src/full-codegen.h - v8/v8.git - Git at Google

 // Copyright 2010 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_FULL_CODEGEN_H_
 #define V8_FULL_CODEGEN_H_

 #include "v8.h"

 #include "ast.h"
 #include "compiler.h"

 namespace v8 {
 namespace internal {

 // AST node visitor which can tell whether a given statement will be breakable
 // when the code is compiled by the full compiler in the debugger. This means
 // that there will be an IC (load/store/call) in the code generated for the
 // debugger to piggybag on.
 class BreakableStatementChecker: public AstVisitor {
  public:
   BreakableStatementChecker() : is_breakable_(false) {}

   void Check(Statement* stmt);
   void Check(Expression* stmt);

   bool is_breakable() { return is_breakable_; }

  private:
   // AST node visit functions.
 #define DECLARE_VISIT(type) virtual void Visit##type(type* node);
   AST_NODE_LIST(DECLARE_VISIT)
 #undef DECLARE_VISIT

   bool is_breakable_;

   DISALLOW_COPY_AND_ASSIGN(BreakableStatementChecker);
 };


 // -----------------------------------------------------------------------------
 // Full code generator.

 class FullCodeGenerator: public AstVisitor {
  public:
   explicit FullCodeGenerator(MacroAssembler* masm)
       : masm_(masm),
         info_(NULL),
         nesting_stack_(NULL),
         loop_depth_(0),
         location_(kStack),
         true_label_(NULL),
         false_label_(NULL),
         fall_through_(NULL) {
   }

   static Handle<Code> MakeCode(CompilationInfo* info);

   void Generate(CompilationInfo* info);

  private:
   class Breakable;
   class Iteration;
   class TryCatch;
   class TryFinally;
   class Finally;
   class ForIn;

   class NestedStatement BASE_EMBEDDED {
    public:
     explicit NestedStatement(FullCodeGenerator* codegen) : codegen_(codegen) {
       // Link into codegen's nesting stack.
       previous_ = codegen->nesting_stack_;
       codegen->nesting_stack_ = this;
     }
     virtual ~NestedStatement() {
       // Unlink from codegen's nesting stack.
       ASSERT_EQ(this, codegen_->nesting_stack_);
       codegen_->nesting_stack_ = previous_;
     }

     virtual Breakable* AsBreakable() { return NULL; }
     virtual Iteration* AsIteration() { return NULL; }
     virtual TryCatch* AsTryCatch() { return NULL; }
     virtual TryFinally* AsTryFinally() { return NULL; }
     virtual Finally* AsFinally() { return NULL; }
     virtual ForIn* AsForIn() { return NULL; }

     virtual bool IsContinueTarget(Statement* target) { return false; }
     virtual bool IsBreakTarget(Statement* target) { return false; }

     // Generate code to leave the nested statement. This includes
     // cleaning up any stack elements in use and restoring the
     // stack to the expectations of the surrounding statements.
     // Takes a number of stack elements currently on top of the
     // nested statement's stack, and returns a number of stack
     // elements left on top of the surrounding statement's stack.
     // The generated code must preserve the result register (which
     // contains the value in case of a return).
     virtual int Exit(int stack_depth) {
       // Default implementation for the case where there is
       // nothing to clean up.
       return stack_depth;
     }
     NestedStatement* outer() { return previous_; }
    protected:
     MacroAssembler* masm() { return codegen_->masm(); }
    private:
     FullCodeGenerator* codegen_;
     NestedStatement* previous_;
     DISALLOW_COPY_AND_ASSIGN(NestedStatement);
   };

   class Breakable : public NestedStatement {
    public:
     Breakable(FullCodeGenerator* codegen,
               BreakableStatement* break_target)
         : NestedStatement(codegen),
           target_(break_target) {}
     virtual ~Breakable() {}
     virtual Breakable* AsBreakable() { return this; }
     virtual bool IsBreakTarget(Statement* statement) {
       return target_ == statement;
     }
     BreakableStatement* statement() { return target_; }
     Label* break_target() { return &break_target_label_; }
    private:
     BreakableStatement* target_;
     Label break_target_label_;
     DISALLOW_COPY_AND_ASSIGN(Breakable);
   };

   class Iteration : public Breakable {
    public:
     Iteration(FullCodeGenerator* codegen,
               IterationStatement* iteration_statement)
         : Breakable(codegen, iteration_statement) {}
     virtual ~Iteration() {}
     virtual Iteration* AsIteration() { return this; }
     virtual bool IsContinueTarget(Statement* statement) {
       return this->statement() == statement;
     }
     Label* continue_target() { return &continue_target_label_; }
    private:
     Label continue_target_label_;
     DISALLOW_COPY_AND_ASSIGN(Iteration);
   };

   // The environment inside the try block of a try/catch statement.
   class TryCatch : public NestedStatement {
    public:
     explicit TryCatch(FullCodeGenerator* codegen, Label* catch_entry)
         : NestedStatement(codegen), catch_entry_(catch_entry) { }
     virtual ~TryCatch() {}
     virtual TryCatch* AsTryCatch() { return this; }
     Label* catch_entry() { return catch_entry_; }
     virtual int Exit(int stack_depth);
    private:
     Label* catch_entry_;
     DISALLOW_COPY_AND_ASSIGN(TryCatch);
   };

   // The environment inside the try block of a try/finally statement.
   class TryFinally : public NestedStatement {
    public:
     explicit TryFinally(FullCodeGenerator* codegen, Label* finally_entry)
         : NestedStatement(codegen), finally_entry_(finally_entry) { }
     virtual ~TryFinally() {}
     virtual TryFinally* AsTryFinally() { return this; }
     Label* finally_entry() { return finally_entry_; }
     virtual int Exit(int stack_depth);
    private:
     Label* finally_entry_;
     DISALLOW_COPY_AND_ASSIGN(TryFinally);
   };

   // A FinallyEnvironment represents being inside a finally block.
   // Abnormal termination of the finally block needs to clean up
   // the block's parameters from the stack.
   class Finally : public NestedStatement {
    public:
     explicit Finally(FullCodeGenerator* codegen) : NestedStatement(codegen) { }
     virtual ~Finally() {}
     virtual Finally* AsFinally() { return this; }
     virtual int Exit(int stack_depth) {
       return stack_depth + kFinallyStackElementCount;
     }
    private:
     // Number of extra stack slots occupied during a finally block.
     static const int kFinallyStackElementCount = 2;
     DISALLOW_COPY_AND_ASSIGN(Finally);
   };

   // A ForInEnvironment represents being inside a for-in loop.
   // Abnormal termination of the for-in block needs to clean up
   // the block's temporary storage from the stack.
   class ForIn : public Iteration {
    public:
     ForIn(FullCodeGenerator* codegen,
           ForInStatement* statement)
         : Iteration(codegen, statement) { }
     virtual ~ForIn() {}
     virtual ForIn* AsForIn() { return this; }
     virtual int Exit(int stack_depth) {
       return stack_depth + kForInStackElementCount;
     }
    private:
     static const int kForInStackElementCount = 5;
     DISALLOW_COPY_AND_ASSIGN(ForIn);
   };

   enum Location {
     kAccumulator,
     kStack
   };

   enum ConstantOperand {
     kNoConstants,
     kLeftConstant,
     kRightConstant
   };

   // Compute the frame pointer relative offset for a given local or
   // parameter slot.
   int SlotOffset(Slot* slot);

   // Determine whether or not to inline the smi case for the given
   // operation.
   bool ShouldInlineSmiCase(Token::Value op);

   // Compute which (if any) of the operands is a compile-time constant.
   ConstantOperand GetConstantOperand(Token::Value op,
                                      Expression* left,
                                      Expression* right);

   // Emit code to convert a pure value (in a register, slot, as a literal,
   // or on top of the stack) into the result expected according to an
   // expression context.
   void Apply(Expression::Context context, Register reg);

   // Slot cannot have type Slot::LOOKUP.
   void Apply(Expression::Context context, Slot* slot);

   void Apply(Expression::Context context, Literal* lit);
   void ApplyTOS(Expression::Context context);

   // Emit code to discard count elements from the top of stack, then convert
   // a pure value into the result expected according to an expression
   // context.
   void DropAndApply(int count, Expression::Context context, Register reg);

   // Set up branch labels for a test expression.
   void PrepareTest(Label* materialize_true,
                    Label* materialize_false,
                    Label** if_true,
                    Label** if_false,
                    Label** fall_through);

   // Emit code to convert pure control flow to a pair of labels into the
   // result expected according to an expression context.
   void Apply(Expression::Context context,
              Label* materialize_true,
              Label* materialize_false);

   // Emit code to convert constant control flow (true or false) into
   // the result expected according to an expression context.
   void Apply(Expression::Context context, bool flag);

   // Helper function to convert a pure value into a test context.  The value
   // is expected on the stack or the accumulator, depending on the platform.
   // See the platform-specific implementation for details.
   void DoTest(Label* if_true, Label* if_false, Label* fall_through);

   // Helper function to split control flow and avoid a branch to the
   // fall-through label if it is set up.
   void Split(Condition cc,
              Label* if_true,
              Label* if_false,
              Label* fall_through);

   void Move(Slot* dst, Register source, Register scratch1, Register scratch2);
   void Move(Register dst, Slot* source);

   // Return an operand used to read/write to a known (ie, non-LOOKUP) slot.
   // May emit code to traverse the context chain, destroying the scratch
   // register.
   MemOperand EmitSlotSearch(Slot* slot, Register scratch);

   void VisitForEffect(Expression* expr) {
     Expression::Context saved_context = context_;
     context_ = Expression::kEffect;
     Visit(expr);
     context_ = saved_context;
   }

   void VisitForValue(Expression* expr, Location where) {
     Expression::Context saved_context = context_;
     Location saved_location = location_;
     context_ = Expression::kValue;
     location_ = where;
     Visit(expr);
     context_ = saved_context;
     location_ = saved_location;
   }

   void VisitForControl(Expression* expr,
                        Label* if_true,
                        Label* if_false,
                        Label* fall_through) {
     Expression::Context saved_context = context_;
     Label* saved_true = true_label_;
     Label* saved_false = false_label_;
     Label* saved_fall_through = fall_through_;
     context_ = Expression::kTest;
     true_label_ = if_true;
     false_label_ = if_false;
     fall_through_ = fall_through;
     Visit(expr);
     context_ = saved_context;
     true_label_ = saved_true;
     false_label_ = saved_false;
     fall_through_ = saved_fall_through;
   }

   void VisitDeclarations(ZoneList<Declaration*>* declarations);
   void DeclareGlobals(Handle<FixedArray> pairs);

   // Try to perform a comparison as a fast inlined literal compare if
   // the operands allow it.  Returns true if the compare operations
   // has been matched and all code generated; false otherwise.
   bool TryLiteralCompare(Token::Value op,
                          Expression* left,
                          Expression* right,
                          Label* if_true,
                          Label* if_false,
                          Label* fall_through);

   // Platform-specific code for a variable, constant, or function
   // declaration.  Functions have an initial value.
   void EmitDeclaration(Variable* variable,
                        Variable::Mode mode,
                        FunctionLiteral* function);

   // Platform-specific return sequence
   void EmitReturnSequence();

   // Platform-specific code sequences for calls
   void EmitCallWithStub(Call* expr);
   void EmitCallWithIC(Call* expr, Handle<Object> name, RelocInfo::Mode mode);
   void EmitKeyedCallWithIC(Call* expr, Expression* key, RelocInfo::Mode mode);

   // Platform-specific code for inline runtime calls.
   void EmitInlineRuntimeCall(CallRuntime* expr);

 #define EMIT_INLINE_RUNTIME_CALL(name, x, y) \
   void Emit##name(ZoneList<Expression*>* arguments);
   INLINE_RUNTIME_FUNCTION_LIST(EMIT_INLINE_RUNTIME_CALL)
 #undef EMIT_INLINE_RUNTIME_CALL

   // Platform-specific code for loading variables.
   void EmitLoadGlobalSlotCheckExtensions(Slot* slot,
                                          TypeofState typeof_state,
                                          Label* slow);
   MemOperand ContextSlotOperandCheckExtensions(Slot* slot, Label* slow);
   void EmitDynamicLoadFromSlotFastCase(Slot* slot,
                                        TypeofState typeof_state,
                                        Label* slow,
                                        Label* done);
   void EmitVariableLoad(Variable* expr, Expression::Context context);

   // Platform-specific support for allocating a new closure based on
   // the given function info.
   void EmitNewClosure(Handle<SharedFunctionInfo> info);

   // Platform-specific support for compiling assignments.

   // Load a value from a named property.
   // The receiver is left on the stack by the IC.
   void EmitNamedPropertyLoad(Property* expr);

   // Load a value from a keyed property.
   // The receiver and the key is left on the stack by the IC.
   void EmitKeyedPropertyLoad(Property* expr);

   // Apply the compound assignment operator. Expects the left operand on top
   // of the stack and the right one in the accumulator.
   void EmitBinaryOp(Token::Value op,
                     Expression::Context context,
                     OverwriteMode mode);

   // Helper functions for generating inlined smi code for certain
   // binary operations.
   void EmitInlineSmiBinaryOp(Expression* expr,
                              Token::Value op,
                              Expression::Context context,
                              OverwriteMode mode,
                              Expression* left,
                              Expression* right,
                              ConstantOperand constant);

   void EmitConstantSmiBinaryOp(Expression* expr,
                                Token::Value op,
                                Expression::Context context,
                                OverwriteMode mode,
                                bool left_is_constant_smi,
                                Smi* value);

   void EmitConstantSmiBitOp(Expression* expr,
                             Token::Value op,
                             Expression::Context context,
                             OverwriteMode mode,
                             Smi* value);

   void EmitConstantSmiShiftOp(Expression* expr,
                               Token::Value op,
                               Expression::Context context,
                               OverwriteMode mode,
                               Smi* value);

   void EmitConstantSmiAdd(Expression* expr,
                           Expression::Context context,
                           OverwriteMode mode,
                           bool left_is_constant_smi,
                           Smi* value);

   void EmitConstantSmiSub(Expression* expr,
                           Expression::Context context,
                           OverwriteMode mode,
                           bool left_is_constant_smi,
                           Smi* value);

   // Assign to the given expression as if via '='. The right-hand-side value
   // is expected in the accumulator.
   void EmitAssignment(Expression* expr);

   // Complete a variable assignment.  The right-hand-side value is expected
   // in the accumulator.
   void EmitVariableAssignment(Variable* var,
                               Token::Value op,
                               Expression::Context context);

   // Complete a named property assignment.  The receiver is expected on top
   // of the stack and the right-hand-side value in the accumulator.
   void EmitNamedPropertyAssignment(Assignment* expr);

   // Complete a keyed property assignment.  The receiver and key are
   // expected on top of the stack and the right-hand-side value in the
   // accumulator.
   void EmitKeyedPropertyAssignment(Assignment* expr);

   void SetFunctionPosition(FunctionLiteral* fun);
   void SetReturnPosition(FunctionLiteral* fun);
   void SetStatementPosition(Statement* stmt);
   void SetExpressionPosition(Expression* expr, int pos);
   void SetStatementPosition(int pos);
   void SetSourcePosition(int pos);

   // Non-local control flow support.
   void EnterFinallyBlock();
   void ExitFinallyBlock();

   // Loop nesting counter.
   int loop_depth() { return loop_depth_; }
   void increment_loop_depth() { loop_depth_++; }
   void decrement_loop_depth() {
     ASSERT(loop_depth_ > 0);
     loop_depth_--;
   }

   MacroAssembler* masm() { return masm_; }

   Handle<Script> script() { return info_->script(); }
   bool is_eval() { return info_->is_eval(); }
   FunctionLiteral* function() { return info_->function(); }
   Scope* scope() { return info_->scope(); }

   static Register result_register();
   static Register context_register();

   // Set fields in the stack frame. Offsets are the frame pointer relative
   // offsets defined in, e.g., StandardFrameConstants.
   void StoreToFrameField(int frame_offset, Register value);

   // Load a value from the current context. Indices are defined as an enum
   // in v8::internal::Context.
   void LoadContextField(Register dst, int context_index);

   // Create an operand for a context field.
   MemOperand ContextOperand(Register context, int context_index);

   // AST node visit functions.
 #define DECLARE_VISIT(type) virtual void Visit##type(type* node);
   AST_NODE_LIST(DECLARE_VISIT)
 #undef DECLARE_VISIT
   // Handles the shortcutted logical binary operations in VisitBinaryOperation.
   void EmitLogicalOperation(BinaryOperation* expr);

   void VisitForTypeofValue(Expression* expr, Location where);

   void VisitLogicalForValue(Expression* expr,
                             Token::Value op,
                             Location where,
                             Label* done);


   MacroAssembler* masm_;
   CompilationInfo* info_;

   Label return_label_;
   NestedStatement* nesting_stack_;
   int loop_depth_;

   Expression::Context context_;
   Location location_;
   Label* true_label_;
   Label* false_label_;
   Label* fall_through_;

   friend class NestedStatement;

   DISALLOW_COPY_AND_ASSIGN(FullCodeGenerator);
 };


 } }  // namespace v8::internal

 #endif  // V8_FULL_CODEGEN_H_
	// Copyright 2010 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_FULL_CODEGEN_H_
	#define V8_FULL_CODEGEN_H_

	#include "v8.h"

	#include "ast.h"
	#include "compiler.h"

	namespace v8 {
	namespace internal {

	// AST node visitor which can tell whether a given statement will be breakable
	// when the code is compiled by the full compiler in the debugger. This means
	// that there will be an IC (load/store/call) in the code generated for the
	// debugger to piggybag on.
	class BreakableStatementChecker: public AstVisitor {
	public:
	BreakableStatementChecker() : is_breakable_(false) {}

	void Check(Statement* stmt);
	void Check(Expression* stmt);

	bool is_breakable() { return is_breakable_; }

	private:
	// AST node visit functions.
	#define DECLARE_VISIT(type) virtual void Visit##type(type* node);
	AST_NODE_LIST(DECLARE_VISIT)
	#undef DECLARE_VISIT

	bool is_breakable_;

	DISALLOW_COPY_AND_ASSIGN(BreakableStatementChecker);
	};


	// -----------------------------------------------------------------------------
	// Full code generator.

	class FullCodeGenerator: public AstVisitor {
	public:
	explicit FullCodeGenerator(MacroAssembler* masm)
	: masm_(masm),
	info_(NULL),
	nesting_stack_(NULL),
	loop_depth_(0),
	location_(kStack),
	true_label_(NULL),
	false_label_(NULL),
	fall_through_(NULL) {
	}

	static Handle<Code> MakeCode(CompilationInfo* info);

	void Generate(CompilationInfo* info);

	private:
	class Breakable;
	class Iteration;
	class TryCatch;
	class TryFinally;
	class Finally;
	class ForIn;

	class NestedStatement BASE_EMBEDDED {
	public:
	explicit NestedStatement(FullCodeGenerator* codegen) : codegen_(codegen) {
	// Link into codegen's nesting stack.
	previous_ = codegen->nesting_stack_;
	codegen->nesting_stack_ = this;
	}
	virtual ~NestedStatement() {
	// Unlink from codegen's nesting stack.
	ASSERT_EQ(this, codegen_->nesting_stack_);
	codegen_->nesting_stack_ = previous_;
	}

	virtual Breakable* AsBreakable() { return NULL; }
	virtual Iteration* AsIteration() { return NULL; }
	virtual TryCatch* AsTryCatch() { return NULL; }
	virtual TryFinally* AsTryFinally() { return NULL; }
	virtual Finally* AsFinally() { return NULL; }
	virtual ForIn* AsForIn() { return NULL; }

	virtual bool IsContinueTarget(Statement* target) { return false; }
	virtual bool IsBreakTarget(Statement* target) { return false; }

	// Generate code to leave the nested statement. This includes
	// cleaning up any stack elements in use and restoring the
	// stack to the expectations of the surrounding statements.
	// Takes a number of stack elements currently on top of the
	// nested statement's stack, and returns a number of stack
	// elements left on top of the surrounding statement's stack.
	// The generated code must preserve the result register (which
	// contains the value in case of a return).
	virtual int Exit(int stack_depth) {
	// Default implementation for the case where there is
	// nothing to clean up.
	return stack_depth;
	}
	NestedStatement* outer() { return previous_; }
	protected:
	MacroAssembler* masm() { return codegen_->masm(); }
	private:
	FullCodeGenerator* codegen_;
	NestedStatement* previous_;
	DISALLOW_COPY_AND_ASSIGN(NestedStatement);
	};

	class Breakable : public NestedStatement {
	public:
	Breakable(FullCodeGenerator* codegen,
	BreakableStatement* break_target)
	: NestedStatement(codegen),
	target_(break_target) {}
	virtual ~Breakable() {}
	virtual Breakable* AsBreakable() { return this; }
	virtual bool IsBreakTarget(Statement* statement) {
	return target_ == statement;
	}
	BreakableStatement* statement() { return target_; }
	Label* break_target() { return &break_target_label_; }
	private:
	BreakableStatement* target_;
	Label break_target_label_;
	DISALLOW_COPY_AND_ASSIGN(Breakable);
	};

	class Iteration : public Breakable {
	public:
	Iteration(FullCodeGenerator* codegen,
	IterationStatement* iteration_statement)
	: Breakable(codegen, iteration_statement) {}
	virtual ~Iteration() {}
	virtual Iteration* AsIteration() { return this; }
	virtual bool IsContinueTarget(Statement* statement) {
	return this->statement() == statement;
	}
	Label* continue_target() { return &continue_target_label_; }
	private:
	Label continue_target_label_;
	DISALLOW_COPY_AND_ASSIGN(Iteration);
	};

	// The environment inside the try block of a try/catch statement.
	class TryCatch : public NestedStatement {
	public:
	explicit TryCatch(FullCodeGenerator* codegen, Label* catch_entry)
	: NestedStatement(codegen), catch_entry_(catch_entry) { }
	virtual ~TryCatch() {}
	virtual TryCatch* AsTryCatch() { return this; }
	Label* catch_entry() { return catch_entry_; }
	virtual int Exit(int stack_depth);
	private:
	Label* catch_entry_;
	DISALLOW_COPY_AND_ASSIGN(TryCatch);
	};

	// The environment inside the try block of a try/finally statement.
	class TryFinally : public NestedStatement {
	public:
	explicit TryFinally(FullCodeGenerator* codegen, Label* finally_entry)
	: NestedStatement(codegen), finally_entry_(finally_entry) { }
	virtual ~TryFinally() {}
	virtual TryFinally* AsTryFinally() { return this; }
	Label* finally_entry() { return finally_entry_; }
	virtual int Exit(int stack_depth);
	private:
	Label* finally_entry_;
	DISALLOW_COPY_AND_ASSIGN(TryFinally);
	};

	// A FinallyEnvironment represents being inside a finally block.
	// Abnormal termination of the finally block needs to clean up
	// the block's parameters from the stack.
	class Finally : public NestedStatement {
	public:
	explicit Finally(FullCodeGenerator* codegen) : NestedStatement(codegen) { }
	virtual ~Finally() {}
	virtual Finally* AsFinally() { return this; }
	virtual int Exit(int stack_depth) {
	return stack_depth + kFinallyStackElementCount;
	}
	private:
	// Number of extra stack slots occupied during a finally block.
	static const int kFinallyStackElementCount = 2;
	DISALLOW_COPY_AND_ASSIGN(Finally);
	};

	// A ForInEnvironment represents being inside a for-in loop.
	// Abnormal termination of the for-in block needs to clean up
	// the block's temporary storage from the stack.
	class ForIn : public Iteration {
	public:
	ForIn(FullCodeGenerator* codegen,
	ForInStatement* statement)
	: Iteration(codegen, statement) { }
	virtual ~ForIn() {}
	virtual ForIn* AsForIn() { return this; }
	virtual int Exit(int stack_depth) {
	return stack_depth + kForInStackElementCount;
	}
	private:
	static const int kForInStackElementCount = 5;
	DISALLOW_COPY_AND_ASSIGN(ForIn);
	};

	enum Location {
	kAccumulator,
	kStack
	};

	enum ConstantOperand {
	kNoConstants,
	kLeftConstant,
	kRightConstant
	};

	// Compute the frame pointer relative offset for a given local or
	// parameter slot.
	int SlotOffset(Slot* slot);

	// Determine whether or not to inline the smi case for the given
	// operation.
	bool ShouldInlineSmiCase(Token::Value op);

	// Compute which (if any) of the operands is a compile-time constant.
	ConstantOperand GetConstantOperand(Token::Value op,
	Expression* left,
	Expression* right);

	// Emit code to convert a pure value (in a register, slot, as a literal,
	// or on top of the stack) into the result expected according to an
	// expression context.
	void Apply(Expression::Context context, Register reg);

	// Slot cannot have type Slot::LOOKUP.
	void Apply(Expression::Context context, Slot* slot);

	void Apply(Expression::Context context, Literal* lit);
	void ApplyTOS(Expression::Context context);

	// Emit code to discard count elements from the top of stack, then convert
	// a pure value into the result expected according to an expression
	// context.
	void DropAndApply(int count, Expression::Context context, Register reg);

	// Set up branch labels for a test expression.
	void PrepareTest(Label* materialize_true,
	Label* materialize_false,
	Label** if_true,
	Label** if_false,
	Label** fall_through);

	// Emit code to convert pure control flow to a pair of labels into the
	// result expected according to an expression context.
	void Apply(Expression::Context context,
	Label* materialize_true,
	Label* materialize_false);

	// Emit code to convert constant control flow (true or false) into
	// the result expected according to an expression context.
	void Apply(Expression::Context context, bool flag);

	// Helper function to convert a pure value into a test context. The value
	// is expected on the stack or the accumulator, depending on the platform.
	// See the platform-specific implementation for details.
	void DoTest(Label* if_true, Label* if_false, Label* fall_through);

	// Helper function to split control flow and avoid a branch to the
	// fall-through label if it is set up.
	void Split(Condition cc,
	Label* if_true,
	Label* if_false,
	Label* fall_through);

	void Move(Slot* dst, Register source, Register scratch1, Register scratch2);
	void Move(Register dst, Slot* source);

	// Return an operand used to read/write to a known (ie, non-LOOKUP) slot.
	// May emit code to traverse the context chain, destroying the scratch
	// register.
	MemOperand EmitSlotSearch(Slot* slot, Register scratch);

	void VisitForEffect(Expression* expr) {
	Expression::Context saved_context = context_;
	context_ = Expression::kEffect;
	Visit(expr);
	context_ = saved_context;
	}

	void VisitForValue(Expression* expr, Location where) {
	Expression::Context saved_context = context_;
	Location saved_location = location_;
	context_ = Expression::kValue;
	location_ = where;
	Visit(expr);
	context_ = saved_context;
	location_ = saved_location;
	}

	void VisitForControl(Expression* expr,
	Label* if_true,
	Label* if_false,
	Label* fall_through) {
	Expression::Context saved_context = context_;
	Label* saved_true = true_label_;
	Label* saved_false = false_label_;
	Label* saved_fall_through = fall_through_;
	context_ = Expression::kTest;
	true_label_ = if_true;
	false_label_ = if_false;
	fall_through_ = fall_through;
	Visit(expr);
	context_ = saved_context;
	true_label_ = saved_true;
	false_label_ = saved_false;
	fall_through_ = saved_fall_through;
	}

	void VisitDeclarations(ZoneList<Declaration> declarations);
	void DeclareGlobals(Handle<FixedArray> pairs);

	// Try to perform a comparison as a fast inlined literal compare if
	// the operands allow it. Returns true if the compare operations
	// has been matched and all code generated; false otherwise.
	bool TryLiteralCompare(Token::Value op,
	Expression* left,
	Expression* right,
	Label* if_true,
	Label* if_false,
	Label* fall_through);

	// Platform-specific code for a variable, constant, or function
	// declaration. Functions have an initial value.
	void EmitDeclaration(Variable* variable,
	Variable::Mode mode,
	FunctionLiteral* function);

	// Platform-specific return sequence
	void EmitReturnSequence();

	// Platform-specific code sequences for calls
	void EmitCallWithStub(Call* expr);
	void EmitCallWithIC(Call* expr, Handle<Object> name, RelocInfo::Mode mode);
	void EmitKeyedCallWithIC(Call* expr, Expression* key, RelocInfo::Mode mode);

	// Platform-specific code for inline runtime calls.
	void EmitInlineRuntimeCall(CallRuntime* expr);

	#define EMIT_INLINE_RUNTIME_CALL(name, x, y) \
	void Emit##name(ZoneList<Expression> arguments);
	INLINE_RUNTIME_FUNCTION_LIST(EMIT_INLINE_RUNTIME_CALL)
	#undef EMIT_INLINE_RUNTIME_CALL

	// Platform-specific code for loading variables.
	void EmitLoadGlobalSlotCheckExtensions(Slot* slot,
	TypeofState typeof_state,
	Label* slow);
	MemOperand ContextSlotOperandCheckExtensions(Slot* slot, Label* slow);
	void EmitDynamicLoadFromSlotFastCase(Slot* slot,
	TypeofState typeof_state,
	Label* slow,
	Label* done);
	void EmitVariableLoad(Variable* expr, Expression::Context context);

	// Platform-specific support for allocating a new closure based on
	// the given function info.
	void EmitNewClosure(Handle<SharedFunctionInfo> info);

	// Platform-specific support for compiling assignments.

	// Load a value from a named property.
	// The receiver is left on the stack by the IC.
	void EmitNamedPropertyLoad(Property* expr);

	// Load a value from a keyed property.
	// The receiver and the key is left on the stack by the IC.
	void EmitKeyedPropertyLoad(Property* expr);

	// Apply the compound assignment operator. Expects the left operand on top
	// of the stack and the right one in the accumulator.
	void EmitBinaryOp(Token::Value op,
	Expression::Context context,
	OverwriteMode mode);

	// Helper functions for generating inlined smi code for certain
	// binary operations.
	void EmitInlineSmiBinaryOp(Expression* expr,
	Token::Value op,
	Expression::Context context,
	OverwriteMode mode,
	Expression* left,
	Expression* right,
	ConstantOperand constant);

	void EmitConstantSmiBinaryOp(Expression* expr,
	Token::Value op,
	Expression::Context context,
	OverwriteMode mode,
	bool left_is_constant_smi,
	Smi* value);

	void EmitConstantSmiBitOp(Expression* expr,
	Token::Value op,
	Expression::Context context,
	OverwriteMode mode,
	Smi* value);

	void EmitConstantSmiShiftOp(Expression* expr,
	Token::Value op,
	Expression::Context context,
	OverwriteMode mode,
	Smi* value);

	void EmitConstantSmiAdd(Expression* expr,
	Expression::Context context,
	OverwriteMode mode,
	bool left_is_constant_smi,
	Smi* value);

	void EmitConstantSmiSub(Expression* expr,
	Expression::Context context,
	OverwriteMode mode,
	bool left_is_constant_smi,
	Smi* value);

	// Assign to the given expression as if via '='. The right-hand-side value
	// is expected in the accumulator.
	void EmitAssignment(Expression* expr);

	// Complete a variable assignment. The right-hand-side value is expected
	// in the accumulator.
	void EmitVariableAssignment(Variable* var,
	Token::Value op,
	Expression::Context context);

	// Complete a named property assignment. The receiver is expected on top
	// of the stack and the right-hand-side value in the accumulator.
	void EmitNamedPropertyAssignment(Assignment* expr);

	// Complete a keyed property assignment. The receiver and key are
	// expected on top of the stack and the right-hand-side value in the
	// accumulator.
	void EmitKeyedPropertyAssignment(Assignment* expr);

	void SetFunctionPosition(FunctionLiteral* fun);
	void SetReturnPosition(FunctionLiteral* fun);
	void SetStatementPosition(Statement* stmt);
	void SetExpressionPosition(Expression* expr, int pos);
	void SetStatementPosition(int pos);
	void SetSourcePosition(int pos);

	// Non-local control flow support.
	void EnterFinallyBlock();
	void ExitFinallyBlock();

	// Loop nesting counter.
	int loop_depth() { return loop_depth_; }
	void increment_loop_depth() { loop_depth_++; }
	void decrement_loop_depth() {
	ASSERT(loop_depth_ > 0);
	loop_depth_--;
	}

	MacroAssembler* masm() { return masm_; }

	Handle<Script> script() { return info_->script(); }
	bool is_eval() { return info_->is_eval(); }
	FunctionLiteral* function() { return info_->function(); }
	Scope* scope() { return info_->scope(); }

	static Register result_register();
	static Register context_register();

	// Set fields in the stack frame. Offsets are the frame pointer relative
	// offsets defined in, e.g., StandardFrameConstants.
	void StoreToFrameField(int frame_offset, Register value);

	// Load a value from the current context. Indices are defined as an enum
	// in v8::internal::Context.
	void LoadContextField(Register dst, int context_index);

	// Create an operand for a context field.
	MemOperand ContextOperand(Register context, int context_index);

	// AST node visit functions.
	#define DECLARE_VISIT(type) virtual void Visit##type(type* node);
	AST_NODE_LIST(DECLARE_VISIT)
	#undef DECLARE_VISIT
	// Handles the shortcutted logical binary operations in VisitBinaryOperation.
	void EmitLogicalOperation(BinaryOperation* expr);

	void VisitForTypeofValue(Expression* expr, Location where);

	void VisitLogicalForValue(Expression* expr,
	Token::Value op,
	Location where,
	Label* done);


	MacroAssembler* masm_;
	CompilationInfo* info_;

	Label return_label_;
	NestedStatement* nesting_stack_;
	int loop_depth_;

	Expression::Context context_;
	Location location_;
	Label* true_label_;
	Label* false_label_;
	Label* fall_through_;

	friend class NestedStatement;

	DISALLOW_COPY_AND_ASSIGN(FullCodeGenerator);
	};


	} } // namespace v8::internal

	#endif // V8_FULL_CODEGEN_H_