src/interpreter/interpreter-assembler.h - v8/v8 - Git at Google

 // 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_INTERPRETER_ASSEMBLER_H_
 #define V8_INTERPRETER_INTERPRETER_ASSEMBLER_H_

 #include "src/builtins/builtins.h"
 #include "src/codegen/code-stub-assembler.h"
 #include "src/common/globals.h"
 #include "src/interpreter/bytecode-register.h"
 #include "src/interpreter/bytecodes.h"
 #include "src/runtime/runtime.h"
 #include "src/utils/allocation.h"

 namespace v8 {
 namespace internal {
 namespace interpreter {

 class V8_EXPORT_PRIVATE InterpreterAssembler : public CodeStubAssembler {
  public:
   InterpreterAssembler(compiler::CodeAssemblerState* state, Bytecode bytecode,
                        OperandScale operand_scale);
   ~InterpreterAssembler();

   // Returns the 32-bit unsigned count immediate for bytecode operand
   // |operand_index| in the current bytecode.
   TNode<Uint32T> BytecodeOperandCount(int operand_index);
   // Returns the 32-bit unsigned flag for bytecode operand |operand_index|
   // in the current bytecode.
   TNode<Uint32T> BytecodeOperandFlag(int operand_index);
   // Returns the 32-bit zero-extended index immediate for bytecode operand
   // |operand_index| in the current bytecode.
   TNode<Uint32T> BytecodeOperandIdxInt32(int operand_index);
   // Returns the word zero-extended index immediate for bytecode operand
   // |operand_index| in the current bytecode.
   TNode<UintPtrT> BytecodeOperandIdx(int operand_index);
   // Returns the smi index immediate for bytecode operand |operand_index|
   // in the current bytecode.
   TNode<Smi> BytecodeOperandIdxSmi(int operand_index);
   // Returns the 32-bit unsigned immediate for bytecode operand |operand_index|
   // in the current bytecode.
   TNode<Uint32T> BytecodeOperandUImm(int operand_index);
   // Returns the word-size unsigned immediate for bytecode operand
   // |operand_index| in the current bytecode.
   TNode<UintPtrT> BytecodeOperandUImmWord(int operand_index);
   // Returns the unsigned smi immediate for bytecode operand |operand_index| in
   // the current bytecode.
   TNode<Smi> BytecodeOperandUImmSmi(int operand_index);
   // Returns the 32-bit signed immediate for bytecode operand |operand_index|
   // in the current bytecode.
   TNode<Int32T> BytecodeOperandImm(int operand_index);
   // Returns the word-size signed immediate for bytecode operand |operand_index|
   // in the current bytecode.
   TNode<IntPtrT> BytecodeOperandImmIntPtr(int operand_index);
   // Returns the smi immediate for bytecode operand |operand_index| in the
   // current bytecode.
   TNode<Smi> BytecodeOperandImmSmi(int operand_index);
   // Returns the 32-bit unsigned runtime id immediate for bytecode operand
   // |operand_index| in the current bytecode.
   TNode<Uint32T> BytecodeOperandRuntimeId(int operand_index);
   // Returns the word zero-extended native context index immediate for bytecode
   // operand |operand_index| in the current bytecode.
   TNode<UintPtrT> BytecodeOperandNativeContextIndex(int operand_index);
   // Returns the 32-bit unsigned intrinsic id immediate for bytecode operand
   // |operand_index| in the current bytecode.
   TNode<Uint32T> BytecodeOperandIntrinsicId(int operand_index);
   // Accumulator.
   TNode<Object> GetAccumulator();
   void SetAccumulator(TNode<Object> value);

   // Context.
   TNode<Context> GetContext();
   void SetContext(TNode<Context> value);

   // Context at |depth| in the context chain starting at |context|.
   TNode<Context> GetContextAtDepth(TNode<Context> context,
                                    TNode<Uint32T> depth);

   // Goto the given |target| if the context chain starting at |context| has any
   // extensions up to the given |depth|.
   void GotoIfHasContextExtensionUpToDepth(TNode<Context> context,
                                           TNode<Uint32T> depth, Label* target);

   // A RegListNodePair provides an abstraction over lists of registers.
   class RegListNodePair {
    public:
     RegListNodePair(TNode<IntPtrT> base_reg_location, TNode<Word32T> reg_count)
         : base_reg_location_(base_reg_location), reg_count_(reg_count) {}

     TNode<Word32T> reg_count() const { return reg_count_; }
     TNode<IntPtrT> base_reg_location() const { return base_reg_location_; }

    private:
     TNode<IntPtrT> base_reg_location_;
     TNode<Word32T> reg_count_;
   };

   // Backup/restore register file to/from a fixed array of the correct length.
   // There is an asymmetry between suspend/export and resume/import.
   // - Suspend copies arguments and registers to the generator.
   // - Resume copies only the registers from the generator, the arguments
   //   are copied by the ResumeGenerator trampoline.
   TNode<FixedArray> ExportParametersAndRegisterFile(
       TNode<FixedArray> array, const RegListNodePair& registers,
       TNode<Int32T> formal_parameter_count);
   TNode<FixedArray> ImportRegisterFile(TNode<FixedArray> array,
                                        const RegListNodePair& registers,
                                        TNode<Int32T> formal_parameter_count);

   // Loads from and stores to the interpreter register file.
   TNode<Object> LoadRegister(Register reg);
   TNode<IntPtrT> LoadAndUntagRegister(Register reg);
   TNode<Object> LoadRegisterAtOperandIndex(int operand_index);
   std::pair<TNode<Object>, TNode<Object>> LoadRegisterPairAtOperandIndex(
       int operand_index);
   void StoreRegister(TNode<Object> value, Register reg);
   void StoreRegisterAtOperandIndex(TNode<Object> value, int operand_index);
   void StoreRegisterPairAtOperandIndex(TNode<Object> value1,
                                        TNode<Object> value2, int operand_index);
   void StoreRegisterTripleAtOperandIndex(TNode<Object> value1,
                                          TNode<Object> value2,
                                          TNode<Object> value3,
                                          int operand_index);

   RegListNodePair GetRegisterListAtOperandIndex(int operand_index);
   TNode<Object> LoadRegisterFromRegisterList(const RegListNodePair& reg_list,
                                              int index);
   TNode<IntPtrT> RegisterLocationInRegisterList(const RegListNodePair& reg_list,
                                                 int index);

   // Load constant at the index specified in operand |operand_index| from the
   // constant pool.
   TNode<Object> LoadConstantPoolEntryAtOperandIndex(int operand_index);
   // Load and untag constant at the index specified in operand |operand_index|
   // from the constant pool.
   TNode<IntPtrT> LoadAndUntagConstantPoolEntryAtOperandIndex(int operand_index);
   // Load constant at |index| in the constant pool.
   TNode<Object> LoadConstantPoolEntry(TNode<WordT> index);
   // Load and untag constant at |index| in the constant pool.
   TNode<IntPtrT> LoadAndUntagConstantPoolEntry(TNode<WordT> index);

   // Load the FeedbackVector for the current function. The retuned node could be
   // undefined.
   TNode<HeapObject> LoadFeedbackVector();

   // Call JSFunction or Callable |function| with |args| arguments, possibly
   // including the receiver depending on |receiver_mode|. After the call returns
   // directly dispatches to the next bytecode.
   void CallJSAndDispatch(TNode<Object> function, TNode<Context> context,
                          const RegListNodePair& args,
                          ConvertReceiverMode receiver_mode);

   // Call JSFunction or Callable |function| with |arg_count| arguments (not
   // including receiver) passed as |args|, possibly including the receiver
   // depending on |receiver_mode|. After the call returns directly dispatches to
   // the next bytecode.
   template <class... TArgs>
   void CallJSAndDispatch(TNode<Object> function, TNode<Context> context,
                          TNode<Word32T> arg_count,
                          ConvertReceiverMode receiver_mode, TArgs... args);

   // Call JSFunction or Callable |function| with |args|
   // arguments (not including receiver), and the final argument being spread.
   // After the call returns directly dispatches to the next bytecode.
   void CallJSWithSpreadAndDispatch(TNode<Object> function,
                                    TNode<Context> context,
                                    const RegListNodePair& args,
                                    TNode<UintPtrT> slot_id,
                                    TNode<HeapObject> maybe_feedback_vector);

   // Call constructor |target| with |args| arguments (not including receiver).
   // The |new_target| is the same as the |target| for the new keyword, but
   // differs for the super keyword.
   TNode<Object> Construct(TNode<Object> target, TNode<Context> context,
                           TNode<Object> new_target, const RegListNodePair& args,
                           TNode<UintPtrT> slot_id,
                           TNode<HeapObject> maybe_feedback_vector);

   // Call constructor |target| with |args| arguments (not including
   // receiver). The last argument is always a spread. The |new_target| is the
   // same as the |target| for the new keyword, but differs for the super
   // keyword.
   TNode<Object> ConstructWithSpread(TNode<Object> target,
                                     TNode<Context> context,
                                     TNode<Object> new_target,
                                     const RegListNodePair& args,
                                     TNode<UintPtrT> slot_id,
                                     TNode<HeapObject> maybe_feedback_vector);

   // Call runtime function with |args| arguments which will return |return_size|
   // number of values.
   compiler::Node* CallRuntimeN(TNode<Uint32T> function_id,
                                TNode<Context> context,
                                const RegListNodePair& args,
                                int return_size = 1);

   // Jump forward relative to the current bytecode by the |jump_offset|.
   void Jump(TNode<IntPtrT> jump_offset);

   // Jump backward relative to the current bytecode by the |jump_offset|.
   void JumpBackward(TNode<IntPtrT> jump_offset);

   // Jump forward relative to the current bytecode by |jump_offset| if the
   // word values |lhs| and |rhs| are equal.
   void JumpIfTaggedEqual(TNode<Object> lhs, TNode<Object> rhs,
                          TNode<IntPtrT> jump_offset);

   // Jump forward relative to the current bytecode by |jump_offset| if the
   // word values |lhs| and |rhs| are not equal.
   void JumpIfTaggedNotEqual(TNode<Object> lhs, TNode<Object> rhs,
                             TNode<IntPtrT> jump_offset);

   // Updates the profiler interrupt budget for a return.
   void UpdateInterruptBudgetOnReturn();

   // Returns the OSR nesting level from the bytecode header.
   TNode<Int8T> LoadOsrNestingLevel();

   // Dispatch to the bytecode.
   void Dispatch();

   // Dispatch bytecode as wide operand variant.
   void DispatchWide(OperandScale operand_scale);

   // Dispatch to |target_bytecode| at |new_bytecode_offset|.
   // |target_bytecode| should be equivalent to loading from the offset.
   void DispatchToBytecode(TNode<WordT> target_bytecode,
                           TNode<IntPtrT> new_bytecode_offset);

   // Abort with the given abort reason.
   void Abort(AbortReason abort_reason);
   void AbortIfWordNotEqual(TNode<WordT> lhs, TNode<WordT> rhs,
                            AbortReason abort_reason);
   // Abort if |register_count| is invalid for given register file array.
   void AbortIfRegisterCountInvalid(
       TNode<FixedArrayBase> parameters_and_registers,
       TNode<IntPtrT> formal_parameter_count, TNode<UintPtrT> register_count);

   // Dispatch to frame dropper trampoline if necessary.
   void MaybeDropFrames(TNode<Context> context);

   // Returns the offset from the BytecodeArrayPointer of the current bytecode.
   TNode<IntPtrT> BytecodeOffset();

  protected:
   Bytecode bytecode() const { return bytecode_; }
   static bool TargetSupportsUnalignedAccess();

   void ToNumberOrNumeric(Object::Conversion mode);

  private:
   // Returns a pointer to the current function's BytecodeArray object.
   TNode<BytecodeArray> BytecodeArrayTaggedPointer();

   // Returns a pointer to first entry in the interpreter dispatch table.
   TNode<ExternalReference> DispatchTablePointer();

   // Returns the accumulator value without checking whether bytecode
   // uses it. This is intended to be used only in dispatch and in
   // tracing as these need to bypass accumulator use validity checks.
   TNode<Object> GetAccumulatorUnchecked();

   // Returns the frame pointer for the interpreted frame of the function being
   // interpreted.
   TNode<RawPtrT> GetInterpretedFramePointer();

   // Operations on registers.
   TNode<IntPtrT> RegisterLocation(Register reg);
   TNode<IntPtrT> RegisterLocation(TNode<IntPtrT> reg_index);
   TNode<IntPtrT> NextRegister(TNode<IntPtrT> reg_index);
   TNode<Object> LoadRegister(TNode<IntPtrT> reg_index);
   void StoreRegister(TNode<Object> value, TNode<IntPtrT> reg_index);

   // Saves and restores interpreter bytecode offset to the interpreter stack
   // frame when performing a call.
   void CallPrologue();
   void CallEpilogue();

   // Increment the dispatch counter for the (current, next) bytecode pair.
   void TraceBytecodeDispatch(TNode<WordT> target_bytecode);

   // Traces the current bytecode by calling |function_id|.
   void TraceBytecode(Runtime::FunctionId function_id);

   // Updates the bytecode array's interrupt budget by a 32-bit unsigned |weight|
   // and calls Runtime::kInterrupt if counter reaches zero. If |backward|, then
   // the interrupt budget is decremented, otherwise it is incremented.
   void UpdateInterruptBudget(TNode<Int32T> weight, bool backward);

   // Returns the offset of register |index| relative to RegisterFilePointer().
   TNode<IntPtrT> RegisterFrameOffset(TNode<IntPtrT> index);

   // Returns the offset of an operand relative to the current bytecode offset.
   TNode<IntPtrT> OperandOffset(int operand_index);

   // Returns a value built from an sequence of bytes in the bytecode
   // array starting at |relative_offset| from the current bytecode.
   // The |result_type| determines the size and signedness.  of the
   // value read. This method should only be used on architectures that
   // do not support unaligned memory accesses.
   TNode<Word32T> BytecodeOperandReadUnaligned(
       int relative_offset, MachineType result_type,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

   // Returns zero- or sign-extended to word32 value of the operand.
   TNode<Uint8T> BytecodeOperandUnsignedByte(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
   TNode<Int8T> BytecodeOperandSignedByte(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
   TNode<Uint16T> BytecodeOperandUnsignedShort(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
   TNode<Int16T> BytecodeOperandSignedShort(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
   TNode<Uint32T> BytecodeOperandUnsignedQuad(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
   TNode<Int32T> BytecodeOperandSignedQuad(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

   // Returns zero- or sign-extended to word32 value of the operand of
   // given size.
   TNode<Int32T> BytecodeSignedOperand(
       int operand_index, OperandSize operand_size,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
   TNode<Uint32T> BytecodeUnsignedOperand(
       int operand_index, OperandSize operand_size,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

   // Returns the word-size sign-extended register index for bytecode operand
   // |operand_index| in the current bytecode. Value is not poisoned on
   // speculation since the value loaded from the register is poisoned instead.
   TNode<IntPtrT> BytecodeOperandReg(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

   // Returns the word zero-extended index immediate for bytecode operand
   // |operand_index| in the current bytecode for use when loading a .
   TNode<UintPtrT> BytecodeOperandConstantPoolIdx(
       int operand_index,
       LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

   // Jump relative to the current bytecode by the |jump_offset|. If |backward|,
   // then jump backward (subtract the offset), otherwise jump forward (add the
   // offset). Helper function for Jump and JumpBackward.
   void Jump(TNode<IntPtrT> jump_offset, bool backward);

   // Jump forward relative to the current bytecode by |jump_offset| if the
   // |condition| is true. Helper function for JumpIfTaggedEqual and
   // JumpIfTaggedNotEqual.
   void JumpConditional(TNode<BoolT> condition, TNode<IntPtrT> jump_offset);

   // Save the bytecode offset to the interpreter frame.
   void SaveBytecodeOffset();
   // Reload the bytecode offset from the interpreter frame.
   TNode<IntPtrT> ReloadBytecodeOffset();

   // Updates and returns BytecodeOffset() advanced by the current bytecode's
   // size. Traces the exit of the current bytecode.
   TNode<IntPtrT> Advance();

   // Updates and returns BytecodeOffset() advanced by delta bytecodes.
   // Traces the exit of the current bytecode.
   TNode<IntPtrT> Advance(int delta);
   TNode<IntPtrT> Advance(TNode<IntPtrT> delta, bool backward = false);

   // Load the bytecode at |bytecode_offset|.
   TNode<WordT> LoadBytecode(TNode<IntPtrT> bytecode_offset);

   // Look ahead for Star and inline it in a branch. Returns a new target
   // bytecode node for dispatch.
   TNode<WordT> StarDispatchLookahead(TNode<WordT> target_bytecode);

   // Build code for Star at the current BytecodeOffset() and Advance() to the
   // next dispatch offset.
   void InlineStar();

   // Dispatch to the bytecode handler with code entry point |handler_entry|.
   void DispatchToBytecodeHandlerEntry(TNode<RawPtrT> handler_entry,
                                       TNode<IntPtrT> bytecode_offset);

   int CurrentBytecodeSize() const;

   OperandScale operand_scale() const { return operand_scale_; }

   Bytecode bytecode_;
   OperandScale operand_scale_;
   CodeStubAssembler::TVariable<RawPtrT> interpreted_frame_pointer_;
   CodeStubAssembler::TVariable<BytecodeArray> bytecode_array_;
   CodeStubAssembler::TVariable<IntPtrT> bytecode_offset_;
   CodeStubAssembler::TVariable<ExternalReference> dispatch_table_;
   CodeStubAssembler::TVariable<Object> accumulator_;
   AccumulatorUse accumulator_use_;
   bool made_call_;
   bool reloaded_frame_ptr_;
   bool bytecode_array_valid_;

   DISALLOW_COPY_AND_ASSIGN(InterpreterAssembler);
 };

 }  // namespace interpreter
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_INTERPRETER_INTERPRETER_ASSEMBLER_H_
	// 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_INTERPRETER_ASSEMBLER_H_
	#define V8_INTERPRETER_INTERPRETER_ASSEMBLER_H_

	#include "src/builtins/builtins.h"
	#include "src/codegen/code-stub-assembler.h"
	#include "src/common/globals.h"
	#include "src/interpreter/bytecode-register.h"
	#include "src/interpreter/bytecodes.h"
	#include "src/runtime/runtime.h"
	#include "src/utils/allocation.h"

	namespace v8 {
	namespace internal {
	namespace interpreter {

	class V8_EXPORT_PRIVATE InterpreterAssembler : public CodeStubAssembler {
	public:
	InterpreterAssembler(compiler::CodeAssemblerState* state, Bytecode bytecode,
	OperandScale operand_scale);
	~InterpreterAssembler();

	// Returns the 32-bit unsigned count immediate for bytecode operand
	// \|operand_index\| in the current bytecode.
	TNode<Uint32T> BytecodeOperandCount(int operand_index);
	// Returns the 32-bit unsigned flag for bytecode operand \|operand_index\|
	// in the current bytecode.
	TNode<Uint32T> BytecodeOperandFlag(int operand_index);
	// Returns the 32-bit zero-extended index immediate for bytecode operand
	// \|operand_index\| in the current bytecode.
	TNode<Uint32T> BytecodeOperandIdxInt32(int operand_index);
	// Returns the word zero-extended index immediate for bytecode operand
	// \|operand_index\| in the current bytecode.
	TNode<UintPtrT> BytecodeOperandIdx(int operand_index);
	// Returns the smi index immediate for bytecode operand \|operand_index\|
	// in the current bytecode.
	TNode<Smi> BytecodeOperandIdxSmi(int operand_index);
	// Returns the 32-bit unsigned immediate for bytecode operand \|operand_index\|
	// in the current bytecode.
	TNode<Uint32T> BytecodeOperandUImm(int operand_index);
	// Returns the word-size unsigned immediate for bytecode operand
	// \|operand_index\| in the current bytecode.
	TNode<UintPtrT> BytecodeOperandUImmWord(int operand_index);
	// Returns the unsigned smi immediate for bytecode operand \|operand_index\| in
	// the current bytecode.
	TNode<Smi> BytecodeOperandUImmSmi(int operand_index);
	// Returns the 32-bit signed immediate for bytecode operand \|operand_index\|
	// in the current bytecode.
	TNode<Int32T> BytecodeOperandImm(int operand_index);
	// Returns the word-size signed immediate for bytecode operand \|operand_index\|
	// in the current bytecode.
	TNode<IntPtrT> BytecodeOperandImmIntPtr(int operand_index);
	// Returns the smi immediate for bytecode operand \|operand_index\| in the
	// current bytecode.
	TNode<Smi> BytecodeOperandImmSmi(int operand_index);
	// Returns the 32-bit unsigned runtime id immediate for bytecode operand
	// \|operand_index\| in the current bytecode.
	TNode<Uint32T> BytecodeOperandRuntimeId(int operand_index);
	// Returns the word zero-extended native context index immediate for bytecode
	// operand \|operand_index\| in the current bytecode.
	TNode<UintPtrT> BytecodeOperandNativeContextIndex(int operand_index);
	// Returns the 32-bit unsigned intrinsic id immediate for bytecode operand
	// \|operand_index\| in the current bytecode.
	TNode<Uint32T> BytecodeOperandIntrinsicId(int operand_index);
	// Accumulator.
	TNode<Object> GetAccumulator();
	void SetAccumulator(TNode<Object> value);

	// Context.
	TNode<Context> GetContext();
	void SetContext(TNode<Context> value);

	// Context at \|depth\| in the context chain starting at \|context\|.
	TNode<Context> GetContextAtDepth(TNode<Context> context,
	TNode<Uint32T> depth);

	// Goto the given \|target\| if the context chain starting at \|context\| has any
	// extensions up to the given \|depth\|.
	void GotoIfHasContextExtensionUpToDepth(TNode<Context> context,
	TNode<Uint32T> depth, Label* target);

	// A RegListNodePair provides an abstraction over lists of registers.
	class RegListNodePair {
	public:
	RegListNodePair(TNode<IntPtrT> base_reg_location, TNode<Word32T> reg_count)
	: base_reg_location_(base_reg_location), reg_count_(reg_count) {}

	TNode<Word32T> reg_count() const { return reg_count_; }
	TNode<IntPtrT> base_reg_location() const { return base_reg_location_; }

	private:
	TNode<IntPtrT> base_reg_location_;
	TNode<Word32T> reg_count_;
	};

	// Backup/restore register file to/from a fixed array of the correct length.
	// There is an asymmetry between suspend/export and resume/import.
	// - Suspend copies arguments and registers to the generator.
	// - Resume copies only the registers from the generator, the arguments
	// are copied by the ResumeGenerator trampoline.
	TNode<FixedArray> ExportParametersAndRegisterFile(
	TNode<FixedArray> array, const RegListNodePair& registers,
	TNode<Int32T> formal_parameter_count);
	TNode<FixedArray> ImportRegisterFile(TNode<FixedArray> array,
	const RegListNodePair& registers,
	TNode<Int32T> formal_parameter_count);

	// Loads from and stores to the interpreter register file.
	TNode<Object> LoadRegister(Register reg);
	TNode<IntPtrT> LoadAndUntagRegister(Register reg);
	TNode<Object> LoadRegisterAtOperandIndex(int operand_index);
	std::pair<TNode<Object>, TNode<Object>> LoadRegisterPairAtOperandIndex(
	int operand_index);
	void StoreRegister(TNode<Object> value, Register reg);
	void StoreRegisterAtOperandIndex(TNode<Object> value, int operand_index);
	void StoreRegisterPairAtOperandIndex(TNode<Object> value1,
	TNode<Object> value2, int operand_index);
	void StoreRegisterTripleAtOperandIndex(TNode<Object> value1,
	TNode<Object> value2,
	TNode<Object> value3,
	int operand_index);

	RegListNodePair GetRegisterListAtOperandIndex(int operand_index);
	TNode<Object> LoadRegisterFromRegisterList(const RegListNodePair& reg_list,
	int index);
	TNode<IntPtrT> RegisterLocationInRegisterList(const RegListNodePair& reg_list,
	int index);

	// Load constant at the index specified in operand \|operand_index\| from the
	// constant pool.
	TNode<Object> LoadConstantPoolEntryAtOperandIndex(int operand_index);
	// Load and untag constant at the index specified in operand \|operand_index\|
	// from the constant pool.
	TNode<IntPtrT> LoadAndUntagConstantPoolEntryAtOperandIndex(int operand_index);
	// Load constant at \|index\| in the constant pool.
	TNode<Object> LoadConstantPoolEntry(TNode<WordT> index);
	// Load and untag constant at \|index\| in the constant pool.
	TNode<IntPtrT> LoadAndUntagConstantPoolEntry(TNode<WordT> index);

	// Load the FeedbackVector for the current function. The retuned node could be
	// undefined.
	TNode<HeapObject> LoadFeedbackVector();

	// Call JSFunction or Callable \|function\| with \|args\| arguments, possibly
	// including the receiver depending on \|receiver_mode\|. After the call returns
	// directly dispatches to the next bytecode.
	void CallJSAndDispatch(TNode<Object> function, TNode<Context> context,
	const RegListNodePair& args,
	ConvertReceiverMode receiver_mode);

	// Call JSFunction or Callable \|function\| with \|arg_count\| arguments (not
	// including receiver) passed as \|args\|, possibly including the receiver
	// depending on \|receiver_mode\|. After the call returns directly dispatches to
	// the next bytecode.
	template <class... TArgs>
	void CallJSAndDispatch(TNode<Object> function, TNode<Context> context,
	TNode<Word32T> arg_count,
	ConvertReceiverMode receiver_mode, TArgs... args);

	// Call JSFunction or Callable \|function\| with \|args\|
	// arguments (not including receiver), and the final argument being spread.
	// After the call returns directly dispatches to the next bytecode.
	void CallJSWithSpreadAndDispatch(TNode<Object> function,
	TNode<Context> context,
	const RegListNodePair& args,
	TNode<UintPtrT> slot_id,
	TNode<HeapObject> maybe_feedback_vector);

	// Call constructor \|target\| with \|args\| arguments (not including receiver).
	// The \|new_target\| is the same as the \|target\| for the new keyword, but
	// differs for the super keyword.
	TNode<Object> Construct(TNode<Object> target, TNode<Context> context,
	TNode<Object> new_target, const RegListNodePair& args,
	TNode<UintPtrT> slot_id,
	TNode<HeapObject> maybe_feedback_vector);

	// Call constructor \|target\| with \|args\| arguments (not including
	// receiver). The last argument is always a spread. The \|new_target\| is the
	// same as the \|target\| for the new keyword, but differs for the super
	// keyword.
	TNode<Object> ConstructWithSpread(TNode<Object> target,
	TNode<Context> context,
	TNode<Object> new_target,
	const RegListNodePair& args,
	TNode<UintPtrT> slot_id,
	TNode<HeapObject> maybe_feedback_vector);

	// Call runtime function with \|args\| arguments which will return \|return_size\|
	// number of values.
	compiler::Node* CallRuntimeN(TNode<Uint32T> function_id,
	TNode<Context> context,
	const RegListNodePair& args,
	int return_size = 1);

	// Jump forward relative to the current bytecode by the \|jump_offset\|.
	void Jump(TNode<IntPtrT> jump_offset);

	// Jump backward relative to the current bytecode by the \|jump_offset\|.
	void JumpBackward(TNode<IntPtrT> jump_offset);

	// Jump forward relative to the current bytecode by \|jump_offset\| if the
	// word values \|lhs\| and \|rhs\| are equal.
	void JumpIfTaggedEqual(TNode<Object> lhs, TNode<Object> rhs,
	TNode<IntPtrT> jump_offset);

	// Jump forward relative to the current bytecode by \|jump_offset\| if the
	// word values \|lhs\| and \|rhs\| are not equal.
	void JumpIfTaggedNotEqual(TNode<Object> lhs, TNode<Object> rhs,
	TNode<IntPtrT> jump_offset);

	// Updates the profiler interrupt budget for a return.
	void UpdateInterruptBudgetOnReturn();

	// Returns the OSR nesting level from the bytecode header.
	TNode<Int8T> LoadOsrNestingLevel();

	// Dispatch to the bytecode.
	void Dispatch();

	// Dispatch bytecode as wide operand variant.
	void DispatchWide(OperandScale operand_scale);

	// Dispatch to \|target_bytecode\| at \|new_bytecode_offset\|.
	// \|target_bytecode\| should be equivalent to loading from the offset.
	void DispatchToBytecode(TNode<WordT> target_bytecode,
	TNode<IntPtrT> new_bytecode_offset);

	// Abort with the given abort reason.
	void Abort(AbortReason abort_reason);
	void AbortIfWordNotEqual(TNode<WordT> lhs, TNode<WordT> rhs,
	AbortReason abort_reason);
	// Abort if \|register_count\| is invalid for given register file array.
	void AbortIfRegisterCountInvalid(
	TNode<FixedArrayBase> parameters_and_registers,
	TNode<IntPtrT> formal_parameter_count, TNode<UintPtrT> register_count);

	// Dispatch to frame dropper trampoline if necessary.
	void MaybeDropFrames(TNode<Context> context);

	// Returns the offset from the BytecodeArrayPointer of the current bytecode.
	TNode<IntPtrT> BytecodeOffset();

	protected:
	Bytecode bytecode() const { return bytecode_; }
	static bool TargetSupportsUnalignedAccess();

	void ToNumberOrNumeric(Object::Conversion mode);

	private:
	// Returns a pointer to the current function's BytecodeArray object.
	TNode<BytecodeArray> BytecodeArrayTaggedPointer();

	// Returns a pointer to first entry in the interpreter dispatch table.
	TNode<ExternalReference> DispatchTablePointer();

	// Returns the accumulator value without checking whether bytecode
	// uses it. This is intended to be used only in dispatch and in
	// tracing as these need to bypass accumulator use validity checks.
	TNode<Object> GetAccumulatorUnchecked();

	// Returns the frame pointer for the interpreted frame of the function being
	// interpreted.
	TNode<RawPtrT> GetInterpretedFramePointer();

	// Operations on registers.
	TNode<IntPtrT> RegisterLocation(Register reg);
	TNode<IntPtrT> RegisterLocation(TNode<IntPtrT> reg_index);
	TNode<IntPtrT> NextRegister(TNode<IntPtrT> reg_index);
	TNode<Object> LoadRegister(TNode<IntPtrT> reg_index);
	void StoreRegister(TNode<Object> value, TNode<IntPtrT> reg_index);

	// Saves and restores interpreter bytecode offset to the interpreter stack
	// frame when performing a call.
	void CallPrologue();
	void CallEpilogue();

	// Increment the dispatch counter for the (current, next) bytecode pair.
	void TraceBytecodeDispatch(TNode<WordT> target_bytecode);

	// Traces the current bytecode by calling \|function_id\|.
	void TraceBytecode(Runtime::FunctionId function_id);

	// Updates the bytecode array's interrupt budget by a 32-bit unsigned \|weight\|
	// and calls Runtime::kInterrupt if counter reaches zero. If \|backward\|, then
	// the interrupt budget is decremented, otherwise it is incremented.
	void UpdateInterruptBudget(TNode<Int32T> weight, bool backward);

	// Returns the offset of register \|index\| relative to RegisterFilePointer().
	TNode<IntPtrT> RegisterFrameOffset(TNode<IntPtrT> index);

	// Returns the offset of an operand relative to the current bytecode offset.
	TNode<IntPtrT> OperandOffset(int operand_index);

	// Returns a value built from an sequence of bytes in the bytecode
	// array starting at \|relative_offset\| from the current bytecode.
	// The \|result_type\| determines the size and signedness. of the
	// value read. This method should only be used on architectures that
	// do not support unaligned memory accesses.
	TNode<Word32T> BytecodeOperandReadUnaligned(
	int relative_offset, MachineType result_type,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

	// Returns zero- or sign-extended to word32 value of the operand.
	TNode<Uint8T> BytecodeOperandUnsignedByte(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
	TNode<Int8T> BytecodeOperandSignedByte(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
	TNode<Uint16T> BytecodeOperandUnsignedShort(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
	TNode<Int16T> BytecodeOperandSignedShort(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
	TNode<Uint32T> BytecodeOperandUnsignedQuad(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
	TNode<Int32T> BytecodeOperandSignedQuad(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

	// Returns zero- or sign-extended to word32 value of the operand of
	// given size.
	TNode<Int32T> BytecodeSignedOperand(
	int operand_index, OperandSize operand_size,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);
	TNode<Uint32T> BytecodeUnsignedOperand(
	int operand_index, OperandSize operand_size,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

	// Returns the word-size sign-extended register index for bytecode operand
	// \|operand_index\| in the current bytecode. Value is not poisoned on
	// speculation since the value loaded from the register is poisoned instead.
	TNode<IntPtrT> BytecodeOperandReg(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

	// Returns the word zero-extended index immediate for bytecode operand
	// \|operand_index\| in the current bytecode for use when loading a .
	TNode<UintPtrT> BytecodeOperandConstantPoolIdx(
	int operand_index,
	LoadSensitivity needs_poisoning = LoadSensitivity::kCritical);

	// Jump relative to the current bytecode by the \|jump_offset\|. If \|backward\|,
	// then jump backward (subtract the offset), otherwise jump forward (add the
	// offset). Helper function for Jump and JumpBackward.
	void Jump(TNode<IntPtrT> jump_offset, bool backward);

	// Jump forward relative to the current bytecode by \|jump_offset\| if the
	// \|condition\| is true. Helper function for JumpIfTaggedEqual and
	// JumpIfTaggedNotEqual.
	void JumpConditional(TNode<BoolT> condition, TNode<IntPtrT> jump_offset);

	// Save the bytecode offset to the interpreter frame.
	void SaveBytecodeOffset();
	// Reload the bytecode offset from the interpreter frame.
	TNode<IntPtrT> ReloadBytecodeOffset();

	// Updates and returns BytecodeOffset() advanced by the current bytecode's
	// size. Traces the exit of the current bytecode.
	TNode<IntPtrT> Advance();

	// Updates and returns BytecodeOffset() advanced by delta bytecodes.
	// Traces the exit of the current bytecode.
	TNode<IntPtrT> Advance(int delta);
	TNode<IntPtrT> Advance(TNode<IntPtrT> delta, bool backward = false);

	// Load the bytecode at \|bytecode_offset\|.
	TNode<WordT> LoadBytecode(TNode<IntPtrT> bytecode_offset);

	// Look ahead for Star and inline it in a branch. Returns a new target
	// bytecode node for dispatch.
	TNode<WordT> StarDispatchLookahead(TNode<WordT> target_bytecode);

	// Build code for Star at the current BytecodeOffset() and Advance() to the
	// next dispatch offset.
	void InlineStar();

	// Dispatch to the bytecode handler with code entry point \|handler_entry\|.
	void DispatchToBytecodeHandlerEntry(TNode<RawPtrT> handler_entry,
	TNode<IntPtrT> bytecode_offset);

	int CurrentBytecodeSize() const;

	OperandScale operand_scale() const { return operand_scale_; }

	Bytecode bytecode_;
	OperandScale operand_scale_;
	CodeStubAssembler::TVariable<RawPtrT> interpreted_frame_pointer_;
	CodeStubAssembler::TVariable<BytecodeArray> bytecode_array_;
	CodeStubAssembler::TVariable<IntPtrT> bytecode_offset_;
	CodeStubAssembler::TVariable<ExternalReference> dispatch_table_;
	CodeStubAssembler::TVariable<Object> accumulator_;
	AccumulatorUse accumulator_use_;
	bool made_call_;
	bool reloaded_frame_ptr_;
	bool bytecode_array_valid_;

	DISALLOW_COPY_AND_ASSIGN(InterpreterAssembler);
	};

	} // namespace interpreter
	} // namespace internal
	} // namespace v8

	#endif // V8_INTERPRETER_INTERPRETER_ASSEMBLER_H_