src/constants_arm.h - platform/art - Gitiles

 // Copyright 2009 Google Inc. All Rights Reserved.

 #ifndef ART_SRC_CONSTANTS_ARM_H_
 #define ART_SRC_CONSTANTS_ARM_H_

 #include <stdint.h>
 #include <iosfwd>
 #include "casts.h"
 #include "globals.h"
 #include "logging.h"

 namespace art {
 namespace arm {

 // Defines constants and accessor classes to assemble, disassemble and
 // simulate ARM instructions.
 //
 // Section references in the code refer to the "ARM Architecture Reference
 // Manual" from July 2005 (available at http://www.arm.com/miscPDFs/14128.pdf)
 //
 // Constants for specific fields are defined in their respective named enums.
 // General constants are in an anonymous enum in class Instr.


 // We support both VFPv3-D16 and VFPv3-D32 profiles, but currently only one at
 // a time, so that compile time optimizations can be applied.
 // Warning: VFPv3-D32 is untested.
 #define VFPv3_D16
 #if defined(VFPv3_D16) == defined(VFPv3_D32)
 #error "Exactly one of VFPv3_D16 or VFPv3_D32 can be defined at a time."
 #endif


 // Values for registers.
 enum Register {
   R0  =  0,
   R1  =  1,
   R2  =  2,
   R3  =  3,
   R4  =  4,
   R5  =  5,
   R6  =  6,
   R7  =  7,
   R8  =  8,
   R9  =  9,
   R10 = 10,
   R11 = 11,
   R12 = 12,
   R13 = 13,
   R14 = 14,
   R15 = 15,
   TR  = 9,  // thread register
   FP  = 11,
   IP  = 12,
   SP  = 13,
   LR  = 14,
   PC  = 15,
   kNumberOfCoreRegisters = 16,
   kNoRegister = -1,
 };
 std::ostream& operator<<(std::ostream& os, const Register& rhs);


 enum ScaleFactor {
   TIMES_1 = 0,
   TIMES_2 = 1,
   TIMES_4 = 2,
   TIMES_8 = 3
 };


 // Values for single-precision floating point registers.
 enum SRegister {
   S0  =  0,
   S1  =  1,
   S2  =  2,
   S3  =  3,
   S4  =  4,
   S5  =  5,
   S6  =  6,
   S7  =  7,
   S8  =  8,
   S9  =  9,
   S10 = 10,
   S11 = 11,
   S12 = 12,
   S13 = 13,
   S14 = 14,
   S15 = 15,
   S16 = 16,
   S17 = 17,
   S18 = 18,
   S19 = 19,
   S20 = 20,
   S21 = 21,
   S22 = 22,
   S23 = 23,
   S24 = 24,
   S25 = 25,
   S26 = 26,
   S27 = 27,
   S28 = 28,
   S29 = 29,
   S30 = 30,
   S31 = 31,
   kNumberOfSRegisters = 32,
   kNoSRegister = -1,
 };
 std::ostream& operator<<(std::ostream& os, const SRegister& rhs);


 // Values for double-precision floating point registers.
 enum DRegister {
   D0  =  0,
   D1  =  1,
   D2  =  2,
   D3  =  3,
   D4  =  4,
   D5  =  5,
   D6  =  6,
   D7  =  7,
   D8  =  8,
   D9  =  9,
   D10 = 10,
   D11 = 11,
   D12 = 12,
   D13 = 13,
   D14 = 14,
   D15 = 15,
 #ifdef VFPv3_D16
   kNumberOfDRegisters = 16,
 #else
   D16 = 16,
   D17 = 17,
   D18 = 18,
   D19 = 19,
   D20 = 20,
   D21 = 21,
   D22 = 22,
   D23 = 23,
   D24 = 24,
   D25 = 25,
   D26 = 26,
   D27 = 27,
   D28 = 28,
   D29 = 29,
   D30 = 30,
   D31 = 31,
   kNumberOfDRegisters = 32,
 #endif
   kNumberOfOverlappingDRegisters = 16,
   kNoDRegister = -1,
 };
 std::ostream& operator<<(std::ostream& os, const DRegister& rhs);


 // Values for the condition field as defined in section A3.2.
 enum Condition {
   kNoCondition = -1,
   EQ =  0,  // equal
   NE =  1,  // not equal
   CS =  2,  // carry set/unsigned higher or same
   CC =  3,  // carry clear/unsigned lower
   MI =  4,  // minus/negative
   PL =  5,  // plus/positive or zero
   VS =  6,  // overflow
   VC =  7,  // no overflow
   HI =  8,  // unsigned higher
   LS =  9,  // unsigned lower or same
   GE = 10,  // signed greater than or equal
   LT = 11,  // signed less than
   GT = 12,  // signed greater than
   LE = 13,  // signed less than or equal
   AL = 14,  // always (unconditional)
   kSpecialCondition = 15,  // special condition (refer to section A3.2.1)
   kMaxCondition = 16,
 };
 std::ostream& operator<<(std::ostream& os, const Condition& rhs);


 // Opcodes for Data-processing instructions (instructions with a type 0 and 1)
 // as defined in section A3.4
 enum Opcode {
   kNoOperand = -1,
   AND =  0,  // Logical AND
   EOR =  1,  // Logical Exclusive OR
   SUB =  2,  // Subtract
   RSB =  3,  // Reverse Subtract
   ADD =  4,  // Add
   ADC =  5,  // Add with Carry
   SBC =  6,  // Subtract with Carry
   RSC =  7,  // Reverse Subtract with Carry
   TST =  8,  // Test
   TEQ =  9,  // Test Equivalence
   CMP = 10,  // Compare
   CMN = 11,  // Compare Negated
   ORR = 12,  // Logical (inclusive) OR
   MOV = 13,  // Move
   BIC = 14,  // Bit Clear
   MVN = 15,  // Move Not
   kMaxOperand = 16
 };


 // Shifter types for Data-processing operands as defined in section A5.1.2.
 enum Shift {
   kNoShift = -1,
   LSL = 0,  // Logical shift left
   LSR = 1,  // Logical shift right
   ASR = 2,  // Arithmetic shift right
   ROR = 3,  // Rotate right
   kMaxShift = 4
 };


 // Special Supervisor Call 24-bit codes used in the presence of the ARM
 // simulator for redirection, breakpoints, stop messages, and spill markers.
 // See /usr/include/asm/unistd.h
 const uint32_t kRedirectionSvcCode = 0x90001f;  //  unused syscall, was sys_stty
 const uint32_t kBreakpointSvcCode = 0x900020;  // unused syscall, was sys_gtty
 const uint32_t kStopMessageSvcCode = 0x9f0001;  // __ARM_NR_breakpoint
 const uint32_t kSpillMarkerSvcBase = 0x9f0100;  // unused ARM private syscall
 const uint32_t kWordSpillMarkerSvcCode = kSpillMarkerSvcBase + 1;
 const uint32_t kDWordSpillMarkerSvcCode = kSpillMarkerSvcBase + 2;


 // Constants used for the decoding or encoding of the individual fields of
 // instructions. Based on the "Figure 3-1 ARM instruction set summary".
 enum InstructionFields {
   kConditionShift = 28,
   kConditionBits = 4,
   kTypeShift = 25,
   kTypeBits = 3,
   kLinkShift = 24,
   kLinkBits = 1,
   kUShift = 23,
   kUBits = 1,
   kOpcodeShift = 21,
   kOpcodeBits = 4,
   kSShift = 20,
   kSBits = 1,
   kRnShift = 16,
   kRnBits = 4,
   kRdShift = 12,
   kRdBits = 4,
   kRsShift = 8,
   kRsBits = 4,
   kRmShift = 0,
   kRmBits = 4,

   // Immediate instruction fields encoding.
   kRotateShift = 8,
   kRotateBits = 4,
   kImmed8Shift = 0,
   kImmed8Bits = 8,

   // Shift instruction register fields encodings.
   kShiftImmShift = 7,
   kShiftRegisterShift = 8,
   kShiftImmBits = 5,
   kShiftShift = 5,
   kShiftBits = 2,

   // Load/store instruction offset field encoding.
   kOffset12Shift = 0,
   kOffset12Bits = 12,
   kOffset12Mask = 0x00000fff,

   // Mul instruction register fields encodings.
   kMulRdShift = 16,
   kMulRdBits = 4,
   kMulRnShift = 12,
   kMulRnBits = 4,

   kBranchOffsetMask = 0x00ffffff
 };


 // Size (in bytes) of registers.
 const int kRegisterSize = 4;

 // List of registers used in load/store multiple.
 typedef uint16_t RegList;

 const RegList kAllCoreRegistersList = 0xFFFF;

 // C++ ABI call registers
 const int kAbiRegisterCount = 4;
 const Register kAbiRegisters[kAbiRegisterCount] = { R0, R1, R2, R3 };
 const RegList kAbiRegisterList = (1 << R0) | (1 << R1) | (1 << R2) | (1 << R3);

 // Parfait callee-saved registers.
 #ifdef DEBUG
 // Save FP only in Debug mode.
 static const Register kUnsavedCoreRegisters[] = { IP, SP, LR, PC };
 static const RegList kUnsavedCoreRegistersList =
     (1 << IP | 1 << SP | 1 << LR | 1 << PC);
 #else
 static const Register kUnsavedCoreRegisters[] = { FP, IP, SP, LR, PC };
 static const RegList kUnsavedCoreRegistersList =
     (1 << FP | 1 << IP | 1 << SP | 1 << LR | 1 << PC);
 #endif  // DEBUG
 static const RegList kSavedCoreRegistersList =
     kAllCoreRegistersList & (~kUnsavedCoreRegistersList);
 static const int kNumberOfUnsavedCoreRegisters =
     arraysize(kUnsavedCoreRegisters);
 static const int kNumberOfSavedCoreRegisters =
     kNumberOfCoreRegisters - kNumberOfUnsavedCoreRegisters;

 // D8-D15 are ABI callee saved. No need to save them. If there are more than 16
 // D-registers than the following ones (D16 ...) are not ABI callee saved and
 // must be saved by parfait.
 static const int kNumberOfUnsavedDRegisters = 8;
 static const int kNumberOfSavedDRegisters =
     kNumberOfDRegisters - kNumberOfUnsavedDRegisters;

 // Frame layout constants.
 const int kExitLinkByteOffsetFromFp = 9 * kPointerSize;
 const int kSpByteOffsetFromPreviousFp = 2 * kPointerSize;
 const int kPcAddressByteOffsetFromSp = -1 * kPointerSize;
 const int kPcAddressByteOffsetFromExitFp = -1 * kPointerSize;
 const int kCallSaveArea = 2 * kPointerSize;
 const int kCallerSavedCoreRegistersByteOffsetFromFp = -2 * kPointerSize;

 // The class Instr enables access to individual fields defined in the ARM
 // architecture instruction set encoding as described in figure A3-1.
 //
 // Example: Test whether the instruction at ptr does set the condition code
 // bits.
 //
 // bool InstructionSetsConditionCodes(byte* ptr) {
 //   Instr* instr = Instr::At(ptr);
 //   int type = instr->TypeField();
 //   return ((type == 0) || (type == 1)) && instr->HasS();
 // }
 //
 class Instr {
  public:
   enum {
     kInstrSize = 4,
     kInstrSizeLog2 = 2,
     kPCReadOffset = 8
   };

   static const int kBreakPointInstructionSize = kInstrSize;
   bool IsBreakPoint() {
     return IsBkpt();
   }

   // Get the raw instruction bits.
   inline int32_t InstructionBits() const {
     return *reinterpret_cast<const int32_t*>(this);
   }

   // Set the raw instruction bits to value.
   inline void SetInstructionBits(int32_t value) {
     *reinterpret_cast<int32_t*>(this) = value;
   }

   // Read one particular bit out of the instruction bits.
   inline int Bit(int nr) const {
     return (InstructionBits() >> nr) & 1;
   }

   // Read a bit field out of the instruction bits.
   inline int Bits(int shift, int count) const {
     return (InstructionBits() >> shift) & ((1 << count) - 1);
   }


   // Accessors for the different named fields used in the ARM encoding.
   // The naming of these accessor corresponds to figure A3-1.
   // Generally applicable fields
   inline Condition ConditionField() const {
     return static_cast<Condition>(Bits(kConditionShift, kConditionBits));
   }
   inline int TypeField() const { return Bits(kTypeShift, kTypeBits); }

   inline Register RnField() const { return static_cast<Register>(
                                         Bits(kRnShift, kRnBits)); }
   inline Register RdField() const { return static_cast<Register>(
                                         Bits(kRdShift, kRdBits)); }

   // Fields used in Data processing instructions
   inline Opcode OpcodeField() const {
     return static_cast<Opcode>(Bits(kOpcodeShift, kOpcodeBits));
   }
   inline int SField() const { return Bits(kSShift, kSBits); }
   // with register
   inline Register RmField() const {
     return static_cast<Register>(Bits(kRmShift, kRmBits));
   }
   inline Shift ShiftField() const { return static_cast<Shift>(
                                         Bits(kShiftShift, kShiftBits)); }
   inline int RegShiftField() const { return Bit(4); }
   inline Register RsField() const {
     return static_cast<Register>(Bits(kRsShift, kRsBits));
   }
   inline int ShiftAmountField() const { return Bits(kShiftImmShift,
                                                     kShiftImmBits); }
   // with immediate
   inline int RotateField() const { return Bits(kRotateShift, kRotateBits); }
   inline int Immed8Field() const { return Bits(kImmed8Shift, kImmed8Bits); }

   // Fields used in Load/Store instructions
   inline int PUField() const { return Bits(23, 2); }
   inline int  BField() const { return Bit(22); }
   inline int  WField() const { return Bit(21); }
   inline int  LField() const { return Bit(20); }
   // with register uses same fields as Data processing instructions above
   // with immediate
   inline int Offset12Field() const { return Bits(kOffset12Shift,
                                                  kOffset12Bits); }
   // multiple
   inline int RlistField() const { return Bits(0, 16); }
   // extra loads and stores
   inline int SignField() const { return Bit(6); }
   inline int HField() const { return Bit(5); }
   inline int ImmedHField() const { return Bits(8, 4); }
   inline int ImmedLField() const { return Bits(0, 4); }

   // Fields used in Branch instructions
   inline int LinkField() const { return Bits(kLinkShift, kLinkBits); }
   inline int SImmed24Field() const { return ((InstructionBits() << 8) >> 8); }

   // Fields used in Supervisor Call instructions
   inline uint32_t SvcField() const { return Bits(0, 24); }

   // Field used in Breakpoint instruction
   inline uint16_t BkptField() const {
     return ((Bits(8, 12) << 4) | Bits(0, 4));
   }

   // Field used in 16-bit immediate move instructions
   inline uint16_t MovwField() const {
     return ((Bits(16, 4) << 12) | Bits(0, 12));
   }

   // Field used in VFP float immediate move instruction
   inline float ImmFloatField() const {
     uint32_t imm32 = (Bit(19) << 31) | (((1 << 5) - Bit(18)) << 25) |
                      (Bits(16, 2) << 23) | (Bits(0, 4) << 19);
     return bit_cast<float, uint32_t>(imm32);
   }

   // Field used in VFP double immediate move instruction
   inline double ImmDoubleField() const {
     uint64_t imm64 = (Bit(19)*(1LL << 63)) | (((1LL << 8) - Bit(18)) << 54) |
                      (Bits(16, 2)*(1LL << 52)) | (Bits(0, 4)*(1LL << 48));
     return bit_cast<double, uint64_t>(imm64);
   }

   // Test for data processing instructions of type 0 or 1.
   // See "ARM Architecture Reference Manual ARMv7-A and ARMv7-R edition",
   // section A5.1 "ARM instruction set encoding".
   inline bool IsDataProcessing() const {
     CHECK_NE(ConditionField(), kSpecialCondition);
     CHECK_EQ(Bits(26, 2), 0);  // Type 0 or 1.
     return ((Bits(20, 5) & 0x19) != 0x10) &&
       ((Bit(25) == 1) ||  // Data processing immediate.
        (Bit(4) == 0) ||  // Data processing register.
        (Bit(7) == 0));  // Data processing register-shifted register.
   }

   // Tests for special encodings of type 0 instructions (extra loads and stores,
   // as well as multiplications, synchronization primitives, and miscellaneous).
   // Can only be called for a type 0 or 1 instruction.
   inline bool IsMiscellaneous() const {
     CHECK_EQ(Bits(26, 2), 0);  // Type 0 or 1.
     return ((Bit(25) == 0) && ((Bits(20, 5) & 0x19) == 0x10) && (Bit(7) == 0));
   }
   inline bool IsMultiplyOrSyncPrimitive() const {
     CHECK_EQ(Bits(26, 2), 0);  // Type 0 or 1.
     return ((Bit(25) == 0) && (Bits(4, 4) == 9));
   }

   // Test for Supervisor Call instruction.
   inline bool IsSvc() const {
     return ((InstructionBits() & 0xff000000) == 0xef000000);
   }

   // Test for Breakpoint instruction.
   inline bool IsBkpt() const {
     return ((InstructionBits() & 0xfff000f0) == 0xe1200070);
   }

   // VFP register fields.
   inline SRegister SnField() const {
     return static_cast<SRegister>((Bits(kRnShift, kRnBits) << 1) + Bit(7));
   }
   inline SRegister SdField() const {
     return static_cast<SRegister>((Bits(kRdShift, kRdBits) << 1) + Bit(22));
   }
   inline SRegister SmField() const {
     return static_cast<SRegister>((Bits(kRmShift, kRmBits) << 1) + Bit(5));
   }
   inline DRegister DnField() const {
     return static_cast<DRegister>(Bits(kRnShift, kRnBits) + (Bit(7) << 4));
   }
   inline DRegister DdField() const {
     return static_cast<DRegister>(Bits(kRdShift, kRdBits) + (Bit(22) << 4));
   }
   inline DRegister DmField() const {
     return static_cast<DRegister>(Bits(kRmShift, kRmBits) + (Bit(5) << 4));
   }

   // Test for VFP data processing or single transfer instructions of type 7.
   inline bool IsVFPDataProcessingOrSingleTransfer() const {
     CHECK_NE(ConditionField(), kSpecialCondition);
     CHECK_EQ(TypeField(), 7);
     return ((Bit(24) == 0) && (Bits(9, 3) == 5));
     // Bit(4) == 0: Data Processing
     // Bit(4) == 1: 8, 16, or 32-bit Transfer between ARM Core and VFP
   }

   // Test for VFP 64-bit transfer instructions of type 6.
   inline bool IsVFPDoubleTransfer() const {
     CHECK_NE(ConditionField(), kSpecialCondition);
     CHECK_EQ(TypeField(), 6);
     return ((Bits(21, 4) == 2) && (Bits(9, 3) == 5) &&
             ((Bits(4, 4) & 0xd) == 1));
   }

   // Test for VFP load and store instructions of type 6.
   inline bool IsVFPLoadStore() const {
     CHECK_NE(ConditionField(), kSpecialCondition);
     CHECK_EQ(TypeField(), 6);
     return ((Bits(20, 5) & 0x12) == 0x10) && (Bits(9, 3) == 5);
   }

   // Special accessors that test for existence of a value.
   inline bool HasS() const { return SField() == 1; }
   inline bool HasB() const { return BField() == 1; }
   inline bool HasW() const { return WField() == 1; }
   inline bool HasL() const { return LField() == 1; }
   inline bool HasSign() const { return SignField() == 1; }
   inline bool HasH() const { return HField() == 1; }
   inline bool HasLink() const { return LinkField() == 1; }

   // Instructions are read out of a code stream. The only way to get a
   // reference to an instruction is to convert a pointer. There is no way
   // to allocate or create instances of class Instr.
   // Use the At(pc) function to create references to Instr.
   static Instr* At(uword pc) { return reinterpret_cast<Instr*>(pc); }
   Instr* Next() { return this + kInstrSize; }

  private:
   // We need to prevent the creation of instances of class Instr.
   DISALLOW_IMPLICIT_CONSTRUCTORS(Instr);
 };

 }  // namespace arm
 }  // namespace art

 #endif  // ART_SRC_CONSTANTS_ARM_H_
	// Copyright 2009 Google Inc. All Rights Reserved.

	#ifndef ART_SRC_CONSTANTS_ARM_H_
	#define ART_SRC_CONSTANTS_ARM_H_

	#include <stdint.h>
	#include <iosfwd>
	#include "casts.h"
	#include "globals.h"
	#include "logging.h"

	namespace art {
	namespace arm {

	// Defines constants and accessor classes to assemble, disassemble and
	// simulate ARM instructions.
	//
	// Section references in the code refer to the "ARM Architecture Reference
	// Manual" from July 2005 (available at http://www.arm.com/miscPDFs/14128.pdf)
	//
	// Constants for specific fields are defined in their respective named enums.
	// General constants are in an anonymous enum in class Instr.


	// We support both VFPv3-D16 and VFPv3-D32 profiles, but currently only one at
	// a time, so that compile time optimizations can be applied.
	// Warning: VFPv3-D32 is untested.
	#define VFPv3_D16
	#if defined(VFPv3_D16) == defined(VFPv3_D32)
	#error "Exactly one of VFPv3_D16 or VFPv3_D32 can be defined at a time."
	#endif


	// Values for registers.
	enum Register {
	R0 = 0,
	R1 = 1,
	R2 = 2,
	R3 = 3,
	R4 = 4,
	R5 = 5,
	R6 = 6,
	R7 = 7,
	R8 = 8,
	R9 = 9,
	R10 = 10,
	R11 = 11,
	R12 = 12,
	R13 = 13,
	R14 = 14,
	R15 = 15,
	TR = 9, // thread register
	FP = 11,
	IP = 12,
	SP = 13,
	LR = 14,
	PC = 15,
	kNumberOfCoreRegisters = 16,
	kNoRegister = -1,
	};
	std::ostream& operator<<(std::ostream& os, const Register& rhs);


	enum ScaleFactor {
	TIMES_1 = 0,
	TIMES_2 = 1,
	TIMES_4 = 2,
	TIMES_8 = 3
	};


	// Values for single-precision floating point registers.
	enum SRegister {
	S0 = 0,
	S1 = 1,
	S2 = 2,
	S3 = 3,
	S4 = 4,
	S5 = 5,
	S6 = 6,
	S7 = 7,
	S8 = 8,
	S9 = 9,
	S10 = 10,
	S11 = 11,
	S12 = 12,
	S13 = 13,
	S14 = 14,
	S15 = 15,
	S16 = 16,
	S17 = 17,
	S18 = 18,
	S19 = 19,
	S20 = 20,
	S21 = 21,
	S22 = 22,
	S23 = 23,
	S24 = 24,
	S25 = 25,
	S26 = 26,
	S27 = 27,
	S28 = 28,
	S29 = 29,
	S30 = 30,
	S31 = 31,
	kNumberOfSRegisters = 32,
	kNoSRegister = -1,
	};
	std::ostream& operator<<(std::ostream& os, const SRegister& rhs);


	// Values for double-precision floating point registers.
	enum DRegister {
	D0 = 0,
	D1 = 1,
	D2 = 2,
	D3 = 3,
	D4 = 4,
	D5 = 5,
	D6 = 6,
	D7 = 7,
	D8 = 8,
	D9 = 9,
	D10 = 10,
	D11 = 11,
	D12 = 12,
	D13 = 13,
	D14 = 14,
	D15 = 15,
	#ifdef VFPv3_D16
	kNumberOfDRegisters = 16,
	#else
	D16 = 16,
	D17 = 17,
	D18 = 18,
	D19 = 19,
	D20 = 20,
	D21 = 21,
	D22 = 22,
	D23 = 23,
	D24 = 24,
	D25 = 25,
	D26 = 26,
	D27 = 27,
	D28 = 28,
	D29 = 29,
	D30 = 30,
	D31 = 31,
	kNumberOfDRegisters = 32,
	#endif
	kNumberOfOverlappingDRegisters = 16,
	kNoDRegister = -1,
	};
	std::ostream& operator<<(std::ostream& os, const DRegister& rhs);


	// Values for the condition field as defined in section A3.2.
	enum Condition {
	kNoCondition = -1,
	EQ = 0, // equal
	NE = 1, // not equal
	CS = 2, // carry set/unsigned higher or same
	CC = 3, // carry clear/unsigned lower
	MI = 4, // minus/negative
	PL = 5, // plus/positive or zero
	VS = 6, // overflow
	VC = 7, // no overflow
	HI = 8, // unsigned higher
	LS = 9, // unsigned lower or same
	GE = 10, // signed greater than or equal
	LT = 11, // signed less than
	GT = 12, // signed greater than
	LE = 13, // signed less than or equal
	AL = 14, // always (unconditional)
	kSpecialCondition = 15, // special condition (refer to section A3.2.1)
	kMaxCondition = 16,
	};
	std::ostream& operator<<(std::ostream& os, const Condition& rhs);


	// Opcodes for Data-processing instructions (instructions with a type 0 and 1)
	// as defined in section A3.4
	enum Opcode {
	kNoOperand = -1,
	AND = 0, // Logical AND
	EOR = 1, // Logical Exclusive OR
	SUB = 2, // Subtract
	RSB = 3, // Reverse Subtract
	ADD = 4, // Add
	ADC = 5, // Add with Carry
	SBC = 6, // Subtract with Carry
	RSC = 7, // Reverse Subtract with Carry
	TST = 8, // Test
	TEQ = 9, // Test Equivalence
	CMP = 10, // Compare
	CMN = 11, // Compare Negated
	ORR = 12, // Logical (inclusive) OR
	MOV = 13, // Move
	BIC = 14, // Bit Clear
	MVN = 15, // Move Not
	kMaxOperand = 16
	};


	// Shifter types for Data-processing operands as defined in section A5.1.2.
	enum Shift {
	kNoShift = -1,
	LSL = 0, // Logical shift left
	LSR = 1, // Logical shift right
	ASR = 2, // Arithmetic shift right
	ROR = 3, // Rotate right
	kMaxShift = 4
	};


	// Special Supervisor Call 24-bit codes used in the presence of the ARM
	// simulator for redirection, breakpoints, stop messages, and spill markers.
	// See /usr/include/asm/unistd.h
	const uint32_t kRedirectionSvcCode = 0x90001f; // unused syscall, was sys_stty
	const uint32_t kBreakpointSvcCode = 0x900020; // unused syscall, was sys_gtty
	const uint32_t kStopMessageSvcCode = 0x9f0001; // __ARM_NR_breakpoint
	const uint32_t kSpillMarkerSvcBase = 0x9f0100; // unused ARM private syscall
	const uint32_t kWordSpillMarkerSvcCode = kSpillMarkerSvcBase + 1;
	const uint32_t kDWordSpillMarkerSvcCode = kSpillMarkerSvcBase + 2;


	// Constants used for the decoding or encoding of the individual fields of
	// instructions. Based on the "Figure 3-1 ARM instruction set summary".
	enum InstructionFields {
	kConditionShift = 28,
	kConditionBits = 4,
	kTypeShift = 25,
	kTypeBits = 3,
	kLinkShift = 24,
	kLinkBits = 1,
	kUShift = 23,
	kUBits = 1,
	kOpcodeShift = 21,
	kOpcodeBits = 4,
	kSShift = 20,
	kSBits = 1,
	kRnShift = 16,
	kRnBits = 4,
	kRdShift = 12,
	kRdBits = 4,
	kRsShift = 8,
	kRsBits = 4,
	kRmShift = 0,
	kRmBits = 4,

	// Immediate instruction fields encoding.
	kRotateShift = 8,
	kRotateBits = 4,
	kImmed8Shift = 0,
	kImmed8Bits = 8,

	// Shift instruction register fields encodings.
	kShiftImmShift = 7,
	kShiftRegisterShift = 8,
	kShiftImmBits = 5,
	kShiftShift = 5,
	kShiftBits = 2,

	// Load/store instruction offset field encoding.
	kOffset12Shift = 0,
	kOffset12Bits = 12,
	kOffset12Mask = 0x00000fff,

	// Mul instruction register fields encodings.
	kMulRdShift = 16,
	kMulRdBits = 4,
	kMulRnShift = 12,
	kMulRnBits = 4,

	kBranchOffsetMask = 0x00ffffff
	};


	// Size (in bytes) of registers.
	const int kRegisterSize = 4;

	// List of registers used in load/store multiple.
	typedef uint16_t RegList;

	const RegList kAllCoreRegistersList = 0xFFFF;

	// C++ ABI call registers
	const int kAbiRegisterCount = 4;
	const Register kAbiRegisters[kAbiRegisterCount] = { R0, R1, R2, R3 };
	const RegList kAbiRegisterList = (1 << R0) \| (1 << R1) \| (1 << R2) \| (1 << R3);

	// Parfait callee-saved registers.
	#ifdef DEBUG
	// Save FP only in Debug mode.
	static const Register kUnsavedCoreRegisters[] = { IP, SP, LR, PC };
	static const RegList kUnsavedCoreRegistersList =
	(1 << IP \| 1 << SP \| 1 << LR \| 1 << PC);
	#else
	static const Register kUnsavedCoreRegisters[] = { FP, IP, SP, LR, PC };
	static const RegList kUnsavedCoreRegistersList =
	(1 << FP \| 1 << IP \| 1 << SP \| 1 << LR \| 1 << PC);
	#endif // DEBUG
	static const RegList kSavedCoreRegistersList =
	kAllCoreRegistersList & (~kUnsavedCoreRegistersList);
	static const int kNumberOfUnsavedCoreRegisters =
	arraysize(kUnsavedCoreRegisters);
	static const int kNumberOfSavedCoreRegisters =
	kNumberOfCoreRegisters - kNumberOfUnsavedCoreRegisters;

	// D8-D15 are ABI callee saved. No need to save them. If there are more than 16
	// D-registers than the following ones (D16 ...) are not ABI callee saved and
	// must be saved by parfait.
	static const int kNumberOfUnsavedDRegisters = 8;
	static const int kNumberOfSavedDRegisters =
	kNumberOfDRegisters - kNumberOfUnsavedDRegisters;

	// Frame layout constants.
	const int kExitLinkByteOffsetFromFp = 9 * kPointerSize;
	const int kSpByteOffsetFromPreviousFp = 2 * kPointerSize;
	const int kPcAddressByteOffsetFromSp = -1 * kPointerSize;
	const int kPcAddressByteOffsetFromExitFp = -1 * kPointerSize;
	const int kCallSaveArea = 2 * kPointerSize;
	const int kCallerSavedCoreRegistersByteOffsetFromFp = -2 * kPointerSize;

	// The class Instr enables access to individual fields defined in the ARM
	// architecture instruction set encoding as described in figure A3-1.
	//
	// Example: Test whether the instruction at ptr does set the condition code
	// bits.
	//
	// bool InstructionSetsConditionCodes(byte* ptr) {
	// Instr* instr = Instr::At(ptr);
	// int type = instr->TypeField();
	// return ((type == 0) \|\| (type == 1)) && instr->HasS();
	// }
	//
	class Instr {
	public:
	enum {
	kInstrSize = 4,
	kInstrSizeLog2 = 2,
	kPCReadOffset = 8
	};

	static const int kBreakPointInstructionSize = kInstrSize;
	bool IsBreakPoint() {
	return IsBkpt();
	}

	// Get the raw instruction bits.
	inline int32_t InstructionBits() const {
	return reinterpret_cast<const int32_t>(this);
	}

	// Set the raw instruction bits to value.
	inline void SetInstructionBits(int32_t value) {
	reinterpret_cast<int32_t>(this) = value;
	}

	// Read one particular bit out of the instruction bits.
	inline int Bit(int nr) const {
	return (InstructionBits() >> nr) & 1;
	}

	// Read a bit field out of the instruction bits.
	inline int Bits(int shift, int count) const {
	return (InstructionBits() >> shift) & ((1 << count) - 1);
	}


	// Accessors for the different named fields used in the ARM encoding.
	// The naming of these accessor corresponds to figure A3-1.
	// Generally applicable fields
	inline Condition ConditionField() const {
	return static_cast<Condition>(Bits(kConditionShift, kConditionBits));
	}
	inline int TypeField() const { return Bits(kTypeShift, kTypeBits); }

	inline Register RnField() const { return static_cast<Register>(
	Bits(kRnShift, kRnBits)); }
	inline Register RdField() const { return static_cast<Register>(
	Bits(kRdShift, kRdBits)); }

	// Fields used in Data processing instructions
	inline Opcode OpcodeField() const {
	return static_cast<Opcode>(Bits(kOpcodeShift, kOpcodeBits));
	}
	inline int SField() const { return Bits(kSShift, kSBits); }
	// with register
	inline Register RmField() const {
	return static_cast<Register>(Bits(kRmShift, kRmBits));
	}
	inline Shift ShiftField() const { return static_cast<Shift>(
	Bits(kShiftShift, kShiftBits)); }
	inline int RegShiftField() const { return Bit(4); }
	inline Register RsField() const {
	return static_cast<Register>(Bits(kRsShift, kRsBits));
	}
	inline int ShiftAmountField() const { return Bits(kShiftImmShift,
	kShiftImmBits); }
	// with immediate
	inline int RotateField() const { return Bits(kRotateShift, kRotateBits); }
	inline int Immed8Field() const { return Bits(kImmed8Shift, kImmed8Bits); }

	// Fields used in Load/Store instructions
	inline int PUField() const { return Bits(23, 2); }
	inline int BField() const { return Bit(22); }
	inline int WField() const { return Bit(21); }
	inline int LField() const { return Bit(20); }
	// with register uses same fields as Data processing instructions above
	// with immediate
	inline int Offset12Field() const { return Bits(kOffset12Shift,
	kOffset12Bits); }
	// multiple
	inline int RlistField() const { return Bits(0, 16); }
	// extra loads and stores
	inline int SignField() const { return Bit(6); }
	inline int HField() const { return Bit(5); }
	inline int ImmedHField() const { return Bits(8, 4); }
	inline int ImmedLField() const { return Bits(0, 4); }

	// Fields used in Branch instructions
	inline int LinkField() const { return Bits(kLinkShift, kLinkBits); }
	inline int SImmed24Field() const { return ((InstructionBits() << 8) >> 8); }

	// Fields used in Supervisor Call instructions
	inline uint32_t SvcField() const { return Bits(0, 24); }

	// Field used in Breakpoint instruction
	inline uint16_t BkptField() const {
	return ((Bits(8, 12) << 4) \| Bits(0, 4));
	}

	// Field used in 16-bit immediate move instructions
	inline uint16_t MovwField() const {
	return ((Bits(16, 4) << 12) \| Bits(0, 12));
	}

	// Field used in VFP float immediate move instruction
	inline float ImmFloatField() const {
	uint32_t imm32 = (Bit(19) << 31) \| (((1 << 5) - Bit(18)) << 25) \|
	(Bits(16, 2) << 23) \| (Bits(0, 4) << 19);
	return bit_cast<float, uint32_t>(imm32);
	}

	// Field used in VFP double immediate move instruction
	inline double ImmDoubleField() const {
	uint64_t imm64 = (Bit(19)*(1LL << 63)) \| (((1LL << 8) - Bit(18)) << 54) \|
	(Bits(16, 2)(1LL << 52)) \| (Bits(0, 4)(1LL << 48));
	return bit_cast<double, uint64_t>(imm64);
	}

	// Test for data processing instructions of type 0 or 1.
	// See "ARM Architecture Reference Manual ARMv7-A and ARMv7-R edition",
	// section A5.1 "ARM instruction set encoding".
	inline bool IsDataProcessing() const {
	CHECK_NE(ConditionField(), kSpecialCondition);
	CHECK_EQ(Bits(26, 2), 0); // Type 0 or 1.
	return ((Bits(20, 5) & 0x19) != 0x10) &&
	((Bit(25) == 1) \|\| // Data processing immediate.
	(Bit(4) == 0) \|\| // Data processing register.
	(Bit(7) == 0)); // Data processing register-shifted register.
	}

	// Tests for special encodings of type 0 instructions (extra loads and stores,
	// as well as multiplications, synchronization primitives, and miscellaneous).
	// Can only be called for a type 0 or 1 instruction.
	inline bool IsMiscellaneous() const {
	CHECK_EQ(Bits(26, 2), 0); // Type 0 or 1.
	return ((Bit(25) == 0) && ((Bits(20, 5) & 0x19) == 0x10) && (Bit(7) == 0));
	}
	inline bool IsMultiplyOrSyncPrimitive() const {
	CHECK_EQ(Bits(26, 2), 0); // Type 0 or 1.
	return ((Bit(25) == 0) && (Bits(4, 4) == 9));
	}

	// Test for Supervisor Call instruction.
	inline bool IsSvc() const {
	return ((InstructionBits() & 0xff000000) == 0xef000000);
	}

	// Test for Breakpoint instruction.
	inline bool IsBkpt() const {
	return ((InstructionBits() & 0xfff000f0) == 0xe1200070);
	}

	// VFP register fields.
	inline SRegister SnField() const {
	return static_cast<SRegister>((Bits(kRnShift, kRnBits) << 1) + Bit(7));
	}
	inline SRegister SdField() const {
	return static_cast<SRegister>((Bits(kRdShift, kRdBits) << 1) + Bit(22));
	}
	inline SRegister SmField() const {
	return static_cast<SRegister>((Bits(kRmShift, kRmBits) << 1) + Bit(5));
	}
	inline DRegister DnField() const {
	return static_cast<DRegister>(Bits(kRnShift, kRnBits) + (Bit(7) << 4));
	}
	inline DRegister DdField() const {
	return static_cast<DRegister>(Bits(kRdShift, kRdBits) + (Bit(22) << 4));
	}
	inline DRegister DmField() const {
	return static_cast<DRegister>(Bits(kRmShift, kRmBits) + (Bit(5) << 4));
	}

	// Test for VFP data processing or single transfer instructions of type 7.
	inline bool IsVFPDataProcessingOrSingleTransfer() const {
	CHECK_NE(ConditionField(), kSpecialCondition);
	CHECK_EQ(TypeField(), 7);
	return ((Bit(24) == 0) && (Bits(9, 3) == 5));
	// Bit(4) == 0: Data Processing
	// Bit(4) == 1: 8, 16, or 32-bit Transfer between ARM Core and VFP
	}

	// Test for VFP 64-bit transfer instructions of type 6.
	inline bool IsVFPDoubleTransfer() const {
	CHECK_NE(ConditionField(), kSpecialCondition);
	CHECK_EQ(TypeField(), 6);
	return ((Bits(21, 4) == 2) && (Bits(9, 3) == 5) &&
	((Bits(4, 4) & 0xd) == 1));
	}

	// Test for VFP load and store instructions of type 6.
	inline bool IsVFPLoadStore() const {
	CHECK_NE(ConditionField(), kSpecialCondition);
	CHECK_EQ(TypeField(), 6);
	return ((Bits(20, 5) & 0x12) == 0x10) && (Bits(9, 3) == 5);
	}

	// Special accessors that test for existence of a value.
	inline bool HasS() const { return SField() == 1; }
	inline bool HasB() const { return BField() == 1; }
	inline bool HasW() const { return WField() == 1; }
	inline bool HasL() const { return LField() == 1; }
	inline bool HasSign() const { return SignField() == 1; }
	inline bool HasH() const { return HField() == 1; }
	inline bool HasLink() const { return LinkField() == 1; }

	// Instructions are read out of a code stream. The only way to get a
	// reference to an instruction is to convert a pointer. There is no way
	// to allocate or create instances of class Instr.
	// Use the At(pc) function to create references to Instr.
	static Instr* At(uword pc) { return reinterpret_cast<Instr*>(pc); }
	Instr* Next() { return this + kInstrSize; }

	private:
	// We need to prevent the creation of instances of class Instr.
	DISALLOW_IMPLICIT_CONSTRUCTORS(Instr);
	};

	} // namespace arm
	} // namespace art

	#endif // ART_SRC_CONSTANTS_ARM_H_