// Copyright 2015, VIXL authors // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // * Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // * Neither the name of ARM Limited nor the names of its contributors may be // used to endorse or promote products derived from this software without // specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS CONTRIBUTORS "AS IS" AND // ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED // WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE // FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL // DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR // SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER // CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, // OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include "utils-vixl.h" #include namespace vixl { // The default NaN values (for FPCR.DN=1). const double kFP64DefaultNaN = RawbitsToDouble(UINT64_C(0x7ff8000000000000)); const float kFP32DefaultNaN = RawbitsToFloat(0x7fc00000); const Float16 kFP16DefaultNaN = RawbitsToFloat16(0x7e00); // Floating-point zero values. const Float16 kFP16PositiveZero = RawbitsToFloat16(0x0); const Float16 kFP16NegativeZero = RawbitsToFloat16(0x8000); // Floating-point infinity values. const Float16 kFP16PositiveInfinity = RawbitsToFloat16(0x7c00); const Float16 kFP16NegativeInfinity = RawbitsToFloat16(0xfc00); const float kFP32PositiveInfinity = RawbitsToFloat(0x7f800000); const float kFP32NegativeInfinity = RawbitsToFloat(0xff800000); const double kFP64PositiveInfinity = RawbitsToDouble(UINT64_C(0x7ff0000000000000)); const double kFP64NegativeInfinity = RawbitsToDouble(UINT64_C(0xfff0000000000000)); bool IsZero(Float16 value) { uint16_t bits = Float16ToRawbits(value); return (bits == Float16ToRawbits(kFP16PositiveZero) || bits == Float16ToRawbits(kFP16NegativeZero)); } uint16_t Float16ToRawbits(Float16 value) { return value.rawbits_; } uint32_t FloatToRawbits(float value) { uint32_t bits = 0; memcpy(&bits, &value, 4); return bits; } uint64_t DoubleToRawbits(double value) { uint64_t bits = 0; memcpy(&bits, &value, 8); return bits; } Float16 RawbitsToFloat16(uint16_t bits) { Float16 f; f.rawbits_ = bits; return f; } float RawbitsToFloat(uint32_t bits) { float value = 0.0; memcpy(&value, &bits, 4); return value; } double RawbitsToDouble(uint64_t bits) { double value = 0.0; memcpy(&value, &bits, 8); return value; } uint32_t Float16Sign(internal::SimFloat16 val) { uint16_t rawbits = Float16ToRawbits(val); return ExtractUnsignedBitfield32(15, 15, rawbits); } uint32_t Float16Exp(internal::SimFloat16 val) { uint16_t rawbits = Float16ToRawbits(val); return ExtractUnsignedBitfield32(14, 10, rawbits); } uint32_t Float16Mantissa(internal::SimFloat16 val) { uint16_t rawbits = Float16ToRawbits(val); return ExtractUnsignedBitfield32(9, 0, rawbits); } uint32_t FloatSign(float val) { uint32_t rawbits = FloatToRawbits(val); return ExtractUnsignedBitfield32(31, 31, rawbits); } uint32_t FloatExp(float val) { uint32_t rawbits = FloatToRawbits(val); return ExtractUnsignedBitfield32(30, 23, rawbits); } uint32_t FloatMantissa(float val) { uint32_t rawbits = FloatToRawbits(val); return ExtractUnsignedBitfield32(22, 0, rawbits); } uint32_t DoubleSign(double val) { uint64_t rawbits = DoubleToRawbits(val); return static_cast(ExtractUnsignedBitfield64(63, 63, rawbits)); } uint32_t DoubleExp(double val) { uint64_t rawbits = DoubleToRawbits(val); return static_cast(ExtractUnsignedBitfield64(62, 52, rawbits)); } uint64_t DoubleMantissa(double val) { uint64_t rawbits = DoubleToRawbits(val); return ExtractUnsignedBitfield64(51, 0, rawbits); } internal::SimFloat16 Float16Pack(uint16_t sign, uint16_t exp, uint16_t mantissa) { uint16_t bits = (sign << 15) | (exp << 10) | mantissa; return RawbitsToFloat16(bits); } float FloatPack(uint32_t sign, uint32_t exp, uint32_t mantissa) { uint32_t bits = (sign << 31) | (exp << 23) | mantissa; return RawbitsToFloat(bits); } double DoublePack(uint64_t sign, uint64_t exp, uint64_t mantissa) { uint64_t bits = (sign << 63) | (exp << 52) | mantissa; return RawbitsToDouble(bits); } int Float16Classify(Float16 value) { uint16_t bits = Float16ToRawbits(value); uint16_t exponent_max = (1 << 5) - 1; uint16_t exponent_mask = exponent_max << 10; uint16_t mantissa_mask = (1 << 10) - 1; uint16_t exponent = (bits & exponent_mask) >> 10; uint16_t mantissa = bits & mantissa_mask; if (exponent == 0) { if (mantissa == 0) { return FP_ZERO; } return FP_SUBNORMAL; } else if (exponent == exponent_max) { if (mantissa == 0) { return FP_INFINITE; } return FP_NAN; } return FP_NORMAL; } unsigned CountClearHalfWords(uint64_t imm, unsigned reg_size) { VIXL_ASSERT((reg_size % 8) == 0); int count = 0; for (unsigned i = 0; i < (reg_size / 16); i++) { if ((imm & 0xffff) == 0) { count++; } imm >>= 16; } return count; } int BitCount(uint64_t value) { return CountSetBits(value); } // Float16 definitions. Float16::Float16(double dvalue) { rawbits_ = Float16ToRawbits(FPToFloat16(dvalue, FPTieEven, kIgnoreDefaultNaN)); } namespace internal { SimFloat16 SimFloat16::operator-() const { return RawbitsToFloat16(rawbits_ ^ 0x8000); } // SimFloat16 definitions. SimFloat16 SimFloat16::operator+(SimFloat16 rhs) const { return static_cast(*this) + static_cast(rhs); } SimFloat16 SimFloat16::operator-(SimFloat16 rhs) const { return static_cast(*this) - static_cast(rhs); } SimFloat16 SimFloat16::operator*(SimFloat16 rhs) const { return static_cast(*this) * static_cast(rhs); } SimFloat16 SimFloat16::operator/(SimFloat16 rhs) const { return static_cast(*this) / static_cast(rhs); } bool SimFloat16::operator<(SimFloat16 rhs) const { return static_cast(*this) < static_cast(rhs); } bool SimFloat16::operator>(SimFloat16 rhs) const { return static_cast(*this) > static_cast(rhs); } bool SimFloat16::operator==(SimFloat16 rhs) const { if (IsNaN(*this) || IsNaN(rhs)) { return false; } else if (IsZero(rhs) && IsZero(*this)) { // +0 and -0 should be treated as equal. return true; } return this->rawbits_ == rhs.rawbits_; } bool SimFloat16::operator!=(SimFloat16 rhs) const { return !(*this == rhs); } bool SimFloat16::operator==(double rhs) const { return static_cast(*this) == static_cast(rhs); } SimFloat16::operator double() const { return FPToDouble(*this, kIgnoreDefaultNaN); } Int64 BitCount(Uint32 value) { return CountSetBits(value.Get()); } } // namespace internal float FPToFloat(Float16 value, UseDefaultNaN DN, bool* exception) { uint16_t bits = Float16ToRawbits(value); uint32_t sign = bits >> 15; uint32_t exponent = ExtractUnsignedBitfield32(kFloat16MantissaBits + kFloat16ExponentBits - 1, kFloat16MantissaBits, bits); uint32_t mantissa = ExtractUnsignedBitfield32(kFloat16MantissaBits - 1, 0, bits); 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)); // 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 + (-15 + 127); break; } case FP_NAN: if (IsSignallingNaN(value)) { if (exception != NULL) { *exception = true; } } if (DN == kUseDefaultNaN) return kFP32DefaultNaN; // Convert NaNs as the processor would: // - The sign is propagated. // - The payload (mantissa) is transferred entirely, except that the top // bit is forced to '1', making the result a quiet NaN. The unused // (low-order) payload bits are set to 0. exponent = (1 << kFloatExponentBits) - 1; // Increase bits in mantissa, making low-order bits 0. mantissa <<= (kFloatMantissaBits - kFloat16MantissaBits); mantissa |= 1 << 22; // Force a quiet NaN. break; case FP_NORMAL: // Increase bits in mantissa, making low-order bits 0. mantissa <<= (kFloatMantissaBits - kFloat16MantissaBits); // Change exponent bias. exponent += (-15 + 127); break; default: VIXL_UNREACHABLE(); } return RawbitsToFloat((sign << 31) | (exponent << kFloatMantissaBits) | mantissa); } float FPToFloat(double value, FPRounding round_mode, UseDefaultNaN DN, bool* exception) { // Only the FPTieEven rounding mode is implemented. VIXL_ASSERT((round_mode == FPTieEven) || (round_mode == FPRoundOdd)); USE(round_mode); switch (std::fpclassify(value)) { case FP_NAN: { if (IsSignallingNaN(value)) { if (exception != NULL) { *exception = true; } } if (DN == kUseDefaultNaN) return kFP32DefaultNaN; // Convert NaNs as the processor would: // - The sign is propagated. // - The payload (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 = DoubleToRawbits(value); uint32_t sign = raw >> 63; uint32_t exponent = (1 << 8) - 1; uint32_t payload = static_cast(ExtractUnsignedBitfield64(50, 52 - 23, raw)); payload |= (1 << 22); // Force a quiet NaN. return RawbitsToFloat((sign << 31) | (exponent << 23) | payload); } 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(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. uint64_t raw = DoubleToRawbits(value); // Extract the IEEE-754 double components. uint32_t sign = raw >> 63; // Extract the exponent and remove the IEEE-754 encoding bias. int32_t exponent = static_cast(ExtractUnsignedBitfield64(62, 52, raw)) - 1023; // Extract the mantissa and add the implicit '1' bit. uint64_t mantissa = ExtractUnsignedBitfield64(51, 0, raw); if (std::fpclassify(value) == FP_NORMAL) { mantissa |= (UINT64_C(1) << 52); } return FPRoundToFloat(sign, exponent, mantissa, round_mode); } } VIXL_UNREACHABLE(); return static_cast(value); } // TODO: We should consider implementing a full FPToDouble(Float16) // conversion function (for performance reasons). double FPToDouble(Float16 value, UseDefaultNaN DN, bool* exception) { // We can rely on implicit float to double conversion here. return FPToFloat(value, DN, exception); } double FPToDouble(float value, UseDefaultNaN DN, bool* exception) { switch (std::fpclassify(value)) { case FP_NAN: { if (IsSignallingNaN(value)) { if (exception != NULL) { *exception = true; } } if (DN == kUseDefaultNaN) return kFP64DefaultNaN; // Convert NaNs as the processor would: // - The sign is propagated. // - The payload (mantissa) is transferred entirely, except that the top // bit is forced to '1', making the result a quiet NaN. The unused // (low-order) payload bits are set to 0. uint32_t raw = FloatToRawbits(value); uint64_t sign = raw >> 31; uint64_t exponent = (1 << 11) - 1; uint64_t payload = ExtractUnsignedBitfield64(21, 0, raw); payload <<= (52 - 23); // The unused low-order bits should be 0. payload |= (UINT64_C(1) << 51); // Force a quiet NaN. return RawbitsToDouble((sign << 63) | (exponent << 52) | payload); } 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(value); } } VIXL_UNREACHABLE(); return static_cast(value); } Float16 FPToFloat16(float value, FPRounding round_mode, UseDefaultNaN DN, bool* exception) { // Only the FPTieEven rounding mode is implemented. VIXL_ASSERT(round_mode == FPTieEven); USE(round_mode); uint32_t raw = FloatToRawbits(value); int32_t sign = raw >> 31; int32_t exponent = ExtractUnsignedBitfield32(30, 23, raw) - 127; uint32_t mantissa = ExtractUnsignedBitfield32(22, 0, raw); switch (std::fpclassify(value)) { case FP_NAN: { if (IsSignallingNaN(value)) { if (exception != NULL) { *exception = true; } } if (DN == kUseDefaultNaN) return kFP16DefaultNaN; // Convert NaNs as the processor would: // - The sign is propagated. // - The payload (mantissa) is transferred as much as possible, except // that the top bit is forced to '1', making the result a quiet NaN. uint16_t result = (sign == 0) ? Float16ToRawbits(kFP16PositiveInfinity) : Float16ToRawbits(kFP16NegativeInfinity); result |= mantissa >> (kFloatMantissaBits - kFloat16MantissaBits); result |= (1 << 9); // Force a quiet NaN; return RawbitsToFloat16(result); } case FP_ZERO: return (sign == 0) ? kFP16PositiveZero : kFP16NegativeZero; 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 << 23); return FPRoundToFloat16(sign, exponent, mantissa, round_mode); } } VIXL_UNREACHABLE(); return kFP16PositiveZero; } Float16 FPToFloat16(double value, FPRounding round_mode, UseDefaultNaN DN, bool* exception) { // Only the FPTieEven rounding mode is implemented. VIXL_ASSERT(round_mode == FPTieEven); USE(round_mode); uint64_t raw = DoubleToRawbits(value); int32_t sign = raw >> 63; int64_t exponent = ExtractUnsignedBitfield64(62, 52, raw) - 1023; uint64_t mantissa = ExtractUnsignedBitfield64(51, 0, raw); switch (std::fpclassify(value)) { case FP_NAN: { if (IsSignallingNaN(value)) { if (exception != NULL) { *exception = true; } } if (DN == kUseDefaultNaN) return kFP16DefaultNaN; // Convert NaNs as the processor would: // - The sign is propagated. // - The payload (mantissa) is transferred as much as possible, except // that the top bit is forced to '1', making the result a quiet NaN. uint16_t result = (sign == 0) ? Float16ToRawbits(kFP16PositiveInfinity) : Float16ToRawbits(kFP16NegativeInfinity); result |= mantissa >> (kDoubleMantissaBits - kFloat16MantissaBits); result |= (1 << 9); // Force a quiet NaN; return RawbitsToFloat16(result); } case FP_ZERO: return (sign == 0) ? kFP16PositiveZero : kFP16NegativeZero; 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) << 52); return FPRoundToFloat16(sign, exponent, mantissa, round_mode); } } VIXL_UNREACHABLE(); return kFP16PositiveZero; } } // namespace vixl