src/arm/codegen-arm.h - platform/external/v8 - Git at Google

 // Copyright 2006-2008 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_ARM_CODEGEN_ARM_H_
 #define V8_ARM_CODEGEN_ARM_H_

 namespace v8 {
 namespace internal {

 // Forward declarations
 class DeferredCode;
 class RegisterAllocator;
 class RegisterFile;

 enum InitState { CONST_INIT, NOT_CONST_INIT };
 enum TypeofState { INSIDE_TYPEOF, NOT_INSIDE_TYPEOF };


 // -------------------------------------------------------------------------
 // Reference support

 // A reference is a C++ stack-allocated object that keeps an ECMA
 // reference on the execution stack while in scope. For variables
 // the reference is empty, indicating that it isn't necessary to
 // store state on the stack for keeping track of references to those.
 // For properties, we keep either one (named) or two (indexed) values
 // on the execution stack to represent the reference.

 class Reference BASE_EMBEDDED {
  public:
   // The values of the types is important, see size().
   enum Type { ILLEGAL = -1, SLOT = 0, NAMED = 1, KEYED = 2 };
   Reference(CodeGenerator* cgen, Expression* expression);
   ~Reference();

   Expression* expression() const { return expression_; }
   Type type() const { return type_; }
   void set_type(Type value) {
     ASSERT(type_ == ILLEGAL);
     type_ = value;
   }

   // The size the reference takes up on the stack.
   int size() const { return (type_ == ILLEGAL) ? 0 : type_; }

   bool is_illegal() const { return type_ == ILLEGAL; }
   bool is_slot() const { return type_ == SLOT; }
   bool is_property() const { return type_ == NAMED || type_ == KEYED; }

   // Return the name.  Only valid for named property references.
   Handle<String> GetName();

   // Generate code to push the value of the reference on top of the
   // expression stack.  The reference is expected to be already on top of
   // the expression stack, and it is left in place with its value above it.
   void GetValue(TypeofState typeof_state);

   // Generate code to push the value of a reference on top of the expression
   // stack and then spill the stack frame.  This function is used temporarily
   // while the code generator is being transformed.
   inline void GetValueAndSpill(TypeofState typeof_state);

   // Generate code to store the value on top of the expression stack in the
   // reference.  The reference is expected to be immediately below the value
   // on the expression stack.  The stored value is left in place (with the
   // reference intact below it) to support chained assignments.
   void SetValue(InitState init_state);

  private:
   CodeGenerator* cgen_;
   Expression* expression_;
   Type type_;
 };


 // -------------------------------------------------------------------------
 // Code generation state

 // The state is passed down the AST by the code generator (and back up, in
 // the form of the state of the label pair).  It is threaded through the
 // call stack.  Constructing a state implicitly pushes it on the owning code
 // generator's stack of states, and destroying one implicitly pops it.

 class CodeGenState BASE_EMBEDDED {
  public:
   // Create an initial code generator state.  Destroying the initial state
   // leaves the code generator with a NULL state.
   explicit CodeGenState(CodeGenerator* owner);

   // Create a code generator state based on a code generator's current
   // state.  The new state has its own typeof state and pair of branch
   // labels.
   CodeGenState(CodeGenerator* owner,
                TypeofState typeof_state,
                JumpTarget* true_target,
                JumpTarget* false_target);

   // Destroy a code generator state and restore the owning code generator's
   // previous state.
   ~CodeGenState();

   TypeofState typeof_state() const { return typeof_state_; }
   JumpTarget* true_target() const { return true_target_; }
   JumpTarget* false_target() const { return false_target_; }

  private:
   CodeGenerator* owner_;
   TypeofState typeof_state_;
   JumpTarget* true_target_;
   JumpTarget* false_target_;
   CodeGenState* previous_;
 };


 // -------------------------------------------------------------------------
 // CodeGenerator

 class CodeGenerator: public AstVisitor {
  public:
   // Takes a function literal, generates code for it. This function should only
   // be called by compiler.cc.
   static Handle<Code> MakeCode(FunctionLiteral* fun,
                                Handle<Script> script,
                                bool is_eval);

 #ifdef ENABLE_LOGGING_AND_PROFILING
   static bool ShouldGenerateLog(Expression* type);
 #endif

   static void SetFunctionInfo(Handle<JSFunction> fun,
                               FunctionLiteral* lit,
                               bool is_toplevel,
                               Handle<Script> script);

   // Accessors
   MacroAssembler* masm() { return masm_; }

   VirtualFrame* frame() const { return frame_; }

   bool has_valid_frame() const { return frame_ != NULL; }

   // Set the virtual frame to be new_frame, with non-frame register
   // reference counts given by non_frame_registers.  The non-frame
   // register reference counts of the old frame are returned in
   // non_frame_registers.
   void SetFrame(VirtualFrame* new_frame, RegisterFile* non_frame_registers);

   void DeleteFrame();

   RegisterAllocator* allocator() const { return allocator_; }

   CodeGenState* state() { return state_; }
   void set_state(CodeGenState* state) { state_ = state; }

   void AddDeferred(DeferredCode* code) { deferred_.Add(code); }

   static const int kUnknownIntValue = -1;

   // Number of instructions used for the JS return sequence. The constant is
   // used by the debugger to patch the JS return sequence.
   static const int kJSReturnSequenceLength = 4;

  private:
   // Construction/Destruction
   CodeGenerator(int buffer_size, Handle<Script> script, bool is_eval);
   virtual ~CodeGenerator() { delete masm_; }

   // Accessors
   Scope* scope() const { return scope_; }

   // Generating deferred code.
   void ProcessDeferred();

   bool is_eval() { return is_eval_; }

   // State
   bool has_cc() const  { return cc_reg_ != al; }
   TypeofState typeof_state() const { return state_->typeof_state(); }
   JumpTarget* true_target() const  { return state_->true_target(); }
   JumpTarget* false_target() const  { return state_->false_target(); }

   // We don't track loop nesting level on ARM yet.
   int loop_nesting() const { return 0; }

   // Node visitors.
   void VisitStatements(ZoneList<Statement*>* statements);

 #define DEF_VISIT(type) \
   void Visit##type(type* node);
   AST_NODE_LIST(DEF_VISIT)
 #undef DEF_VISIT

   // Visit a statement and then spill the virtual frame if control flow can
   // reach the end of the statement (ie, it does not exit via break,
   // continue, return, or throw).  This function is used temporarily while
   // the code generator is being transformed.
   inline void VisitAndSpill(Statement* statement);

   // Visit a list of statements and then spill the virtual frame if control
   // flow can reach the end of the list.
   inline void VisitStatementsAndSpill(ZoneList<Statement*>* statements);

   // Main code generation function
   void GenCode(FunctionLiteral* fun);

   // The following are used by class Reference.
   void LoadReference(Reference* ref);
   void UnloadReference(Reference* ref);

   MemOperand ContextOperand(Register context, int index) const {
     return MemOperand(context, Context::SlotOffset(index));
   }

   MemOperand SlotOperand(Slot* slot, Register tmp);

   MemOperand ContextSlotOperandCheckExtensions(Slot* slot,
                                                Register tmp,
                                                Register tmp2,
                                                JumpTarget* slow);

   // Expressions
   MemOperand GlobalObject() const  {
     return ContextOperand(cp, Context::GLOBAL_INDEX);
   }

   void LoadCondition(Expression* x,
                      TypeofState typeof_state,
                      JumpTarget* true_target,
                      JumpTarget* false_target,
                      bool force_cc);
   void Load(Expression* x, TypeofState typeof_state = NOT_INSIDE_TYPEOF);
   void LoadGlobal();
   void LoadGlobalReceiver(Register scratch);

   // Generate code to push the value of an expression on top of the frame
   // and then spill the frame fully to memory.  This function is used
   // temporarily while the code generator is being transformed.
   inline void LoadAndSpill(Expression* expression,
                            TypeofState typeof_state = NOT_INSIDE_TYPEOF);

   // Call LoadCondition and then spill the virtual frame unless control flow
   // cannot reach the end of the expression (ie, by emitting only
   // unconditional jumps to the control targets).
   inline void LoadConditionAndSpill(Expression* expression,
                                     TypeofState typeof_state,
                                     JumpTarget* true_target,
                                     JumpTarget* false_target,
                                     bool force_control);

   // Read a value from a slot and leave it on top of the expression stack.
   void LoadFromSlot(Slot* slot, TypeofState typeof_state);
   void LoadFromGlobalSlotCheckExtensions(Slot* slot,
                                          TypeofState typeof_state,
                                          Register tmp,
                                          Register tmp2,
                                          JumpTarget* slow);

   // Special code for typeof expressions: Unfortunately, we must
   // be careful when loading the expression in 'typeof'
   // expressions. We are not allowed to throw reference errors for
   // non-existing properties of the global object, so we must make it
   // look like an explicit property access, instead of an access
   // through the context chain.
   void LoadTypeofExpression(Expression* x);

   void ToBoolean(JumpTarget* true_target, JumpTarget* false_target);

   void GenericBinaryOperation(Token::Value op,
                               OverwriteMode overwrite_mode,
                               int known_rhs = kUnknownIntValue);
   void Comparison(Condition cc,
                   Expression* left,
                   Expression* right,
                   bool strict = false);

   void SmiOperation(Token::Value op,
                     Handle<Object> value,
                     bool reversed,
                     OverwriteMode mode);

   void CallWithArguments(ZoneList<Expression*>* arguments, int position);

   // Control flow
   void Branch(bool if_true, JumpTarget* target);
   void CheckStack();

   struct InlineRuntimeLUT {
     void (CodeGenerator::*method)(ZoneList<Expression*>*);
     const char* name;
   };

   static InlineRuntimeLUT* FindInlineRuntimeLUT(Handle<String> name);
   bool CheckForInlineRuntimeCall(CallRuntime* node);
   static bool PatchInlineRuntimeEntry(Handle<String> name,
                                       const InlineRuntimeLUT& new_entry,
                                       InlineRuntimeLUT* old_entry);

   Handle<JSFunction> BuildBoilerplate(FunctionLiteral* node);
   void ProcessDeclarations(ZoneList<Declaration*>* declarations);

   Handle<Code> ComputeCallInitialize(int argc, InLoopFlag in_loop);

   // Declare global variables and functions in the given array of
   // name/value pairs.
   void DeclareGlobals(Handle<FixedArray> pairs);

   // Instantiate the function boilerplate.
   void InstantiateBoilerplate(Handle<JSFunction> boilerplate);

   // Support for type checks.
   void GenerateIsSmi(ZoneList<Expression*>* args);
   void GenerateIsNonNegativeSmi(ZoneList<Expression*>* args);
   void GenerateIsArray(ZoneList<Expression*>* args);

   // Support for construct call checks.
   void GenerateIsConstructCall(ZoneList<Expression*>* args);

   // Support for arguments.length and arguments[?].
   void GenerateArgumentsLength(ZoneList<Expression*>* args);
   void GenerateArgumentsAccess(ZoneList<Expression*>* args);

   // Support for accessing the class and value fields of an object.
   void GenerateClassOf(ZoneList<Expression*>* args);
   void GenerateValueOf(ZoneList<Expression*>* args);
   void GenerateSetValueOf(ZoneList<Expression*>* args);

   // Fast support for charCodeAt(n).
   void GenerateFastCharCodeAt(ZoneList<Expression*>* args);

   // Fast support for object equality testing.
   void GenerateObjectEquals(ZoneList<Expression*>* args);

   void GenerateLog(ZoneList<Expression*>* args);

   // Fast support for Math.random().
   void GenerateRandomPositiveSmi(ZoneList<Expression*>* args);

   // Fast support for Math.sin and Math.cos.
   enum MathOp { SIN, COS };
   void GenerateFastMathOp(MathOp op, ZoneList<Expression*>* args);
   inline void GenerateMathSin(ZoneList<Expression*>* args);
   inline void GenerateMathCos(ZoneList<Expression*>* args);

   // Methods used to indicate which source code is generated for. Source
   // positions are collected by the assembler and emitted with the relocation
   // information.
   void CodeForFunctionPosition(FunctionLiteral* fun);
   void CodeForReturnPosition(FunctionLiteral* fun);
   void CodeForStatementPosition(Statement* node);
   void CodeForSourcePosition(int pos);

 #ifdef DEBUG
   // True if the registers are valid for entry to a block.
   bool HasValidEntryRegisters();
 #endif

   bool is_eval_;  // Tells whether code is generated for eval.

   Handle<Script> script_;
   List<DeferredCode*> deferred_;

   // Assembler
   MacroAssembler* masm_;  // to generate code

   // Code generation state
   Scope* scope_;
   VirtualFrame* frame_;
   RegisterAllocator* allocator_;
   Condition cc_reg_;
   CodeGenState* state_;

   // Jump targets
   BreakTarget function_return_;

   // True if the function return is shadowed (ie, jumping to the target
   // function_return_ does not jump to the true function return, but rather
   // to some unlinking code).
   bool function_return_is_shadowed_;

   static InlineRuntimeLUT kInlineRuntimeLUT[];

   friend class VirtualFrame;
   friend class JumpTarget;
   friend class Reference;

   DISALLOW_COPY_AND_ASSIGN(CodeGenerator);
 };


 class GenericBinaryOpStub : public CodeStub {
  public:
   GenericBinaryOpStub(Token::Value op,
                       OverwriteMode mode,
                       int constant_rhs = CodeGenerator::kUnknownIntValue)
       : op_(op),
         mode_(mode),
         constant_rhs_(constant_rhs),
         specialized_on_rhs_(RhsIsOneWeWantToOptimizeFor(op, constant_rhs)) { }

  private:
   Token::Value op_;
   OverwriteMode mode_;
   int constant_rhs_;
   bool specialized_on_rhs_;

   static const int kMaxKnownRhs = 0x40000000;

   // Minor key encoding in 16 bits.
   class ModeBits: public BitField<OverwriteMode, 0, 2> {};
   class OpBits: public BitField<Token::Value, 2, 6> {};
   class KnownIntBits: public BitField<int, 8, 8> {};

   Major MajorKey() { return GenericBinaryOp; }
   int MinorKey() {
     // Encode the parameters in a unique 16 bit value.
     return OpBits::encode(op_)
            | ModeBits::encode(mode_)
            | KnownIntBits::encode(MinorKeyForKnownInt());
   }

   void Generate(MacroAssembler* masm);
   void HandleNonSmiBitwiseOp(MacroAssembler* masm);

   static bool RhsIsOneWeWantToOptimizeFor(Token::Value op, int constant_rhs) {
     if (constant_rhs == CodeGenerator::kUnknownIntValue) return false;
     if (op == Token::DIV) return constant_rhs >= 2 && constant_rhs <= 3;
     if (op == Token::MOD) {
       if (constant_rhs <= 1) return false;
       if (constant_rhs <= 10) return true;
       if (constant_rhs <= kMaxKnownRhs && IsPowerOf2(constant_rhs)) return true;
       return false;
     }
     return false;
   }

   int MinorKeyForKnownInt() {
     if (!specialized_on_rhs_) return 0;
     if (constant_rhs_ <= 10) return constant_rhs_ + 1;
     ASSERT(IsPowerOf2(constant_rhs_));
     int key = 12;
     int d = constant_rhs_;
     while ((d & 1) == 0) {
       key++;
       d >>= 1;
     }
     return key;
   }

   const char* GetName() {
     switch (op_) {
       case Token::ADD: return "GenericBinaryOpStub_ADD";
       case Token::SUB: return "GenericBinaryOpStub_SUB";
       case Token::MUL: return "GenericBinaryOpStub_MUL";
       case Token::DIV: return "GenericBinaryOpStub_DIV";
       case Token::MOD: return "GenericBinaryOpStub_MOD";
       case Token::BIT_OR: return "GenericBinaryOpStub_BIT_OR";
       case Token::BIT_AND: return "GenericBinaryOpStub_BIT_AND";
       case Token::BIT_XOR: return "GenericBinaryOpStub_BIT_XOR";
       case Token::SAR: return "GenericBinaryOpStub_SAR";
       case Token::SHL: return "GenericBinaryOpStub_SHL";
       case Token::SHR: return "GenericBinaryOpStub_SHR";
       default:         return "GenericBinaryOpStub";
     }
   }

 #ifdef DEBUG
   void Print() {
     if (!specialized_on_rhs_) {
       PrintF("GenericBinaryOpStub (%s)\n", Token::String(op_));
     } else {
       PrintF("GenericBinaryOpStub (%s by %d)\n",
              Token::String(op_),
              constant_rhs_);
     }
   }
 #endif
 };


 } }  // namespace v8::internal

 #endif  // V8_ARM_CODEGEN_ARM_H_
	// Copyright 2006-2008 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_ARM_CODEGEN_ARM_H_
	#define V8_ARM_CODEGEN_ARM_H_

	namespace v8 {
	namespace internal {

	// Forward declarations
	class DeferredCode;
	class RegisterAllocator;
	class RegisterFile;

	enum InitState { CONST_INIT, NOT_CONST_INIT };
	enum TypeofState { INSIDE_TYPEOF, NOT_INSIDE_TYPEOF };


	// -------------------------------------------------------------------------
	// Reference support

	// A reference is a C++ stack-allocated object that keeps an ECMA
	// reference on the execution stack while in scope. For variables
	// the reference is empty, indicating that it isn't necessary to
	// store state on the stack for keeping track of references to those.
	// For properties, we keep either one (named) or two (indexed) values
	// on the execution stack to represent the reference.

	class Reference BASE_EMBEDDED {
	public:
	// The values of the types is important, see size().
	enum Type { ILLEGAL = -1, SLOT = 0, NAMED = 1, KEYED = 2 };
	Reference(CodeGenerator* cgen, Expression* expression);
	~Reference();

	Expression* expression() const { return expression_; }
	Type type() const { return type_; }
	void set_type(Type value) {
	ASSERT(type_ == ILLEGAL);
	type_ = value;
	}

	// The size the reference takes up on the stack.
	int size() const { return (type_ == ILLEGAL) ? 0 : type_; }

	bool is_illegal() const { return type_ == ILLEGAL; }
	bool is_slot() const { return type_ == SLOT; }
	bool is_property() const { return type_ == NAMED \|\| type_ == KEYED; }

	// Return the name. Only valid for named property references.
	Handle<String> GetName();

	// Generate code to push the value of the reference on top of the
	// expression stack. The reference is expected to be already on top of
	// the expression stack, and it is left in place with its value above it.
	void GetValue(TypeofState typeof_state);

	// Generate code to push the value of a reference on top of the expression
	// stack and then spill the stack frame. This function is used temporarily
	// while the code generator is being transformed.
	inline void GetValueAndSpill(TypeofState typeof_state);

	// Generate code to store the value on top of the expression stack in the
	// reference. The reference is expected to be immediately below the value
	// on the expression stack. The stored value is left in place (with the
	// reference intact below it) to support chained assignments.
	void SetValue(InitState init_state);

	private:
	CodeGenerator* cgen_;
	Expression* expression_;
	Type type_;
	};


	// -------------------------------------------------------------------------
	// Code generation state

	// The state is passed down the AST by the code generator (and back up, in
	// the form of the state of the label pair). It is threaded through the
	// call stack. Constructing a state implicitly pushes it on the owning code
	// generator's stack of states, and destroying one implicitly pops it.

	class CodeGenState BASE_EMBEDDED {
	public:
	// Create an initial code generator state. Destroying the initial state
	// leaves the code generator with a NULL state.
	explicit CodeGenState(CodeGenerator* owner);

	// Create a code generator state based on a code generator's current
	// state. The new state has its own typeof state and pair of branch
	// labels.
	CodeGenState(CodeGenerator* owner,
	TypeofState typeof_state,
	JumpTarget* true_target,
	JumpTarget* false_target);

	// Destroy a code generator state and restore the owning code generator's
	// previous state.
	~CodeGenState();

	TypeofState typeof_state() const { return typeof_state_; }
	JumpTarget* true_target() const { return true_target_; }
	JumpTarget* false_target() const { return false_target_; }

	private:
	CodeGenerator* owner_;
	TypeofState typeof_state_;
	JumpTarget* true_target_;
	JumpTarget* false_target_;
	CodeGenState* previous_;
	};


	// -------------------------------------------------------------------------
	// CodeGenerator

	class CodeGenerator: public AstVisitor {
	public:
	// Takes a function literal, generates code for it. This function should only
	// be called by compiler.cc.
	static Handle<Code> MakeCode(FunctionLiteral* fun,
	Handle<Script> script,
	bool is_eval);

	#ifdef ENABLE_LOGGING_AND_PROFILING
	static bool ShouldGenerateLog(Expression* type);
	#endif

	static void SetFunctionInfo(Handle<JSFunction> fun,
	FunctionLiteral* lit,
	bool is_toplevel,
	Handle<Script> script);

	// Accessors
	MacroAssembler* masm() { return masm_; }

	VirtualFrame* frame() const { return frame_; }

	bool has_valid_frame() const { return frame_ != NULL; }

	// Set the virtual frame to be new_frame, with non-frame register
	// reference counts given by non_frame_registers. The non-frame
	// register reference counts of the old frame are returned in
	// non_frame_registers.
	void SetFrame(VirtualFrame* new_frame, RegisterFile* non_frame_registers);

	void DeleteFrame();

	RegisterAllocator* allocator() const { return allocator_; }

	CodeGenState* state() { return state_; }
	void set_state(CodeGenState* state) { state_ = state; }

	void AddDeferred(DeferredCode* code) { deferred_.Add(code); }

	static const int kUnknownIntValue = -1;

	// Number of instructions used for the JS return sequence. The constant is
	// used by the debugger to patch the JS return sequence.
	static const int kJSReturnSequenceLength = 4;

	private:
	// Construction/Destruction
	CodeGenerator(int buffer_size, Handle<Script> script, bool is_eval);
	virtual ~CodeGenerator() { delete masm_; }

	// Accessors
	Scope* scope() const { return scope_; }

	// Generating deferred code.
	void ProcessDeferred();

	bool is_eval() { return is_eval_; }

	// State
	bool has_cc() const { return cc_reg_ != al; }
	TypeofState typeof_state() const { return state_->typeof_state(); }
	JumpTarget* true_target() const { return state_->true_target(); }
	JumpTarget* false_target() const { return state_->false_target(); }

	// We don't track loop nesting level on ARM yet.
	int loop_nesting() const { return 0; }

	// Node visitors.
	void VisitStatements(ZoneList<Statement> statements);

	#define DEF_VISIT(type) \
	void Visit##type(type* node);
	AST_NODE_LIST(DEF_VISIT)
	#undef DEF_VISIT

	// Visit a statement and then spill the virtual frame if control flow can
	// reach the end of the statement (ie, it does not exit via break,
	// continue, return, or throw). This function is used temporarily while
	// the code generator is being transformed.
	inline void VisitAndSpill(Statement* statement);

	// Visit a list of statements and then spill the virtual frame if control
	// flow can reach the end of the list.
	inline void VisitStatementsAndSpill(ZoneList<Statement> statements);

	// Main code generation function
	void GenCode(FunctionLiteral* fun);

	// The following are used by class Reference.
	void LoadReference(Reference* ref);
	void UnloadReference(Reference* ref);

	MemOperand ContextOperand(Register context, int index) const {
	return MemOperand(context, Context::SlotOffset(index));
	}

	MemOperand SlotOperand(Slot* slot, Register tmp);

	MemOperand ContextSlotOperandCheckExtensions(Slot* slot,
	Register tmp,
	Register tmp2,
	JumpTarget* slow);

	// Expressions
	MemOperand GlobalObject() const {
	return ContextOperand(cp, Context::GLOBAL_INDEX);
	}

	void LoadCondition(Expression* x,
	TypeofState typeof_state,
	JumpTarget* true_target,
	JumpTarget* false_target,
	bool force_cc);
	void Load(Expression* x, TypeofState typeof_state = NOT_INSIDE_TYPEOF);
	void LoadGlobal();
	void LoadGlobalReceiver(Register scratch);

	// Generate code to push the value of an expression on top of the frame
	// and then spill the frame fully to memory. This function is used
	// temporarily while the code generator is being transformed.
	inline void LoadAndSpill(Expression* expression,
	TypeofState typeof_state = NOT_INSIDE_TYPEOF);

	// Call LoadCondition and then spill the virtual frame unless control flow
	// cannot reach the end of the expression (ie, by emitting only
	// unconditional jumps to the control targets).
	inline void LoadConditionAndSpill(Expression* expression,
	TypeofState typeof_state,
	JumpTarget* true_target,
	JumpTarget* false_target,
	bool force_control);

	// Read a value from a slot and leave it on top of the expression stack.
	void LoadFromSlot(Slot* slot, TypeofState typeof_state);
	void LoadFromGlobalSlotCheckExtensions(Slot* slot,
	TypeofState typeof_state,
	Register tmp,
	Register tmp2,
	JumpTarget* slow);

	// Special code for typeof expressions: Unfortunately, we must
	// be careful when loading the expression in 'typeof'
	// expressions. We are not allowed to throw reference errors for
	// non-existing properties of the global object, so we must make it
	// look like an explicit property access, instead of an access
	// through the context chain.
	void LoadTypeofExpression(Expression* x);

	void ToBoolean(JumpTarget* true_target, JumpTarget* false_target);

	void GenericBinaryOperation(Token::Value op,
	OverwriteMode overwrite_mode,
	int known_rhs = kUnknownIntValue);
	void Comparison(Condition cc,
	Expression* left,
	Expression* right,
	bool strict = false);

	void SmiOperation(Token::Value op,
	Handle<Object> value,
	bool reversed,
	OverwriteMode mode);

	void CallWithArguments(ZoneList<Expression> arguments, int position);

	// Control flow
	void Branch(bool if_true, JumpTarget* target);
	void CheckStack();

	struct InlineRuntimeLUT {
	void (CodeGenerator::method)(ZoneList<Expression>*);
	const char* name;
	};

	static InlineRuntimeLUT* FindInlineRuntimeLUT(Handle<String> name);
	bool CheckForInlineRuntimeCall(CallRuntime* node);
	static bool PatchInlineRuntimeEntry(Handle<String> name,
	const InlineRuntimeLUT& new_entry,
	InlineRuntimeLUT* old_entry);

	Handle<JSFunction> BuildBoilerplate(FunctionLiteral* node);
	void ProcessDeclarations(ZoneList<Declaration> declarations);

	Handle<Code> ComputeCallInitialize(int argc, InLoopFlag in_loop);

	// Declare global variables and functions in the given array of
	// name/value pairs.
	void DeclareGlobals(Handle<FixedArray> pairs);

	// Instantiate the function boilerplate.
	void InstantiateBoilerplate(Handle<JSFunction> boilerplate);

	// Support for type checks.
	void GenerateIsSmi(ZoneList<Expression> args);
	void GenerateIsNonNegativeSmi(ZoneList<Expression> args);
	void GenerateIsArray(ZoneList<Expression> args);

	// Support for construct call checks.
	void GenerateIsConstructCall(ZoneList<Expression> args);

	// Support for arguments.length and arguments[?].
	void GenerateArgumentsLength(ZoneList<Expression> args);
	void GenerateArgumentsAccess(ZoneList<Expression> args);

	// Support for accessing the class and value fields of an object.
	void GenerateClassOf(ZoneList<Expression> args);
	void GenerateValueOf(ZoneList<Expression> args);
	void GenerateSetValueOf(ZoneList<Expression> args);

	// Fast support for charCodeAt(n).
	void GenerateFastCharCodeAt(ZoneList<Expression> args);

	// Fast support for object equality testing.
	void GenerateObjectEquals(ZoneList<Expression> args);

	void GenerateLog(ZoneList<Expression> args);

	// Fast support for Math.random().
	void GenerateRandomPositiveSmi(ZoneList<Expression> args);

	// Fast support for Math.sin and Math.cos.
	enum MathOp { SIN, COS };
	void GenerateFastMathOp(MathOp op, ZoneList<Expression> args);
	inline void GenerateMathSin(ZoneList<Expression> args);
	inline void GenerateMathCos(ZoneList<Expression> args);

	// Methods used to indicate which source code is generated for. Source
	// positions are collected by the assembler and emitted with the relocation
	// information.
	void CodeForFunctionPosition(FunctionLiteral* fun);
	void CodeForReturnPosition(FunctionLiteral* fun);
	void CodeForStatementPosition(Statement* node);
	void CodeForSourcePosition(int pos);

	#ifdef DEBUG
	// True if the registers are valid for entry to a block.
	bool HasValidEntryRegisters();
	#endif

	bool is_eval_; // Tells whether code is generated for eval.

	Handle<Script> script_;
	List<DeferredCode*> deferred_;

	// Assembler
	MacroAssembler* masm_; // to generate code

	// Code generation state
	Scope* scope_;
	VirtualFrame* frame_;
	RegisterAllocator* allocator_;
	Condition cc_reg_;
	CodeGenState* state_;

	// Jump targets
	BreakTarget function_return_;

	// True if the function return is shadowed (ie, jumping to the target
	// function_return_ does not jump to the true function return, but rather
	// to some unlinking code).
	bool function_return_is_shadowed_;

	static InlineRuntimeLUT kInlineRuntimeLUT[];

	friend class VirtualFrame;
	friend class JumpTarget;
	friend class Reference;

	DISALLOW_COPY_AND_ASSIGN(CodeGenerator);
	};


	class GenericBinaryOpStub : public CodeStub {
	public:
	GenericBinaryOpStub(Token::Value op,
	OverwriteMode mode,
	int constant_rhs = CodeGenerator::kUnknownIntValue)
	: op_(op),
	mode_(mode),
	constant_rhs_(constant_rhs),
	specialized_on_rhs_(RhsIsOneWeWantToOptimizeFor(op, constant_rhs)) { }

	private:
	Token::Value op_;
	OverwriteMode mode_;
	int constant_rhs_;
	bool specialized_on_rhs_;

	static const int kMaxKnownRhs = 0x40000000;

	// Minor key encoding in 16 bits.
	class ModeBits: public BitField<OverwriteMode, 0, 2> {};
	class OpBits: public BitField<Token::Value, 2, 6> {};
	class KnownIntBits: public BitField<int, 8, 8> {};

	Major MajorKey() { return GenericBinaryOp; }
	int MinorKey() {
	// Encode the parameters in a unique 16 bit value.
	return OpBits::encode(op_)
	\| ModeBits::encode(mode_)
	\| KnownIntBits::encode(MinorKeyForKnownInt());
	}

	void Generate(MacroAssembler* masm);
	void HandleNonSmiBitwiseOp(MacroAssembler* masm);

	static bool RhsIsOneWeWantToOptimizeFor(Token::Value op, int constant_rhs) {
	if (constant_rhs == CodeGenerator::kUnknownIntValue) return false;
	if (op == Token::DIV) return constant_rhs >= 2 && constant_rhs <= 3;
	if (op == Token::MOD) {
	if (constant_rhs <= 1) return false;
	if (constant_rhs <= 10) return true;
	if (constant_rhs <= kMaxKnownRhs && IsPowerOf2(constant_rhs)) return true;
	return false;
	}
	return false;
	}

	int MinorKeyForKnownInt() {
	if (!specialized_on_rhs_) return 0;
	if (constant_rhs_ <= 10) return constant_rhs_ + 1;
	ASSERT(IsPowerOf2(constant_rhs_));
	int key = 12;
	int d = constant_rhs_;
	while ((d & 1) == 0) {
	key++;
	d >>= 1;
	}
	return key;
	}

	const char* GetName() {
	switch (op_) {
	case Token::ADD: return "GenericBinaryOpStub_ADD";
	case Token::SUB: return "GenericBinaryOpStub_SUB";
	case Token::MUL: return "GenericBinaryOpStub_MUL";
	case Token::DIV: return "GenericBinaryOpStub_DIV";
	case Token::MOD: return "GenericBinaryOpStub_MOD";
	case Token::BIT_OR: return "GenericBinaryOpStub_BIT_OR";
	case Token::BIT_AND: return "GenericBinaryOpStub_BIT_AND";
	case Token::BIT_XOR: return "GenericBinaryOpStub_BIT_XOR";
	case Token::SAR: return "GenericBinaryOpStub_SAR";
	case Token::SHL: return "GenericBinaryOpStub_SHL";
	case Token::SHR: return "GenericBinaryOpStub_SHR";
	default: return "GenericBinaryOpStub";
	}
	}

	#ifdef DEBUG
	void Print() {
	if (!specialized_on_rhs_) {
	PrintF("GenericBinaryOpStub (%s)\n", Token::String(op_));
	} else {
	PrintF("GenericBinaryOpStub (%s by %d)\n",
	Token::String(op_),
	constant_rhs_);
	}
	}
	#endif
	};


	} } // namespace v8::internal

	#endif // V8_ARM_CODEGEN_ARM_H_