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path: root/src/3rdparty/masm/assembler/ARM64Assembler.h
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/*
 * Copyright (C) 2012, 2014 Apple Inc. All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
 * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 
 */

#ifndef ARM64Assembler_h
#define ARM64Assembler_h

#if ENABLE(ASSEMBLER) && (CPU(ARM64) || defined(V4_BOOTSTRAP))

#include "AssemblerBuffer.h"
#include "AbstractMacroAssembler.h"
#include <limits.h>
#include <wtf/Assertions.h>
#include <wtf/Vector.h>
#include <stdint.h>

#if OS(IOS)
#include <libkern/OSCacheControl.h>
#endif

#if OS(INTEGRITY)
#include <INTEGRITY.h>
#endif

#define CHECK_DATASIZE_OF(datasize) ASSERT(datasize == 32 || datasize == 64)
#define DATASIZE_OF(datasize) ((datasize == 64) ? Datasize_64 : Datasize_32)
#define MEMOPSIZE_OF(datasize) ((datasize == 8 || datasize == 128) ? MemOpSize_8_or_128 : (datasize == 16) ? MemOpSize_16 : (datasize == 32) ? MemOpSize_32 : MemOpSize_64)
#define CHECK_DATASIZE() CHECK_DATASIZE_OF(datasize)
#define CHECK_VECTOR_DATASIZE() ASSERT(datasize == 64 || datasize == 128)
#define DATASIZE DATASIZE_OF(datasize)
#define MEMOPSIZE MEMOPSIZE_OF(datasize)
#define CHECK_FP_MEMOP_DATASIZE() ASSERT(datasize == 8 || datasize == 16 || datasize == 32 || datasize == 64 || datasize == 128)
#define MEMPAIROPSIZE_INT(datasize) ((datasize == 64) ? MemPairOp_64 : MemPairOp_32)
#define MEMPAIROPSIZE_FP(datasize) ((datasize == 128) ? MemPairOp_V128 : (datasize == 64) ? MemPairOp_V64 : MemPairOp_32)

namespace JSC {

ALWAYS_INLINE bool isInt9(int32_t value)
{
    return value == ((value << 23) >> 23);
}

template<typename Type>
ALWAYS_INLINE bool isUInt12(Type value)
{
    return !(value & ~static_cast<Type>(0xfff));
}

template<int datasize>
ALWAYS_INLINE bool isValidScaledUImm12(int32_t offset)
{
    int32_t maxPImm = 4095 * (datasize / 8);
    if (offset < 0)
        return false;
    if (offset > maxPImm)
        return false;
    if (offset & ((datasize / 8) - 1))
        return false;
    return true;
}

ALWAYS_INLINE bool isValidSignedImm9(int32_t value)
{
    return isInt9(value);
}

ALWAYS_INLINE bool isInt7(int32_t value)
{
    return value == ((value << 25) >> 25);
}

ALWAYS_INLINE bool isInt11(int32_t value)
{
    return value == ((value << 21) >> 21);
}

ALWAYS_INLINE bool isUInt5(int32_t value)
{
    return !(value & ~0x1f);
}

class UInt5 {
public:
    explicit UInt5(int value)
        : m_value(value)
    {
        ASSERT(isUInt5(value));
    }

    operator int() { return m_value; }

private:
    int m_value;
};

class UInt12 {
public:
    explicit UInt12(int value)
        : m_value(value)
    {
        ASSERT(isUInt12(value));
    }

    operator int() { return m_value; }

private:
    int m_value;
};

class PostIndex {
public:
    explicit PostIndex(int value)
        : m_value(value)
    {
        ASSERT(isInt9(value));
    }

    operator int() { return m_value; }

private:
    int m_value;
};

class PreIndex {
public:
    explicit PreIndex(int value)
        : m_value(value)
    {
        ASSERT(isInt9(value));
    }

    operator int() { return m_value; }

private:
    int m_value;
};

class PairPostIndex {
public:
    explicit PairPostIndex(int value)
        : m_value(value)
    {
        ASSERT(isInt11(value));
    }

    operator int() { return m_value; }

private:
    int m_value;
};

class PairPreIndex {
public:
    explicit PairPreIndex(int value)
        : m_value(value)
    {
        ASSERT(isInt11(value));
    }

    operator int() { return m_value; }

private:
    int m_value;
};

class LogicalImmediate {
public:
    static LogicalImmediate create32(uint32_t value)
    {
        // Check for 0, -1 - these cannot be encoded.
        if (!value || !~value)
            return InvalidLogicalImmediate;

        // First look for a 32-bit pattern, then for repeating 16-bit
        // patterns, 8-bit, 4-bit, and finally 2-bit.

        unsigned hsb, lsb;
        bool inverted;
        if (findBitRange<32>(value, hsb, lsb, inverted))
            return encodeLogicalImmediate<32>(hsb, lsb, inverted);

        if ((value & 0xffff) != (value >> 16))
            return InvalidLogicalImmediate;
        value &= 0xffff;

        if (findBitRange<16>(value, hsb, lsb, inverted))
            return encodeLogicalImmediate<16>(hsb, lsb, inverted);

        if ((value & 0xff) != (value >> 8))
            return InvalidLogicalImmediate;
        value &= 0xff;

        if (findBitRange<8>(value, hsb, lsb, inverted))
            return encodeLogicalImmediate<8>(hsb, lsb, inverted);

        if ((value & 0xf) != (value >> 4))
            return InvalidLogicalImmediate;
        value &= 0xf;

        if (findBitRange<4>(value, hsb, lsb, inverted))
            return encodeLogicalImmediate<4>(hsb, lsb, inverted);

        if ((value & 0x3) != (value >> 2))
            return InvalidLogicalImmediate;
        value &= 0x3;

        if (findBitRange<2>(value, hsb, lsb, inverted))
            return encodeLogicalImmediate<2>(hsb, lsb, inverted);

        return InvalidLogicalImmediate;
    }

    static LogicalImmediate create64(uint64_t value)
    {
        // Check for 0, -1 - these cannot be encoded.
        if (!value || !~value)
            return InvalidLogicalImmediate;

        // Look for a contiguous bit range.
        unsigned hsb, lsb;
        bool inverted;
        if (findBitRange<64>(value, hsb, lsb, inverted))
            return encodeLogicalImmediate<64>(hsb, lsb, inverted);

        // If the high & low 32 bits are equal, we can try for a 32-bit (or narrower) pattern.
        if (static_cast<uint32_t>(value) == static_cast<uint32_t>(value >> 32))
            return create32(static_cast<uint32_t>(value));
        return InvalidLogicalImmediate;
    }

    int value() const
    {
        ASSERT(isValid());
        return m_value;
    }

    bool isValid() const
    {
        return m_value != InvalidLogicalImmediate;
    }

    bool is64bit() const
    {
        return m_value & (1 << 12);
    }

private:
    LogicalImmediate(int value)
        : m_value(value)
    {
    }

    // Generate a mask with bits in the range hsb..0 set, for example:
    //   hsb:63 = 0xffffffffffffffff
    //   hsb:42 = 0x000007ffffffffff
    //   hsb: 0 = 0x0000000000000001
    static uint64_t mask(unsigned hsb)
    {
        ASSERT(hsb < 64);
        return 0xffffffffffffffffull >> (63 - hsb);
    }

    template<unsigned N>
    static void partialHSB(uint64_t& value, unsigned&result)
    {
        if (value & (0xffffffffffffffffull << N)) {
            result += N;
            value >>= N;
        }
    }

    // Find the bit number of the highest bit set in a non-zero value, for example:
    //   0x8080808080808080 = hsb:63
    //   0x0000000000000001 = hsb: 0
    //   0x000007ffffe00000 = hsb:42
    static unsigned highestSetBit(uint64_t value)
    {
        ASSERT(value);
        unsigned hsb = 0;
        partialHSB<32>(value, hsb);
        partialHSB<16>(value, hsb);
        partialHSB<8>(value, hsb);
        partialHSB<4>(value, hsb);
        partialHSB<2>(value, hsb);
        partialHSB<1>(value, hsb);
        return hsb;
    }

    // This function takes a value and a bit width, where value obeys the following constraints:
    //   * bits outside of the width of the value must be zero.
    //   * bits within the width of value must neither be all clear or all set.
    // The input is inspected to detect values that consist of either two or three contiguous
    // ranges of bits. The output range hsb..lsb will describe the second range of the value.
    // if the range is set, inverted will be false, and if the range is clear, inverted will
    // be true. For example (with width 8):
    //   00001111 = hsb:3, lsb:0, inverted:false
    //   11110000 = hsb:3, lsb:0, inverted:true
    //   00111100 = hsb:5, lsb:2, inverted:false
    //   11000011 = hsb:5, lsb:2, inverted:true
    template<unsigned width>
    static bool findBitRange(uint64_t value, unsigned& hsb, unsigned& lsb, bool& inverted)
    {
        ASSERT(value & mask(width - 1));
        ASSERT(value != mask(width - 1));
        ASSERT(!(value & ~mask(width - 1)));

        // Detect cases where the top bit is set; if so, flip all the bits & set invert.
        // This halves the number of patterns we need to look for.
        const uint64_t msb = 1ull << (width - 1);
        if ((inverted = (value & msb)))
            value ^= mask(width - 1);

        // Find the highest set bit in value, generate a corresponding mask & flip all
        // bits under it.
        hsb = highestSetBit(value);
        value ^= mask(hsb);
        if (!value) {
            // If this cleared the value, then the range hsb..0 was all set.
            lsb = 0;
            return true;
        }

        // Try making one more mask, and flipping the bits!
        lsb = highestSetBit(value);
        value ^= mask(lsb);
        if (!value) {
            // Success - but lsb actually points to the hsb of a third range - add one
            // to get to the lsb of the mid range.
            ++lsb;
            return true;
        }

        return false;
    }

    // Encodes the set of immN:immr:imms fields found in a logical immediate.
    template<unsigned width>
    static int encodeLogicalImmediate(unsigned hsb, unsigned lsb, bool inverted)
    {
        // Check width is a power of 2!
        ASSERT(!(width & (width -1)));
        ASSERT(width <= 64 && width >= 2);
        ASSERT(hsb >= lsb);
        ASSERT(hsb < width);

        int immN = 0;
        int imms = 0;
        int immr = 0;

        // For 64-bit values this is easy - just set immN to true, and imms just
        // contains the bit number of the highest set bit of the set range. For
        // values with narrower widths, these are encoded by a leading set of
        // one bits, followed by a zero bit, followed by the remaining set of bits
        // being the high bit of the range. For a 32-bit immediate there are no
        // leading one bits, just a zero followed by a five bit number. For a
        // 16-bit immediate there is one one bit, a zero bit, and then a four bit
        // bit-position, etc.
        if (width == 64)
            immN = 1;
        else
            imms = 63 & ~(width + width - 1);

        if (inverted) {
            // if width is 64 & hsb is 62, then we have a value something like:
            //   0x80000000ffffffff (in this case with lsb 32).
            // The ror should be by 1, imms (effectively set width minus 1) is
            // 32. Set width is full width minus cleared width.
            immr = (width - 1) - hsb;
            imms |= (width - ((hsb - lsb) + 1)) - 1;
        } else {
            // if width is 64 & hsb is 62, then we have a value something like:
            //   0x7fffffff00000000 (in this case with lsb 32).
            // The value is effectively rol'ed by lsb, which is equivalent to
            // a ror by width - lsb (or 0, in the case where lsb is 0). imms
            // is hsb - lsb.
            immr = (width - lsb) & (width - 1);
            imms |= hsb - lsb;
        }

        return immN << 12 | immr << 6 | imms;
    }

    static const int InvalidLogicalImmediate = -1;

    int m_value;
};

inline uint16_t getHalfword(uint64_t value, int which)
{
    return value >> (which << 4);
}

namespace ARM64Registers {

#define FOR_EACH_CPU_REGISTER(V) \
    FOR_EACH_CPU_GPREGISTER(V) \
    FOR_EACH_CPU_SPECIAL_REGISTER(V) \
    FOR_EACH_CPU_FPREGISTER(V)

// The following are defined as pairs of the following value:
// 1. type of the storage needed to save the register value by the JIT probe.
// 2. name of the register.
#define FOR_EACH_CPU_GPREGISTER(V) \
    /* Parameter/result registers */ \
    V(void*, x0) \
    V(void*, x1) \
    V(void*, x2) \
    V(void*, x3) \
    V(void*, x4) \
    V(void*, x5) \
    V(void*, x6) \
    V(void*, x7) \
    /* Indirect result location register */ \
    V(void*, x8) \
    /* Temporary registers */ \
    V(void*, x9) \
    V(void*, x10) \
    V(void*, x11) \
    V(void*, x12) \
    V(void*, x13) \
    V(void*, x14) \
    V(void*, x15) \
    /* Intra-procedure-call scratch registers (temporary) */ \
    V(void*, x16) \
    V(void*, x17) \
    /* Platform Register (temporary) */ \
    V(void*, x18) \
    /* Callee-saved */ \
    V(void*, x19) \
    V(void*, x20) \
    V(void*, x21) \
    V(void*, x22) \
    V(void*, x23) \
    V(void*, x24) \
    V(void*, x25) \
    V(void*, x26) \
    V(void*, x27) \
    V(void*, x28) \
    /* Special */ \
    V(void*, fp) \
    V(void*, lr) \
    V(void*, sp)

#define FOR_EACH_CPU_SPECIAL_REGISTER(V) \
    V(void*, pc) \
    V(void*, nzcv) \
    V(void*, fpsr) \

// ARM64 always has 32 FPU registers 128-bits each. See http://llvm.org/devmtg/2012-11/Northover-AArch64.pdf
// and Section 5.1.2 in http://infocenter.arm.com/help/topic/com.arm.doc.ihi0055b/IHI0055B_aapcs64.pdf.
// However, we only use them for 64-bit doubles.
#define FOR_EACH_CPU_FPREGISTER(V) \
    /* Parameter/result registers */ \
    V(double, q0) \
    V(double, q1) \
    V(double, q2) \
    V(double, q3) \
    V(double, q4) \
    V(double, q5) \
    V(double, q6) \
    V(double, q7) \
    /* Callee-saved (up to 64-bits only!) */ \
    V(double, q8) \
    V(double, q9) \
    V(double, q10) \
    V(double, q11) \
    V(double, q12) \
    V(double, q13) \
    V(double, q14) \
    V(double, q15) \
    /* Temporary registers */ \
    V(double, q16) \
    V(double, q17) \
    V(double, q18) \
    V(double, q19) \
    V(double, q20) \
    V(double, q21) \
    V(double, q22) \
    V(double, q23) \
    V(double, q24) \
    V(double, q25) \
    V(double, q26) \
    V(double, q27) \
    V(double, q28) \
    V(double, q29) \
    V(double, q30) \
    V(double, q31)

typedef enum {
    #define DECLARE_REGISTER(_type, _regName) _regName,
    FOR_EACH_CPU_GPREGISTER(DECLARE_REGISTER)
    #undef DECLARE_REGISTER

    ip0 = x16,
    ip1 = x17,
    x29 = fp,
    x30 = lr,
    zr = 0x3f,
} RegisterID;

typedef enum {
    #define DECLARE_REGISTER(_type, _regName) _regName,
    FOR_EACH_CPU_FPREGISTER(DECLARE_REGISTER)
    #undef DECLARE_REGISTER
} FPRegisterID;

static Q_DECL_CONSTEXPR bool isSp(RegisterID reg) { return reg == sp; }
static Q_DECL_CONSTEXPR bool isZr(RegisterID reg) { return reg == zr; }

} // namespace ARM64Registers

class ARM64Assembler {
public:
    typedef ARM64Registers::RegisterID RegisterID;
    typedef ARM64Registers::FPRegisterID FPRegisterID;
    
    static Q_DECL_CONSTEXPR RegisterID firstRegister() { return ARM64Registers::x0; }
    static Q_DECL_CONSTEXPR RegisterID lastRegister() { return ARM64Registers::sp; }
    
    static Q_DECL_CONSTEXPR FPRegisterID firstFPRegister() { return ARM64Registers::q0; }
    static Q_DECL_CONSTEXPR FPRegisterID lastFPRegister() { return ARM64Registers::q31; }

private:
    static Q_DECL_CONSTEXPR bool isSp(RegisterID reg) { return ARM64Registers::isSp(reg); }
    static Q_DECL_CONSTEXPR bool isZr(RegisterID reg) { return ARM64Registers::isZr(reg); }

public:
    ARM64Assembler()
        : m_indexOfLastWatchpoint(INT_MIN)
        , m_indexOfTailOfLastWatchpoint(INT_MIN)
    {
    }

    AssemblerBuffer& buffer() { return m_buffer; }

    // (HS, LO, HI, LS) -> (AE, B, A, BE)
    // (VS, VC) -> (O, NO)
    typedef enum {
        ConditionEQ,
        ConditionNE,
        ConditionHS, ConditionCS = ConditionHS,
        ConditionLO, ConditionCC = ConditionLO,
        ConditionMI,
        ConditionPL,
        ConditionVS,
        ConditionVC,
        ConditionHI,
        ConditionLS,
        ConditionGE,
        ConditionLT,
        ConditionGT,
        ConditionLE,
        ConditionAL,
        ConditionInvalid
    } Condition;

    static Condition invert(Condition cond)
    {
        return static_cast<Condition>(cond ^ 1);
    }

    typedef enum {
        LSL,
        LSR,
        ASR,
        ROR
    } ShiftType;

    typedef enum {
        UXTB,
        UXTH,
        UXTW,
        UXTX,
        SXTB,
        SXTH,
        SXTW,
        SXTX
    } ExtendType;

    enum SetFlags {
        DontSetFlags,
        S
    };

#define JUMP_ENUM_WITH_SIZE(index, value) (((value) << 4) | (index))
#define JUMP_ENUM_SIZE(jump) ((jump) >> 4)
    enum JumpType { JumpFixed = JUMP_ENUM_WITH_SIZE(0, 0),
        JumpNoCondition = JUMP_ENUM_WITH_SIZE(1, 1 * sizeof(uint32_t)),
        JumpCondition = JUMP_ENUM_WITH_SIZE(2, 2 * sizeof(uint32_t)),
        JumpCompareAndBranch = JUMP_ENUM_WITH_SIZE(3, 2 * sizeof(uint32_t)),
        JumpTestBit = JUMP_ENUM_WITH_SIZE(4, 2 * sizeof(uint32_t)),
        JumpNoConditionFixedSize = JUMP_ENUM_WITH_SIZE(5, 1 * sizeof(uint32_t)),
        JumpConditionFixedSize = JUMP_ENUM_WITH_SIZE(6, 2 * sizeof(uint32_t)),
        JumpCompareAndBranchFixedSize = JUMP_ENUM_WITH_SIZE(7, 2 * sizeof(uint32_t)),
        JumpTestBitFixedSize = JUMP_ENUM_WITH_SIZE(8, 2 * sizeof(uint32_t)),
    };
    enum JumpLinkType {
        LinkInvalid = JUMP_ENUM_WITH_SIZE(0, 0),
        LinkJumpNoCondition = JUMP_ENUM_WITH_SIZE(1, 1 * sizeof(uint32_t)),
        LinkJumpConditionDirect = JUMP_ENUM_WITH_SIZE(2, 1 * sizeof(uint32_t)),
        LinkJumpCondition = JUMP_ENUM_WITH_SIZE(3, 2 * sizeof(uint32_t)),
        LinkJumpCompareAndBranch = JUMP_ENUM_WITH_SIZE(4, 2 * sizeof(uint32_t)),
        LinkJumpCompareAndBranchDirect = JUMP_ENUM_WITH_SIZE(5, 1 * sizeof(uint32_t)),
        LinkJumpTestBit = JUMP_ENUM_WITH_SIZE(6, 2 * sizeof(uint32_t)),
        LinkJumpTestBitDirect = JUMP_ENUM_WITH_SIZE(7, 1 * sizeof(uint32_t)),
    };

    class LinkRecord {
    public:
        LinkRecord(intptr_t from, intptr_t to, JumpType type, Condition condition)
        {
            data.realTypes.m_from = from;
            data.realTypes.m_to = to;
            data.realTypes.m_type = type;
            data.realTypes.m_linkType = LinkInvalid;
            data.realTypes.m_condition = condition;
        }
        LinkRecord(intptr_t from, intptr_t to, JumpType type, Condition condition, bool is64Bit, RegisterID compareRegister)
        {
            data.realTypes.m_from = from;
            data.realTypes.m_to = to;
            data.realTypes.m_type = type;
            data.realTypes.m_linkType = LinkInvalid;
            data.realTypes.m_condition = condition;
            data.realTypes.m_is64Bit = is64Bit;
            data.realTypes.m_compareRegister = compareRegister;
        }
        LinkRecord(intptr_t from, intptr_t to, JumpType type, Condition condition, unsigned bitNumber, RegisterID compareRegister)
        {
            data.realTypes.m_from = from;
            data.realTypes.m_to = to;
            data.realTypes.m_type = type;
            data.realTypes.m_linkType = LinkInvalid;
            data.realTypes.m_condition = condition;
            data.realTypes.m_bitNumber = bitNumber;
            data.realTypes.m_compareRegister = compareRegister;
        }
        void operator=(const LinkRecord& other)
        {
            data.realTypes = other.data.realTypes;
        }
        intptr_t from() const { return data.realTypes.m_from; }
        void setFrom(intptr_t from) { data.realTypes.m_from = from; }
        intptr_t to() const { return data.realTypes.m_to; }
        JumpType type() const { return data.realTypes.m_type; }
        JumpLinkType linkType() const { return data.realTypes.m_linkType; }
        void setLinkType(JumpLinkType linkType) { ASSERT(data.realTypes.m_linkType == LinkInvalid); data.realTypes.m_linkType = linkType; }
        Condition condition() const { return data.realTypes.m_condition; }
        bool is64Bit() const { return data.realTypes.m_is64Bit; }
        unsigned bitNumber() const { return data.realTypes.m_bitNumber; }
        RegisterID compareRegister() const { return data.realTypes.m_compareRegister; }

    private:
        union {
            struct RealTypes {
                int64_t m_from : 48;
                int64_t m_to : 48;
                JumpType m_type : 8;
                JumpLinkType m_linkType : 8;
                Condition m_condition : 4;
                unsigned m_bitNumber : 6;
                RegisterID m_compareRegister : 6;
                bool m_is64Bit : 1;
            } realTypes;
        } data;
    };

    // bits(N) VFPExpandImm(bits(8) imm8);
    //
    // Encoding of floating point immediates is a litte complicated. Here's a
    // high level description:
    //     +/-m*2-n where m and n are integers, 16 <= m <= 31, 0 <= n <= 7
    // and the algirithm for expanding to a single precision float:
    //     return imm8<7>:NOT(imm8<6>):Replicate(imm8<6>,5):imm8<5:0>:Zeros(19);
    //
    // The trickiest bit is how the exponent is handled. The following table
    // may help clarify things a little:
    //     654
    //     100 01111100 124 -3 1020 01111111100
    //     101 01111101 125 -2 1021 01111111101
    //     110 01111110 126 -1 1022 01111111110
    //     111 01111111 127  0 1023 01111111111
    //     000 10000000 128  1 1024 10000000000
    //     001 10000001 129  2 1025 10000000001
    //     010 10000010 130  3 1026 10000000010
    //     011 10000011 131  4 1027 10000000011
    // The first column shows the bit pattern stored in bits 6-4 of the arm
    // encoded immediate. The second column shows the 8-bit IEEE 754 single
    // -precision exponent in binary, the third column shows the raw decimal
    // value. IEEE 754 single-precision numbers are stored with a bias of 127
    // to the exponent, so the fourth column shows the resulting exponent.
    // From this was can see that the exponent can be in the range -3..4,
    // which agrees with the high level description given above. The fifth
    // and sixth columns shows the value stored in a IEEE 754 double-precision
    // number to represent these exponents in decimal and binary, given the
    // bias of 1023.
    //
    // Ultimately, detecting doubles that can be encoded as immediates on arm
    // and encoding doubles is actually not too bad. A floating point value can
    // be encoded by retaining the sign bit, the low three bits of the exponent
    // and the high 4 bits of the mantissa. To validly be able to encode an
    // immediate the remainder of the mantissa must be zero, and the high part
    // of the exponent must match the top bit retained, bar the highest bit
    // which must be its inverse.
    static bool canEncodeFPImm(double d)
    {
        // Discard the sign bit, the low two bits of the exponent & the highest
        // four bits of the mantissa.
        uint64_t masked = bitwise_cast<uint64_t>(d) & 0x7fc0ffffffffffffull;
        return (masked == 0x3fc0000000000000ull) || (masked == 0x4000000000000000ull);
    }

    template<int datasize>
    static bool canEncodePImmOffset(int32_t offset)
    {
        return isValidScaledUImm12<datasize>(offset);
    }

    static bool canEncodeSImmOffset(int32_t offset)
    {
        return isValidSignedImm9(offset);
    }


    // Jump:
    //
    // A jump object is a reference to a jump instruction that has been planted
    // into the code buffer - it is typically used to link the jump, setting the
    // relative offset such that when executed it will jump to the desired
    // destination.
    template <typename LabelType>
    class Jump {
        template<class TemplateAssemblerType>
        friend class AbstractMacroAssembler;
        friend class Call;
        template <typename, template <typename> class> friend class LinkBufferBase;
    public:
        Jump()
        {
        }

        Jump(AssemblerLabel jmp, ARM64Assembler::JumpType type = ARM64Assembler::JumpNoCondition, ARM64Assembler::Condition condition = ARM64Assembler::ConditionInvalid)
            : m_label(jmp)
            , m_type(type)
            , m_condition(condition)
        {
        }

        Jump(AssemblerLabel jmp, ARM64Assembler::JumpType type, ARM64Assembler::Condition condition, bool is64Bit, ARM64Assembler::RegisterID compareRegister)
            : m_label(jmp)
            , m_type(type)
            , m_condition(condition)
            , m_is64Bit(is64Bit)
            , m_compareRegister(compareRegister)
        {
            ASSERT((type == ARM64Assembler::JumpCompareAndBranch) || (type == ARM64Assembler::JumpCompareAndBranchFixedSize));
        }

        Jump(AssemblerLabel jmp, ARM64Assembler::JumpType type, ARM64Assembler::Condition condition, unsigned bitNumber, ARM64Assembler::RegisterID compareRegister)
            : m_label(jmp)
            , m_type(type)
            , m_condition(condition)
            , m_bitNumber(bitNumber)
            , m_compareRegister(compareRegister)
        {
            ASSERT((type == ARM64Assembler::JumpTestBit) || (type == ARM64Assembler::JumpTestBitFixedSize));
        }

        LabelType label() const
        {
            LabelType result;
            result.m_label = m_label;
            return result;
        }

        void link(AbstractMacroAssembler<ARM64Assembler>* masm) const
        {
            if ((m_type == ARM64Assembler::JumpCompareAndBranch) || (m_type == ARM64Assembler::JumpCompareAndBranchFixedSize))
                masm->m_assembler.linkJump(m_label, masm->m_assembler.label(), m_type, m_condition, m_is64Bit, m_compareRegister);
            else if ((m_type == ARM64Assembler::JumpTestBit) || (m_type == ARM64Assembler::JumpTestBitFixedSize))
                masm->m_assembler.linkJump(m_label, masm->m_assembler.label(), m_type, m_condition, m_bitNumber, m_compareRegister);
            else
                masm->m_assembler.linkJump(m_label, masm->m_assembler.label(), m_type, m_condition);
        }

        void linkTo(LabelType label, AbstractMacroAssembler<ARM64Assembler>* masm) const
        {
            if ((m_type == ARM64Assembler::JumpCompareAndBranch) || (m_type == ARM64Assembler::JumpCompareAndBranchFixedSize))
                masm->m_assembler.linkJump(m_label, label.label(), m_type, m_condition, m_is64Bit, m_compareRegister);
            else if ((m_type == ARM64Assembler::JumpTestBit) || (m_type == ARM64Assembler::JumpTestBitFixedSize))
                masm->m_assembler.linkJump(m_label, label.label(), m_type, m_condition, m_bitNumber, m_compareRegister);
            else
                masm->m_assembler.linkJump(m_label, label.label(), m_type, m_condition);
        }

        bool isSet() const { return m_label.isSet(); }

    private:
        AssemblerLabel m_label;
        ARM64Assembler::JumpType m_type;
        ARM64Assembler::Condition m_condition;
        bool m_is64Bit;
        unsigned m_bitNumber;
        ARM64Assembler::RegisterID m_compareRegister;
    };

private:
    int encodeFPImm(double d)
    {
        ASSERT(canEncodeFPImm(d));
        uint64_t u64 = bitwise_cast<uint64_t>(d);
        return (static_cast<int>(u64 >> 56) & 0x80) | (static_cast<int>(u64 >> 48) & 0x7f);
    }

    template<int datasize>
    int encodeShiftAmount(int amount)
    {
        ASSERT(!amount || datasize == (8 << amount));
        return amount;
    }

    template<int datasize>
    static int encodePositiveImmediate(unsigned pimm)
    {
        ASSERT(!(pimm & ((datasize / 8) - 1)));
        return pimm / (datasize / 8);
    }

    enum Datasize {
        Datasize_32,
        Datasize_64,
        Datasize_64_top,
        Datasize_16
    };

    enum MemOpSize {
        MemOpSize_8_or_128,
        MemOpSize_16,
        MemOpSize_32,
        MemOpSize_64,
    };

    enum BranchType {
        BranchType_JMP,
        BranchType_CALL,
        BranchType_RET
    };

    enum AddOp {
        AddOp_ADD,
        AddOp_SUB
    };

    enum BitfieldOp {
        BitfieldOp_SBFM,
        BitfieldOp_BFM,
        BitfieldOp_UBFM
    };

    enum DataOp1Source {
        DataOp_RBIT,
        DataOp_REV16,
        DataOp_REV32,
        DataOp_REV64,
        DataOp_CLZ,
        DataOp_CLS
    };

    enum DataOp2Source {
        DataOp_UDIV = 2,
        DataOp_SDIV = 3,
        DataOp_LSLV = 8,
        DataOp_LSRV = 9,
        DataOp_ASRV = 10,
        DataOp_RORV = 11
    };

    enum DataOp3Source {
        DataOp_MADD = 0,
        DataOp_MSUB = 1,
        DataOp_SMADDL = 2,
        DataOp_SMSUBL = 3,
        DataOp_SMULH = 4,
        DataOp_UMADDL = 10,
        DataOp_UMSUBL = 11,
        DataOp_UMULH = 12
    };

    enum ExcepnOp {
        ExcepnOp_EXCEPTION = 0,
        ExcepnOp_BREAKPOINT = 1,
        ExcepnOp_HALT = 2,
        ExcepnOp_DCPS = 5
    };

    enum FPCmpOp {
        FPCmpOp_FCMP = 0x00,
        FPCmpOp_FCMP0 = 0x08,
        FPCmpOp_FCMPE = 0x10,
        FPCmpOp_FCMPE0 = 0x18
    };

    enum FPCondCmpOp {
        FPCondCmpOp_FCMP,
        FPCondCmpOp_FCMPE
    };

    enum FPDataOp1Source {
        FPDataOp_FMOV = 0,
        FPDataOp_FABS = 1,
        FPDataOp_FNEG = 2,
        FPDataOp_FSQRT = 3,
        FPDataOp_FCVT_toSingle = 4,
        FPDataOp_FCVT_toDouble = 5,
        FPDataOp_FCVT_toHalf = 7,
        FPDataOp_FRINTN = 8,
        FPDataOp_FRINTP = 9,
        FPDataOp_FRINTM = 10,
        FPDataOp_FRINTZ = 11,
        FPDataOp_FRINTA = 12,
        FPDataOp_FRINTX = 14,
        FPDataOp_FRINTI = 15
    };

    enum FPDataOp2Source {
        FPDataOp_FMUL,
        FPDataOp_FDIV,
        FPDataOp_FADD,
        FPDataOp_FSUB,
        FPDataOp_FMAX,
        FPDataOp_FMIN,
        FPDataOp_FMAXNM,
        FPDataOp_FMINNM,
        FPDataOp_FNMUL
    };

    enum SIMD3Same {
        SIMD_LogicalOp_AND = 0x03
    };

    enum FPIntConvOp {
        FPIntConvOp_FCVTNS = 0x00,
        FPIntConvOp_FCVTNU = 0x01,
        FPIntConvOp_SCVTF = 0x02,
        FPIntConvOp_UCVTF = 0x03,
        FPIntConvOp_FCVTAS = 0x04,
        FPIntConvOp_FCVTAU = 0x05,
        FPIntConvOp_FMOV_QtoX = 0x06,
        FPIntConvOp_FMOV_XtoQ = 0x07,
        FPIntConvOp_FCVTPS = 0x08,
        FPIntConvOp_FCVTPU = 0x09,
        FPIntConvOp_FMOV_QtoX_top = 0x0e,
        FPIntConvOp_FMOV_XtoQ_top = 0x0f,
        FPIntConvOp_FCVTMS = 0x10,
        FPIntConvOp_FCVTMU = 0x11,
        FPIntConvOp_FCVTZS = 0x18,
        FPIntConvOp_FCVTZU = 0x19,
    };

    enum LogicalOp {
        LogicalOp_AND,
        LogicalOp_ORR,
        LogicalOp_EOR,
        LogicalOp_ANDS
    };

    enum MemOp {
        MemOp_STORE,
        MemOp_LOAD,
        MemOp_STORE_V128, 
        MemOp_LOAD_V128,
        MemOp_PREFETCH = 2, // size must be 3
        MemOp_LOAD_signed64 = 2, // size may be 0, 1 or 2
        MemOp_LOAD_signed32 = 3 // size may be 0 or 1
    };

    enum MemPairOpSize {
        MemPairOp_32 = 0,
        MemPairOp_LoadSigned_32 = 1,
        MemPairOp_64 = 2,

        MemPairOp_V32 = MemPairOp_32,
        MemPairOp_V64 = 1,
        MemPairOp_V128 = 2
    };

    enum MoveWideOp {
        MoveWideOp_N = 0,
        MoveWideOp_Z = 2,
        MoveWideOp_K = 3 
    };

    enum LdrLiteralOp {
        LdrLiteralOp_32BIT = 0,
        LdrLiteralOp_64BIT = 1,
        LdrLiteralOp_LDRSW = 2,
        LdrLiteralOp_128BIT = 2
    };

    static unsigned memPairOffsetShift(bool V, MemPairOpSize size)
    {
        // return the log2 of the size in bytes, e.g. 64 bit size returns 3
        if (V)
            return size + 2;
        return (size >> 1) + 2;
    }

public:
    // Integer Instructions:

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void adc(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(addSubtractWithCarry(DATASIZE, AddOp_ADD, setFlags, rm, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void add(RegisterID rd, RegisterID rn, UInt12 imm12, int shift = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!shift || shift == 12);
        insn(addSubtractImmediate(DATASIZE, AddOp_ADD, setFlags, shift == 12, imm12, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void add(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        add<datasize, setFlags>(rd, rn, rm, LSL, 0);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void add(RegisterID rd, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_DATASIZE();
        insn(addSubtractExtendedRegister(DATASIZE, AddOp_ADD, setFlags, rm, extend, amount, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void add(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        if (isSp(rd) || isSp(rn)) {
            ASSERT(shift == LSL);
            ASSERT(!isSp(rm));
            add<datasize, setFlags>(rd, rn, rm, UXTX, amount);
        } else
            insn(addSubtractShiftedRegister(DATASIZE, AddOp_ADD, setFlags, shift, rm, amount, rn, rd));
    }

    ALWAYS_INLINE void adr(RegisterID rd, int offset)
    {
        insn(pcRelative(false, offset, rd));
    }

    ALWAYS_INLINE void adrp(RegisterID rd, int offset)
    {
        ASSERT(!(offset & 0xfff));
        insn(pcRelative(true, offset >> 12, rd));
        nopCortexA53Fix843419();
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void and_(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        and_<datasize, setFlags>(rd, rn, rm, LSL, 0);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void and_(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        insn(logicalShiftedRegister(DATASIZE, setFlags ? LogicalOp_ANDS : LogicalOp_AND, shift, false, rm, amount, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void and_(RegisterID rd, RegisterID rn, LogicalImmediate imm)
    {
        CHECK_DATASIZE();
        insn(logicalImmediate(DATASIZE, setFlags ? LogicalOp_ANDS : LogicalOp_AND, imm.value(), rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void asr(RegisterID rd, RegisterID rn, int shift)
    {
        ASSERT(shift < datasize);
        sbfm<datasize>(rd, rn, shift, datasize - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void asr(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        asrv<datasize>(rd, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void asrv(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(dataProcessing2Source(DATASIZE, rm, DataOp_ASRV, rn, rd));
    }

    ALWAYS_INLINE void b(int32_t offset = 0)
    {
        ASSERT(!(offset & 3));
        offset >>= 2;
        ASSERT(offset == (offset << 6) >> 6);
        insn(unconditionalBranchImmediate(false, offset));
    }

    ALWAYS_INLINE void b_cond(Condition cond, int32_t offset = 0)
    {
        ASSERT(!(offset & 3));
        offset >>= 2;
        ASSERT(offset == (offset << 13) >> 13);
        insn(conditionalBranchImmediate(offset, cond));
    }

    template<int datasize>
    ALWAYS_INLINE void bfi(RegisterID rd, RegisterID rn, int lsb, int width)
    {
        bfm<datasize>(rd, rn, (datasize - lsb) & (datasize - 1), width - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void bfm(RegisterID rd, RegisterID rn, int immr, int imms)
    {
        CHECK_DATASIZE();
        insn(bitfield(DATASIZE, BitfieldOp_BFM, immr, imms, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void bfxil(RegisterID rd, RegisterID rn, int lsb, int width)
    {
        bfm<datasize>(rd, rn, lsb, lsb + width - 1);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void bic(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        bic<datasize, setFlags>(rd, rn, rm, LSL, 0);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void bic(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        insn(logicalShiftedRegister(DATASIZE, setFlags ? LogicalOp_ANDS : LogicalOp_AND, shift, true, rm, amount, rn, rd));
    }

    ALWAYS_INLINE void bl(int32_t offset = 0)
    {
        ASSERT(!(offset & 3));
        offset >>= 2;
        insn(unconditionalBranchImmediate(true, offset));
    }

    ALWAYS_INLINE void blr(RegisterID rn)
    {
        insn(unconditionalBranchRegister(BranchType_CALL, rn));
    }

    ALWAYS_INLINE void br(RegisterID rn)
    {
        insn(unconditionalBranchRegister(BranchType_JMP, rn));
    }

    ALWAYS_INLINE void brk(uint16_t imm)
    {
        insn(excepnGeneration(ExcepnOp_BREAKPOINT, imm, 0));
    }
    
    template<int datasize>
    ALWAYS_INLINE void cbnz(RegisterID rt, int32_t offset = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!(offset & 3));
        offset >>= 2;
        insn(compareAndBranchImmediate(DATASIZE, true, offset, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void cbz(RegisterID rt, int32_t offset = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!(offset & 3));
        offset >>= 2;
        insn(compareAndBranchImmediate(DATASIZE, false, offset, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ccmn(RegisterID rn, RegisterID rm, int nzcv, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalCompareRegister(DATASIZE, AddOp_ADD, rm, cond, rn, nzcv));
    }

    template<int datasize>
    ALWAYS_INLINE void ccmn(RegisterID rn, UInt5 imm, int nzcv, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalCompareImmediate(DATASIZE, AddOp_ADD, imm, cond, rn, nzcv));
    }

    template<int datasize>
    ALWAYS_INLINE void ccmp(RegisterID rn, RegisterID rm, int nzcv, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalCompareRegister(DATASIZE, AddOp_SUB, rm, cond, rn, nzcv));
    }

    template<int datasize>
    ALWAYS_INLINE void ccmp(RegisterID rn, UInt5 imm, int nzcv, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalCompareImmediate(DATASIZE, AddOp_SUB, imm, cond, rn, nzcv));
    }

    template<int datasize>
    ALWAYS_INLINE void cinc(RegisterID rd, RegisterID rn, Condition cond)
    {
        csinc<datasize>(rd, rn, rn, invert(cond));
    }

    template<int datasize>
    ALWAYS_INLINE void cinv(RegisterID rd, RegisterID rn, Condition cond)
    {
        csinv<datasize>(rd, rn, rn, invert(cond));
    }

    template<int datasize>
    ALWAYS_INLINE void cls(RegisterID rd, RegisterID rn)
    {
        CHECK_DATASIZE();
        insn(dataProcessing1Source(DATASIZE, DataOp_CLS, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void clz(RegisterID rd, RegisterID rn)
    {
        CHECK_DATASIZE();
        insn(dataProcessing1Source(DATASIZE, DataOp_CLZ, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void cmn(RegisterID rn, UInt12 imm12, int shift = 0)
    {
        add<datasize, S>(ARM64Registers::zr, rn, imm12, shift);
    }

    template<int datasize>
    ALWAYS_INLINE void cmn(RegisterID rn, RegisterID rm)
    {
        add<datasize, S>(ARM64Registers::zr, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void cmn(RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        add<datasize, S>(ARM64Registers::zr, rn, rm, extend, amount);
    }

    template<int datasize>
    ALWAYS_INLINE void cmn(RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        add<datasize, S>(ARM64Registers::zr, rn, rm, shift, amount);
    }

    template<int datasize>
    ALWAYS_INLINE void cmp(RegisterID rn, UInt12 imm12, int shift = 0)
    {
        sub<datasize, S>(ARM64Registers::zr, rn, imm12, shift);
    }

    template<int datasize>
    ALWAYS_INLINE void cmp(RegisterID rn, RegisterID rm)
    {
        sub<datasize, S>(ARM64Registers::zr, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void cmp(RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        sub<datasize, S>(ARM64Registers::zr, rn, rm, extend, amount);
    }

    template<int datasize>
    ALWAYS_INLINE void cmp(RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        sub<datasize, S>(ARM64Registers::zr, rn, rm, shift, amount);
    }

    template<int datasize>
    ALWAYS_INLINE void cneg(RegisterID rd, RegisterID rn, Condition cond)
    {
        csneg<datasize>(rd, rn, rn, invert(cond));
    }

    template<int datasize>
    ALWAYS_INLINE void csel(RegisterID rd, RegisterID rn, RegisterID rm, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalSelect(DATASIZE, false, rm, cond, false, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void cset(RegisterID rd, Condition cond)
    {
        csinc<datasize>(rd, ARM64Registers::zr, ARM64Registers::zr, invert(cond));
    }

    template<int datasize>
    ALWAYS_INLINE void csetm(RegisterID rd, Condition cond)
    {
        csinv<datasize>(rd, ARM64Registers::zr, ARM64Registers::zr, invert(cond));
    }

    template<int datasize>
    ALWAYS_INLINE void csinc(RegisterID rd, RegisterID rn, RegisterID rm, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalSelect(DATASIZE, false, rm, cond, true, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void csinv(RegisterID rd, RegisterID rn, RegisterID rm, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalSelect(DATASIZE, true, rm, cond, false, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void csneg(RegisterID rd, RegisterID rn, RegisterID rm, Condition cond)
    {
        CHECK_DATASIZE();
        insn(conditionalSelect(DATASIZE, true, rm, cond, true, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void eon(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        eon<datasize>(rd, rn, rm, LSL, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void eon(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        insn(logicalShiftedRegister(DATASIZE, LogicalOp_EOR, shift, true, rm, amount, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void eor(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        eor<datasize>(rd, rn, rm, LSL, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void eor(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        insn(logicalShiftedRegister(DATASIZE, LogicalOp_EOR, shift, false, rm, amount, rn, rd));
    }
    
    template<int datasize>
    ALWAYS_INLINE void eor(RegisterID rd, RegisterID rn, LogicalImmediate imm)
    {
        CHECK_DATASIZE();
        insn(logicalImmediate(DATASIZE, LogicalOp_EOR, imm.value(), rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void extr(RegisterID rd, RegisterID rn, RegisterID rm, int lsb)
    {
        CHECK_DATASIZE();
        insn(extract(DATASIZE, rm, lsb, rn, rd));
    }

    ALWAYS_INLINE void hint(int imm)
    {
        insn(hintPseudo(imm));
    }

    ALWAYS_INLINE void hlt(uint16_t imm)
    {
        insn(excepnGeneration(ExcepnOp_HALT, imm, 0));
    }

    template<int datasize>
    ALWAYS_INLINE void ldp(RegisterID rt, RegisterID rt2, RegisterID rn, PairPostIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPairPostIndex(MEMPAIROPSIZE_INT(datasize), false, MemOp_LOAD, simm, rn, rt, rt2));
    }

    template<int datasize>
    ALWAYS_INLINE void ldp(RegisterID rt, RegisterID rt2, RegisterID rn, PairPreIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPairPreIndex(MEMPAIROPSIZE_INT(datasize), false, MemOp_LOAD, simm, rn, rt, rt2));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        ldr<datasize>(rt, rn, rm, UXTX, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterRegisterOffset(MEMOPSIZE, false, MemOp_LOAD, rm, extend, encodeShiftAmount<datasize>(amount), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnsignedImmediate(MEMOPSIZE, false, MemOp_LOAD, encodePositiveImmediate<datasize>(pimm), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPostIndex(MEMOPSIZE, false, MemOp_LOAD, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPreIndex(MEMOPSIZE, false, MemOp_LOAD, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr_literal(RegisterID rt, int offset = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!(offset & 3));
        insn(loadRegisterLiteral(datasize == 64 ? LdrLiteralOp_64BIT : LdrLiteralOp_32BIT, false, offset >> 2, rt));
    }

    ALWAYS_INLINE void ldrb(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        // Not calling the 5 argument form of ldrb, since is amount is ommitted S is false.
        insn(loadStoreRegisterRegisterOffset(MemOpSize_8_or_128, false, MemOp_LOAD, rm, UXTX, false, rn, rt));
    }

    ALWAYS_INLINE void ldrb(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        ASSERT_UNUSED(amount, !amount);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_8_or_128, false, MemOp_LOAD, rm, extend, true, rn, rt));
    }

    ALWAYS_INLINE void ldrb(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_8_or_128, false, MemOp_LOAD, encodePositiveImmediate<8>(pimm), rn, rt));
    }

    ALWAYS_INLINE void ldrb(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        insn(loadStoreRegisterPostIndex(MemOpSize_8_or_128, false, MemOp_LOAD, simm, rn, rt));
    }

    ALWAYS_INLINE void ldrb(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        insn(loadStoreRegisterPreIndex(MemOpSize_8_or_128, false, MemOp_LOAD, simm, rn, rt));
    }

    ALWAYS_INLINE void ldrh(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        ldrh(rt, rn, rm, UXTX, 0);
    }

    ALWAYS_INLINE void ldrh(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        ASSERT(!amount || amount == 1);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_16, false, MemOp_LOAD, rm, extend, amount == 1, rn, rt));
    }

    ALWAYS_INLINE void ldrh(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_16, false, MemOp_LOAD, encodePositiveImmediate<16>(pimm), rn, rt));
    }

    ALWAYS_INLINE void ldrh(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        insn(loadStoreRegisterPostIndex(MemOpSize_16, false, MemOp_LOAD, simm, rn, rt));
    }

    ALWAYS_INLINE void ldrh(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        insn(loadStoreRegisterPreIndex(MemOpSize_16, false, MemOp_LOAD, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsb(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        // Not calling the 5 argument form of ldrsb, since is amount is ommitted S is false.
        insn(loadStoreRegisterRegisterOffset(MemOpSize_8_or_128, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, rm, UXTX, false, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsb(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_DATASIZE();
        ASSERT_UNUSED(amount, !amount);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_8_or_128, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, rm, extend, true, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsb(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_8_or_128, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, encodePositiveImmediate<8>(pimm), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsb(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPostIndex(MemOpSize_8_or_128, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsb(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPreIndex(MemOpSize_8_or_128, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsh(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        ldrsh<datasize>(rt, rn, rm, UXTX, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsh(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_DATASIZE();
        ASSERT(!amount || amount == 1);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_16, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, rm, extend, amount == 1, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsh(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_16, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, encodePositiveImmediate<16>(pimm), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsh(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPostIndex(MemOpSize_16, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldrsh(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPreIndex(MemOpSize_16, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, simm, rn, rt));
    }

    ALWAYS_INLINE void ldrsw(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        ldrsw(rt, rn, rm, UXTX, 0);
    }

    ALWAYS_INLINE void ldrsw(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        ASSERT(!amount || amount == 2);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_32, false, MemOp_LOAD_signed64, rm, extend, amount == 2, rn, rt));
    }

    ALWAYS_INLINE void ldrsw(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_32, false, MemOp_LOAD_signed64, encodePositiveImmediate<32>(pimm), rn, rt));
    }

    ALWAYS_INLINE void ldrsw(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        insn(loadStoreRegisterPostIndex(MemOpSize_32, false, MemOp_LOAD_signed64, simm, rn, rt));
    }

    ALWAYS_INLINE void ldrsw(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        insn(loadStoreRegisterPreIndex(MemOpSize_32, false, MemOp_LOAD_signed64, simm, rn, rt));
    }

    ALWAYS_INLINE void ldrsw_literal(RegisterID rt, int offset = 0)
    {
        ASSERT(!(offset & 3));
        insn(loadRegisterLiteral(LdrLiteralOp_LDRSW, false, offset >> 2, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldur(RegisterID rt, RegisterID rn, int simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnscaledImmediate(MEMOPSIZE, false, MemOp_LOAD, simm, rn, rt));
    }

    ALWAYS_INLINE void ldurb(RegisterID rt, RegisterID rn, int simm)
    {
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_8_or_128, false, MemOp_LOAD, simm, rn, rt));
    }

    ALWAYS_INLINE void ldurh(RegisterID rt, RegisterID rn, int simm)
    {
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_16, false, MemOp_LOAD, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldursb(RegisterID rt, RegisterID rn, int simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_8_or_128, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldursh(RegisterID rt, RegisterID rn, int simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_16, false, (datasize == 64) ? MemOp_LOAD_signed64 : MemOp_LOAD_signed32, simm, rn, rt));
    }

    ALWAYS_INLINE void ldursw(RegisterID rt, RegisterID rn, int simm)
    {
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_32, false, MemOp_LOAD_signed64, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void lsl(RegisterID rd, RegisterID rn, int shift)
    {
        ASSERT(shift < datasize);
        ubfm<datasize>(rd, rn, (datasize - shift) & (datasize - 1), datasize - 1 - shift);
    }

    template<int datasize>
    ALWAYS_INLINE void lsl(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        lslv<datasize>(rd, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void lslv(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(dataProcessing2Source(DATASIZE, rm, DataOp_LSLV, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void lsr(RegisterID rd, RegisterID rn, int shift)
    {
        ASSERT(shift < datasize);
        ubfm<datasize>(rd, rn, shift, datasize - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void lsr(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        lsrv<datasize>(rd, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void lsrv(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(dataProcessing2Source(DATASIZE, rm, DataOp_LSRV, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void madd(RegisterID rd, RegisterID rn, RegisterID rm, RegisterID ra)
    {
        CHECK_DATASIZE();
        nopCortexA53Fix835769<datasize>();
        insn(dataProcessing3Source(DATASIZE, DataOp_MADD, rm, ra, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void mneg(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        msub<datasize>(rd, rn, rm, ARM64Registers::zr);
    }

    template<int datasize>
    ALWAYS_INLINE void mov(RegisterID rd, RegisterID rm)
    {
        if (isSp(rd) || isSp(rm))
            add<datasize>(rd, rm, UInt12(0));
        else
            orr<datasize>(rd, ARM64Registers::zr, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void movi(RegisterID rd, LogicalImmediate imm)
    {
        orr<datasize>(rd, ARM64Registers::zr, imm);
    }

    template<int datasize>
    ALWAYS_INLINE void movk(RegisterID rd, uint16_t value, int shift = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!(shift & 0xf));
        insn(moveWideImediate(DATASIZE, MoveWideOp_K, shift >> 4, value, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void movn(RegisterID rd, uint16_t value, int shift = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!(shift & 0xf));
        insn(moveWideImediate(DATASIZE, MoveWideOp_N, shift >> 4, value, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void movz(RegisterID rd, uint16_t value, int shift = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!(shift & 0xf));
        insn(moveWideImediate(DATASIZE, MoveWideOp_Z, shift >> 4, value, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void msub(RegisterID rd, RegisterID rn, RegisterID rm, RegisterID ra)
    {
        CHECK_DATASIZE();
        nopCortexA53Fix835769<datasize>();
        insn(dataProcessing3Source(DATASIZE, DataOp_MSUB, rm, ra, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void mul(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        madd<datasize>(rd, rn, rm, ARM64Registers::zr);
    }

    template<int datasize>
    ALWAYS_INLINE void mvn(RegisterID rd, RegisterID rm)
    {
        orn<datasize>(rd, ARM64Registers::zr, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void mvn(RegisterID rd, RegisterID rm, ShiftType shift, int amount)
    {
        orn<datasize>(rd, ARM64Registers::zr, rm, shift, amount);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void neg(RegisterID rd, RegisterID rm)
    {
        sub<datasize, setFlags>(rd, ARM64Registers::zr, rm);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void neg(RegisterID rd, RegisterID rm, ShiftType shift, int amount)
    {
        sub<datasize, setFlags>(rd, ARM64Registers::zr, rm, shift, amount);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void ngc(RegisterID rd, RegisterID rm)
    {
        sbc<datasize, setFlags>(rd, ARM64Registers::zr, rm);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void ngc(RegisterID rd, RegisterID rm, ShiftType shift, int amount)
    {
        sbc<datasize, setFlags>(rd, ARM64Registers::zr, rm, shift, amount);
    }

    ALWAYS_INLINE void nop()
    {
        insn(nopPseudo());
    }
    
    static void fillNops(void* base, size_t size)
    {
        RELEASE_ASSERT(!(size % sizeof(int32_t)));
        size_t n = size / sizeof(int32_t);
        for (int32_t* ptr = static_cast<int32_t*>(base); n--;)
            *ptr++ = nopPseudo();
    }
    
    ALWAYS_INLINE void dmbSY()
    {
        insn(0xd5033fbf);
    }

    template<int datasize>
    ALWAYS_INLINE void orn(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        orn<datasize>(rd, rn, rm, LSL, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void orn(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        insn(logicalShiftedRegister(DATASIZE, LogicalOp_ORR, shift, true, rm, amount, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void orr(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        orr<datasize>(rd, rn, rm, LSL, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void orr(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        insn(logicalShiftedRegister(DATASIZE, LogicalOp_ORR, shift, false, rm, amount, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void orr(RegisterID rd, RegisterID rn, LogicalImmediate imm)
    {
        CHECK_DATASIZE();
        insn(logicalImmediate(DATASIZE, LogicalOp_ORR, imm.value(), rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void rbit(RegisterID rd, RegisterID rn)
    {
        CHECK_DATASIZE();
        insn(dataProcessing1Source(DATASIZE, DataOp_RBIT, rn, rd));
    }

    ALWAYS_INLINE void ret(RegisterID rn = ARM64Registers::lr)
    {
        insn(unconditionalBranchRegister(BranchType_RET, rn));
    }

    template<int datasize>
    ALWAYS_INLINE void rev(RegisterID rd, RegisterID rn)
    {
        CHECK_DATASIZE();
        if (datasize == 32) // 'rev' mnemonic means REV32 or REV64 depending on the operand width.
            insn(dataProcessing1Source(Datasize_32, DataOp_REV32, rn, rd));
        else
            insn(dataProcessing1Source(Datasize_64, DataOp_REV64, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void rev16(RegisterID rd, RegisterID rn)
    {
        CHECK_DATASIZE();
        insn(dataProcessing1Source(DATASIZE, DataOp_REV16, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void rev32(RegisterID rd, RegisterID rn)
    {
        ASSERT(datasize == 64); // 'rev32' only valid with 64-bit operands.
        insn(dataProcessing1Source(Datasize_64, DataOp_REV32, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void ror(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        rorv<datasize>(rd, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void ror(RegisterID rd, RegisterID rs, int shift)
    {
        extr<datasize>(rd, rs, rs, shift);
    }

    template<int datasize>
    ALWAYS_INLINE void rorv(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(dataProcessing2Source(DATASIZE, rm, DataOp_RORV, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void sbc(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(addSubtractWithCarry(DATASIZE, AddOp_SUB, setFlags, rm, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void sbfiz(RegisterID rd, RegisterID rn, int lsb, int width)
    {
        sbfm<datasize>(rd, rn, (datasize - lsb) & (datasize - 1), width - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void sbfm(RegisterID rd, RegisterID rn, int immr, int imms)
    {
        CHECK_DATASIZE();
        insn(bitfield(DATASIZE, BitfieldOp_SBFM, immr, imms, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void sbfx(RegisterID rd, RegisterID rn, int lsb, int width)
    {
        sbfm<datasize>(rd, rn, lsb, lsb + width - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void sdiv(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(dataProcessing2Source(DATASIZE, rm, DataOp_SDIV, rn, rd));
    }

    ALWAYS_INLINE void smaddl(RegisterID rd, RegisterID rn, RegisterID rm, RegisterID ra)
    {
        nopCortexA53Fix835769<64>();
        insn(dataProcessing3Source(Datasize_64, DataOp_SMADDL, rm, ra, rn, rd));
    }

    ALWAYS_INLINE void smnegl(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        smsubl(rd, rn, rm, ARM64Registers::zr);
    }

    ALWAYS_INLINE void smsubl(RegisterID rd, RegisterID rn, RegisterID rm, RegisterID ra)
    {
        nopCortexA53Fix835769<64>();
        insn(dataProcessing3Source(Datasize_64, DataOp_SMSUBL, rm, ra, rn, rd));
    }

    ALWAYS_INLINE void smulh(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        insn(dataProcessing3Source(Datasize_64, DataOp_SMULH, rm, ARM64Registers::zr, rn, rd));
    }

    ALWAYS_INLINE void smull(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        smaddl(rd, rn, rm, ARM64Registers::zr);
    }

    template<int datasize>
    ALWAYS_INLINE void stp(RegisterID rt, RegisterID rt2, RegisterID rn, PairPostIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPairPostIndex(MEMPAIROPSIZE_INT(datasize), false, MemOp_STORE, simm, rn, rt, rt2));
    }

    template<int datasize>
    ALWAYS_INLINE void stp(RegisterID rt, RegisterID rt2, RegisterID rn, PairPreIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPairPreIndex(MEMPAIROPSIZE_INT(datasize), false, MemOp_STORE, simm, rn, rt, rt2));
    }

    template<int datasize>
    ALWAYS_INLINE void stp(RegisterID rt, RegisterID rt2, RegisterID rn, unsigned pimm = 0)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPairOffset(MEMPAIROPSIZE_INT(datasize), false, MemOp_STORE, pimm, rn, rt, rt2));
    }

    template<int datasize>
    ALWAYS_INLINE void str(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        str<datasize>(rt, rn, rm, UXTX, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void str(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterRegisterOffset(MEMOPSIZE, false, MemOp_STORE, rm, extend, encodeShiftAmount<datasize>(amount), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void str(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnsignedImmediate(MEMOPSIZE, false, MemOp_STORE, encodePositiveImmediate<datasize>(pimm), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void str(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPostIndex(MEMOPSIZE, false, MemOp_STORE, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void str(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterPreIndex(MEMOPSIZE, false, MemOp_STORE, simm, rn, rt));
    }

    ALWAYS_INLINE void strb(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        // Not calling the 5 argument form of strb, since is amount is ommitted S is false.
        insn(loadStoreRegisterRegisterOffset(MemOpSize_8_or_128, false, MemOp_STORE, rm, UXTX, false, rn, rt));
    }

    ALWAYS_INLINE void strb(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        ASSERT_UNUSED(amount, !amount);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_8_or_128, false, MemOp_STORE, rm, extend, true, rn, rt));
    }

    ALWAYS_INLINE void strb(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_8_or_128, false, MemOp_STORE, encodePositiveImmediate<8>(pimm), rn, rt));
    }

    ALWAYS_INLINE void strb(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        insn(loadStoreRegisterPostIndex(MemOpSize_8_or_128, false, MemOp_STORE, simm, rn, rt));
    }

    ALWAYS_INLINE void strb(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        insn(loadStoreRegisterPreIndex(MemOpSize_8_or_128, false, MemOp_STORE, simm, rn, rt));
    }

    ALWAYS_INLINE void strh(RegisterID rt, RegisterID rn, RegisterID rm)
    {
        strh(rt, rn, rm, UXTX, 0);
    }

    ALWAYS_INLINE void strh(RegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        ASSERT(!amount || amount == 1);
        insn(loadStoreRegisterRegisterOffset(MemOpSize_16, false, MemOp_STORE, rm, extend, amount == 1, rn, rt));
    }

    ALWAYS_INLINE void strh(RegisterID rt, RegisterID rn, unsigned pimm)
    {
        insn(loadStoreRegisterUnsignedImmediate(MemOpSize_16, false, MemOp_STORE, encodePositiveImmediate<16>(pimm), rn, rt));
    }

    ALWAYS_INLINE void strh(RegisterID rt, RegisterID rn, PostIndex simm)
    {
        insn(loadStoreRegisterPostIndex(MemOpSize_16, false, MemOp_STORE, simm, rn, rt));
    }

    ALWAYS_INLINE void strh(RegisterID rt, RegisterID rn, PreIndex simm)
    {
        insn(loadStoreRegisterPreIndex(MemOpSize_16, false, MemOp_STORE, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void stur(RegisterID rt, RegisterID rn, int simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnscaledImmediate(MEMOPSIZE, false, MemOp_STORE, simm, rn, rt));
    }

    ALWAYS_INLINE void sturb(RegisterID rt, RegisterID rn, int simm)
    {
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_8_or_128, false, MemOp_STORE, simm, rn, rt));
    }

    ALWAYS_INLINE void sturh(RegisterID rt, RegisterID rn, int simm)
    {
        insn(loadStoreRegisterUnscaledImmediate(MemOpSize_16, false, MemOp_STORE, simm, rn, rt));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void sub(RegisterID rd, RegisterID rn, UInt12 imm12, int shift = 0)
    {
        CHECK_DATASIZE();
        ASSERT(!shift || shift == 12);
        insn(addSubtractImmediate(DATASIZE, AddOp_SUB, setFlags, shift == 12, imm12, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void sub(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        ASSERT_WITH_MESSAGE(!isSp(rd) || setFlags == DontSetFlags, "SUBS with shifted register does not support SP for Xd, it uses XZR for the register 31. SUBS with extended register support SP for Xd, but only if SetFlag is not used, otherwise register 31 is Xd.");
        ASSERT_WITH_MESSAGE(!isSp(rm), "No encoding of SUBS supports SP for the third operand.");

        if (isSp(rd) || isSp(rn))
            sub<datasize, setFlags>(rd, rn, rm, UXTX, 0);
        else
            sub<datasize, setFlags>(rd, rn, rm, LSL, 0);
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void sub(RegisterID rd, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_DATASIZE();
        insn(addSubtractExtendedRegister(DATASIZE, AddOp_SUB, setFlags, rm, extend, amount, rn, rd));
    }

    template<int datasize, SetFlags setFlags = DontSetFlags>
    ALWAYS_INLINE void sub(RegisterID rd, RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        CHECK_DATASIZE();
        ASSERT(!isSp(rd) && !isSp(rn) && !isSp(rm));
        insn(addSubtractShiftedRegister(DATASIZE, AddOp_SUB, setFlags, shift, rm, amount, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void sxtb(RegisterID rd, RegisterID rn)
    {
        sbfm<datasize>(rd, rn, 0, 7);
    }

    template<int datasize>
    ALWAYS_INLINE void sxth(RegisterID rd, RegisterID rn)
    {
        sbfm<datasize>(rd, rn, 0, 15);
    }

    ALWAYS_INLINE void sxtw(RegisterID rd, RegisterID rn)
    {
        sbfm<64>(rd, rn, 0, 31);
    }

    ALWAYS_INLINE void tbz(RegisterID rt, int imm, int offset = 0)
    {
        ASSERT(!(offset & 3));
        offset >>= 2;
        insn(testAndBranchImmediate(false, imm, offset, rt));
    }

    ALWAYS_INLINE void tbnz(RegisterID rt, int imm, int offset = 0)
    {
        ASSERT(!(offset & 3));
        offset >>= 2;
        insn(testAndBranchImmediate(true, imm, offset, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void tst(RegisterID rn, RegisterID rm)
    {
        and_<datasize, S>(ARM64Registers::zr, rn, rm);
    }

    template<int datasize>
    ALWAYS_INLINE void tst(RegisterID rn, RegisterID rm, ShiftType shift, int amount)
    {
        and_<datasize, S>(ARM64Registers::zr, rn, rm, shift, amount);
    }

    template<int datasize>
    ALWAYS_INLINE void tst(RegisterID rn, LogicalImmediate imm)
    {
        and_<datasize, S>(ARM64Registers::zr, rn, imm);
    }

    template<int datasize>
    ALWAYS_INLINE void ubfiz(RegisterID rd, RegisterID rn, int lsb, int width)
    {
        ubfm<datasize>(rd, rn, (datasize - lsb) & (datasize - 1), width - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void ubfm(RegisterID rd, RegisterID rn, int immr, int imms)
    {
        CHECK_DATASIZE();
        insn(bitfield(DATASIZE, BitfieldOp_UBFM, immr, imms, rn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void ubfx(RegisterID rd, RegisterID rn, int lsb, int width)
    {
        ubfm<datasize>(rd, rn, lsb, lsb + width - 1);
    }

    template<int datasize>
    ALWAYS_INLINE void udiv(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        CHECK_DATASIZE();
        insn(dataProcessing2Source(DATASIZE, rm, DataOp_UDIV, rn, rd));
    }

    ALWAYS_INLINE void umaddl(RegisterID rd, RegisterID rn, RegisterID rm, RegisterID ra)
    {
        nopCortexA53Fix835769<64>();
        insn(dataProcessing3Source(Datasize_64, DataOp_UMADDL, rm, ra, rn, rd));
    }

    ALWAYS_INLINE void umnegl(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        umsubl(rd, rn, rm, ARM64Registers::zr);
    }

    ALWAYS_INLINE void umsubl(RegisterID rd, RegisterID rn, RegisterID rm, RegisterID ra)
    {
        nopCortexA53Fix835769<64>();
        insn(dataProcessing3Source(Datasize_64, DataOp_UMSUBL, rm, ra, rn, rd));
    }

    ALWAYS_INLINE void umulh(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        insn(dataProcessing3Source(Datasize_64, DataOp_UMULH, rm, ARM64Registers::zr, rn, rd));
    }

    ALWAYS_INLINE void umull(RegisterID rd, RegisterID rn, RegisterID rm)
    {
        umaddl(rd, rn, rm, ARM64Registers::zr);
    }

    template<int datasize>
    ALWAYS_INLINE void uxtb(RegisterID rd, RegisterID rn)
    {
        ubfm<datasize>(rd, rn, 0, 7);
    }

    template<int datasize>
    ALWAYS_INLINE void uxth(RegisterID rd, RegisterID rn)
    {
        ubfm<datasize>(rd, rn, 0, 15);
    }

    ALWAYS_INLINE void uxtw(RegisterID rd, RegisterID rn)
    {
        ubfm<64>(rd, rn, 0, 31);
    }

    // Floating Point Instructions:

    template<int datasize>
    ALWAYS_INLINE void fabs(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FABS, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fadd(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FADD, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fccmp(FPRegisterID vn, FPRegisterID vm, int nzcv, Condition cond)
    {
        CHECK_DATASIZE();
        insn(floatingPointConditionalCompare(DATASIZE, vm, cond, vn, FPCondCmpOp_FCMP, nzcv));
    }

    template<int datasize>
    ALWAYS_INLINE void fccmpe(FPRegisterID vn, FPRegisterID vm, int nzcv, Condition cond)
    {
        CHECK_DATASIZE();
        insn(floatingPointConditionalCompare(DATASIZE, vm, cond, vn, FPCondCmpOp_FCMPE, nzcv));
    }

    template<int datasize>
    ALWAYS_INLINE void fcmp(FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointCompare(DATASIZE, vm, vn, FPCmpOp_FCMP));
    }

    template<int datasize>
    ALWAYS_INLINE void fcmp_0(FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointCompare(DATASIZE, static_cast<FPRegisterID>(0), vn, FPCmpOp_FCMP0));
    }

    template<int datasize>
    ALWAYS_INLINE void fcmpe(FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointCompare(DATASIZE, vm, vn, FPCmpOp_FCMPE));
    }

    template<int datasize>
    ALWAYS_INLINE void fcmpe_0(FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointCompare(DATASIZE, static_cast<FPRegisterID>(0), vn, FPCmpOp_FCMPE0));
    }

    template<int datasize>
    ALWAYS_INLINE void fcsel(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm, Condition cond)
    {
        CHECK_DATASIZE();
        insn(floatingPointConditionalSelect(DATASIZE, vm, cond, vn, vd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvt(FPRegisterID vd, FPRegisterID vn)
    {
        ASSERT(dstsize == 16 || dstsize == 32 || dstsize == 64);
        ASSERT(srcsize == 16 || srcsize == 32 || srcsize == 64);
        ASSERT(dstsize != srcsize);
        Datasize type = (srcsize == 64) ? Datasize_64 : (srcsize == 32) ? Datasize_32 : Datasize_16;
        FPDataOp1Source opcode = (dstsize == 64) ? FPDataOp_FCVT_toDouble : (dstsize == 32) ? FPDataOp_FCVT_toSingle : FPDataOp_FCVT_toHalf;
        insn(floatingPointDataProcessing1Source(type, opcode, vn, vd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtas(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTAS, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtau(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTAU, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtms(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTMS, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtmu(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTMU, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtns(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTNS, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtnu(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTNU, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtps(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTPS, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtpu(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTPU, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtzs(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTZS, vn, rd));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void fcvtzu(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(dstsize), DATASIZE_OF(srcsize), FPIntConvOp_FCVTZU, vn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void fdiv(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FDIV, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmadd(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm, FPRegisterID va)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing3Source(DATASIZE, false, vm, AddOp_ADD, va, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmax(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FMAX, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmaxnm(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FMAXNM, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmin(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FMIN, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fminnm(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FMINNM, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmov(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FMOV, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmov(FPRegisterID vd, RegisterID rn)
    {
        CHECK_DATASIZE();
        insn(floatingPointIntegerConversions(DATASIZE, DATASIZE, FPIntConvOp_FMOV_XtoQ, rn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmov(RegisterID rd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointIntegerConversions(DATASIZE, DATASIZE, FPIntConvOp_FMOV_QtoX, vn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmov(FPRegisterID vd, double imm)
    {
        CHECK_DATASIZE();
        insn(floatingPointImmediate(DATASIZE, encodeFPImm(imm), vd));
    }

    ALWAYS_INLINE void fmov_top(FPRegisterID vd, RegisterID rn)
    {
        insn(floatingPointIntegerConversions(Datasize_64, Datasize_64, FPIntConvOp_FMOV_XtoQ_top, rn, vd));
    }

    ALWAYS_INLINE void fmov_top(RegisterID rd, FPRegisterID vn)
    {
        insn(floatingPointIntegerConversions(Datasize_64, Datasize_64, FPIntConvOp_FMOV_QtoX_top, vn, rd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmsub(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm, FPRegisterID va)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing3Source(DATASIZE, false, vm, AddOp_SUB, va, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fmul(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FMUL, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fneg(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FNEG, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fnmadd(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm, FPRegisterID va)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing3Source(DATASIZE, true, vm, AddOp_ADD, va, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fnmsub(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm, FPRegisterID va)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing3Source(DATASIZE, true, vm, AddOp_SUB, va, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fnmul(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FNMUL, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void vand(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_VECTOR_DATASIZE();
        insn(vectorDataProcessing2Source(SIMD_LogicalOp_AND, vm, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frinta(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTA, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frinti(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTI, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frintm(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTM, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frintn(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTN, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frintp(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTP, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frintx(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTX, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void frintz(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FRINTZ, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fsqrt(FPRegisterID vd, FPRegisterID vn)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing1Source(DATASIZE, FPDataOp_FSQRT, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void fsub(FPRegisterID vd, FPRegisterID vn, FPRegisterID vm)
    {
        CHECK_DATASIZE();
        insn(floatingPointDataProcessing2Source(DATASIZE, vm, FPDataOp_FSUB, vn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(FPRegisterID rt, RegisterID rn, RegisterID rm)
    {
        ldr<datasize>(rt, rn, rm, UXTX, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(FPRegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterRegisterOffset(MEMOPSIZE, true, datasize == 128 ? MemOp_LOAD_V128 : MemOp_LOAD, rm, extend, encodeShiftAmount<datasize>(amount), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(FPRegisterID rt, RegisterID rn, unsigned pimm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterUnsignedImmediate(MEMOPSIZE, true, datasize == 128 ? MemOp_LOAD_V128 : MemOp_LOAD, encodePositiveImmediate<datasize>(pimm), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(FPRegisterID rt, RegisterID rn, PostIndex simm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterPostIndex(MEMOPSIZE, true, datasize == 128 ? MemOp_LOAD_V128 : MemOp_LOAD, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr(FPRegisterID rt, RegisterID rn, PreIndex simm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterPreIndex(MEMOPSIZE, true, datasize == 128 ? MemOp_LOAD_V128 : MemOp_LOAD, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldr_literal(FPRegisterID rt, int offset = 0)
    {
        CHECK_FP_MEMOP_DATASIZE();
        ASSERT(datasize >= 32);
        ASSERT(!(offset & 3));
        insn(loadRegisterLiteral(datasize == 128 ? LdrLiteralOp_128BIT : datasize == 64 ? LdrLiteralOp_64BIT : LdrLiteralOp_32BIT, true, offset >> 2, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void ldur(FPRegisterID rt, RegisterID rn, int simm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterUnscaledImmediate(MEMOPSIZE, true, datasize == 128 ? MemOp_LOAD_V128 : MemOp_LOAD, simm, rn, rt));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void scvtf(FPRegisterID vd, RegisterID rn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(srcsize), DATASIZE_OF(dstsize), FPIntConvOp_SCVTF, rn, vd));
    }

    template<int datasize>
    ALWAYS_INLINE void str(FPRegisterID rt, RegisterID rn, RegisterID rm)
    {
        str<datasize>(rt, rn, rm, UXTX, 0);
    }

    template<int datasize>
    ALWAYS_INLINE void str(FPRegisterID rt, RegisterID rn, RegisterID rm, ExtendType extend, int amount)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterRegisterOffset(MEMOPSIZE, true, datasize == 128 ? MemOp_STORE_V128 : MemOp_STORE, rm, extend, encodeShiftAmount<datasize>(amount), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void str(FPRegisterID rt, RegisterID rn, unsigned pimm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterUnsignedImmediate(MEMOPSIZE, true, datasize == 128 ? MemOp_STORE_V128 : MemOp_STORE, encodePositiveImmediate<datasize>(pimm), rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void str(FPRegisterID rt, RegisterID rn, PostIndex simm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterPostIndex(MEMOPSIZE, true, datasize == 128 ? MemOp_STORE_V128 : MemOp_STORE, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void str(FPRegisterID rt, RegisterID rn, PreIndex simm)
    {
        CHECK_FP_MEMOP_DATASIZE();
        insn(loadStoreRegisterPreIndex(MEMOPSIZE, true, datasize == 128 ? MemOp_STORE_V128 : MemOp_STORE, simm, rn, rt));
    }

    template<int datasize>
    ALWAYS_INLINE void stur(FPRegisterID rt, RegisterID rn, int simm)
    {
        CHECK_DATASIZE();
        insn(loadStoreRegisterUnscaledImmediate(MEMOPSIZE, true, datasize == 128 ? MemOp_STORE_V128 : MemOp_STORE, simm, rn, rt));
    }

    template<int dstsize, int srcsize>
    ALWAYS_INLINE void ucvtf(FPRegisterID vd, RegisterID rn)
    {
        CHECK_DATASIZE_OF(dstsize);
        CHECK_DATASIZE_OF(srcsize);
        insn(floatingPointIntegerConversions(DATASIZE_OF(srcsize), DATASIZE_OF(dstsize), FPIntConvOp_UCVTF, rn, vd));
    }

    // Admin methods:

    AssemblerLabel labelIgnoringWatchpoints()
    {
        return m_buffer.label();
    }

    AssemblerLabel labelForWatchpoint()
    {
        AssemblerLabel result = m_buffer.label();
        if (static_cast<int>(result.m_offset) != m_indexOfLastWatchpoint)
            result = label();
        m_indexOfLastWatchpoint = result.m_offset;
        m_indexOfTailOfLastWatchpoint = result.m_offset + maxJumpReplacementSize();
        return result;
    }

    AssemblerLabel label()
    {
        AssemblerLabel result = m_buffer.label();
        while (UNLIKELY(static_cast<int>(result.m_offset) < m_indexOfTailOfLastWatchpoint)) {
            nop();
            result = m_buffer.label();
        }
        return result;
    }

    AssemblerLabel align(int alignment)
    {
        ASSERT(!(alignment & 3));
        while (!m_buffer.isAligned(alignment))
            brk(0);
        return label();
    }
    
    static void* getRelocatedAddress(void* code, AssemblerLabel label)
    {
        ASSERT(label.isSet());
        return reinterpret_cast<void*>(reinterpret_cast<ptrdiff_t>(code) + label.m_offset);
    }
    
    static int getDifferenceBetweenLabels(AssemblerLabel a, AssemblerLabel b)
    {
        return b.m_offset - a.m_offset;
    }

    void* unlinkedCode() { return m_buffer.data(); }
    size_t codeSize() const { return m_buffer.codeSize(); }

    static unsigned getCallReturnOffset(AssemblerLabel call)
    {
        ASSERT(call.isSet());
        return call.m_offset;
    }

    // Linking & patching:
    //
    // 'link' and 'patch' methods are for use on unprotected code - such as the code
    // within the AssemblerBuffer, and code being patched by the patch buffer. Once
    // code has been finalized it is (platform support permitting) within a non-
    // writable region of memory; to modify the code in an execute-only execuable
    // pool the 'repatch' and 'relink' methods should be used.

    void linkJump(AssemblerLabel from, AssemblerLabel to, JumpType type, Condition condition)
    {
        ASSERT(to.isSet());
        ASSERT(from.isSet());
        m_jumpsToLink.append(LinkRecord(from.m_offset, to.m_offset, type, condition));
    }

    void linkJump(AssemblerLabel from, AssemblerLabel to, JumpType type, Condition condition, bool is64Bit, RegisterID compareRegister)
    {
        ASSERT(to.isSet());
        ASSERT(from.isSet());
        m_jumpsToLink.append(LinkRecord(from.m_offset, to.m_offset, type, condition, is64Bit, compareRegister));
    }

    void linkJump(AssemblerLabel from, AssemblerLabel to, JumpType type, Condition condition, unsigned bitNumber, RegisterID compareRegister)
    {
        ASSERT(to.isSet());
        ASSERT(from.isSet());
        m_jumpsToLink.append(LinkRecord(from.m_offset, to.m_offset, type, condition, bitNumber, compareRegister));
    }

    void linkJump(AssemblerLabel from, AssemblerLabel to)
    {
        ASSERT(from.isSet());
        ASSERT(to.isSet());
        relinkJumpOrCall<false>(addressOf(from), addressOf(to));
    }
    
    static void linkJump(void* code, AssemblerLabel from, void* to)
    {
        ASSERT(from.isSet());
        relinkJumpOrCall<false>(addressOf(code, from), to);
    }

    static void linkCall(void* code, AssemblerLabel from, void* to)
    {
        ASSERT(from.isSet());
        linkJumpOrCall<true>(addressOf(code, from) - 1, to);
    }

    static void linkPointer(void* code, AssemblerLabel where, void* valuePtr)
    {
        linkPointer(addressOf(code, where), valuePtr);
    }

    static void replaceWithJump(void* where, void* to)
    {
        intptr_t offset = (reinterpret_cast<intptr_t>(to) - reinterpret_cast<intptr_t>(where)) >> 2;
        ASSERT(static_cast<int>(offset) == offset);
        *static_cast<int*>(where) = unconditionalBranchImmediate(false, static_cast<int>(offset));
        cacheFlush(where, sizeof(int));
    }
    
    static ptrdiff_t maxJumpReplacementSize()
    {
        return 4;
    }
    
    static void replaceWithLoad(void* where)
    {
        Datasize sf;
        AddOp op;
        SetFlags S;
        int shift;
        int imm12;
        RegisterID rn;
        RegisterID rd;
        if (disassembleAddSubtractImmediate(where, sf, op, S, shift, imm12, rn, rd)) {
            ASSERT(sf == Datasize_64);
            ASSERT(op == AddOp_ADD);
            ASSERT(!S);
            ASSERT(!shift);
            ASSERT(!(imm12 & ~0xff8));
            *static_cast<int*>(where) = loadStoreRegisterUnsignedImmediate(MemOpSize_64, false, MemOp_LOAD, encodePositiveImmediate<64>(imm12), rn, rd);
            cacheFlush(where, sizeof(int));
        }
#if !ASSERT_DISABLED
        else {
            MemOpSize size;
            bool V;
            MemOp opc;
            int imm12;
            RegisterID rn;
            RegisterID rt;
            ASSERT(disassembleLoadStoreRegisterUnsignedImmediate(where, size, V, opc, imm12, rn, rt));
            ASSERT(size == MemOpSize_64);
            ASSERT(!V);
            ASSERT(opc == MemOp_LOAD);
            ASSERT(!(imm12 & ~0x1ff));
        }
#endif
    }

    static void replaceWithAddressComputation(void* where)
    {
        MemOpSize size;
        bool V;
        MemOp opc;
        int imm12;
        RegisterID rn;
        RegisterID rt;
        if (disassembleLoadStoreRegisterUnsignedImmediate(where, size, V, opc, imm12, rn, rt)) {
            ASSERT(size == MemOpSize_64);
            ASSERT(!V);
            ASSERT(opc == MemOp_LOAD);
            ASSERT(!(imm12 & ~0x1ff));
            *static_cast<int*>(where) = addSubtractImmediate(Datasize_64, AddOp_ADD, DontSetFlags, 0, imm12 * sizeof(void*), rn, rt);
            cacheFlush(where, sizeof(int));
        }
#if !ASSERT_DISABLED
        else {
            Datasize sf;
            AddOp op;
            SetFlags S;
            int shift;
            int imm12;
            RegisterID rn;
            RegisterID rd;
            ASSERT(disassembleAddSubtractImmediate(where, sf, op, S, shift, imm12, rn, rd));
            ASSERT(sf == Datasize_64);
            ASSERT(op == AddOp_ADD);
            ASSERT(!S);
            ASSERT(!shift);
            ASSERT(!(imm12 & ~0xff8));
        }
#endif
    }

    static void repatchPointer(void* where, void* valuePtr)
    {
        linkPointer(static_cast<int*>(where), valuePtr, true);
    }

    static void setPointer(int* address, void* valuePtr, RegisterID rd, bool flush)
    {
        uintptr_t value = reinterpret_cast<uintptr_t>(valuePtr);
        address[0] = moveWideImediate(Datasize_64, MoveWideOp_Z, 0, getHalfword(value, 0), rd);
        address[1] = moveWideImediate(Datasize_64, MoveWideOp_K, 1, getHalfword(value, 1), rd);
        address[2] = moveWideImediate(Datasize_64, MoveWideOp_K, 2, getHalfword(value, 2), rd);

        if (flush)
            cacheFlush(address, sizeof(int) * 3);
    }

    static void repatchInt32(void* where, int32_t value)
    {
        int* address = static_cast<int*>(where);

        Datasize sf;
        MoveWideOp opc;
        int hw;
        uint16_t imm16;
        RegisterID rd;
        bool expected = disassembleMoveWideImediate(address, sf, opc, hw, imm16, rd);
        ASSERT_UNUSED(expected, expected && !sf && (opc == MoveWideOp_Z || opc == MoveWideOp_N) && !hw);
        ASSERT(checkMovk<Datasize_32>(address[1], 1, rd));

        if (value >= 0) {
            address[0] = moveWideImediate(Datasize_32, MoveWideOp_Z, 0, getHalfword(value, 0), rd);
            address[1] = moveWideImediate(Datasize_32, MoveWideOp_K, 1, getHalfword(value, 1), rd);
        } else {
            address[0] = moveWideImediate(Datasize_32, MoveWideOp_N, 0, ~getHalfword(value, 0), rd);
            address[1] = moveWideImediate(Datasize_32, MoveWideOp_K, 1, getHalfword(value, 1), rd);
        }

        cacheFlush(where, sizeof(int) * 2);
    }

    static void* readPointer(void* where)
    {
        int* address = static_cast<int*>(where);

        Datasize sf;
        MoveWideOp opc;
        int hw;
        uint16_t imm16;
        RegisterID rdFirst, rd;

        bool expected = disassembleMoveWideImediate(address, sf, opc, hw, imm16, rdFirst);
        ASSERT_UNUSED(expected, expected && sf && opc == MoveWideOp_Z && !hw);
        uintptr_t result = imm16;

        expected = disassembleMoveWideImediate(address + 1, sf, opc, hw, imm16, rd);
        ASSERT_UNUSED(expected, expected && sf && opc == MoveWideOp_K && hw == 1 && rd == rdFirst);
        result |= static_cast<uint64_t>(imm16) << 16;

        expected = disassembleMoveWideImediate(address + 2, sf, opc, hw, imm16, rd);
        ASSERT_UNUSED(expected, expected && sf && opc == MoveWideOp_K && hw == 2 && rd == rdFirst);
        result |= static_cast<uint64_t>(imm16) << 32;

        return reinterpret_cast<void*>(result);
    }

    static void* readCallTarget(void* from)
    {
        return readPointer(reinterpret_cast<int*>(from) - 4);
    }

    static void relinkJump(void* from, void* to)
    {
        relinkJumpOrCall<false>(reinterpret_cast<int*>(from), to);
        cacheFlush(from, sizeof(int));
    }
    
    static void relinkCall(void* from, void* to)
    {
        relinkJumpOrCall<true>(reinterpret_cast<int*>(from) - 1, to);
        cacheFlush(reinterpret_cast<int*>(from) - 1, sizeof(int));
    }
    
    static void repatchCompact(void* where, int32_t value)
    {
        ASSERT(!(value & ~0x3ff8));

        MemOpSize size;
        bool V;
        MemOp opc;
        int imm12;
        RegisterID rn;
        RegisterID rt;
        bool expected = disassembleLoadStoreRegisterUnsignedImmediate(where, size, V, opc, imm12, rn, rt);
        ASSERT_UNUSED(expected, expected && size >= MemOpSize_32 && !V && opc == MemOp_LOAD); // expect 32/64 bit load to GPR.

        if (size == MemOpSize_32)
            imm12 = encodePositiveImmediate<32>(value);
        else
            imm12 = encodePositiveImmediate<64>(value);
        *static_cast<int*>(where) = loadStoreRegisterUnsignedImmediate(size, V, opc, imm12, rn, rt);

        cacheFlush(where, sizeof(int));
    }

    unsigned debugOffset() { return m_buffer.debugOffset(); }

    void recordLinkOffsets(int32_t regionStart, int32_t regionEnd, int32_t offset)
    {
        int32_t ptr = regionStart / sizeof(int32_t);
        const int32_t end = regionEnd / sizeof(int32_t);
        int32_t* offsets = static_cast<int32_t*>(m_buffer.data());
        while (ptr < end)
            offsets[ptr++] = offset;
    }

    int executableOffsetFor(int location)
    {
        if (!location)
            return 0;
        return static_cast<int32_t*>(m_buffer.data())[location / sizeof(int32_t) - 1];
    }

#if OS(LINUX)
    static inline void linuxPageFlush(uintptr_t begin, uintptr_t end)
    {
        __builtin___clear_cache(reinterpret_cast<char*>(begin), reinterpret_cast<char*>(end));
    }
#endif

    static void cacheFlush(void* code, size_t size)
    {
#if defined(V4_BOOTSTRAP)
        UNUSED_PARAM(code)
        UNUSED_PARAM(size)
#elif OS(IOS)
        sys_cache_control(kCacheFunctionPrepareForExecution, code, size);
#elif OS(LINUX)
        size_t page = pageSize();
        uintptr_t current = reinterpret_cast<uintptr_t>(code);
        uintptr_t end = current + size;
        uintptr_t firstPageEnd = (current & ~(page - 1)) + page;

        if (end <= firstPageEnd) {
            linuxPageFlush(current, end);
            return;
        }

        linuxPageFlush(current, firstPageEnd);

        for (current = firstPageEnd; current + page < end; current += page)
            linuxPageFlush(current, current + page);

        linuxPageFlush(current, end);
#elif OS(QNX)
#if !ENABLE(ASSEMBLER_WX_EXCLUSIVE)
        msync(code, size, MS_INVALIDATE_ICACHE);
#else
        UNUSED_PARAM(code);
        UNUSED_PARAM(size);
#endif
#elif OS(INTEGRITY)
        ManageCaches((Address)code, size, ACCESS_DST_SYNC);
#else
#error "The cacheFlush support is missing on this platform."
#endif
    }

    // Assembler admin methods:

    static int jumpSizeDelta(JumpType jumpType, JumpLinkType jumpLinkType) { return JUMP_ENUM_SIZE(jumpType) - JUMP_ENUM_SIZE(jumpLinkType); }

    static ALWAYS_INLINE bool linkRecordSourceComparator(const LinkRecord& a, const LinkRecord& b)
    {
        return a.from() < b.from();
    }

    static bool canCompact(JumpType jumpType)
    {
        // Fixed jumps cannot be compacted
        return (jumpType == JumpNoCondition) || (jumpType == JumpCondition) || (jumpType == JumpCompareAndBranch) || (jumpType == JumpTestBit);
    }

    static JumpLinkType computeJumpType(JumpType jumpType, const uint8_t* from, const uint8_t* to)
    {
        switch (jumpType) {
        case JumpFixed:
            return LinkInvalid;
        case JumpNoConditionFixedSize:
            return LinkJumpNoCondition;
        case JumpConditionFixedSize:
            return LinkJumpCondition;
        case JumpCompareAndBranchFixedSize:
            return LinkJumpCompareAndBranch;
        case JumpTestBitFixedSize:
            return LinkJumpTestBit;
        case JumpNoCondition:
            return LinkJumpNoCondition;
        case JumpCondition: {
            ASSERT(!(reinterpret_cast<intptr_t>(from) & 0x3));
            ASSERT(!(reinterpret_cast<intptr_t>(to) & 0x3));
            int64_t relative = reinterpret_cast<intptr_t>(to) - (reinterpret_cast<intptr_t>(from));

            if (((relative << 43) >> 43) == relative)
                return LinkJumpConditionDirect;

            return LinkJumpCondition;
            }
        case JumpCompareAndBranch:  {
            ASSERT(!(reinterpret_cast<intptr_t>(from) & 0x3));
            ASSERT(!(reinterpret_cast<intptr_t>(to) & 0x3));
            int64_t relative = reinterpret_cast<intptr_t>(to) - (reinterpret_cast<intptr_t>(from));

            if (((relative << 43) >> 43) == relative)
                return LinkJumpCompareAndBranchDirect;

            return LinkJumpCompareAndBranch;
        }
        case JumpTestBit:   {
            ASSERT(!(reinterpret_cast<intptr_t>(from) & 0x3));
            ASSERT(!(reinterpret_cast<intptr_t>(to) & 0x3));
            int64_t relative = reinterpret_cast<intptr_t>(to) - (reinterpret_cast<intptr_t>(from));

            if (((relative << 50) >> 50) == relative)
                return LinkJumpTestBitDirect;

            return LinkJumpTestBit;
        }
        default:
            ASSERT_NOT_REACHED();
        }

        return LinkJumpNoCondition;
    }

    static JumpLinkType computeJumpType(LinkRecord& record, const uint8_t* from, const uint8_t* to)
    {
        JumpLinkType linkType = computeJumpType(record.type(), from, to);
        record.setLinkType(linkType);
        return linkType;
    }

    Vector<LinkRecord, 0, UnsafeVectorOverflow>& jumpsToLink()
    {
        std::sort(m_jumpsToLink.begin(), m_jumpsToLink.end(), linkRecordSourceComparator);
        return m_jumpsToLink;
    }

    static void ALWAYS_INLINE link(LinkRecord& record, uint8_t* from, uint8_t* to)
    {
        switch (record.linkType()) {
        case LinkJumpNoCondition:
            linkJumpOrCall<false>(reinterpret_cast<int*>(from), to);
            break;
        case LinkJumpConditionDirect:
            linkConditionalBranch<true>(record.condition(), reinterpret_cast<int*>(from), to);
            break;
        case LinkJumpCondition:
            linkConditionalBranch<false>(record.condition(), reinterpret_cast<int*>(from) - 1, to);
            break;
        case LinkJumpCompareAndBranchDirect:
            linkCompareAndBranch<true>(record.condition(), record.is64Bit(), record.compareRegister(), reinterpret_cast<int*>(from), to);
            break;
        case LinkJumpCompareAndBranch:
            linkCompareAndBranch<false>(record.condition(), record.is64Bit(), record.compareRegister(), reinterpret_cast<int*>(from) - 1, to);
            break;
        case LinkJumpTestBitDirect:
            linkTestAndBranch<true>(record.condition(), record.bitNumber(), record.compareRegister(), reinterpret_cast<int*>(from), to);
            break;
        case LinkJumpTestBit:
            linkTestAndBranch<false>(record.condition(), record.bitNumber(), record.compareRegister(), reinterpret_cast<int*>(from) - 1, to);
            break;
        default:
            ASSERT_NOT_REACHED();
            break;
        }
    }

private:
    template<Datasize size>
    static bool checkMovk(int insn, int _hw, RegisterID _rd)
    {
        Datasize sf;
        MoveWideOp opc;
        int hw;
        uint16_t imm16;
        RegisterID rd;
        bool expected = disassembleMoveWideImediate(&insn, sf, opc, hw, imm16, rd);

        return expected
            && sf == size
            && opc == MoveWideOp_K
            && hw == _hw
            && rd == _rd;
    }

    static void linkPointer(int* address, void* valuePtr, bool flush = false)
    {
        Datasize sf;
        MoveWideOp opc;
        int hw;
        uint16_t imm16;
        RegisterID rd;
        bool expected = disassembleMoveWideImediate(address, sf, opc, hw, imm16, rd);
        ASSERT_UNUSED(expected, expected && sf && opc == MoveWideOp_Z && !hw);
        ASSERT(checkMovk<Datasize_64>(address[1], 1, rd));
        ASSERT(checkMovk<Datasize_64>(address[2], 2, rd));

        setPointer(address, valuePtr, rd, flush);
    }

    template<bool isCall>
    static void linkJumpOrCall(int* from, void* to)
    {
        bool link;
        int imm26;
        bool isUnconditionalBranchImmediateOrNop = disassembleUnconditionalBranchImmediate(from, link, imm26) || disassembleNop(from);

        ASSERT_UNUSED(isUnconditionalBranchImmediateOrNop, isUnconditionalBranchImmediateOrNop);
        ASSERT_UNUSED(isCall, (link == isCall) || disassembleNop(from));
        ASSERT(!(reinterpret_cast<intptr_t>(from) & 3));
        ASSERT(!(reinterpret_cast<intptr_t>(to) & 3));
        intptr_t offset = (reinterpret_cast<intptr_t>(to) - reinterpret_cast<intptr_t>(from)) >> 2;
        ASSERT(static_cast<int>(offset) == offset);

        *from = unconditionalBranchImmediate(isCall, static_cast<int>(offset));
    }

    template<bool isDirect>
    static void linkCompareAndBranch(Condition condition, bool is64Bit, RegisterID rt, int* from, void* to)
    {
        ASSERT(!(reinterpret_cast<intptr_t>(from) & 3));
        ASSERT(!(reinterpret_cast<intptr_t>(to) & 3));
        int64_t offset = (reinterpret_cast<intptr_t>(to) - reinterpret_cast<intptr_t>(from)) >> 2;
        ASSERT(((offset << 38) >> 38) == offset);

        bool useDirect = ((offset << 45) >> 45) == offset; // Fits in 19 bits
        ASSERT(!isDirect || useDirect);

        if (useDirect || isDirect) {
            *from = compareAndBranchImmediate(is64Bit ? Datasize_64 : Datasize_32, condition == ConditionNE, static_cast<int>(offset), rt);
            if (!isDirect)
                *(from + 1) = nopPseudo();
        } else {
            *from = compareAndBranchImmediate(is64Bit ? Datasize_64 : Datasize_32, invert(condition) == ConditionNE, 2, rt);
            linkJumpOrCall<false>(from + 1, to);
        }
    }

    template<bool isDirect>
    static void linkConditionalBranch(Condition condition, int* from, void* to)
    {
        ASSERT(!(reinterpret_cast<intptr_t>(from) & 3));
        ASSERT(!(reinterpret_cast<intptr_t>(to) & 3));
        int64_t offset = (reinterpret_cast<intptr_t>(to) - reinterpret_cast<intptr_t>(from)) >> 2;
        ASSERT(((offset << 38) >> 38) == offset);

        bool useDirect = ((offset << 45) >> 45) == offset; // Fits in 19 bits
        ASSERT(!isDirect || useDirect);

        if (useDirect || isDirect) {
            *from = conditionalBranchImmediate(static_cast<int>(offset), condition);
            if (!isDirect)
                *(from + 1) = nopPseudo();
        } else {
            *from = conditionalBranchImmediate(2, invert(condition));
            linkJumpOrCall<false>(from + 1, to);
        }
    }

    template<bool isDirect>
    static void linkTestAndBranch(Condition condition, unsigned bitNumber, RegisterID rt, int* from, void* to)
    {
        ASSERT(!(reinterpret_cast<intptr_t>(from) & 3));
        ASSERT(!(reinterpret_cast<intptr_t>(to) & 3));
        int64_t offset = (reinterpret_cast<intptr_t>(to) - reinterpret_cast<intptr_t>(from)) >> 2;
        ASSERT(static_cast<int>(offset) == offset);
        ASSERT(((offset << 38) >> 38) == offset);

        bool useDirect = ((offset << 50) >> 50) == offset; // Fits in 14 bits
        ASSERT(!isDirect || useDirect);

        if (useDirect || isDirect) {
            *from = testAndBranchImmediate(condition == ConditionNE, static_cast<int>(bitNumber), static_cast<int>(offset), rt);
            if (!isDirect)
                *(from + 1) = nopPseudo();
        } else {
            *from = testAndBranchImmediate(invert(condition) == ConditionNE, static_cast<int>(bitNumber), 2, rt);
            linkJumpOrCall<false>(from + 1, to);
        }
    }

    template<bool isCall>
    static void relinkJumpOrCall(int* from, void* to)
    {
        if (!isCall && disassembleNop(from)) {
            unsigned op01;
            int imm19;
            Condition condition;
            bool isConditionalBranchImmediate = disassembleConditionalBranchImmediate(from - 1, op01, imm19, condition);

            if (isConditionalBranchImmediate) {
                ASSERT_UNUSED(op01, !op01);
                ASSERT_UNUSED(isCall, !isCall);

                if (imm19 == 8)
                    condition = invert(condition);

                linkConditionalBranch<false>(condition, from - 1, to);
                return;
            }

            Datasize opSize;
            bool op;
            RegisterID rt;
            bool isCompareAndBranchImmediate = disassembleCompareAndBranchImmediate(from - 1, opSize, op, imm19, rt);

            if (isCompareAndBranchImmediate) {
                if (imm19 == 8)
                    op = !op;

                linkCompareAndBranch<false>(op ? ConditionNE : ConditionEQ, opSize == Datasize_64, rt, from - 1, to);
                return;
            }

            int imm14;
            unsigned bitNumber;
            bool isTestAndBranchImmediate = disassembleTestAndBranchImmediate(from - 1, op, bitNumber, imm14, rt);

            if (isTestAndBranchImmediate) {
                if (imm14 == 8)
                    op = !op;

                linkTestAndBranch<false>(op ? ConditionNE : ConditionEQ, bitNumber, rt, from - 1, to);
                return;
            }
        }

        linkJumpOrCall<isCall>(from, to);
    }

    static int* addressOf(void* code, AssemblerLabel label)
    {
        return reinterpret_cast<int*>(static_cast<char*>(code) + label.m_offset);
    }

    int* addressOf(AssemblerLabel label)
    {
        return addressOf(m_buffer.data(), label);
    }

    static RegisterID disassembleXOrSp(int reg) { return reg == 31 ? ARM64Registers::sp : static_cast<RegisterID>(reg); }
    static RegisterID disassembleXOrZr(int reg) { return reg == 31 ? ARM64Registers::zr : static_cast<RegisterID>(reg); }
    static RegisterID disassembleXOrZrOrSp(bool useZr, int reg) { return reg == 31 ? (useZr ? ARM64Registers::zr : ARM64Registers::sp) : static_cast<RegisterID>(reg); }

    static bool disassembleAddSubtractImmediate(void* address, Datasize& sf, AddOp& op, SetFlags& S, int& shift, int& imm12, RegisterID& rn, RegisterID& rd)
    {
        int insn = *static_cast<int*>(address);
        sf = static_cast<Datasize>((insn >> 31) & 1);
        op = static_cast<AddOp>((insn >> 30) & 1);
        S = static_cast<SetFlags>((insn >> 29) & 1);
        shift = (insn >> 22) & 3;
        imm12 = (insn >> 10) & 0x3ff;
        rn = disassembleXOrSp((insn >> 5) & 0x1f);
        rd = disassembleXOrZrOrSp(S, insn & 0x1f);
        return (insn & 0x1f000000) == 0x11000000;
    }

    static bool disassembleLoadStoreRegisterUnsignedImmediate(void* address, MemOpSize& size, bool& V, MemOp& opc, int& imm12, RegisterID& rn, RegisterID& rt)
    {
        int insn = *static_cast<int*>(address);
        size = static_cast<MemOpSize>((insn >> 30) & 3);
        V = (insn >> 26) & 1;
        opc = static_cast<MemOp>((insn >> 22) & 3);
        imm12 = (insn >> 10) & 0xfff;
        rn = disassembleXOrSp((insn >> 5) & 0x1f);
        rt = disassembleXOrZr(insn & 0x1f);
        return (insn & 0x3b000000) == 0x39000000;
    }

    static bool disassembleMoveWideImediate(void* address, Datasize& sf, MoveWideOp& opc, int& hw, uint16_t& imm16, RegisterID& rd)
    {
        int insn = *static_cast<int*>(address);
        sf = static_cast<Datasize>((insn >> 31) & 1);
        opc = static_cast<MoveWideOp>((insn >> 29) & 3);
        hw = (insn >> 21) & 3;
        imm16 = insn >> 5;
        rd = disassembleXOrZr(insn & 0x1f);
        return (insn & 0x1f800000) == 0x12800000;
    }

    static bool disassembleNop(void* address)
    {
        unsigned insn = *static_cast<unsigned*>(address);
        return insn == 0xd503201f;
    }

    static bool disassembleCompareAndBranchImmediate(void* address, Datasize& sf, bool& op, int& imm19, RegisterID& rt)
    {
        int insn = *static_cast<int*>(address);
        sf = static_cast<Datasize>((insn >> 31) & 1);
        op = (insn >> 24) & 0x1;
        imm19 = (insn << 8) >> 13;
        rt = static_cast<RegisterID>(insn & 0x1f);
        return (insn & 0x7e000000) == 0x34000000;
        
    }

    static bool disassembleConditionalBranchImmediate(void* address, unsigned& op01, int& imm19, Condition &condition)
    {
        int insn = *static_cast<int*>(address);
        op01 = ((insn >> 23) & 0x2) | ((insn >> 4) & 0x1);
        imm19 = (insn << 8) >> 13;
        condition = static_cast<Condition>(insn & 0xf);
        return (insn & 0xfe000000) == 0x54000000;
    }

    static bool disassembleTestAndBranchImmediate(void* address, bool& op, unsigned& bitNumber, int& imm14, RegisterID& rt)
    {
        int insn = *static_cast<int*>(address);
        op = (insn >> 24) & 0x1;
        imm14 = (insn << 13) >> 18;
        bitNumber = static_cast<unsigned>((((insn >> 26) & 0x20)) | ((insn >> 19) & 0x1f));
        rt = static_cast<RegisterID>(insn & 0x1f);
        return (insn & 0x7e000000) == 0x36000000;
        
    }

    static bool disassembleUnconditionalBranchImmediate(void* address, bool& op, int& imm26)
    {
        int insn = *static_cast<int*>(address);
        op = (insn >> 31) & 1;
        imm26 = (insn << 6) >> 6;
        return (insn & 0x7c000000) == 0x14000000;
    }

    static int xOrSp(RegisterID reg) { ASSERT(!isZr(reg)); return reg; }
    static int xOrZr(RegisterID reg) { ASSERT(!isSp(reg)); return reg & 31; }
    static FPRegisterID xOrZrAsFPR(RegisterID reg) { return static_cast<FPRegisterID>(xOrZr(reg)); }
    static int xOrZrOrSp(bool useZr, RegisterID reg) { return useZr ? xOrZr(reg) : xOrSp(reg); }

    ALWAYS_INLINE void insn(int instruction)
    {
        m_buffer.putInt(instruction);
    }

    ALWAYS_INLINE static int addSubtractExtendedRegister(Datasize sf, AddOp op, SetFlags S, RegisterID rm, ExtendType option, int imm3, RegisterID rn, RegisterID rd)
    {
        ASSERT(imm3 < 5);
        // The only allocated values for opt is 0.
        const int opt = 0;
        return (0x0b200000 | sf << 31 | op << 30 | S << 29 | opt << 22 | xOrZr(rm) << 16 | option << 13 | (imm3 & 0x7) << 10 | xOrSp(rn) << 5 | xOrZrOrSp(S, rd));
    }

    ALWAYS_INLINE static int addSubtractImmediate(Datasize sf, AddOp op, SetFlags S, int shift, int imm12, RegisterID rn, RegisterID rd)
    {
        ASSERT(shift < 2);
        ASSERT(isUInt12(imm12));
        return (0x11000000 | sf << 31 | op << 30 | S << 29 | shift << 22 | (imm12 & 0xfff) << 10 | xOrSp(rn) << 5 | xOrZrOrSp(S, rd));
    }

    ALWAYS_INLINE static int addSubtractShiftedRegister(Datasize sf, AddOp op, SetFlags S, ShiftType shift, RegisterID rm, int imm6, RegisterID rn, RegisterID rd)
    {
        ASSERT(shift < 3);
        ASSERT(!(imm6 & (sf ? ~63 : ~31)));
        return (0x0b000000 | sf << 31 | op << 30 | S << 29 | shift << 22 | xOrZr(rm) << 16 | (imm6 & 0x3f) << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int addSubtractWithCarry(Datasize sf, AddOp op, SetFlags S, RegisterID rm, RegisterID rn, RegisterID rd)
    {
        const int opcode2 = 0;
        return (0x1a000000 | sf << 31 | op << 30 | S << 29 | xOrZr(rm) << 16 | opcode2 << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int bitfield(Datasize sf, BitfieldOp opc, int immr, int imms, RegisterID rn, RegisterID rd)
    {
        ASSERT(immr < (sf ? 64 : 32));
        ASSERT(imms < (sf ? 64 : 32));
        const int N = sf;
        return (0x13000000 | sf << 31 | opc << 29 | N << 22 | immr << 16 | imms << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    // 'op' means negate
    ALWAYS_INLINE static int compareAndBranchImmediate(Datasize sf, bool op, int32_t imm19, RegisterID rt)
    {
        ASSERT(imm19 == (imm19 << 13) >> 13);
        return (0x34000000 | sf << 31 | op << 24 | (imm19 & 0x7ffff) << 5 | xOrZr(rt));
    }

    ALWAYS_INLINE static int conditionalBranchImmediate(int32_t imm19, Condition cond)
    {
        ASSERT(imm19 == (imm19 << 13) >> 13);
        ASSERT(!(cond & ~15));
        // The only allocated values for o1 & o0 are 0.
        const int o1 = 0;
        const int o0 = 0;
        return (0x54000000 | o1 << 24 | (imm19 & 0x7ffff) << 5 | o0 << 4 | cond);
    }

    ALWAYS_INLINE static int conditionalCompareImmediate(Datasize sf, AddOp op, int imm5, Condition cond, RegisterID rn, int nzcv)
    {
        ASSERT(!(imm5 & ~0x1f));
        ASSERT(nzcv < 16);
        const int S = 1;
        const int o2 = 0;
        const int o3 = 0;
        return (0x1a400800 | sf << 31 | op << 30 | S << 29 | (imm5 & 0x1f) << 16 | cond << 12 | o2 << 10 | xOrZr(rn) << 5 | o3 << 4 | nzcv);
    }

    ALWAYS_INLINE static int conditionalCompareRegister(Datasize sf, AddOp op, RegisterID rm, Condition cond, RegisterID rn, int nzcv)
    {
        ASSERT(nzcv < 16);
        const int S = 1;
        const int o2 = 0;
        const int o3 = 0;
        return (0x1a400000 | sf << 31 | op << 30 | S << 29 | xOrZr(rm) << 16 | cond << 12 | o2 << 10 | xOrZr(rn) << 5 | o3 << 4 | nzcv);
    }

    // 'op' means negate
    // 'op2' means increment
    ALWAYS_INLINE static int conditionalSelect(Datasize sf, bool op, RegisterID rm, Condition cond, bool op2, RegisterID rn, RegisterID rd)
    {
        const int S = 0;
        return (0x1a800000 | sf << 31 | op << 30 | S << 29 | xOrZr(rm) << 16 | cond << 12 | op2 << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int dataProcessing1Source(Datasize sf, DataOp1Source opcode, RegisterID rn, RegisterID rd)
    {
        const int S = 0;
        const int opcode2 = 0;
        return (0x5ac00000 | sf << 31 | S << 29 | opcode2 << 16 | opcode << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int dataProcessing2Source(Datasize sf, RegisterID rm, DataOp2Source opcode, RegisterID rn, RegisterID rd)
    {
        const int S = 0;
        return (0x1ac00000 | sf << 31 | S << 29 | xOrZr(rm) << 16 | opcode << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int dataProcessing3Source(Datasize sf, DataOp3Source opcode, RegisterID rm, RegisterID ra, RegisterID rn, RegisterID rd)
    {
        int op54 = opcode >> 4;
        int op31 = (opcode >> 1) & 7;
        int op0 = opcode & 1;
        return (0x1b000000 | sf << 31 | op54 << 29 | op31 << 21 | xOrZr(rm) << 16 | op0 << 15 | xOrZr(ra) << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int excepnGeneration(ExcepnOp opc, uint16_t imm16, int LL)
    {
        ASSERT((opc == ExcepnOp_BREAKPOINT || opc == ExcepnOp_HALT) ? !LL : (LL && (LL < 4)));
        const int op2 = 0;
        return (0xd4000000 | opc << 21 | imm16 << 5 | op2 << 2 | LL);
    }

    ALWAYS_INLINE static int extract(Datasize sf, RegisterID rm, int imms, RegisterID rn, RegisterID rd)
    {
        ASSERT(imms < (sf ? 64 : 32));
        const int op21 = 0;
        const int N = sf;
        const int o0 = 0;
        return (0x13800000 | sf << 31 | op21 << 29 | N << 22 | o0 << 21 | xOrZr(rm) << 16 | imms << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int floatingPointCompare(Datasize type, FPRegisterID rm, FPRegisterID rn, FPCmpOp opcode2)
    {
        const int M = 0;
        const int S = 0;
        const int op = 0;
        return (0x1e202000 | M << 31 | S << 29 | type << 22 | rm << 16 | op << 14 | rn << 5 | opcode2);
    }

    ALWAYS_INLINE static int floatingPointConditionalCompare(Datasize type, FPRegisterID rm, Condition cond, FPRegisterID rn, FPCondCmpOp op, int nzcv)
    {
        ASSERT(nzcv < 16);
        const int M = 0;
        const int S = 0;
        return (0x1e200400 | M << 31 | S << 29 | type << 22 | rm << 16 | cond << 12 | rn << 5 | op << 4 | nzcv);
    }

    ALWAYS_INLINE static int floatingPointConditionalSelect(Datasize type, FPRegisterID rm, Condition cond, FPRegisterID rn, FPRegisterID rd)
    {
        const int M = 0;
        const int S = 0;
        return (0x1e200c00 | M << 31 | S << 29 | type << 22 | rm << 16 | cond << 12 | rn << 5 | rd);
    }

    ALWAYS_INLINE static int floatingPointImmediate(Datasize type, int imm8, FPRegisterID rd)
    {
        const int M = 0;
        const int S = 0;
        const int imm5 = 0;
        return (0x1e201000 | M << 31 | S << 29 | type << 22 | (imm8 & 0xff) << 13 | imm5 << 5 | rd);
    }

    ALWAYS_INLINE static int floatingPointIntegerConversions(Datasize sf, Datasize type, FPIntConvOp rmodeOpcode, FPRegisterID rn, FPRegisterID rd)
    {
        const int S = 0;
        return (0x1e200000 | sf << 31 | S << 29 | type << 22 | rmodeOpcode << 16 | rn << 5 | rd);
    }

    ALWAYS_INLINE static int floatingPointIntegerConversions(Datasize sf, Datasize type, FPIntConvOp rmodeOpcode, FPRegisterID rn, RegisterID rd)
    {
        return floatingPointIntegerConversions(sf, type, rmodeOpcode, rn, xOrZrAsFPR(rd));
    }

    ALWAYS_INLINE static int floatingPointIntegerConversions(Datasize sf, Datasize type, FPIntConvOp rmodeOpcode, RegisterID rn, FPRegisterID rd)
    {
        return floatingPointIntegerConversions(sf, type, rmodeOpcode, xOrZrAsFPR(rn), rd);
    }

    ALWAYS_INLINE static int floatingPointDataProcessing1Source(Datasize type, FPDataOp1Source opcode, FPRegisterID rn, FPRegisterID rd)
    {
        const int M = 0;
        const int S = 0;
        return (0x1e204000 | M << 31 | S << 29 | type << 22 | opcode << 15 | rn << 5 | rd);
    }

    ALWAYS_INLINE static int floatingPointDataProcessing2Source(Datasize type, FPRegisterID rm, FPDataOp2Source opcode, FPRegisterID rn, FPRegisterID rd)
    {
        const int M = 0;
        const int S = 0;
        return (0x1e200800 | M << 31 | S << 29 | type << 22 | rm << 16 | opcode << 12 | rn << 5 | rd);
    }

    ALWAYS_INLINE static int vectorDataProcessing2Source(SIMD3Same opcode, unsigned size, FPRegisterID vm, FPRegisterID vn, FPRegisterID vd)
    {
        const int Q = 0;
        return (0xe201c00 | Q << 30 | size << 22 | vm << 16 | opcode << 11 | vn << 5 | vd);
    }

    ALWAYS_INLINE static int vectorDataProcessing2Source(SIMD3Same opcode, FPRegisterID vm, FPRegisterID vn, FPRegisterID vd)
    {
        return vectorDataProcessing2Source(opcode, 0, vm, vn, vd);
    }


    // 'o1' means negate
    ALWAYS_INLINE static int floatingPointDataProcessing3Source(Datasize type, bool o1, FPRegisterID rm, AddOp o2, FPRegisterID ra, FPRegisterID rn, FPRegisterID rd)
    {
        const int M = 0;
        const int S = 0;
        return (0x1f000000 | M << 31 | S << 29 | type << 22 | o1 << 21 | rm << 16 | o2 << 15 | ra << 10 | rn << 5 | rd);
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadRegisterLiteral(LdrLiteralOp opc, bool V, int imm19, FPRegisterID rt)
    {
        ASSERT(((imm19 << 13) >> 13) == imm19);
        return (0x18000000 | opc << 30 | V << 26 | (imm19 & 0x7ffff) << 5 | rt);
    }

    ALWAYS_INLINE static int loadRegisterLiteral(LdrLiteralOp opc, bool V, int imm19, RegisterID rt)
    {
        return loadRegisterLiteral(opc, V, imm19, xOrZrAsFPR(rt));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterPostIndex(MemOpSize size, bool V, MemOp opc, int imm9, RegisterID rn, FPRegisterID rt)
    {
        ASSERT(!(size && V && (opc & 2))); // Maximum vector size is 128 bits.
        ASSERT(!((size & 2) && !V && (opc == 3))); // signed 32-bit load must be extending from 8/16 bits.
        ASSERT(isInt9(imm9));
        return (0x38000400 | size << 30 | V << 26 | opc << 22 | (imm9 & 0x1ff) << 12 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterPostIndex(MemOpSize size, bool V, MemOp opc, int imm9, RegisterID rn, RegisterID rt)
    {
        return loadStoreRegisterPostIndex(size, V, opc, imm9, rn, xOrZrAsFPR(rt));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterPairPostIndex(MemPairOpSize size, bool V, MemOp opc, int immediate, RegisterID rn, FPRegisterID rt, FPRegisterID rt2)
    {
        ASSERT(size < 3);
        ASSERT(opc == (opc & 1)); // Only load or store, load signed 64 is handled via size.
        ASSERT(V || (size != MemPairOp_LoadSigned_32) || (opc == MemOp_LOAD)); // There isn't an integer store signed.
        unsigned immedShiftAmount = memPairOffsetShift(V, size);
        int imm7 = immediate >> immedShiftAmount;
        ASSERT((imm7 << immedShiftAmount) == immediate && isInt7(imm7));
        return (0x28800000 | size << 30 | V << 26 | opc << 22 | (imm7 & 0x7f) << 15 | rt2 << 10 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterPairPostIndex(MemPairOpSize size, bool V, MemOp opc, int immediate, RegisterID rn, RegisterID rt, RegisterID rt2)
    {
        return loadStoreRegisterPairPostIndex(size, V, opc, immediate, rn, xOrZrAsFPR(rt), xOrZrAsFPR(rt2));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterPreIndex(MemOpSize size, bool V, MemOp opc, int imm9, RegisterID rn, FPRegisterID rt)
    {
        ASSERT(!(size && V && (opc & 2))); // Maximum vector size is 128 bits.
        ASSERT(!((size & 2) && !V && (opc == 3))); // signed 32-bit load must be extending from 8/16 bits.
        ASSERT(isInt9(imm9));
        return (0x38000c00 | size << 30 | V << 26 | opc << 22 | (imm9 & 0x1ff) << 12 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterPreIndex(MemOpSize size, bool V, MemOp opc, int imm9, RegisterID rn, RegisterID rt)
    {
        return loadStoreRegisterPreIndex(size, V, opc, imm9, rn, xOrZrAsFPR(rt));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterPairPreIndex(MemPairOpSize size, bool V, MemOp opc, int immediate, RegisterID rn, FPRegisterID rt, FPRegisterID rt2)
    {
        ASSERT(size < 3);
        ASSERT(opc == (opc & 1)); // Only load or store, load signed 64 is handled via size.
        ASSERT(V || (size != MemPairOp_LoadSigned_32) || (opc == MemOp_LOAD)); // There isn't an integer store signed.
        unsigned immedShiftAmount = memPairOffsetShift(V, size);
        int imm7 = immediate >> immedShiftAmount;
        ASSERT((imm7 << immedShiftAmount) == immediate && isInt7(imm7));
        return (0x29800000 | size << 30 | V << 26 | opc << 22 | (imm7 & 0x7f) << 15 | rt2 << 10 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterPairPreIndex(MemPairOpSize size, bool V, MemOp opc, int immediate, RegisterID rn, RegisterID rt, RegisterID rt2)
    {
        return loadStoreRegisterPairPreIndex(size, V, opc, immediate, rn, xOrZrAsFPR(rt), xOrZrAsFPR(rt2));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterPairOffset(MemPairOpSize size, bool V, MemOp opc, int immediate, RegisterID rn, FPRegisterID rt, FPRegisterID rt2)
    {
        ASSERT(size < 3);
        ASSERT(opc == (opc & 1)); // Only load or store, load signed 64 is handled via size.
        ASSERT(V || (size != MemPairOp_LoadSigned_32) || (opc == MemOp_LOAD)); // There isn't an integer store signed.
        unsigned immedShiftAmount = memPairOffsetShift(V, size);
        int imm7 = immediate >> immedShiftAmount;
        ASSERT((imm7 << immedShiftAmount) == immediate && isInt7(imm7));
        return (0x29000000 | size << 30 | V << 26 | opc << 22 | (imm7 & 0x7f) << 15 | rt2 << 10 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterPairOffset(MemPairOpSize size, bool V, MemOp opc, int immediate, RegisterID rn, RegisterID rt, RegisterID rt2)
    {
        return loadStoreRegisterPairOffset(size, V, opc, immediate, rn, xOrZrAsFPR(rt), xOrZrAsFPR(rt2));
    }

    // 'V' means vector
    // 'S' means shift rm
    ALWAYS_INLINE static int loadStoreRegisterRegisterOffset(MemOpSize size, bool V, MemOp opc, RegisterID rm, ExtendType option, bool S, RegisterID rn, FPRegisterID rt)
    {
        ASSERT(!(size && V && (opc & 2))); // Maximum vector size is 128 bits.
        ASSERT(!((size & 2) && !V && (opc == 3))); // signed 32-bit load must be extending from 8/16 bits.
        ASSERT(option & 2); // The ExtendType for the address must be 32/64 bit, signed or unsigned - not 8/16bit.
        return (0x38200800 | size << 30 | V << 26 | opc << 22 | xOrZr(rm) << 16 | option << 13 | S << 12 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterRegisterOffset(MemOpSize size, bool V, MemOp opc, RegisterID rm, ExtendType option, bool S, RegisterID rn, RegisterID rt)
    {
        return loadStoreRegisterRegisterOffset(size, V, opc, rm, option, S, rn, xOrZrAsFPR(rt));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterUnscaledImmediate(MemOpSize size, bool V, MemOp opc, int imm9, RegisterID rn, FPRegisterID rt)
    {
        ASSERT(!(size && V && (opc & 2))); // Maximum vector size is 128 bits.
        ASSERT(!((size & 2) && !V && (opc == 3))); // signed 32-bit load must be extending from 8/16 bits.
        ASSERT(isInt9(imm9));
        return (0x38000000 | size << 30 | V << 26 | opc << 22 | (imm9 & 0x1ff) << 12 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterUnscaledImmediate(MemOpSize size, bool V, MemOp opc, int imm9, RegisterID rn, RegisterID rt)
    {
        ASSERT(isInt9(imm9));
        return loadStoreRegisterUnscaledImmediate(size, V, opc, imm9, rn, xOrZrAsFPR(rt));
    }

    // 'V' means vector
    ALWAYS_INLINE static int loadStoreRegisterUnsignedImmediate(MemOpSize size, bool V, MemOp opc, int imm12, RegisterID rn, FPRegisterID rt)
    {
        ASSERT(!(size && V && (opc & 2))); // Maximum vector size is 128 bits.
        ASSERT(!((size & 2) && !V && (opc == 3))); // signed 32-bit load must be extending from 8/16 bits.
        ASSERT(isUInt12(imm12));
        return (0x39000000 | size << 30 | V << 26 | opc << 22 | (imm12 & 0xfff) << 10 | xOrSp(rn) << 5 | rt);
    }

    ALWAYS_INLINE static int loadStoreRegisterUnsignedImmediate(MemOpSize size, bool V, MemOp opc, int imm12, RegisterID rn, RegisterID rt)
    {
        return loadStoreRegisterUnsignedImmediate(size, V, opc, imm12, rn, xOrZrAsFPR(rt));
    }

    ALWAYS_INLINE static int logicalImmediate(Datasize sf, LogicalOp opc, int N_immr_imms, RegisterID rn, RegisterID rd)
    {
        ASSERT(!(N_immr_imms & (sf ? ~0x1fff : ~0xfff)));
        return (0x12000000 | sf << 31 | opc << 29 | N_immr_imms << 10 | xOrZr(rn) << 5 | xOrZrOrSp(opc == LogicalOp_ANDS, rd));
    }

    // 'N' means negate rm
    ALWAYS_INLINE static int logicalShiftedRegister(Datasize sf, LogicalOp opc, ShiftType shift, bool N, RegisterID rm, int imm6, RegisterID rn, RegisterID rd)
    {
        ASSERT(!(imm6 & (sf ? ~63 : ~31)));
        return (0x0a000000 | sf << 31 | opc << 29 | shift << 22 | N << 21 | xOrZr(rm) << 16 | (imm6 & 0x3f) << 10 | xOrZr(rn) << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int moveWideImediate(Datasize sf, MoveWideOp opc, int hw, uint16_t imm16, RegisterID rd)
    {
        ASSERT(hw < (sf ? 4 : 2));
        return (0x12800000 | sf << 31 | opc << 29 | hw << 21 | (int)imm16 << 5 | xOrZr(rd));
    }

    // 'op' means link
    ALWAYS_INLINE static int unconditionalBranchImmediate(bool op, int32_t imm26)
    {
        ASSERT(imm26 == (imm26 << 6) >> 6);
        return (0x14000000 | op << 31 | (imm26 & 0x3ffffff));
    }

    // 'op' means page
    ALWAYS_INLINE static int pcRelative(bool op, int32_t imm21, RegisterID rd)
    {
        ASSERT(imm21 == (imm21 << 11) >> 11);
        int32_t immlo = imm21 & 3;
        int32_t immhi = (imm21 >> 2) & 0x7ffff;
        return (0x10000000 | op << 31 | immlo << 29 | immhi << 5 | xOrZr(rd));
    }

    ALWAYS_INLINE static int system(bool L, int op0, int op1, int crn, int crm, int op2, RegisterID rt)
    {
        return (0xd5000000 | L << 21 | op0 << 19 | op1 << 16 | crn << 12 | crm << 8 | op2 << 5 | xOrZr(rt));
    }

    ALWAYS_INLINE static int hintPseudo(int imm)
    {
        ASSERT(!(imm & ~0x7f));
        return system(0, 0, 3, 2, (imm >> 3) & 0xf, imm & 0x7, ARM64Registers::zr);
    }

    ALWAYS_INLINE static int nopPseudo()
    {
        return hintPseudo(0);
    }
    
    // 'op' means negate
    ALWAYS_INLINE static int testAndBranchImmediate(bool op, int b50, int imm14, RegisterID rt)
    {
        ASSERT(!(b50 & ~0x3f));
        ASSERT(imm14 == (imm14 << 18) >> 18);
        int b5 = b50 >> 5;
        int b40 = b50 & 0x1f;
        return (0x36000000 | b5 << 31 | op << 24 | b40 << 19 | (imm14 & 0x3fff) << 5 | xOrZr(rt));
    }

    ALWAYS_INLINE static int unconditionalBranchRegister(BranchType opc, RegisterID rn)
    {
        // The only allocated values for op2 is 0x1f, for op3 & op4 are 0.
        const int op2 = 0x1f;
        const int op3 = 0;
        const int op4 = 0;
        return (0xd6000000 | opc << 21 | op2 << 16 | op3 << 10 | xOrZr(rn) << 5 | op4);
    }

    // Workaround for Cortex-A53 erratum (835769). Emit an extra nop if the
    // last instruction in the buffer is a load, store or prefetch. Needed
    // before 64-bit multiply-accumulate instructions.
    template<int datasize>
    ALWAYS_INLINE void nopCortexA53Fix835769()
    {
#if CPU(ARM64_CORTEXA53)
        CHECK_DATASIZE();
        if (datasize == 64) {
            if (LIKELY(m_buffer.codeSize() >= sizeof(int32_t))) {
                // From ARMv8 Reference Manual, Section C4.1: the encoding of the
                // instructions in the Loads and stores instruction group is:
                // ---- 1-0- ---- ---- ---- ---- ---- ----
                if (UNLIKELY((*reinterpret_cast_ptr<int32_t*>(reinterpret_cast_ptr<char*>(m_buffer.data()) + m_buffer.codeSize() - sizeof(int32_t)) & 0x0a000000) == 0x08000000))
                    nop();
            }
        }
#endif
    }

    // Workaround for Cortex-A53 erratum (843419). Emit extra nops to avoid
    // wrong address access after ADRP instruction.
    ALWAYS_INLINE void nopCortexA53Fix843419()
    {
#if CPU(ARM64_CORTEXA53)
        nop();
        nop();
        nop();
#endif
    }

    AssemblerBuffer m_buffer;
    Vector<LinkRecord, 0, UnsafeVectorOverflow> m_jumpsToLink;
    int m_indexOfLastWatchpoint;
    int m_indexOfTailOfLastWatchpoint;
};

} // namespace JSC

#undef CHECK_DATASIZE_OF
#undef DATASIZE_OF
#undef MEMOPSIZE_OF
#undef CHECK_DATASIZE
#undef DATASIZE
#undef MEMOPSIZE
#undef CHECK_FP_MEMOP_DATASIZE
#undef JUMP_ENUM_WITH_SIZE
#undef JUMP_ENUM_SIZE

#endif // ENABLE(ASSEMBLER) && CPU(ARM64)

#endif // ARM64Assembler_h