextEnumerationIndex(Node* dictionary, Node* next_enum_index_smi); |
| |
| // Looks up an entry in a NameDictionaryBase successor. If the entry is found |
| // control goes to {if_found} and {var_name_index} contains an index of the |
| // key field of the entry found. If the key is not found control goes to |
| // {if_not_found}. |
| static const int kInlinedDictionaryProbes = 4; |
| enum LookupMode { kFindExisting, kFindInsertionIndex }; |
| template <typename Dictionary> |
| void NameDictionaryLookup(Node* dictionary, Node* unique_name, |
| Label* if_found, Variable* var_name_index, |
| Label* if_not_found, |
| int inlined_probes = kInlinedDictionaryProbes, |
| LookupMode mode = kFindExisting); |
| |
| Node* ComputeIntegerHash(Node* key, Node* seed); |
| |
| template <typename Dictionary> |
| void NumberDictionaryLookup(Node* dictionary, Node* intptr_index, |
| Label* if_found, Variable* var_entry, |
| Label* if_not_found); |
| |
| template <class Dictionary> |
| void FindInsertionEntry(Node* dictionary, Node* key, Variable* var_key_index); |
| |
| template <class Dictionary> |
| void InsertEntry(Node* dictionary, Node* key, Node* value, Node* index, |
| Node* enum_index); |
| |
| template <class Dictionary> |
| void Add(Node* dictionary, Node* key, Node* value, Label* bailout); |
| |
| // Tries to check if {object} has own {unique_name} property. |
| void TryHasOwnProperty(Node* object, Node* map, Node* instance_type, |
| Node* unique_name, Label* if_found, |
| Label* if_not_found, Label* if_bailout); |
| |
| // Tries to get {object}'s own {unique_name} property value. If the property |
| // is an accessor then it also calls a getter. If the property is a double |
| // field it re-wraps value in an immutable heap number. |
| void TryGetOwnProperty(Node* context, Node* receiver, Node* object, Node* map, |
| Node* instance_type, Node* unique_name, |
| Label* if_found, Variable* var_value, |
| Label* if_not_found, Label* if_bailout); |
| |
| Node* GetProperty(Node* context, Node* receiver, Handle<Name> name) { |
| return GetProperty(context, receiver, HeapConstant(name)); |
| } |
| |
| Node* GetProperty(Node* context, Node* receiver, Node* const name) { |
| return CallStub(CodeFactory::GetProperty(isolate()), context, receiver, |
| name); |
| } |
| |
| template <class... TArgs> |
| Node* CallBuiltin(Builtins::Name id, Node* context, TArgs... args) { |
| return CallStub(Builtins::CallableFor(isolate(), id), context, args...); |
| } |
| |
| template <class... TArgs> |
| Node* TailCallBuiltin(Builtins::Name id, Node* context, TArgs... args) { |
| return TailCallStub(Builtins::CallableFor(isolate(), id), context, args...); |
| } |
| |
| void LoadPropertyFromFastObject(Node* object, Node* map, Node* descriptors, |
| Node* name_index, Variable* var_details, |
| Variable* var_value); |
| |
| void LoadPropertyFromNameDictionary(Node* dictionary, Node* entry, |
| Variable* var_details, |
| Variable* var_value); |
| |
| void LoadPropertyFromGlobalDictionary(Node* dictionary, Node* entry, |
| Variable* var_details, |
| Variable* var_value, Label* if_deleted); |
| |
| // Generic property lookup generator. If the {object} is fast and |
| // {unique_name} property is found then the control goes to {if_found_fast} |
| // label and {var_meta_storage} and {var_name_index} will contain |
| // DescriptorArray and an index of the descriptor's name respectively. |
| // If the {object} is slow or global then the control goes to {if_found_dict} |
| // or {if_found_global} and the {var_meta_storage} and {var_name_index} will |
| // contain a dictionary and an index of the key field of the found entry. |
| // If property is not found or given lookup is not supported then |
| // the control goes to {if_not_found} or {if_bailout} respectively. |
| // |
| // Note: this code does not check if the global dictionary points to deleted |
| // entry! This has to be done by the caller. |
| void TryLookupProperty(Node* object, Node* map, Node* instance_type, |
| Node* unique_name, Label* if_found_fast, |
| Label* if_found_dict, Label* if_found_global, |
| Variable* var_meta_storage, Variable* var_name_index, |
| Label* if_not_found, Label* if_bailout); |
| |
| // This method jumps to if_found if the element is known to exist. To |
| // if_absent if it's known to not exist. To if_not_found if the prototype |
| // chain needs to be checked. And if_bailout if the lookup is unsupported. |
| void TryLookupElement(Node* object, Node* map, Node* instance_type, |
| Node* intptr_index, Label* if_found, Label* if_absent, |
| Label* if_not_found, Label* if_bailout); |
| |
| // This is a type of a lookup in holder generator function. In case of a |
| // property lookup the {key} is guaranteed to be an unique name and in case of |
| // element lookup the key is an Int32 index. |
| typedef std::function<void(Node* receiver, Node* holder, Node* map, |
| Node* instance_type, Node* key, Label* next_holder, |
| Label* if_bailout)> |
| LookupInHolder; |
| |
| // Generic property prototype chain lookup generator. |
| // For properties it generates lookup using given {lookup_property_in_holder} |
| // and for elements it uses {lookup_element_in_holder}. |
| // Upon reaching the end of prototype chain the control goes to {if_end}. |
| // If it can't handle the case {receiver}/{key} case then the control goes |
| // to {if_bailout}. |
| void TryPrototypeChainLookup(Node* receiver, Node* key, |
| const LookupInHolder& lookup_property_in_holder, |
| const LookupInHolder& lookup_element_in_holder, |
| Label* if_end, Label* if_bailout); |
| |
| // Instanceof helpers. |
| // Returns true if {object} has {prototype} somewhere in it's prototype |
| // chain, otherwise false is returned. Might cause arbitrary side effects |
| // due to [[GetPrototypeOf]] invocations. |
| Node* HasInPrototypeChain(Node* context, Node* object, Node* prototype); |
| // ES6 section 7.3.19 OrdinaryHasInstance (C, O) |
| Node* OrdinaryHasInstance(Node* context, Node* callable, Node* object); |
| |
| // Load type feedback vector from the stub caller's frame. |
| Node* LoadFeedbackVectorForStub(); |
| |
| // Update the type feedback vector. |
| void UpdateFeedback(Node* feedback, Node* feedback_vector, Node* slot_id, |
| Node* function); |
| |
| // Combine the new feedback with the existing_feedback. |
| void CombineFeedback(Variable* existing_feedback, Node* feedback); |
| |
| // Check if a property name might require protector invalidation when it is |
| // used for a property store or deletion. |
| void CheckForAssociatedProtector(Node* name, Label* if_protector); |
| |
| Node* LoadReceiverMap(Node* receiver); |
| |
| // Emits keyed sloppy arguments load. Returns either the loaded value. |
| Node* LoadKeyedSloppyArguments(Node* receiver, Node* key, Label* bailout) { |
| return EmitKeyedSloppyArguments(receiver, key, nullptr, bailout); |
| } |
| |
| // Emits keyed sloppy arguments store. |
| void StoreKeyedSloppyArguments(Node* receiver, Node* key, Node* value, |
| Label* bailout) { |
| DCHECK_NOT_NULL(value); |
| EmitKeyedSloppyArguments(receiver, key, value, bailout); |
| } |
| |
| // Loads script context from the script context table. |
| Node* LoadScriptContext(Node* context, int context_index); |
| |
| Node* Int32ToUint8Clamped(Node* int32_value); |
| Node* Float64ToUint8Clamped(Node* float64_value); |
| |
| Node* PrepareValueForWriteToTypedArray(Node* key, ElementsKind elements_kind, |
| Label* bailout); |
| |
| // Store value to an elements array with given elements kind. |
| void StoreElement(Node* elements, ElementsKind kind, Node* index, Node* value, |
| ParameterMode mode); |
| |
| void EmitElementStore(Node* object, Node* key, Node* value, bool is_jsarray, |
| ElementsKind elements_kind, |
| KeyedAccessStoreMode store_mode, Label* bailout); |
| |
| Node* CheckForCapacityGrow(Node* object, Node* elements, ElementsKind kind, |
| Node* length, Node* key, ParameterMode mode, |
| bool is_js_array, Label* bailout); |
| |
| Node* CopyElementsOnWrite(Node* object, Node* elements, ElementsKind kind, |
| Node* length, ParameterMode mode, Label* bailout); |
| |
| void TransitionElementsKind(Node* object, Node* map, ElementsKind from_kind, |
| ElementsKind to_kind, bool is_jsarray, |
| Label* bailout); |
| |
| void TrapAllocationMemento(Node* object, Label* memento_found); |
| |
| Node* PageFromAddress(Node* address); |
| |
| // Create a new weak cell with a specified value and install it into a |
| // feedback vector. |
| Node* CreateWeakCellInFeedbackVector(Node* feedback_vector, Node* slot, |
| Node* value); |
| |
| // Create a new AllocationSite and install it into a feedback vector. |
| Node* CreateAllocationSiteInFeedbackVector(Node* feedback_vector, Node* slot); |
| |
| // Given a recently allocated object {object}, with map {initial_map}, |
| // initialize remaining fields appropriately to comply with slack tracking. |
| void HandleSlackTracking(Node* context, Node* object, Node* initial_map, |
| int start_offset); |
| |
| enum class IndexAdvanceMode { kPre, kPost }; |
| |
| typedef std::function<void(Node* index)> FastLoopBody; |
| |
| Node* BuildFastLoop(const VariableList& var_list, Node* start_index, |
| Node* end_index, const FastLoopBody& body, int increment, |
| ParameterMode parameter_mode, |
| IndexAdvanceMode advance_mode = IndexAdvanceMode::kPre); |
| |
| Node* BuildFastLoop(Node* start_index, Node* end_index, |
| const FastLoopBody& body, int increment, |
| ParameterMode parameter_mode, |
| IndexAdvanceMode advance_mode = IndexAdvanceMode::kPre) { |
| return BuildFastLoop(VariableList(0, zone()), start_index, end_index, body, |
| increment, parameter_mode, advance_mode); |
| } |
| |
| enum class ForEachDirection { kForward, kReverse }; |
| |
| typedef std::function<void(Node* fixed_array, Node* offset)> |
| FastFixedArrayForEachBody; |
| |
| void BuildFastFixedArrayForEach( |
| const CodeStubAssembler::VariableList& vars, Node* fixed_array, |
| ElementsKind kind, Node* first_element_inclusive, |
| Node* last_element_exclusive, const FastFixedArrayForEachBody& body, |
| ParameterMode mode = INTPTR_PARAMETERS, |
| ForEachDirection direction = ForEachDirection::kReverse); |
| |
| void BuildFastFixedArrayForEach( |
| Node* fixed_array, ElementsKind kind, Node* first_element_inclusive, |
| Node* last_element_exclusive, const FastFixedArrayForEachBody& body, |
| ParameterMode mode = INTPTR_PARAMETERS, |
| ForEachDirection direction = ForEachDirection::kReverse) { |
| CodeStubAssembler::VariableList list(0, zone()); |
| BuildFastFixedArrayForEach(list, fixed_array, kind, first_element_inclusive, |
| last_element_exclusive, body, mode, direction); |
| } |
| |
| Node* GetArrayAllocationSize(Node* element_count, ElementsKind kind, |
| ParameterMode mode, int header_size) { |
| return ElementOffsetFromIndex(element_count, kind, mode, header_size); |
| } |
| |
| Node* GetFixedArrayAllocationSize(Node* element_count, ElementsKind kind, |
| ParameterMode mode) { |
| return GetArrayAllocationSize(element_count, kind, mode, |
| FixedArray::kHeaderSize); |
| } |
| |
| void GotoIfFixedArraySizeDoesntFitInNewSpace(Node* element_count, |
| Label* doesnt_fit, int base_size, |
| ParameterMode mode); |
| |
| void InitializeFieldsWithRoot(Node* object, Node* start_offset, |
| Node* end_offset, Heap::RootListIndex root); |
| |
| enum RelationalComparisonMode { |
| kLessThan, |
| kLessThanOrEqual, |
| kGreaterThan, |
| kGreaterThanOrEqual |
| }; |
| |
| Node* RelationalComparison(RelationalComparisonMode mode, Node* lhs, |
| Node* rhs, Node* context, |
| Variable* var_type_feedback = nullptr); |
| |
| void BranchIfNumericRelationalComparison(RelationalComparisonMode mode, |
| Node* lhs, Node* rhs, Label* if_true, |
| Label* if_false); |
| |
| void GotoUnlessNumberLessThan(Node* lhs, Node* rhs, Label* if_false); |
| |
| Node* Equal(Node* lhs, Node* rhs, Node* context, |
| Variable* var_type_feedback = nullptr); |
| |
| Node* StrictEqual(Node* lhs, Node* rhs, |
| Variable* var_type_feedback = nullptr); |
| |
| // ECMA#sec-samevalue |
| // Similar to StrictEqual except that NaNs are treated as equal and minus zero |
| // differs from positive zero. |
| // Unlike Equal and StrictEqual, returns a value suitable for use in Branch |
| // instructions, e.g. Branch(SameValue(...), &label). |
| Node* SameValue(Node* lhs, Node* rhs); |
| |
| Node* HasProperty( |
| Node* object, Node* key, Node* context, |
| Runtime::FunctionId fallback_runtime_function_id = Runtime::kHasProperty); |
| |
| Node* ClassOf(Node* object); |
| |
| Node* Typeof(Node* value); |
| |
| Node* GetSuperConstructor(Node* value, Node* context); |
| |
| Node* InstanceOf(Node* object, Node* callable, Node* context); |
| |
| // Debug helpers |
| Node* IsDebugActive(); |
| |
| // TypedArray/ArrayBuffer helpers |
| Node* IsDetachedBuffer(Node* buffer); |
| |
| Node* ElementOffsetFromIndex(Node* index, ElementsKind kind, |
| ParameterMode mode, int base_size = 0); |
| |
| Node* AllocateFunctionWithMapAndContext(Node* map, Node* shared_info, |
| Node* context); |
| |
| // Promise helpers |
| Node* IsPromiseHookEnabledOrDebugIsActive(); |
| |
| Node* AllocatePromiseReactionJobInfo(Node* value, Node* tasks, |
| Node* deferred_promise, |
| Node* deferred_on_resolve, |
| Node* deferred_on_reject, Node* context); |
| |
| // Helpers for StackFrame markers. |
| Node* MarkerIsFrameType(Node* marker_or_function, |
| StackFrame::Type frame_type); |
| Node* MarkerIsNotFrameType(Node* marker_or_function, |
| StackFrame::Type frame_type); |
| |
| // Support for printf-style debugging |
| void Print(const char* s); |
| void Print(const char* prefix, Node* tagged_value); |
| inline void Print(Node* tagged_value) { return Print(nullptr, tagged_value); } |
| |
| template <class... TArgs> |
| Node* MakeTypeError(MessageTemplate::Template message, Node* context, |
| TArgs... args) { |
| STATIC_ASSERT(sizeof...(TArgs) <= 3); |
| Node* const make_type_error = LoadContextElement( |
| LoadNativeContext(context), Context::MAKE_TYPE_ERROR_INDEX); |
| return CallJS(CodeFactory::Call(isolate()), context, make_type_error, |
| UndefinedConstant(), SmiConstant(message), args...); |
| } |
| |
| void Abort(BailoutReason reason) { |
| CallRuntime(Runtime::kAbort, NoContextConstant(), SmiConstant(reason)); |
| Unreachable(); |
| } |
| |
| protected: |
| void DescriptorLookup(Node* unique_name, Node* descriptors, Node* bitfield3, |
| Label* if_found, Variable* var_name_index, |
| Label* if_not_found); |
| void DescriptorLookupLinear(Node* unique_name, Node* descriptors, Node* nof, |
| Label* if_found, Variable* var_name_index, |
| Label* if_not_found); |
| void DescriptorLookupBinary(Node* unique_name, Node* descriptors, Node* nof, |
| Label* if_found, Variable* var_name_index, |
| Label* if_not_found); |
| // Implements DescriptorArray::ToKeyIndex. |
| // Returns an untagged IntPtr. |
| Node* DescriptorArrayToKeyIndex(Node* descriptor_number); |
| |
| Node* CallGetterIfAccessor(Node* value, Node* details, Node* context, |
| Node* receiver, Label* if_bailout); |
| |
| Node* TryToIntptr(Node* key, Label* miss); |
| |
| void BranchIfPrototypesHaveNoElements(Node* receiver_map, |
| Label* definitely_no_elements, |
| Label* possibly_elements); |
| |
| private: |
| friend class CodeStubArguments; |
| |
| void HandleBreakOnNode(); |
| |
| Node* AllocateRawDoubleAligned(Node* size_in_bytes, AllocationFlags flags, |
| Node* top_address, Node* limit_address); |
| Node* AllocateRawUnaligned(Node* size_in_bytes, AllocationFlags flags, |
| Node* top_adddress, Node* limit_address); |
| Node* AllocateRaw(Node* size_in_bytes, AllocationFlags flags, |
| Node* top_address, Node* limit_address); |
| // Allocate and return a JSArray of given total size in bytes with header |
| // fields initialized. |
| Node* AllocateUninitializedJSArray(ElementsKind kind, Node* array_map, |
| Node* length, Node* allocation_site, |
| Node* size_in_bytes); |
| |
| Node* SmiShiftBitsConstant(); |
| |
| // Emits keyed sloppy arguments load if the |value| is nullptr or store |
| // otherwise. Returns either the loaded value or |value|. |
| Node* EmitKeyedSloppyArguments(Node* receiver, Node* key, Node* value, |
| Label* bailout); |
| |
| Node* AllocateSlicedString(Heap::RootListIndex map_root_index, Node* length, |
| Node* parent, Node* offset); |
| |
| Node* AllocateConsString(Heap::RootListIndex map_root_index, Node* length, |
| Node* first, Node* second, AllocationFlags flags); |
| |
| // Implements DescriptorArray::number_of_entries. |
| // Returns an untagged int32. |
| Node* DescriptorArrayNumberOfEntries(Node* descriptors); |
| // Implements DescriptorArray::GetSortedKeyIndex. |
| // Returns an untagged int32. |
| Node* DescriptorArrayGetSortedKeyIndex(Node* descriptors, |
| Node* descriptor_number); |
| // Implements DescriptorArray::GetKey. |
| Node* DescriptorArrayGetKey(Node* descriptors, Node* descriptor_number); |
| |
| Node* CollectFeedbackForString(Node* instance_type); |
| void GenerateEqual_Same(Node* value, Label* if_equal, Label* if_notequal, |
| Variable* var_type_feedback = nullptr); |
| Node* AllocAndCopyStringCharacters(Node* context, Node* from, |
| Node* from_instance_type, Node* from_index, |
| Node* character_count); |
| |
| static const int kElementLoopUnrollThreshold = 8; |
| }; |
| |
| class CodeStubArguments { |
| public: |
| typedef compiler::Node Node; |
| enum ReceiverMode { kHasReceiver, kNoReceiver }; |
| |
| // |argc| is an intptr value which specifies the number of arguments passed |
| // to the builtin excluding the receiver. The arguments will include a |
| // receiver iff |receiver_mode| is kHasReceiver. |
| CodeStubArguments(CodeStubAssembler* assembler, Node* argc, |
| ReceiverMode receiver_mode = ReceiverMode::kHasReceiver) |
| : CodeStubArguments(assembler, argc, nullptr, |
| CodeStubAssembler::INTPTR_PARAMETERS, receiver_mode) { |
| } |
| // |argc| is either a smi or intptr depending on |param_mode|. The arguments |
| // include a receiver iff |receiver_mode| is kHasReceiver. |
| CodeStubArguments(CodeStubAssembler* assembler, Node* argc, Node* fp, |
| CodeStubAssembler::ParameterMode param_mode, |
| ReceiverMode receiver_mode = ReceiverMode::kHasReceiver); |
| |
| Node* GetReceiver() const; |
| |
| Node* AtIndexPtr(Node* index, CodeStubAssembler::ParameterMode mode = |
| CodeStubAssembler::INTPTR_PARAMETERS) const; |
| |
| // |index| is zero-based and does not include the receiver |
| Node* AtIndex(Node* index, CodeStubAssembler::ParameterMode mode = |
| CodeStubAssembler::INTPTR_PARAMETERS) const; |
| |
| Node* AtIndex(int index) const; |
| |
| Node* GetOptionalArgumentValue(int index) { |
| return GetOptionalArgumentValue(index, assembler_->UndefinedConstant()); |
| } |
| Node* GetOptionalArgumentValue(int index, Node* default_value); |
| |
| Node* GetLength() const { return argc_; } |
| |
| typedef std::function<void(Node* arg)> ForEachBodyFunction; |
| |
| // Iteration doesn't include the receiver. |first| and |last| are zero-based. |
| void ForEach(const ForEachBodyFunction& body, Node* first = nullptr, |
| Node* last = nullptr, CodeStubAssembler::ParameterMode mode = |
| CodeStubAssembler::INTPTR_PARAMETERS) { |
| CodeStubAssembler::VariableList list(0, assembler_->zone()); |
| ForEach(list, body, first, last); |
| } |
| |
| // Iteration doesn't include the receiver. |first| and |last| are zero-based. |
| void ForEach(const CodeStubAssembler::VariableList& vars, |
| const ForEachBodyFunction& body, Node* first = nullptr, |
| Node* last = nullptr, CodeStubAssembler::ParameterMode mode = |
| CodeStubAssembler::INTPTR_PARAMETERS); |
| |
| void PopAndReturn(Node* value); |
| |
| private: |
| Node* GetArguments(); |
| |
| CodeStubAssembler* assembler_; |
| CodeStubAssembler::ParameterMode argc_mode_; |
| ReceiverMode receiver_mode_; |
| Node* argc_; |
| Node* arguments_; |
| Node* fp_; |
| }; |
| |
| class ToDirectStringAssembler : public CodeStubAssembler { |
| private: |
| enum StringPointerKind { PTR_TO_DATA, PTR_TO_STRING }; |
| |
| public: |
| enum Flag { |
| kDontUnpackSlicedStrings = 1 << 0, |
| }; |
| typedef base::Flags<Flag> Flags; |
| |
| ToDirectStringAssembler(compiler::CodeAssemblerState* state, Node* string, |
| Flags flags = Flags()); |
| |
| // Converts flat cons, thin, and sliced strings and returns the direct |
| // string. The result can be either a sequential or external string. |
| // Jumps to if_bailout if the string if the string is indirect and cannot |
| // be unpacked. |
| Node* TryToDirect(Label* if_bailout); |
| |
| // Returns a pointer to the beginning of the string data. |
| // Jumps to if_bailout if the external string cannot be unpacked. |
| Node* PointerToData(Label* if_bailout) { |
| return TryToSequential(PTR_TO_DATA, if_bailout); |
| } |
| |
| // Returns a pointer that, offset-wise, looks like a String. |
| // Jumps to if_bailout if the external string cannot be unpacked. |
| Node* PointerToString(Label* if_bailout) { |
| return TryToSequential(PTR_TO_STRING, if_bailout); |
| } |
| |
| Node* string() { return var_string_.value(); } |
| Node* instance_type() { return var_instance_type_.value(); } |
| Node* offset() { return var_offset_.value(); } |
| Node* is_external() { return var_is_external_.value(); } |
| |
| private: |
| Node* TryToSequential(StringPointerKind ptr_kind, Label* if_bailout); |
| |
| Variable var_string_; |
| Variable var_instance_type_; |
| Variable var_offset_; |
| Variable var_is_external_; |
| |
| const Flags flags_; |
| }; |
| |
| #define CSA_CHECK(csa, x) \ |
| (csa)->Check([&] { return (x); }, #x, __FILE__, __LINE__) |
| |
| #ifdef DEBUG |
| #define CSA_ASSERT(csa, x) \ |
| (csa)->Assert([&] { return (x); }, #x, __FILE__, __LINE__) |
| #define CSA_ASSERT_JS_ARGC_OP(csa, Op, op, expected) \ |
| (csa)->Assert( \ |
| [&] { \ |
| compiler::Node* const argc = \ |
| (csa)->Parameter(Descriptor::kActualArgumentsCount); \ |
| return (csa)->Op(argc, (csa)->Int32Constant(expected)); \ |
| }, \ |
| "argc " #op " " #expected, __FILE__, __LINE__) |
| |
| #define CSA_ASSERT_JS_ARGC_EQ(csa, expected) \ |
| CSA_ASSERT_JS_ARGC_OP(csa, Word32Equal, ==, expected) |
| |
| #define CSA_DEBUG_INFO(name) \ |
| , { #name, __FILE__, __LINE__ } |
| #define BIND(label) Bind(label CSA_DEBUG_INFO(label)) |
| #define VARIABLE(name, ...) \ |
| Variable name(this CSA_DEBUG_INFO(name), __VA_ARGS__); |
| |
| #else // DEBUG |
| #define CSA_ASSERT(csa, x) ((void)0) |
| #define CSA_ASSERT_JS_ARGC_EQ(csa, expected) ((void)0) |
| #define CSA_DEBUG_INFO(name) |
| #define BIND(label) Bind(label); |
| #define VARIABLE(name, ...) Variable name(this, __VA_ARGS__); |
| #endif // DEBUG |
| |
| #ifdef ENABLE_SLOW_DCHECKS |
| #define CSA_SLOW_ASSERT(csa, x) \ |
| if (FLAG_enable_slow_asserts) { \ |
| CSA_ASSERT(csa, x); \ |
| } |
| #else |
| #define CSA_SLOW_ASSERT(csa, x) ((void)0) |
| #endif |
| |
| DEFINE_OPERATORS_FOR_FLAGS(CodeStubAssembler::AllocationFlags); |
| |
| } // namespace internal |
| } // namespace v8 |
| #endif // V8_CODE_STUB_ASSEMBLER_H_ |