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- // Copyright (c) 2015-2016 The Khronos Group Inc.
- //
- // Licensed under the Apache License, Version 2.0 (the "License");
- // you may not use this file except in compliance with the License.
- // You may obtain a copy of the License at
- //
- // http://www.apache.org/licenses/LICENSE-2.0
- //
- // Unless required by applicable law or agreed to in writing, software
- // distributed under the License is distributed on an "AS IS" BASIS,
- // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
- // See the License for the specific language governing permissions and
- // limitations under the License.
- #include <cfloat>
- #include <cmath>
- #include <cstdio>
- #include <sstream>
- #include <string>
- #include <tuple>
- #include <gmock/gmock.h>
- #include "SPIRV/hex_float.h"
- namespace {
- using ::testing::Eq;
- using spvutils::BitwiseCast;
- using spvutils::Float16;
- using spvutils::FloatProxy;
- using spvutils::HexFloat;
- using spvutils::ParseNormalFloat;
- // In this file "encode" means converting a number into a string,
- // and "decode" means converting a string into a number.
- using HexFloatTest =
- ::testing::TestWithParam<std::pair<FloatProxy<float>, std::string>>;
- using DecodeHexFloatTest =
- ::testing::TestWithParam<std::pair<std::string, FloatProxy<float>>>;
- using HexDoubleTest =
- ::testing::TestWithParam<std::pair<FloatProxy<double>, std::string>>;
- using DecodeHexDoubleTest =
- ::testing::TestWithParam<std::pair<std::string, FloatProxy<double>>>;
- // Hex-encodes a float value.
- template <typename T>
- std::string EncodeViaHexFloat(const T& value) {
- std::stringstream ss;
- ss << spvutils::HexFloat<T>(value);
- return ss.str();
- }
- // The following two tests can't be DRY because they take different parameter
- // types.
- TEST_P(HexFloatTest, EncodeCorrectly) {
- EXPECT_THAT(EncodeViaHexFloat(GetParam().first), Eq(GetParam().second));
- }
- TEST_P(HexDoubleTest, EncodeCorrectly) {
- EXPECT_THAT(EncodeViaHexFloat(GetParam().first), Eq(GetParam().second));
- }
- // Decodes a hex-float string.
- template <typename T>
- FloatProxy<T> Decode(const std::string& str) {
- spvutils::HexFloat<FloatProxy<T>> decoded(0.f);
- EXPECT_TRUE((std::stringstream(str) >> decoded).eof());
- return decoded.value();
- }
- TEST_P(HexFloatTest, DecodeCorrectly) {
- EXPECT_THAT(Decode<float>(GetParam().second), Eq(GetParam().first));
- }
- TEST_P(HexDoubleTest, DecodeCorrectly) {
- EXPECT_THAT(Decode<double>(GetParam().second), Eq(GetParam().first));
- }
- INSTANTIATE_TEST_CASE_P(
- Float32Tests, HexFloatTest,
- ::testing::ValuesIn(std::vector<std::pair<FloatProxy<float>, std::string>>({
- {0.f, "0x0p+0"},
- {1.f, "0x1p+0"},
- {2.f, "0x1p+1"},
- {3.f, "0x1.8p+1"},
- {0.5f, "0x1p-1"},
- {0.25f, "0x1p-2"},
- {0.75f, "0x1.8p-1"},
- {-0.f, "-0x0p+0"},
- {-1.f, "-0x1p+0"},
- {-0.5f, "-0x1p-1"},
- {-0.25f, "-0x1p-2"},
- {-0.75f, "-0x1.8p-1"},
- // Larger numbers
- {512.f, "0x1p+9"},
- {-512.f, "-0x1p+9"},
- {1024.f, "0x1p+10"},
- {-1024.f, "-0x1p+10"},
- {1024.f + 8.f, "0x1.02p+10"},
- {-1024.f - 8.f, "-0x1.02p+10"},
- // Small numbers
- {1.0f / 512.f, "0x1p-9"},
- {1.0f / -512.f, "-0x1p-9"},
- {1.0f / 1024.f, "0x1p-10"},
- {1.0f / -1024.f, "-0x1p-10"},
- {1.0f / 1024.f + 1.0f / 8.f, "0x1.02p-3"},
- {1.0f / -1024.f - 1.0f / 8.f, "-0x1.02p-3"},
- // lowest non-denorm
- {float(ldexp(1.0f, -126)), "0x1p-126"},
- {float(ldexp(-1.0f, -126)), "-0x1p-126"},
- // Denormalized values
- {float(ldexp(1.0f, -127)), "0x1p-127"},
- {float(ldexp(1.0f, -127) / 2.0f), "0x1p-128"},
- {float(ldexp(1.0f, -127) / 4.0f), "0x1p-129"},
- {float(ldexp(1.0f, -127) / 8.0f), "0x1p-130"},
- {float(ldexp(-1.0f, -127)), "-0x1p-127"},
- {float(ldexp(-1.0f, -127) / 2.0f), "-0x1p-128"},
- {float(ldexp(-1.0f, -127) / 4.0f), "-0x1p-129"},
- {float(ldexp(-1.0f, -127) / 8.0f), "-0x1p-130"},
- {float(ldexp(1.0, -127) + (ldexp(1.0, -127) / 2.0f)), "0x1.8p-127"},
- {float(ldexp(1.0, -127) / 2.0 + (ldexp(1.0, -127) / 4.0f)),
- "0x1.8p-128"},
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float32NanTests, HexFloatTest,
- ::testing::ValuesIn(std::vector<std::pair<FloatProxy<float>, std::string>>({
- // Various NAN and INF cases
- {uint32_t(0xFF800000), "-0x1p+128"}, // -inf
- {uint32_t(0x7F800000), "0x1p+128"}, // inf
- {uint32_t(0xFFC00000), "-0x1.8p+128"}, // -nan
- {uint32_t(0xFF800100), "-0x1.0002p+128"}, // -nan
- {uint32_t(0xFF800c00), "-0x1.0018p+128"}, // -nan
- {uint32_t(0xFF80F000), "-0x1.01ep+128"}, // -nan
- {uint32_t(0xFFFFFFFF), "-0x1.fffffep+128"}, // -nan
- {uint32_t(0x7FC00000), "0x1.8p+128"}, // +nan
- {uint32_t(0x7F800100), "0x1.0002p+128"}, // +nan
- {uint32_t(0x7f800c00), "0x1.0018p+128"}, // +nan
- {uint32_t(0x7F80F000), "0x1.01ep+128"}, // +nan
- {uint32_t(0x7FFFFFFF), "0x1.fffffep+128"}, // +nan
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float64Tests, HexDoubleTest,
- ::testing::ValuesIn(
- std::vector<std::pair<FloatProxy<double>, std::string>>({
- {0., "0x0p+0"},
- {1., "0x1p+0"},
- {2., "0x1p+1"},
- {3., "0x1.8p+1"},
- {0.5, "0x1p-1"},
- {0.25, "0x1p-2"},
- {0.75, "0x1.8p-1"},
- {-0., "-0x0p+0"},
- {-1., "-0x1p+0"},
- {-0.5, "-0x1p-1"},
- {-0.25, "-0x1p-2"},
- {-0.75, "-0x1.8p-1"},
- // Larger numbers
- {512., "0x1p+9"},
- {-512., "-0x1p+9"},
- {1024., "0x1p+10"},
- {-1024., "-0x1p+10"},
- {1024. + 8., "0x1.02p+10"},
- {-1024. - 8., "-0x1.02p+10"},
- // Large outside the range of normal floats
- {ldexp(1.0, 128), "0x1p+128"},
- {ldexp(1.0, 129), "0x1p+129"},
- {ldexp(-1.0, 128), "-0x1p+128"},
- {ldexp(-1.0, 129), "-0x1p+129"},
- {ldexp(1.0, 128) + ldexp(1.0, 90), "0x1.0000000004p+128"},
- {ldexp(1.0, 129) + ldexp(1.0, 120), "0x1.008p+129"},
- {ldexp(-1.0, 128) + ldexp(1.0, 90), "-0x1.fffffffff8p+127"},
- {ldexp(-1.0, 129) + ldexp(1.0, 120), "-0x1.ffp+128"},
- // Small numbers
- {1.0 / 512., "0x1p-9"},
- {1.0 / -512., "-0x1p-9"},
- {1.0 / 1024., "0x1p-10"},
- {1.0 / -1024., "-0x1p-10"},
- {1.0 / 1024. + 1.0 / 8., "0x1.02p-3"},
- {1.0 / -1024. - 1.0 / 8., "-0x1.02p-3"},
- // Small outside the range of normal floats
- {ldexp(1.0, -128), "0x1p-128"},
- {ldexp(1.0, -129), "0x1p-129"},
- {ldexp(-1.0, -128), "-0x1p-128"},
- {ldexp(-1.0, -129), "-0x1p-129"},
- {ldexp(1.0, -128) + ldexp(1.0, -90), "0x1.0000000004p-90"},
- {ldexp(1.0, -129) + ldexp(1.0, -120), "0x1.008p-120"},
- {ldexp(-1.0, -128) + ldexp(1.0, -90), "0x1.fffffffff8p-91"},
- {ldexp(-1.0, -129) + ldexp(1.0, -120), "0x1.ffp-121"},
- // lowest non-denorm
- {ldexp(1.0, -1022), "0x1p-1022"},
- {ldexp(-1.0, -1022), "-0x1p-1022"},
- // Denormalized values
- {ldexp(1.0, -1023), "0x1p-1023"},
- {ldexp(1.0, -1023) / 2.0, "0x1p-1024"},
- {ldexp(1.0, -1023) / 4.0, "0x1p-1025"},
- {ldexp(1.0, -1023) / 8.0, "0x1p-1026"},
- {ldexp(-1.0, -1024), "-0x1p-1024"},
- {ldexp(-1.0, -1024) / 2.0, "-0x1p-1025"},
- {ldexp(-1.0, -1024) / 4.0, "-0x1p-1026"},
- {ldexp(-1.0, -1024) / 8.0, "-0x1p-1027"},
- {ldexp(1.0, -1023) + (ldexp(1.0, -1023) / 2.0), "0x1.8p-1023"},
- {ldexp(1.0, -1023) / 2.0 + (ldexp(1.0, -1023) / 4.0),
- "0x1.8p-1024"},
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float64NanTests, HexDoubleTest,
- ::testing::ValuesIn(std::vector<
- std::pair<FloatProxy<double>, std::string>>({
- // Various NAN and INF cases
- {uint64_t(0xFFF0000000000000LL), "-0x1p+1024"}, //-inf
- {uint64_t(0x7FF0000000000000LL), "0x1p+1024"}, //+inf
- {uint64_t(0xFFF8000000000000LL), "-0x1.8p+1024"}, // -nan
- {uint64_t(0xFFF0F00000000000LL), "-0x1.0fp+1024"}, // -nan
- {uint64_t(0xFFF0000000000001LL), "-0x1.0000000000001p+1024"}, // -nan
- {uint64_t(0xFFF0000300000000LL), "-0x1.00003p+1024"}, // -nan
- {uint64_t(0xFFFFFFFFFFFFFFFFLL), "-0x1.fffffffffffffp+1024"}, // -nan
- {uint64_t(0x7FF8000000000000LL), "0x1.8p+1024"}, // +nan
- {uint64_t(0x7FF0F00000000000LL), "0x1.0fp+1024"}, // +nan
- {uint64_t(0x7FF0000000000001LL), "0x1.0000000000001p+1024"}, // -nan
- {uint64_t(0x7FF0000300000000LL), "0x1.00003p+1024"}, // -nan
- {uint64_t(0x7FFFFFFFFFFFFFFFLL), "0x1.fffffffffffffp+1024"}, // -nan
- })),);
- TEST(HexFloatStreamTest, OperatorLeftShiftPreservesFloatAndFill) {
- std::stringstream s;
- s << std::setw(4) << std::oct << std::setfill('x') << 8 << " "
- << FloatProxy<float>(uint32_t(0xFF800100)) << " " << std::setw(4) << 9;
- EXPECT_THAT(s.str(), Eq(std::string("xx10 -0x1.0002p+128 xx11")));
- }
- TEST(HexDoubleStreamTest, OperatorLeftShiftPreservesFloatAndFill) {
- std::stringstream s;
- s << std::setw(4) << std::oct << std::setfill('x') << 8 << " "
- << FloatProxy<double>(uint64_t(0x7FF0F00000000000LL)) << " " << std::setw(4)
- << 9;
- EXPECT_THAT(s.str(), Eq(std::string("xx10 0x1.0fp+1024 xx11")));
- }
- TEST_P(DecodeHexFloatTest, DecodeCorrectly) {
- EXPECT_THAT(Decode<float>(GetParam().first), Eq(GetParam().second));
- }
- TEST_P(DecodeHexDoubleTest, DecodeCorrectly) {
- EXPECT_THAT(Decode<double>(GetParam().first), Eq(GetParam().second));
- }
- INSTANTIATE_TEST_CASE_P(
- Float32DecodeTests, DecodeHexFloatTest,
- ::testing::ValuesIn(std::vector<std::pair<std::string, FloatProxy<float>>>({
- {"0x0p+000", 0.f},
- {"0x0p0", 0.f},
- {"0x0p-0", 0.f},
- // flush to zero cases
- {"0x1p-500", 0.f}, // Exponent underflows.
- {"-0x1p-500", -0.f},
- {"0x0.00000000001p-126", 0.f}, // Fraction causes underflow.
- {"-0x0.0000000001p-127", -0.f},
- {"-0x0.01p-142", -0.f}, // Fraction causes additional underflow.
- {"0x0.01p-142", 0.f},
- // Some floats that do not encode the same way as they decode.
- {"0x2p+0", 2.f},
- {"0xFFp+0", 255.f},
- {"0x0.8p+0", 0.5f},
- {"0x0.4p+0", 0.25f},
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float32DecodeInfTests, DecodeHexFloatTest,
- ::testing::ValuesIn(std::vector<std::pair<std::string, FloatProxy<float>>>({
- // inf cases
- {"-0x1p+128", uint32_t(0xFF800000)}, // -inf
- {"0x32p+127", uint32_t(0x7F800000)}, // inf
- {"0x32p+500", uint32_t(0x7F800000)}, // inf
- {"-0x32p+127", uint32_t(0xFF800000)}, // -inf
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float64DecodeTests, DecodeHexDoubleTest,
- ::testing::ValuesIn(
- std::vector<std::pair<std::string, FloatProxy<double>>>({
- {"0x0p+000", 0.},
- {"0x0p0", 0.},
- {"0x0p-0", 0.},
- // flush to zero cases
- {"0x1p-5000", 0.}, // Exponent underflows.
- {"-0x1p-5000", -0.},
- {"0x0.0000000000000001p-1023", 0.}, // Fraction causes underflow.
- {"-0x0.000000000000001p-1024", -0.},
- {"-0x0.01p-1090", -0.f}, // Fraction causes additional underflow.
- {"0x0.01p-1090", 0.},
- // Some floats that do not encode the same way as they decode.
- {"0x2p+0", 2.},
- {"0xFFp+0", 255.},
- {"0x0.8p+0", 0.5},
- {"0x0.4p+0", 0.25},
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float64DecodeInfTests, DecodeHexDoubleTest,
- ::testing::ValuesIn(
- std::vector<std::pair<std::string, FloatProxy<double>>>({
- // inf cases
- {"-0x1p+1024", uint64_t(0xFFF0000000000000)}, // -inf
- {"0x32p+1023", uint64_t(0x7FF0000000000000)}, // inf
- {"0x32p+5000", uint64_t(0x7FF0000000000000)}, // inf
- {"-0x32p+1023", uint64_t(0xFFF0000000000000)}, // -inf
- })),);
- TEST(FloatProxy, ValidConversion) {
- EXPECT_THAT(FloatProxy<float>(1.f).getAsFloat(), Eq(1.0f));
- EXPECT_THAT(FloatProxy<float>(32.f).getAsFloat(), Eq(32.0f));
- EXPECT_THAT(FloatProxy<float>(-1.f).getAsFloat(), Eq(-1.0f));
- EXPECT_THAT(FloatProxy<float>(0.f).getAsFloat(), Eq(0.0f));
- EXPECT_THAT(FloatProxy<float>(-0.f).getAsFloat(), Eq(-0.0f));
- EXPECT_THAT(FloatProxy<float>(1.2e32f).getAsFloat(), Eq(1.2e32f));
- EXPECT_TRUE(std::isinf(FloatProxy<float>(uint32_t(0xFF800000)).getAsFloat()));
- EXPECT_TRUE(std::isinf(FloatProxy<float>(uint32_t(0x7F800000)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0xFFC00000)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0xFF800100)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0xFF800c00)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0xFF80F000)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0xFFFFFFFF)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0x7FC00000)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0x7F800100)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0x7f800c00)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0x7F80F000)).getAsFloat()));
- EXPECT_TRUE(std::isnan(FloatProxy<float>(uint32_t(0x7FFFFFFF)).getAsFloat()));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0xFF800000)).data(), Eq(0xFF800000u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0x7F800000)).data(), Eq(0x7F800000u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0xFFC00000)).data(), Eq(0xFFC00000u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0xFF800100)).data(), Eq(0xFF800100u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0xFF800c00)).data(), Eq(0xFF800c00u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0xFF80F000)).data(), Eq(0xFF80F000u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0xFFFFFFFF)).data(), Eq(0xFFFFFFFFu));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0x7FC00000)).data(), Eq(0x7FC00000u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0x7F800100)).data(), Eq(0x7F800100u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0x7f800c00)).data(), Eq(0x7f800c00u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0x7F80F000)).data(), Eq(0x7F80F000u));
- EXPECT_THAT(FloatProxy<float>(uint32_t(0x7FFFFFFF)).data(), Eq(0x7FFFFFFFu));
- }
- TEST(FloatProxy, Nan) {
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0xFFC00000)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0xFF800100)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0xFF800c00)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0xFF80F000)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0xFFFFFFFF)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0x7FC00000)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0x7F800100)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0x7f800c00)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0x7F80F000)).isNan());
- EXPECT_TRUE(FloatProxy<float>(uint32_t(0x7FFFFFFF)).isNan());
- }
- TEST(FloatProxy, Negation) {
- EXPECT_THAT((-FloatProxy<float>(1.f)).getAsFloat(), Eq(-1.0f));
- EXPECT_THAT((-FloatProxy<float>(0.f)).getAsFloat(), Eq(-0.0f));
- EXPECT_THAT((-FloatProxy<float>(-1.f)).getAsFloat(), Eq(1.0f));
- EXPECT_THAT((-FloatProxy<float>(-0.f)).getAsFloat(), Eq(0.0f));
- EXPECT_THAT((-FloatProxy<float>(32.f)).getAsFloat(), Eq(-32.0f));
- EXPECT_THAT((-FloatProxy<float>(-32.f)).getAsFloat(), Eq(32.0f));
- EXPECT_THAT((-FloatProxy<float>(1.2e32f)).getAsFloat(), Eq(-1.2e32f));
- EXPECT_THAT((-FloatProxy<float>(-1.2e32f)).getAsFloat(), Eq(1.2e32f));
- EXPECT_THAT(
- (-FloatProxy<float>(std::numeric_limits<float>::infinity())).getAsFloat(),
- Eq(-std::numeric_limits<float>::infinity()));
- EXPECT_THAT((-FloatProxy<float>(-std::numeric_limits<float>::infinity()))
- .getAsFloat(),
- Eq(std::numeric_limits<float>::infinity()));
- }
- // Test conversion of FloatProxy values to strings.
- //
- // In previous cases, we always wrapped the FloatProxy value in a HexFloat
- // before conversion to a string. In the following cases, the FloatProxy
- // decides for itself whether to print as a regular number or as a hex float.
- using FloatProxyFloatTest =
- ::testing::TestWithParam<std::pair<FloatProxy<float>, std::string>>;
- using FloatProxyDoubleTest =
- ::testing::TestWithParam<std::pair<FloatProxy<double>, std::string>>;
- // Converts a float value to a string via a FloatProxy.
- template <typename T>
- std::string EncodeViaFloatProxy(const T& value) {
- std::stringstream ss;
- ss << value;
- return ss.str();
- }
- // Converts a floating point string so that the exponent prefix
- // is 'e', and the exponent value does not have leading zeros.
- // The Microsoft runtime library likes to write things like "2.5E+010".
- // Convert that to "2.5e+10".
- // We don't care what happens to strings that are not floating point
- // strings.
- std::string NormalizeExponentInFloatString(std::string in) {
- std::string result;
- // Reserve one spot for the terminating null, even when the sscanf fails.
- std::vector<char> prefix(in.size() + 1);
- char e;
- char plus_or_minus;
- int exponent; // in base 10
- if ((4 == std::sscanf(in.c_str(), "%[-+.0123456789]%c%c%d", prefix.data(), &e,
- &plus_or_minus, &exponent)) &&
- (e == 'e' || e == 'E') &&
- (plus_or_minus == '-' || plus_or_minus == '+')) {
- // It looks like a floating point value with exponent.
- std::stringstream out;
- out << prefix.data() << 'e' << plus_or_minus << exponent;
- result = out.str();
- } else {
- result = in;
- }
- return result;
- }
- TEST(NormalizeFloat, Sample) {
- EXPECT_THAT(NormalizeExponentInFloatString(""), Eq(""));
- EXPECT_THAT(NormalizeExponentInFloatString("1e-12"), Eq("1e-12"));
- EXPECT_THAT(NormalizeExponentInFloatString("1E+14"), Eq("1e+14"));
- EXPECT_THAT(NormalizeExponentInFloatString("1e-0012"), Eq("1e-12"));
- EXPECT_THAT(NormalizeExponentInFloatString("1.263E+014"), Eq("1.263e+14"));
- }
- // The following two tests can't be DRY because they take different parameter
- // types.
- TEST_P(FloatProxyFloatTest, EncodeCorrectly) {
- EXPECT_THAT(
- NormalizeExponentInFloatString(EncodeViaFloatProxy(GetParam().first)),
- Eq(GetParam().second));
- }
- TEST_P(FloatProxyDoubleTest, EncodeCorrectly) {
- EXPECT_THAT(
- NormalizeExponentInFloatString(EncodeViaFloatProxy(GetParam().first)),
- Eq(GetParam().second));
- }
- INSTANTIATE_TEST_CASE_P(
- Float32Tests, FloatProxyFloatTest,
- ::testing::ValuesIn(std::vector<std::pair<FloatProxy<float>, std::string>>({
- // Zero
- {0.f, "0"},
- // Normal numbers
- {1.f, "1"},
- {-0.25f, "-0.25"},
- {1000.0f, "1000"},
- // Still normal numbers, but with large magnitude exponents.
- {float(ldexp(1.f, 126)), "8.50706e+37"},
- {float(ldexp(-1.f, -126)), "-1.17549e-38"},
- // denormalized values are printed as hex floats.
- {float(ldexp(1.0f, -127)), "0x1p-127"},
- {float(ldexp(1.5f, -128)), "0x1.8p-128"},
- {float(ldexp(1.25, -129)), "0x1.4p-129"},
- {float(ldexp(1.125, -130)), "0x1.2p-130"},
- {float(ldexp(-1.0f, -127)), "-0x1p-127"},
- {float(ldexp(-1.0f, -128)), "-0x1p-128"},
- {float(ldexp(-1.0f, -129)), "-0x1p-129"},
- {float(ldexp(-1.5f, -130)), "-0x1.8p-130"},
- // NaNs
- {FloatProxy<float>(uint32_t(0xFFC00000)), "-0x1.8p+128"},
- {FloatProxy<float>(uint32_t(0xFF800100)), "-0x1.0002p+128"},
- {std::numeric_limits<float>::infinity(), "0x1p+128"},
- {-std::numeric_limits<float>::infinity(), "-0x1p+128"},
- })),);
- INSTANTIATE_TEST_CASE_P(
- Float64Tests, FloatProxyDoubleTest,
- ::testing::ValuesIn(
- std::vector<std::pair<FloatProxy<double>, std::string>>({
- {0., "0"},
- {1., "1"},
- {-0.25, "-0.25"},
- {1000.0, "1000"},
- // Large outside the range of normal floats
- {ldexp(1.0, 128), "3.40282366920938e+38"},
- {ldexp(1.5, 129), "1.02084710076282e+39"},
- {ldexp(-1.0, 128), "-3.40282366920938e+38"},
- {ldexp(-1.5, 129), "-1.02084710076282e+39"},
- // Small outside the range of normal floats
- {ldexp(1.5, -129), "2.20405190779179e-39"},
- {ldexp(-1.5, -129), "-2.20405190779179e-39"},
- // lowest non-denorm
- {ldexp(1.0, -1022), "2.2250738585072e-308"},
- {ldexp(-1.0, -1022), "-2.2250738585072e-308"},
- // Denormalized values
- {ldexp(1.125, -1023), "0x1.2p-1023"},
- {ldexp(-1.375, -1024), "-0x1.6p-1024"},
- // NaNs
- {uint64_t(0x7FF8000000000000LL), "0x1.8p+1024"},
- {uint64_t(0xFFF0F00000000000LL), "-0x1.0fp+1024"},
- // Infinity
- {std::numeric_limits<double>::infinity(), "0x1p+1024"},
- {-std::numeric_limits<double>::infinity(), "-0x1p+1024"},
- })),);
- // double is used so that unbiased_exponent can be used with the output
- // of ldexp directly.
- int32_t unbiased_exponent(double f) {
- return spvutils::HexFloat<spvutils::FloatProxy<float>>(
- static_cast<float>(f)).getUnbiasedNormalizedExponent();
- }
- int16_t unbiased_half_exponent(uint16_t f) {
- return spvutils::HexFloat<spvutils::FloatProxy<spvutils::Float16>>(f)
- .getUnbiasedNormalizedExponent();
- }
- TEST(HexFloatOperationTest, UnbiasedExponent) {
- // Float cases
- EXPECT_EQ(0, unbiased_exponent(ldexp(1.0f, 0)));
- EXPECT_EQ(-32, unbiased_exponent(ldexp(1.0f, -32)));
- EXPECT_EQ(42, unbiased_exponent(ldexp(1.0f, 42)));
- EXPECT_EQ(125, unbiased_exponent(ldexp(1.0f, 125)));
- // Saturates to 128
- EXPECT_EQ(128, unbiased_exponent(ldexp(1.0f, 256)));
- EXPECT_EQ(-100, unbiased_exponent(ldexp(1.0f, -100)));
- EXPECT_EQ(-127, unbiased_exponent(ldexp(1.0f, -127))); // First denorm
- EXPECT_EQ(-128, unbiased_exponent(ldexp(1.0f, -128)));
- EXPECT_EQ(-129, unbiased_exponent(ldexp(1.0f, -129)));
- EXPECT_EQ(-140, unbiased_exponent(ldexp(1.0f, -140)));
- // Smallest representable number
- EXPECT_EQ(-126 - 23, unbiased_exponent(ldexp(1.0f, -126 - 23)));
- // Should get rounded to 0 first.
- EXPECT_EQ(0, unbiased_exponent(ldexp(1.0f, -127 - 23)));
- // Float16 cases
- // The exponent is represented in the bits 0x7C00
- // The offset is -15
- EXPECT_EQ(0, unbiased_half_exponent(0x3C00));
- EXPECT_EQ(3, unbiased_half_exponent(0x4800));
- EXPECT_EQ(-1, unbiased_half_exponent(0x3800));
- EXPECT_EQ(-14, unbiased_half_exponent(0x0400));
- EXPECT_EQ(16, unbiased_half_exponent(0x7C00));
- EXPECT_EQ(10, unbiased_half_exponent(0x6400));
- // Smallest representable number
- EXPECT_EQ(-24, unbiased_half_exponent(0x0001));
- }
- // Creates a float that is the sum of 1/(2 ^ fractions[i]) for i in factions
- float float_fractions(const std::vector<uint32_t>& fractions) {
- float f = 0;
- for(int32_t i: fractions) {
- f += std::ldexp(1.0f, -i);
- }
- return f;
- }
- // Returns the normalized significand of a HexFloat<FloatProxy<float>>
- // that was created by calling float_fractions with the input fractions,
- // raised to the power of exp.
- uint32_t normalized_significand(const std::vector<uint32_t>& fractions, uint32_t exp) {
- return spvutils::HexFloat<spvutils::FloatProxy<float>>(
- static_cast<float>(ldexp(float_fractions(fractions), exp)))
- .getNormalizedSignificand();
- }
- // Sets the bits from MSB to LSB of the significand part of a float.
- // For example 0 would set the bit 23 (counting from LSB to MSB),
- // and 1 would set the 22nd bit.
- uint32_t bits_set(const std::vector<uint32_t>& bits) {
- const uint32_t top_bit = 1u << 22u;
- uint32_t val= 0;
- for(uint32_t i: bits) {
- val |= top_bit >> i;
- }
- return val;
- }
- // The same as bits_set but for a Float16 value instead of 32-bit floating
- // point.
- uint16_t half_bits_set(const std::vector<uint32_t>& bits) {
- const uint32_t top_bit = 1u << 9u;
- uint32_t val= 0;
- for(uint32_t i: bits) {
- val |= top_bit >> i;
- }
- return static_cast<uint16_t>(val);
- }
- TEST(HexFloatOperationTest, NormalizedSignificand) {
- // For normalized numbers (the following) it should be a simple matter
- // of getting rid of the top implicit bit
- EXPECT_EQ(bits_set({}), normalized_significand({0}, 0));
- EXPECT_EQ(bits_set({0}), normalized_significand({0, 1}, 0));
- EXPECT_EQ(bits_set({0, 1}), normalized_significand({0, 1, 2}, 0));
- EXPECT_EQ(bits_set({1}), normalized_significand({0, 2}, 0));
- EXPECT_EQ(bits_set({1}), normalized_significand({0, 2}, 32));
- EXPECT_EQ(bits_set({1}), normalized_significand({0, 2}, 126));
- // For denormalized numbers we expect the normalized significand to
- // shift as if it were normalized. This means, in practice that the
- // top_most set bit will be cut off. Looks very similar to above (on purpose)
- EXPECT_EQ(bits_set({}), normalized_significand({0}, -127));
- EXPECT_EQ(bits_set({3}), normalized_significand({0, 4}, -128));
- EXPECT_EQ(bits_set({3}), normalized_significand({0, 4}, -127));
- EXPECT_EQ(bits_set({}), normalized_significand({22}, -127));
- EXPECT_EQ(bits_set({0}), normalized_significand({21, 22}, -127));
- }
- // Returns the 32-bit floating point value created by
- // calling setFromSignUnbiasedExponentAndNormalizedSignificand
- // on a HexFloat<FloatProxy<float>>
- float set_from_sign(bool negative, int32_t unbiased_exponent,
- uint32_t significand, bool round_denorm_up) {
- spvutils::HexFloat<spvutils::FloatProxy<float>> f(0.f);
- f.setFromSignUnbiasedExponentAndNormalizedSignificand(
- negative, unbiased_exponent, significand, round_denorm_up);
- return f.value().getAsFloat();
- }
- TEST(HexFloatOperationTests,
- SetFromSignUnbiasedExponentAndNormalizedSignificand) {
- EXPECT_EQ(1.f, set_from_sign(false, 0, 0, false));
- // Tests insertion of various denormalized numbers with and without round up.
- EXPECT_EQ(static_cast<float>(ldexp(1.f, -149)), set_from_sign(false, -149, 0, false));
- EXPECT_EQ(static_cast<float>(ldexp(1.f, -149)), set_from_sign(false, -149, 0, true));
- EXPECT_EQ(0.f, set_from_sign(false, -150, 1, false));
- EXPECT_EQ(static_cast<float>(ldexp(1.f, -149)), set_from_sign(false, -150, 1, true));
- EXPECT_EQ(ldexp(1.0f, -127), set_from_sign(false, -127, 0, false));
- EXPECT_EQ(ldexp(1.0f, -128), set_from_sign(false, -128, 0, false));
- EXPECT_EQ(float_fractions({0, 1, 2, 5}),
- set_from_sign(false, 0, bits_set({0, 1, 4}), false));
- EXPECT_EQ(ldexp(float_fractions({0, 1, 2, 5}), -32),
- set_from_sign(false, -32, bits_set({0, 1, 4}), false));
- EXPECT_EQ(ldexp(float_fractions({0, 1, 2, 5}), -128),
- set_from_sign(false, -128, bits_set({0, 1, 4}), false));
- // The negative cases from above.
- EXPECT_EQ(-1.f, set_from_sign(true, 0, 0, false));
- EXPECT_EQ(-ldexp(1.0, -127), set_from_sign(true, -127, 0, false));
- EXPECT_EQ(-ldexp(1.0, -128), set_from_sign(true, -128, 0, false));
- EXPECT_EQ(-float_fractions({0, 1, 2, 5}),
- set_from_sign(true, 0, bits_set({0, 1, 4}), false));
- EXPECT_EQ(-ldexp(float_fractions({0, 1, 2, 5}), -32),
- set_from_sign(true, -32, bits_set({0, 1, 4}), false));
- EXPECT_EQ(-ldexp(float_fractions({0, 1, 2, 5}), -128),
- set_from_sign(true, -128, bits_set({0, 1, 4}), false));
- }
- TEST(HexFloatOperationTests, NonRounding) {
- // Rounding from 32-bit hex-float to 32-bit hex-float should be trivial,
- // except in the denorm case which is a bit more complex.
- using HF = spvutils::HexFloat<spvutils::FloatProxy<float>>;
- bool carry_bit = false;
- spvutils::round_direction rounding[] = {
- spvutils::kRoundToZero,
- spvutils::kRoundToNearestEven,
- spvutils::kRoundToPositiveInfinity,
- spvutils::kRoundToNegativeInfinity};
- // Everything fits, so this should be straight-forward
- for (spvutils::round_direction round : rounding) {
- EXPECT_EQ(bits_set({}), HF(0.f).getRoundedNormalizedSignificand<HF>(
- round, &carry_bit));
- EXPECT_FALSE(carry_bit);
- EXPECT_EQ(bits_set({0}),
- HF(float_fractions({0, 1}))
- .getRoundedNormalizedSignificand<HF>(round, &carry_bit));
- EXPECT_FALSE(carry_bit);
- EXPECT_EQ(bits_set({1, 3}),
- HF(float_fractions({0, 2, 4}))
- .getRoundedNormalizedSignificand<HF>(round, &carry_bit));
- EXPECT_FALSE(carry_bit);
- EXPECT_EQ(
- bits_set({0, 1, 4}),
- HF(static_cast<float>(-ldexp(float_fractions({0, 1, 2, 5}), -128)))
- .getRoundedNormalizedSignificand<HF>(round, &carry_bit));
- EXPECT_FALSE(carry_bit);
- EXPECT_EQ(
- bits_set({0, 1, 4, 22}),
- HF(static_cast<float>(float_fractions({0, 1, 2, 5, 23})))
- .getRoundedNormalizedSignificand<HF>(round, &carry_bit));
- EXPECT_FALSE(carry_bit);
- }
- }
- struct RoundSignificandCase {
- float source_float;
- std::pair<int16_t, bool> expected_results;
- spvutils::round_direction round;
- };
- using HexFloatRoundTest =
- ::testing::TestWithParam<RoundSignificandCase>;
- TEST_P(HexFloatRoundTest, RoundDownToFP16) {
- using HF = spvutils::HexFloat<spvutils::FloatProxy<float>>;
- using HF16 = spvutils::HexFloat<spvutils::FloatProxy<spvutils::Float16>>;
- HF input_value(GetParam().source_float);
- bool carry_bit = false;
- EXPECT_EQ(GetParam().expected_results.first,
- input_value.getRoundedNormalizedSignificand<HF16>(
- GetParam().round, &carry_bit));
- EXPECT_EQ(carry_bit, GetParam().expected_results.second);
- }
- // clang-format off
- INSTANTIATE_TEST_CASE_P(F32ToF16, HexFloatRoundTest,
- ::testing::ValuesIn(std::vector<RoundSignificandCase>(
- {
- {float_fractions({0}), std::make_pair(half_bits_set({}), false), spvutils::kRoundToZero},
- {float_fractions({0}), std::make_pair(half_bits_set({}), false), spvutils::kRoundToNearestEven},
- {float_fractions({0}), std::make_pair(half_bits_set({}), false), spvutils::kRoundToPositiveInfinity},
- {float_fractions({0}), std::make_pair(half_bits_set({}), false), spvutils::kRoundToNegativeInfinity},
- {float_fractions({0, 1}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToZero},
- {float_fractions({0, 1, 11}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToZero},
- {float_fractions({0, 1, 11}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToPositiveInfinity},
- {float_fractions({0, 1, 11}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToNegativeInfinity},
- {float_fractions({0, 1, 11}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToNearestEven},
- {float_fractions({0, 1, 10, 11}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToZero},
- {float_fractions({0, 1, 10, 11}), std::make_pair(half_bits_set({0, 8}), false), spvutils::kRoundToPositiveInfinity},
- {float_fractions({0, 1, 10, 11}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToNegativeInfinity},
- {float_fractions({0, 1, 10, 11}), std::make_pair(half_bits_set({0, 8}), false), spvutils::kRoundToNearestEven},
- {float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToZero},
- {float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToPositiveInfinity},
- {float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToNegativeInfinity},
- {float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToNearestEven},
- {-float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToZero},
- {-float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToPositiveInfinity},
- {-float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToNegativeInfinity},
- {-float_fractions({0, 1, 11, 12}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToNearestEven},
- {float_fractions({0, 1, 11, 22}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToZero},
- {float_fractions({0, 1, 11, 22}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToPositiveInfinity},
- {float_fractions({0, 1, 11, 22}), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToNegativeInfinity},
- {float_fractions({0, 1, 11, 22}), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToNearestEven},
- // Carries
- {float_fractions({0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}), std::make_pair(half_bits_set({0, 1, 2, 3, 4, 5, 6, 7, 8, 9}), false), spvutils::kRoundToZero},
- {float_fractions({0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}), std::make_pair(half_bits_set({}), true), spvutils::kRoundToPositiveInfinity},
- {float_fractions({0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}), std::make_pair(half_bits_set({0, 1, 2, 3, 4, 5, 6, 7, 8, 9}), false), spvutils::kRoundToNegativeInfinity},
- {float_fractions({0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}), std::make_pair(half_bits_set({}), true), spvutils::kRoundToNearestEven},
- // Cases where original number was denorm. Note: this should have no effect
- // the number is pre-normalized.
- {static_cast<float>(ldexp(float_fractions({0, 1, 11, 13}), -128)), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToZero},
- {static_cast<float>(ldexp(float_fractions({0, 1, 11, 13}), -129)), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToPositiveInfinity},
- {static_cast<float>(ldexp(float_fractions({0, 1, 11, 13}), -131)), std::make_pair(half_bits_set({0}), false), spvutils::kRoundToNegativeInfinity},
- {static_cast<float>(ldexp(float_fractions({0, 1, 11, 13}), -130)), std::make_pair(half_bits_set({0, 9}), false), spvutils::kRoundToNearestEven},
- })),);
- // clang-format on
- struct UpCastSignificandCase {
- uint16_t source_half;
- uint32_t expected_result;
- };
- using HexFloatRoundUpSignificandTest =
- ::testing::TestWithParam<UpCastSignificandCase>;
- TEST_P(HexFloatRoundUpSignificandTest, Widening) {
- using HF = spvutils::HexFloat<spvutils::FloatProxy<float>>;
- using HF16 = spvutils::HexFloat<spvutils::FloatProxy<spvutils::Float16>>;
- bool carry_bit = false;
- spvutils::round_direction rounding[] = {
- spvutils::kRoundToZero,
- spvutils::kRoundToNearestEven,
- spvutils::kRoundToPositiveInfinity,
- spvutils::kRoundToNegativeInfinity};
- // Everything fits, so everything should just be bit-shifts.
- for (spvutils::round_direction round : rounding) {
- carry_bit = false;
- HF16 input_value(GetParam().source_half);
- EXPECT_EQ(
- GetParam().expected_result,
- input_value.getRoundedNormalizedSignificand<HF>(round, &carry_bit))
- << std::hex << "0x"
- << input_value.getRoundedNormalizedSignificand<HF>(round, &carry_bit)
- << " 0x" << GetParam().expected_result;
- EXPECT_FALSE(carry_bit);
- }
- }
- INSTANTIATE_TEST_CASE_P(F16toF32, HexFloatRoundUpSignificandTest,
- // 0xFC00 of the source 16-bit hex value cover the sign and the exponent.
- // They are ignored for this test.
- ::testing::ValuesIn(std::vector<UpCastSignificandCase>(
- {
- {0x3F00, 0x600000},
- {0x0F00, 0x600000},
- {0x0F01, 0x602000},
- {0x0FFF, 0x7FE000},
- })),);
- struct DownCastTest {
- float source_float;
- uint16_t expected_half;
- std::vector<spvutils::round_direction> directions;
- };
- std::string get_round_text(spvutils::round_direction direction) {
- #define CASE(round_direction) \
- case round_direction: \
- return #round_direction
- switch (direction) {
- CASE(spvutils::kRoundToZero);
- CASE(spvutils::kRoundToPositiveInfinity);
- CASE(spvutils::kRoundToNegativeInfinity);
- CASE(spvutils::kRoundToNearestEven);
- }
- #undef CASE
- return "";
- }
- using HexFloatFP32To16Tests = ::testing::TestWithParam<DownCastTest>;
- TEST_P(HexFloatFP32To16Tests, NarrowingCasts) {
- using HF = spvutils::HexFloat<spvutils::FloatProxy<float>>;
- using HF16 = spvutils::HexFloat<spvutils::FloatProxy<spvutils::Float16>>;
- HF f(GetParam().source_float);
- for (auto round : GetParam().directions) {
- HF16 half(0);
- f.castTo(half, round);
- EXPECT_EQ(GetParam().expected_half, half.value().getAsFloat().get_value())
- << get_round_text(round) << " " << std::hex
- << spvutils::BitwiseCast<uint32_t>(GetParam().source_float)
- << " cast to: " << half.value().getAsFloat().get_value();
- }
- }
- const uint16_t positive_infinity = 0x7C00;
- const uint16_t negative_infinity = 0xFC00;
- INSTANTIATE_TEST_CASE_P(F32ToF16, HexFloatFP32To16Tests,
- ::testing::ValuesIn(std::vector<DownCastTest>(
- {
- // Exactly representable as half.
- {0.f, 0x0, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {-0.f, 0x8000, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {1.0f, 0x3C00, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {-1.0f, 0xBC00, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {float_fractions({0, 1, 10}) , 0x3E01, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {-float_fractions({0, 1, 10}) , 0xBE01, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(ldexp(float_fractions({0, 1, 10}), 3)), 0x4A01, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(-ldexp(float_fractions({0, 1, 10}), 3)), 0xCA01, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- // Underflow
- {static_cast<float>(ldexp(1.0f, -25)), 0x0, {spvutils::kRoundToZero, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(ldexp(1.0f, -25)), 0x1, {spvutils::kRoundToPositiveInfinity}},
- {static_cast<float>(-ldexp(1.0f, -25)), 0x8000, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(-ldexp(1.0f, -25)), 0x8001, {spvutils::kRoundToNegativeInfinity}},
- {static_cast<float>(ldexp(1.0f, -24)), 0x1, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- // Overflow
- {static_cast<float>(ldexp(1.0f, 16)), positive_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(ldexp(1.0f, 18)), positive_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(ldexp(1.3f, 16)), positive_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(-ldexp(1.0f, 16)), negative_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(-ldexp(1.0f, 18)), negative_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {static_cast<float>(-ldexp(1.3f, 16)), negative_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- // Transfer of Infinities
- {std::numeric_limits<float>::infinity(), positive_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- {-std::numeric_limits<float>::infinity(), negative_infinity, {spvutils::kRoundToZero, spvutils::kRoundToPositiveInfinity, spvutils::kRoundToNegativeInfinity, spvutils::kRoundToNearestEven}},
- // Nans are below because we cannot test for equality.
- })),);
- struct UpCastCase{
- uint16_t source_half;
- float expected_float;
- };
- using HexFloatFP16To32Tests = ::testing::TestWithParam<UpCastCase>;
- TEST_P(HexFloatFP16To32Tests, WideningCasts) {
- using HF = spvutils::HexFloat<spvutils::FloatProxy<float>>;
- using HF16 = spvutils::HexFloat<spvutils::FloatProxy<spvutils::Float16>>;
- HF16 f(GetParam().source_half);
- spvutils::round_direction rounding[] = {
- spvutils::kRoundToZero,
- spvutils::kRoundToNearestEven,
- spvutils::kRoundToPositiveInfinity,
- spvutils::kRoundToNegativeInfinity};
- // Everything fits, so everything should just be bit-shifts.
- for (spvutils::round_direction round : rounding) {
- HF flt(0.f);
- f.castTo(flt, round);
- EXPECT_EQ(GetParam().expected_float, flt.value().getAsFloat())
- << get_round_text(round) << " " << std::hex
- << spvutils::BitwiseCast<uint16_t>(GetParam().source_half)
- << " cast to: " << flt.value().getAsFloat();
- }
- }
- INSTANTIATE_TEST_CASE_P(F16ToF32, HexFloatFP16To32Tests,
- ::testing::ValuesIn(std::vector<UpCastCase>(
- {
- {0x0000, 0.f},
- {0x8000, -0.f},
- {0x3C00, 1.0f},
- {0xBC00, -1.0f},
- {0x3F00, float_fractions({0, 1, 2})},
- {0xBF00, -float_fractions({0, 1, 2})},
- {0x3F01, float_fractions({0, 1, 2, 10})},
- {0xBF01, -float_fractions({0, 1, 2, 10})},
- // denorm
- {0x0001, static_cast<float>(ldexp(1.0, -24))},
- {0x0002, static_cast<float>(ldexp(1.0, -23))},
- {0x8001, static_cast<float>(-ldexp(1.0, -24))},
- {0x8011, static_cast<float>(-ldexp(1.0, -20) + -ldexp(1.0, -24))},
- // inf
- {0x7C00, std::numeric_limits<float>::infinity()},
- {0xFC00, -std::numeric_limits<float>::infinity()},
- })),);
- TEST(HexFloatOperationTests, NanTests) {
- using HF = spvutils::HexFloat<spvutils::FloatProxy<float>>;
- using HF16 = spvutils::HexFloat<spvutils::FloatProxy<spvutils::Float16>>;
- spvutils::round_direction rounding[] = {
- spvutils::kRoundToZero,
- spvutils::kRoundToNearestEven,
- spvutils::kRoundToPositiveInfinity,
- spvutils::kRoundToNegativeInfinity};
- // Everything fits, so everything should just be bit-shifts.
- for (spvutils::round_direction round : rounding) {
- HF16 f16(0);
- HF f(0.f);
- HF(std::numeric_limits<float>::quiet_NaN()).castTo(f16, round);
- EXPECT_TRUE(f16.value().isNan());
- HF(std::numeric_limits<float>::signaling_NaN()).castTo(f16, round);
- EXPECT_TRUE(f16.value().isNan());
- HF16(0x7C01).castTo(f, round);
- EXPECT_TRUE(f.value().isNan());
- HF16(0x7C11).castTo(f, round);
- EXPECT_TRUE(f.value().isNan());
- HF16(0xFC01).castTo(f, round);
- EXPECT_TRUE(f.value().isNan());
- HF16(0x7C10).castTo(f, round);
- EXPECT_TRUE(f.value().isNan());
- HF16(0xFF00).castTo(f, round);
- EXPECT_TRUE(f.value().isNan());
- }
- }
- // A test case for parsing good and bad HexFloat<FloatProxy<T>> literals.
- template <typename T>
- struct FloatParseCase {
- std::string literal;
- bool negate_value;
- bool expect_success;
- HexFloat<FloatProxy<T>> expected_value;
- };
- using ParseNormalFloatTest = ::testing::TestWithParam<FloatParseCase<float>>;
- TEST_P(ParseNormalFloatTest, Samples) {
- std::stringstream input(GetParam().literal);
- HexFloat<FloatProxy<float>> parsed_value(0.0f);
- ParseNormalFloat(input, GetParam().negate_value, parsed_value);
- EXPECT_NE(GetParam().expect_success, input.fail())
- << " literal: " << GetParam().literal
- << " negate: " << GetParam().negate_value;
- if (GetParam().expect_success) {
- EXPECT_THAT(parsed_value.value(), Eq(GetParam().expected_value.value()))
- << " literal: " << GetParam().literal
- << " negate: " << GetParam().negate_value;
- }
- }
- // Returns a FloatParseCase with expected failure.
- template <typename T>
- FloatParseCase<T> BadFloatParseCase(std::string literal, bool negate_value,
- T expected_value) {
- HexFloat<FloatProxy<T>> proxy_expected_value(expected_value);
- return FloatParseCase<T>{literal, negate_value, false, proxy_expected_value};
- }
- // Returns a FloatParseCase that should successfully parse to a given value.
- template <typename T>
- FloatParseCase<T> GoodFloatParseCase(std::string literal, bool negate_value,
- T expected_value) {
- HexFloat<FloatProxy<T>> proxy_expected_value(expected_value);
- return FloatParseCase<T>{literal, negate_value, true, proxy_expected_value};
- }
- INSTANTIATE_TEST_CASE_P(
- FloatParse, ParseNormalFloatTest,
- ::testing::ValuesIn(std::vector<FloatParseCase<float>>{
- // Failing cases due to trivially incorrect syntax.
- BadFloatParseCase("abc", false, 0.0f),
- BadFloatParseCase("abc", true, 0.0f),
- // Valid cases.
- GoodFloatParseCase("0", false, 0.0f),
- GoodFloatParseCase("0.0", false, 0.0f),
- GoodFloatParseCase("-0.0", false, -0.0f),
- GoodFloatParseCase("2.0", false, 2.0f),
- GoodFloatParseCase("-2.0", false, -2.0f),
- GoodFloatParseCase("+2.0", false, 2.0f),
- // Cases with negate_value being true.
- GoodFloatParseCase("0.0", true, -0.0f),
- GoodFloatParseCase("2.0", true, -2.0f),
- // When negate_value is true, we should not accept a
- // leading minus or plus.
- BadFloatParseCase("-0.0", true, 0.0f),
- BadFloatParseCase("-2.0", true, 0.0f),
- BadFloatParseCase("+0.0", true, 0.0f),
- BadFloatParseCase("+2.0", true, 0.0f),
- // Overflow is an error for 32-bit float parsing.
- BadFloatParseCase("1e40", false, FLT_MAX),
- BadFloatParseCase("1e40", true, -FLT_MAX),
- BadFloatParseCase("-1e40", false, -FLT_MAX),
- // We can't have -1e40 and negate_value == true since
- // that represents an original case of "--1e40" which
- // is invalid.
- }),);
- using ParseNormalFloat16Test =
- ::testing::TestWithParam<FloatParseCase<Float16>>;
- TEST_P(ParseNormalFloat16Test, Samples) {
- std::stringstream input(GetParam().literal);
- HexFloat<FloatProxy<Float16>> parsed_value(0);
- ParseNormalFloat(input, GetParam().negate_value, parsed_value);
- EXPECT_NE(GetParam().expect_success, input.fail())
- << " literal: " << GetParam().literal
- << " negate: " << GetParam().negate_value;
- if (GetParam().expect_success) {
- EXPECT_THAT(parsed_value.value(), Eq(GetParam().expected_value.value()))
- << " literal: " << GetParam().literal
- << " negate: " << GetParam().negate_value;
- }
- }
- INSTANTIATE_TEST_CASE_P(
- Float16Parse, ParseNormalFloat16Test,
- ::testing::ValuesIn(std::vector<FloatParseCase<Float16>>{
- // Failing cases due to trivially incorrect syntax.
- BadFloatParseCase<Float16>("abc", false, uint16_t{0}),
- BadFloatParseCase<Float16>("abc", true, uint16_t{0}),
- // Valid cases.
- GoodFloatParseCase<Float16>("0", false, uint16_t{0}),
- GoodFloatParseCase<Float16>("0.0", false, uint16_t{0}),
- GoodFloatParseCase<Float16>("-0.0", false, uint16_t{0x8000}),
- GoodFloatParseCase<Float16>("2.0", false, uint16_t{0x4000}),
- GoodFloatParseCase<Float16>("-2.0", false, uint16_t{0xc000}),
- GoodFloatParseCase<Float16>("+2.0", false, uint16_t{0x4000}),
- // Cases with negate_value being true.
- GoodFloatParseCase<Float16>("0.0", true, uint16_t{0x8000}),
- GoodFloatParseCase<Float16>("2.0", true, uint16_t{0xc000}),
- // When negate_value is true, we should not accept a leading minus or
- // plus.
- BadFloatParseCase<Float16>("-0.0", true, uint16_t{0}),
- BadFloatParseCase<Float16>("-2.0", true, uint16_t{0}),
- BadFloatParseCase<Float16>("+0.0", true, uint16_t{0}),
- BadFloatParseCase<Float16>("+2.0", true, uint16_t{0}),
- }),);
- // A test case for detecting infinities.
- template <typename T>
- struct OverflowParseCase {
- std::string input;
- bool expect_success;
- T expected_value;
- };
- using FloatProxyParseOverflowFloatTest =
- ::testing::TestWithParam<OverflowParseCase<float>>;
- TEST_P(FloatProxyParseOverflowFloatTest, Sample) {
- std::istringstream input(GetParam().input);
- HexFloat<FloatProxy<float>> value(0.0f);
- input >> value;
- EXPECT_NE(GetParam().expect_success, input.fail());
- if (GetParam().expect_success) {
- EXPECT_THAT(value.value().getAsFloat(), GetParam().expected_value);
- }
- }
- INSTANTIATE_TEST_CASE_P(
- FloatOverflow, FloatProxyParseOverflowFloatTest,
- ::testing::ValuesIn(std::vector<OverflowParseCase<float>>({
- {"0", true, 0.0f},
- {"0.0", true, 0.0f},
- {"1.0", true, 1.0f},
- {"1e38", true, 1e38f},
- {"-1e38", true, -1e38f},
- {"1e40", false, FLT_MAX},
- {"-1e40", false, -FLT_MAX},
- {"1e400", false, FLT_MAX},
- {"-1e400", false, -FLT_MAX},
- })),);
- using FloatProxyParseOverflowDoubleTest =
- ::testing::TestWithParam<OverflowParseCase<double>>;
- TEST_P(FloatProxyParseOverflowDoubleTest, Sample) {
- std::istringstream input(GetParam().input);
- HexFloat<FloatProxy<double>> value(0.0);
- input >> value;
- EXPECT_NE(GetParam().expect_success, input.fail());
- if (GetParam().expect_success) {
- EXPECT_THAT(value.value().getAsFloat(), Eq(GetParam().expected_value));
- }
- }
- INSTANTIATE_TEST_CASE_P(
- DoubleOverflow, FloatProxyParseOverflowDoubleTest,
- ::testing::ValuesIn(std::vector<OverflowParseCase<double>>({
- {"0", true, 0.0},
- {"0.0", true, 0.0},
- {"1.0", true, 1.0},
- {"1e38", true, 1e38},
- {"-1e38", true, -1e38},
- {"1e40", true, 1e40},
- {"-1e40", true, -1e40},
- {"1e400", false, DBL_MAX},
- {"-1e400", false, -DBL_MAX},
- })),);
- using FloatProxyParseOverflowFloat16Test =
- ::testing::TestWithParam<OverflowParseCase<uint16_t>>;
- TEST_P(FloatProxyParseOverflowFloat16Test, Sample) {
- std::istringstream input(GetParam().input);
- HexFloat<FloatProxy<Float16>> value(0);
- input >> value;
- EXPECT_NE(GetParam().expect_success, input.fail()) << " literal: "
- << GetParam().input;
- if (GetParam().expect_success) {
- EXPECT_THAT(value.value().data(), Eq(GetParam().expected_value))
- << " literal: " << GetParam().input;
- }
- }
- INSTANTIATE_TEST_CASE_P(
- Float16Overflow, FloatProxyParseOverflowFloat16Test,
- ::testing::ValuesIn(std::vector<OverflowParseCase<uint16_t>>({
- {"0", true, uint16_t{0}},
- {"0.0", true, uint16_t{0}},
- {"1.0", true, uint16_t{0x3c00}},
- // Overflow for 16-bit float is an error, and returns max or
- // lowest value.
- {"1e38", false, uint16_t{0x7bff}},
- {"1e40", false, uint16_t{0x7bff}},
- {"1e400", false, uint16_t{0x7bff}},
- {"-1e38", false, uint16_t{0xfbff}},
- {"-1e40", false, uint16_t{0xfbff}},
- {"-1e400", false, uint16_t{0xfbff}},
- })),);
- TEST(FloatProxy, Max) {
- EXPECT_THAT(FloatProxy<Float16>::max().getAsFloat().get_value(),
- Eq(uint16_t{0x7bff}));
- EXPECT_THAT(FloatProxy<float>::max().getAsFloat(),
- Eq(std::numeric_limits<float>::max()));
- EXPECT_THAT(FloatProxy<double>::max().getAsFloat(),
- Eq(std::numeric_limits<double>::max()));
- }
- TEST(FloatProxy, Lowest) {
- EXPECT_THAT(FloatProxy<Float16>::lowest().getAsFloat().get_value(),
- Eq(uint16_t{0xfbff}));
- EXPECT_THAT(FloatProxy<float>::lowest().getAsFloat(),
- Eq(std::numeric_limits<float>::lowest()));
- EXPECT_THAT(FloatProxy<double>::lowest().getAsFloat(),
- Eq(std::numeric_limits<double>::lowest()));
- }
- // TODO(awoloszyn): Add fp16 tests and HexFloatTraits.
- } // anonymous namespace
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