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gem5 / public / gem5 / fd1a8bed393a2ef48d584fcabeee4d98eda0e3fa / . / src / arch / arm / insts / vfp.hh
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/*
* Copyright (c) 2010-2013, 2019 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Authors: Gabe Black
*/
#ifndef __ARCH_ARM_INSTS_VFP_HH__
#define __ARCH_ARM_INSTS_VFP_HH__
#include <fenv.h>
#include <cmath>
#include "arch/arm/insts/misc.hh"
#include "arch/arm/miscregs.hh"
namespace ArmISA
{
enum VfpMicroMode {
VfpNotAMicroop,
VfpMicroop,
VfpFirstMicroop,
VfpLastMicroop
};
template<class T>
static inline void
setVfpMicroFlags(VfpMicroMode mode, T &flags)
{
switch (mode) {
case VfpMicroop:
flags[StaticInst::IsMicroop] = true;
break;
case VfpFirstMicroop:
flags[StaticInst::IsMicroop] =
flags[StaticInst::IsFirstMicroop] = true;
break;
case VfpLastMicroop:
flags[StaticInst::IsMicroop] =
flags[StaticInst::IsLastMicroop] = true;
break;
case VfpNotAMicroop:
break;
}
if (mode == VfpMicroop || mode == VfpFirstMicroop) {
flags[StaticInst::IsDelayedCommit] = true;
}
}
enum FeExceptionBit
{
FeDivByZero = FE_DIVBYZERO,
FeInexact = FE_INEXACT,
FeInvalid = FE_INVALID,
FeOverflow = FE_OVERFLOW,
FeUnderflow = FE_UNDERFLOW,
FeAllExceptions = FE_ALL_EXCEPT
};
enum FeRoundingMode
{
FeRoundDown = FE_DOWNWARD,
FeRoundNearest = FE_TONEAREST,
FeRoundZero = FE_TOWARDZERO,
FeRoundUpward = FE_UPWARD
};
enum VfpRoundingMode
{
VfpRoundNearest = 0,
VfpRoundUpward = 1,
VfpRoundDown = 2,
VfpRoundZero = 3,
VfpRoundAway = 4
};
static inline float bitsToFp(uint64_t, float);
static inline double bitsToFp(uint64_t, double);
static inline uint32_t fpToBits(float);
static inline uint64_t fpToBits(double);
template <class fpType>
static inline bool
flushToZero(fpType &op)
{
fpType junk = 0.0;
if (std::fpclassify(op) == FP_SUBNORMAL) {
uint64_t bitMask = ULL(0x1) << (sizeof(fpType) * 8 - 1);
op = bitsToFp(fpToBits(op) & bitMask, junk);
return true;
}
return false;
}
template <class fpType>
static inline bool
flushToZero(fpType &op1, fpType &op2)
{
bool flush1 = flushToZero(op1);
bool flush2 = flushToZero(op2);
return flush1 || flush2;
}
template <class fpType>
static inline void
vfpFlushToZero(FPSCR &fpscr, fpType &op)
{
if (fpscr.fz == 1 && flushToZero(op)) {
fpscr.idc = 1;
}
}
template <class fpType>
static inline void
vfpFlushToZero(FPSCR &fpscr, fpType &op1, fpType &op2)
{
vfpFlushToZero(fpscr, op1);
vfpFlushToZero(fpscr, op2);
}
static inline uint32_t
fpToBits(float fp)
{
union
{
float fp;
uint32_t bits;
} val;
val.fp = fp;
return val.bits;
}
static inline uint64_t
fpToBits(double fp)
{
union
{
double fp;
uint64_t bits;
} val;
val.fp = fp;
return val.bits;
}
static inline float
bitsToFp(uint64_t bits, float junk)
{
union
{
float fp;
uint32_t bits;
} val;
val.bits = bits;
return val.fp;
}
static inline double
bitsToFp(uint64_t bits, double junk)
{
union
{
double fp;
uint64_t bits;
} val;
val.bits = bits;
return val.fp;
}
template <class fpType>
static inline bool
isSnan(fpType val)
{
const bool single = (sizeof(fpType) == sizeof(float));
const uint64_t qnan =
single ? 0x7fc00000 : ULL(0x7ff8000000000000);
return std::isnan(val) && ((fpToBits(val) & qnan) != qnan);
}
typedef int VfpSavedState;
VfpSavedState prepFpState(uint32_t rMode);
void finishVfp(FPSCR &fpscr, VfpSavedState state, bool flush, FPSCR mask = FpscrExcMask);
template <class fpType>
fpType fixDest(FPSCR fpscr, fpType val, fpType op1);
template <class fpType>
fpType fixDest(FPSCR fpscr, fpType val, fpType op1, fpType op2);
template <class fpType>
fpType fixDivDest(FPSCR fpscr, fpType val, fpType op1, fpType op2);
float fixFpDFpSDest(FPSCR fpscr, double val);
double fixFpSFpDDest(FPSCR fpscr, float val);
uint16_t vcvtFpSFpH(FPSCR &fpscr, bool flush, bool defaultNan,
uint32_t rMode, bool ahp, float op);
uint16_t vcvtFpDFpH(FPSCR &fpscr, bool flush, bool defaultNan,
uint32_t rMode, bool ahp, double op);
float vcvtFpHFpS(FPSCR &fpscr, bool defaultNan, bool ahp, uint16_t op);
double vcvtFpHFpD(FPSCR &fpscr, bool defaultNan, bool ahp, uint16_t op);
static inline double
makeDouble(uint32_t low, uint32_t high)
{
double junk = 0.0;
return bitsToFp((uint64_t)low | ((uint64_t)high << 32), junk);
}
static inline uint32_t
lowFromDouble(double val)
{
return fpToBits(val);
}
static inline uint32_t
highFromDouble(double val)
{
return fpToBits(val) >> 32;
}
static inline void
setFPExceptions(int exceptions) {
feclearexcept(FeAllExceptions);
feraiseexcept(exceptions);
}
template <typename T>
uint64_t
vfpFpToFixed(T val, bool isSigned, uint8_t width, uint8_t imm, bool
useRmode = true, VfpRoundingMode roundMode = VfpRoundZero,
bool aarch64 = false)
{
int rmode;
bool roundAwayFix = false;
if (!useRmode) {
rmode = fegetround();
} else {
switch (roundMode)
{
case VfpRoundNearest:
rmode = FeRoundNearest;
break;
case VfpRoundUpward:
rmode = FeRoundUpward;
break;
case VfpRoundDown:
rmode = FeRoundDown;
break;
case VfpRoundZero:
rmode = FeRoundZero;
break;
case VfpRoundAway:
// There is no equivalent rounding mode, use round down and we'll
// fix it later
rmode = FeRoundDown;
roundAwayFix = true;
break;
default:
panic("Unsupported roundMode %d\n", roundMode);
}
}
__asm__ __volatile__("" : "=m" (rmode) : "m" (rmode));
fesetround(FeRoundNearest);
val = val * pow(2.0, imm);
__asm__ __volatile__("" : "=m" (val) : "m" (val));
fesetround(rmode);
feclearexcept(FeAllExceptions);
__asm__ __volatile__("" : "=m" (val) : "m" (val));
T origVal = val;
val = rint(val);
__asm__ __volatile__("" : "=m" (val) : "m" (val));
int exceptions = fetestexcept(FeAllExceptions);
int fpType = std::fpclassify(val);
if (fpType == FP_SUBNORMAL || fpType == FP_NAN) {
if (fpType == FP_NAN) {
exceptions |= FeInvalid;
}
val = 0.0;
} else if (origVal != val) {
switch (rmode) {
case FeRoundNearest:
if (origVal - val > 0.5)
val += 1.0;
else if (val - origVal > 0.5)
val -= 1.0;
break;
case FeRoundDown:
if (roundAwayFix) {
// The ordering on the subtraction looks a bit odd in that we
// don't do the obvious origVal - val, instead we do
// -(val - origVal). This is required to get the corruct bit
// exact behaviour when very close to the 0.5 threshold.
volatile T error = val;
error -= origVal;
error = -error;
if ( (error > 0.5) ||
((error == 0.5) && (val >= 0)) )
val += 1.0;
} else {
if (origVal < val)
val -= 1.0;
}
break;
case FeRoundUpward:
if (origVal > val)
val += 1.0;
break;
}
exceptions |= FeInexact;
}
__asm__ __volatile__("" : "=m" (val) : "m" (val));
if (isSigned) {
bool outOfRange = false;
int64_t result = (int64_t) val;
uint64_t finalVal;
if (!aarch64) {
if (width == 16) {
finalVal = (int16_t)val;
} else if (width == 32) {
finalVal =(int32_t)val;
} else if (width == 64) {
finalVal = result;
} else {
panic("Unsupported width %d\n", width);
}
// check if value is in range
int64_t minVal = ~mask(width-1);
if ((double)val < minVal) {
outOfRange = true;
finalVal = minVal;
}
int64_t maxVal = mask(width-1);
if ((double)val > maxVal) {
outOfRange = true;
finalVal = maxVal;
}
} else {
bool isNeg = val < 0;
finalVal = result & mask(width);
// If the result is supposed to be less than 64 bits check that the
// upper bits that got thrown away are just sign extension bits
if (width != 64) {
outOfRange = ((uint64_t) result >> (width - 1)) !=
(isNeg ? mask(64-width+1) : 0);
}
// Check if the original floating point value doesn't matches the
// integer version we are also out of range. So create a saturated
// result.
if (isNeg) {
outOfRange |= val < result;
if (outOfRange) {
finalVal = 1LL << (width-1);
}
} else {
outOfRange |= val > result;
if (outOfRange) {
finalVal = mask(width-1);
}
}
}
// Raise an exception if the value was out of range
if (outOfRange) {
exceptions |= FeInvalid;
exceptions &= ~FeInexact;
}
setFPExceptions(exceptions);
return finalVal;
} else {
if ((double)val < 0) {
exceptions |= FeInvalid;
exceptions &= ~FeInexact;
setFPExceptions(exceptions);
return 0;
}
uint64_t result = ((uint64_t) val) & mask(width);
if (val > result) {
exceptions |= FeInvalid;
exceptions &= ~FeInexact;
setFPExceptions(exceptions);
return mask(width);
}
setFPExceptions(exceptions);
return result;
}
};
float vfpUFixedToFpS(bool flush, bool defaultNan,
uint64_t val, uint8_t width, uint8_t imm);
float vfpSFixedToFpS(bool flush, bool defaultNan,
int64_t val, uint8_t width, uint8_t imm);
double vfpUFixedToFpD(bool flush, bool defaultNan,
uint64_t val, uint8_t width, uint8_t imm);
double vfpSFixedToFpD(bool flush, bool defaultNan,
int64_t val, uint8_t width, uint8_t imm);
float fprSqrtEstimate(FPSCR &fpscr, float op);
uint32_t unsignedRSqrtEstimate(uint32_t op);
float fpRecipEstimate(FPSCR &fpscr, float op);
uint32_t unsignedRecipEstimate(uint32_t op);
FPSCR
fpStandardFPSCRValue(const FPSCR &fpscr);
class VfpMacroOp : public PredMacroOp
{
public:
static bool
inScalarBank(IntRegIndex idx)
{
return (idx % 32) < 8;
}
protected:
bool wide;
VfpMacroOp(const char *mnem, ExtMachInst _machInst,
OpClass __opClass, bool _wide) :
PredMacroOp(mnem, _machInst, __opClass), wide(_wide)
{}
IntRegIndex addStride(IntRegIndex idx, unsigned stride);
void nextIdxs(IntRegIndex &dest, IntRegIndex &op1, IntRegIndex &op2);
void nextIdxs(IntRegIndex &dest, IntRegIndex &op1);
void nextIdxs(IntRegIndex &dest);
};
template <typename T>
static inline T
fpAdd(T a, T b)
{
return a + b;
};
template <typename T>
static inline T
fpSub(T a, T b)
{
return a - b;
};
static inline float
fpAddS(float a, float b)
{
return a + b;
}
static inline double
fpAddD(double a, double b)
{
return a + b;
}
static inline float
fpSubS(float a, float b)
{
return a - b;
}
static inline double
fpSubD(double a, double b)
{
return a - b;
}
static inline float
fpDivS(float a, float b)
{
return a / b;
}
static inline double
fpDivD(double a, double b)
{
return a / b;
}
template <typename T>
static inline T
fpDiv(T a, T b)
{
return a / b;
};
template <typename T>
static inline T
fpMulX(T a, T b)
{
uint64_t opData;
uint32_t sign1;
uint32_t sign2;
const bool single = (sizeof(T) == sizeof(float));
if (single) {
opData = (fpToBits(a));
sign1 = opData>>31;
opData = (fpToBits(b));
sign2 = opData>>31;
} else {
opData = (fpToBits(a));
sign1 = opData>>63;
opData = (fpToBits(b));
sign2 = opData>>63;
}
bool inf1 = (std::fpclassify(a) == FP_INFINITE);
bool inf2 = (std::fpclassify(b) == FP_INFINITE);
bool zero1 = (std::fpclassify(a) == FP_ZERO);
bool zero2 = (std::fpclassify(b) == FP_ZERO);
if ((inf1 && zero2) || (zero1 && inf2)) {
if (sign1 ^ sign2)
return (T)(-2.0);
else
return (T)(2.0);
} else {
return (a * b);
}
};
template <typename T>
static inline T
fpMul(T a, T b)
{
return a * b;
};
static inline float
fpMulS(float a, float b)
{
return a * b;
}
static inline double
fpMulD(double a, double b)
{
return a * b;
}
template <typename T>
static inline T
// @todo remove this when all calls to it have been replaced with the new fplib implementation
fpMulAdd(T op1, T op2, T addend)
{
T result;
if (sizeof(T) == sizeof(float))
result = fmaf(op1, op2, addend);
else
result = fma(op1, op2, addend);
// ARM doesn't generate signed nan's from this opperation, so fix up the result
if (std::isnan(result) && !std::isnan(op1) &&
!std::isnan(op2) && !std::isnan(addend))
{
uint64_t bitMask = ULL(0x1) << ((sizeof(T) * 8) - 1);
result = bitsToFp(fpToBits(result) & ~bitMask, op1);
}
return result;
}
template <typename T>
static inline T
fpRIntX(T a, FPSCR &fpscr)
{
T rVal;
rVal = rint(a);
if (rVal != a && !std::isnan(a))
fpscr.ixc = 1;
return (rVal);
};
template <typename T>
static inline T
fpMaxNum(T a, T b)
{
const bool single = (sizeof(T) == sizeof(float));
const uint64_t qnan = single ? 0x7fc00000 : ULL(0x7ff8000000000000);
if (std::isnan(a))
return ((fpToBits(a) & qnan) == qnan) ? b : a;
if (std::isnan(b))
return ((fpToBits(b) & qnan) == qnan) ? a : b;
// Handle comparisons of +0 and -0.
if (!std::signbit(a) && std::signbit(b))
return a;
return fmax(a, b);
};
template <typename T>
static inline T
fpMax(T a, T b)
{
if (std::isnan(a))
return a;
if (std::isnan(b))
return b;
return fpMaxNum<T>(a, b);
};
template <typename T>
static inline T
fpMinNum(T a, T b)
{
const bool single = (sizeof(T) == sizeof(float));
const uint64_t qnan = single ? 0x7fc00000 : ULL(0x7ff8000000000000);
if (std::isnan(a))
return ((fpToBits(a) & qnan) == qnan) ? b : a;
if (std::isnan(b))
return ((fpToBits(b) & qnan) == qnan) ? a : b;
// Handle comparisons of +0 and -0.
if (std::signbit(a) && !std::signbit(b))
return a;
return fmin(a, b);
};
template <typename T>
static inline T
fpMin(T a, T b)
{
if (std::isnan(a))
return a;
if (std::isnan(b))
return b;
return fpMinNum<T>(a, b);
};
template <typename T>
static inline T
fpRSqrts(T a, T b)
{
int fpClassA = std::fpclassify(a);
int fpClassB = std::fpclassify(b);
T aXb;
int fpClassAxB;
if ((fpClassA == FP_ZERO && fpClassB == FP_INFINITE) ||
(fpClassA == FP_INFINITE && fpClassB == FP_ZERO)) {
return 1.5;
}
aXb = a*b;
fpClassAxB = std::fpclassify(aXb);
if (fpClassAxB == FP_SUBNORMAL) {
feraiseexcept(FeUnderflow);
return 1.5;
}
return (3.0 - (a * b)) / 2.0;
};
template <typename T>
static inline T
fpRecps(T a, T b)
{
int fpClassA = std::fpclassify(a);
int fpClassB = std::fpclassify(b);
T aXb;
int fpClassAxB;
if ((fpClassA == FP_ZERO && fpClassB == FP_INFINITE) ||
(fpClassA == FP_INFINITE && fpClassB == FP_ZERO)) {
return 2.0;
}
aXb = a*b;
fpClassAxB = std::fpclassify(aXb);
if (fpClassAxB == FP_SUBNORMAL) {
feraiseexcept(FeUnderflow);
return 2.0;
}
return 2.0 - (a * b);
};
static inline float
fpRSqrtsS(float a, float b)
{
int fpClassA = std::fpclassify(a);
int fpClassB = std::fpclassify(b);
float aXb;
int fpClassAxB;
if ((fpClassA == FP_ZERO && fpClassB == FP_INFINITE) ||
(fpClassA == FP_INFINITE && fpClassB == FP_ZERO)) {
return 1.5;
}
aXb = a*b;
fpClassAxB = std::fpclassify(aXb);
if (fpClassAxB == FP_SUBNORMAL) {
feraiseexcept(FeUnderflow);
return 1.5;
}
return (3.0 - (a * b)) / 2.0;
}
static inline float
fpRecpsS(float a, float b)
{
int fpClassA = std::fpclassify(a);
int fpClassB = std::fpclassify(b);
float aXb;
int fpClassAxB;
if ((fpClassA == FP_ZERO && fpClassB == FP_INFINITE) ||
(fpClassA == FP_INFINITE && fpClassB == FP_ZERO)) {
return 2.0;
}
aXb = a*b;
fpClassAxB = std::fpclassify(aXb);
if (fpClassAxB == FP_SUBNORMAL) {
feraiseexcept(FeUnderflow);
return 2.0;
}
return 2.0 - (a * b);
}
template <typename T>
static inline T
roundNEven(T a) {
T val;
val = round(a);
if (a - val == 0.5) {
if ( (((int) a) & 1) == 0 ) val += 1.0;
}
else if (a - val == -0.5) {
if ( (((int) a) & 1) == 0 ) val -= 1.0;
}
return val;
}
class FpOp : public PredOp
{
protected:
FpOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass) :
PredOp(mnem, _machInst, __opClass)
{}
virtual float
doOp(float op1, float op2) const
{
panic("Unimplemented version of doOp called.\n");
}
virtual float
doOp(float op1) const
{
panic("Unimplemented version of doOp called.\n");
}
virtual double
doOp(double op1, double op2) const
{
panic("Unimplemented version of doOp called.\n");
}
virtual double
doOp(double op1) const
{
panic("Unimplemented version of doOp called.\n");
}
double
dbl(uint32_t low, uint32_t high) const
{
double junk = 0.0;
return bitsToFp((uint64_t)low | ((uint64_t)high << 32), junk);
}
uint32_t
dblLow(double val) const
{
return fpToBits(val);
}
uint32_t
dblHi(double val) const
{
return fpToBits(val) >> 32;
}
template <class fpType>
fpType
processNans(FPSCR &fpscr, bool &done, bool defaultNan,
fpType op1, fpType op2) const;
template <class fpType>
fpType
ternaryOp(FPSCR &fpscr, fpType op1, fpType op2, fpType op3,
fpType (*func)(fpType, fpType, fpType),
bool flush, bool defaultNan, uint32_t rMode) const;
template <class fpType>
fpType
binaryOp(FPSCR &fpscr, fpType op1, fpType op2,
fpType (*func)(fpType, fpType),
bool flush, bool defaultNan, uint32_t rMode) const;
template <class fpType>
fpType
unaryOp(FPSCR &fpscr, fpType op1,
fpType (*func)(fpType),
bool flush, uint32_t rMode) const;
void
advancePC(PCState &pcState) const
{
if (flags[IsLastMicroop]) {
pcState.uEnd();
} else if (flags[IsMicroop]) {
pcState.uAdvance();
} else {
pcState.advance();
}
}
float
fpSqrt (FPSCR fpscr,float x) const
{
return unaryOp(fpscr,x,sqrtf,fpscr.fz,fpscr.rMode);
}
double
fpSqrt (FPSCR fpscr,double x) const
{
return unaryOp(fpscr,x,sqrt,fpscr.fz,fpscr.rMode);
}
};
class FpCondCompRegOp : public FpOp
{
protected:
IntRegIndex op1, op2;
ConditionCode condCode;
uint8_t defCc;
FpCondCompRegOp(const char *mnem, ExtMachInst _machInst,
OpClass __opClass, IntRegIndex _op1, IntRegIndex _op2,
ConditionCode _condCode, uint8_t _defCc) :
FpOp(mnem, _machInst, __opClass),
op1(_op1), op2(_op2), condCode(_condCode), defCc(_defCc)
{}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpCondSelOp : public FpOp
{
protected:
IntRegIndex dest, op1, op2;
ConditionCode condCode;
FpCondSelOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass,
IntRegIndex _dest, IntRegIndex _op1, IntRegIndex _op2,
ConditionCode _condCode) :
FpOp(mnem, _machInst, __opClass),
dest(_dest), op1(_op1), op2(_op2), condCode(_condCode)
{}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegRegOp : public FpOp
{
protected:
IntRegIndex dest;
IntRegIndex op1;
FpRegRegOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass,
IntRegIndex _dest, IntRegIndex _op1,
VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass), dest(_dest), op1(_op1)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegImmOp : public FpOp
{
protected:
IntRegIndex dest;
uint64_t imm;
FpRegImmOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass,
IntRegIndex _dest, uint64_t _imm,
VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass), dest(_dest), imm(_imm)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegRegImmOp : public FpOp
{
protected:
IntRegIndex dest;
IntRegIndex op1;
uint64_t imm;
FpRegRegImmOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass,
IntRegIndex _dest, IntRegIndex _op1,
uint64_t _imm, VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass), dest(_dest), op1(_op1), imm(_imm)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegRegRegOp : public FpOp
{
protected:
IntRegIndex dest;
IntRegIndex op1;
IntRegIndex op2;
FpRegRegRegOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass,
IntRegIndex _dest, IntRegIndex _op1, IntRegIndex _op2,
VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass), dest(_dest), op1(_op1), op2(_op2)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegRegRegCondOp : public FpOp
{
protected:
IntRegIndex dest;
IntRegIndex op1;
IntRegIndex op2;
ConditionCode cond;
FpRegRegRegCondOp(const char *mnem, ExtMachInst _machInst,
OpClass __opClass, IntRegIndex _dest, IntRegIndex _op1,
IntRegIndex _op2, ConditionCode _cond,
VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass), dest(_dest), op1(_op1), op2(_op2),
cond(_cond)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegRegRegRegOp : public FpOp
{
protected:
IntRegIndex dest;
IntRegIndex op1;
IntRegIndex op2;
IntRegIndex op3;
FpRegRegRegRegOp(const char *mnem, ExtMachInst _machInst, OpClass __opClass,
IntRegIndex _dest, IntRegIndex _op1, IntRegIndex _op2,
IntRegIndex _op3, VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass), dest(_dest), op1(_op1), op2(_op2),
op3(_op3)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
class FpRegRegRegImmOp : public FpOp
{
protected:
IntRegIndex dest;
IntRegIndex op1;
IntRegIndex op2;
uint64_t imm;
FpRegRegRegImmOp(const char *mnem, ExtMachInst _machInst,
OpClass __opClass, IntRegIndex _dest,
IntRegIndex _op1, IntRegIndex _op2,
uint64_t _imm, VfpMicroMode mode = VfpNotAMicroop) :
FpOp(mnem, _machInst, __opClass),
dest(_dest), op1(_op1), op2(_op2), imm(_imm)
{
setVfpMicroFlags(mode, flags);
}
std::string generateDisassembly(
Addr pc, const SymbolTable *symtab) const override;
};
}
#endif //__ARCH_ARM_INSTS_VFP_HH__