blob: db39408a49ea8aba8e6cd2ab3fde06912efdb8c8 [file] [log] [blame]
// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/execution/arm64/simulator-arm64.h"
#if defined(USE_SIMULATOR)
#include <cmath>
namespace v8 {
namespace internal {
namespace {
// See FPRound for a description of this function.
inline double FPRoundToDouble(int64_t sign, int64_t exponent, uint64_t mantissa,
FPRounding round_mode) {
uint64_t bits = FPRound<uint64_t, kDoubleExponentBits, kDoubleMantissaBits>(
sign, exponent, mantissa, round_mode);
return bit_cast<double>(bits);
}
// See FPRound for a description of this function.
inline float FPRoundToFloat(int64_t sign, int64_t exponent, uint64_t mantissa,
FPRounding round_mode) {
uint32_t bits = FPRound<uint32_t, kFloatExponentBits, kFloatMantissaBits>(
sign, exponent, mantissa, round_mode);
return bit_cast<float>(bits);
}
// See FPRound for a description of this function.
inline float16 FPRoundToFloat16(int64_t sign, int64_t exponent,
uint64_t mantissa, FPRounding round_mode) {
return FPRound<float16, kFloat16ExponentBits, kFloat16MantissaBits>(
sign, exponent, mantissa, round_mode);
}
} // namespace
double Simulator::FixedToDouble(int64_t src, int fbits, FPRounding round) {
if (src >= 0) {
return UFixedToDouble(src, fbits, round);
} else if (src == INT64_MIN) {
return -UFixedToDouble(src, fbits, round);
} else {
return -UFixedToDouble(-src, fbits, round);
}
}
double Simulator::UFixedToDouble(uint64_t src, int fbits, FPRounding round) {
// An input of 0 is a special case because the result is effectively
// subnormal: The exponent is encoded as 0 and there is no implicit 1 bit.
if (src == 0) {
return 0.0;
}
// Calculate the exponent. The highest significant bit will have the value
// 2^exponent.
const int highest_significant_bit = 63 - CountLeadingZeros(src, 64);
const int64_t exponent = highest_significant_bit - fbits;
return FPRoundToDouble(0, exponent, src, round);
}
float Simulator::FixedToFloat(int64_t src, int fbits, FPRounding round) {
if (src >= 0) {
return UFixedToFloat(src, fbits, round);
} else if (src == INT64_MIN) {
return -UFixedToFloat(src, fbits, round);
} else {
return -UFixedToFloat(-src, fbits, round);
}
}
float Simulator::UFixedToFloat(uint64_t src, int fbits, FPRounding round) {
// An input of 0 is a special case because the result is effectively
// subnormal: The exponent is encoded as 0 and there is no implicit 1 bit.
if (src == 0) {
return 0.0f;
}
// Calculate the exponent. The highest significant bit will have the value
// 2^exponent.
const int highest_significant_bit = 63 - CountLeadingZeros(src, 64);
const int32_t exponent = highest_significant_bit - fbits;
return FPRoundToFloat(0, exponent, src, round);
}
double Simulator::FPToDouble(float value) {
switch (std::fpclassify(value)) {
case FP_NAN: {
if (IsSignallingNaN(value)) {
FPProcessException();
}
if (DN()) return kFP64DefaultNaN;
// Convert NaNs as the processor would:
// - The sign is propagated.
// - The mantissa is transferred entirely, except that the top bit is
// forced to '1', making the result a quiet NaN. The unused (low-order)
// mantissa bits are set to 0.
uint32_t raw = bit_cast<uint32_t>(value);
uint64_t sign = raw >> 31;
uint64_t exponent = (1 << kDoubleExponentBits) - 1;
uint64_t mantissa = unsigned_bitextract_64(21, 0, raw);
// Unused low-order bits remain zero.
mantissa <<= (kDoubleMantissaBits - kFloatMantissaBits);
// Force a quiet NaN.
mantissa |= (UINT64_C(1) << (kDoubleMantissaBits - 1));
return double_pack(sign, exponent, mantissa);
}
case FP_ZERO:
case FP_NORMAL:
case FP_SUBNORMAL:
case FP_INFINITE: {
// All other inputs are preserved in a standard cast, because every value
// representable using an IEEE-754 float is also representable using an
// IEEE-754 double.
return static_cast<double>(value);
}
}
UNREACHABLE();
}
float Simulator::FPToFloat(float16 value) {
uint32_t sign = value >> 15;
uint32_t exponent =
unsigned_bitextract_32(kFloat16MantissaBits + kFloat16ExponentBits - 1,
kFloat16MantissaBits, value);
uint32_t mantissa =
unsigned_bitextract_32(kFloat16MantissaBits - 1, 0, value);
switch (float16classify(value)) {
case FP_ZERO:
return (sign == 0) ? 0.0f : -0.0f;
case FP_INFINITE:
return (sign == 0) ? kFP32PositiveInfinity : kFP32NegativeInfinity;
case FP_SUBNORMAL: {
// Calculate shift required to put mantissa into the most-significant bits
// of the destination mantissa.
int shift = CountLeadingZeros(mantissa << (32 - 10), 32);
// Shift mantissa and discard implicit '1'.
mantissa <<= (kFloatMantissaBits - kFloat16MantissaBits) + shift + 1;
mantissa &= (1 << kFloatMantissaBits) - 1;
// Adjust the exponent for the shift applied, and rebias.
exponent = exponent - shift + (kFloatExponentBias - kFloat16ExponentBias);
break;
}
case FP_NAN: {
if (IsSignallingNaN(value)) {
FPProcessException();
}
if (DN()) return kFP32DefaultNaN;
// Convert NaNs as the processor would:
// - The sign is propagated.
// - The mantissa is transferred entirely, except that the top bit is
// forced to '1', making the result a quiet NaN. The unused (low-order)
// mantissa bits are set to 0.
exponent = (1 << kFloatExponentBits) - 1;
// Increase bits in mantissa, making low-order bits 0.
mantissa <<= (kFloatMantissaBits - kFloat16MantissaBits);
mantissa |= 1 << (kFloatMantissaBits - 1); // Force a quiet NaN.
break;
}
case FP_NORMAL: {
// Increase bits in mantissa, making low-order bits 0.
mantissa <<= (kFloatMantissaBits - kFloat16MantissaBits);
// Change exponent bias.
exponent += (kFloatExponentBias - kFloat16ExponentBias);
break;
}
default:
UNREACHABLE();
}
return float_pack(sign, exponent, mantissa);
}
float16 Simulator::FPToFloat16(float value, FPRounding round_mode) {
// Only the FPTieEven rounding mode is implemented.
DCHECK_EQ(round_mode, FPTieEven);
USE(round_mode);
int64_t sign = float_sign(value);
int64_t exponent =
static_cast<int64_t>(float_exp(value)) - kFloatExponentBias;
uint32_t mantissa = float_mantissa(value);
switch (std::fpclassify(value)) {
case FP_NAN: {
if (IsSignallingNaN(value)) {
FPProcessException();
}
if (DN()) return kFP16DefaultNaN;
// Convert NaNs as the processor would:
// - The sign is propagated.
// - The mantissa is transferred as much as possible, except that the top
// bit is forced to '1', making the result a quiet NaN.
float16 result =
(sign == 0) ? kFP16PositiveInfinity : kFP16NegativeInfinity;
result |= mantissa >> (kFloatMantissaBits - kFloat16MantissaBits);
result |= (1 << (kFloat16MantissaBits - 1)); // Force a quiet NaN;
return result;
}
case FP_ZERO:
return (sign == 0) ? 0 : 0x8000;
case FP_INFINITE:
return (sign == 0) ? kFP16PositiveInfinity : kFP16NegativeInfinity;
case FP_NORMAL:
case FP_SUBNORMAL: {
// Convert float-to-half as the processor would, assuming that FPCR.FZ
// (flush-to-zero) is not set.
// Add the implicit '1' bit to the mantissa.
mantissa += (1 << kFloatMantissaBits);
return FPRoundToFloat16(sign, exponent, mantissa, round_mode);
}
}
UNREACHABLE();
}
float16 Simulator::FPToFloat16(double value, FPRounding round_mode) {
// Only the FPTieEven rounding mode is implemented.
DCHECK_EQ(round_mode, FPTieEven);
USE(round_mode);
int64_t sign = double_sign(value);
int64_t exponent =
static_cast<int64_t>(double_exp(value)) - kDoubleExponentBias;
uint64_t mantissa = double_mantissa(value);
switch (std::fpclassify(value)) {
case FP_NAN: {
if (IsSignallingNaN(value)) {
FPProcessException();
}
if (DN()) return kFP16DefaultNaN;
// Convert NaNs as the processor would:
// - The sign is propagated.
// - The mantissa is transferred as much as possible, except that the top
// bit is forced to '1', making the result a quiet NaN.
float16 result =
(sign == 0) ? kFP16PositiveInfinity : kFP16NegativeInfinity;
result |= mantissa >> (kDoubleMantissaBits - kFloat16MantissaBits);
result |= (1 << (kFloat16MantissaBits - 1)); // Force a quiet NaN;
return result;
}
case FP_ZERO:
return (sign == 0) ? 0 : 0x8000;
case FP_INFINITE:
return (sign == 0) ? kFP16PositiveInfinity : kFP16NegativeInfinity;
case FP_NORMAL:
case FP_SUBNORMAL: {
// Convert double-to-half as the processor would, assuming that FPCR.FZ
// (flush-to-zero) is not set.
// Add the implicit '1' bit to the mantissa.
mantissa += (UINT64_C(1) << kDoubleMantissaBits);
return FPRoundToFloat16(sign, exponent, mantissa, round_mode);
}
}
UNREACHABLE();
}
float Simulator::FPToFloat(double value, FPRounding round_mode) {
// Only the FPTieEven rounding mode is implemented.
DCHECK((round_mode == FPTieEven) || (round_mode == FPRoundOdd));
USE(round_mode);
switch (std::fpclassify(value)) {
case FP_NAN: {
if (IsSignallingNaN(value)) {
FPProcessException();
}
if (DN()) return kFP32DefaultNaN;
// Convert NaNs as the processor would:
// - The sign is propagated.
// - The mantissa is transferred as much as possible, except that the
// top bit is forced to '1', making the result a quiet NaN.
uint64_t raw = bit_cast<uint64_t>(value);
uint32_t sign = raw >> 63;
uint32_t exponent = (1 << 8) - 1;
uint32_t mantissa = static_cast<uint32_t>(unsigned_bitextract_64(
50, kDoubleMantissaBits - kFloatMantissaBits, raw));
mantissa |= (1 << (kFloatMantissaBits - 1)); // Force a quiet NaN.
return float_pack(sign, exponent, mantissa);
}
case FP_ZERO:
case FP_INFINITE: {
// In a C++ cast, any value representable in the target type will be
// unchanged. This is always the case for +/-0.0 and infinities.
return static_cast<float>(value);
}
case FP_NORMAL:
case FP_SUBNORMAL: {
// Convert double-to-float as the processor would, assuming that FPCR.FZ
// (flush-to-zero) is not set.
uint32_t sign = double_sign(value);
int64_t exponent =
static_cast<int64_t>(double_exp(value)) - kDoubleExponentBias;
uint64_t mantissa = double_mantissa(value);
if (std::fpclassify(value) == FP_NORMAL) {
// For normal FP values, add the hidden bit.
mantissa |= (UINT64_C(1) << kDoubleMantissaBits);
}
return FPRoundToFloat(sign, exponent, mantissa, round_mode);
}
}
UNREACHABLE();
}
void Simulator::ld1(VectorFormat vform, LogicVRegister dst, uint64_t addr) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.ReadUintFromMem(vform, i, addr);
addr += LaneSizeInBytesFromFormat(vform);
}
}
void Simulator::ld1(VectorFormat vform, LogicVRegister dst, int index,
uint64_t addr) {
dst.ReadUintFromMem(vform, index, addr);
}
void Simulator::ld1r(VectorFormat vform, LogicVRegister dst, uint64_t addr) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.ReadUintFromMem(vform, i, addr);
}
}
void Simulator::ld2(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, uint64_t addr1) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
int esize = LaneSizeInBytesFromFormat(vform);
uint64_t addr2 = addr1 + esize;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst1.ReadUintFromMem(vform, i, addr1);
dst2.ReadUintFromMem(vform, i, addr2);
addr1 += 2 * esize;
addr2 += 2 * esize;
}
}
void Simulator::ld2(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, int index, uint64_t addr1) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
uint64_t addr2 = addr1 + LaneSizeInBytesFromFormat(vform);
dst1.ReadUintFromMem(vform, index, addr1);
dst2.ReadUintFromMem(vform, index, addr2);
}
void Simulator::ld2r(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, uint64_t addr) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
uint64_t addr2 = addr + LaneSizeInBytesFromFormat(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst1.ReadUintFromMem(vform, i, addr);
dst2.ReadUintFromMem(vform, i, addr2);
}
}
void Simulator::ld3(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, LogicVRegister dst3, uint64_t addr1) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
dst3.ClearForWrite(vform);
int esize = LaneSizeInBytesFromFormat(vform);
uint64_t addr2 = addr1 + esize;
uint64_t addr3 = addr2 + esize;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst1.ReadUintFromMem(vform, i, addr1);
dst2.ReadUintFromMem(vform, i, addr2);
dst3.ReadUintFromMem(vform, i, addr3);
addr1 += 3 * esize;
addr2 += 3 * esize;
addr3 += 3 * esize;
}
}
void Simulator::ld3(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, LogicVRegister dst3, int index,
uint64_t addr1) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
dst3.ClearForWrite(vform);
uint64_t addr2 = addr1 + LaneSizeInBytesFromFormat(vform);
uint64_t addr3 = addr2 + LaneSizeInBytesFromFormat(vform);
dst1.ReadUintFromMem(vform, index, addr1);
dst2.ReadUintFromMem(vform, index, addr2);
dst3.ReadUintFromMem(vform, index, addr3);
}
void Simulator::ld3r(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, LogicVRegister dst3, uint64_t addr) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
dst3.ClearForWrite(vform);
uint64_t addr2 = addr + LaneSizeInBytesFromFormat(vform);
uint64_t addr3 = addr2 + LaneSizeInBytesFromFormat(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst1.ReadUintFromMem(vform, i, addr);
dst2.ReadUintFromMem(vform, i, addr2);
dst3.ReadUintFromMem(vform, i, addr3);
}
}
void Simulator::ld4(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, LogicVRegister dst3,
LogicVRegister dst4, uint64_t addr1) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
dst3.ClearForWrite(vform);
dst4.ClearForWrite(vform);
int esize = LaneSizeInBytesFromFormat(vform);
uint64_t addr2 = addr1 + esize;
uint64_t addr3 = addr2 + esize;
uint64_t addr4 = addr3 + esize;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst1.ReadUintFromMem(vform, i, addr1);
dst2.ReadUintFromMem(vform, i, addr2);
dst3.ReadUintFromMem(vform, i, addr3);
dst4.ReadUintFromMem(vform, i, addr4);
addr1 += 4 * esize;
addr2 += 4 * esize;
addr3 += 4 * esize;
addr4 += 4 * esize;
}
}
void Simulator::ld4(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, LogicVRegister dst3,
LogicVRegister dst4, int index, uint64_t addr1) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
dst3.ClearForWrite(vform);
dst4.ClearForWrite(vform);
uint64_t addr2 = addr1 + LaneSizeInBytesFromFormat(vform);
uint64_t addr3 = addr2 + LaneSizeInBytesFromFormat(vform);
uint64_t addr4 = addr3 + LaneSizeInBytesFromFormat(vform);
dst1.ReadUintFromMem(vform, index, addr1);
dst2.ReadUintFromMem(vform, index, addr2);
dst3.ReadUintFromMem(vform, index, addr3);
dst4.ReadUintFromMem(vform, index, addr4);
}
void Simulator::ld4r(VectorFormat vform, LogicVRegister dst1,
LogicVRegister dst2, LogicVRegister dst3,
LogicVRegister dst4, uint64_t addr) {
dst1.ClearForWrite(vform);
dst2.ClearForWrite(vform);
dst3.ClearForWrite(vform);
dst4.ClearForWrite(vform);
uint64_t addr2 = addr + LaneSizeInBytesFromFormat(vform);
uint64_t addr3 = addr2 + LaneSizeInBytesFromFormat(vform);
uint64_t addr4 = addr3 + LaneSizeInBytesFromFormat(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst1.ReadUintFromMem(vform, i, addr);
dst2.ReadUintFromMem(vform, i, addr2);
dst3.ReadUintFromMem(vform, i, addr3);
dst4.ReadUintFromMem(vform, i, addr4);
}
}
void Simulator::st1(VectorFormat vform, LogicVRegister src, uint64_t addr) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
src.WriteUintToMem(vform, i, addr);
addr += LaneSizeInBytesFromFormat(vform);
}
}
void Simulator::st1(VectorFormat vform, LogicVRegister src, int index,
uint64_t addr) {
src.WriteUintToMem(vform, index, addr);
}
void Simulator::st2(VectorFormat vform, LogicVRegister dst, LogicVRegister dst2,
uint64_t addr) {
int esize = LaneSizeInBytesFromFormat(vform);
uint64_t addr2 = addr + esize;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.WriteUintToMem(vform, i, addr);
dst2.WriteUintToMem(vform, i, addr2);
addr += 2 * esize;
addr2 += 2 * esize;
}
}
void Simulator::st2(VectorFormat vform, LogicVRegister dst, LogicVRegister dst2,
int index, uint64_t addr) {
int esize = LaneSizeInBytesFromFormat(vform);
dst.WriteUintToMem(vform, index, addr);
dst2.WriteUintToMem(vform, index, addr + 1 * esize);
}
void Simulator::st3(VectorFormat vform, LogicVRegister dst, LogicVRegister dst2,
LogicVRegister dst3, uint64_t addr) {
int esize = LaneSizeInBytesFromFormat(vform);
uint64_t addr2 = addr + esize;
uint64_t addr3 = addr2 + esize;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.WriteUintToMem(vform, i, addr);
dst2.WriteUintToMem(vform, i, addr2);
dst3.WriteUintToMem(vform, i, addr3);
addr += 3 * esize;
addr2 += 3 * esize;
addr3 += 3 * esize;
}
}
void Simulator::st3(VectorFormat vform, LogicVRegister dst, LogicVRegister dst2,
LogicVRegister dst3, int index, uint64_t addr) {
int esize = LaneSizeInBytesFromFormat(vform);
dst.WriteUintToMem(vform, index, addr);
dst2.WriteUintToMem(vform, index, addr + 1 * esize);
dst3.WriteUintToMem(vform, index, addr + 2 * esize);
}
void Simulator::st4(VectorFormat vform, LogicVRegister dst, LogicVRegister dst2,
LogicVRegister dst3, LogicVRegister dst4, uint64_t addr) {
int esize = LaneSizeInBytesFromFormat(vform);
uint64_t addr2 = addr + esize;
uint64_t addr3 = addr2 + esize;
uint64_t addr4 = addr3 + esize;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.WriteUintToMem(vform, i, addr);
dst2.WriteUintToMem(vform, i, addr2);
dst3.WriteUintToMem(vform, i, addr3);
dst4.WriteUintToMem(vform, i, addr4);
addr += 4 * esize;
addr2 += 4 * esize;
addr3 += 4 * esize;
addr4 += 4 * esize;
}
}
void Simulator::st4(VectorFormat vform, LogicVRegister dst, LogicVRegister dst2,
LogicVRegister dst3, LogicVRegister dst4, int index,
uint64_t addr) {
int esize = LaneSizeInBytesFromFormat(vform);
dst.WriteUintToMem(vform, index, addr);
dst2.WriteUintToMem(vform, index, addr + 1 * esize);
dst3.WriteUintToMem(vform, index, addr + 2 * esize);
dst4.WriteUintToMem(vform, index, addr + 3 * esize);
}
LogicVRegister Simulator::cmp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, Condition cond) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
int64_t sa = src1.Int(vform, i);
int64_t sb = src2.Int(vform, i);
uint64_t ua = src1.Uint(vform, i);
uint64_t ub = src2.Uint(vform, i);
bool result = false;
switch (cond) {
case eq:
result = (ua == ub);
break;
case ge:
result = (sa >= sb);
break;
case gt:
result = (sa > sb);
break;
case hi:
result = (ua > ub);
break;
case hs:
result = (ua >= ub);
break;
case lt:
result = (sa < sb);
break;
case le:
result = (sa <= sb);
break;
default:
UNREACHABLE();
}
dst.SetUint(vform, i, result ? MaxUintFromFormat(vform) : 0);
}
return dst;
}
LogicVRegister Simulator::cmp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1, int imm,
Condition cond) {
SimVRegister temp;
LogicVRegister imm_reg = dup_immediate(vform, temp, imm);
return cmp(vform, dst, src1, imm_reg, cond);
}
LogicVRegister Simulator::cmptst(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t ua = src1.Uint(vform, i);
uint64_t ub = src2.Uint(vform, i);
dst.SetUint(vform, i, ((ua & ub) != 0) ? MaxUintFromFormat(vform) : 0);
}
return dst;
}
LogicVRegister Simulator::add(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
int lane_size = LaneSizeInBitsFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
// Test for unsigned saturation.
uint64_t ua = src1.UintLeftJustified(vform, i);
uint64_t ub = src2.UintLeftJustified(vform, i);
uint64_t ur = ua + ub;
if (ur < ua) {
dst.SetUnsignedSat(i, true);
}
// Test for signed saturation.
bool pos_a = (ua >> 63) == 0;
bool pos_b = (ub >> 63) == 0;
bool pos_r = (ur >> 63) == 0;
// If the signs of the operands are the same, but different from the result,
// there was an overflow.
if ((pos_a == pos_b) && (pos_a != pos_r)) {
dst.SetSignedSat(i, pos_a);
}
dst.SetInt(vform, i, ur >> (64 - lane_size));
}
return dst;
}
LogicVRegister Simulator::addp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uzp1(vform, temp1, src1, src2);
uzp2(vform, temp2, src1, src2);
add(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::mla(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
mul(vform, temp, src1, src2);
add(vform, dst, dst, temp);
return dst;
}
LogicVRegister Simulator::mls(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
mul(vform, temp, src1, src2);
sub(vform, dst, dst, temp);
return dst;
}
LogicVRegister Simulator::mul(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src1.Uint(vform, i) * src2.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::mul(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform = VectorFormatFillQ(vform);
return mul(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::mla(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform = VectorFormatFillQ(vform);
return mla(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::mls(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform = VectorFormatFillQ(vform);
return mls(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::smull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return smull(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::smull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return smull2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::umull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return umull(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::umull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return umull2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::smlal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return smlal(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::smlal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return smlal2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::umlal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return umlal(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::umlal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return umlal2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::smlsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return smlsl(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::smlsl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return smlsl2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::umlsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return umlsl(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::umlsl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return umlsl2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return sqdmull(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return sqdmull2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmlal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return sqdmlal(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmlal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return sqdmlal2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmlsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return sqdmlsl(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmlsl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform =
VectorFormatHalfWidthDoubleLanes(VectorFormatFillQ(vform));
return sqdmlsl2(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqdmulh(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform = VectorFormatFillQ(vform);
return sqdmulh(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
LogicVRegister Simulator::sqrdmulh(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
SimVRegister temp;
VectorFormat indexform = VectorFormatFillQ(vform);
return sqrdmulh(vform, dst, src1, dup_element(indexform, temp, src2, index));
}
uint16_t Simulator::PolynomialMult(uint8_t op1, uint8_t op2) {
uint16_t result = 0;
uint16_t extended_op2 = op2;
for (int i = 0; i < 8; ++i) {
if ((op1 >> i) & 1) {
result = result ^ (extended_op2 << i);
}
}
return result;
}
LogicVRegister Simulator::pmul(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i,
PolynomialMult(src1.Uint(vform, i), src2.Uint(vform, i)));
}
return dst;
}
LogicVRegister Simulator::pmull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
VectorFormat vform_src = VectorFormatHalfWidth(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(
vform, i,
PolynomialMult(src1.Uint(vform_src, i), src2.Uint(vform_src, i)));
}
return dst;
}
LogicVRegister Simulator::pmull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
VectorFormat vform_src = VectorFormatHalfWidthDoubleLanes(vform);
dst.ClearForWrite(vform);
int lane_count = LaneCountFromFormat(vform);
for (int i = 0; i < lane_count; i++) {
dst.SetUint(vform, i,
PolynomialMult(src1.Uint(vform_src, lane_count + i),
src2.Uint(vform_src, lane_count + i)));
}
return dst;
}
LogicVRegister Simulator::sub(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
int lane_size = LaneSizeInBitsFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
// Test for unsigned saturation.
uint64_t ua = src1.UintLeftJustified(vform, i);
uint64_t ub = src2.UintLeftJustified(vform, i);
uint64_t ur = ua - ub;
if (ub > ua) {
dst.SetUnsignedSat(i, false);
}
// Test for signed saturation.
bool pos_a = (ua >> 63) == 0;
bool pos_b = (ub >> 63) == 0;
bool pos_r = (ur >> 63) == 0;
// If the signs of the operands are different, and the sign of the first
// operand doesn't match the result, there was an overflow.
if ((pos_a != pos_b) && (pos_a != pos_r)) {
dst.SetSignedSat(i, pos_a);
}
dst.SetInt(vform, i, ur >> (64 - lane_size));
}
return dst;
}
LogicVRegister Simulator::and_(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src1.Uint(vform, i) & src2.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::orr(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src1.Uint(vform, i) | src2.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::orn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src1.Uint(vform, i) | ~src2.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::eor(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src1.Uint(vform, i) ^ src2.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::bic(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src1.Uint(vform, i) & ~src2.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::bic(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, uint64_t imm) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; ++i) {
result[i] = src.Uint(vform, i) & ~imm;
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::bif(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t operand1 = dst.Uint(vform, i);
uint64_t operand2 = ~src2.Uint(vform, i);
uint64_t operand3 = src1.Uint(vform, i);
uint64_t result = operand1 ^ ((operand1 ^ operand3) & operand2);
dst.SetUint(vform, i, result);
}
return dst;
}
LogicVRegister Simulator::bit(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t operand1 = dst.Uint(vform, i);
uint64_t operand2 = src2.Uint(vform, i);
uint64_t operand3 = src1.Uint(vform, i);
uint64_t result = operand1 ^ ((operand1 ^ operand3) & operand2);
dst.SetUint(vform, i, result);
}
return dst;
}
LogicVRegister Simulator::bsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t operand1 = src2.Uint(vform, i);
uint64_t operand2 = dst.Uint(vform, i);
uint64_t operand3 = src1.Uint(vform, i);
uint64_t result = operand1 ^ ((operand1 ^ operand3) & operand2);
dst.SetUint(vform, i, result);
}
return dst;
}
LogicVRegister Simulator::SMinMax(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, bool max) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
int64_t src1_val = src1.Int(vform, i);
int64_t src2_val = src2.Int(vform, i);
int64_t dst_val;
if (max) {
dst_val = (src1_val > src2_val) ? src1_val : src2_val;
} else {
dst_val = (src1_val < src2_val) ? src1_val : src2_val;
}
dst.SetInt(vform, i, dst_val);
}
return dst;
}
LogicVRegister Simulator::smax(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return SMinMax(vform, dst, src1, src2, true);
}
LogicVRegister Simulator::smin(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return SMinMax(vform, dst, src1, src2, false);
}
LogicVRegister Simulator::SMinMaxP(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, bool max) {
int lanes = LaneCountFromFormat(vform);
int64_t result[kMaxLanesPerVector];
const LogicVRegister* src = &src1;
for (int j = 0; j < 2; j++) {
for (int i = 0; i < lanes; i += 2) {
int64_t first_val = src->Int(vform, i);
int64_t second_val = src->Int(vform, i + 1);
int64_t dst_val;
if (max) {
dst_val = (first_val > second_val) ? first_val : second_val;
} else {
dst_val = (first_val < second_val) ? first_val : second_val;
}
DCHECK_LT((i >> 1) + (j * lanes / 2), kMaxLanesPerVector);
result[(i >> 1) + (j * lanes / 2)] = dst_val;
}
src = &src2;
}
dst.SetIntArray(vform, result);
return dst;
}
LogicVRegister Simulator::smaxp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return SMinMaxP(vform, dst, src1, src2, true);
}
LogicVRegister Simulator::sminp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return SMinMaxP(vform, dst, src1, src2, false);
}
LogicVRegister Simulator::addp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
DCHECK_EQ(vform, kFormatD);
uint64_t dst_val = src.Uint(kFormat2D, 0) + src.Uint(kFormat2D, 1);
dst.ClearForWrite(vform);
dst.SetUint(vform, 0, dst_val);
return dst;
}
LogicVRegister Simulator::addv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_dst =
ScalarFormatFromLaneSize(LaneSizeInBitsFromFormat(vform));
int64_t dst_val = 0;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst_val += src.Int(vform, i);
}
dst.ClearForWrite(vform_dst);
dst.SetInt(vform_dst, 0, dst_val);
return dst;
}
LogicVRegister Simulator::saddlv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_dst =
ScalarFormatFromLaneSize(LaneSizeInBitsFromFormat(vform) * 2);
int64_t dst_val = 0;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst_val += src.Int(vform, i);
}
dst.ClearForWrite(vform_dst);
dst.SetInt(vform_dst, 0, dst_val);
return dst;
}
LogicVRegister Simulator::uaddlv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_dst =
ScalarFormatFromLaneSize(LaneSizeInBitsFromFormat(vform) * 2);
uint64_t dst_val = 0;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst_val += src.Uint(vform, i);
}
dst.ClearForWrite(vform_dst);
dst.SetUint(vform_dst, 0, dst_val);
return dst;
}
LogicVRegister Simulator::SMinMaxV(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, bool max) {
int64_t dst_val = max ? INT64_MIN : INT64_MAX;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
int64_t src_val = src.Int(vform, i);
if (max) {
dst_val = (src_val > dst_val) ? src_val : dst_val;
} else {
dst_val = (src_val < dst_val) ? src_val : dst_val;
}
}
dst.ClearForWrite(ScalarFormatFromFormat(vform));
dst.SetInt(vform, 0, dst_val);
return dst;
}
LogicVRegister Simulator::smaxv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
SMinMaxV(vform, dst, src, true);
return dst;
}
LogicVRegister Simulator::sminv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
SMinMaxV(vform, dst, src, false);
return dst;
}
LogicVRegister Simulator::UMinMax(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, bool max) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t src1_val = src1.Uint(vform, i);
uint64_t src2_val = src2.Uint(vform, i);
uint64_t dst_val;
if (max) {
dst_val = (src1_val > src2_val) ? src1_val : src2_val;
} else {
dst_val = (src1_val < src2_val) ? src1_val : src2_val;
}
dst.SetUint(vform, i, dst_val);
}
return dst;
}
LogicVRegister Simulator::umax(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return UMinMax(vform, dst, src1, src2, true);
}
LogicVRegister Simulator::umin(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return UMinMax(vform, dst, src1, src2, false);
}
LogicVRegister Simulator::UMinMaxP(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, bool max) {
int lanes = LaneCountFromFormat(vform);
uint64_t result[kMaxLanesPerVector];
const LogicVRegister* src = &src1;
for (int j = 0; j < 2; j++) {
for (int i = 0; i < LaneCountFromFormat(vform); i += 2) {
uint64_t first_val = src->Uint(vform, i);
uint64_t second_val = src->Uint(vform, i + 1);
uint64_t dst_val;
if (max) {
dst_val = (first_val > second_val) ? first_val : second_val;
} else {
dst_val = (first_val < second_val) ? first_val : second_val;
}
DCHECK_LT((i >> 1) + (j * lanes / 2), kMaxLanesPerVector);
result[(i >> 1) + (j * lanes / 2)] = dst_val;
}
src = &src2;
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::umaxp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return UMinMaxP(vform, dst, src1, src2, true);
}
LogicVRegister Simulator::uminp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return UMinMaxP(vform, dst, src1, src2, false);
}
LogicVRegister Simulator::UMinMaxV(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, bool max) {
uint64_t dst_val = max ? 0 : UINT64_MAX;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t src_val = src.Uint(vform, i);
if (max) {
dst_val = (src_val > dst_val) ? src_val : dst_val;
} else {
dst_val = (src_val < dst_val) ? src_val : dst_val;
}
}
dst.ClearForWrite(ScalarFormatFromFormat(vform));
dst.SetUint(vform, 0, dst_val);
return dst;
}
LogicVRegister Simulator::umaxv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
UMinMaxV(vform, dst, src, true);
return dst;
}
LogicVRegister Simulator::uminv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
UMinMaxV(vform, dst, src, false);
return dst;
}
LogicVRegister Simulator::shl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp;
LogicVRegister shiftreg = dup_immediate(vform, temp, shift);
return ushl(vform, dst, src, shiftreg);
}
LogicVRegister Simulator::sshll(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp1, temp2;
LogicVRegister shiftreg = dup_immediate(vform, temp1, shift);
LogicVRegister extendedreg = sxtl(vform, temp2, src);
return sshl(vform, dst, extendedreg, shiftreg);
}
LogicVRegister Simulator::sshll2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp1, temp2;
LogicVRegister shiftreg = dup_immediate(vform, temp1, shift);
LogicVRegister extendedreg = sxtl2(vform, temp2, src);
return sshl(vform, dst, extendedreg, shiftreg);
}
LogicVRegister Simulator::shll(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
int shift = LaneSizeInBitsFromFormat(vform) / 2;
return sshll(vform, dst, src, shift);
}
LogicVRegister Simulator::shll2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
int shift = LaneSizeInBitsFromFormat(vform) / 2;
return sshll2(vform, dst, src, shift);
}
LogicVRegister Simulator::ushll(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp1, temp2;
LogicVRegister shiftreg = dup_immediate(vform, temp1, shift);
LogicVRegister extendedreg = uxtl(vform, temp2, src);
return ushl(vform, dst, extendedreg, shiftreg);
}
LogicVRegister Simulator::ushll2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp1, temp2;
LogicVRegister shiftreg = dup_immediate(vform, temp1, shift);
LogicVRegister extendedreg = uxtl2(vform, temp2, src);
return ushl(vform, dst, extendedreg, shiftreg);
}
LogicVRegister Simulator::sli(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
dst.ClearForWrite(vform);
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; i++) {
uint64_t src_lane = src.Uint(vform, i);
uint64_t dst_lane = dst.Uint(vform, i);
uint64_t shifted = src_lane << shift;
uint64_t mask = MaxUintFromFormat(vform) << shift;
dst.SetUint(vform, i, (dst_lane & ~mask) | shifted);
}
return dst;
}
LogicVRegister Simulator::sqshl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp;
LogicVRegister shiftreg = dup_immediate(vform, temp, shift);
return sshl(vform, dst, src, shiftreg).SignedSaturate(vform);
}
LogicVRegister Simulator::uqshl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp;
LogicVRegister shiftreg = dup_immediate(vform, temp, shift);
return ushl(vform, dst, src, shiftreg).UnsignedSaturate(vform);
}
LogicVRegister Simulator::sqshlu(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp;
LogicVRegister shiftreg = dup_immediate(vform, temp, shift);
return sshl(vform, dst, src, shiftreg).UnsignedSaturate(vform);
}
LogicVRegister Simulator::sri(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
dst.ClearForWrite(vform);
int laneCount = LaneCountFromFormat(vform);
DCHECK((shift > 0) &&
(shift <= static_cast<int>(LaneSizeInBitsFromFormat(vform))));
for (int i = 0; i < laneCount; i++) {
uint64_t src_lane = src.Uint(vform, i);
uint64_t dst_lane = dst.Uint(vform, i);
uint64_t shifted;
uint64_t mask;
if (shift == 64) {
shifted = 0;
mask = 0;
} else {
shifted = src_lane >> shift;
mask = MaxUintFromFormat(vform) >> shift;
}
dst.SetUint(vform, i, (dst_lane & ~mask) | shifted);
}
return dst;
}
LogicVRegister Simulator::ushr(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp;
LogicVRegister shiftreg = dup_immediate(vform, temp, -shift);
return ushl(vform, dst, src, shiftreg);
}
LogicVRegister Simulator::sshr(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
DCHECK_GE(shift, 0);
SimVRegister temp;
LogicVRegister shiftreg = dup_immediate(vform, temp, -shift);
return sshl(vform, dst, src, shiftreg);
}
LogicVRegister Simulator::ssra(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
LogicVRegister shifted_reg = sshr(vform, temp, src, shift);
return add(vform, dst, dst, shifted_reg);
}
LogicVRegister Simulator::usra(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
LogicVRegister shifted_reg = ushr(vform, temp, src, shift);
return add(vform, dst, dst, shifted_reg);
}
LogicVRegister Simulator::srsra(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
LogicVRegister shifted_reg = sshr(vform, temp, src, shift).Round(vform);
return add(vform, dst, dst, shifted_reg);
}
LogicVRegister Simulator::ursra(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
LogicVRegister shifted_reg = ushr(vform, temp, src, shift).Round(vform);
return add(vform, dst, dst, shifted_reg);
}
LogicVRegister Simulator::cls(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
uint64_t result[16];
int laneSizeInBits = LaneSizeInBitsFromFormat(vform);
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; i++) {
result[i] = CountLeadingSignBits(src.Int(vform, i), laneSizeInBits);
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::clz(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
uint64_t result[16];
int laneSizeInBits = LaneSizeInBitsFromFormat(vform);
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; i++) {
result[i] = CountLeadingZeros(src.Uint(vform, i), laneSizeInBits);
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::cnt(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
uint64_t result[16];
int laneSizeInBits = LaneSizeInBitsFromFormat(vform);
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; i++) {
uint64_t value = src.Uint(vform, i);
result[i] = 0;
for (int j = 0; j < laneSizeInBits; j++) {
result[i] += (value & 1);
value >>= 1;
}
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::sshl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
int8_t shift_val = src2.Int(vform, i);
int64_t lj_src_val = src1.IntLeftJustified(vform, i);
// Set signed saturation state.
if ((shift_val > CountLeadingSignBits(lj_src_val, 64)) &&
(lj_src_val != 0)) {
dst.SetSignedSat(i, lj_src_val >= 0);
}
// Set unsigned saturation state.
if (lj_src_val < 0) {
dst.SetUnsignedSat(i, false);
} else if ((shift_val > CountLeadingZeros(lj_src_val, 64)) &&
(lj_src_val != 0)) {
dst.SetUnsignedSat(i, true);
}
int64_t src_val = src1.Int(vform, i);
bool src_is_negative = src_val < 0;
if (shift_val > 63) {
dst.SetInt(vform, i, 0);
} else if (shift_val < -63) {
dst.SetRounding(i, src_is_negative);
dst.SetInt(vform, i, src_is_negative ? -1 : 0);
} else {
// Use unsigned types for shifts, as behaviour is undefined for signed
// lhs.
uint64_t usrc_val = static_cast<uint64_t>(src_val);
if (shift_val < 0) {
// Convert to right shift.
shift_val = -shift_val;
// Set rounding state by testing most-significant bit shifted out.
// Rounding only needed on right shifts.
if (((usrc_val >> (shift_val - 1)) & 1) == 1) {
dst.SetRounding(i, true);
}
usrc_val >>= shift_val;
if (src_is_negative) {
// Simulate sign-extension.
usrc_val |= (~UINT64_C(0) << (64 - shift_val));
}
} else {
usrc_val <<= shift_val;
}
dst.SetUint(vform, i, usrc_val);
}
}
return dst;
}
LogicVRegister Simulator::ushl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
int8_t shift_val = src2.Int(vform, i);
uint64_t lj_src_val = src1.UintLeftJustified(vform, i);
// Set saturation state.
if ((shift_val > CountLeadingZeros(lj_src_val, 64)) && (lj_src_val != 0)) {
dst.SetUnsignedSat(i, true);
}
uint64_t src_val = src1.Uint(vform, i);
if ((shift_val > 63) || (shift_val < -64)) {
dst.SetUint(vform, i, 0);
} else {
if (shift_val < 0) {
// Set rounding state. Rounding only needed on right shifts.
if (((src_val >> (-shift_val - 1)) & 1) == 1) {
dst.SetRounding(i, true);
}
if (shift_val == -64) {
src_val = 0;
} else {
src_val >>= -shift_val;
}
} else {
src_val <<= shift_val;
}
dst.SetUint(vform, i, src_val);
}
}
return dst;
}
LogicVRegister Simulator::neg(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
// Test for signed saturation.
int64_t sa = src.Int(vform, i);
if (sa == MinIntFromFormat(vform)) {
dst.SetSignedSat(i, true);
}
dst.SetInt(vform, i, (sa == INT64_MIN) ? sa : -sa);
}
return dst;
}
LogicVRegister Simulator::suqadd(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
int64_t sa = dst.IntLeftJustified(vform, i);
uint64_t ub = src.UintLeftJustified(vform, i);
uint64_t ur = sa + ub;
int64_t sr = bit_cast<int64_t>(ur);
if (sr < sa) { // Test for signed positive saturation.
dst.SetInt(vform, i, MaxIntFromFormat(vform));
} else {
dst.SetUint(vform, i, dst.Int(vform, i) + src.Uint(vform, i));
}
}
return dst;
}
LogicVRegister Simulator::usqadd(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t ua = dst.UintLeftJustified(vform, i);
int64_t sb = src.IntLeftJustified(vform, i);
uint64_t ur = ua + sb;
if ((sb > 0) && (ur <= ua)) {
dst.SetUint(vform, i, MaxUintFromFormat(vform)); // Positive saturation.
} else if ((sb < 0) && (ur >= ua)) {
dst.SetUint(vform, i, 0); // Negative saturation.
} else {
dst.SetUint(vform, i, dst.Uint(vform, i) + src.Int(vform, i));
}
}
return dst;
}
LogicVRegister Simulator::abs(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
// Test for signed saturation.
int64_t sa = src.Int(vform, i);
if (sa == MinIntFromFormat(vform)) {
dst.SetSignedSat(i, true);
}
if (sa < 0) {
dst.SetInt(vform, i, (sa == INT64_MIN) ? sa : -sa);
} else {
dst.SetInt(vform, i, sa);
}
}
return dst;
}
LogicVRegister Simulator::ExtractNarrow(VectorFormat dstform,
LogicVRegister dst, bool dstIsSigned,
const LogicVRegister& src,
bool srcIsSigned) {
bool upperhalf = false;
VectorFormat srcform = kFormatUndefined;
int64_t ssrc[8];
uint64_t usrc[8];
switch (dstform) {
case kFormat8B:
upperhalf = false;
srcform = kFormat8H;
break;
case kFormat16B:
upperhalf = true;
srcform = kFormat8H;
break;
case kFormat4H:
upperhalf = false;
srcform = kFormat4S;
break;
case kFormat8H:
upperhalf = true;
srcform = kFormat4S;
break;
case kFormat2S:
upperhalf = false;
srcform = kFormat2D;
break;
case kFormat4S:
upperhalf = true;
srcform = kFormat2D;
break;
case kFormatB:
upperhalf = false;
srcform = kFormatH;
break;
case kFormatH:
upperhalf = false;
srcform = kFormatS;
break;
case kFormatS:
upperhalf = false;
srcform = kFormatD;
break;
default:
UNIMPLEMENTED();
}
for (int i = 0; i < LaneCountFromFormat(srcform); i++) {
ssrc[i] = src.Int(srcform, i);
usrc[i] = src.Uint(srcform, i);
}
int offset;
if (upperhalf) {
offset = LaneCountFromFormat(dstform) / 2;
} else {
offset = 0;
dst.ClearForWrite(dstform);
}
for (int i = 0; i < LaneCountFromFormat(srcform); i++) {
// Test for signed saturation
if (ssrc[i] > MaxIntFromFormat(dstform)) {
dst.SetSignedSat(offset + i, true);
} else if (ssrc[i] < MinIntFromFormat(dstform)) {
dst.SetSignedSat(offset + i, false);
}
// Test for unsigned saturation
if (srcIsSigned) {
if (ssrc[i] > static_cast<int64_t>(MaxUintFromFormat(dstform))) {
dst.SetUnsignedSat(offset + i, true);
} else if (ssrc[i] < 0) {
dst.SetUnsignedSat(offset + i, false);
}
} else {
if (usrc[i] > MaxUintFromFormat(dstform)) {
dst.SetUnsignedSat(offset + i, true);
}
}
int64_t result;
if (srcIsSigned) {
result = ssrc[i] & MaxUintFromFormat(dstform);
} else {
result = usrc[i] & MaxUintFromFormat(dstform);
}
if (dstIsSigned) {
dst.SetInt(dstform, offset + i, result);
} else {
dst.SetUint(dstform, offset + i, result);
}
}
return dst;
}
LogicVRegister Simulator::xtn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return ExtractNarrow(vform, dst, true, src, true);
}
LogicVRegister Simulator::sqxtn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return ExtractNarrow(vform, dst, true, src, true).SignedSaturate(vform);
}
LogicVRegister Simulator::sqxtun(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return ExtractNarrow(vform, dst, false, src, true).UnsignedSaturate(vform);
}
LogicVRegister Simulator::uqxtn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return ExtractNarrow(vform, dst, false, src, false).UnsignedSaturate(vform);
}
LogicVRegister Simulator::AbsDiff(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, bool issigned) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
if (issigned) {
int64_t sr = src1.Int(vform, i) - src2.Int(vform, i);
sr = sr > 0 ? sr : -sr;
dst.SetInt(vform, i, sr);
} else {
int64_t sr = src1.Uint(vform, i) - src2.Uint(vform, i);
sr = sr > 0 ? sr : -sr;
dst.SetUint(vform, i, sr);
}
}
return dst;
}
LogicVRegister Simulator::saba(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
dst.ClearForWrite(vform);
AbsDiff(vform, temp, src1, src2, true);
add(vform, dst, dst, temp);
return dst;
}
LogicVRegister Simulator::uaba(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
dst.ClearForWrite(vform);
AbsDiff(vform, temp, src1, src2, false);
add(vform, dst, dst, temp);
return dst;
}
LogicVRegister Simulator::not_(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, ~src.Uint(vform, i));
}
return dst;
}
LogicVRegister Simulator::rbit(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
int laneSizeInBits = LaneSizeInBitsFromFormat(vform);
uint64_t reversed_value;
uint64_t value;
for (int i = 0; i < laneCount; i++) {
value = src.Uint(vform, i);
reversed_value = 0;
for (int j = 0; j < laneSizeInBits; j++) {
reversed_value = (reversed_value << 1) | (value & 1);
value >>= 1;
}
result[i] = reversed_value;
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::rev(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int revSize) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
int laneSize = LaneSizeInBytesFromFormat(vform);
int lanesPerLoop = revSize / laneSize;
for (int i = 0; i < laneCount; i += lanesPerLoop) {
for (int j = 0; j < lanesPerLoop; j++) {
result[i + lanesPerLoop - 1 - j] = src.Uint(vform, i + j);
}
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::rev16(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return rev(vform, dst, src, 2);
}
LogicVRegister Simulator::rev32(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return rev(vform, dst, src, 4);
}
LogicVRegister Simulator::rev64(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return rev(vform, dst, src, 8);
}
LogicVRegister Simulator::addlp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, bool is_signed,
bool do_accumulate) {
VectorFormat vformsrc = VectorFormatHalfWidthDoubleLanes(vform);
DCHECK_LE(LaneSizeInBitsFromFormat(vformsrc), 32U);
DCHECK_LE(LaneCountFromFormat(vform), 8);
uint64_t result[8];
int lane_count = LaneCountFromFormat(vform);
for (int i = 0; i < lane_count; i++) {
if (is_signed) {
result[i] = static_cast<uint64_t>(src.Int(vformsrc, 2 * i) +
src.Int(vformsrc, 2 * i + 1));
} else {
result[i] = src.Uint(vformsrc, 2 * i) + src.Uint(vformsrc, 2 * i + 1);
}
}
dst.ClearForWrite(vform);
for (int i = 0; i < lane_count; ++i) {
if (do_accumulate) {
result[i] += dst.Uint(vform, i);
}
dst.SetUint(vform, i, result[i]);
}
return dst;
}
LogicVRegister Simulator::saddlp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return addlp(vform, dst, src, true, false);
}
LogicVRegister Simulator::uaddlp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return addlp(vform, dst, src, false, false);
}
LogicVRegister Simulator::sadalp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return addlp(vform, dst, src, true, true);
}
LogicVRegister Simulator::uadalp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return addlp(vform, dst, src, false, true);
}
LogicVRegister Simulator::ext(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
uint8_t result[16];
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount - index; ++i) {
result[i] = src1.Uint(vform, i + index);
}
for (int i = 0; i < index; ++i) {
result[laneCount - index + i] = src2.Uint(vform, i);
}
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, result[i]);
}
return dst;
}
LogicVRegister Simulator::dup_element(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src,
int src_index) {
int laneCount = LaneCountFromFormat(vform);
uint64_t value = src.Uint(vform, src_index);
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, value);
}
return dst;
}
LogicVRegister Simulator::dup_immediate(VectorFormat vform, LogicVRegister dst,
uint64_t imm) {
int laneCount = LaneCountFromFormat(vform);
uint64_t value = imm & MaxUintFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, value);
}
return dst;
}
LogicVRegister Simulator::ins_element(VectorFormat vform, LogicVRegister dst,
int dst_index, const LogicVRegister& src,
int src_index) {
dst.SetUint(vform, dst_index, src.Uint(vform, src_index));
return dst;
}
LogicVRegister Simulator::ins_immediate(VectorFormat vform, LogicVRegister dst,
int dst_index, uint64_t imm) {
uint64_t value = imm & MaxUintFromFormat(vform);
dst.SetUint(vform, dst_index, value);
return dst;
}
LogicVRegister Simulator::movi(VectorFormat vform, LogicVRegister dst,
uint64_t imm) {
int laneCount = LaneCountFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, imm);
}
return dst;
}
LogicVRegister Simulator::mvni(VectorFormat vform, LogicVRegister dst,
uint64_t imm) {
int laneCount = LaneCountFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, ~imm);
}
return dst;
}
LogicVRegister Simulator::orr(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, uint64_t imm) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; ++i) {
result[i] = src.Uint(vform, i) | imm;
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::uxtl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_half = VectorFormatHalfWidth(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetUint(vform, i, src.Uint(vform_half, i));
}
return dst;
}
LogicVRegister Simulator::sxtl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_half = VectorFormatHalfWidth(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetInt(vform, i, src.Int(vform_half, i));
}
return dst;
}
LogicVRegister Simulator::uxtl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_half = VectorFormatHalfWidth(vform);
int lane_count = LaneCountFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < lane_count; i++) {
dst.SetUint(vform, i, src.Uint(vform_half, lane_count + i));
}
return dst;
}
LogicVRegister Simulator::sxtl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
VectorFormat vform_half = VectorFormatHalfWidth(vform);
int lane_count = LaneCountFromFormat(vform);
dst.ClearForWrite(vform);
for (int i = 0; i < lane_count; i++) {
dst.SetInt(vform, i, src.Int(vform_half, lane_count + i));
}
return dst;
}
LogicVRegister Simulator::shrn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vform_src = VectorFormatDoubleWidth(vform);
VectorFormat vform_dst = vform;
LogicVRegister shifted_src = ushr(vform_src, temp, src, shift);
return ExtractNarrow(vform_dst, dst, false, shifted_src, false);
}
LogicVRegister Simulator::shrn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(VectorFormatHalfLanes(vform));
VectorFormat vformdst = vform;
LogicVRegister shifted_src = ushr(vformsrc, temp, src, shift);
return ExtractNarrow(vformdst, dst, false, shifted_src, false);
}
LogicVRegister Simulator::rshrn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(vform);
VectorFormat vformdst = vform;
LogicVRegister shifted_src = ushr(vformsrc, temp, src, shift).Round(vformsrc);
return ExtractNarrow(vformdst, dst, false, shifted_src, false);
}
LogicVRegister Simulator::rshrn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(VectorFormatHalfLanes(vform));
VectorFormat vformdst = vform;
LogicVRegister shifted_src = ushr(vformsrc, temp, src, shift).Round(vformsrc);
return ExtractNarrow(vformdst, dst, false, shifted_src, false);
}
LogicVRegister Simulator::Table(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& ind,
bool zero_out_of_bounds,
const LogicVRegister* tab1,
const LogicVRegister* tab2,
const LogicVRegister* tab3,
const LogicVRegister* tab4) {
DCHECK_NOT_NULL(tab1);
const LogicVRegister* tab[4] = {tab1, tab2, tab3, tab4};
uint64_t result[kMaxLanesPerVector];
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
result[i] = zero_out_of_bounds ? 0 : dst.Uint(kFormat16B, i);
}
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
uint64_t j = ind.Uint(vform, i);
int tab_idx = static_cast<int>(j >> 4);
int j_idx = static_cast<int>(j & 15);
if ((tab_idx < 4) && (tab[tab_idx] != nullptr)) {
result[i] = tab[tab_idx]->Uint(kFormat16B, j_idx);
}
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::tbl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& ind) {
return Table(vform, dst, ind, true, &tab);
}
LogicVRegister Simulator::tbl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& tab2,
const LogicVRegister& ind) {
return Table(vform, dst, ind, true, &tab, &tab2);
}
LogicVRegister Simulator::tbl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& tab2,
const LogicVRegister& tab3,
const LogicVRegister& ind) {
return Table(vform, dst, ind, true, &tab, &tab2, &tab3);
}
LogicVRegister Simulator::tbl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& tab2,
const LogicVRegister& tab3,
const LogicVRegister& tab4,
const LogicVRegister& ind) {
return Table(vform, dst, ind, true, &tab, &tab2, &tab3, &tab4);
}
LogicVRegister Simulator::tbx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& ind) {
return Table(vform, dst, ind, false, &tab);
}
LogicVRegister Simulator::tbx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& tab2,
const LogicVRegister& ind) {
return Table(vform, dst, ind, false, &tab, &tab2);
}
LogicVRegister Simulator::tbx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& tab2,
const LogicVRegister& tab3,
const LogicVRegister& ind) {
return Table(vform, dst, ind, false, &tab, &tab2, &tab3);
}
LogicVRegister Simulator::tbx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& tab,
const LogicVRegister& tab2,
const LogicVRegister& tab3,
const LogicVRegister& tab4,
const LogicVRegister& ind) {
return Table(vform, dst, ind, false, &tab, &tab2, &tab3, &tab4);
}
LogicVRegister Simulator::uqshrn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
return shrn(vform, dst, src, shift).UnsignedSaturate(vform);
}
LogicVRegister Simulator::uqshrn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
return shrn2(vform, dst, src, shift).UnsignedSaturate(vform);
}
LogicVRegister Simulator::uqrshrn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
return rshrn(vform, dst, src, shift).UnsignedSaturate(vform);
}
LogicVRegister Simulator::uqrshrn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
return rshrn2(vform, dst, src, shift).UnsignedSaturate(vform);
}
LogicVRegister Simulator::sqshrn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(vform);
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift);
return sqxtn(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqshrn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(VectorFormatHalfLanes(vform));
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift);
return sqxtn(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqrshrn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(vform);
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift).Round(vformsrc);
return sqxtn(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqrshrn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(VectorFormatHalfLanes(vform));
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift).Round(vformsrc);
return sqxtn(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqshrun(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(vform);
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift);
return sqxtun(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqshrun2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(VectorFormatHalfLanes(vform));
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift);
return sqxtun(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqrshrun(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(vform);
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift).Round(vformsrc);
return sqxtun(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::sqrshrun2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int shift) {
SimVRegister temp;
VectorFormat vformsrc = VectorFormatDoubleWidth(VectorFormatHalfLanes(vform));
VectorFormat vformdst = vform;
LogicVRegister shifted_src = sshr(vformsrc, temp, src, shift).Round(vformsrc);
return sqxtun(vformdst, dst, shifted_src);
}
LogicVRegister Simulator::uaddl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
add(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::uaddl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
add(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::uaddw(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
uxtl(vform, temp, src2);
add(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::uaddw2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
uxtl2(vform, temp, src2);
add(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::saddl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
add(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::saddl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
add(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::saddw(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sxtl(vform, temp, src2);
add(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::saddw2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sxtl2(vform, temp, src2);
add(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::usubl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
sub(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::usubl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
sub(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::usubw(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
uxtl(vform, temp, src2);
sub(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::usubw2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
uxtl2(vform, temp, src2);
sub(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::ssubl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
sub(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::ssubl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
sub(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::ssubw(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sxtl(vform, temp, src2);
sub(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::ssubw2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sxtl2(vform, temp, src2);
sub(vform, dst, src1, temp);
return dst;
}
LogicVRegister Simulator::uabal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
uaba(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::uabal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
uaba(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::sabal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
saba(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::sabal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
saba(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::uabdl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
AbsDiff(vform, dst, temp1, temp2, false);
return dst;
}
LogicVRegister Simulator::uabdl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
AbsDiff(vform, dst, temp1, temp2, false);
return dst;
}
LogicVRegister Simulator::sabdl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
AbsDiff(vform, dst, temp1, temp2, true);
return dst;
}
LogicVRegister Simulator::sabdl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
AbsDiff(vform, dst, temp1, temp2, true);
return dst;
}
LogicVRegister Simulator::umull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
mul(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::umull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
mul(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::smull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
mul(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::smull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
mul(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::umlsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
mls(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::umlsl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
mls(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::smlsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
mls(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::smlsl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
mls(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::umlal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl(vform, temp1, src1);
uxtl(vform, temp2, src2);
mla(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::umlal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
uxtl2(vform, temp1, src1);
uxtl2(vform, temp2, src2);
mla(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::smlal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl(vform, temp1, src1);
sxtl(vform, temp2, src2);
mla(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::smlal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp1, temp2;
sxtl2(vform, temp1, src1);
sxtl2(vform, temp2, src2);
mla(vform, dst, temp1, temp2);
return dst;
}
LogicVRegister Simulator::sqdmlal(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = sqdmull(vform, temp, src1, src2);
return add(vform, dst, dst, product).SignedSaturate(vform);
}
LogicVRegister Simulator::sqdmlal2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = sqdmull2(vform, temp, src1, src2);
return add(vform, dst, dst, product).SignedSaturate(vform);
}
LogicVRegister Simulator::sqdmlsl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = sqdmull(vform, temp, src1, src2);
return sub(vform, dst, dst, product).SignedSaturate(vform);
}
LogicVRegister Simulator::sqdmlsl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = sqdmull2(vform, temp, src1, src2);
return sub(vform, dst, dst, product).SignedSaturate(vform);
}
LogicVRegister Simulator::sqdmull(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = smull(vform, temp, src1, src2);
return add(vform, dst, product, product).SignedSaturate(vform);
}
LogicVRegister Simulator::sqdmull2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = smull2(vform, temp, src1, src2);
return add(vform, dst, product, product).SignedSaturate(vform);
}
LogicVRegister Simulator::sqrdmulh(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, bool round) {
// 2 * INT_32_MIN * INT_32_MIN causes int64_t to overflow.
// To avoid this, we use (src1 * src2 + 1 << (esize - 2)) >> (esize - 1)
// which is same as (2 * src1 * src2 + 1 << (esize - 1)) >> esize.
int esize = LaneSizeInBitsFromFormat(vform);
int round_const = round ? (1 << (esize - 2)) : 0;
int64_t product;
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
product = src1.Int(vform, i) * src2.Int(vform, i);
product += round_const;
product = product >> (esize - 1);
if (product > MaxIntFromFormat(vform)) {
product = MaxIntFromFormat(vform);
} else if (product < MinIntFromFormat(vform)) {
product = MinIntFromFormat(vform);
}
dst.SetInt(vform, i, product);
}
return dst;
}
LogicVRegister Simulator::sqdmulh(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
return sqrdmulh(vform, dst, src1, src2, false);
}
LogicVRegister Simulator::addhn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
add(VectorFormatDoubleWidth(vform), temp, src1, src2);
shrn(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::addhn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
add(VectorFormatDoubleWidth(VectorFormatHalfLanes(vform)), temp, src1, src2);
shrn2(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::raddhn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
add(VectorFormatDoubleWidth(vform), temp, src1, src2);
rshrn(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::raddhn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
add(VectorFormatDoubleWidth(VectorFormatHalfLanes(vform)), temp, src1, src2);
rshrn2(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::subhn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sub(VectorFormatDoubleWidth(vform), temp, src1, src2);
shrn(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::subhn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sub(VectorFormatDoubleWidth(VectorFormatHalfLanes(vform)), temp, src1, src2);
shrn2(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::rsubhn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sub(VectorFormatDoubleWidth(vform), temp, src1, src2);
rshrn(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::rsubhn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
sub(VectorFormatDoubleWidth(VectorFormatHalfLanes(vform)), temp, src1, src2);
rshrn2(vform, dst, temp, LaneSizeInBitsFromFormat(vform));
return dst;
}
LogicVRegister Simulator::trn1(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
int pairs = laneCount / 2;
for (int i = 0; i < pairs; ++i) {
result[2 * i] = src1.Uint(vform, 2 * i);
result[(2 * i) + 1] = src2.Uint(vform, 2 * i);
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::trn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
int pairs = laneCount / 2;
for (int i = 0; i < pairs; ++i) {
result[2 * i] = src1.Uint(vform, (2 * i) + 1);
result[(2 * i) + 1] = src2.Uint(vform, (2 * i) + 1);
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::zip1(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
int pairs = laneCount / 2;
for (int i = 0; i < pairs; ++i) {
result[2 * i] = src1.Uint(vform, i);
result[(2 * i) + 1] = src2.Uint(vform, i);
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::zip2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
uint64_t result[16];
int laneCount = LaneCountFromFormat(vform);
int pairs = laneCount / 2;
for (int i = 0; i < pairs; ++i) {
result[2 * i] = src1.Uint(vform, pairs + i);
result[(2 * i) + 1] = src2.Uint(vform, pairs + i);
}
dst.SetUintArray(vform, result);
return dst;
}
LogicVRegister Simulator::uzp1(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
uint64_t result[32];
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; ++i) {
result[i] = src1.Uint(vform, i);
result[laneCount + i] = src2.Uint(vform, i);
}
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, result[2 * i]);
}
return dst;
}
LogicVRegister Simulator::uzp2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
uint64_t result[32];
int laneCount = LaneCountFromFormat(vform);
for (int i = 0; i < laneCount; ++i) {
result[i] = src1.Uint(vform, i);
result[laneCount + i] = src2.Uint(vform, i);
}
dst.ClearForWrite(vform);
for (int i = 0; i < laneCount; ++i) {
dst.SetUint(vform, i, result[(2 * i) + 1]);
}
return dst;
}
template <typename T>
T Simulator::FPAdd(T op1, T op2) {
T result = FPProcessNaNs(op1, op2);
if (std::isnan(result)) return result;
if (std::isinf(op1) && std::isinf(op2) && (op1 != op2)) {
// inf + -inf returns the default NaN.
FPProcessException();
return FPDefaultNaN<T>();
} else {
// Other cases should be handled by standard arithmetic.
return op1 + op2;
}
}
template <typename T>
T Simulator::FPSub(T op1, T op2) {
// NaNs should be handled elsewhere.
DCHECK(!std::isnan(op1) && !std::isnan(op2));
if (std::isinf(op1) && std::isinf(op2) && (op1 == op2)) {
// inf - inf returns the default NaN.
FPProcessException();
return FPDefaultNaN<T>();
} else {
// Other cases should be handled by standard arithmetic.
return op1 - op2;
}
}
template <typename T>
T Simulator::FPMul(T op1, T op2) {
// NaNs should be handled elsewhere.
DCHECK(!std::isnan(op1) && !std::isnan(op2));
if ((std::isinf(op1) && (op2 == 0.0)) || (std::isinf(op2) && (op1 == 0.0))) {
// inf * 0.0 returns the default NaN.
FPProcessException();
return FPDefaultNaN<T>();
} else {
// Other cases should be handled by standard arithmetic.
return op1 * op2;
}
}
template <typename T>
T Simulator::FPMulx(T op1, T op2) {
if ((std::isinf(op1) && (op2 == 0.0)) || (std::isinf(op2) && (op1 == 0.0))) {
// inf * 0.0 returns +/-2.0.
T two = 2.0;
return std::copysign(1.0, op1) * std::copysign(1.0, op2) * two;
}
return FPMul(op1, op2);
}
template <typename T>
T Simulator::FPMulAdd(T a, T op1, T op2) {
T result = FPProcessNaNs3(a, op1, op2);
T sign_a = std::copysign(1.0, a);
T sign_prod = std::copysign(1.0, op1) * std::copysign(1.0, op2);
bool isinf_prod = std::isinf(op1) || std::isinf(op2);
bool operation_generates_nan =
(std::isinf(op1) && (op2 == 0.0)) || // inf * 0.0
(std::isinf(op2) && (op1 == 0.0)) || // 0.0 * inf
(std::isinf(a) && isinf_prod && (sign_a != sign_prod)); // inf - inf
if (std::isnan(result)) {
// Generated NaNs override quiet NaNs propagated from a.
if (operation_generates_nan && IsQuietNaN(a)) {
FPProcessException();
return FPDefaultNaN<T>();
} else {
return result;
}
}
// If the operation would produce a NaN, return the default NaN.
if (operation_generates_nan) {
FPProcessException();
return FPDefaultNaN<T>();
}
// Work around broken fma implementations for exact zero results: The sign of
// exact 0.0 results is positive unless both a and op1 * op2 are negative.
if (((op1 == 0.0) || (op2 == 0.0)) && (a == 0.0)) {
return ((sign_a < 0) && (sign_prod < 0)) ? -0.0 : 0.0;
}
result = FusedMultiplyAdd(op1, op2, a);
DCHECK(!std::isnan(result));
// Work around broken fma implementations for rounded zero results: If a is
// 0.0, the sign of the result is the sign of op1 * op2 before rounding.
if ((a == 0.0) && (result == 0.0)) {
return std::copysign(0.0, sign_prod);
}
return result;
}
template <typename T>
T Simulator::FPDiv(T op1, T op2) {
// NaNs should be handled elsewhere.
DCHECK(!std::isnan(op1) && !std::isnan(op2));
if ((std::isinf(op1) && std::isinf(op2)) || ((op1 == 0.0) && (op2 == 0.0))) {
// inf / inf and 0.0 / 0.0 return the default NaN.
FPProcessException();
return FPDefaultNaN<T>();
} else {
if (op2 == 0.0) {
FPProcessException();
if (!std::isnan(op1)) {
double op1_sign = std::copysign(1.0, op1);
double op2_sign = std::copysign(1.0, op2);
return static_cast<T>(op1_sign * op2_sign * kFP64PositiveInfinity);
}
}
// Other cases should be handled by standard arithmetic.
return op1 / op2;
}
}
template <typename T>
T Simulator::FPSqrt(T op) {
if (std::isnan(op)) {
return FPProcessNaN(op);
} else if (op < 0.0) {
FPProcessException();
return FPDefaultNaN<T>();
} else {
return std::sqrt(op);
}
}
template <typename T>
T Simulator::FPMax(T a, T b) {
T result = FPProcessNaNs(a, b);
if (std::isnan(result)) return result;
if ((a == 0.0) && (b == 0.0) &&
(std::copysign(1.0, a) != std::copysign(1.0, b))) {
// a and b are zero, and the sign differs: return +0.0.
return 0.0;
} else {
return (a > b) ? a : b;
}
}
template <typename T>
T Simulator::FPMaxNM(T a, T b) {
if (IsQuietNaN(a) && !IsQuietNaN(b)) {
a = kFP64NegativeInfinity;
} else if (!IsQuietNaN(a) && IsQuietNaN(b)) {
b = kFP64NegativeInfinity;
}
T result = FPProcessNaNs(a, b);
return std::isnan(result) ? result : FPMax(a, b);
}
template <typename T>
T Simulator::FPMin(T a, T b) {
T result = FPProcessNaNs(a, b);
if (std::isnan(result)) return result;
if ((a == 0.0) && (b == 0.0) &&
(std::copysign(1.0, a) != std::copysign(1.0, b))) {
// a and b are zero, and the sign differs: return -0.0.
return -0.0;
} else {
return (a < b) ? a : b;
}
}
template <typename T>
T Simulator::FPMinNM(T a, T b) {
if (IsQuietNaN(a) && !IsQuietNaN(b)) {
a = kFP64PositiveInfinity;
} else if (!IsQuietNaN(a) && IsQuietNaN(b)) {
b = kFP64PositiveInfinity;
}
T result = FPProcessNaNs(a, b);
return std::isnan(result) ? result : FPMin(a, b);
}
template <typename T>
T Simulator::FPRecipStepFused(T op1, T op2) {
const T two = 2.0;
if ((std::isinf(op1) && (op2 == 0.0)) ||
((op1 == 0.0) && (std::isinf(op2)))) {
return two;
} else if (std::isinf(op1) || std::isinf(op2)) {
// Return +inf if signs match, otherwise -inf.
return ((op1 >= 0.0) == (op2 >= 0.0)) ? kFP64PositiveInfinity
: kFP64NegativeInfinity;
} else {
return FusedMultiplyAdd(op1, op2, two);
}
}
template <typename T>
T Simulator::FPRSqrtStepFused(T op1, T op2) {
const T one_point_five = 1.5;
const T two = 2.0;
if ((std::isinf(op1) && (op2 == 0.0)) ||
((op1 == 0.0) && (std::isinf(op2)))) {
return one_point_five;
} else if (std::isinf(op1) || std::isinf(op2)) {
// Return +inf if signs match, otherwise -inf.
return ((op1 >= 0.0) == (op2 >= 0.0)) ? kFP64PositiveInfinity
: kFP64NegativeInfinity;
} else {
// The multiply-add-halve operation must be fully fused, so avoid interim
// rounding by checking which operand can be losslessly divided by two
// before doing the multiply-add.
if (std::isnormal(op1 / two)) {
return FusedMultiplyAdd(op1 / two, op2, one_point_five);
} else if (std::isnormal(op2 / two)) {
return FusedMultiplyAdd(op1, op2 / two, one_point_five);
} else {
// Neither operand is normal after halving: the result is dominated by
// the addition term, so just return that.
return one_point_five;
}
}
}
double Simulator::FPRoundInt(double value, FPRounding round_mode) {
if ((value == 0.0) || (value == kFP64PositiveInfinity) ||
(value == kFP64NegativeInfinity)) {
return value;
} else if (std::isnan(value)) {
return FPProcessNaN(value);
}
double int_result = std::floor(value);
double error = value - int_result;
switch (round_mode) {
case FPTieAway: {
// Take care of correctly handling the range ]-0.5, -0.0], which must
// yield -0.0.
if ((-0.5 < value) && (value < 0.0)) {
int_result = -0.0;
} else if ((error > 0.5) || ((error == 0.5) && (int_result >= 0.0))) {
// If the error is greater than 0.5, or is equal to 0.5 and the integer
// result is positive, round up.
int_result++;
}
break;
}
case FPTieEven: {
// Take care of correctly handling the range [-0.5, -0.0], which must
// yield -0.0.
if ((-0.5 <= value) && (value < 0.0)) {
int_result = -0.0;
// If the error is greater than 0.5, or is equal to 0.5 and the integer
// result is odd, round up.
} else if ((error > 0.5) ||
((error == 0.5) && (std::fmod(int_result, 2) != 0))) {
int_result++;
}
break;
}
case FPZero: {
// If value>0 then we take floor(value)
// otherwise, ceil(value).
if (value < 0) {
int_result = ceil(value);
}
break;
}
case FPNegativeInfinity: {
// We always use floor(value).
break;
}
case FPPositiveInfinity: {
// Take care of correctly handling the range ]-1.0, -0.0], which must
// yield -0.0.
if ((-1.0 < value) && (value < 0.0)) {
int_result = -0.0;
// If the error is non-zero, round up.
} else if (error > 0.0) {
int_result++;
}
break;
}
default:
UNIMPLEMENTED();
}
return int_result;
}
int32_t Simulator::FPToInt32(double value, FPRounding rmode) {
value = FPRoundInt(value, rmode);
if (value >= kWMaxInt) {
return kWMaxInt;
} else if (value < kWMinInt) {
return kWMinInt;
}
return std::isnan(value) ? 0 : static_cast<int32_t>(value);
}
int64_t Simulator::FPToInt64(double value, FPRounding rmode) {
value = FPRoundInt(value, rmode);
if (value >= kXMaxInt) {
return kXMaxInt;
} else if (value < kXMinInt) {
return kXMinInt;
}
return std::isnan(value) ? 0 : static_cast<int64_t>(value);
}
uint32_t Simulator::FPToUInt32(double value, FPRounding rmode) {
value = FPRoundInt(value, rmode);
if (value >= kWMaxUInt) {
return kWMaxUInt;
} else if (value < 0.0) {
return 0;
}
return std::isnan(value) ? 0 : static_cast<uint32_t>(value);
}
uint64_t Simulator::FPToUInt64(double value, FPRounding rmode) {
value = FPRoundInt(value, rmode);
if (value >= kXMaxUInt) {
return kXMaxUInt;
} else if (value < 0.0) {
return 0;
}
return std::isnan(value) ? 0 : static_cast<uint64_t>(value);
}
#define DEFINE_NEON_FP_VECTOR_OP(FN, OP, PROCNAN) \
template <typename T> \
LogicVRegister Simulator::FN(VectorFormat vform, LogicVRegister dst, \
const LogicVRegister& src1, \
const LogicVRegister& src2) { \
dst.ClearForWrite(vform); \
for (int i = 0; i < LaneCountFromFormat(vform); i++) { \
T op1 = src1.Float<T>(i); \
T op2 = src2.Float<T>(i); \
T result; \
if (PROCNAN) { \
result = FPProcessNaNs(op1, op2); \
if (!std::isnan(result)) { \
result = OP(op1, op2); \
} \
} else { \
result = OP(op1, op2); \
} \
dst.SetFloat(i, result); \
} \
return dst; \
} \
\
LogicVRegister Simulator::FN(VectorFormat vform, LogicVRegister dst, \
const LogicVRegister& src1, \
const LogicVRegister& src2) { \
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) { \
FN<float>(vform, dst, src1, src2); \
} else { \
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize); \
FN<double>(vform, dst, src1, src2); \
} \
return dst; \
}
NEON_FP3SAME_LIST(DEFINE_NEON_FP_VECTOR_OP)
#undef DEFINE_NEON_FP_VECTOR_OP
LogicVRegister Simulator::fnmul(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
LogicVRegister product = fmul(vform, temp, src1, src2);
return fneg(vform, dst, product);
}
template <typename T>
LogicVRegister Simulator::frecps(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op1 = -src1.Float<T>(i);
T op2 = src2.Float<T>(i);
T result = FPProcessNaNs(op1, op2);
dst.SetFloat(i, std::isnan(result) ? result : FPRecipStepFused(op1, op2));
}
return dst;
}
LogicVRegister Simulator::frecps(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
frecps<float>(vform, dst, src1, src2);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
frecps<double>(vform, dst, src1, src2);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::frsqrts(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op1 = -src1.Float<T>(i);
T op2 = src2.Float<T>(i);
T result = FPProcessNaNs(op1, op2);
dst.SetFloat(i, std::isnan(result) ? result : FPRSqrtStepFused(op1, op2));
}
return dst;
}
int32_t Simulator::FPToFixedJS(double value) {
// The Z-flag is set when the conversion from double precision floating-point
// to 32-bit integer is exact. If the source value is +/-Infinity, -0.0, NaN,
// outside the bounds of a 32-bit integer, or isn't an exact integer then the
// Z-flag is unset.
int Z = 1;
int32_t result;
if ((value == 0.0) || (value == kFP64PositiveInfinity) ||
(value == kFP64NegativeInfinity)) {
// +/- zero and infinity all return zero, however -0 and +/- Infinity also
// unset the Z-flag.
result = 0.0;
if ((value != 0.0) || std::signbit(value)) {
Z = 0;
}
} else if (std::isnan(value)) {
// NaN values unset the Z-flag and set the result to 0.
result = 0;
Z = 0;
} else {
// All other values are converted to an integer representation, rounded
// toward zero.
double int_result = std::floor(value);
double error = value - int_result;
if ((error != 0.0) && (int_result < 0.0)) {
int_result++;
}
// Constrain the value into the range [INT32_MIN, INT32_MAX]. We can almost
// write a one-liner with std::round, but the behaviour on ties is incorrect
// for our purposes.
double mod_const = static_cast<double>(UINT64_C(1) << 32);
double mod_error =
(int_result / mod_const) - std::floor(int_result / mod_const);
double constrained;
if (mod_error == 0.5) {
constrained = INT32_MIN;
} else {
constrained = int_result - mod_const * round(int_result / mod_const);
}
DCHECK(std::floor(constrained) == constrained);
DCHECK(constrained >= INT32_MIN);
DCHECK(constrained <= INT32_MAX);
// Take the bottom 32 bits of the result as a 32-bit integer.
result = static_cast<int32_t>(constrained);
if ((int_result < INT32_MIN) || (int_result > INT32_MAX) ||
(error != 0.0)) {
// If the integer result is out of range or the conversion isn't exact,
// take exception and unset the Z-flag.
FPProcessException();
Z = 0;
}
}
nzcv().SetN(0);
nzcv().SetZ(Z);
nzcv().SetC(0);
nzcv().SetV(0);
return result;
}
LogicVRegister Simulator::frsqrts(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
frsqrts<float>(vform, dst, src1, src2);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
frsqrts<double>(vform, dst, src1, src2);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::fcmp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, Condition cond) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
bool result = false;
T op1 = src1.Float<T>(i);
T op2 = src2.Float<T>(i);
T nan_result = FPProcessNaNs(op1, op2);
if (!std::isnan(nan_result)) {
switch (cond) {
case eq:
result = (op1 == op2);
break;
case ge:
result = (op1 >= op2);
break;
case gt:
result = (op1 > op2);
break;
case le:
result = (op1 <= op2);
break;
case lt:
result = (op1 < op2);
break;
default:
UNREACHABLE();
}
}
dst.SetUint(vform, i, result ? MaxUintFromFormat(vform) : 0);
}
return dst;
}
LogicVRegister Simulator::fcmp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, Condition cond) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
fcmp<float>(vform, dst, src1, src2, cond);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
fcmp<double>(vform, dst, src1, src2, cond);
}
return dst;
}
LogicVRegister Simulator::fcmp_zero(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, Condition cond) {
SimVRegister temp;
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
LogicVRegister zero_reg =
dup_immediate(vform, temp, bit_cast<uint32_t>(0.0f));
fcmp<float>(vform, dst, src, zero_reg, cond);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
LogicVRegister zero_reg =
dup_immediate(vform, temp, bit_cast<uint64_t>(0.0));
fcmp<double>(vform, dst, src, zero_reg, cond);
}
return dst;
}
LogicVRegister Simulator::fabscmp(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, Condition cond) {
SimVRegister temp1, temp2;
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
LogicVRegister abs_src1 = fabs_<float>(vform, temp1, src1);
LogicVRegister abs_src2 = fabs_<float>(vform, temp2, src2);
fcmp<float>(vform, dst, abs_src1, abs_src2, cond);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
LogicVRegister abs_src1 = fabs_<double>(vform, temp1, src1);
LogicVRegister abs_src2 = fabs_<double>(vform, temp2, src2);
fcmp<double>(vform, dst, abs_src1, abs_src2, cond);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::fmla(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op1 = src1.Float<T>(i);
T op2 = src2.Float<T>(i);
T acc = dst.Float<T>(i);
T result = FPMulAdd(acc, op1, op2);
dst.SetFloat(i, result);
}
return dst;
}
LogicVRegister Simulator::fmla(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
fmla<float>(vform, dst, src1, src2);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
fmla<double>(vform, dst, src1, src2);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::fmls(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op1 = -src1.Float<T>(i);
T op2 = src2.Float<T>(i);
T acc = dst.Float<T>(i);
T result = FPMulAdd(acc, op1, op2);
dst.SetFloat(i, result);
}
return dst;
}
LogicVRegister Simulator::fmls(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
fmls<float>(vform, dst, src1, src2);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
fmls<double>(vform, dst, src1, src2);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::fneg(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op = src.Float<T>(i);
op = -op;
dst.SetFloat(i, op);
}
return dst;
}
LogicVRegister Simulator::fneg(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
fneg<float>(vform, dst, src);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
fneg<double>(vform, dst, src);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::fabs_(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op = src.Float<T>(i);
if (std::copysign(1.0, op) < 0.0) {
op = -op;
}
dst.SetFloat(i, op);
}
return dst;
}
LogicVRegister Simulator::fabs_(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
fabs_<float>(vform, dst, src);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
fabs_<double>(vform, dst, src);
}
return dst;
}
LogicVRegister Simulator::fabd(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2) {
SimVRegister temp;
fsub(vform, temp, src1, src2);
fabs_(vform, dst, temp);
return dst;
}
LogicVRegister Simulator::fsqrt(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
float result = FPSqrt(src.Float<float>(i));
dst.SetFloat(i, result);
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
double result = FPSqrt(src.Float<double>(i));
dst.SetFloat(i, result);
}
}
return dst;
}
#define DEFINE_NEON_FP_PAIR_OP(FNP, FN, OP) \
LogicVRegister Simulator::FNP(VectorFormat vform, LogicVRegister dst, \
const LogicVRegister& src1, \
const LogicVRegister& src2) { \
SimVRegister temp1, temp2; \
uzp1(vform, temp1, src1, src2); \
uzp2(vform, temp2, src1, src2); \
FN(vform, dst, temp1, temp2); \
return dst; \
} \
\
LogicVRegister Simulator::FNP(VectorFormat vform, LogicVRegister dst, \
const LogicVRegister& src) { \
if (vform == kFormatS) { \
float result = OP(src.Float<float>(0), src.Float<float>(1)); \
dst.SetFloat(0, result); \
} else { \
DCHECK_EQ(vform, kFormatD); \
double result = OP(src.Float<double>(0), src.Float<double>(1)); \
dst.SetFloat(0, result); \
} \
dst.ClearForWrite(vform); \
return dst; \
}
NEON_FPPAIRWISE_LIST(DEFINE_NEON_FP_PAIR_OP)
#undef DEFINE_NEON_FP_PAIR_OP
LogicVRegister Simulator::FMinMaxV(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, FPMinMaxOp Op) {
DCHECK_EQ(vform, kFormat4S);
USE(vform);
float result1 = (this->*Op)(src.Float<float>(0), src.Float<float>(1));
float result2 = (this->*Op)(src.Float<float>(2), src.Float<float>(3));
float result = (this->*Op)(result1, result2);
dst.ClearForWrite(kFormatS);
dst.SetFloat<float>(0, result);
return dst;
}
LogicVRegister Simulator::fmaxv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return FMinMaxV(vform, dst, src, &Simulator::FPMax);
}
LogicVRegister Simulator::fminv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return FMinMaxV(vform, dst, src, &Simulator::FPMin);
}
LogicVRegister Simulator::fmaxnmv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return FMinMaxV(vform, dst, src, &Simulator::FPMaxNM);
}
LogicVRegister Simulator::fminnmv(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
return FMinMaxV(vform, dst, src, &Simulator::FPMinNM);
}
LogicVRegister Simulator::fmul(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
dst.ClearForWrite(vform);
SimVRegister temp;
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
LogicVRegister index_reg = dup_element(kFormat4S, temp, src2, index);
fmul<float>(vform, dst, src1, index_reg);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
LogicVRegister index_reg = dup_element(kFormat2D, temp, src2, index);
fmul<double>(vform, dst, src1, index_reg);
}
return dst;
}
LogicVRegister Simulator::fmla(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
dst.ClearForWrite(vform);
SimVRegister temp;
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
LogicVRegister index_reg = dup_element(kFormat4S, temp, src2, index);
fmla<float>(vform, dst, src1, index_reg);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
LogicVRegister index_reg = dup_element(kFormat2D, temp, src2, index);
fmla<double>(vform, dst, src1, index_reg);
}
return dst;
}
LogicVRegister Simulator::fmls(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
dst.ClearForWrite(vform);
SimVRegister temp;
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
LogicVRegister index_reg = dup_element(kFormat4S, temp, src2, index);
fmls<float>(vform, dst, src1, index_reg);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
LogicVRegister index_reg = dup_element(kFormat2D, temp, src2, index);
fmls<double>(vform, dst, src1, index_reg);
}
return dst;
}
LogicVRegister Simulator::fmulx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src1,
const LogicVRegister& src2, int index) {
dst.ClearForWrite(vform);
SimVRegister temp;
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
LogicVRegister index_reg = dup_element(kFormat4S, temp, src2, index);
fmulx<float>(vform, dst, src1, index_reg);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
LogicVRegister index_reg = dup_element(kFormat2D, temp, src2, index);
fmulx<double>(vform, dst, src1, index_reg);
}
return dst;
}
LogicVRegister Simulator::frint(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src,
FPRounding rounding_mode,
bool inexact_exception) {
dst.ClearForWrite(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
float input = src.Float<float>(i);
float rounded = FPRoundInt(input, rounding_mode);
if (inexact_exception && !std::isnan(input) && (input != rounded)) {
FPProcessException();
}
dst.SetFloat<float>(i, rounded);
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
double input = src.Float<double>(i);
double rounded = FPRoundInt(input, rounding_mode);
if (inexact_exception && !std::isnan(input) && (input != rounded)) {
FPProcessException();
}
dst.SetFloat<double>(i, rounded);
}
}
return dst;
}
LogicVRegister Simulator::fcvts(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src,
FPRounding rounding_mode, int fbits) {
dst.ClearForWrite(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
float op = src.Float<float>(i) * std::pow(2.0f, fbits);
dst.SetInt(vform, i, FPToInt32(op, rounding_mode));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
double op = src.Float<double>(i) * std::pow(2.0, fbits);
dst.SetInt(vform, i, FPToInt64(op, rounding_mode));
}
}
return dst;
}
LogicVRegister Simulator::fcvtu(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src,
FPRounding rounding_mode, int fbits) {
dst.ClearForWrite(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
float op = src.Float<float>(i) * std::pow(2.0f, fbits);
dst.SetUint(vform, i, FPToUInt32(op, rounding_mode));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
double op = src.Float<double>(i) * std::pow(2.0, fbits);
dst.SetUint(vform, i, FPToUInt64(op, rounding_mode));
}
}
return dst;
}
LogicVRegister Simulator::fcvtl(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = LaneCountFromFormat(vform) - 1; i >= 0; i--) {
dst.SetFloat(i, FPToFloat(src.Float<float16>(i)));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = LaneCountFromFormat(vform) - 1; i >= 0; i--) {
dst.SetFloat(i, FPToDouble(src.Float<float>(i)));
}
}
return dst;
}
LogicVRegister Simulator::fcvtl2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
int lane_count = LaneCountFromFormat(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < lane_count; i++) {
dst.SetFloat(i, FPToFloat(src.Float<float16>(i + lane_count)));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < lane_count; i++) {
dst.SetFloat(i, FPToDouble(src.Float<float>(i + lane_count)));
}
}
return dst;
}
LogicVRegister Simulator::fcvtn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
if (LaneSizeInBytesFromFormat(vform) == kHRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetFloat(i, FPToFloat16(src.Float<float>(i), FPTieEven));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kSRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetFloat(i, FPToFloat(src.Float<double>(i), FPTieEven));
}
}
return dst;
}
LogicVRegister Simulator::fcvtn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
int lane_count = LaneCountFromFormat(vform) / 2;
if (LaneSizeInBytesFromFormat(vform) == kHRegSize) {
for (int i = lane_count - 1; i >= 0; i--) {
dst.SetFloat(i + lane_count, FPToFloat16(src.Float<float>(i), FPTieEven));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kSRegSize);
for (int i = lane_count - 1; i >= 0; i--) {
dst.SetFloat(i + lane_count, FPToFloat(src.Float<double>(i), FPTieEven));
}
}
return dst;
}
LogicVRegister Simulator::fcvtxn(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kSRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
dst.SetFloat(i, FPToFloat(src.Float<double>(i), FPRoundOdd));
}
return dst;
}
LogicVRegister Simulator::fcvtxn2(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kSRegSize);
int lane_count = LaneCountFromFormat(vform) / 2;
for (int i = lane_count - 1; i >= 0; i--) {
dst.SetFloat(i + lane_count, FPToFloat(src.Float<double>(i), FPRoundOdd));
}
return dst;
}
// Based on reference C function recip_sqrt_estimate from ARM ARM.
double Simulator::recip_sqrt_estimate(double a) {
int q0, q1, s;
double r;
if (a < 0.5) {
q0 = static_cast<int>(a * 512.0);
r = 1.0 / sqrt((static_cast<double>(q0) + 0.5) / 512.0);
} else {
q1 = static_cast<int>(a * 256.0);
r = 1.0 / sqrt((static_cast<double>(q1) + 0.5) / 256.0);
}
s = static_cast<int>(256.0 * r + 0.5);
return static_cast<double>(s) / 256.0;
}
namespace {
inline uint64_t Bits(uint64_t val, int start_bit, int end_bit) {
return unsigned_bitextract_64(start_bit, end_bit, val);
}
} // anonymous namespace
template <typename T>
T Simulator::FPRecipSqrtEstimate(T op) {
static_assert(std::is_same<float, T>::value || std::is_same<double, T>::value,
"T must be a float or double");
if (std::isnan(op)) {
return FPProcessNaN(op);
} else if (op == 0.0) {
if (std::copysign(1.0, op) < 0.0) {
return kFP64NegativeInfinity;
} else {
return kFP64PositiveInfinity;
}
} else if (std::copysign(1.0, op) < 0.0) {
FPProcessException();
return FPDefaultNaN<T>();
} else if (std::isinf(op)) {
return 0.0;
} else {
uint64_t fraction;
int32_t exp, result_exp;
if (sizeof(T) == sizeof(float)) {
exp = static_cast<int32_t>(float_exp(op));
fraction = float_mantissa(op);
fraction <<= 29;
} else {
exp = static_cast<int32_t>(double_exp(op));
fraction = double_mantissa(op);
}
if (exp == 0) {
while (Bits(fraction, 51, 51) == 0) {
fraction = Bits(fraction, 50, 0) << 1;
exp -= 1;
}
fraction = Bits(fraction, 50, 0) << 1;
}
double scaled;
if (Bits(exp, 0, 0) == 0) {
scaled = double_pack(0, 1022, Bits(fraction, 51, 44) << 44);
} else {
scaled = double_pack(0, 1021, Bits(fraction, 51, 44) << 44);
}
if (sizeof(T) == sizeof(float)) {
result_exp = (380 - exp) / 2;
} else {
result_exp = (3068 - exp) / 2;
}
uint64_t estimate = bit_cast<uint64_t>(recip_sqrt_estimate(scaled));
if (sizeof(T) == sizeof(float)) {
uint32_t exp_bits = static_cast<uint32_t>(Bits(result_exp, 7, 0));
uint32_t est_bits = static_cast<uint32_t>(Bits(estimate, 51, 29));
return float_pack(0, exp_bits, est_bits);
} else {
return double_pack(0, Bits(result_exp, 10, 0), Bits(estimate, 51, 0));
}
}
}
LogicVRegister Simulator::frsqrte(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
float input = src.Float<float>(i);
dst.SetFloat(i, FPRecipSqrtEstimate<float>(input));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
double input = src.Float<double>(i);
dst.SetFloat(i, FPRecipSqrtEstimate<double>(input));
}
}
return dst;
}
template <typename T>
T Simulator::FPRecipEstimate(T op, FPRounding rounding) {
static_assert(std::is_same<float, T>::value || std::is_same<double, T>::value,
"T must be a float or double");
uint32_t sign;
if (sizeof(T) == sizeof(float)) {
sign = float_sign(op);
} else {
sign = double_sign(op);
}
if (std::isnan(op)) {
return FPProcessNaN(op);
} else if (std::isinf(op)) {
return (sign == 1) ? -0.0 : 0.0;
} else if (op == 0.0) {
FPProcessException(); // FPExc_DivideByZero exception.
return (sign == 1) ? kFP64NegativeInfinity : kFP64PositiveInfinity;
} else if (((sizeof(T) == sizeof(float)) &&
(std::fabs(op) < std::pow(2.0, -128.0))) ||
((sizeof(T) == sizeof(double)) &&
(std::fabs(op) < std::pow(2.0, -1024.0)))) {
bool overflow_to_inf = false;
switch (rounding) {
case FPTieEven:
overflow_to_inf = true;
break;
case FPPositiveInfinity:
overflow_to_inf = (sign == 0);
break;
case FPNegativeInfinity:
overflow_to_inf = (sign == 1);
break;
case FPZero:
overflow_to_inf = false;
break;
default:
break;
}
FPProcessException(); // FPExc_Overflow and FPExc_Inexact.
if (overflow_to_inf) {
return (sign == 1) ? kFP64NegativeInfinity : kFP64PositiveInfinity;
} else {
// Return FPMaxNormal(sign).
if (sizeof(T) == sizeof(float)) {
return float_pack(sign, 0xFE, 0x07FFFFF);
} else {
return double_pack(sign, 0x7FE, 0x0FFFFFFFFFFFFFl);
}
}
} else {
uint64_t fraction;
int32_t exp, result_exp;
uint32_t sign;
if (sizeof(T) == sizeof(float)) {
sign = float_sign(op);
exp = static_cast<int32_t>(float_exp(op));
fraction = float_mantissa(op);
fraction <<= 29;
} else {
sign = double_sign(op);
exp = static_cast<int32_t>(double_exp(op));
fraction = double_mantissa(op);
}
if (exp == 0) {
if (Bits(fraction, 51, 51) == 0) {
exp -= 1;
fraction = Bits(fraction, 49, 0) << 2;
} else {
fraction = Bits(fraction, 50, 0) << 1;
}
}
double scaled = double_pack(0, 1022, Bits(fraction, 51, 44) << 44);
if (sizeof(T) == sizeof(float)) {
result_exp = 253 - exp;
} else {
result_exp = 2045 - exp;
}
double estimate = recip_estimate(scaled);
fraction = double_mantissa(estimate);
if (result_exp == 0) {
fraction = (UINT64_C(1) << 51) | Bits(fraction, 51, 1);
} else if (result_exp == -1) {
fraction = (UINT64_C(1) << 50) | Bits(fraction, 51, 2);
result_exp = 0;
}
if (sizeof(T) == sizeof(float)) {
uint32_t exp_bits = static_cast<uint32_t>(Bits(result_exp, 7, 0));
uint32_t frac_bits = static_cast<uint32_t>(Bits(fraction, 51, 29));
return float_pack(sign, exp_bits, frac_bits);
} else {
return double_pack(sign, Bits(result_exp, 10, 0), Bits(fraction, 51, 0));
}
}
}
LogicVRegister Simulator::frecpe(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, FPRounding round) {
dst.ClearForWrite(vform);
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
float input = src.Float<float>(i);
dst.SetFloat(i, FPRecipEstimate<float>(input, round));
}
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
double input = src.Float<double>(i);
dst.SetFloat(i, FPRecipEstimate<double>(input, round));
}
}
return dst;
}
LogicVRegister Simulator::ursqrte(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
uint64_t operand;
uint32_t result;
double dp_operand, dp_result;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
operand = src.Uint(vform, i);
if (operand <= 0x3FFFFFFF) {
result = 0xFFFFFFFF;
} else {
dp_operand = operand * std::pow(2.0, -32);
dp_result = recip_sqrt_estimate(dp_operand) * std::pow(2.0, 31);
result = static_cast<uint32_t>(dp_result);
}
dst.SetUint(vform, i, result);
}
return dst;
}
// Based on reference C function recip_estimate from ARM ARM.
double Simulator::recip_estimate(double a) {
int q, s;
double r;
q = static_cast<int>(a * 512.0);
r = 1.0 / ((static_cast<double>(q) + 0.5) / 512.0);
s = static_cast<int>(256.0 * r + 0.5);
return static_cast<double>(s) / 256.0;
}
LogicVRegister Simulator::urecpe(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
uint64_t operand;
uint32_t result;
double dp_operand, dp_result;
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
operand = src.Uint(vform, i);
if (operand <= 0x7FFFFFFF) {
result = 0xFFFFFFFF;
} else {
dp_operand = operand * std::pow(2.0, -32);
dp_result = recip_estimate(dp_operand) * std::pow(2.0, 31);
result = static_cast<uint32_t>(dp_result);
}
dst.SetUint(vform, i, result);
}
return dst;
}
template <typename T>
LogicVRegister Simulator::frecpx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
dst.ClearForWrite(vform);
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
T op = src.Float<T>(i);
T result;
if (std::isnan(op)) {
result = FPProcessNaN(op);
} else {
int exp;
uint32_t sign;
if (sizeof(T) == sizeof(float)) {
sign = float_sign(op);
exp = static_cast<int>(float_exp(op));
exp = (exp == 0) ? (0xFF - 1) : static_cast<int>(Bits(~exp, 7, 0));
result = float_pack(sign, exp, 0);
} else {
sign = double_sign(op);
exp = static_cast<int>(double_exp(op));
exp = (exp == 0) ? (0x7FF - 1) : static_cast<int>(Bits(~exp, 10, 0));
result = double_pack(sign, exp, 0);
}
}
dst.SetFloat(i, result);
}
return dst;
}
LogicVRegister Simulator::frecpx(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
frecpx<float>(vform, dst, src);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
frecpx<double>(vform, dst, src);
}
return dst;
}
LogicVRegister Simulator::scvtf(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int fbits,
FPRounding round) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
float result = FixedToFloat(src.Int(kFormatS, i), fbits, round);
dst.SetFloat<float>(i, result);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
double result = FixedToDouble(src.Int(kFormatD, i), fbits, round);
dst.SetFloat<double>(i, result);
}
}
return dst;
}
LogicVRegister Simulator::ucvtf(VectorFormat vform, LogicVRegister dst,
const LogicVRegister& src, int fbits,
FPRounding round) {
for (int i = 0; i < LaneCountFromFormat(vform); i++) {
if (LaneSizeInBytesFromFormat(vform) == kSRegSize) {
float result = UFixedToFloat(src.Uint(kFormatS, i), fbits, round);
dst.SetFloat<float>(i, result);
} else {
DCHECK_EQ(LaneSizeInBytesFromFormat(vform), kDRegSize);
double result = UFixedToDouble(src.Uint(kFormatD, i), fbits, round);
dst.SetFloat<double>(i, result);
}
}
return dst;
}
} // namespace internal
} // namespace v8
#endif // USE_SIMULATOR