77a7a1b57c
Reland from: https://skia-review.googlesource.com/c/8021/ BUG=skia: Change-Id: I18985f130587b15fccbc86b76b2bb5c49ba5ba8a Reviewed-on: https://skia-review.googlesource.com/8136 Reviewed-by: Matt Sarett <msarett@google.com> Commit-Queue: Matt Sarett <msarett@google.com>
340 lines
14 KiB
C++
340 lines
14 KiB
C++
/*
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* Copyright 2016 Google Inc.
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*
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* Use of this source code is governed by a BSD-style license that can be
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* found in the LICENSE file.
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*/
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#include "Resources.h"
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#include "SkCodec.h"
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#include "SkCodecPriv.h"
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#include "SkColorPriv.h"
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#include "SkColorSpace.h"
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#include "SkColorSpace_A2B.h"
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#include "SkColorSpace_Base.h"
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#include "SkColorSpace_XYZ.h"
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#include "SkColorSpaceXform_Base.h"
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#include "Test.h"
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static constexpr int kChannels = 3;
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class ColorSpaceXformTest {
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public:
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static std::unique_ptr<SkColorSpaceXform> CreateIdentityXform(const sk_sp<SkGammas>& gammas) {
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// Logically we can pass any matrix here. For simplicty, pass I(), i.e. D50 XYZ gamut.
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sk_sp<SkColorSpace> space(new SkColorSpace_XYZ(
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kNonStandard_SkGammaNamed, gammas, SkMatrix::I(), nullptr));
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// Use special testing entry point, so we don't skip the xform, even though src == dst.
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return SlowIdentityXform(static_cast<SkColorSpace_XYZ*>(space.get()));
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}
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static std::unique_ptr<SkColorSpaceXform> CreateIdentityXform_A2B(
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SkGammaNamed gammaNamed, const sk_sp<SkGammas>& gammas) {
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std::vector<SkColorSpace_A2B::Element> srcElements;
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// sRGB
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const float values[16] = {
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0.4358f, 0.3853f, 0.1430f, 0.0f,
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0.2224f, 0.7170f, 0.0606f, 0.0f,
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0.0139f, 0.0971f, 0.7139f, 0.0f,
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0.0000f, 0.0000f, 0.0000f, 1.0f
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};
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SkMatrix44 arbitraryMatrix{SkMatrix44::kUninitialized_Constructor};
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arbitraryMatrix.setRowMajorf(values);
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if (kNonStandard_SkGammaNamed == gammaNamed) {
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SkASSERT(gammas);
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srcElements.push_back(SkColorSpace_A2B::Element(gammas));
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} else {
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srcElements.push_back(SkColorSpace_A2B::Element(gammaNamed, kChannels));
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}
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srcElements.push_back(SkColorSpace_A2B::Element(arbitraryMatrix));
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auto srcSpace =
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ColorSpaceXformTest::CreateA2BSpace(SkColorSpace_A2B::PCS::kXYZ,
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SkColorSpace_Base::kRGB_ICCTypeFlag,
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std::move(srcElements));
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sk_sp<SkColorSpace> dstSpace(new SkColorSpace_XYZ(gammaNamed, gammas, arbitraryMatrix,
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nullptr));
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return SkColorSpaceXform::New(static_cast<SkColorSpace_A2B*>(srcSpace.get()),
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static_cast<SkColorSpace_XYZ*>(dstSpace.get()));
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}
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static sk_sp<SkColorSpace> CreateA2BSpace(SkColorSpace_A2B::PCS pcs,
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SkColorSpace_Base::ICCTypeFlag iccType,
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std::vector<SkColorSpace_A2B::Element> elements) {
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return sk_sp<SkColorSpace>(new SkColorSpace_A2B(iccType, std::move(elements),
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pcs, nullptr));
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}
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};
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static bool almost_equal(int x, int y) {
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return SkTAbs(x - y) <= 1;
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}
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static void test_identity_xform(skiatest::Reporter* r, const sk_sp<SkGammas>& gammas,
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bool repeat) {
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// Arbitrary set of 10 pixels
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constexpr int width = 10;
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constexpr uint32_t srcPixels[width] = {
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0xFFABCDEF, 0xFF146829, 0xFF382759, 0xFF184968, 0xFFDE8271,
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0xFF32AB52, 0xFF0383BC, 0xFF000102, 0xFFFFFFFF, 0xFFDDEEFF, };
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uint32_t dstPixels[width];
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// Create and perform an identity xform.
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std::unique_ptr<SkColorSpaceXform> xform = ColorSpaceXformTest::CreateIdentityXform(gammas);
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bool result = xform->apply(select_xform_format(kN32_SkColorType), dstPixels,
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SkColorSpaceXform::kBGRA_8888_ColorFormat, srcPixels, width,
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kOpaque_SkAlphaType);
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REPORTER_ASSERT(r, result);
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// Since the src->dst matrix is the identity, and the gamma curves match,
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// the pixels should be unchanged.
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for (int i = 0; i < width; i++) {
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 0) & 0xFF),
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SkGetPackedB32(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 8) & 0xFF),
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SkGetPackedG32(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 16) & 0xFF),
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SkGetPackedR32(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 24) & 0xFF),
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SkGetPackedA32(dstPixels[i])));
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}
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if (repeat) {
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// We should cache part of the transform after the run. So it is interesting
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// to make sure it still runs correctly the second time.
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test_identity_xform(r, gammas, false);
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}
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}
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static void test_identity_xform_A2B(skiatest::Reporter* r, SkGammaNamed gammaNamed,
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const sk_sp<SkGammas>& gammas) {
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// Arbitrary set of 10 pixels
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constexpr int width = 10;
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constexpr uint32_t srcPixels[width] = {
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0xFFABCDEF, 0xFF146829, 0xFF382759, 0xFF184968, 0xFFDE8271,
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0xFF32AB52, 0xFF0383BC, 0xFF000102, 0xFFFFFFFF, 0xFFDDEEFF, };
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uint32_t dstPixels[width];
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// Create and perform an identity xform.
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auto xform = ColorSpaceXformTest::CreateIdentityXform_A2B(gammaNamed, gammas);
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bool result = xform->apply(select_xform_format(kN32_SkColorType), dstPixels,
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SkColorSpaceXform::kBGRA_8888_ColorFormat, srcPixels, width,
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kOpaque_SkAlphaType);
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REPORTER_ASSERT(r, result);
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// Since the src->dst matrix is the identity, and the gamma curves match,
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// the pixels should be unchanged.
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for (int i = 0; i < width; i++) {
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 0) & 0xFF),
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SkGetPackedB32(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 8) & 0xFF),
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SkGetPackedG32(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 16) & 0xFF),
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SkGetPackedR32(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(((srcPixels[i] >> 24) & 0xFF),
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SkGetPackedA32(dstPixels[i])));
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}
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}
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DEF_TEST(ColorSpaceXform_TableGamma, r) {
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// Lookup-table based gamma curves
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constexpr size_t tableSize = 10;
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void* memory = sk_malloc_throw(sizeof(SkGammas) + sizeof(float) * tableSize);
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sk_sp<SkGammas> gammas = sk_sp<SkGammas>(new (memory) SkGammas(kChannels));
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for (int i = 0; i < kChannels; ++i) {
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gammas->fType[i] = SkGammas::Type::kTable_Type;
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gammas->fData[i].fTable.fSize = tableSize;
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gammas->fData[i].fTable.fOffset = 0;
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}
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float* table = SkTAddOffset<float>(memory, sizeof(SkGammas));
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table[0] = 0.00f;
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table[1] = 0.05f;
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table[2] = 0.10f;
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table[3] = 0.15f;
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table[4] = 0.25f;
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table[5] = 0.35f;
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table[6] = 0.45f;
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table[7] = 0.60f;
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table[8] = 0.75f;
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table[9] = 1.00f;
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test_identity_xform(r, gammas, true);
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test_identity_xform_A2B(r, kNonStandard_SkGammaNamed, gammas);
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}
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DEF_TEST(ColorSpaceXform_ParametricGamma, r) {
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// Parametric gamma curves
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void* memory = sk_malloc_throw(sizeof(SkGammas) + sizeof(SkColorSpaceTransferFn));
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sk_sp<SkGammas> gammas = sk_sp<SkGammas>(new (memory) SkGammas(kChannels));
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for (int i = 0; i < kChannels; ++i) {
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gammas->fType[i] = SkGammas::Type::kParam_Type;
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gammas->fData[i].fParamOffset = 0;
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}
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SkColorSpaceTransferFn* params = SkTAddOffset<SkColorSpaceTransferFn>
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(memory, sizeof(SkGammas));
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// Interval.
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params->fD = 0.04045f;
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// First equation:
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params->fC = 1.0f / 12.92f;
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params->fF = 0.0f;
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// Second equation:
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// Note that the function is continuous (it's actually sRGB).
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params->fA = 1.0f / 1.055f;
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params->fB = 0.055f / 1.055f;
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params->fE = 0.0f;
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params->fG = 2.4f;
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test_identity_xform(r, gammas, true);
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test_identity_xform_A2B(r, kNonStandard_SkGammaNamed, gammas);
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}
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DEF_TEST(ColorSpaceXform_ExponentialGamma, r) {
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// Exponential gamma curves
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sk_sp<SkGammas> gammas = sk_sp<SkGammas>(new SkGammas(kChannels));
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for (int i = 0; i < kChannels; ++i) {
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gammas->fType[i] = SkGammas::Type::kValue_Type;
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gammas->fData[i].fValue = 1.4f;
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}
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test_identity_xform(r, gammas, true);
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test_identity_xform_A2B(r, kNonStandard_SkGammaNamed, gammas);
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}
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DEF_TEST(ColorSpaceXform_NamedGamma, r) {
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sk_sp<SkGammas> gammas = sk_sp<SkGammas>(new SkGammas(kChannels));
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gammas->fType[0] = gammas->fType[1] = gammas->fType[2] = SkGammas::Type::kNamed_Type;
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gammas->fData[0].fNamed = kSRGB_SkGammaNamed;
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gammas->fData[1].fNamed = k2Dot2Curve_SkGammaNamed;
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gammas->fData[2].fNamed = kLinear_SkGammaNamed;
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test_identity_xform(r, gammas, true);
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test_identity_xform_A2B(r, kNonStandard_SkGammaNamed, gammas);
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test_identity_xform_A2B(r, kSRGB_SkGammaNamed, nullptr);
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test_identity_xform_A2B(r, k2Dot2Curve_SkGammaNamed, nullptr);
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test_identity_xform_A2B(r, kLinear_SkGammaNamed, nullptr);
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}
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DEF_TEST(ColorSpaceXform_NonMatchingGamma, r) {
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constexpr size_t tableSize = 10;
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void* memory = sk_malloc_throw(sizeof(SkGammas) + sizeof(float) * tableSize +
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sizeof(SkColorSpaceTransferFn));
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sk_sp<SkGammas> gammas = sk_sp<SkGammas>(new (memory) SkGammas(kChannels));
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float* table = SkTAddOffset<float>(memory, sizeof(SkGammas));
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table[0] = 0.00f;
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table[1] = 0.15f;
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table[2] = 0.20f;
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table[3] = 0.25f;
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table[4] = 0.35f;
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table[5] = 0.45f;
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table[6] = 0.55f;
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table[7] = 0.70f;
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table[8] = 0.85f;
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table[9] = 1.00f;
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SkColorSpaceTransferFn* params = SkTAddOffset<SkColorSpaceTransferFn>(memory,
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sizeof(SkGammas) + sizeof(float) * tableSize);
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params->fA = 1.0f / 1.055f;
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params->fB = 0.055f / 1.055f;
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params->fC = 1.0f / 12.92f;
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params->fD = 0.04045f;
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params->fE = 0.0f;
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params->fF = 0.0f;
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params->fG = 2.4f;
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gammas->fType[0] = SkGammas::Type::kValue_Type;
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gammas->fData[0].fValue = 1.2f;
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gammas->fType[1] = SkGammas::Type::kTable_Type;
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gammas->fData[1].fTable.fSize = tableSize;
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gammas->fData[1].fTable.fOffset = 0;
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gammas->fType[2] = SkGammas::Type::kParam_Type;
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gammas->fData[2].fParamOffset = sizeof(float) * tableSize;
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test_identity_xform(r, gammas, true);
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test_identity_xform_A2B(r, kNonStandard_SkGammaNamed, gammas);
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}
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DEF_TEST(ColorSpaceXform_A2BCLUT, r) {
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constexpr int inputChannels = 3;
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constexpr int gp = 4; // # grid points
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constexpr int numEntries = gp*gp*gp*3;
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const uint8_t gridPoints[3] = {gp, gp, gp};
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void* memory = sk_malloc_throw(sizeof(SkColorLookUpTable) + sizeof(float) * numEntries);
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sk_sp<SkColorLookUpTable> colorLUT(new (memory) SkColorLookUpTable(inputChannels, gridPoints));
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// make a CLUT that rotates R, G, and B ie R->G, G->B, B->R
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float* table = SkTAddOffset<float>(memory, sizeof(SkColorLookUpTable));
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for (int r = 0; r < gp; ++r) {
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for (int g = 0; g < gp; ++g) {
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for (int b = 0; b < gp; ++b) {
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table[3*(gp*gp*r + gp*g + b) + 0] = g * (1.f / (gp - 1.f));
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table[3*(gp*gp*r + gp*g + b) + 1] = b * (1.f / (gp - 1.f));
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table[3*(gp*gp*r + gp*g + b) + 2] = r * (1.f / (gp - 1.f));
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}
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}
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}
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// build an even distribution of pixels every (7 / 255) steps
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// to test the xform on
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constexpr int pixelgp = 7;
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constexpr int numPixels = pixelgp*pixelgp*pixelgp;
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SkAutoTMalloc<uint32_t> srcPixels(numPixels);
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int srcIndex = 0;
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for (int r = 0; r < pixelgp; ++r) {
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for (int g = 0; g < pixelgp; ++g) {
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for (int b = 0; b < pixelgp; ++b) {
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const int red = (int) (r * (255.f / (pixelgp - 1.f)));
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const int green = (int) (g * (255.f / (pixelgp - 1.f)));
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const int blue = (int) (b * (255.f / (pixelgp - 1.f)));
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srcPixels[srcIndex] = SkColorSetRGB(red, green, blue);
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++srcIndex;
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}
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}
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}
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SkAutoTMalloc<uint32_t> dstPixels(numPixels);
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// src space is identity besides CLUT
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std::vector<SkColorSpace_A2B::Element> srcElements;
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srcElements.push_back(SkColorSpace_A2B::Element(std::move(colorLUT)));
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auto srcSpace = ColorSpaceXformTest::CreateA2BSpace(SkColorSpace_A2B::PCS::kXYZ,
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SkColorSpace_Base::kRGB_ICCTypeFlag,
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std::move(srcElements));
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// dst space is entirely identity
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auto dstSpace = SkColorSpace::MakeRGB(SkColorSpace::kLinear_RenderTargetGamma, SkMatrix44::I());
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auto xform = SkColorSpaceXform::New(srcSpace.get(), dstSpace.get());
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bool result = xform->apply(SkColorSpaceXform::kRGBA_8888_ColorFormat, dstPixels.get(),
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SkColorSpaceXform::kRGBA_8888_ColorFormat, srcPixels.get(),
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numPixels, kOpaque_SkAlphaType);
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REPORTER_ASSERT(r, result);
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for (int i = 0; i < numPixels; ++i) {
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REPORTER_ASSERT(r, almost_equal(SkColorGetR(srcPixels[i]),
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SkColorGetG(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(SkColorGetG(srcPixels[i]),
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SkColorGetB(dstPixels[i])));
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REPORTER_ASSERT(r, almost_equal(SkColorGetB(srcPixels[i]),
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SkColorGetR(dstPixels[i])));
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}
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}
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DEF_TEST(SkColorSpaceXform_LoadTail, r) {
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std::unique_ptr<uint64_t[]> srcPixel(new uint64_t[1]);
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srcPixel[0] = 0;
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uint32_t dstPixel;
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sk_sp<SkColorSpace> adobe = SkColorSpace_Base::MakeNamed(SkColorSpace_Base::kAdobeRGB_Named);
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sk_sp<SkColorSpace> srgb = SkColorSpace::MakeSRGB();
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std::unique_ptr<SkColorSpaceXform> xform = SkColorSpaceXform::New(adobe.get(), srgb.get());
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// ASAN will catch us if we read past the tail.
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bool success = xform->apply(SkColorSpaceXform::kRGBA_8888_ColorFormat, &dstPixel,
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SkColorSpaceXform::kRGBA_U16_BE_ColorFormat, srcPixel.get(), 1,
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kUnpremul_SkAlphaType);
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REPORTER_ASSERT(r, success);
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}
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