// Copyright 2015 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_INTERPRETER_CONSTANT_ARRAY_BUILDER_H_ #define V8_INTERPRETER_CONSTANT_ARRAY_BUILDER_H_ #include "src/ast/ast-value-factory.h" #include "src/common/globals.h" #include "src/interpreter/bytecodes.h" #include "src/objects/smi.h" #include "src/utils/identity-map.h" #include "src/zone/zone-containers.h" namespace v8 { namespace internal { class Isolate; class AstRawString; class AstValue; namespace interpreter { // Constant array entries that represent singletons. #define SINGLETON_CONSTANT_ENTRY_TYPES(V) \ V(AsyncIteratorSymbol, async_iterator_symbol) \ V(ClassFieldsSymbol, class_fields_symbol) \ V(EmptyObjectBoilerplateDescription, empty_object_boilerplate_description) \ V(EmptyArrayBoilerplateDescription, empty_array_boilerplate_description) \ V(EmptyFixedArray, empty_fixed_array) \ V(HomeObjectSymbol, home_object_symbol) \ V(IteratorSymbol, iterator_symbol) \ V(InterpreterTrampolineSymbol, interpreter_trampoline_symbol) \ V(NaN, nan_value) // A helper class for constructing constant arrays for the // interpreter. Each instance of this class is intended to be used to // generate exactly one FixedArray of constants via the ToFixedArray // method. class V8_EXPORT_PRIVATE ConstantArrayBuilder final { public: // Capacity of the 8-bit operand slice. static const size_t k8BitCapacity = 1u << kBitsPerByte; // Capacity of the 16-bit operand slice. static const size_t k16BitCapacity = (1u << 2 * kBitsPerByte) - k8BitCapacity; // Capacity of the 32-bit operand slice. static const size_t k32BitCapacity = kMaxUInt32 - k16BitCapacity - k8BitCapacity + 1; explicit ConstantArrayBuilder(Zone* zone); // Generate a fixed array of constant handles based on inserted objects. Handle ToFixedArray(Isolate* isolate); // Returns the object, as a handle in |isolate|, that is in the constant pool // array at index |index|. Returns null if there is no handle at this index. // Only expected to be used in tests. MaybeHandle At(size_t index, Isolate* isolate) const; // Returns the number of elements in the array. size_t size() const; // Insert an object into the constants array if it is not already present. // Returns the array index associated with the object. size_t Insert(Smi smi); size_t Insert(double number); size_t Insert(const AstRawString* raw_string); size_t Insert(AstBigInt bigint); size_t Insert(const Scope* scope); #define INSERT_ENTRY(NAME, ...) size_t Insert##NAME(); SINGLETON_CONSTANT_ENTRY_TYPES(INSERT_ENTRY) #undef INSERT_ENTRY // Inserts an empty entry and returns the array index associated with the // reservation. The entry's handle value can be inserted by calling // SetDeferredAt(). size_t InsertDeferred(); // Inserts |size| consecutive empty entries and returns the array index // associated with the first reservation. Each entry's Smi value can be // inserted by calling SetJumpTableSmi(). size_t InsertJumpTable(size_t size); // Sets the deferred value at |index| to |object|. void SetDeferredAt(size_t index, Handle object); // Sets the jump table entry at |index| to |smi|. Note that |index| is the // constant pool index, not the switch case value. void SetJumpTableSmi(size_t index, Smi smi); // Creates a reserved entry in the constant pool and returns // the size of the operand that'll be required to hold the entry // when committed. OperandSize CreateReservedEntry(); // Commit reserved entry and returns the constant pool index for the // SMI value. size_t CommitReservedEntry(OperandSize operand_size, Smi value); // Discards constant pool reservation. void DiscardReservedEntry(OperandSize operand_size); private: using index_t = uint32_t; struct ConstantArraySlice; class Entry { private: enum class Tag : uint8_t; public: explicit Entry(Smi smi) : smi_(smi), tag_(Tag::kSmi) {} explicit Entry(double heap_number) : heap_number_(heap_number), tag_(Tag::kHeapNumber) {} explicit Entry(const AstRawString* raw_string) : raw_string_(raw_string), tag_(Tag::kRawString) {} explicit Entry(AstBigInt bigint) : bigint_(bigint), tag_(Tag::kBigInt) {} explicit Entry(const Scope* scope) : scope_(scope), tag_(Tag::kScope) {} #define CONSTRUCT_ENTRY(NAME, LOWER_NAME) \ static Entry NAME() { return Entry(Tag::k##NAME); } SINGLETON_CONSTANT_ENTRY_TYPES(CONSTRUCT_ENTRY) #undef CONSTRUCT_ENTRY static Entry Deferred() { return Entry(Tag::kDeferred); } static Entry UninitializedJumpTableSmi() { return Entry(Tag::kUninitializedJumpTableSmi); } bool IsDeferred() const { return tag_ == Tag::kDeferred; } bool IsJumpTableEntry() const { return tag_ == Tag::kUninitializedJumpTableSmi || tag_ == Tag::kJumpTableSmi; } void SetDeferred(Handle handle) { DCHECK_EQ(tag_, Tag::kDeferred); tag_ = Tag::kHandle; handle_ = handle; } void SetJumpTableSmi(Smi smi) { DCHECK_EQ(tag_, Tag::kUninitializedJumpTableSmi); tag_ = Tag::kJumpTableSmi; smi_ = smi; } Handle ToHandle(Isolate* isolate) const; private: explicit Entry(Tag tag) : tag_(tag) {} union { Handle handle_; Smi smi_; double heap_number_; const AstRawString* raw_string_; AstBigInt bigint_; const Scope* scope_; }; enum class Tag : uint8_t { kDeferred, kHandle, kSmi, kRawString, kHeapNumber, kBigInt, kScope, kUninitializedJumpTableSmi, kJumpTableSmi, #define ENTRY_TAG(NAME, ...) k##NAME, SINGLETON_CONSTANT_ENTRY_TYPES(ENTRY_TAG) #undef ENTRY_TAG } tag_; #if DEBUG // Required by CheckAllElementsAreUnique(). friend struct ConstantArraySlice; #endif }; index_t AllocateIndex(Entry constant_entry); index_t AllocateIndexArray(Entry constant_entry, size_t size); index_t AllocateReservedEntry(Smi value); struct ConstantArraySlice final : public ZoneObject { ConstantArraySlice(Zone* zone, size_t start_index, size_t capacity, OperandSize operand_size); void Reserve(); void Unreserve(); size_t Allocate(Entry entry, size_t count = 1); Entry& At(size_t index); const Entry& At(size_t index) const; #if DEBUG void CheckAllElementsAreUnique(Isolate* isolate) const; #endif inline size_t available() const { return capacity() - reserved() - size(); } inline size_t reserved() const { return reserved_; } inline size_t capacity() const { return capacity_; } inline size_t size() const { return constants_.size(); } inline size_t start_index() const { return start_index_; } inline size_t max_index() const { return start_index_ + capacity() - 1; } inline OperandSize operand_size() const { return operand_size_; } private: const size_t start_index_; const size_t capacity_; size_t reserved_; OperandSize operand_size_; ZoneVector constants_; DISALLOW_COPY_AND_ASSIGN(ConstantArraySlice); }; ConstantArraySlice* IndexToSlice(size_t index) const; ConstantArraySlice* OperandSizeToSlice(OperandSize operand_size) const; ConstantArraySlice* idx_slice_[3]; base::TemplateHashMapImpl, ZoneAllocationPolicy> constants_map_; ZoneMap smi_map_; ZoneVector> smi_pairs_; ZoneMap heap_number_map_; #define SINGLETON_ENTRY_FIELD(NAME, LOWER_NAME) int LOWER_NAME##_; SINGLETON_CONSTANT_ENTRY_TYPES(SINGLETON_ENTRY_FIELD) #undef SINGLETON_ENTRY_FIELD Zone* zone_; }; } // namespace interpreter } // namespace internal } // namespace v8 #endif // V8_INTERPRETER_CONSTANT_ARRAY_BUILDER_H_