tests/gtest/avifcolrtest.cc - libavif - Git at Google

 // Copyright 2023 Google LLC
 // SPDX-License-Identifier: BSD-2-Clause

 #include <cmath>

 #include "avif/internal.h"
 #include "aviftest_helpers.h"
 #include "gtest/gtest.h"

 namespace avif {
 namespace {

 constexpr int kMaxTransferCharacteristic = 18;

 // Thresholds in the transfer curve formulas.
 // Add a little tolerance for test to pass on MinGW32.
 constexpr float kTransferLog100Threshold = 0.01f + 1e-7f;
 constexpr float kTransferLog100Sqrt10Threshold = 0.00316227766f;

 TEST(TransferCharacteristicsTest, RoundTrip) {
   for (int tc_idx = 0; tc_idx <= kMaxTransferCharacteristic; ++tc_idx) {
     const avifTransferCharacteristics tc = (avifTransferCharacteristics)tc_idx;
     SCOPED_TRACE("transfer characteristics: " + std::to_string(tc));

     const avifTransferFunction to_linear =
         avifTransferCharacteristicsGetGammaToLinearFunction(tc);
     const avifTransferFunction to_gamma =
         avifTransferCharacteristicsGetLinearToGammaFunction(tc);

     constexpr int kSteps = 1000;
     float min_linear = std::numeric_limits<float>::max();
     float max_linear = 0.0f;
     for (int j = 0; j <= kSteps; ++j) {
       const float v = static_cast<float>(j) / kSteps;

       float epsilon = 0.0001f;
       // Non bijective part of some transfer functions.
       if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100 &&
           v <= kTransferLog100Threshold) {
         epsilon = kTransferLog100Threshold / 2.0f;
       } else if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100_SQRT10 &&
                  v <= kTransferLog100Sqrt10Threshold) {
         epsilon = kTransferLog100Sqrt10Threshold / 2.0f;
       }

       // Check round trips.
       ASSERT_NEAR(to_linear(to_gamma(v)), v, epsilon);
       ASSERT_NEAR(to_gamma(to_linear(v)), v, epsilon);

       const float linear = to_linear(v);
       if (linear > max_linear) max_linear = linear;
       if (linear < min_linear) min_linear = linear;
     }

     if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100) {
       EXPECT_NEAR(min_linear, kTransferLog100Threshold / 2.0f, 1e-7f);
     } else if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100_SQRT10) {
       EXPECT_EQ(min_linear, kTransferLog100Sqrt10Threshold / 2.0f);
     } else {
       EXPECT_EQ(min_linear, 0.0f);
     }

     if (tc == AVIF_TRANSFER_CHARACTERISTICS_PQ) {
       EXPECT_NEAR(max_linear, 10000.0f / 203.0f,
                   0.00001);  // PQ max extended SDR value.
     } else if (tc == AVIF_TRANSFER_CHARACTERISTICS_HLG) {
       EXPECT_NEAR(max_linear, 1000.0f / 203.0f,
                   0.00001);  // HLG max extended SDR value.
     } else if (tc == AVIF_TRANSFER_CHARACTERISTICS_SMPTE428) {
       // See formula in Table 3 of ITU-T H.273.
       EXPECT_NEAR(max_linear, 52.37f / 48.0f, 0.00001f);
     } else {
       EXPECT_EQ(max_linear, 1.0f);
     }
   }
 }

 // Check that the liner->gamma function has the right shape, i.e. it's mostly
 // above the y=x diagonal.
 // This detects bugs where the linear->gamma and
 // gamma->linear implementations are swapped.
 TEST(TransferCharacteristicsTest, ToGammaHasCorrectShape) {
   for (int tc_idx = 0; tc_idx <= kMaxTransferCharacteristic; ++tc_idx) {
     const avifTransferCharacteristics tc = (avifTransferCharacteristics)tc_idx;
     SCOPED_TRACE("transfer characteristics: " + std::to_string(tc));

     const avifTransferFunction to_gamma =
         avifTransferCharacteristicsGetLinearToGammaFunction(tc);

     constexpr int kSteps = 20;
     for (int j = 0; j <= kSteps; ++j) {
       const float linear = static_cast<float>(j) / kSteps;

       float extended_sdr_scaled = linear;
       if (tc == AVIF_TRANSFER_CHARACTERISTICS_PQ) {
         // Scale to the whole range.
         extended_sdr_scaled *= 10000.0f / 203.0f;
       } else if (tc == AVIF_TRANSFER_CHARACTERISTICS_HLG) {
         extended_sdr_scaled *= 1000.0f / 203.0f;
       }

       const float gamma = to_gamma(extended_sdr_scaled);

       if (tc == AVIF_TRANSFER_CHARACTERISTICS_SMPTE428 && linear > 0.9f) {
         continue;  // Smpte428 is a bit below the y=x diagonal at the high end.
       }

       // Check the point is above (or at) the y=x diagonal, with some tolerance.
       ASSERT_GE(gamma, linear - 1e-6f);
     }
   }
 }

 }  // namespace
 }  // namespace avif
	// Copyright 2023 Google LLC
	// SPDX-License-Identifier: BSD-2-Clause

	#include <cmath>

	#include "avif/internal.h"
	#include "aviftest_helpers.h"
	#include "gtest/gtest.h"

	namespace avif {
	namespace {

	constexpr int kMaxTransferCharacteristic = 18;

	// Thresholds in the transfer curve formulas.
	// Add a little tolerance for test to pass on MinGW32.
	constexpr float kTransferLog100Threshold = 0.01f + 1e-7f;
	constexpr float kTransferLog100Sqrt10Threshold = 0.00316227766f;

	TEST(TransferCharacteristicsTest, RoundTrip) {
	for (int tc_idx = 0; tc_idx <= kMaxTransferCharacteristic; ++tc_idx) {
	const avifTransferCharacteristics tc = (avifTransferCharacteristics)tc_idx;
	SCOPED_TRACE("transfer characteristics: " + std::to_string(tc));

	const avifTransferFunction to_linear =
	avifTransferCharacteristicsGetGammaToLinearFunction(tc);
	const avifTransferFunction to_gamma =
	avifTransferCharacteristicsGetLinearToGammaFunction(tc);

	constexpr int kSteps = 1000;
	float min_linear = std::numeric_limits<float>::max();
	float max_linear = 0.0f;
	for (int j = 0; j <= kSteps; ++j) {
	const float v = static_cast<float>(j) / kSteps;

	float epsilon = 0.0001f;
	// Non bijective part of some transfer functions.
	if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100 &&
	v <= kTransferLog100Threshold) {
	epsilon = kTransferLog100Threshold / 2.0f;
	} else if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100_SQRT10 &&
	v <= kTransferLog100Sqrt10Threshold) {
	epsilon = kTransferLog100Sqrt10Threshold / 2.0f;
	}

	// Check round trips.
	ASSERT_NEAR(to_linear(to_gamma(v)), v, epsilon);
	ASSERT_NEAR(to_gamma(to_linear(v)), v, epsilon);

	const float linear = to_linear(v);
	if (linear > max_linear) max_linear = linear;
	if (linear < min_linear) min_linear = linear;
	}

	if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100) {
	EXPECT_NEAR(min_linear, kTransferLog100Threshold / 2.0f, 1e-7f);
	} else if (tc == AVIF_TRANSFER_CHARACTERISTICS_LOG100_SQRT10) {
	EXPECT_EQ(min_linear, kTransferLog100Sqrt10Threshold / 2.0f);
	} else {
	EXPECT_EQ(min_linear, 0.0f);
	}

	if (tc == AVIF_TRANSFER_CHARACTERISTICS_PQ) {
	EXPECT_NEAR(max_linear, 10000.0f / 203.0f,
	0.00001); // PQ max extended SDR value.
	} else if (tc == AVIF_TRANSFER_CHARACTERISTICS_HLG) {
	EXPECT_NEAR(max_linear, 1000.0f / 203.0f,
	0.00001); // HLG max extended SDR value.
	} else if (tc == AVIF_TRANSFER_CHARACTERISTICS_SMPTE428) {
	// See formula in Table 3 of ITU-T H.273.
	EXPECT_NEAR(max_linear, 52.37f / 48.0f, 0.00001f);
	} else {
	EXPECT_EQ(max_linear, 1.0f);
	}
	}
	}

	// Check that the liner->gamma function has the right shape, i.e. it's mostly
	// above the y=x diagonal.
	// This detects bugs where the linear->gamma and
	// gamma->linear implementations are swapped.
	TEST(TransferCharacteristicsTest, ToGammaHasCorrectShape) {
	for (int tc_idx = 0; tc_idx <= kMaxTransferCharacteristic; ++tc_idx) {
	const avifTransferCharacteristics tc = (avifTransferCharacteristics)tc_idx;
	SCOPED_TRACE("transfer characteristics: " + std::to_string(tc));

	const avifTransferFunction to_gamma =
	avifTransferCharacteristicsGetLinearToGammaFunction(tc);

	constexpr int kSteps = 20;
	for (int j = 0; j <= kSteps; ++j) {
	const float linear = static_cast<float>(j) / kSteps;

	float extended_sdr_scaled = linear;
	if (tc == AVIF_TRANSFER_CHARACTERISTICS_PQ) {
	// Scale to the whole range.
	extended_sdr_scaled *= 10000.0f / 203.0f;
	} else if (tc == AVIF_TRANSFER_CHARACTERISTICS_HLG) {
	extended_sdr_scaled *= 1000.0f / 203.0f;
	}

	const float gamma = to_gamma(extended_sdr_scaled);

	if (tc == AVIF_TRANSFER_CHARACTERISTICS_SMPTE428 && linear > 0.9f) {
	continue; // Smpte428 is a bit below the y=x diagonal at the high end.
	}

	// Check the point is above (or at) the y=x diagonal, with some tolerance.
	ASSERT_GE(gamma, linear - 1e-6f);
	}
	}
	}

	} // namespace
	} // namespace avif