// Copyright 2012 the V8 project authors. All rights reserved. // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #ifndef V8_TYPE_INFO_H_ #define V8_TYPE_INFO_H_ #include "allocation.h" #include "ast.h" #include "globals.h" #include "zone-inl.h" namespace v8 { namespace internal { const int kMaxKeyedPolymorphism = 4; // Unknown // | \____________ // | | // Primitive Non-primitive // | \_______ | // | | | // Number String | // / \ | | // Double Integer32 | / // | | / / // | Smi / / // | | / __/ // Uninitialized. class TypeInfo { public: TypeInfo() : type_(kUninitialized) { } static TypeInfo Unknown() { return TypeInfo(kUnknown); } // We know it's a primitive type. static TypeInfo Primitive() { return TypeInfo(kPrimitive); } // We know it's a number of some sort. static TypeInfo Number() { return TypeInfo(kNumber); } // We know it's a signed 32 bit integer. static TypeInfo Integer32() { return TypeInfo(kInteger32); } // We know it's a Smi. static TypeInfo Smi() { return TypeInfo(kSmi); } // We know it's a heap number. static TypeInfo Double() { return TypeInfo(kDouble); } // We know it's a string. static TypeInfo String() { return TypeInfo(kString); } // We know it's an internalized string. static TypeInfo InternalizedString() { return TypeInfo(kInternalizedString); } // We know it's a non-primitive (object) type. static TypeInfo NonPrimitive() { return TypeInfo(kNonPrimitive); } // We haven't started collecting info yet. static TypeInfo Uninitialized() { return TypeInfo(kUninitialized); } int ToInt() { return type_; } static TypeInfo FromInt(int bit_representation) { Type t = static_cast(bit_representation); ASSERT(t == kUnknown || t == kPrimitive || t == kNumber || t == kInteger32 || t == kSmi || t == kDouble || t == kString || t == kNonPrimitive); return TypeInfo(t); } // Return the weakest (least precise) common type. static TypeInfo Combine(TypeInfo a, TypeInfo b) { return TypeInfo(static_cast(a.type_ & b.type_)); } // Integer32 is an integer that can be represented as a signed // 32-bit integer. It has to be // in the range [-2^31, 2^31 - 1]. We also have to check for negative 0 // as it is not an Integer32. static inline bool IsInt32Double(double value) { const DoubleRepresentation minus_zero(-0.0); DoubleRepresentation rep(value); if (rep.bits == minus_zero.bits) return false; if (value >= kMinInt && value <= kMaxInt && value == static_cast(value)) { return true; } return false; } static TypeInfo TypeFromValue(Handle value); bool Equals(const TypeInfo& other) { return type_ == other.type_; } inline bool IsUnknown() { ASSERT(type_ != kUninitialized); return type_ == kUnknown; } inline bool IsPrimitive() { ASSERT(type_ != kUninitialized); return ((type_ & kPrimitive) == kPrimitive); } inline bool IsNumber() { ASSERT(type_ != kUninitialized); return ((type_ & kNumber) == kNumber); } inline bool IsSmi() { ASSERT(type_ != kUninitialized); return ((type_ & kSmi) == kSmi); } inline bool IsInternalizedString() { ASSERT(type_ != kUninitialized); return ((type_ & kInternalizedString) == kInternalizedString); } inline bool IsNonInternalizedString() { ASSERT(type_ != kUninitialized); return ((type_ & kInternalizedString) == kString); } inline bool IsInteger32() { ASSERT(type_ != kUninitialized); return ((type_ & kInteger32) == kInteger32); } inline bool IsDouble() { ASSERT(type_ != kUninitialized); return ((type_ & kDouble) == kDouble); } inline bool IsString() { ASSERT(type_ != kUninitialized); return ((type_ & kString) == kString); } inline bool IsNonPrimitive() { ASSERT(type_ != kUninitialized); return ((type_ & kNonPrimitive) == kNonPrimitive); } inline bool IsUninitialized() { return type_ == kUninitialized; } const char* ToString() { switch (type_) { case kUnknown: return "Unknown"; case kPrimitive: return "Primitive"; case kNumber: return "Number"; case kInteger32: return "Integer32"; case kSmi: return "Smi"; case kInternalizedString: return "InternalizedString"; case kDouble: return "Double"; case kString: return "String"; case kNonPrimitive: return "Object"; case kUninitialized: return "Uninitialized"; } UNREACHABLE(); return "Unreachable code"; } private: enum Type { kUnknown = 0, // 0000000 kPrimitive = 0x10, // 0010000 kNumber = 0x11, // 0010001 kInteger32 = 0x13, // 0010011 kSmi = 0x17, // 0010111 kDouble = 0x19, // 0011001 kString = 0x30, // 0110000 kInternalizedString = 0x32, // 0110010 kNonPrimitive = 0x40, // 1000000 kUninitialized = 0x7f // 1111111 }; explicit inline TypeInfo(Type t) : type_(t) { } Type type_; }; enum StringStubFeedback { DEFAULT_STRING_STUB = 0, STRING_INDEX_OUT_OF_BOUNDS = 1 }; // Forward declarations. class Assignment; class BinaryOperation; class Call; class CallNew; class CaseClause; class CompareOperation; class CompilationInfo; class CountOperation; class Expression; class ForInStatement; class ICStub; class Property; class SmallMapList; class UnaryOperation; class TypeFeedbackOracle: public ZoneObject { public: TypeFeedbackOracle(Handle code, Handle native_context, Isolate* isolate, Zone* zone); bool LoadIsMonomorphicNormal(Property* expr); bool LoadIsUninitialized(Property* expr); bool LoadIsPolymorphic(Property* expr); bool StoreIsMonomorphicNormal(TypeFeedbackId ast_id); bool StoreIsPolymorphic(TypeFeedbackId ast_id); bool CallIsMonomorphic(Call* expr); bool CallNewIsMonomorphic(CallNew* expr); bool ObjectLiteralStoreIsMonomorphic(ObjectLiteral::Property* prop); bool IsForInFastCase(ForInStatement* expr); Handle LoadMonomorphicReceiverType(Property* expr); Handle StoreMonomorphicReceiverType(TypeFeedbackId ast_id); void LoadReceiverTypes(Property* expr, Handle name, SmallMapList* types); void StoreReceiverTypes(Assignment* expr, Handle name, SmallMapList* types); void CallReceiverTypes(Call* expr, Handle name, CallKind call_kind, SmallMapList* types); void CollectKeyedReceiverTypes(TypeFeedbackId ast_id, SmallMapList* types); static bool CanRetainOtherContext(Map* map, Context* native_context); static bool CanRetainOtherContext(JSFunction* function, Context* native_context); CheckType GetCallCheckType(Call* expr); Handle GetPrototypeForPrimitiveCheck(CheckType check); Handle GetCallTarget(Call* expr); Handle GetCallNewTarget(CallNew* expr); ElementsKind GetCallNewElementsKind(CallNew* expr); Handle GetObjectLiteralStoreMap(ObjectLiteral::Property* prop); bool LoadIsBuiltin(Property* expr, Builtins::Name id); bool LoadIsStub(Property* expr, ICStub* stub); // TODO(1571) We can't use ToBooleanStub::Types as the return value because // of various cylces in our headers. Death to tons of implementations in // headers!! :-P byte ToBooleanTypes(TypeFeedbackId ast_id); // Get type information for arithmetic operations and compares. TypeInfo UnaryType(UnaryOperation* expr); void BinaryType(BinaryOperation* expr, TypeInfo* left, TypeInfo* right, TypeInfo* result); void CompareType(CompareOperation* expr, TypeInfo* left_type, TypeInfo* right_type, TypeInfo* overall_type); Handle GetCompareMap(CompareOperation* expr); TypeInfo SwitchType(CaseClause* clause); TypeInfo IncrementType(CountOperation* expr); Zone* zone() const { return zone_; } private: void CollectReceiverTypes(TypeFeedbackId ast_id, Handle name, Code::Flags flags, SmallMapList* types); void SetInfo(TypeFeedbackId ast_id, Object* target); void BuildDictionary(Handle code); void GetRelocInfos(Handle code, ZoneList* infos); void CreateDictionary(Handle code, ZoneList* infos); void RelocateRelocInfos(ZoneList* infos, byte* old_start, byte* new_start); void ProcessRelocInfos(ZoneList* infos); void ProcessTypeFeedbackCells(Handle code); // Returns an element from the backing store. Returns undefined if // there is no information. public: // TODO(mvstanton): how to get this information without making the method // public? Handle GetInfo(TypeFeedbackId ast_id); private: Handle native_context_; Isolate* isolate_; Handle dictionary_; Zone* zone_; DISALLOW_COPY_AND_ASSIGN(TypeFeedbackOracle); }; } } // namespace v8::internal #endif // V8_TYPE_INFO_H_