src/mips64/simulator-mips64.h - fp2-dev/platform/external/v8 - Gitiles

 // Copyright 2011 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.


 // Declares a Simulator for MIPS instructions if we are not generating a native
 // MIPS binary. This Simulator allows us to run and debug MIPS code generation
 // on regular desktop machines.
 // V8 calls into generated code by "calling" the CALL_GENERATED_CODE macro,
 // which will start execution in the Simulator or forwards to the real entry
 // on a MIPS HW platform.

 #ifndef V8_MIPS_SIMULATOR_MIPS_H_
 #define V8_MIPS_SIMULATOR_MIPS_H_

 #include "src/allocation.h"
 #include "src/mips64/constants-mips64.h"

 #if !defined(USE_SIMULATOR)
 // Running without a simulator on a native mips platform.

 namespace v8 {
 namespace internal {

 // When running without a simulator we call the entry directly.
 #define CALL_GENERATED_CODE(isolate, entry, p0, p1, p2, p3, p4) \
   entry(p0, p1, p2, p3, p4)


 // Call the generated regexp code directly. The code at the entry address
 // should act as a function matching the type arm_regexp_matcher.
 // The fifth (or ninth) argument is a dummy that reserves the space used for
 // the return address added by the ExitFrame in native calls.
 typedef int (*mips_regexp_matcher)(String* input,
                                    int64_t start_offset,
                                    const byte* input_start,
                                    const byte* input_end,
                                    int* output,
                                    int64_t output_size,
                                    Address stack_base,
                                    int64_t direct_call,
                                    void* return_address,
                                    Isolate* isolate);

 #define CALL_GENERATED_REGEXP_CODE(isolate, entry, p0, p1, p2, p3, p4, p5, p6, \
                                    p7, p8)                                     \
   (FUNCTION_CAST<mips_regexp_matcher>(entry)(p0, p1, p2, p3, p4, p5, p6, p7,   \
                                              NULL, p8))


 // The stack limit beyond which we will throw stack overflow errors in
 // generated code. Because generated code on mips uses the C stack, we
 // just use the C stack limit.
 class SimulatorStack : public v8::internal::AllStatic {
  public:
   static inline uintptr_t JsLimitFromCLimit(Isolate* isolate,
                                             uintptr_t c_limit) {
     return c_limit;
   }

   static inline uintptr_t RegisterCTryCatch(Isolate* isolate,
                                             uintptr_t try_catch_address) {
     USE(isolate);
     return try_catch_address;
   }

   static inline void UnregisterCTryCatch(Isolate* isolate) { USE(isolate); }
 };

 }  // namespace internal
 }  // namespace v8

 // Calculated the stack limit beyond which we will throw stack overflow errors.
 // This macro must be called from a C++ method. It relies on being able to take
 // the address of "this" to get a value on the current execution stack and then
 // calculates the stack limit based on that value.
 // NOTE: The check for overflow is not safe as there is no guarantee that the
 // running thread has its stack in all memory up to address 0x00000000.
 #define GENERATED_CODE_STACK_LIMIT(limit) \
   (reinterpret_cast<uintptr_t>(this) >= limit ? \
       reinterpret_cast<uintptr_t>(this) - limit : 0)

 #else  // !defined(USE_SIMULATOR)
 // Running with a simulator.

 #include "src/assembler.h"
 #include "src/base/hashmap.h"

 namespace v8 {
 namespace internal {

 // -----------------------------------------------------------------------------
 // Utility functions

 class CachePage {
  public:
   static const int LINE_VALID = 0;
   static const int LINE_INVALID = 1;

   static const int kPageShift = 12;
   static const int kPageSize = 1 << kPageShift;
   static const int kPageMask = kPageSize - 1;
   static const int kLineShift = 2;  // The cache line is only 4 bytes right now.
   static const int kLineLength = 1 << kLineShift;
   static const int kLineMask = kLineLength - 1;

   CachePage() {
     memset(&validity_map_, LINE_INVALID, sizeof(validity_map_));
   }

   char* ValidityByte(int offset) {
     return &validity_map_[offset >> kLineShift];
   }

   char* CachedData(int offset) {
     return &data_[offset];
   }

  private:
   char data_[kPageSize];   // The cached data.
   static const int kValidityMapSize = kPageSize >> kLineShift;
   char validity_map_[kValidityMapSize];  // One byte per line.
 };

 class Simulator {
  public:
   friend class MipsDebugger;

   // Registers are declared in order. See SMRL chapter 2.
   enum Register {
     no_reg = -1,
     zero_reg = 0,
     at,
     v0, v1,
     a0, a1, a2, a3, a4, a5, a6, a7,
     t0, t1, t2, t3,
     s0, s1, s2, s3, s4, s5, s6, s7,
     t8, t9,
     k0, k1,
     gp,
     sp,
     s8,
     ra,
     // LO, HI, and pc.
     LO,
     HI,
     pc,   // pc must be the last register.
     kNumSimuRegisters,
     // aliases
     fp = s8
   };

   // Coprocessor registers.
   // Generated code will always use doubles. So we will only use even registers.
   enum FPURegister {
     f0, f1, f2, f3, f4, f5, f6, f7, f8, f9, f10, f11,
     f12, f13, f14, f15,   // f12 and f14 are arguments FPURegisters.
     f16, f17, f18, f19, f20, f21, f22, f23, f24, f25,
     f26, f27, f28, f29, f30, f31,
     kNumFPURegisters
   };

   explicit Simulator(Isolate* isolate);
   ~Simulator();

   // The currently executing Simulator instance. Potentially there can be one
   // for each native thread.
   static Simulator* current(v8::internal::Isolate* isolate);

   // Accessors for register state. Reading the pc value adheres to the MIPS
   // architecture specification and is off by a 8 from the currently executing
   // instruction.
   void set_register(int reg, int64_t value);
   void set_register_word(int reg, int32_t value);
   void set_dw_register(int dreg, const int* dbl);
   int64_t get_register(int reg) const;
   double get_double_from_register_pair(int reg);
   // Same for FPURegisters.
   void set_fpu_register(int fpureg, int64_t value);
   void set_fpu_register_word(int fpureg, int32_t value);
   void set_fpu_register_hi_word(int fpureg, int32_t value);
   void set_fpu_register_float(int fpureg, float value);
   void set_fpu_register_double(int fpureg, double value);
   void set_fpu_register_invalid_result64(float original, float rounded);
   void set_fpu_register_invalid_result(float original, float rounded);
   void set_fpu_register_word_invalid_result(float original, float rounded);
   void set_fpu_register_invalid_result64(double original, double rounded);
   void set_fpu_register_invalid_result(double original, double rounded);
   void set_fpu_register_word_invalid_result(double original, double rounded);
   int64_t get_fpu_register(int fpureg) const;
   int32_t get_fpu_register_word(int fpureg) const;
   int32_t get_fpu_register_signed_word(int fpureg) const;
   int32_t get_fpu_register_hi_word(int fpureg) const;
   float get_fpu_register_float(int fpureg) const;
   double get_fpu_register_double(int fpureg) const;
   void set_fcsr_bit(uint32_t cc, bool value);
   bool test_fcsr_bit(uint32_t cc);
   bool set_fcsr_round_error(double original, double rounded);
   bool set_fcsr_round64_error(double original, double rounded);
   bool set_fcsr_round_error(float original, float rounded);
   bool set_fcsr_round64_error(float original, float rounded);
   void round_according_to_fcsr(double toRound, double& rounded,
                                int32_t& rounded_int, double fs);
   void round64_according_to_fcsr(double toRound, double& rounded,
                                  int64_t& rounded_int, double fs);
   void round_according_to_fcsr(float toRound, float& rounded,
                                int32_t& rounded_int, float fs);
   void round64_according_to_fcsr(float toRound, float& rounded,
                                  int64_t& rounded_int, float fs);
   void set_fcsr_rounding_mode(FPURoundingMode mode);
   unsigned int get_fcsr_rounding_mode();
   // Special case of set_register and get_register to access the raw PC value.
   void set_pc(int64_t value);
   int64_t get_pc() const;

   Address get_sp() const {
     return reinterpret_cast<Address>(static_cast<intptr_t>(get_register(sp)));
   }

   // Accessor to the internal simulator stack area.
   uintptr_t StackLimit(uintptr_t c_limit) const;

   // Executes MIPS instructions until the PC reaches end_sim_pc.
   void Execute();

   // Call on program start.
   static void Initialize(Isolate* isolate);

   static void TearDown(base::HashMap* i_cache, Redirection* first);

   // V8 generally calls into generated JS code with 5 parameters and into
   // generated RegExp code with 7 parameters. This is a convenience function,
   // which sets up the simulator state and grabs the result on return.
   int64_t Call(byte* entry, int argument_count, ...);
   // Alternative: call a 2-argument double function.
   double CallFP(byte* entry, double d0, double d1);

   // Push an address onto the JS stack.
   uintptr_t PushAddress(uintptr_t address);

   // Pop an address from the JS stack.
   uintptr_t PopAddress();

   // Debugger input.
   void set_last_debugger_input(char* input);
   char* last_debugger_input() { return last_debugger_input_; }

   // ICache checking.
   static void FlushICache(base::HashMap* i_cache, void* start, size_t size);

   // Returns true if pc register contains one of the 'special_values' defined
   // below (bad_ra, end_sim_pc).
   bool has_bad_pc() const;

  private:
   enum special_values {
     // Known bad pc value to ensure that the simulator does not execute
     // without being properly setup.
     bad_ra = -1,
     // A pc value used to signal the simulator to stop execution.  Generally
     // the ra is set to this value on transition from native C code to
     // simulated execution, so that the simulator can "return" to the native
     // C code.
     end_sim_pc = -2,
     // Unpredictable value.
     Unpredictable = 0xbadbeaf
   };

   // Unsupported instructions use Format to print an error and stop execution.
   void Format(Instruction* instr, const char* format);

   // Read and write memory.
   inline uint32_t ReadBU(int64_t addr);
   inline int32_t ReadB(int64_t addr);
   inline void WriteB(int64_t addr, uint8_t value);
   inline void WriteB(int64_t addr, int8_t value);

   inline uint16_t ReadHU(int64_t addr, Instruction* instr);
   inline int16_t ReadH(int64_t addr, Instruction* instr);
   // Note: Overloaded on the sign of the value.
   inline void WriteH(int64_t addr, uint16_t value, Instruction* instr);
   inline void WriteH(int64_t addr, int16_t value, Instruction* instr);

   inline uint32_t ReadWU(int64_t addr, Instruction* instr);
   inline int32_t ReadW(int64_t addr, Instruction* instr);
   inline void WriteW(int64_t addr, int32_t value, Instruction* instr);
   inline int64_t Read2W(int64_t addr, Instruction* instr);
   inline void Write2W(int64_t addr, int64_t value, Instruction* instr);

   inline double ReadD(int64_t addr, Instruction* instr);
   inline void WriteD(int64_t addr, double value, Instruction* instr);

   // Helper for debugging memory access.
   inline void DieOrDebug();

   // Helpers for data value tracing.
     enum TraceType {
     BYTE,
     HALF,
     WORD,
     DWORD
     // DFLOAT - Floats may have printing issues due to paired lwc1's
   };

   void TraceRegWr(int64_t value);
   void TraceMemWr(int64_t addr, int64_t value, TraceType t);
   void TraceMemRd(int64_t addr, int64_t value);

   // Operations depending on endianness.
   // Get Double Higher / Lower word.
   inline int32_t GetDoubleHIW(double* addr);
   inline int32_t GetDoubleLOW(double* addr);
   // Set Double Higher / Lower word.
   inline int32_t SetDoubleHIW(double* addr);
   inline int32_t SetDoubleLOW(double* addr);

   // functions called from DecodeTypeRegister.
   void DecodeTypeRegisterCOP1();

   void DecodeTypeRegisterCOP1X();

   void DecodeTypeRegisterSPECIAL();


   void DecodeTypeRegisterSPECIAL2();

   void DecodeTypeRegisterSPECIAL3();

   void DecodeTypeRegisterSRsType();

   void DecodeTypeRegisterDRsType();

   void DecodeTypeRegisterWRsType();

   void DecodeTypeRegisterLRsType();

   // Executing is handled based on the instruction type.
   void DecodeTypeRegister(Instruction* instr);

   Instruction* currentInstr_;
   inline Instruction* get_instr() const { return currentInstr_; }
   inline void set_instr(Instruction* instr) { currentInstr_ = instr; }

   inline int32_t rs_reg() const { return currentInstr_->RsValue(); }
   inline int64_t rs() const { return get_register(rs_reg()); }
   inline uint64_t rs_u() const {
     return static_cast<uint64_t>(get_register(rs_reg()));
   }
   inline int32_t rt_reg() const { return currentInstr_->RtValue(); }
   inline int64_t rt() const { return get_register(rt_reg()); }
   inline uint64_t rt_u() const {
     return static_cast<uint64_t>(get_register(rt_reg()));
   }
   inline int32_t rd_reg() const { return currentInstr_->RdValue(); }
   inline int32_t fr_reg() const { return currentInstr_->FrValue(); }
   inline int32_t fs_reg() const { return currentInstr_->FsValue(); }
   inline int32_t ft_reg() const { return currentInstr_->FtValue(); }
   inline int32_t fd_reg() const { return currentInstr_->FdValue(); }
   inline int32_t sa() const { return currentInstr_->SaValue(); }
   inline int32_t lsa_sa() const { return currentInstr_->LsaSaValue(); }

   inline void SetResult(const int32_t rd_reg, const int64_t alu_out) {
     set_register(rd_reg, alu_out);
     TraceRegWr(alu_out);
   }

   void DecodeTypeImmediate(Instruction* instr);
   void DecodeTypeJump(Instruction* instr);

   // Used for breakpoints and traps.
   void SoftwareInterrupt(Instruction* instr);

   // Compact branch guard.
   void CheckForbiddenSlot(int64_t current_pc) {
     Instruction* instr_after_compact_branch =
         reinterpret_cast<Instruction*>(current_pc + Instruction::kInstrSize);
     if (instr_after_compact_branch->IsForbiddenAfterBranch()) {
       V8_Fatal(__FILE__, __LINE__,
                "Error: Unexpected instruction 0x%08x immediately after a "
                "compact branch instruction.",
                *reinterpret_cast<uint32_t*>(instr_after_compact_branch));
     }
   }

   // Stop helper functions.
   bool IsWatchpoint(uint64_t code);
   void PrintWatchpoint(uint64_t code);
   void HandleStop(uint64_t code, Instruction* instr);
   bool IsStopInstruction(Instruction* instr);
   bool IsEnabledStop(uint64_t code);
   void EnableStop(uint64_t code);
   void DisableStop(uint64_t code);
   void IncreaseStopCounter(uint64_t code);
   void PrintStopInfo(uint64_t code);


   // Executes one instruction.
   void InstructionDecode(Instruction* instr);
   // Execute one instruction placed in a branch delay slot.
   void BranchDelayInstructionDecode(Instruction* instr) {
     if (instr->InstructionBits() == nopInstr) {
       // Short-cut generic nop instructions. They are always valid and they
       // never change the simulator state.
       return;
     }

     if (instr->IsForbiddenAfterBranch()) {
       V8_Fatal(__FILE__, __LINE__,
                "Eror:Unexpected %i opcode in a branch delay slot.",
                instr->OpcodeValue());
     }
     InstructionDecode(instr);
     SNPrintF(trace_buf_, " ");
   }

   // ICache.
   static void CheckICache(base::HashMap* i_cache, Instruction* instr);
   static void FlushOnePage(base::HashMap* i_cache, intptr_t start, size_t size);
   static CachePage* GetCachePage(base::HashMap* i_cache, void* page);

   enum Exception {
     none,
     kIntegerOverflow,
     kIntegerUnderflow,
     kDivideByZero,
     kNumExceptions
   };

   // Exceptions.
   void SignalException(Exception e);

   // Runtime call support.
   static void* RedirectExternalReference(Isolate* isolate,
                                          void* external_function,
                                          ExternalReference::Type type);

   // Handle arguments and return value for runtime FP functions.
   void GetFpArgs(double* x, double* y, int32_t* z);
   void SetFpResult(const double& result);

   void CallInternal(byte* entry);

   // Architecture state.
   // Registers.
   int64_t registers_[kNumSimuRegisters];
   // Coprocessor Registers.
   int64_t FPUregisters_[kNumFPURegisters];
   // FPU control register.
   uint32_t FCSR_;

   // Simulator support.
   // Allocate 1MB for stack.
   size_t stack_size_;
   char* stack_;
   bool pc_modified_;
   int64_t icount_;
   int break_count_;
   EmbeddedVector<char, 128> trace_buf_;

   // Debugger input.
   char* last_debugger_input_;

   // Icache simulation.
   base::HashMap* i_cache_;

   v8::internal::Isolate* isolate_;

   // Registered breakpoints.
   Instruction* break_pc_;
   Instr break_instr_;

   // Stop is disabled if bit 31 is set.
   static const uint32_t kStopDisabledBit = 1 << 31;

   // A stop is enabled, meaning the simulator will stop when meeting the
   // instruction, if bit 31 of watched_stops_[code].count is unset.
   // The value watched_stops_[code].count & ~(1 << 31) indicates how many times
   // the breakpoint was hit or gone through.
   struct StopCountAndDesc {
     uint32_t count;
     char* desc;
   };
   StopCountAndDesc watched_stops_[kMaxStopCode + 1];
 };


 // When running with the simulator transition into simulated execution at this
 // point.
 #define CALL_GENERATED_CODE(isolate, entry, p0, p1, p2, p3, p4)       \
   reinterpret_cast<Object*>(Simulator::current(isolate)->Call(        \
       FUNCTION_ADDR(entry), 5, reinterpret_cast<int64_t*>(p0),        \
       reinterpret_cast<int64_t*>(p1), reinterpret_cast<int64_t*>(p2), \
       reinterpret_cast<int64_t*>(p3), reinterpret_cast<int64_t*>(p4)))


 #define CALL_GENERATED_REGEXP_CODE(isolate, entry, p0, p1, p2, p3, p4, p5, p6, \
                                    p7, p8)                                     \
   static_cast<int>(Simulator::current(isolate)->Call(                          \
       entry, 10, p0, p1, p2, p3, p4, reinterpret_cast<int64_t*>(p5), p6, p7,   \
       NULL, p8))


 // The simulator has its own stack. Thus it has a different stack limit from
 // the C-based native code.  The JS-based limit normally points near the end of
 // the simulator stack.  When the C-based limit is exhausted we reflect that by
 // lowering the JS-based limit as well, to make stack checks trigger.
 class SimulatorStack : public v8::internal::AllStatic {
  public:
   static inline uintptr_t JsLimitFromCLimit(Isolate* isolate,
                                             uintptr_t c_limit) {
     return Simulator::current(isolate)->StackLimit(c_limit);
   }

   static inline uintptr_t RegisterCTryCatch(Isolate* isolate,
                                             uintptr_t try_catch_address) {
     Simulator* sim = Simulator::current(isolate);
     return sim->PushAddress(try_catch_address);
   }

   static inline void UnregisterCTryCatch(Isolate* isolate) {
     Simulator::current(isolate)->PopAddress();
   }
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // !defined(USE_SIMULATOR)
 #endif  // V8_MIPS_SIMULATOR_MIPS_H_
	// Copyright 2011 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.


	// Declares a Simulator for MIPS instructions if we are not generating a native
	// MIPS binary. This Simulator allows us to run and debug MIPS code generation
	// on regular desktop machines.
	// V8 calls into generated code by "calling" the CALL_GENERATED_CODE macro,
	// which will start execution in the Simulator or forwards to the real entry
	// on a MIPS HW platform.

	#ifndef V8_MIPS_SIMULATOR_MIPS_H_
	#define V8_MIPS_SIMULATOR_MIPS_H_

	#include "src/allocation.h"
	#include "src/mips64/constants-mips64.h"

	#if !defined(USE_SIMULATOR)
	// Running without a simulator on a native mips platform.

	namespace v8 {
	namespace internal {

	// When running without a simulator we call the entry directly.
	#define CALL_GENERATED_CODE(isolate, entry, p0, p1, p2, p3, p4) \
	entry(p0, p1, p2, p3, p4)


	// Call the generated regexp code directly. The code at the entry address
	// should act as a function matching the type arm_regexp_matcher.
	// The fifth (or ninth) argument is a dummy that reserves the space used for
	// the return address added by the ExitFrame in native calls.
	typedef int (mips_regexp_matcher)(String input,
	int64_t start_offset,
	const byte* input_start,
	const byte* input_end,
	int* output,
	int64_t output_size,
	Address stack_base,
	int64_t direct_call,
	void* return_address,
	Isolate* isolate);

	#define CALL_GENERATED_REGEXP_CODE(isolate, entry, p0, p1, p2, p3, p4, p5, p6, \
	p7, p8) \
	(FUNCTION_CAST<mips_regexp_matcher>(entry)(p0, p1, p2, p3, p4, p5, p6, p7, \
	NULL, p8))


	// The stack limit beyond which we will throw stack overflow errors in
	// generated code. Because generated code on mips uses the C stack, we
	// just use the C stack limit.
	class SimulatorStack : public v8::internal::AllStatic {
	public:
	static inline uintptr_t JsLimitFromCLimit(Isolate* isolate,
	uintptr_t c_limit) {
	return c_limit;
	}

	static inline uintptr_t RegisterCTryCatch(Isolate* isolate,
	uintptr_t try_catch_address) {
	USE(isolate);
	return try_catch_address;
	}

	static inline void UnregisterCTryCatch(Isolate* isolate) { USE(isolate); }
	};

	} // namespace internal
	} // namespace v8

	// Calculated the stack limit beyond which we will throw stack overflow errors.
	// This macro must be called from a C++ method. It relies on being able to take
	// the address of "this" to get a value on the current execution stack and then
	// calculates the stack limit based on that value.
	// NOTE: The check for overflow is not safe as there is no guarantee that the
	// running thread has its stack in all memory up to address 0x00000000.
	#define GENERATED_CODE_STACK_LIMIT(limit) \
	(reinterpret_cast<uintptr_t>(this) >= limit ? \
	reinterpret_cast<uintptr_t>(this) - limit : 0)

	#else // !defined(USE_SIMULATOR)
	// Running with a simulator.

	#include "src/assembler.h"
	#include "src/base/hashmap.h"

	namespace v8 {
	namespace internal {

	// -----------------------------------------------------------------------------
	// Utility functions

	class CachePage {
	public:
	static const int LINE_VALID = 0;
	static const int LINE_INVALID = 1;

	static const int kPageShift = 12;
	static const int kPageSize = 1 << kPageShift;
	static const int kPageMask = kPageSize - 1;
	static const int kLineShift = 2; // The cache line is only 4 bytes right now.
	static const int kLineLength = 1 << kLineShift;
	static const int kLineMask = kLineLength - 1;

	CachePage() {
	memset(&validity_map_, LINE_INVALID, sizeof(validity_map_));
	}

	char* ValidityByte(int offset) {
	return &validity_map_[offset >> kLineShift];
	}

	char* CachedData(int offset) {
	return &data_[offset];
	}

	private:
	char data_[kPageSize]; // The cached data.
	static const int kValidityMapSize = kPageSize >> kLineShift;
	char validity_map_[kValidityMapSize]; // One byte per line.
	};

	class Simulator {
	public:
	friend class MipsDebugger;

	// Registers are declared in order. See SMRL chapter 2.
	enum Register {
	no_reg = -1,
	zero_reg = 0,
	at,
	v0, v1,
	a0, a1, a2, a3, a4, a5, a6, a7,
	t0, t1, t2, t3,
	s0, s1, s2, s3, s4, s5, s6, s7,
	t8, t9,
	k0, k1,
	gp,
	sp,
	s8,
	ra,
	// LO, HI, and pc.
	LO,
	HI,
	pc, // pc must be the last register.
	kNumSimuRegisters,
	// aliases
	fp = s8
	};

	// Coprocessor registers.
	// Generated code will always use doubles. So we will only use even registers.
	enum FPURegister {
	f0, f1, f2, f3, f4, f5, f6, f7, f8, f9, f10, f11,
	f12, f13, f14, f15, // f12 and f14 are arguments FPURegisters.
	f16, f17, f18, f19, f20, f21, f22, f23, f24, f25,
	f26, f27, f28, f29, f30, f31,
	kNumFPURegisters
	};

	explicit Simulator(Isolate* isolate);
	~Simulator();

	// The currently executing Simulator instance. Potentially there can be one
	// for each native thread.
	static Simulator* current(v8::internal::Isolate* isolate);

	// Accessors for register state. Reading the pc value adheres to the MIPS
	// architecture specification and is off by a 8 from the currently executing
	// instruction.
	void set_register(int reg, int64_t value);
	void set_register_word(int reg, int32_t value);
	void set_dw_register(int dreg, const int* dbl);
	int64_t get_register(int reg) const;
	double get_double_from_register_pair(int reg);
	// Same for FPURegisters.
	void set_fpu_register(int fpureg, int64_t value);
	void set_fpu_register_word(int fpureg, int32_t value);
	void set_fpu_register_hi_word(int fpureg, int32_t value);
	void set_fpu_register_float(int fpureg, float value);
	void set_fpu_register_double(int fpureg, double value);
	void set_fpu_register_invalid_result64(float original, float rounded);
	void set_fpu_register_invalid_result(float original, float rounded);
	void set_fpu_register_word_invalid_result(float original, float rounded);
	void set_fpu_register_invalid_result64(double original, double rounded);
	void set_fpu_register_invalid_result(double original, double rounded);
	void set_fpu_register_word_invalid_result(double original, double rounded);
	int64_t get_fpu_register(int fpureg) const;
	int32_t get_fpu_register_word(int fpureg) const;
	int32_t get_fpu_register_signed_word(int fpureg) const;
	int32_t get_fpu_register_hi_word(int fpureg) const;
	float get_fpu_register_float(int fpureg) const;
	double get_fpu_register_double(int fpureg) const;
	void set_fcsr_bit(uint32_t cc, bool value);
	bool test_fcsr_bit(uint32_t cc);
	bool set_fcsr_round_error(double original, double rounded);
	bool set_fcsr_round64_error(double original, double rounded);
	bool set_fcsr_round_error(float original, float rounded);
	bool set_fcsr_round64_error(float original, float rounded);
	void round_according_to_fcsr(double toRound, double& rounded,
	int32_t& rounded_int, double fs);
	void round64_according_to_fcsr(double toRound, double& rounded,
	int64_t& rounded_int, double fs);
	void round_according_to_fcsr(float toRound, float& rounded,
	int32_t& rounded_int, float fs);
	void round64_according_to_fcsr(float toRound, float& rounded,
	int64_t& rounded_int, float fs);
	void set_fcsr_rounding_mode(FPURoundingMode mode);
	unsigned int get_fcsr_rounding_mode();
	// Special case of set_register and get_register to access the raw PC value.
	void set_pc(int64_t value);
	int64_t get_pc() const;

	Address get_sp() const {
	return reinterpret_cast<Address>(static_cast<intptr_t>(get_register(sp)));
	}

	// Accessor to the internal simulator stack area.
	uintptr_t StackLimit(uintptr_t c_limit) const;

	// Executes MIPS instructions until the PC reaches end_sim_pc.
	void Execute();

	// Call on program start.
	static void Initialize(Isolate* isolate);

	static void TearDown(base::HashMap* i_cache, Redirection* first);

	// V8 generally calls into generated JS code with 5 parameters and into
	// generated RegExp code with 7 parameters. This is a convenience function,
	// which sets up the simulator state and grabs the result on return.
	int64_t Call(byte* entry, int argument_count, ...);
	// Alternative: call a 2-argument double function.
	double CallFP(byte* entry, double d0, double d1);

	// Push an address onto the JS stack.
	uintptr_t PushAddress(uintptr_t address);

	// Pop an address from the JS stack.
	uintptr_t PopAddress();

	// Debugger input.
	void set_last_debugger_input(char* input);
	char* last_debugger_input() { return last_debugger_input_; }

	// ICache checking.
	static void FlushICache(base::HashMap* i_cache, void* start, size_t size);

	// Returns true if pc register contains one of the 'special_values' defined
	// below (bad_ra, end_sim_pc).
	bool has_bad_pc() const;

	private:
	enum special_values {
	// Known bad pc value to ensure that the simulator does not execute
	// without being properly setup.
	bad_ra = -1,
	// A pc value used to signal the simulator to stop execution. Generally
	// the ra is set to this value on transition from native C code to
	// simulated execution, so that the simulator can "return" to the native
	// C code.
	end_sim_pc = -2,
	// Unpredictable value.
	Unpredictable = 0xbadbeaf
	};

	// Unsupported instructions use Format to print an error and stop execution.
	void Format(Instruction* instr, const char* format);

	// Read and write memory.
	inline uint32_t ReadBU(int64_t addr);
	inline int32_t ReadB(int64_t addr);
	inline void WriteB(int64_t addr, uint8_t value);
	inline void WriteB(int64_t addr, int8_t value);

	inline uint16_t ReadHU(int64_t addr, Instruction* instr);
	inline int16_t ReadH(int64_t addr, Instruction* instr);
	// Note: Overloaded on the sign of the value.
	inline void WriteH(int64_t addr, uint16_t value, Instruction* instr);
	inline void WriteH(int64_t addr, int16_t value, Instruction* instr);

	inline uint32_t ReadWU(int64_t addr, Instruction* instr);
	inline int32_t ReadW(int64_t addr, Instruction* instr);
	inline void WriteW(int64_t addr, int32_t value, Instruction* instr);
	inline int64_t Read2W(int64_t addr, Instruction* instr);
	inline void Write2W(int64_t addr, int64_t value, Instruction* instr);

	inline double ReadD(int64_t addr, Instruction* instr);
	inline void WriteD(int64_t addr, double value, Instruction* instr);

	// Helper for debugging memory access.
	inline void DieOrDebug();

	// Helpers for data value tracing.
	enum TraceType {
	BYTE,
	HALF,
	WORD,
	DWORD
	// DFLOAT - Floats may have printing issues due to paired lwc1's
	};

	void TraceRegWr(int64_t value);
	void TraceMemWr(int64_t addr, int64_t value, TraceType t);
	void TraceMemRd(int64_t addr, int64_t value);

	// Operations depending on endianness.
	// Get Double Higher / Lower word.
	inline int32_t GetDoubleHIW(double* addr);
	inline int32_t GetDoubleLOW(double* addr);
	// Set Double Higher / Lower word.
	inline int32_t SetDoubleHIW(double* addr);
	inline int32_t SetDoubleLOW(double* addr);

	// functions called from DecodeTypeRegister.
	void DecodeTypeRegisterCOP1();

	void DecodeTypeRegisterCOP1X();

	void DecodeTypeRegisterSPECIAL();


	void DecodeTypeRegisterSPECIAL2();

	void DecodeTypeRegisterSPECIAL3();

	void DecodeTypeRegisterSRsType();

	void DecodeTypeRegisterDRsType();

	void DecodeTypeRegisterWRsType();

	void DecodeTypeRegisterLRsType();

	// Executing is handled based on the instruction type.
	void DecodeTypeRegister(Instruction* instr);

	Instruction* currentInstr_;
	inline Instruction* get_instr() const { return currentInstr_; }
	inline void set_instr(Instruction* instr) { currentInstr_ = instr; }

	inline int32_t rs_reg() const { return currentInstr_->RsValue(); }
	inline int64_t rs() const { return get_register(rs_reg()); }
	inline uint64_t rs_u() const {
	return static_cast<uint64_t>(get_register(rs_reg()));
	}
	inline int32_t rt_reg() const { return currentInstr_->RtValue(); }
	inline int64_t rt() const { return get_register(rt_reg()); }
	inline uint64_t rt_u() const {
	return static_cast<uint64_t>(get_register(rt_reg()));
	}
	inline int32_t rd_reg() const { return currentInstr_->RdValue(); }
	inline int32_t fr_reg() const { return currentInstr_->FrValue(); }
	inline int32_t fs_reg() const { return currentInstr_->FsValue(); }
	inline int32_t ft_reg() const { return currentInstr_->FtValue(); }
	inline int32_t fd_reg() const { return currentInstr_->FdValue(); }
	inline int32_t sa() const { return currentInstr_->SaValue(); }
	inline int32_t lsa_sa() const { return currentInstr_->LsaSaValue(); }

	inline void SetResult(const int32_t rd_reg, const int64_t alu_out) {
	set_register(rd_reg, alu_out);
	TraceRegWr(alu_out);
	}

	void DecodeTypeImmediate(Instruction* instr);
	void DecodeTypeJump(Instruction* instr);

	// Used for breakpoints and traps.
	void SoftwareInterrupt(Instruction* instr);

	// Compact branch guard.
	void CheckForbiddenSlot(int64_t current_pc) {
	Instruction* instr_after_compact_branch =
	reinterpret_cast<Instruction*>(current_pc + Instruction::kInstrSize);
	if (instr_after_compact_branch->IsForbiddenAfterBranch()) {
	V8_Fatal(__FILE__, __LINE__,
	"Error: Unexpected instruction 0x%08x immediately after a "
	"compact branch instruction.",
	reinterpret_cast<uint32_t>(instr_after_compact_branch));
	}
	}

	// Stop helper functions.
	bool IsWatchpoint(uint64_t code);
	void PrintWatchpoint(uint64_t code);
	void HandleStop(uint64_t code, Instruction* instr);
	bool IsStopInstruction(Instruction* instr);
	bool IsEnabledStop(uint64_t code);
	void EnableStop(uint64_t code);
	void DisableStop(uint64_t code);
	void IncreaseStopCounter(uint64_t code);
	void PrintStopInfo(uint64_t code);


	// Executes one instruction.
	void InstructionDecode(Instruction* instr);
	// Execute one instruction placed in a branch delay slot.
	void BranchDelayInstructionDecode(Instruction* instr) {
	if (instr->InstructionBits() == nopInstr) {
	// Short-cut generic nop instructions. They are always valid and they
	// never change the simulator state.
	return;
	}

	if (instr->IsForbiddenAfterBranch()) {
	V8_Fatal(__FILE__, __LINE__,
	"Eror:Unexpected %i opcode in a branch delay slot.",
	instr->OpcodeValue());
	}
	InstructionDecode(instr);
	SNPrintF(trace_buf_, " ");
	}

	// ICache.
	static void CheckICache(base::HashMap* i_cache, Instruction* instr);
	static void FlushOnePage(base::HashMap* i_cache, intptr_t start, size_t size);
	static CachePage* GetCachePage(base::HashMap* i_cache, void* page);

	enum Exception {
	none,
	kIntegerOverflow,
	kIntegerUnderflow,
	kDivideByZero,
	kNumExceptions
	};

	// Exceptions.
	void SignalException(Exception e);

	// Runtime call support.
	static void* RedirectExternalReference(Isolate* isolate,
	void* external_function,
	ExternalReference::Type type);

	// Handle arguments and return value for runtime FP functions.
	void GetFpArgs(double* x, double* y, int32_t* z);
	void SetFpResult(const double& result);

	void CallInternal(byte* entry);

	// Architecture state.
	// Registers.
	int64_t registers_[kNumSimuRegisters];
	// Coprocessor Registers.
	int64_t FPUregisters_[kNumFPURegisters];
	// FPU control register.
	uint32_t FCSR_;

	// Simulator support.
	// Allocate 1MB for stack.
	size_t stack_size_;
	char* stack_;
	bool pc_modified_;
	int64_t icount_;
	int break_count_;
	EmbeddedVector<char, 128> trace_buf_;

	// Debugger input.
	char* last_debugger_input_;

	// Icache simulation.
	base::HashMap* i_cache_;

	v8::internal::Isolate* isolate_;

	// Registered breakpoints.
	Instruction* break_pc_;
	Instr break_instr_;

	// Stop is disabled if bit 31 is set.
	static const uint32_t kStopDisabledBit = 1 << 31;

	// A stop is enabled, meaning the simulator will stop when meeting the
	// instruction, if bit 31 of watched_stops_[code].count is unset.
	// The value watched_stops_[code].count & ~(1 << 31) indicates how many times
	// the breakpoint was hit or gone through.
	struct StopCountAndDesc {
	uint32_t count;
	char* desc;
	};
	StopCountAndDesc watched_stops_[kMaxStopCode + 1];
	};


	// When running with the simulator transition into simulated execution at this
	// point.
	#define CALL_GENERATED_CODE(isolate, entry, p0, p1, p2, p3, p4) \
	reinterpret_cast<Object*>(Simulator::current(isolate)->Call( \
	FUNCTION_ADDR(entry), 5, reinterpret_cast<int64_t*>(p0), \
	reinterpret_cast<int64_t>(p1), reinterpret_cast<int64_t>(p2), \
	reinterpret_cast<int64_t>(p3), reinterpret_cast<int64_t>(p4)))


	#define CALL_GENERATED_REGEXP_CODE(isolate, entry, p0, p1, p2, p3, p4, p5, p6, \
	p7, p8) \
	static_cast<int>(Simulator::current(isolate)->Call( \
	entry, 10, p0, p1, p2, p3, p4, reinterpret_cast<int64_t*>(p5), p6, p7, \
	NULL, p8))


	// The simulator has its own stack. Thus it has a different stack limit from
	// the C-based native code. The JS-based limit normally points near the end of
	// the simulator stack. When the C-based limit is exhausted we reflect that by
	// lowering the JS-based limit as well, to make stack checks trigger.
	class SimulatorStack : public v8::internal::AllStatic {
	public:
	static inline uintptr_t JsLimitFromCLimit(Isolate* isolate,
	uintptr_t c_limit) {
	return Simulator::current(isolate)->StackLimit(c_limit);
	}

	static inline uintptr_t RegisterCTryCatch(Isolate* isolate,
	uintptr_t try_catch_address) {
	Simulator* sim = Simulator::current(isolate);
	return sim->PushAddress(try_catch_address);
	}

	static inline void UnregisterCTryCatch(Isolate* isolate) {
	Simulator::current(isolate)->PopAddress();
	}
	};

	} // namespace internal
	} // namespace v8

	#endif // !defined(USE_SIMULATOR)
	#endif // V8_MIPS_SIMULATOR_MIPS_H_