// 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_BYTECODES_H_ #define V8_INTERPRETER_BYTECODES_H_ #include #include #include #include #include "src/common/globals.h" #include "src/interpreter/bytecode-operands.h" // This interface and it's implementation are independent of the // libv8_base library as they are used by the interpreter and the // standalone mkpeephole table generator program. namespace v8 { namespace internal { namespace interpreter { // The list of bytecodes which are interpreted by the interpreter. // Format is V(, , ). #define BYTECODE_LIST(V) \ /* Extended width operands */ \ V(Wide, AccumulatorUse::kNone) \ V(ExtraWide, AccumulatorUse::kNone) \ \ /* Debug Breakpoints - one for each possible size of unscaled bytecodes */ \ /* and one for each operand widening prefix bytecode */ \ V(DebugBreakWide, AccumulatorUse::kReadWrite) \ V(DebugBreakExtraWide, AccumulatorUse::kReadWrite) \ V(DebugBreak0, AccumulatorUse::kReadWrite) \ V(DebugBreak1, AccumulatorUse::kReadWrite, OperandType::kReg) \ V(DebugBreak2, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kReg) \ V(DebugBreak3, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kReg) \ V(DebugBreak4, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kReg, OperandType::kReg) \ V(DebugBreak5, AccumulatorUse::kReadWrite, OperandType::kRuntimeId, \ OperandType::kReg, OperandType::kReg) \ V(DebugBreak6, AccumulatorUse::kReadWrite, OperandType::kRuntimeId, \ OperandType::kReg, OperandType::kReg, OperandType::kReg) \ \ /* Loading the accumulator */ \ V(LdaZero, AccumulatorUse::kWrite) \ V(LdaSmi, AccumulatorUse::kWrite, OperandType::kImm) \ V(LdaUndefined, AccumulatorUse::kWrite) \ V(LdaNull, AccumulatorUse::kWrite) \ V(LdaTheHole, AccumulatorUse::kWrite) \ V(LdaTrue, AccumulatorUse::kWrite) \ V(LdaFalse, AccumulatorUse::kWrite) \ V(LdaConstant, AccumulatorUse::kWrite, OperandType::kIdx) \ \ /* Globals */ \ V(LdaGlobal, AccumulatorUse::kWrite, OperandType::kIdx, OperandType::kIdx) \ V(LdaGlobalInsideTypeof, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx) \ V(StaGlobal, AccumulatorUse::kRead, OperandType::kIdx, OperandType::kIdx) \ \ /* Context operations */ \ V(PushContext, AccumulatorUse::kRead, OperandType::kRegOut) \ V(PopContext, AccumulatorUse::kNone, OperandType::kReg) \ V(LdaContextSlot, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx, OperandType::kUImm) \ V(LdaImmutableContextSlot, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx, OperandType::kUImm) \ V(LdaCurrentContextSlot, AccumulatorUse::kWrite, OperandType::kIdx) \ V(LdaImmutableCurrentContextSlot, AccumulatorUse::kWrite, OperandType::kIdx) \ V(StaContextSlot, AccumulatorUse::kRead, OperandType::kReg, \ OperandType::kIdx, OperandType::kUImm) \ V(StaCurrentContextSlot, AccumulatorUse::kRead, OperandType::kIdx) \ \ /* Load-Store lookup slots */ \ V(LdaLookupSlot, AccumulatorUse::kWrite, OperandType::kIdx) \ V(LdaLookupContextSlot, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx, OperandType::kUImm) \ V(LdaLookupGlobalSlot, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx, OperandType::kUImm) \ V(LdaLookupSlotInsideTypeof, AccumulatorUse::kWrite, OperandType::kIdx) \ V(LdaLookupContextSlotInsideTypeof, AccumulatorUse::kWrite, \ OperandType::kIdx, OperandType::kIdx, OperandType::kUImm) \ V(LdaLookupGlobalSlotInsideTypeof, AccumulatorUse::kWrite, \ OperandType::kIdx, OperandType::kIdx, OperandType::kUImm) \ V(StaLookupSlot, AccumulatorUse::kReadWrite, OperandType::kIdx, \ OperandType::kFlag8) \ \ /* Register-accumulator transfers */ \ V(Ldar, AccumulatorUse::kWrite, OperandType::kReg) \ V(Star, AccumulatorUse::kRead, OperandType::kRegOut) \ \ /* Register-register transfers */ \ V(Mov, AccumulatorUse::kNone, OperandType::kReg, OperandType::kRegOut) \ \ /* Property loads (LoadIC) operations */ \ V(LdaNamedProperty, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx, OperandType::kIdx) \ V(LdaNamedPropertyNoFeedback, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx) \ V(LdaKeyedProperty, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ \ /* Operations on module variables */ \ V(LdaModuleVariable, AccumulatorUse::kWrite, OperandType::kImm, \ OperandType::kUImm) \ V(StaModuleVariable, AccumulatorUse::kRead, OperandType::kImm, \ OperandType::kUImm) \ \ /* Propery stores (StoreIC) operations */ \ V(StaNamedProperty, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx, OperandType::kIdx) \ V(StaNamedPropertyNoFeedback, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx, OperandType::kFlag8) \ V(StaNamedOwnProperty, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx, OperandType::kIdx) \ V(StaKeyedProperty, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kIdx) \ V(StaInArrayLiteral, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kIdx) \ V(StaDataPropertyInLiteral, AccumulatorUse::kRead, OperandType::kReg, \ OperandType::kReg, OperandType::kFlag8, OperandType::kIdx) \ V(CollectTypeProfile, AccumulatorUse::kRead, OperandType::kImm) \ \ /* Binary Operators */ \ V(Add, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(Sub, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(Mul, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(Div, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(Mod, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(Exp, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(BitwiseOr, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(BitwiseXor, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(BitwiseAnd, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(ShiftLeft, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(ShiftRight, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(ShiftRightLogical, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ \ /* Binary operators with immediate operands */ \ V(AddSmi, AccumulatorUse::kReadWrite, OperandType::kImm, OperandType::kIdx) \ V(SubSmi, AccumulatorUse::kReadWrite, OperandType::kImm, OperandType::kIdx) \ V(MulSmi, AccumulatorUse::kReadWrite, OperandType::kImm, OperandType::kIdx) \ V(DivSmi, AccumulatorUse::kReadWrite, OperandType::kImm, OperandType::kIdx) \ V(ModSmi, AccumulatorUse::kReadWrite, OperandType::kImm, OperandType::kIdx) \ V(ExpSmi, AccumulatorUse::kReadWrite, OperandType::kImm, OperandType::kIdx) \ V(BitwiseOrSmi, AccumulatorUse::kReadWrite, OperandType::kImm, \ OperandType::kIdx) \ V(BitwiseXorSmi, AccumulatorUse::kReadWrite, OperandType::kImm, \ OperandType::kIdx) \ V(BitwiseAndSmi, AccumulatorUse::kReadWrite, OperandType::kImm, \ OperandType::kIdx) \ V(ShiftLeftSmi, AccumulatorUse::kReadWrite, OperandType::kImm, \ OperandType::kIdx) \ V(ShiftRightSmi, AccumulatorUse::kReadWrite, OperandType::kImm, \ OperandType::kIdx) \ V(ShiftRightLogicalSmi, AccumulatorUse::kReadWrite, OperandType::kImm, \ OperandType::kIdx) \ \ /* Unary Operators */ \ V(Inc, AccumulatorUse::kReadWrite, OperandType::kIdx) \ V(Dec, AccumulatorUse::kReadWrite, OperandType::kIdx) \ V(Negate, AccumulatorUse::kReadWrite, OperandType::kIdx) \ V(BitwiseNot, AccumulatorUse::kReadWrite, OperandType::kIdx) \ V(ToBooleanLogicalNot, AccumulatorUse::kReadWrite) \ V(LogicalNot, AccumulatorUse::kReadWrite) \ V(TypeOf, AccumulatorUse::kReadWrite) \ V(DeletePropertyStrict, AccumulatorUse::kReadWrite, OperandType::kReg) \ V(DeletePropertySloppy, AccumulatorUse::kReadWrite, OperandType::kReg) \ \ /* GetSuperConstructor operator */ \ V(GetSuperConstructor, AccumulatorUse::kRead, OperandType::kRegOut) \ \ /* Call operations */ \ V(CallAnyReceiver, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kIdx) \ V(CallProperty, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kIdx) \ V(CallProperty0, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kIdx) \ V(CallProperty1, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kReg, OperandType::kIdx) \ V(CallProperty2, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kReg, OperandType::kReg, \ OperandType::kIdx) \ V(CallUndefinedReceiver, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kIdx) \ V(CallUndefinedReceiver0, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx) \ V(CallUndefinedReceiver1, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kIdx) \ V(CallUndefinedReceiver2, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kReg, OperandType::kReg, OperandType::kIdx) \ V(CallNoFeedback, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount) \ V(CallWithSpread, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kIdx) \ V(CallRuntime, AccumulatorUse::kWrite, OperandType::kRuntimeId, \ OperandType::kRegList, OperandType::kRegCount) \ V(CallRuntimeForPair, AccumulatorUse::kNone, OperandType::kRuntimeId, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kRegOutPair) \ V(CallJSRuntime, AccumulatorUse::kWrite, OperandType::kNativeContextIndex, \ OperandType::kRegList, OperandType::kRegCount) \ \ /* Intrinsics */ \ V(InvokeIntrinsic, AccumulatorUse::kWrite, OperandType::kIntrinsicId, \ OperandType::kRegList, OperandType::kRegCount) \ \ /* Construct operators */ \ V(Construct, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kIdx) \ V(ConstructWithSpread, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kIdx) \ \ /* Test Operators */ \ V(TestEqual, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestEqualStrict, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestLessThan, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestGreaterThan, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestLessThanOrEqual, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestGreaterThanOrEqual, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestReferenceEqual, AccumulatorUse::kReadWrite, OperandType::kReg) \ V(TestInstanceOf, AccumulatorUse::kReadWrite, OperandType::kReg, \ OperandType::kIdx) \ V(TestIn, AccumulatorUse::kReadWrite, OperandType::kReg, OperandType::kIdx) \ V(TestUndetectable, AccumulatorUse::kReadWrite) \ V(TestNull, AccumulatorUse::kReadWrite) \ V(TestUndefined, AccumulatorUse::kReadWrite) \ V(TestTypeOf, AccumulatorUse::kReadWrite, OperandType::kFlag8) \ \ /* Cast operators */ \ V(ToName, AccumulatorUse::kRead, OperandType::kRegOut) \ V(ToNumber, AccumulatorUse::kReadWrite, OperandType::kIdx) \ V(ToNumeric, AccumulatorUse::kReadWrite, OperandType::kIdx) \ V(ToObject, AccumulatorUse::kRead, OperandType::kRegOut) \ V(ToString, AccumulatorUse::kReadWrite) \ \ /* Literals */ \ V(CreateRegExpLiteral, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx, OperandType::kFlag8) \ V(CreateArrayLiteral, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx, OperandType::kFlag8) \ V(CreateArrayFromIterable, AccumulatorUse::kReadWrite) \ V(CreateEmptyArrayLiteral, AccumulatorUse::kWrite, OperandType::kIdx) \ V(CreateObjectLiteral, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx, OperandType::kFlag8) \ V(CreateEmptyObjectLiteral, AccumulatorUse::kWrite) \ V(CloneObject, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kFlag8, OperandType::kIdx) \ \ /* Tagged templates */ \ V(GetTemplateObject, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx) \ \ /* Closure allocation */ \ V(CreateClosure, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kIdx, OperandType::kFlag8) \ \ /* Context allocation */ \ V(CreateBlockContext, AccumulatorUse::kWrite, OperandType::kIdx) \ V(CreateCatchContext, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx) \ V(CreateFunctionContext, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kUImm) \ V(CreateEvalContext, AccumulatorUse::kWrite, OperandType::kIdx, \ OperandType::kUImm) \ V(CreateWithContext, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kIdx) \ \ /* Arguments allocation */ \ V(CreateMappedArguments, AccumulatorUse::kWrite) \ V(CreateUnmappedArguments, AccumulatorUse::kWrite) \ V(CreateRestParameter, AccumulatorUse::kWrite) \ \ /* Control Flow -- carefully ordered for efficient checks */ \ /* - [Unconditional jumps] */ \ V(JumpLoop, AccumulatorUse::kNone, OperandType::kUImm, OperandType::kImm) \ /* - [Forward jumps] */ \ V(Jump, AccumulatorUse::kNone, OperandType::kUImm) \ /* - [Start constant jumps] */ \ V(JumpConstant, AccumulatorUse::kNone, OperandType::kIdx) \ /* - [Conditional jumps] */ \ /* - [Conditional constant jumps] */ \ V(JumpIfNullConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfNotNullConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfUndefinedConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfNotUndefinedConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfUndefinedOrNullConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfTrueConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfFalseConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfJSReceiverConstant, AccumulatorUse::kRead, OperandType::kIdx) \ /* - [Start ToBoolean jumps] */ \ V(JumpIfToBooleanTrueConstant, AccumulatorUse::kRead, OperandType::kIdx) \ V(JumpIfToBooleanFalseConstant, AccumulatorUse::kRead, OperandType::kIdx) \ /* - [End constant jumps] */ \ /* - [Conditional immediate jumps] */ \ V(JumpIfToBooleanTrue, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfToBooleanFalse, AccumulatorUse::kRead, OperandType::kUImm) \ /* - [End ToBoolean jumps] */ \ V(JumpIfTrue, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfFalse, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfNull, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfNotNull, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfUndefined, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfNotUndefined, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfUndefinedOrNull, AccumulatorUse::kRead, OperandType::kUImm) \ V(JumpIfJSReceiver, AccumulatorUse::kRead, OperandType::kUImm) \ \ /* Smi-table lookup for switch statements */ \ V(SwitchOnSmiNoFeedback, AccumulatorUse::kRead, OperandType::kIdx, \ OperandType::kUImm, OperandType::kImm) \ \ /* Complex flow control For..in */ \ V(ForInEnumerate, AccumulatorUse::kWrite, OperandType::kReg) \ V(ForInPrepare, AccumulatorUse::kRead, OperandType::kRegOutTriple, \ OperandType::kIdx) \ V(ForInContinue, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kReg) \ V(ForInNext, AccumulatorUse::kWrite, OperandType::kReg, OperandType::kReg, \ OperandType::kRegPair, OperandType::kIdx) \ V(ForInStep, AccumulatorUse::kWrite, OperandType::kReg) \ \ /* Perform a stack guard check */ \ V(StackCheck, AccumulatorUse::kNone) \ \ /* Update the pending message */ \ V(SetPendingMessage, AccumulatorUse::kReadWrite) \ \ /* Non-local flow control */ \ V(Throw, AccumulatorUse::kRead) \ V(ReThrow, AccumulatorUse::kRead) \ V(Return, AccumulatorUse::kRead) \ V(ThrowReferenceErrorIfHole, AccumulatorUse::kRead, OperandType::kIdx) \ V(ThrowSuperNotCalledIfHole, AccumulatorUse::kRead) \ V(ThrowSuperAlreadyCalledIfNotHole, AccumulatorUse::kRead) \ \ /* Generators */ \ V(SwitchOnGeneratorState, AccumulatorUse::kNone, OperandType::kReg, \ OperandType::kIdx, OperandType::kUImm) \ V(SuspendGenerator, AccumulatorUse::kRead, OperandType::kReg, \ OperandType::kRegList, OperandType::kRegCount, OperandType::kUImm) \ V(ResumeGenerator, AccumulatorUse::kWrite, OperandType::kReg, \ OperandType::kRegOutList, OperandType::kRegCount) \ \ /* Iterator protocol operations */ \ V(GetIterator, AccumulatorUse::kWrite, OperandType::kReg, OperandType::kIdx) \ \ /* Debugger */ \ V(Debugger, AccumulatorUse::kNone) \ \ /* Block Coverage */ \ V(IncBlockCounter, AccumulatorUse::kNone, OperandType::kIdx) \ \ /* Execution Abort (internal error) */ \ V(Abort, AccumulatorUse::kNone, OperandType::kIdx) \ \ /* Illegal bytecode */ \ V(Illegal, AccumulatorUse::kNone) // List of debug break bytecodes. #define DEBUG_BREAK_PLAIN_BYTECODE_LIST(V) \ V(DebugBreak0) \ V(DebugBreak1) \ V(DebugBreak2) \ V(DebugBreak3) \ V(DebugBreak4) \ V(DebugBreak5) \ V(DebugBreak6) #define DEBUG_BREAK_PREFIX_BYTECODE_LIST(V) \ V(DebugBreakWide) \ V(DebugBreakExtraWide) #define DEBUG_BREAK_BYTECODE_LIST(V) \ DEBUG_BREAK_PLAIN_BYTECODE_LIST(V) \ DEBUG_BREAK_PREFIX_BYTECODE_LIST(V) // Lists of jump bytecodes. #define JUMP_UNCONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ V(JumpLoop) \ V(Jump) #define JUMP_UNCONDITIONAL_CONSTANT_BYTECODE_LIST(V) V(JumpConstant) #define JUMP_TOBOOLEAN_CONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ V(JumpIfToBooleanTrue) \ V(JumpIfToBooleanFalse) #define JUMP_TOBOOLEAN_CONDITIONAL_CONSTANT_BYTECODE_LIST(V) \ V(JumpIfToBooleanTrueConstant) \ V(JumpIfToBooleanFalseConstant) #define JUMP_CONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ JUMP_TOBOOLEAN_CONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ V(JumpIfTrue) \ V(JumpIfFalse) \ V(JumpIfNull) \ V(JumpIfNotNull) \ V(JumpIfUndefined) \ V(JumpIfNotUndefined) \ V(JumpIfUndefinedOrNull) \ V(JumpIfJSReceiver) #define JUMP_CONDITIONAL_CONSTANT_BYTECODE_LIST(V) \ JUMP_TOBOOLEAN_CONDITIONAL_CONSTANT_BYTECODE_LIST(V) \ V(JumpIfNullConstant) \ V(JumpIfNotNullConstant) \ V(JumpIfUndefinedConstant) \ V(JumpIfNotUndefinedConstant) \ V(JumpIfUndefinedOrNullConstant) \ V(JumpIfTrueConstant) \ V(JumpIfFalseConstant) \ V(JumpIfJSReceiverConstant) #define JUMP_CONSTANT_BYTECODE_LIST(V) \ JUMP_UNCONDITIONAL_CONSTANT_BYTECODE_LIST(V) \ JUMP_CONDITIONAL_CONSTANT_BYTECODE_LIST(V) #define JUMP_IMMEDIATE_BYTECODE_LIST(V) \ JUMP_UNCONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ JUMP_CONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) #define JUMP_TO_BOOLEAN_BYTECODE_LIST(V) \ JUMP_TOBOOLEAN_CONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ JUMP_TOBOOLEAN_CONDITIONAL_CONSTANT_BYTECODE_LIST(V) #define JUMP_UNCONDITIONAL_BYTECODE_LIST(V) \ JUMP_UNCONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ JUMP_UNCONDITIONAL_CONSTANT_BYTECODE_LIST(V) #define JUMP_CONDITIONAL_BYTECODE_LIST(V) \ JUMP_CONDITIONAL_IMMEDIATE_BYTECODE_LIST(V) \ JUMP_CONDITIONAL_CONSTANT_BYTECODE_LIST(V) #define JUMP_FORWARD_BYTECODE_LIST(V) \ V(Jump) \ V(JumpConstant) \ JUMP_CONDITIONAL_BYTECODE_LIST(V) #define JUMP_BYTECODE_LIST(V) \ JUMP_FORWARD_BYTECODE_LIST(V) \ V(JumpLoop) #define RETURN_BYTECODE_LIST(V) \ V(Return) \ V(SuspendGenerator) // Enumeration of interpreter bytecodes. enum class Bytecode : uint8_t { #define DECLARE_BYTECODE(Name, ...) k##Name, BYTECODE_LIST(DECLARE_BYTECODE) #undef DECLARE_BYTECODE #define COUNT_BYTECODE(x, ...) +1 // The COUNT_BYTECODE macro will turn this into kLast = -1 +1 +1... which will // evaluate to the same value as the last real bytecode. kLast = -1 BYTECODE_LIST(COUNT_BYTECODE) #undef COUNT_BYTECODE }; class V8_EXPORT_PRIVATE Bytecodes final : public AllStatic { public: // The maximum number of operands a bytecode may have. static const int kMaxOperands = 5; // The total number of bytecodes used. static const int kBytecodeCount = static_cast(Bytecode::kLast) + 1; // Returns string representation of |bytecode|. static const char* ToString(Bytecode bytecode); // Returns string representation of |bytecode| combined with |operand_scale| // using the optionally provided |separator|. static std::string ToString(Bytecode bytecode, OperandScale operand_scale, const char* separator = "."); // Returns byte value of bytecode. static uint8_t ToByte(Bytecode bytecode) { DCHECK_LE(bytecode, Bytecode::kLast); return static_cast(bytecode); } // Returns bytecode for |value|. static Bytecode FromByte(uint8_t value) { Bytecode bytecode = static_cast(value); DCHECK_LE(bytecode, Bytecode::kLast); return bytecode; } // Returns the prefix bytecode representing an operand scale to be // applied to a a bytecode. static Bytecode OperandScaleToPrefixBytecode(OperandScale operand_scale) { switch (operand_scale) { case OperandScale::kQuadruple: return Bytecode::kExtraWide; case OperandScale::kDouble: return Bytecode::kWide; default: UNREACHABLE(); } } // Returns true if the operand scale requires a prefix bytecode. static bool OperandScaleRequiresPrefixBytecode(OperandScale operand_scale) { return operand_scale != OperandScale::kSingle; } // Returns the scaling applied to scalable operands if bytecode is // is a scaling prefix. static OperandScale PrefixBytecodeToOperandScale(Bytecode bytecode) { switch (bytecode) { case Bytecode::kExtraWide: case Bytecode::kDebugBreakExtraWide: return OperandScale::kQuadruple; case Bytecode::kWide: case Bytecode::kDebugBreakWide: return OperandScale::kDouble; default: UNREACHABLE(); } } // Returns how accumulator is used by |bytecode|. static AccumulatorUse GetAccumulatorUse(Bytecode bytecode) { DCHECK_LE(bytecode, Bytecode::kLast); return kAccumulatorUse[static_cast(bytecode)]; } // Returns true if |bytecode| reads the accumulator. static bool ReadsAccumulator(Bytecode bytecode) { return BytecodeOperands::ReadsAccumulator(GetAccumulatorUse(bytecode)); } // Returns true if |bytecode| writes the accumulator. static bool WritesAccumulator(Bytecode bytecode) { return BytecodeOperands::WritesAccumulator(GetAccumulatorUse(bytecode)); } // Return true if |bytecode| is an accumulator load without effects, // e.g. LdaConstant, LdaTrue, Ldar. static constexpr bool IsAccumulatorLoadWithoutEffects(Bytecode bytecode) { return bytecode == Bytecode::kLdar || bytecode == Bytecode::kLdaZero || bytecode == Bytecode::kLdaSmi || bytecode == Bytecode::kLdaNull || bytecode == Bytecode::kLdaTrue || bytecode == Bytecode::kLdaFalse || bytecode == Bytecode::kLdaUndefined || bytecode == Bytecode::kLdaTheHole || bytecode == Bytecode::kLdaConstant || bytecode == Bytecode::kLdaContextSlot || bytecode == Bytecode::kLdaCurrentContextSlot || bytecode == Bytecode::kLdaImmutableContextSlot || bytecode == Bytecode::kLdaImmutableCurrentContextSlot; } // Returns true if |bytecode| is a compare operation without external effects // (e.g., Type cooersion). static constexpr bool IsCompareWithoutEffects(Bytecode bytecode) { return bytecode == Bytecode::kTestUndetectable || bytecode == Bytecode::kTestNull || bytecode == Bytecode::kTestUndefined || bytecode == Bytecode::kTestTypeOf; } // Return true if |bytecode| is a register load without effects, // e.g. Mov, Star. static constexpr bool IsRegisterLoadWithoutEffects(Bytecode bytecode) { return bytecode == Bytecode::kMov || bytecode == Bytecode::kPopContext || bytecode == Bytecode::kPushContext || bytecode == Bytecode::kStar; } // Returns true if the bytecode is a conditional jump taking // an immediate byte operand (OperandType::kImm). static constexpr bool IsConditionalJumpImmediate(Bytecode bytecode) { return bytecode >= Bytecode::kJumpIfToBooleanTrue && bytecode <= Bytecode::kJumpIfJSReceiver; } // Returns true if the bytecode is a conditional jump taking // a constant pool entry (OperandType::kIdx). static constexpr bool IsConditionalJumpConstant(Bytecode bytecode) { return bytecode >= Bytecode::kJumpIfNullConstant && bytecode <= Bytecode::kJumpIfToBooleanFalseConstant; } // Returns true if the bytecode is a conditional jump taking // any kind of operand. static constexpr bool IsConditionalJump(Bytecode bytecode) { return bytecode >= Bytecode::kJumpIfNullConstant && bytecode <= Bytecode::kJumpIfJSReceiver; } // Returns true if the bytecode is an unconditional jump. static constexpr bool IsUnconditionalJump(Bytecode bytecode) { return bytecode >= Bytecode::kJumpLoop && bytecode <= Bytecode::kJumpConstant; } // Returns true if the bytecode is a jump or a conditional jump taking // an immediate byte operand (OperandType::kImm). static constexpr bool IsJumpImmediate(Bytecode bytecode) { return bytecode == Bytecode::kJump || bytecode == Bytecode::kJumpLoop || IsConditionalJumpImmediate(bytecode); } // Returns true if the bytecode is a jump or conditional jump taking a // constant pool entry (OperandType::kIdx). static constexpr bool IsJumpConstant(Bytecode bytecode) { return bytecode >= Bytecode::kJumpConstant && bytecode <= Bytecode::kJumpIfToBooleanFalseConstant; } // Returns true if the bytecode is a jump that internally coerces the // accumulator to a boolean. static constexpr bool IsJumpIfToBoolean(Bytecode bytecode) { return bytecode >= Bytecode::kJumpIfToBooleanTrueConstant && bytecode <= Bytecode::kJumpIfToBooleanFalse; } // Returns true if the bytecode is a jump or conditional jump taking // any kind of operand. static constexpr bool IsJump(Bytecode bytecode) { return bytecode >= Bytecode::kJumpLoop && bytecode <= Bytecode::kJumpIfJSReceiver; } // Returns true if the bytecode is a forward jump or conditional jump taking // any kind of operand. static constexpr bool IsForwardJump(Bytecode bytecode) { return bytecode >= Bytecode::kJump && bytecode <= Bytecode::kJumpIfJSReceiver; } // Return true if |bytecode| is a jump without effects, // e.g. any jump excluding those that include type coercion like // JumpIfTrueToBoolean. static constexpr bool IsJumpWithoutEffects(Bytecode bytecode) { return IsJump(bytecode) && !IsJumpIfToBoolean(bytecode); } // Returns true if the bytecode is a switch. static constexpr bool IsSwitch(Bytecode bytecode) { return bytecode == Bytecode::kSwitchOnSmiNoFeedback || bytecode == Bytecode::kSwitchOnGeneratorState; } // Returns true if |bytecode| has no effects. These bytecodes only manipulate // interpreter frame state and will never throw. static constexpr bool IsWithoutExternalSideEffects(Bytecode bytecode) { return (IsAccumulatorLoadWithoutEffects(bytecode) || IsRegisterLoadWithoutEffects(bytecode) || IsCompareWithoutEffects(bytecode) || IsJumpWithoutEffects(bytecode) || IsSwitch(bytecode)); } // Returns true if the bytecode is Ldar or Star. static constexpr bool IsLdarOrStar(Bytecode bytecode) { return bytecode == Bytecode::kLdar || bytecode == Bytecode::kStar; } // Returns true if the bytecode is a call or a constructor call. static constexpr bool IsCallOrConstruct(Bytecode bytecode) { return bytecode == Bytecode::kCallAnyReceiver || bytecode == Bytecode::kCallProperty || bytecode == Bytecode::kCallProperty0 || bytecode == Bytecode::kCallProperty1 || bytecode == Bytecode::kCallProperty2 || bytecode == Bytecode::kCallUndefinedReceiver || bytecode == Bytecode::kCallUndefinedReceiver0 || bytecode == Bytecode::kCallUndefinedReceiver1 || bytecode == Bytecode::kCallUndefinedReceiver2 || bytecode == Bytecode::kCallNoFeedback || bytecode == Bytecode::kConstruct || bytecode == Bytecode::kCallWithSpread || bytecode == Bytecode::kConstructWithSpread || bytecode == Bytecode::kCallJSRuntime; } // Returns true if the bytecode is a call to the runtime. static constexpr bool IsCallRuntime(Bytecode bytecode) { return bytecode == Bytecode::kCallRuntime || bytecode == Bytecode::kCallRuntimeForPair || bytecode == Bytecode::kInvokeIntrinsic; } // Returns true if the bytecode is an one-shot bytecode. One-shot bytecodes // don`t collect feedback and are intended for code that runs only once and // shouldn`t be optimized. static constexpr bool IsOneShotBytecode(Bytecode bytecode) { return bytecode == Bytecode::kCallNoFeedback || bytecode == Bytecode::kLdaNamedPropertyNoFeedback || bytecode == Bytecode::kStaNamedPropertyNoFeedback; } // Returns true if the bytecode is a scaling prefix bytecode. static constexpr bool IsPrefixScalingBytecode(Bytecode bytecode) { return bytecode == Bytecode::kExtraWide || bytecode == Bytecode::kWide || bytecode == Bytecode::kDebugBreakExtraWide || bytecode == Bytecode::kDebugBreakWide; } // Returns true if the bytecode returns. static constexpr bool Returns(Bytecode bytecode) { #define OR_BYTECODE(NAME) || bytecode == Bytecode::k##NAME return false RETURN_BYTECODE_LIST(OR_BYTECODE); #undef OR_BYTECODE } // Returns the number of operands expected by |bytecode|. static int NumberOfOperands(Bytecode bytecode) { DCHECK_LE(bytecode, Bytecode::kLast); return kOperandCount[static_cast(bytecode)]; } // Returns the i-th operand of |bytecode|. static OperandType GetOperandType(Bytecode bytecode, int i) { DCHECK_LE(bytecode, Bytecode::kLast); DCHECK_LT(i, NumberOfOperands(bytecode)); DCHECK_GE(i, 0); return GetOperandTypes(bytecode)[i]; } // Returns a pointer to an array of operand types terminated in // OperandType::kNone. static const OperandType* GetOperandTypes(Bytecode bytecode) { DCHECK_LE(bytecode, Bytecode::kLast); return kOperandTypes[static_cast(bytecode)]; } static bool OperandIsScalableSignedByte(Bytecode bytecode, int operand_index) { DCHECK_LE(bytecode, Bytecode::kLast); return kOperandTypeInfos[static_cast(bytecode)][operand_index] == OperandTypeInfo::kScalableSignedByte; } static bool OperandIsScalableUnsignedByte(Bytecode bytecode, int operand_index) { DCHECK_LE(bytecode, Bytecode::kLast); return kOperandTypeInfos[static_cast(bytecode)][operand_index] == OperandTypeInfo::kScalableUnsignedByte; } static bool OperandIsScalable(Bytecode bytecode, int operand_index) { return OperandIsScalableSignedByte(bytecode, operand_index) || OperandIsScalableUnsignedByte(bytecode, operand_index); } // Returns true if the bytecode has wider operand forms. static bool IsBytecodeWithScalableOperands(Bytecode bytecode); // Returns the size of the i-th operand of |bytecode|. static OperandSize GetOperandSize(Bytecode bytecode, int i, OperandScale operand_scale) { CHECK_LT(i, NumberOfOperands(bytecode)); return GetOperandSizes(bytecode, operand_scale)[i]; } // Returns the operand sizes of |bytecode| with scale |operand_scale|. static const OperandSize* GetOperandSizes(Bytecode bytecode, OperandScale operand_scale) { DCHECK_LE(bytecode, Bytecode::kLast); DCHECK_GE(operand_scale, OperandScale::kSingle); DCHECK_LE(operand_scale, OperandScale::kLast); STATIC_ASSERT(static_cast(OperandScale::kQuadruple) == 4 && OperandScale::kLast == OperandScale::kQuadruple); int scale_index = static_cast(operand_scale) >> 1; return kOperandSizes[scale_index][static_cast(bytecode)]; } // Returns the offset of the i-th operand of |bytecode| relative to the start // of the bytecode. static int GetOperandOffset(Bytecode bytecode, int i, OperandScale operand_scale); // Returns the size of the bytecode including its operands for the // given |operand_scale|. static int Size(Bytecode bytecode, OperandScale operand_scale) { DCHECK_LE(bytecode, Bytecode::kLast); STATIC_ASSERT(static_cast(OperandScale::kQuadruple) == 4 && OperandScale::kLast == OperandScale::kQuadruple); int scale_index = static_cast(operand_scale) >> 1; return kBytecodeSizes[scale_index][static_cast(bytecode)]; } // Returns a debug break bytecode to replace |bytecode|. static Bytecode GetDebugBreak(Bytecode bytecode); // Returns the equivalent jump bytecode without the accumulator coercion. static Bytecode GetJumpWithoutToBoolean(Bytecode bytecode); // Returns true if there is a call in the most-frequently executed path // through the bytecode's handler. static bool MakesCallAlongCriticalPath(Bytecode bytecode); // Returns the receiver mode of the given call bytecode. static ConvertReceiverMode GetReceiverMode(Bytecode bytecode) { DCHECK(IsCallOrConstruct(bytecode) || bytecode == Bytecode::kInvokeIntrinsic); switch (bytecode) { case Bytecode::kCallProperty: case Bytecode::kCallProperty0: case Bytecode::kCallProperty1: case Bytecode::kCallProperty2: return ConvertReceiverMode::kNotNullOrUndefined; case Bytecode::kCallUndefinedReceiver: case Bytecode::kCallUndefinedReceiver0: case Bytecode::kCallUndefinedReceiver1: case Bytecode::kCallUndefinedReceiver2: case Bytecode::kCallJSRuntime: return ConvertReceiverMode::kNullOrUndefined; case Bytecode::kCallAnyReceiver: case Bytecode::kCallNoFeedback: case Bytecode::kConstruct: case Bytecode::kCallWithSpread: case Bytecode::kConstructWithSpread: case Bytecode::kInvokeIntrinsic: return ConvertReceiverMode::kAny; default: UNREACHABLE(); } } // Returns true if the bytecode is a debug break. static bool IsDebugBreak(Bytecode bytecode); // Returns true if |operand_type| is any type of register operand. static bool IsRegisterOperandType(OperandType operand_type); // Returns true if |operand_type| represents a register used as an input. static bool IsRegisterInputOperandType(OperandType operand_type); // Returns true if |operand_type| represents a register used as an output. static bool IsRegisterOutputOperandType(OperandType operand_type); // Returns true if |operand_type| represents a register list operand. static bool IsRegisterListOperandType(OperandType operand_type); // Returns true if the handler for |bytecode| should look ahead and inline a // dispatch to a Star bytecode. static bool IsStarLookahead(Bytecode bytecode, OperandScale operand_scale); // Returns the number of registers represented by a register operand. For // instance, a RegPair represents two registers. Should not be called for // kRegList which has a variable number of registers based on the following // kRegCount operand. static int GetNumberOfRegistersRepresentedBy(OperandType operand_type) { switch (operand_type) { case OperandType::kReg: case OperandType::kRegOut: return 1; case OperandType::kRegPair: case OperandType::kRegOutPair: return 2; case OperandType::kRegOutTriple: return 3; case OperandType::kRegList: case OperandType::kRegOutList: UNREACHABLE(); default: return 0; } UNREACHABLE(); } // Returns the size of |operand_type| for |operand_scale|. static OperandSize SizeOfOperand(OperandType operand_type, OperandScale operand_scale) { DCHECK_LE(operand_type, OperandType::kLast); DCHECK_GE(operand_scale, OperandScale::kSingle); DCHECK_LE(operand_scale, OperandScale::kLast); STATIC_ASSERT(static_cast(OperandScale::kQuadruple) == 4 && OperandScale::kLast == OperandScale::kQuadruple); int scale_index = static_cast(operand_scale) >> 1; return kOperandKindSizes[scale_index][static_cast(operand_type)]; } // Returns true if |operand_type| is a runtime-id operand (kRuntimeId). static bool IsRuntimeIdOperandType(OperandType operand_type); // Returns true if |operand_type| is unsigned, false if signed. static bool IsUnsignedOperandType(OperandType operand_type); // Returns true if a handler is generated for a bytecode at a given // operand scale. All bytecodes have handlers at OperandScale::kSingle, // but only bytecodes with scalable operands have handlers with larger // OperandScale values. static bool BytecodeHasHandler(Bytecode bytecode, OperandScale operand_scale); // Return the operand scale required to hold a signed operand with |value|. static OperandScale ScaleForSignedOperand(int32_t value) { if (value >= kMinInt8 && value <= kMaxInt8) { return OperandScale::kSingle; } else if (value >= kMinInt16 && value <= kMaxInt16) { return OperandScale::kDouble; } else { return OperandScale::kQuadruple; } } // Return the operand scale required to hold an unsigned operand with |value|. static OperandScale ScaleForUnsignedOperand(uint32_t value) { if (value <= kMaxUInt8) { return OperandScale::kSingle; } else if (value <= kMaxUInt16) { return OperandScale::kDouble; } else { return OperandScale::kQuadruple; } } // Return the operand size required to hold an unsigned operand with |value|. static OperandSize SizeForUnsignedOperand(uint32_t value) { if (value <= kMaxUInt8) { return OperandSize::kByte; } else if (value <= kMaxUInt16) { return OperandSize::kShort; } else { return OperandSize::kQuad; } } static Address bytecode_size_table_address() { return reinterpret_cast

(const_cast(&kBytecodeSizes[0][0])); } private: static const OperandType* const kOperandTypes[]; static const OperandTypeInfo* const kOperandTypeInfos[]; static const int kOperandCount[]; static const int kNumberOfRegisterOperands[]; static const AccumulatorUse kAccumulatorUse[]; static const bool kIsScalable[]; static const int kBytecodeSizes[3][kBytecodeCount]; static const OperandSize* const kOperandSizes[3][kBytecodeCount]; static OperandSize const kOperandKindSizes[3][BytecodeOperands::kOperandTypeCount]; }; V8_EXPORT_PRIVATE std::ostream& operator<<(std::ostream& os, const Bytecode& bytecode); } // namespace interpreter } // namespace internal } // namespace v8 #endif // V8_INTERPRETER_BYTECODES_H_