src/arm/virtual-frame-arm.h - fp2-dev/platform/external/v8 - Gitiles

 // Copyright 2009 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_VIRTUAL_FRAME_ARM_H_
 #define V8_ARM_VIRTUAL_FRAME_ARM_H_

 #include "register-allocator.h"

 namespace v8 {
 namespace internal {

 // This dummy class is only used to create invalid virtual frames.
 extern class InvalidVirtualFrameInitializer {}* kInvalidVirtualFrameInitializer;


 // -------------------------------------------------------------------------
 // Virtual frames
 //
 // The virtual frame is an abstraction of the physical stack frame.  It
 // encapsulates the parameters, frame-allocated locals, and the expression
 // stack.  It supports push/pop operations on the expression stack, as well
 // as random access to the expression stack elements, locals, and
 // parameters.

 class VirtualFrame : public ZoneObject {
  public:
   class RegisterAllocationScope;
   // A utility class to introduce a scope where the virtual frame is
   // expected to remain spilled.  The constructor spills the code
   // generator's current frame, and keeps it spilled.
   class SpilledScope BASE_EMBEDDED {
    public:
     explicit SpilledScope(VirtualFrame* frame)
       : old_is_spilled_(is_spilled_) {
       if (frame != NULL) {
         if (!is_spilled_) {
           frame->SpillAll();
         } else {
           frame->AssertIsSpilled();
         }
       }
       is_spilled_ = true;
     }
     ~SpilledScope() {
       is_spilled_ = old_is_spilled_;
     }
     static bool is_spilled() { return is_spilled_; }

    private:
     static bool is_spilled_;
     int old_is_spilled_;

     SpilledScope() { }

     friend class RegisterAllocationScope;
   };

   class RegisterAllocationScope BASE_EMBEDDED {
    public:
     // A utility class to introduce a scope where the virtual frame
     // is not spilled, ie. where register allocation occurs.  Eventually
     // when RegisterAllocationScope is ubiquitous it can be removed
     // along with the (by then unused) SpilledScope class.
     inline explicit RegisterAllocationScope(CodeGenerator* cgen);
     inline ~RegisterAllocationScope();

    private:
     CodeGenerator* cgen_;
     bool old_is_spilled_;

     RegisterAllocationScope() { }
   };

   // An illegal index into the virtual frame.
   static const int kIllegalIndex = -1;

   // Construct an initial virtual frame on entry to a JS function.
   inline VirtualFrame();

   // Construct an invalid virtual frame, used by JumpTargets.
   inline VirtualFrame(InvalidVirtualFrameInitializer* dummy);

   // Construct a virtual frame as a clone of an existing one.
   explicit inline VirtualFrame(VirtualFrame* original);

   inline CodeGenerator* cgen() const;
   inline MacroAssembler* masm();

   // The number of elements on the virtual frame.
   int element_count() const { return element_count_; }

   // The height of the virtual expression stack.
   inline int height() const;

   bool is_used(int num) {
     switch (num) {
       case 0: {  // r0.
         return kR0InUse[top_of_stack_state_];
       }
       case 1: {  // r1.
         return kR1InUse[top_of_stack_state_];
       }
       case 2:
       case 3:
       case 4:
       case 5:
       case 6: {  // r2 to r6.
         ASSERT(num - kFirstAllocatedRegister < kNumberOfAllocatedRegisters);
         ASSERT(num >= kFirstAllocatedRegister);
         if ((register_allocation_map_ &
              (1 << (num - kFirstAllocatedRegister))) == 0) {
           return false;
         } else {
           return true;
         }
       }
       default: {
         ASSERT(num < kFirstAllocatedRegister ||
                num >= kFirstAllocatedRegister + kNumberOfAllocatedRegisters);
         return false;
       }
     }
   }

   // Add extra in-memory elements to the top of the frame to match an actual
   // frame (eg, the frame after an exception handler is pushed).  No code is
   // emitted.
   void Adjust(int count);

   // Forget elements from the top of the frame to match an actual frame (eg,
   // the frame after a runtime call).  No code is emitted except to bring the
   // frame to a spilled state.
   void Forget(int count);

   // Spill all values from the frame to memory.
   void SpillAll();

   void AssertIsSpilled() const {
     ASSERT(top_of_stack_state_ == NO_TOS_REGISTERS);
     ASSERT(register_allocation_map_ == 0);
   }

   void AssertIsNotSpilled() {
     ASSERT(!SpilledScope::is_spilled());
   }

   // Spill all occurrences of a specific register from the frame.
   void Spill(Register reg) {
     UNIMPLEMENTED();
   }

   // Spill all occurrences of an arbitrary register if possible.  Return the
   // register spilled or no_reg if it was not possible to free any register
   // (ie, they all have frame-external references).  Unimplemented.
   Register SpillAnyRegister();

   // Make this virtual frame have a state identical to an expected virtual
   // frame.  As a side effect, code may be emitted to make this frame match
   // the expected one.
   void MergeTo(VirtualFrame* expected, Condition cond = al);
   void MergeTo(const VirtualFrame* expected, Condition cond = al);

   // Checks whether this frame can be branched to by the other frame.
   bool IsCompatibleWith(const VirtualFrame* other) const {
     return (tos_known_smi_map_ & (~other->tos_known_smi_map_)) == 0;
   }

   inline void ForgetTypeInfo() {
     tos_known_smi_map_ = 0;
   }

   // Detach a frame from its code generator, perhaps temporarily.  This
   // tells the register allocator that it is free to use frame-internal
   // registers.  Used when the code generator's frame is switched from this
   // one to NULL by an unconditional jump.
   void DetachFromCodeGenerator() {
   }

   // (Re)attach a frame to its code generator.  This informs the register
   // allocator that the frame-internal register references are active again.
   // Used when a code generator's frame is switched from NULL to this one by
   // binding a label.
   void AttachToCodeGenerator() {
   }

   // Emit code for the physical JS entry and exit frame sequences.  After
   // calling Enter, the virtual frame is ready for use; and after calling
   // Exit it should not be used.  Note that Enter does not allocate space in
   // the physical frame for storing frame-allocated locals.
   void Enter();
   void Exit();

   // Prepare for returning from the frame by elements in the virtual frame. This
   // avoids generating unnecessary merge code when jumping to the
   // shared return site. No spill code emitted. Value to return should be in r0.
   inline void PrepareForReturn();

   // Number of local variables after when we use a loop for allocating.
   static const int kLocalVarBound = 5;

   // Allocate and initialize the frame-allocated locals.
   void AllocateStackSlots();

   // The current top of the expression stack as an assembly operand.
   MemOperand Top() {
     AssertIsSpilled();
     return MemOperand(sp, 0);
   }

   // An element of the expression stack as an assembly operand.
   MemOperand ElementAt(int index) {
     int adjusted_index = index - kVirtualElements[top_of_stack_state_];
     ASSERT(adjusted_index >= 0);
     return MemOperand(sp, adjusted_index * kPointerSize);
   }

   bool KnownSmiAt(int index) {
     if (index >= kTOSKnownSmiMapSize) return false;
     return (tos_known_smi_map_ & (1 << index)) != 0;
   }

   // A frame-allocated local as an assembly operand.
   inline MemOperand LocalAt(int index);

   // Push the address of the receiver slot on the frame.
   void PushReceiverSlotAddress();

   // The function frame slot.
   MemOperand Function() { return MemOperand(fp, kFunctionOffset); }

   // The context frame slot.
   MemOperand Context() { return MemOperand(fp, kContextOffset); }

   // A parameter as an assembly operand.
   inline MemOperand ParameterAt(int index);

   // The receiver frame slot.
   inline MemOperand Receiver();

   // Push a try-catch or try-finally handler on top of the virtual frame.
   void PushTryHandler(HandlerType type);

   // Call stub given the number of arguments it expects on (and
   // removes from) the stack.
   inline void CallStub(CodeStub* stub, int arg_count);

   // Call JS function from top of the stack with arguments
   // taken from the stack.
   void CallJSFunction(int arg_count);

   // Call runtime given the number of arguments expected on (and
   // removed from) the stack.
   void CallRuntime(Runtime::Function* f, int arg_count);
   void CallRuntime(Runtime::FunctionId id, int arg_count);

 #ifdef ENABLE_DEBUGGER_SUPPORT
   void DebugBreak();
 #endif

   // Invoke builtin given the number of arguments it expects on (and
   // removes from) the stack.
   void InvokeBuiltin(Builtins::JavaScript id,
                      InvokeJSFlags flag,
                      int arg_count);

   // Call load IC. Receiver is on the stack and is consumed. Result is returned
   // in r0.
   void CallLoadIC(Handle<String> name, RelocInfo::Mode mode);

   // Call store IC. If the load is contextual, value is found on top of the
   // frame. If not, value and receiver are on the frame. Both are consumed.
   // Result is returned in r0.
   void CallStoreIC(Handle<String> name, bool is_contextual);

   // Call keyed load IC. Key and receiver are on the stack. Both are consumed.
   // Result is returned in r0.
   void CallKeyedLoadIC();

   // Call keyed store IC. Value, key and receiver are on the stack. All three
   // are consumed. Result is returned in r0.
   void CallKeyedStoreIC();

   // Call into an IC stub given the number of arguments it removes
   // from the stack.  Register arguments to the IC stub are implicit,
   // and depend on the type of IC stub.
   void CallCodeObject(Handle<Code> ic,
                       RelocInfo::Mode rmode,
                       int dropped_args);

   // Drop a number of elements from the top of the expression stack.  May
   // emit code to affect the physical frame.  Does not clobber any registers
   // excepting possibly the stack pointer.
   void Drop(int count);

   // Drop one element.
   void Drop() { Drop(1); }

   // Pop an element from the top of the expression stack.  Discards
   // the result.
   void Pop();

   // Pop an element from the top of the expression stack.  The register
   // will be one normally used for the top of stack register allocation
   // so you can't hold on to it if you push on the stack.
   Register PopToRegister(Register but_not_to_this_one = no_reg);

   // Look at the top of the stack.  The register returned is aliased and
   // must be copied to a scratch register before modification.
   Register Peek();

   // Look at the value beneath the top of the stack.  The register returned is
   // aliased and must be copied to a scratch register before modification.
   Register Peek2();

   // Duplicate the top of stack.
   void Dup();

   // Duplicate the two elements on top of stack.
   void Dup2();

   // Flushes all registers, but it puts a copy of the top-of-stack in r0.
   void SpillAllButCopyTOSToR0();

   // Flushes all registers, but it puts a copy of the top-of-stack in r1.
   void SpillAllButCopyTOSToR1();

   // Flushes all registers, but it puts a copy of the top-of-stack in r1
   // and the next value on the stack in r0.
   void SpillAllButCopyTOSToR1R0();

   // Pop and save an element from the top of the expression stack and
   // emit a corresponding pop instruction.
   void EmitPop(Register reg);

   // Takes the top two elements and puts them in r0 (top element) and r1
   // (second element).
   void PopToR1R0();

   // Takes the top element and puts it in r1.
   void PopToR1();

   // Takes the top element and puts it in r0.
   void PopToR0();

   // Push an element on top of the expression stack and emit a
   // corresponding push instruction.
   void EmitPush(Register reg, TypeInfo type_info = TypeInfo::Unknown());
   void EmitPush(Operand operand, TypeInfo type_info = TypeInfo::Unknown());
   void EmitPush(MemOperand operand, TypeInfo type_info = TypeInfo::Unknown());
   void EmitPushRoot(Heap::RootListIndex index);

   // Overwrite the nth thing on the stack.  If the nth position is in a
   // register then this turns into a mov, otherwise an str.  Afterwards
   // you can still use the register even if it is a register that can be
   // used for TOS (r0 or r1).
   void SetElementAt(Register reg, int this_far_down);

   // Get a register which is free and which must be immediately used to
   // push on the top of the stack.
   Register GetTOSRegister();

   // Push multiple registers on the stack and the virtual frame
   // Register are selected by setting bit in src_regs and
   // are pushed in decreasing order: r15 .. r0.
   void EmitPushMultiple(int count, int src_regs);

   static Register scratch0() { return r7; }
   static Register scratch1() { return r9; }

  private:
   static const int kLocal0Offset = JavaScriptFrameConstants::kLocal0Offset;
   static const int kFunctionOffset = JavaScriptFrameConstants::kFunctionOffset;
   static const int kContextOffset = StandardFrameConstants::kContextOffset;

   static const int kHandlerSize = StackHandlerConstants::kSize / kPointerSize;
   static const int kPreallocatedElements = 5 + 8;  // 8 expression stack slots.

   // 5 states for the top of stack, which can be in memory or in r0 and r1.
   enum TopOfStack {
     NO_TOS_REGISTERS,
     R0_TOS,
     R1_TOS,
     R1_R0_TOS,
     R0_R1_TOS,
     TOS_STATES
   };

   static const int kMaxTOSRegisters = 2;

   static const bool kR0InUse[TOS_STATES];
   static const bool kR1InUse[TOS_STATES];
   static const int kVirtualElements[TOS_STATES];
   static const TopOfStack kStateAfterPop[TOS_STATES];
   static const TopOfStack kStateAfterPush[TOS_STATES];
   static const Register kTopRegister[TOS_STATES];
   static const Register kBottomRegister[TOS_STATES];

   // We allocate up to 5 locals in registers.
   static const int kNumberOfAllocatedRegisters = 5;
   // r2 to r6 are allocated to locals.
   static const int kFirstAllocatedRegister = 2;

   static const Register kAllocatedRegisters[kNumberOfAllocatedRegisters];

   static Register AllocatedRegister(int r) {
     ASSERT(r >= 0 && r < kNumberOfAllocatedRegisters);
     return kAllocatedRegisters[r];
   }

   // The number of elements on the stack frame.
   int element_count_;
   TopOfStack top_of_stack_state_:3;
   int register_allocation_map_:kNumberOfAllocatedRegisters;
   static const int kTOSKnownSmiMapSize = 4;
   unsigned tos_known_smi_map_:kTOSKnownSmiMapSize;

   // The index of the element that is at the processor's stack pointer
   // (the sp register).  For now since everything is in memory it is given
   // by the number of elements on the not-very-virtual stack frame.
   int stack_pointer() { return element_count_ - 1; }

   // The number of frame-allocated locals and parameters respectively.
   inline int parameter_count() const;
   inline int local_count() const;

   // The index of the element that is at the processor's frame pointer
   // (the fp register).  The parameters, receiver, function, and context
   // are below the frame pointer.
   inline int frame_pointer() const;

   // The index of the first parameter.  The receiver lies below the first
   // parameter.
   int param0_index() { return 1; }

   // The index of the context slot in the frame.  It is immediately
   // below the frame pointer.
   inline int context_index();

   // The index of the function slot in the frame.  It is below the frame
   // pointer and context slot.
   inline int function_index();

   // The index of the first local.  Between the frame pointer and the
   // locals lies the return address.
   inline int local0_index() const;

   // The index of the base of the expression stack.
   inline int expression_base_index() const;

   // Convert a frame index into a frame pointer relative offset into the
   // actual stack.
   inline int fp_relative(int index);

   // Spill all elements in registers. Spill the top spilled_args elements
   // on the frame.  Sync all other frame elements.
   // Then drop dropped_args elements from the virtual frame, to match
   // the effect of an upcoming call that will drop them from the stack.
   void PrepareForCall(int spilled_args, int dropped_args);

   // If all top-of-stack registers are in use then the lowest one is pushed
   // onto the physical stack and made free.
   void EnsureOneFreeTOSRegister();

   // Emit instructions to get the top of stack state from where we are to where
   // we want to be.
   void MergeTOSTo(TopOfStack expected_state, Condition cond = al);

   inline bool Equals(const VirtualFrame* other);

   inline void LowerHeight(int count) {
     element_count_ -= count;
     if (count >= kTOSKnownSmiMapSize) {
       tos_known_smi_map_ = 0;
     } else {
       tos_known_smi_map_ >>= count;
     }
   }

   inline void RaiseHeight(int count, unsigned known_smi_map = 0) {
     ASSERT(known_smi_map < (1u << count));
     element_count_ += count;
     if (count >= kTOSKnownSmiMapSize) {
       tos_known_smi_map_ = known_smi_map;
     } else {
       tos_known_smi_map_ = ((tos_known_smi_map_ << count) | known_smi_map);
     }
   }

   friend class JumpTarget;
 };


 } }  // namespace v8::internal

 #endif  // V8_ARM_VIRTUAL_FRAME_ARM_H_
	// Copyright 2009 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_VIRTUAL_FRAME_ARM_H_
	#define V8_ARM_VIRTUAL_FRAME_ARM_H_

	#include "register-allocator.h"

	namespace v8 {
	namespace internal {

	// This dummy class is only used to create invalid virtual frames.
	extern class InvalidVirtualFrameInitializer {}* kInvalidVirtualFrameInitializer;


	// -------------------------------------------------------------------------
	// Virtual frames
	//
	// The virtual frame is an abstraction of the physical stack frame. It
	// encapsulates the parameters, frame-allocated locals, and the expression
	// stack. It supports push/pop operations on the expression stack, as well
	// as random access to the expression stack elements, locals, and
	// parameters.

	class VirtualFrame : public ZoneObject {
	public:
	class RegisterAllocationScope;
	// A utility class to introduce a scope where the virtual frame is
	// expected to remain spilled. The constructor spills the code
	// generator's current frame, and keeps it spilled.
	class SpilledScope BASE_EMBEDDED {
	public:
	explicit SpilledScope(VirtualFrame* frame)
	: old_is_spilled_(is_spilled_) {
	if (frame != NULL) {
	if (!is_spilled_) {
	frame->SpillAll();
	} else {
	frame->AssertIsSpilled();
	}
	}
	is_spilled_ = true;
	}
	~SpilledScope() {
	is_spilled_ = old_is_spilled_;
	}
	static bool is_spilled() { return is_spilled_; }

	private:
	static bool is_spilled_;
	int old_is_spilled_;

	SpilledScope() { }

	friend class RegisterAllocationScope;
	};

	class RegisterAllocationScope BASE_EMBEDDED {
	public:
	// A utility class to introduce a scope where the virtual frame
	// is not spilled, ie. where register allocation occurs. Eventually
	// when RegisterAllocationScope is ubiquitous it can be removed
	// along with the (by then unused) SpilledScope class.
	inline explicit RegisterAllocationScope(CodeGenerator* cgen);
	inline ~RegisterAllocationScope();

	private:
	CodeGenerator* cgen_;
	bool old_is_spilled_;

	RegisterAllocationScope() { }
	};

	// An illegal index into the virtual frame.
	static const int kIllegalIndex = -1;

	// Construct an initial virtual frame on entry to a JS function.
	inline VirtualFrame();

	// Construct an invalid virtual frame, used by JumpTargets.
	inline VirtualFrame(InvalidVirtualFrameInitializer* dummy);

	// Construct a virtual frame as a clone of an existing one.
	explicit inline VirtualFrame(VirtualFrame* original);

	inline CodeGenerator* cgen() const;
	inline MacroAssembler* masm();

	// The number of elements on the virtual frame.
	int element_count() const { return element_count_; }

	// The height of the virtual expression stack.
	inline int height() const;

	bool is_used(int num) {
	switch (num) {
	case 0: { // r0.
	return kR0InUse[top_of_stack_state_];
	}
	case 1: { // r1.
	return kR1InUse[top_of_stack_state_];
	}
	case 2:
	case 3:
	case 4:
	case 5:
	case 6: { // r2 to r6.
	ASSERT(num - kFirstAllocatedRegister < kNumberOfAllocatedRegisters);
	ASSERT(num >= kFirstAllocatedRegister);
	if ((register_allocation_map_ &
	(1 << (num - kFirstAllocatedRegister))) == 0) {
	return false;
	} else {
	return true;
	}
	}
	default: {
	ASSERT(num < kFirstAllocatedRegister \|\|
	num >= kFirstAllocatedRegister + kNumberOfAllocatedRegisters);
	return false;
	}
	}
	}

	// Add extra in-memory elements to the top of the frame to match an actual
	// frame (eg, the frame after an exception handler is pushed). No code is
	// emitted.
	void Adjust(int count);

	// Forget elements from the top of the frame to match an actual frame (eg,
	// the frame after a runtime call). No code is emitted except to bring the
	// frame to a spilled state.
	void Forget(int count);

	// Spill all values from the frame to memory.
	void SpillAll();

	void AssertIsSpilled() const {
	ASSERT(top_of_stack_state_ == NO_TOS_REGISTERS);
	ASSERT(register_allocation_map_ == 0);
	}

	void AssertIsNotSpilled() {
	ASSERT(!SpilledScope::is_spilled());
	}

	// Spill all occurrences of a specific register from the frame.
	void Spill(Register reg) {
	UNIMPLEMENTED();
	}

	// Spill all occurrences of an arbitrary register if possible. Return the
	// register spilled or no_reg if it was not possible to free any register
	// (ie, they all have frame-external references). Unimplemented.
	Register SpillAnyRegister();

	// Make this virtual frame have a state identical to an expected virtual
	// frame. As a side effect, code may be emitted to make this frame match
	// the expected one.
	void MergeTo(VirtualFrame* expected, Condition cond = al);
	void MergeTo(const VirtualFrame* expected, Condition cond = al);

	// Checks whether this frame can be branched to by the other frame.
	bool IsCompatibleWith(const VirtualFrame* other) const {
	return (tos_known_smi_map_ & (~other->tos_known_smi_map_)) == 0;
	}

	inline void ForgetTypeInfo() {
	tos_known_smi_map_ = 0;
	}

	// Detach a frame from its code generator, perhaps temporarily. This
	// tells the register allocator that it is free to use frame-internal
	// registers. Used when the code generator's frame is switched from this
	// one to NULL by an unconditional jump.
	void DetachFromCodeGenerator() {
	}

	// (Re)attach a frame to its code generator. This informs the register
	// allocator that the frame-internal register references are active again.
	// Used when a code generator's frame is switched from NULL to this one by
	// binding a label.
	void AttachToCodeGenerator() {
	}

	// Emit code for the physical JS entry and exit frame sequences. After
	// calling Enter, the virtual frame is ready for use; and after calling
	// Exit it should not be used. Note that Enter does not allocate space in
	// the physical frame for storing frame-allocated locals.
	void Enter();
	void Exit();

	// Prepare for returning from the frame by elements in the virtual frame. This
	// avoids generating unnecessary merge code when jumping to the
	// shared return site. No spill code emitted. Value to return should be in r0.
	inline void PrepareForReturn();

	// Number of local variables after when we use a loop for allocating.
	static const int kLocalVarBound = 5;

	// Allocate and initialize the frame-allocated locals.
	void AllocateStackSlots();

	// The current top of the expression stack as an assembly operand.
	MemOperand Top() {
	AssertIsSpilled();
	return MemOperand(sp, 0);
	}

	// An element of the expression stack as an assembly operand.
	MemOperand ElementAt(int index) {
	int adjusted_index = index - kVirtualElements[top_of_stack_state_];
	ASSERT(adjusted_index >= 0);
	return MemOperand(sp, adjusted_index * kPointerSize);
	}

	bool KnownSmiAt(int index) {
	if (index >= kTOSKnownSmiMapSize) return false;
	return (tos_known_smi_map_ & (1 << index)) != 0;
	}

	// A frame-allocated local as an assembly operand.
	inline MemOperand LocalAt(int index);

	// Push the address of the receiver slot on the frame.
	void PushReceiverSlotAddress();

	// The function frame slot.
	MemOperand Function() { return MemOperand(fp, kFunctionOffset); }

	// The context frame slot.
	MemOperand Context() { return MemOperand(fp, kContextOffset); }

	// A parameter as an assembly operand.
	inline MemOperand ParameterAt(int index);

	// The receiver frame slot.
	inline MemOperand Receiver();

	// Push a try-catch or try-finally handler on top of the virtual frame.
	void PushTryHandler(HandlerType type);

	// Call stub given the number of arguments it expects on (and
	// removes from) the stack.
	inline void CallStub(CodeStub* stub, int arg_count);

	// Call JS function from top of the stack with arguments
	// taken from the stack.
	void CallJSFunction(int arg_count);

	// Call runtime given the number of arguments expected on (and
	// removed from) the stack.
	void CallRuntime(Runtime::Function* f, int arg_count);
	void CallRuntime(Runtime::FunctionId id, int arg_count);

	#ifdef ENABLE_DEBUGGER_SUPPORT
	void DebugBreak();
	#endif

	// Invoke builtin given the number of arguments it expects on (and
	// removes from) the stack.
	void InvokeBuiltin(Builtins::JavaScript id,
	InvokeJSFlags flag,
	int arg_count);

	// Call load IC. Receiver is on the stack and is consumed. Result is returned
	// in r0.
	void CallLoadIC(Handle<String> name, RelocInfo::Mode mode);

	// Call store IC. If the load is contextual, value is found on top of the
	// frame. If not, value and receiver are on the frame. Both are consumed.
	// Result is returned in r0.
	void CallStoreIC(Handle<String> name, bool is_contextual);

	// Call keyed load IC. Key and receiver are on the stack. Both are consumed.
	// Result is returned in r0.
	void CallKeyedLoadIC();

	// Call keyed store IC. Value, key and receiver are on the stack. All three
	// are consumed. Result is returned in r0.
	void CallKeyedStoreIC();

	// Call into an IC stub given the number of arguments it removes
	// from the stack. Register arguments to the IC stub are implicit,
	// and depend on the type of IC stub.
	void CallCodeObject(Handle<Code> ic,
	RelocInfo::Mode rmode,
	int dropped_args);

	// Drop a number of elements from the top of the expression stack. May
	// emit code to affect the physical frame. Does not clobber any registers
	// excepting possibly the stack pointer.
	void Drop(int count);

	// Drop one element.
	void Drop() { Drop(1); }

	// Pop an element from the top of the expression stack. Discards
	// the result.
	void Pop();

	// Pop an element from the top of the expression stack. The register
	// will be one normally used for the top of stack register allocation
	// so you can't hold on to it if you push on the stack.
	Register PopToRegister(Register but_not_to_this_one = no_reg);

	// Look at the top of the stack. The register returned is aliased and
	// must be copied to a scratch register before modification.
	Register Peek();

	// Look at the value beneath the top of the stack. The register returned is
	// aliased and must be copied to a scratch register before modification.
	Register Peek2();

	// Duplicate the top of stack.
	void Dup();

	// Duplicate the two elements on top of stack.
	void Dup2();

	// Flushes all registers, but it puts a copy of the top-of-stack in r0.
	void SpillAllButCopyTOSToR0();

	// Flushes all registers, but it puts a copy of the top-of-stack in r1.
	void SpillAllButCopyTOSToR1();

	// Flushes all registers, but it puts a copy of the top-of-stack in r1
	// and the next value on the stack in r0.
	void SpillAllButCopyTOSToR1R0();

	// Pop and save an element from the top of the expression stack and
	// emit a corresponding pop instruction.
	void EmitPop(Register reg);

	// Takes the top two elements and puts them in r0 (top element) and r1
	// (second element).
	void PopToR1R0();

	// Takes the top element and puts it in r1.
	void PopToR1();

	// Takes the top element and puts it in r0.
	void PopToR0();

	// Push an element on top of the expression stack and emit a
	// corresponding push instruction.
	void EmitPush(Register reg, TypeInfo type_info = TypeInfo::Unknown());
	void EmitPush(Operand operand, TypeInfo type_info = TypeInfo::Unknown());
	void EmitPush(MemOperand operand, TypeInfo type_info = TypeInfo::Unknown());
	void EmitPushRoot(Heap::RootListIndex index);

	// Overwrite the nth thing on the stack. If the nth position is in a
	// register then this turns into a mov, otherwise an str. Afterwards
	// you can still use the register even if it is a register that can be
	// used for TOS (r0 or r1).
	void SetElementAt(Register reg, int this_far_down);

	// Get a register which is free and which must be immediately used to
	// push on the top of the stack.
	Register GetTOSRegister();

	// Push multiple registers on the stack and the virtual frame
	// Register are selected by setting bit in src_regs and
	// are pushed in decreasing order: r15 .. r0.
	void EmitPushMultiple(int count, int src_regs);

	static Register scratch0() { return r7; }
	static Register scratch1() { return r9; }

	private:
	static const int kLocal0Offset = JavaScriptFrameConstants::kLocal0Offset;
	static const int kFunctionOffset = JavaScriptFrameConstants::kFunctionOffset;
	static const int kContextOffset = StandardFrameConstants::kContextOffset;

	static const int kHandlerSize = StackHandlerConstants::kSize / kPointerSize;
	static const int kPreallocatedElements = 5 + 8; // 8 expression stack slots.

	// 5 states for the top of stack, which can be in memory or in r0 and r1.
	enum TopOfStack {
	NO_TOS_REGISTERS,
	R0_TOS,
	R1_TOS,
	R1_R0_TOS,
	R0_R1_TOS,
	TOS_STATES
	};

	static const int kMaxTOSRegisters = 2;

	static const bool kR0InUse[TOS_STATES];
	static const bool kR1InUse[TOS_STATES];
	static const int kVirtualElements[TOS_STATES];
	static const TopOfStack kStateAfterPop[TOS_STATES];
	static const TopOfStack kStateAfterPush[TOS_STATES];
	static const Register kTopRegister[TOS_STATES];
	static const Register kBottomRegister[TOS_STATES];

	// We allocate up to 5 locals in registers.
	static const int kNumberOfAllocatedRegisters = 5;
	// r2 to r6 are allocated to locals.
	static const int kFirstAllocatedRegister = 2;

	static const Register kAllocatedRegisters[kNumberOfAllocatedRegisters];

	static Register AllocatedRegister(int r) {
	ASSERT(r >= 0 && r < kNumberOfAllocatedRegisters);
	return kAllocatedRegisters[r];
	}

	// The number of elements on the stack frame.
	int element_count_;
	TopOfStack top_of_stack_state_:3;
	int register_allocation_map_:kNumberOfAllocatedRegisters;
	static const int kTOSKnownSmiMapSize = 4;
	unsigned tos_known_smi_map_:kTOSKnownSmiMapSize;

	// The index of the element that is at the processor's stack pointer
	// (the sp register). For now since everything is in memory it is given
	// by the number of elements on the not-very-virtual stack frame.
	int stack_pointer() { return element_count_ - 1; }

	// The number of frame-allocated locals and parameters respectively.
	inline int parameter_count() const;
	inline int local_count() const;

	// The index of the element that is at the processor's frame pointer
	// (the fp register). The parameters, receiver, function, and context
	// are below the frame pointer.
	inline int frame_pointer() const;

	// The index of the first parameter. The receiver lies below the first
	// parameter.
	int param0_index() { return 1; }

	// The index of the context slot in the frame. It is immediately
	// below the frame pointer.
	inline int context_index();

	// The index of the function slot in the frame. It is below the frame
	// pointer and context slot.
	inline int function_index();

	// The index of the first local. Between the frame pointer and the
	// locals lies the return address.
	inline int local0_index() const;

	// The index of the base of the expression stack.
	inline int expression_base_index() const;

	// Convert a frame index into a frame pointer relative offset into the
	// actual stack.
	inline int fp_relative(int index);

	// Spill all elements in registers. Spill the top spilled_args elements
	// on the frame. Sync all other frame elements.
	// Then drop dropped_args elements from the virtual frame, to match
	// the effect of an upcoming call that will drop them from the stack.
	void PrepareForCall(int spilled_args, int dropped_args);

	// If all top-of-stack registers are in use then the lowest one is pushed
	// onto the physical stack and made free.
	void EnsureOneFreeTOSRegister();

	// Emit instructions to get the top of stack state from where we are to where
	// we want to be.
	void MergeTOSTo(TopOfStack expected_state, Condition cond = al);

	inline bool Equals(const VirtualFrame* other);

	inline void LowerHeight(int count) {
	element_count_ -= count;
	if (count >= kTOSKnownSmiMapSize) {
	tos_known_smi_map_ = 0;
	} else {
	tos_known_smi_map_ >>= count;
	}
	}

	inline void RaiseHeight(int count, unsigned known_smi_map = 0) {
	ASSERT(known_smi_map < (1u << count));
	element_count_ += count;
	if (count >= kTOSKnownSmiMapSize) {
	tos_known_smi_map_ = known_smi_map;
	} else {
	tos_known_smi_map_ = ((tos_known_smi_map_ << count) \| known_smi_map);
	}
	}

	friend class JumpTarget;
	};


	} } // namespace v8::internal

	#endif // V8_ARM_VIRTUAL_FRAME_ARM_H_