src/v8/src/arm/simulator-arm.h - cobalt - Git at Google

 // Copyright 2012 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 ARM instructions if we are not generating a native
 // ARM binary. This Simulator allows us to run and debug ARM code generation on
 // regular desktop machines.
 // V8 calls into generated code by using the GeneratedCode class,
 // which will start execution in the Simulator or forwards to the real entry
 // on a ARM HW platform.

 #ifndef V8_ARM_SIMULATOR_ARM_H_
 #define V8_ARM_SIMULATOR_ARM_H_

 #include "src/allocation.h"
 #include "src/base/lazy-instance.h"
 #include "src/base/platform/mutex.h"
 #include "src/boxed-float.h"

 #if defined(USE_SIMULATOR)
 // Running with a simulator.

 #include "src/arm/constants-arm.h"
 #include "src/assembler.h"
 #include "src/base/hashmap.h"
 #include "src/simulator-base.h"

 namespace v8 {
 namespace internal {

 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 SimulatorBase {
  public:
   friend class ArmDebugger;
   enum Register {
     no_reg = -1,
     r0 = 0, r1, r2, r3, r4, r5, r6, r7,
     r8, r9, r10, r11, r12, r13, r14, r15,
     num_registers,
     sp = 13,
     lr = 14,
     pc = 15,
     s0 = 0, s1, s2, s3, s4, s5, s6, s7,
     s8, s9, s10, s11, s12, s13, s14, s15,
     s16, s17, s18, s19, s20, s21, s22, s23,
     s24, s25, s26, s27, s28, s29, s30, s31,
     num_s_registers = 32,
     d0 = 0, d1, d2, d3, d4, d5, d6, d7,
     d8, d9, d10, d11, d12, d13, d14, d15,
     d16, d17, d18, d19, d20, d21, d22, d23,
     d24, d25, d26, d27, d28, d29, d30, d31,
     num_d_registers = 32,
     q0 = 0, q1, q2, q3, q4, q5, q6, q7,
     q8, q9, q10, q11, q12, q13, q14, q15,
     num_q_registers = 16
   };

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

   // The currently executing Simulator instance. Potentially there can be one
   // for each native thread.
   V8_EXPORT_PRIVATE static Simulator* current(v8::internal::Isolate* isolate);

   // Accessors for register state. Reading the pc value adheres to the ARM
   // architecture specification and is off by a 8 from the currently executing
   // instruction.
   void set_register(int reg, int32_t value);
   int32_t get_register(int reg) const;
   double get_double_from_register_pair(int reg);
   void set_register_pair_from_double(int reg, double* value);
   void set_dw_register(int dreg, const int* dbl);

   // Support for VFP.
   void get_d_register(int dreg, uint64_t* value);
   void set_d_register(int dreg, const uint64_t* value);
   void get_d_register(int dreg, uint32_t* value);
   void set_d_register(int dreg, const uint32_t* value);
   // Support for NEON.
   template <typename T, int SIZE = kSimd128Size>
   void get_neon_register(int reg, T (&value)[SIZE / sizeof(T)]);
   template <typename T, int SIZE = kSimd128Size>
   void set_neon_register(int reg, const T (&value)[SIZE / sizeof(T)]);

   void set_s_register(int reg, unsigned int value);
   unsigned int get_s_register(int reg) const;

   void set_d_register_from_double(int dreg, const Float64 dbl) {
     SetVFPRegister<Float64, 2>(dreg, dbl);
   }
   void set_d_register_from_double(int dreg, const double dbl) {
     SetVFPRegister<double, 2>(dreg, dbl);
   }

   Float64 get_double_from_d_register(int dreg) {
     return GetFromVFPRegister<Float64, 2>(dreg);
   }

   void set_s_register_from_float(int sreg, const Float32 flt) {
     SetVFPRegister<Float32, 1>(sreg, flt);
   }
   void set_s_register_from_float(int sreg, const float flt) {
     SetVFPRegister<float, 1>(sreg, flt);
   }

   Float32 get_float_from_s_register(int sreg) {
     return GetFromVFPRegister<Float32, 1>(sreg);
   }

   void set_s_register_from_sinteger(int sreg, const int sint) {
     SetVFPRegister<int, 1>(sreg, sint);
   }

   int get_sinteger_from_s_register(int sreg) {
     return GetFromVFPRegister<int, 1>(sreg);
   }

   // Special case of set_register and get_register to access the raw PC value.
   void set_pc(int32_t value);
   int32_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 ARM instructions until the PC reaches end_sim_pc.
   void Execute();

   template <typename Return, typename... Args>
   Return Call(byte* entry, Args... args) {
     return VariadicCall<Return>(this, &Simulator::CallImpl, entry, args...);
   }

   // Alternative: call a 2-argument double function.
   template <typename Return>
   Return CallFP(byte* entry, double d0, double d1) {
     return ConvertReturn<Return>(CallFPImpl(entry, d0, 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_; }

   // Redirection support.
   static void SetRedirectInstruction(Instruction* instruction);

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

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

   // EABI variant for double arguments in use.
   bool use_eabi_hardfloat() {
 #if USE_EABI_HARDFLOAT
     return true;
 #else
     return false;
 #endif
   }

  private:
   enum special_values {
     // Known bad pc value to ensure that the simulator does not execute
     // without being properly setup.
     bad_lr = -1,
     // A pc value used to signal the simulator to stop execution.  Generally
     // the lr 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
   };

   V8_EXPORT_PRIVATE intptr_t CallImpl(byte* entry, int argument_count,
                                       const intptr_t* arguments);
   intptr_t CallFPImpl(byte* entry, double d0, double d1);

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

   // Checks if the current instruction should be executed based on its
   // condition bits.
   inline bool ConditionallyExecute(Instruction* instr);

   // Helper functions to set the conditional flags in the architecture state.
   void SetNZFlags(int32_t val);
   void SetCFlag(bool val);
   void SetVFlag(bool val);
   bool CarryFrom(int32_t left, int32_t right, int32_t carry = 0);
   bool BorrowFrom(int32_t left, int32_t right, int32_t carry = 1);
   bool OverflowFrom(int32_t alu_out,
                     int32_t left,
                     int32_t right,
                     bool addition);

   inline int GetCarry() {
     return c_flag_ ? 1 : 0;
   }

   // Support for VFP.
   void Compute_FPSCR_Flags(float val1, float val2);
   void Compute_FPSCR_Flags(double val1, double val2);
   void Copy_FPSCR_to_APSR();
   inline float canonicalizeNaN(float value);
   inline double canonicalizeNaN(double value);
   inline Float32 canonicalizeNaN(Float32 value);
   inline Float64 canonicalizeNaN(Float64 value);

   // Helper functions to decode common "addressing" modes
   int32_t GetShiftRm(Instruction* instr, bool* carry_out);
   int32_t GetImm(Instruction* instr, bool* carry_out);
   int32_t ProcessPU(Instruction* instr,
                     int num_regs,
                     int operand_size,
                     intptr_t* start_address,
                     intptr_t* end_address);
   void HandleRList(Instruction* instr, bool load);
   void HandleVList(Instruction* inst);
   void SoftwareInterrupt(Instruction* instr);

   // Stop helper functions.
   inline bool isStopInstruction(Instruction* instr);
   inline bool isWatchedStop(uint32_t bkpt_code);
   inline bool isEnabledStop(uint32_t bkpt_code);
   inline void EnableStop(uint32_t bkpt_code);
   inline void DisableStop(uint32_t bkpt_code);
   inline void IncreaseStopCounter(uint32_t bkpt_code);
   void PrintStopInfo(uint32_t code);

   // Read and write memory.
   // The *Ex functions are exclusive access. The writes return the strex status:
   // 0 if the write succeeds, and 1 if the write fails.
   inline uint8_t ReadBU(int32_t addr);
   inline int8_t ReadB(int32_t addr);
   uint8_t ReadExBU(int32_t addr);
   inline void WriteB(int32_t addr, uint8_t value);
   inline void WriteB(int32_t addr, int8_t value);
   int WriteExB(int32_t addr, uint8_t value);

   inline uint16_t ReadHU(int32_t addr, Instruction* instr);
   inline int16_t ReadH(int32_t addr, Instruction* instr);
   uint16_t ReadExHU(int32_t addr, Instruction* instr);
   // Note: Overloaded on the sign of the value.
   inline void WriteH(int32_t addr, uint16_t value, Instruction* instr);
   inline void WriteH(int32_t addr, int16_t value, Instruction* instr);
   int WriteExH(int32_t addr, uint16_t value, Instruction* instr);

   inline int ReadW(int32_t addr, Instruction* instr);
   int ReadExW(int32_t addr, Instruction* instr);
   inline void WriteW(int32_t addr, int value, Instruction* instr);
   int WriteExW(int32_t addr, int value, Instruction* instr);

   int32_t* ReadDW(int32_t addr);
   void WriteDW(int32_t addr, int32_t value1, int32_t value2);

   // Executing is handled based on the instruction type.
   // Both type 0 and type 1 rolled into one.
   void DecodeType01(Instruction* instr);
   void DecodeType2(Instruction* instr);
   void DecodeType3(Instruction* instr);
   void DecodeType4(Instruction* instr);
   void DecodeType5(Instruction* instr);
   void DecodeType6(Instruction* instr);
   void DecodeType7(Instruction* instr);

   // CP15 coprocessor instructions.
   void DecodeTypeCP15(Instruction* instr);

   // Support for VFP.
   void DecodeTypeVFP(Instruction* instr);
   void DecodeType6CoprocessorIns(Instruction* instr);
   void DecodeSpecialCondition(Instruction* instr);

   void DecodeVMOVBetweenCoreAndSinglePrecisionRegisters(Instruction* instr);
   void DecodeVCMP(Instruction* instr);
   void DecodeVCVTBetweenDoubleAndSingle(Instruction* instr);
   int32_t ConvertDoubleToInt(double val, bool unsigned_integer,
                              VFPRoundingMode mode);
   void DecodeVCVTBetweenFloatingPointAndInteger(Instruction* instr);

   // Executes one instruction.
   void InstructionDecode(Instruction* instr);

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

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

   template<class ReturnType, int register_size>
       ReturnType GetFromVFPRegister(int reg_index);

   template<class InputType, int register_size>
       void SetVFPRegister(int reg_index, const InputType& value);

   void SetSpecialRegister(SRegisterFieldMask reg_and_mask, uint32_t value);
   uint32_t GetFromSpecialRegister(SRegister reg);

   void CallInternal(byte* entry);

   // Architecture state.
   // Saturating instructions require a Q flag to indicate saturation.
   // There is currently no way to read the CPSR directly, and thus read the Q
   // flag, so this is left unimplemented.
   int32_t registers_[16];
   bool n_flag_;
   bool z_flag_;
   bool c_flag_;
   bool v_flag_;

   // VFP architecture state.
   unsigned int vfp_registers_[num_d_registers * 2];
   bool n_flag_FPSCR_;
   bool z_flag_FPSCR_;
   bool c_flag_FPSCR_;
   bool v_flag_FPSCR_;

   // VFP rounding mode. See ARM DDI 0406B Page A2-29.
   VFPRoundingMode FPSCR_rounding_mode_;
   bool FPSCR_default_NaN_mode_;

   // VFP FP exception flags architecture state.
   bool inv_op_vfp_flag_;
   bool div_zero_vfp_flag_;
   bool overflow_vfp_flag_;
   bool underflow_vfp_flag_;
   bool inexact_vfp_flag_;

   // Simulator support.
   char* stack_;
   bool pc_modified_;
   int icount_;

   // Debugger input.
   char* last_debugger_input_;

   // Icache simulation
   base::CustomMatcherHashMap* i_cache_;

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

   v8::internal::Isolate* isolate_;

   // A stop is watched if its code is less than kNumOfWatchedStops.
   // Only watched stops support enabling/disabling and the counter feature.
   static const uint32_t kNumOfWatchedStops = 256;

   // Breakpoint 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_[kNumOfWatchedStops];

   // Synchronization primitives. See ARM DDI 0406C.b, A2.9.
   enum class MonitorAccess {
     Open,
     Exclusive,
   };

   enum class TransactionSize {
     None = 0,
     Byte = 1,
     HalfWord = 2,
     Word = 4,
   };

   // The least-significant bits of the address are ignored. The number of bits
   // is implementation-defined, between 3 and 11. See ARM DDI 0406C.b, A3.4.3.
   static const int32_t kExclusiveTaggedAddrMask = ~((1 << 11) - 1);

   class LocalMonitor {
    public:
     LocalMonitor();

     // These functions manage the state machine for the local monitor, but do
     // not actually perform loads and stores. NotifyStoreExcl only returns
     // true if the exclusive store is allowed; the global monitor will still
     // have to be checked to see whether the memory should be updated.
     void NotifyLoad(int32_t addr);
     void NotifyLoadExcl(int32_t addr, TransactionSize size);
     void NotifyStore(int32_t addr);
     bool NotifyStoreExcl(int32_t addr, TransactionSize size);

    private:
     void Clear();

     MonitorAccess access_state_;
     int32_t tagged_addr_;
     TransactionSize size_;
   };

   class GlobalMonitor {
    public:
     GlobalMonitor();

     class Processor {
      public:
       Processor();

      private:
       friend class GlobalMonitor;
       // These functions manage the state machine for the global monitor, but do
       // not actually perform loads and stores.
       void Clear_Locked();
       void NotifyLoadExcl_Locked(int32_t addr);
       void NotifyStore_Locked(int32_t addr, bool is_requesting_processor);
       bool NotifyStoreExcl_Locked(int32_t addr, bool is_requesting_processor);

       MonitorAccess access_state_;
       int32_t tagged_addr_;
       Processor* next_;
       Processor* prev_;
       // A strex can fail due to background cache evictions. Rather than
       // simulating this, we'll just occasionally introduce cases where an
       // exclusive store fails. This will happen once after every
       // kMaxFailureCounter exclusive stores.
       static const int kMaxFailureCounter = 5;
       int failure_counter_;
     };

     // Exposed so it can be accessed by Simulator::{Read,Write}Ex*.
     base::Mutex mutex;

     void NotifyLoadExcl_Locked(int32_t addr, Processor* processor);
     void NotifyStore_Locked(int32_t addr, Processor* processor);
     bool NotifyStoreExcl_Locked(int32_t addr, Processor* processor);

     // Called when the simulator is destroyed.
     void RemoveProcessor(Processor* processor);

    private:
     bool IsProcessorInLinkedList_Locked(Processor* processor) const;
     void PrependProcessor_Locked(Processor* processor);

     Processor* head_;
   };

   LocalMonitor local_monitor_;
   GlobalMonitor::Processor global_monitor_processor_;
   static base::LazyInstance<GlobalMonitor>::type global_monitor_;
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // defined(USE_SIMULATOR)
 #endif  // V8_ARM_SIMULATOR_ARM_H_
	// Copyright 2012 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 ARM instructions if we are not generating a native
	// ARM binary. This Simulator allows us to run and debug ARM code generation on
	// regular desktop machines.
	// V8 calls into generated code by using the GeneratedCode class,
	// which will start execution in the Simulator or forwards to the real entry
	// on a ARM HW platform.

	#ifndef V8_ARM_SIMULATOR_ARM_H_
	#define V8_ARM_SIMULATOR_ARM_H_

	#include "src/allocation.h"
	#include "src/base/lazy-instance.h"
	#include "src/base/platform/mutex.h"
	#include "src/boxed-float.h"

	#if defined(USE_SIMULATOR)
	// Running with a simulator.

	#include "src/arm/constants-arm.h"
	#include "src/assembler.h"
	#include "src/base/hashmap.h"
	#include "src/simulator-base.h"

	namespace v8 {
	namespace internal {

	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 SimulatorBase {
	public:
	friend class ArmDebugger;
	enum Register {
	no_reg = -1,
	r0 = 0, r1, r2, r3, r4, r5, r6, r7,
	r8, r9, r10, r11, r12, r13, r14, r15,
	num_registers,
	sp = 13,
	lr = 14,
	pc = 15,
	s0 = 0, s1, s2, s3, s4, s5, s6, s7,
	s8, s9, s10, s11, s12, s13, s14, s15,
	s16, s17, s18, s19, s20, s21, s22, s23,
	s24, s25, s26, s27, s28, s29, s30, s31,
	num_s_registers = 32,
	d0 = 0, d1, d2, d3, d4, d5, d6, d7,
	d8, d9, d10, d11, d12, d13, d14, d15,
	d16, d17, d18, d19, d20, d21, d22, d23,
	d24, d25, d26, d27, d28, d29, d30, d31,
	num_d_registers = 32,
	q0 = 0, q1, q2, q3, q4, q5, q6, q7,
	q8, q9, q10, q11, q12, q13, q14, q15,
	num_q_registers = 16
	};

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

	// The currently executing Simulator instance. Potentially there can be one
	// for each native thread.
	V8_EXPORT_PRIVATE static Simulator* current(v8::internal::Isolate* isolate);

	// Accessors for register state. Reading the pc value adheres to the ARM
	// architecture specification and is off by a 8 from the currently executing
	// instruction.
	void set_register(int reg, int32_t value);
	int32_t get_register(int reg) const;
	double get_double_from_register_pair(int reg);
	void set_register_pair_from_double(int reg, double* value);
	void set_dw_register(int dreg, const int* dbl);

	// Support for VFP.
	void get_d_register(int dreg, uint64_t* value);
	void set_d_register(int dreg, const uint64_t* value);
	void get_d_register(int dreg, uint32_t* value);
	void set_d_register(int dreg, const uint32_t* value);
	// Support for NEON.
	template <typename T, int SIZE = kSimd128Size>
	void get_neon_register(int reg, T (&value)[SIZE / sizeof(T)]);
	template <typename T, int SIZE = kSimd128Size>
	void set_neon_register(int reg, const T (&value)[SIZE / sizeof(T)]);

	void set_s_register(int reg, unsigned int value);
	unsigned int get_s_register(int reg) const;

	void set_d_register_from_double(int dreg, const Float64 dbl) {
	SetVFPRegister<Float64, 2>(dreg, dbl);
	}
	void set_d_register_from_double(int dreg, const double dbl) {
	SetVFPRegister<double, 2>(dreg, dbl);
	}

	Float64 get_double_from_d_register(int dreg) {
	return GetFromVFPRegister<Float64, 2>(dreg);
	}

	void set_s_register_from_float(int sreg, const Float32 flt) {
	SetVFPRegister<Float32, 1>(sreg, flt);
	}
	void set_s_register_from_float(int sreg, const float flt) {
	SetVFPRegister<float, 1>(sreg, flt);
	}

	Float32 get_float_from_s_register(int sreg) {
	return GetFromVFPRegister<Float32, 1>(sreg);
	}

	void set_s_register_from_sinteger(int sreg, const int sint) {
	SetVFPRegister<int, 1>(sreg, sint);
	}

	int get_sinteger_from_s_register(int sreg) {
	return GetFromVFPRegister<int, 1>(sreg);
	}

	// Special case of set_register and get_register to access the raw PC value.
	void set_pc(int32_t value);
	int32_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 ARM instructions until the PC reaches end_sim_pc.
	void Execute();

	template <typename Return, typename... Args>
	Return Call(byte* entry, Args... args) {
	return VariadicCall<Return>(this, &Simulator::CallImpl, entry, args...);
	}

	// Alternative: call a 2-argument double function.
	template <typename Return>
	Return CallFP(byte* entry, double d0, double d1) {
	return ConvertReturn<Return>(CallFPImpl(entry, d0, 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_; }

	// Redirection support.
	static void SetRedirectInstruction(Instruction* instruction);

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

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

	// EABI variant for double arguments in use.
	bool use_eabi_hardfloat() {
	#if USE_EABI_HARDFLOAT
	return true;
	#else
	return false;
	#endif
	}

	private:
	enum special_values {
	// Known bad pc value to ensure that the simulator does not execute
	// without being properly setup.
	bad_lr = -1,
	// A pc value used to signal the simulator to stop execution. Generally
	// the lr 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
	};

	V8_EXPORT_PRIVATE intptr_t CallImpl(byte* entry, int argument_count,
	const intptr_t* arguments);
	intptr_t CallFPImpl(byte* entry, double d0, double d1);

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

	// Checks if the current instruction should be executed based on its
	// condition bits.
	inline bool ConditionallyExecute(Instruction* instr);

	// Helper functions to set the conditional flags in the architecture state.
	void SetNZFlags(int32_t val);
	void SetCFlag(bool val);
	void SetVFlag(bool val);
	bool CarryFrom(int32_t left, int32_t right, int32_t carry = 0);
	bool BorrowFrom(int32_t left, int32_t right, int32_t carry = 1);
	bool OverflowFrom(int32_t alu_out,
	int32_t left,
	int32_t right,
	bool addition);

	inline int GetCarry() {
	return c_flag_ ? 1 : 0;
	}

	// Support for VFP.
	void Compute_FPSCR_Flags(float val1, float val2);
	void Compute_FPSCR_Flags(double val1, double val2);
	void Copy_FPSCR_to_APSR();
	inline float canonicalizeNaN(float value);
	inline double canonicalizeNaN(double value);
	inline Float32 canonicalizeNaN(Float32 value);
	inline Float64 canonicalizeNaN(Float64 value);

	// Helper functions to decode common "addressing" modes
	int32_t GetShiftRm(Instruction* instr, bool* carry_out);
	int32_t GetImm(Instruction* instr, bool* carry_out);
	int32_t ProcessPU(Instruction* instr,
	int num_regs,
	int operand_size,
	intptr_t* start_address,
	intptr_t* end_address);
	void HandleRList(Instruction* instr, bool load);
	void HandleVList(Instruction* inst);
	void SoftwareInterrupt(Instruction* instr);

	// Stop helper functions.
	inline bool isStopInstruction(Instruction* instr);
	inline bool isWatchedStop(uint32_t bkpt_code);
	inline bool isEnabledStop(uint32_t bkpt_code);
	inline void EnableStop(uint32_t bkpt_code);
	inline void DisableStop(uint32_t bkpt_code);
	inline void IncreaseStopCounter(uint32_t bkpt_code);
	void PrintStopInfo(uint32_t code);

	// Read and write memory.
	// The *Ex functions are exclusive access. The writes return the strex status:
	// 0 if the write succeeds, and 1 if the write fails.
	inline uint8_t ReadBU(int32_t addr);
	inline int8_t ReadB(int32_t addr);
	uint8_t ReadExBU(int32_t addr);
	inline void WriteB(int32_t addr, uint8_t value);
	inline void WriteB(int32_t addr, int8_t value);
	int WriteExB(int32_t addr, uint8_t value);

	inline uint16_t ReadHU(int32_t addr, Instruction* instr);
	inline int16_t ReadH(int32_t addr, Instruction* instr);
	uint16_t ReadExHU(int32_t addr, Instruction* instr);
	// Note: Overloaded on the sign of the value.
	inline void WriteH(int32_t addr, uint16_t value, Instruction* instr);
	inline void WriteH(int32_t addr, int16_t value, Instruction* instr);
	int WriteExH(int32_t addr, uint16_t value, Instruction* instr);

	inline int ReadW(int32_t addr, Instruction* instr);
	int ReadExW(int32_t addr, Instruction* instr);
	inline void WriteW(int32_t addr, int value, Instruction* instr);
	int WriteExW(int32_t addr, int value, Instruction* instr);

	int32_t* ReadDW(int32_t addr);
	void WriteDW(int32_t addr, int32_t value1, int32_t value2);

	// Executing is handled based on the instruction type.
	// Both type 0 and type 1 rolled into one.
	void DecodeType01(Instruction* instr);
	void DecodeType2(Instruction* instr);
	void DecodeType3(Instruction* instr);
	void DecodeType4(Instruction* instr);
	void DecodeType5(Instruction* instr);
	void DecodeType6(Instruction* instr);
	void DecodeType7(Instruction* instr);

	// CP15 coprocessor instructions.
	void DecodeTypeCP15(Instruction* instr);

	// Support for VFP.
	void DecodeTypeVFP(Instruction* instr);
	void DecodeType6CoprocessorIns(Instruction* instr);
	void DecodeSpecialCondition(Instruction* instr);

	void DecodeVMOVBetweenCoreAndSinglePrecisionRegisters(Instruction* instr);
	void DecodeVCMP(Instruction* instr);
	void DecodeVCVTBetweenDoubleAndSingle(Instruction* instr);
	int32_t ConvertDoubleToInt(double val, bool unsigned_integer,
	VFPRoundingMode mode);
	void DecodeVCVTBetweenFloatingPointAndInteger(Instruction* instr);

	// Executes one instruction.
	void InstructionDecode(Instruction* instr);

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

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

	template<class ReturnType, int register_size>
	ReturnType GetFromVFPRegister(int reg_index);

	template<class InputType, int register_size>
	void SetVFPRegister(int reg_index, const InputType& value);

	void SetSpecialRegister(SRegisterFieldMask reg_and_mask, uint32_t value);
	uint32_t GetFromSpecialRegister(SRegister reg);

	void CallInternal(byte* entry);

	// Architecture state.
	// Saturating instructions require a Q flag to indicate saturation.
	// There is currently no way to read the CPSR directly, and thus read the Q
	// flag, so this is left unimplemented.
	int32_t registers_[16];
	bool n_flag_;
	bool z_flag_;
	bool c_flag_;
	bool v_flag_;

	// VFP architecture state.
	unsigned int vfp_registers_[num_d_registers * 2];
	bool n_flag_FPSCR_;
	bool z_flag_FPSCR_;
	bool c_flag_FPSCR_;
	bool v_flag_FPSCR_;

	// VFP rounding mode. See ARM DDI 0406B Page A2-29.
	VFPRoundingMode FPSCR_rounding_mode_;
	bool FPSCR_default_NaN_mode_;

	// VFP FP exception flags architecture state.
	bool inv_op_vfp_flag_;
	bool div_zero_vfp_flag_;
	bool overflow_vfp_flag_;
	bool underflow_vfp_flag_;
	bool inexact_vfp_flag_;

	// Simulator support.
	char* stack_;
	bool pc_modified_;
	int icount_;

	// Debugger input.
	char* last_debugger_input_;

	// Icache simulation
	base::CustomMatcherHashMap* i_cache_;

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

	v8::internal::Isolate* isolate_;

	// A stop is watched if its code is less than kNumOfWatchedStops.
	// Only watched stops support enabling/disabling and the counter feature.
	static const uint32_t kNumOfWatchedStops = 256;

	// Breakpoint 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_[kNumOfWatchedStops];

	// Synchronization primitives. See ARM DDI 0406C.b, A2.9.
	enum class MonitorAccess {
	Open,
	Exclusive,
	};

	enum class TransactionSize {
	None = 0,
	Byte = 1,
	HalfWord = 2,
	Word = 4,
	};

	// The least-significant bits of the address are ignored. The number of bits
	// is implementation-defined, between 3 and 11. See ARM DDI 0406C.b, A3.4.3.
	static const int32_t kExclusiveTaggedAddrMask = ~((1 << 11) - 1);

	class LocalMonitor {
	public:
	LocalMonitor();

	// These functions manage the state machine for the local monitor, but do
	// not actually perform loads and stores. NotifyStoreExcl only returns
	// true if the exclusive store is allowed; the global monitor will still
	// have to be checked to see whether the memory should be updated.
	void NotifyLoad(int32_t addr);
	void NotifyLoadExcl(int32_t addr, TransactionSize size);
	void NotifyStore(int32_t addr);
	bool NotifyStoreExcl(int32_t addr, TransactionSize size);

	private:
	void Clear();

	MonitorAccess access_state_;
	int32_t tagged_addr_;
	TransactionSize size_;
	};

	class GlobalMonitor {
	public:
	GlobalMonitor();

	class Processor {
	public:
	Processor();

	private:
	friend class GlobalMonitor;
	// These functions manage the state machine for the global monitor, but do
	// not actually perform loads and stores.
	void Clear_Locked();
	void NotifyLoadExcl_Locked(int32_t addr);
	void NotifyStore_Locked(int32_t addr, bool is_requesting_processor);
	bool NotifyStoreExcl_Locked(int32_t addr, bool is_requesting_processor);

	MonitorAccess access_state_;
	int32_t tagged_addr_;
	Processor* next_;
	Processor* prev_;
	// A strex can fail due to background cache evictions. Rather than
	// simulating this, we'll just occasionally introduce cases where an
	// exclusive store fails. This will happen once after every
	// kMaxFailureCounter exclusive stores.
	static const int kMaxFailureCounter = 5;
	int failure_counter_;
	};

	// Exposed so it can be accessed by Simulator::{Read,Write}Ex*.
	base::Mutex mutex;

	void NotifyLoadExcl_Locked(int32_t addr, Processor* processor);
	void NotifyStore_Locked(int32_t addr, Processor* processor);
	bool NotifyStoreExcl_Locked(int32_t addr, Processor* processor);

	// Called when the simulator is destroyed.
	void RemoveProcessor(Processor* processor);

	private:
	bool IsProcessorInLinkedList_Locked(Processor* processor) const;
	void PrependProcessor_Locked(Processor* processor);

	Processor* head_;
	};

	LocalMonitor local_monitor_;
	GlobalMonitor::Processor global_monitor_processor_;
	static base::LazyInstance<GlobalMonitor>::type global_monitor_;
	};

	} // namespace internal
	} // namespace v8

	#endif // defined(USE_SIMULATOR)
	#endif // V8_ARM_SIMULATOR_ARM_H_