src/core/SkColorSpace.cpp - skia - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkColorSpace.h"
 #include "include/core/SkData.h"
 #include "include/third_party/skcms/skcms.h"
 #include "src/core/SkColorSpacePriv.h"
 #include "src/core/SkOpts.h"

 bool SkColorSpacePrimaries::toXYZD50(skcms_Matrix3x3* toXYZ_D50) const {
     return skcms_PrimariesToXYZD50(fRX, fRY, fGX, fGY, fBX, fBY, fWX, fWY, toXYZ_D50);
 }

 SkColorSpace::SkColorSpace(const skcms_TransferFunction& transferFn,
                            const skcms_Matrix3x3& toXYZD50)
         : fTransferFn(transferFn)
         , fToXYZD50(toXYZD50) {
     fTransferFnHash = SkOpts::hash_fn(&fTransferFn, 7*sizeof(float), 0);
     fToXYZD50Hash = SkOpts::hash_fn(&fToXYZD50, 9*sizeof(float), 0);
 }

 static bool xyz_almost_equal(const skcms_Matrix3x3& mA, const skcms_Matrix3x3& mB) {
     for (int r = 0; r < 3; ++r) {
         for (int c = 0; c < 3; ++c) {
             if (!color_space_almost_equal(mA.vals[r][c], mB.vals[r][c])) {
                 return false;
             }
         }
     }

     return true;
 }

 sk_sp<SkColorSpace> SkColorSpace::MakeRGB(const skcms_TransferFunction& transferFn,
                                           const skcms_Matrix3x3& toXYZ) {
     if (classify_transfer_fn(transferFn) == Bad_TF) {
         return nullptr;
     }

     const skcms_TransferFunction* tf = &transferFn;

     if (is_almost_srgb(transferFn)) {
         if (xyz_almost_equal(toXYZ, SkNamedGamut::kSRGB)) {
             return SkColorSpace::MakeSRGB();
         }
         tf = &SkNamedTransferFn::kSRGB;
     } else if (is_almost_2dot2(transferFn)) {
         tf = &SkNamedTransferFn::k2Dot2;
     } else if (is_almost_linear(transferFn)) {
         if (xyz_almost_equal(toXYZ, SkNamedGamut::kSRGB)) {
             return SkColorSpace::MakeSRGBLinear();
         }
         tf = &SkNamedTransferFn::kLinear;
     }

     return sk_sp<SkColorSpace>(new SkColorSpace(*tf, toXYZ));
 }

 class SkColorSpaceSingletonFactory {
 public:
     static SkColorSpace* Make(const skcms_TransferFunction& transferFn,
                               const skcms_Matrix3x3& to_xyz) {
         return new SkColorSpace(transferFn, to_xyz);
     }
 };

 SkColorSpace* sk_srgb_singleton() {
     static SkColorSpace* cs = SkColorSpaceSingletonFactory::Make(SkNamedTransferFn::kSRGB,
                                                                  SkNamedGamut::kSRGB);
     return cs;
 }

 SkColorSpace* sk_srgb_linear_singleton() {
     static SkColorSpace* cs = SkColorSpaceSingletonFactory::Make(SkNamedTransferFn::kLinear,
                                                                  SkNamedGamut::kSRGB);
     return cs;
 }

 sk_sp<SkColorSpace> SkColorSpace::MakeSRGB() {
     return sk_ref_sp(sk_srgb_singleton());
 }

 sk_sp<SkColorSpace> SkColorSpace::MakeSRGBLinear() {
     return sk_ref_sp(sk_srgb_linear_singleton());
 }

 void SkColorSpace::computeLazyDstFields() const {
     fLazyDstFieldsOnce([this] {

         // Invert 3x3 gamut, defaulting to sRGB if we can't.
         {
             if (!skcms_Matrix3x3_invert(&fToXYZD50, &fFromXYZD50)) {
                 SkAssertResult(skcms_Matrix3x3_invert(&skcms_sRGB_profile()->toXYZD50,
                                                       &fFromXYZD50));
             }
         }

         // Invert transfer function, defaulting to sRGB if we can't.
         {
             if (!skcms_TransferFunction_invert(&fTransferFn, &fInvTransferFn)) {
                 fInvTransferFn = *skcms_sRGB_Inverse_TransferFunction();
             }
         }

     });
 }

 bool SkColorSpace::isNumericalTransferFn(skcms_TransferFunction* coeffs) const {
     // TODO: Change transferFn/invTransferFn to just operate on skcms_TransferFunction (all callers
     // already pass pointers to an skcms struct). Then remove this function, and update the two
     // remaining callers to do the right thing with transferFn and classify.
     this->transferFn(coeffs);
     return classify_transfer_fn(*coeffs) == sRGBish_TF;
 }

 void SkColorSpace::transferFn(float gabcdef[7]) const {
     memcpy(gabcdef, &fTransferFn, 7*sizeof(float));
 }

 void SkColorSpace::transferFn(skcms_TransferFunction* fn) const {
     *fn = fTransferFn;
 }

 void SkColorSpace::invTransferFn(skcms_TransferFunction* fn) const {
     this->computeLazyDstFields();
     *fn = fInvTransferFn;
 }

 bool SkColorSpace::toXYZD50(skcms_Matrix3x3* toXYZD50) const {
     *toXYZD50 = fToXYZD50;
     return true;
 }

 void SkColorSpace::gamutTransformTo(const SkColorSpace* dst, skcms_Matrix3x3* src_to_dst) const {
     dst->computeLazyDstFields();
     *src_to_dst = skcms_Matrix3x3_concat(&dst->fFromXYZD50, &fToXYZD50);
 }

 bool SkColorSpace::isSRGB() const {
     return sk_srgb_singleton() == this;
 }

 bool SkColorSpace::gammaCloseToSRGB() const {
     // Nearly-equal transfer functions were snapped at construction time, so just do an exact test
     return memcmp(&fTransferFn, &SkNamedTransferFn::kSRGB, 7*sizeof(float)) == 0;
 }

 bool SkColorSpace::gammaIsLinear() const {
     // Nearly-equal transfer functions were snapped at construction time, so just do an exact test
     return memcmp(&fTransferFn, &SkNamedTransferFn::kLinear, 7*sizeof(float)) == 0;
 }

 sk_sp<SkColorSpace> SkColorSpace::makeLinearGamma() const {
     if (this->gammaIsLinear()) {
         return sk_ref_sp(const_cast<SkColorSpace*>(this));
     }
     return SkColorSpace::MakeRGB(SkNamedTransferFn::kLinear, fToXYZD50);
 }

 sk_sp<SkColorSpace> SkColorSpace::makeSRGBGamma() const {
     if (this->gammaCloseToSRGB()) {
         return sk_ref_sp(const_cast<SkColorSpace*>(this));
     }
     return SkColorSpace::MakeRGB(SkNamedTransferFn::kSRGB, fToXYZD50);
 }

 sk_sp<SkColorSpace> SkColorSpace::makeColorSpin() const {
     skcms_Matrix3x3 spin = {{
         { 0, 0, 1 },
         { 1, 0, 0 },
         { 0, 1, 0 },
     }};

     skcms_Matrix3x3 spun = skcms_Matrix3x3_concat(&fToXYZD50, &spin);

     return sk_sp<SkColorSpace>(new SkColorSpace(fTransferFn, spun));
 }

 void SkColorSpace::toProfile(skcms_ICCProfile* profile) const {
     skcms_Init               (profile);
     skcms_SetTransferFunction(profile, &fTransferFn);
     skcms_SetXYZD50          (profile, &fToXYZD50);
 }

 sk_sp<SkColorSpace> SkColorSpace::Make(const skcms_ICCProfile& profile) {
     // TODO: move below ≈sRGB test?
     if (!profile.has_toXYZD50 || !profile.has_trc) {
         return nullptr;
     }

     if (skcms_ApproximatelyEqualProfiles(&profile, skcms_sRGB_profile())) {
         return SkColorSpace::MakeSRGB();
     }

     // TODO: can we save this work and skip lazily inverting the matrix later?
     skcms_Matrix3x3 inv;
     if (!skcms_Matrix3x3_invert(&profile.toXYZD50, &inv)) {
         return nullptr;
     }

     // We can't work with tables or mismatched parametric curves,
     // but if they all look close enough to sRGB, that's fine.
     // TODO: should we maybe do this unconditionally to snap near-sRGB parametrics to sRGB?
     const skcms_Curve* trc = profile.trc;
     if (trc[0].table_entries != 0 ||
         trc[1].table_entries != 0 ||
         trc[2].table_entries != 0 ||
         0 != memcmp(&trc[0].parametric, &trc[1].parametric, sizeof(trc[0].parametric)) ||
         0 != memcmp(&trc[0].parametric, &trc[2].parametric, sizeof(trc[0].parametric)))
     {
         if (skcms_TRCs_AreApproximateInverse(&profile, skcms_sRGB_Inverse_TransferFunction())) {
             return SkColorSpace::MakeRGB(SkNamedTransferFn::kSRGB, profile.toXYZD50);
         }
         return nullptr;
     }

     return SkColorSpace::MakeRGB(profile.trc[0].parametric, profile.toXYZD50);
 }

 ///////////////////////////////////////////////////////////////////////////////////////////////////

 enum Version {
     k0_Version, // Initial version, header + flags for matrix and profile
     k1_Version, // Simple header (version tag) + 16 floats

     kCurrent_Version = k1_Version,
 };

 enum NamedColorSpace {
     kSRGB_NamedColorSpace,
     kAdobeRGB_NamedColorSpace,
     kSRGBLinear_NamedColorSpace,
 };

 enum NamedGamma {
     kLinear_NamedGamma,
     kSRGB_NamedGamma,
     k2Dot2_NamedGamma,
 };

 struct ColorSpaceHeader {
     // Flag values, only used by old (k0_Version) serialization
     static constexpr uint8_t kMatrix_Flag     = 1 << 0;
     static constexpr uint8_t kICC_Flag        = 1 << 1;
     static constexpr uint8_t kTransferFn_Flag = 1 << 3;

     uint8_t fVersion = kCurrent_Version;

     // Other fields are only used by k0_Version. Could be re-purposed in future versions.
     uint8_t fNamed      = 0;
     uint8_t fGammaNamed = 0;
     uint8_t fFlags      = 0;
 };

 size_t SkColorSpace::writeToMemory(void* memory) const {
     if (memory) {
         *((ColorSpaceHeader*) memory) = ColorSpaceHeader();
         memory = SkTAddOffset<void>(memory, sizeof(ColorSpaceHeader));

         memcpy(memory, &fTransferFn, 7 * sizeof(float));
         memory = SkTAddOffset<void>(memory, 7 * sizeof(float));

         memcpy(memory, &fToXYZD50, 9 * sizeof(float));
     }

     return sizeof(ColorSpaceHeader) + 16 * sizeof(float);
 }

 sk_sp<SkData> SkColorSpace::serialize() const {
     sk_sp<SkData> data = SkData::MakeUninitialized(this->writeToMemory(nullptr));
     this->writeToMemory(data->writable_data());
     return data;
 }

 sk_sp<SkColorSpace> SkColorSpace::Deserialize(const void* data, size_t length) {
     if (length < sizeof(ColorSpaceHeader)) {
         return nullptr;
     }

     ColorSpaceHeader header = *((const ColorSpaceHeader*) data);
     data = SkTAddOffset<const void>(data, sizeof(ColorSpaceHeader));
     length -= sizeof(ColorSpaceHeader);
     if (k1_Version == header.fVersion) {
         if (length < 16 * sizeof(float)) {
             return nullptr;
         }

         skcms_TransferFunction transferFn;
         memcpy(&transferFn, data, 7 * sizeof(float));
         data = SkTAddOffset<const void>(data, 7 * sizeof(float));

         skcms_Matrix3x3 toXYZ;
         memcpy(&toXYZ, data, 9 * sizeof(float));
         return SkColorSpace::MakeRGB(transferFn, toXYZ);
     } else if (k0_Version == header.fVersion) {
         if (0 == header.fFlags) {
             switch ((NamedColorSpace)header.fNamed) {
                 case kSRGB_NamedColorSpace:
                     return SkColorSpace::MakeSRGB();
                 case kSRGBLinear_NamedColorSpace:
                     return SkColorSpace::MakeSRGBLinear();
                 case kAdobeRGB_NamedColorSpace:
                     return SkColorSpace::MakeRGB(SkNamedTransferFn::k2Dot2,
                                                  SkNamedGamut::kAdobeRGB);
             }
         }

         auto make_named_tf = [=](const skcms_TransferFunction& tf) {
             if (ColorSpaceHeader::kMatrix_Flag != header.fFlags || length < 12 * sizeof(float)) {
                 return sk_sp<SkColorSpace>(nullptr);
             }

             // Version 0 matrix is row-major 3x4
             skcms_Matrix3x3 toXYZ;
             memcpy(&toXYZ.vals[0][0], (const float*)data + 0, 3 * sizeof(float));
             memcpy(&toXYZ.vals[1][0], (const float*)data + 4, 3 * sizeof(float));
             memcpy(&toXYZ.vals[2][0], (const float*)data + 8, 3 * sizeof(float));
             return SkColorSpace::MakeRGB(tf, toXYZ);
         };

         switch ((NamedGamma) header.fGammaNamed) {
             case kSRGB_NamedGamma:
                 return make_named_tf(SkNamedTransferFn::kSRGB);
             case k2Dot2_NamedGamma:
                 return make_named_tf(SkNamedTransferFn::k2Dot2);
             case kLinear_NamedGamma:
                 return make_named_tf(SkNamedTransferFn::kLinear);
             default:
                 break;
         }

         switch (header.fFlags) {
             case ColorSpaceHeader::kICC_Flag: {
                 // Deprecated and unsupported code path
                 return nullptr;
             }
             case ColorSpaceHeader::kTransferFn_Flag: {
                 if (length < 19 * sizeof(float)) {
                     return nullptr;
                 }

                 // Version 0 TF is in abcdefg order
                 skcms_TransferFunction transferFn;
                 transferFn.a = *(((const float*) data) + 0);
                 transferFn.b = *(((const float*) data) + 1);
                 transferFn.c = *(((const float*) data) + 2);
                 transferFn.d = *(((const float*) data) + 3);
                 transferFn.e = *(((const float*) data) + 4);
                 transferFn.f = *(((const float*) data) + 5);
                 transferFn.g = *(((const float*) data) + 6);
                 data = SkTAddOffset<const void>(data, 7 * sizeof(float));

                 // Version 0 matrix is row-major 3x4
                 skcms_Matrix3x3 toXYZ;
                 memcpy(&toXYZ.vals[0][0], (const float*)data + 0, 3 * sizeof(float));
                 memcpy(&toXYZ.vals[1][0], (const float*)data + 4, 3 * sizeof(float));
                 memcpy(&toXYZ.vals[2][0], (const float*)data + 8, 3 * sizeof(float));
                 return SkColorSpace::MakeRGB(transferFn, toXYZ);
             }
             default:
                 return nullptr;
         }
     } else {
         return nullptr;
     }
 }

 bool SkColorSpace::Equals(const SkColorSpace* x, const SkColorSpace* y) {
     if (x == y) {
         return true;
     }

     if (!x || !y) {
         return false;
     }

     if (x->hash() == y->hash()) {
         for (int i = 0; i < 7; i++) {
             SkASSERT((&x->fTransferFn.g)[i] == (&y->fTransferFn.g)[i] && "Hash collsion");
         }
         for (int r = 0; r < 3; r++) {
             for (int c = 0; c < 3; ++c) {
                 SkASSERT(x->fToXYZD50.vals[r][c] == y->fToXYZD50.vals[r][c] && "Hash collsion");
             }
         }
         return true;
     }
     return false;
 }
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkColorSpace.h"
	#include "include/core/SkData.h"
	#include "include/third_party/skcms/skcms.h"
	#include "src/core/SkColorSpacePriv.h"
	#include "src/core/SkOpts.h"

	bool SkColorSpacePrimaries::toXYZD50(skcms_Matrix3x3* toXYZ_D50) const {
	return skcms_PrimariesToXYZD50(fRX, fRY, fGX, fGY, fBX, fBY, fWX, fWY, toXYZ_D50);
	}

	SkColorSpace::SkColorSpace(const skcms_TransferFunction& transferFn,
	const skcms_Matrix3x3& toXYZD50)
	: fTransferFn(transferFn)
	, fToXYZD50(toXYZD50) {
	fTransferFnHash = SkOpts::hash_fn(&fTransferFn, 7*sizeof(float), 0);
	fToXYZD50Hash = SkOpts::hash_fn(&fToXYZD50, 9*sizeof(float), 0);
	}

	static bool xyz_almost_equal(const skcms_Matrix3x3& mA, const skcms_Matrix3x3& mB) {
	for (int r = 0; r < 3; ++r) {
	for (int c = 0; c < 3; ++c) {
	if (!color_space_almost_equal(mA.vals[r][c], mB.vals[r][c])) {
	return false;
	}
	}
	}

	return true;
	}

	sk_sp<SkColorSpace> SkColorSpace::MakeRGB(const skcms_TransferFunction& transferFn,
	const skcms_Matrix3x3& toXYZ) {
	if (classify_transfer_fn(transferFn) == Bad_TF) {
	return nullptr;
	}

	const skcms_TransferFunction* tf = &transferFn;

	if (is_almost_srgb(transferFn)) {
	if (xyz_almost_equal(toXYZ, SkNamedGamut::kSRGB)) {
	return SkColorSpace::MakeSRGB();
	}
	tf = &SkNamedTransferFn::kSRGB;
	} else if (is_almost_2dot2(transferFn)) {
	tf = &SkNamedTransferFn::k2Dot2;
	} else if (is_almost_linear(transferFn)) {
	if (xyz_almost_equal(toXYZ, SkNamedGamut::kSRGB)) {
	return SkColorSpace::MakeSRGBLinear();
	}
	tf = &SkNamedTransferFn::kLinear;
	}

	return sk_sp<SkColorSpace>(new SkColorSpace(*tf, toXYZ));
	}

	class SkColorSpaceSingletonFactory {
	public:
	static SkColorSpace* Make(const skcms_TransferFunction& transferFn,
	const skcms_Matrix3x3& to_xyz) {
	return new SkColorSpace(transferFn, to_xyz);
	}
	};

	SkColorSpace* sk_srgb_singleton() {
	static SkColorSpace* cs = SkColorSpaceSingletonFactory::Make(SkNamedTransferFn::kSRGB,
	SkNamedGamut::kSRGB);
	return cs;
	}

	SkColorSpace* sk_srgb_linear_singleton() {
	static SkColorSpace* cs = SkColorSpaceSingletonFactory::Make(SkNamedTransferFn::kLinear,
	SkNamedGamut::kSRGB);
	return cs;
	}

	sk_sp<SkColorSpace> SkColorSpace::MakeSRGB() {
	return sk_ref_sp(sk_srgb_singleton());
	}

	sk_sp<SkColorSpace> SkColorSpace::MakeSRGBLinear() {
	return sk_ref_sp(sk_srgb_linear_singleton());
	}

	void SkColorSpace::computeLazyDstFields() const {
	fLazyDstFieldsOnce([this] {

	// Invert 3x3 gamut, defaulting to sRGB if we can't.
	{
	if (!skcms_Matrix3x3_invert(&fToXYZD50, &fFromXYZD50)) {
	SkAssertResult(skcms_Matrix3x3_invert(&skcms_sRGB_profile()->toXYZD50,
	&fFromXYZD50));
	}
	}

	// Invert transfer function, defaulting to sRGB if we can't.
	{
	if (!skcms_TransferFunction_invert(&fTransferFn, &fInvTransferFn)) {
	fInvTransferFn = *skcms_sRGB_Inverse_TransferFunction();
	}
	}

	});
	}

	bool SkColorSpace::isNumericalTransferFn(skcms_TransferFunction* coeffs) const {
	// TODO: Change transferFn/invTransferFn to just operate on skcms_TransferFunction (all callers
	// already pass pointers to an skcms struct). Then remove this function, and update the two
	// remaining callers to do the right thing with transferFn and classify.
	this->transferFn(coeffs);
	return classify_transfer_fn(*coeffs) == sRGBish_TF;
	}

	void SkColorSpace::transferFn(float gabcdef[7]) const {
	memcpy(gabcdef, &fTransferFn, 7*sizeof(float));
	}

	void SkColorSpace::transferFn(skcms_TransferFunction* fn) const {
	*fn = fTransferFn;
	}

	void SkColorSpace::invTransferFn(skcms_TransferFunction* fn) const {
	this->computeLazyDstFields();
	*fn = fInvTransferFn;
	}

	bool SkColorSpace::toXYZD50(skcms_Matrix3x3* toXYZD50) const {
	*toXYZD50 = fToXYZD50;
	return true;
	}

	void SkColorSpace::gamutTransformTo(const SkColorSpace* dst, skcms_Matrix3x3* src_to_dst) const {
	dst->computeLazyDstFields();
	*src_to_dst = skcms_Matrix3x3_concat(&dst->fFromXYZD50, &fToXYZD50);
	}

	bool SkColorSpace::isSRGB() const {
	return sk_srgb_singleton() == this;
	}

	bool SkColorSpace::gammaCloseToSRGB() const {
	// Nearly-equal transfer functions were snapped at construction time, so just do an exact test
	return memcmp(&fTransferFn, &SkNamedTransferFn::kSRGB, 7*sizeof(float)) == 0;
	}

	bool SkColorSpace::gammaIsLinear() const {
	// Nearly-equal transfer functions were snapped at construction time, so just do an exact test
	return memcmp(&fTransferFn, &SkNamedTransferFn::kLinear, 7*sizeof(float)) == 0;
	}

	sk_sp<SkColorSpace> SkColorSpace::makeLinearGamma() const {
	if (this->gammaIsLinear()) {
	return sk_ref_sp(const_cast<SkColorSpace*>(this));
	}
	return SkColorSpace::MakeRGB(SkNamedTransferFn::kLinear, fToXYZD50);
	}

	sk_sp<SkColorSpace> SkColorSpace::makeSRGBGamma() const {
	if (this->gammaCloseToSRGB()) {
	return sk_ref_sp(const_cast<SkColorSpace*>(this));
	}
	return SkColorSpace::MakeRGB(SkNamedTransferFn::kSRGB, fToXYZD50);
	}

	sk_sp<SkColorSpace> SkColorSpace::makeColorSpin() const {
	skcms_Matrix3x3 spin = {{
	{ 0, 0, 1 },
	{ 1, 0, 0 },
	{ 0, 1, 0 },
	}};

	skcms_Matrix3x3 spun = skcms_Matrix3x3_concat(&fToXYZD50, &spin);

	return sk_sp<SkColorSpace>(new SkColorSpace(fTransferFn, spun));
	}

	void SkColorSpace::toProfile(skcms_ICCProfile* profile) const {
	skcms_Init (profile);
	skcms_SetTransferFunction(profile, &fTransferFn);
	skcms_SetXYZD50 (profile, &fToXYZD50);
	}

	sk_sp<SkColorSpace> SkColorSpace::Make(const skcms_ICCProfile& profile) {
	// TODO: move below ≈sRGB test?
	if (!profile.has_toXYZD50 \|\| !profile.has_trc) {
	return nullptr;
	}

	if (skcms_ApproximatelyEqualProfiles(&profile, skcms_sRGB_profile())) {
	return SkColorSpace::MakeSRGB();
	}

	// TODO: can we save this work and skip lazily inverting the matrix later?
	skcms_Matrix3x3 inv;
	if (!skcms_Matrix3x3_invert(&profile.toXYZD50, &inv)) {
	return nullptr;
	}

	// We can't work with tables or mismatched parametric curves,
	// but if they all look close enough to sRGB, that's fine.
	// TODO: should we maybe do this unconditionally to snap near-sRGB parametrics to sRGB?
	const skcms_Curve* trc = profile.trc;
	if (trc[0].table_entries != 0 \|\|
	trc[1].table_entries != 0 \|\|
	trc[2].table_entries != 0 \|\|
	0 != memcmp(&trc[0].parametric, &trc[1].parametric, sizeof(trc[0].parametric)) \|\|
	0 != memcmp(&trc[0].parametric, &trc[2].parametric, sizeof(trc[0].parametric)))
	{
	if (skcms_TRCs_AreApproximateInverse(&profile, skcms_sRGB_Inverse_TransferFunction())) {
	return SkColorSpace::MakeRGB(SkNamedTransferFn::kSRGB, profile.toXYZD50);
	}
	return nullptr;
	}

	return SkColorSpace::MakeRGB(profile.trc[0].parametric, profile.toXYZD50);
	}

	///////////////////////////////////////////////////////////////////////////////////////////////////

	enum Version {
	k0_Version, // Initial version, header + flags for matrix and profile
	k1_Version, // Simple header (version tag) + 16 floats

	kCurrent_Version = k1_Version,
	};

	enum NamedColorSpace {
	kSRGB_NamedColorSpace,
	kAdobeRGB_NamedColorSpace,
	kSRGBLinear_NamedColorSpace,
	};

	enum NamedGamma {
	kLinear_NamedGamma,
	kSRGB_NamedGamma,
	k2Dot2_NamedGamma,
	};

	struct ColorSpaceHeader {
	// Flag values, only used by old (k0_Version) serialization
	static constexpr uint8_t kMatrix_Flag = 1 << 0;
	static constexpr uint8_t kICC_Flag = 1 << 1;
	static constexpr uint8_t kTransferFn_Flag = 1 << 3;

	uint8_t fVersion = kCurrent_Version;

	// Other fields are only used by k0_Version. Could be re-purposed in future versions.
	uint8_t fNamed = 0;
	uint8_t fGammaNamed = 0;
	uint8_t fFlags = 0;
	};

	size_t SkColorSpace::writeToMemory(void* memory) const {
	if (memory) {
	((ColorSpaceHeader) memory) = ColorSpaceHeader();
	memory = SkTAddOffset<void>(memory, sizeof(ColorSpaceHeader));

	memcpy(memory, &fTransferFn, 7 * sizeof(float));
	memory = SkTAddOffset<void>(memory, 7 * sizeof(float));

	memcpy(memory, &fToXYZD50, 9 * sizeof(float));
	}

	return sizeof(ColorSpaceHeader) + 16 * sizeof(float);
	}

	sk_sp<SkData> SkColorSpace::serialize() const {
	sk_sp<SkData> data = SkData::MakeUninitialized(this->writeToMemory(nullptr));
	this->writeToMemory(data->writable_data());
	return data;
	}

	sk_sp<SkColorSpace> SkColorSpace::Deserialize(const void* data, size_t length) {
	if (length < sizeof(ColorSpaceHeader)) {
	return nullptr;
	}

	ColorSpaceHeader header = ((const ColorSpaceHeader) data);
	data = SkTAddOffset<const void>(data, sizeof(ColorSpaceHeader));
	length -= sizeof(ColorSpaceHeader);
	if (k1_Version == header.fVersion) {
	if (length < 16 * sizeof(float)) {
	return nullptr;
	}

	skcms_TransferFunction transferFn;
	memcpy(&transferFn, data, 7 * sizeof(float));
	data = SkTAddOffset<const void>(data, 7 * sizeof(float));

	skcms_Matrix3x3 toXYZ;
	memcpy(&toXYZ, data, 9 * sizeof(float));
	return SkColorSpace::MakeRGB(transferFn, toXYZ);
	} else if (k0_Version == header.fVersion) {
	if (0 == header.fFlags) {
	switch ((NamedColorSpace)header.fNamed) {
	case kSRGB_NamedColorSpace:
	return SkColorSpace::MakeSRGB();
	case kSRGBLinear_NamedColorSpace:
	return SkColorSpace::MakeSRGBLinear();
	case kAdobeRGB_NamedColorSpace:
	return SkColorSpace::MakeRGB(SkNamedTransferFn::k2Dot2,
	SkNamedGamut::kAdobeRGB);
	}
	}

	auto make_named_tf = [=](const skcms_TransferFunction& tf) {
	if (ColorSpaceHeader::kMatrix_Flag != header.fFlags \|\| length < 12 * sizeof(float)) {
	return sk_sp<SkColorSpace>(nullptr);
	}

	// Version 0 matrix is row-major 3x4
	skcms_Matrix3x3 toXYZ;
	memcpy(&toXYZ.vals[0][0], (const float)data + 0, 3 sizeof(float));
	memcpy(&toXYZ.vals[1][0], (const float)data + 4, 3 sizeof(float));
	memcpy(&toXYZ.vals[2][0], (const float)data + 8, 3 sizeof(float));
	return SkColorSpace::MakeRGB(tf, toXYZ);
	};

	switch ((NamedGamma) header.fGammaNamed) {
	case kSRGB_NamedGamma:
	return make_named_tf(SkNamedTransferFn::kSRGB);
	case k2Dot2_NamedGamma:
	return make_named_tf(SkNamedTransferFn::k2Dot2);
	case kLinear_NamedGamma:
	return make_named_tf(SkNamedTransferFn::kLinear);
	default:
	break;
	}

	switch (header.fFlags) {
	case ColorSpaceHeader::kICC_Flag: {
	// Deprecated and unsupported code path
	return nullptr;
	}
	case ColorSpaceHeader::kTransferFn_Flag: {
	if (length < 19 * sizeof(float)) {
	return nullptr;
	}

	// Version 0 TF is in abcdefg order
	skcms_TransferFunction transferFn;
	transferFn.a = (((const float) data) + 0);
	transferFn.b = (((const float) data) + 1);
	transferFn.c = (((const float) data) + 2);
	transferFn.d = (((const float) data) + 3);
	transferFn.e = (((const float) data) + 4);
	transferFn.f = (((const float) data) + 5);
	transferFn.g = (((const float) data) + 6);
	data = SkTAddOffset<const void>(data, 7 * sizeof(float));

	// Version 0 matrix is row-major 3x4
	skcms_Matrix3x3 toXYZ;
	memcpy(&toXYZ.vals[0][0], (const float)data + 0, 3 sizeof(float));
	memcpy(&toXYZ.vals[1][0], (const float)data + 4, 3 sizeof(float));
	memcpy(&toXYZ.vals[2][0], (const float)data + 8, 3 sizeof(float));
	return SkColorSpace::MakeRGB(transferFn, toXYZ);
	}
	default:
	return nullptr;
	}
	} else {
	return nullptr;
	}
	}

	bool SkColorSpace::Equals(const SkColorSpace* x, const SkColorSpace* y) {
	if (x == y) {
	return true;
	}

	if (!x \|\| !y) {
	return false;
	}

	if (x->hash() == y->hash()) {
	for (int i = 0; i < 7; i++) {
	SkASSERT((&x->fTransferFn.g)[i] == (&y->fTransferFn.g)[i] && "Hash collsion");
	}
	for (int r = 0; r < 3; r++) {
	for (int c = 0; c < 3; ++c) {
	SkASSERT(x->fToXYZD50.vals[r][c] == y->fToXYZD50.vals[r][c] && "Hash collsion");
	}
	}
	return true;
	}
	return false;
	}