src/core/SkICC.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 "SkAutoMalloc.h"
 #include "SkColorSpacePriv.h"
 #include "SkColorSpaceXformPriv.h"
 #include "SkColorSpace_XYZ.h"
 #include "SkEndian.h"
 #include "SkFixed.h"
 #include "SkICC.h"
 #include "SkICCPriv.h"
 #include "SkMD5.h"
 #include "SkString.h"
 #include "SkUtils.h"

 SkICC::SkICC(sk_sp<SkColorSpace> colorSpace)
     : fColorSpace(std::move(colorSpace))
 {}

 sk_sp<SkICC> SkICC::Make(const void* ptr, size_t len) {
     sk_sp<SkColorSpace> colorSpace = SkColorSpace::MakeICC(ptr, len);
     if (!colorSpace) {
         return nullptr;
     }

     return sk_sp<SkICC>(new SkICC(std::move(colorSpace)));
 }

 bool SkICC::toXYZD50(SkMatrix44* toXYZD50) const {
     return fColorSpace->toXYZD50(toXYZD50);
 }

 bool SkICC::isNumericalTransferFn(SkColorSpaceTransferFn* coeffs) const {
     return fColorSpace->isNumericalTransferFn(coeffs);
 }

 static const int kDefaultTableSize = 512; // Arbitrary

 void fn_to_table(float* tablePtr, const SkColorSpaceTransferFn& fn) {
     // Y = (aX + b)^g + e  for X >= d
     // Y = cX + f          otherwise
     for (int i = 0; i < kDefaultTableSize; i++) {
         float x = ((float) i) / ((float) (kDefaultTableSize - 1));
         if (x >= fn.fD) {
             tablePtr[i] = clamp_0_1(powf(fn.fA * x + fn.fB, fn.fG) + fn.fE);
         } else {
             tablePtr[i] = clamp_0_1(fn.fC * x + fn.fF);
         }
     }
 }

 void copy_to_table(float* tablePtr, const SkGammas* gammas, int index) {
     SkASSERT(gammas->isTable(index));
     const float* ptr = gammas->table(index);
     const size_t bytes = gammas->tableSize(index) * sizeof(float);
     memcpy(tablePtr, ptr, bytes);
 }

 bool SkICC::rawTransferFnData(Tables* tables) const {
     if (!fColorSpace->toXYZD50()) {
         return false;  // Can't even dream of handling A2B here...
     }
     SkColorSpace_XYZ* colorSpace = (SkColorSpace_XYZ*) fColorSpace.get();

     SkColorSpaceTransferFn fn;
     if (this->isNumericalTransferFn(&fn)) {
         tables->fStorage = SkData::MakeUninitialized(kDefaultTableSize * sizeof(float));
         fn_to_table((float*) tables->fStorage->writable_data(), fn);
         tables->fRed.fOffset = tables->fGreen.fOffset = tables->fBlue.fOffset = 0;
         tables->fRed.fCount = tables->fGreen.fCount = tables->fBlue.fCount = kDefaultTableSize;
         return true;
     }

     const SkGammas* gammas = colorSpace->gammas();
     SkASSERT(gammas);
     if (gammas->allChannelsSame()) {
         SkASSERT(gammas->isTable(0));
         tables->fStorage = SkData::MakeUninitialized(gammas->tableSize(0) * sizeof(float));
         copy_to_table((float*) tables->fStorage->writable_data(), gammas, 0);
         tables->fRed.fOffset = tables->fGreen.fOffset = tables->fBlue.fOffset = 0;
         tables->fRed.fCount = tables->fGreen.fCount = tables->fBlue.fCount = gammas->tableSize(0);
         return true;
     }

     // Determine the storage size.
     size_t storageSize = 0;
     for (int i = 0; i < 3; i++) {
         if (gammas->isTable(i)) {
             storageSize += gammas->tableSize(i) * sizeof(float);
         } else {
             storageSize += kDefaultTableSize * sizeof(float);
         }
     }

     // Fill in the tables.
     tables->fStorage = SkData::MakeUninitialized(storageSize);
     float* ptr = (float*) tables->fStorage->writable_data();
     size_t offset = 0;
     Channel rgb[3];
     for (int i = 0; i < 3; i++) {
         if (gammas->isTable(i)) {
             copy_to_table(ptr, gammas, i);
             rgb[i].fOffset = offset;
             rgb[i].fCount = gammas->tableSize(i);
             offset += rgb[i].fCount * sizeof(float);
             ptr += rgb[i].fCount;
             continue;
         }

         if (gammas->isNamed(i)) {
             SkAssertResult(named_to_parametric(&fn, gammas->data(i).fNamed));
         } else if (gammas->isValue(i)) {
             value_to_parametric(&fn, gammas->data(i).fValue);
         } else {
             SkASSERT(gammas->isParametric(i));
             fn = gammas->params(i);
         }

         fn_to_table(ptr, fn);
         rgb[i].fOffset = offset;
         rgb[i].fCount = kDefaultTableSize;
         offset += kDefaultTableSize * sizeof(float);
         ptr += kDefaultTableSize;
     }

     tables->fRed = rgb[0];
     tables->fGreen = rgb[1];
     tables->fBlue = rgb[2];
     return true;
 }

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

 static constexpr char kDescriptionTagBodyPrefix[12] =
         { 'G', 'o', 'o', 'g', 'l', 'e', '/', 'S', 'k', 'i', 'a' , '/'};

 static constexpr size_t kICCDescriptionTagSize = 44;

 static_assert(kICCDescriptionTagSize ==
               sizeof(kDescriptionTagBodyPrefix) + 2 * sizeof(SkMD5::Digest), "");
 static constexpr size_t kDescriptionTagBodySize = kICCDescriptionTagSize * 2;  // ascii->utf16be

 static_assert(SkIsAlign4(kDescriptionTagBodySize), "Description must be aligned to 4-bytes.");
 static constexpr uint32_t kDescriptionTagHeader[7] {
     SkEndian_SwapBE32(kTAG_TextType),                        // Type signature
     0,                                                       // Reserved
     SkEndian_SwapBE32(1),                                    // Number of records
     SkEndian_SwapBE32(12),                                   // Record size (must be 12)
     SkEndian_SwapBE32(SkSetFourByteTag('e', 'n', 'U', 'S')), // English USA
     SkEndian_SwapBE32(kDescriptionTagBodySize),              // Length of string
     SkEndian_SwapBE32(28),                                   // Offset of string
 };

 static constexpr uint32_t kWhitePointTag[5] {
     SkEndian_SwapBE32(kXYZ_PCSSpace),
     0,
     SkEndian_SwapBE32(0x0000f6d6), // X = 0.96420 (D50)
     SkEndian_SwapBE32(0x00010000), // Y = 1.00000 (D50)
     SkEndian_SwapBE32(0x0000d32d), // Z = 0.82491 (D50)
 };

 // Google Inc. 2016 (UTF-16)
 static constexpr uint8_t kCopyrightTagBody[] = {
         0x00, 0x47, 0x00, 0x6f, 0x00, 0x6f, 0x00, 0x67, 0x00, 0x6c, 0x00, 0x65, 0x00, 0x20, 0x00,
         0x49, 0x00, 0x6e, 0x00, 0x63, 0x00, 0x2e, 0x00, 0x20, 0x00, 0x32, 0x00, 0x30, 0x00, 0x31,
         0x00, 0x36,
 };
 static_assert(SkIsAlign4(sizeof(kCopyrightTagBody)), "Copyright must be aligned to 4-bytes.");
 static constexpr uint32_t kCopyrightTagHeader[7] {
     SkEndian_SwapBE32(kTAG_TextType),                        // Type signature
     0,                                                       // Reserved
     SkEndian_SwapBE32(1),                                    // Number of records
     SkEndian_SwapBE32(12),                                   // Record size (must be 12)
     SkEndian_SwapBE32(SkSetFourByteTag('e', 'n', 'U', 'S')), // English USA
     SkEndian_SwapBE32(sizeof(kCopyrightTagBody)),            // Length of string
     SkEndian_SwapBE32(28),                                   // Offset of string
 };

 // We will write a profile with the minimum nine required tags.
 static constexpr uint32_t kICCNumEntries = 9;

 static constexpr uint32_t kTAG_desc = SkSetFourByteTag('d', 'e', 's', 'c');
 static constexpr uint32_t kTAG_desc_Bytes = sizeof(kDescriptionTagHeader) +
                                             kDescriptionTagBodySize;
 static constexpr uint32_t kTAG_desc_Offset = kICCHeaderSize +
                                              kICCNumEntries * kICCTagTableEntrySize;

 static constexpr uint32_t kTAG_XYZ_Bytes = 20;
 static constexpr uint32_t kTAG_rXYZ_Offset = kTAG_desc_Offset + kTAG_desc_Bytes;
 static constexpr uint32_t kTAG_gXYZ_Offset = kTAG_rXYZ_Offset + kTAG_XYZ_Bytes;
 static constexpr uint32_t kTAG_bXYZ_Offset = kTAG_gXYZ_Offset + kTAG_XYZ_Bytes;

 static constexpr uint32_t kTAG_TRC_Bytes = 40;
 static constexpr uint32_t kTAG_rTRC_Offset = kTAG_bXYZ_Offset + kTAG_XYZ_Bytes;
 static constexpr uint32_t kTAG_gTRC_Offset = kTAG_rTRC_Offset;
 static constexpr uint32_t kTAG_bTRC_Offset = kTAG_rTRC_Offset;

 static constexpr uint32_t kTAG_wtpt = SkSetFourByteTag('w', 't', 'p', 't');
 static constexpr uint32_t kTAG_wtpt_Offset = kTAG_bTRC_Offset + kTAG_TRC_Bytes;

 static constexpr uint32_t kTAG_cprt = SkSetFourByteTag('c', 'p', 'r', 't');
 static constexpr uint32_t kTAG_cprt_Bytes = sizeof(kCopyrightTagHeader) +
                                             sizeof(kCopyrightTagBody);
 static constexpr uint32_t kTAG_cprt_Offset = kTAG_wtpt_Offset + kTAG_XYZ_Bytes;

 static constexpr uint32_t kICCProfileSize = kTAG_cprt_Offset + kTAG_cprt_Bytes;

 static constexpr uint32_t kICCHeader[kICCHeaderSize / 4] {
     SkEndian_SwapBE32(kICCProfileSize),  // Size of the profile
     0,                                   // Preferred CMM type (ignored)
     SkEndian_SwapBE32(0x02100000),       // Version 2.1
     SkEndian_SwapBE32(kDisplay_Profile), // Display device profile
     SkEndian_SwapBE32(kRGB_ColorSpace),  // RGB input color space
     SkEndian_SwapBE32(kXYZ_PCSSpace),    // XYZ profile connection space
     0, 0, 0,                             // Date and time (ignored)
     SkEndian_SwapBE32(kACSP_Signature),  // Profile signature
     0,                                   // Platform target (ignored)
     0x00000000,                          // Flags: not embedded, can be used independently
     0,                                   // Device manufacturer (ignored)
     0,                                   // Device model (ignored)
     0, 0,                                // Device attributes (ignored)
     SkEndian_SwapBE32(1),                // Relative colorimetric rendering intent
     SkEndian_SwapBE32(0x0000f6d6),       // D50 standard illuminant (X)
     SkEndian_SwapBE32(0x00010000),       // D50 standard illuminant (Y)
     SkEndian_SwapBE32(0x0000d32d),       // D50 standard illuminant (Z)
     0,                                   // Profile creator (ignored)
     0, 0, 0, 0,                          // Profile id checksum (ignored)
     0, 0, 0, 0, 0, 0, 0,                 // Reserved (ignored)
     SkEndian_SwapBE32(kICCNumEntries),   // Number of tags
 };

 static constexpr uint32_t kICCTagTable[3 * kICCNumEntries] {
     // Profile description
     SkEndian_SwapBE32(kTAG_desc),
     SkEndian_SwapBE32(kTAG_desc_Offset),
     SkEndian_SwapBE32(kTAG_desc_Bytes),

     // rXYZ
     SkEndian_SwapBE32(kTAG_rXYZ),
     SkEndian_SwapBE32(kTAG_rXYZ_Offset),
     SkEndian_SwapBE32(kTAG_XYZ_Bytes),

     // gXYZ
     SkEndian_SwapBE32(kTAG_gXYZ),
     SkEndian_SwapBE32(kTAG_gXYZ_Offset),
     SkEndian_SwapBE32(kTAG_XYZ_Bytes),

     // bXYZ
     SkEndian_SwapBE32(kTAG_bXYZ),
     SkEndian_SwapBE32(kTAG_bXYZ_Offset),
     SkEndian_SwapBE32(kTAG_XYZ_Bytes),

     // rTRC
     SkEndian_SwapBE32(kTAG_rTRC),
     SkEndian_SwapBE32(kTAG_rTRC_Offset),
     SkEndian_SwapBE32(kTAG_TRC_Bytes),

     // gTRC
     SkEndian_SwapBE32(kTAG_gTRC),
     SkEndian_SwapBE32(kTAG_gTRC_Offset),
     SkEndian_SwapBE32(kTAG_TRC_Bytes),

     // bTRC
     SkEndian_SwapBE32(kTAG_bTRC),
     SkEndian_SwapBE32(kTAG_bTRC_Offset),
     SkEndian_SwapBE32(kTAG_TRC_Bytes),

     // White point
     SkEndian_SwapBE32(kTAG_wtpt),
     SkEndian_SwapBE32(kTAG_wtpt_Offset),
     SkEndian_SwapBE32(kTAG_XYZ_Bytes),

     // Copyright
     SkEndian_SwapBE32(kTAG_cprt),
     SkEndian_SwapBE32(kTAG_cprt_Offset),
     SkEndian_SwapBE32(kTAG_cprt_Bytes),
 };

 // This is like SkFloatToFixed, but rounds to nearest, preserving as much accuracy as possible
 // when going float -> fixed -> float (it has the same accuracy when going fixed -> float -> fixed).
 // The use of double is necessary to accomodate the full potential 32-bit mantissa of the 16.16
 // SkFixed value, and so avoiding rounding problems with float. Also, see the comment in SkFixed.h.
 static SkFixed float_round_to_fixed(float x) {
     return sk_float_saturate2int((float)floor((double)x * SK_Fixed1 + 0.5));
 }

 static void write_xyz_tag(uint32_t* ptr, const SkMatrix44& toXYZ, int col) {
     ptr[0] = SkEndian_SwapBE32(kXYZ_PCSSpace);
     ptr[1] = 0;
     ptr[2] = SkEndian_SwapBE32(float_round_to_fixed(toXYZ.getFloat(0, col)));
     ptr[3] = SkEndian_SwapBE32(float_round_to_fixed(toXYZ.getFloat(1, col)));
     ptr[4] = SkEndian_SwapBE32(float_round_to_fixed(toXYZ.getFloat(2, col)));
 }

 static void write_trc_tag(uint32_t* ptr, const SkColorSpaceTransferFn& fn) {
     ptr[0] = SkEndian_SwapBE32(kTAG_ParaCurveType);
     ptr[1] = 0;
     ptr[2] = (uint32_t) (SkEndian_SwapBE16(kGABCDEF_ParaCurveType));
     ptr[3] = SkEndian_SwapBE32(float_round_to_fixed(fn.fG));
     ptr[4] = SkEndian_SwapBE32(float_round_to_fixed(fn.fA));
     ptr[5] = SkEndian_SwapBE32(float_round_to_fixed(fn.fB));
     ptr[6] = SkEndian_SwapBE32(float_round_to_fixed(fn.fC));
     ptr[7] = SkEndian_SwapBE32(float_round_to_fixed(fn.fD));
     ptr[8] = SkEndian_SwapBE32(float_round_to_fixed(fn.fE));
     ptr[9] = SkEndian_SwapBE32(float_round_to_fixed(fn.fF));
 }

 static bool is_3x3(const SkMatrix44& toXYZD50) {
     return 0.0f == toXYZD50.get(3, 0) && 0.0f == toXYZD50.get(3, 1) && 0.0f == toXYZD50.get(3, 2) &&
            0.0f == toXYZD50.get(0, 3) && 0.0f == toXYZD50.get(1, 3) && 0.0f == toXYZD50.get(2, 3) &&
            1.0f == toXYZD50.get(3, 3);
 }

 static bool nearly_equal(float x, float y) {
     // A note on why I chose this tolerance:  transfer_fn_almost_equal() uses a
     // tolerance of 0.001f, which doesn't seem to be enough to distinguish
     // between similar transfer functions, for example: gamma2.2 and sRGB.
     //
     // If the tolerance is 0.0f, then this we can't distinguish between two
     // different encodings of what is clearly the same colorspace.  Some
     // experimentation with example files lead to this number:
     static constexpr float kTolerance = 1.0f / (1 << 11);
     return ::fabsf(x - y) <= kTolerance;
 }

 static bool nearly_equal(const SkColorSpaceTransferFn& u,
                          const SkColorSpaceTransferFn& v) {
     return nearly_equal(u.fG, v.fG)
         && nearly_equal(u.fA, v.fA)
         && nearly_equal(u.fB, v.fB)
         && nearly_equal(u.fC, v.fC)
         && nearly_equal(u.fD, v.fD)
         && nearly_equal(u.fE, v.fE)
         && nearly_equal(u.fF, v.fF);
 }

 static bool nearly_equal(const SkMatrix44& toXYZD50, const float standard[9]) {
     return nearly_equal(toXYZD50.getFloat(0, 0), standard[0])
         && nearly_equal(toXYZD50.getFloat(0, 1), standard[1])
         && nearly_equal(toXYZD50.getFloat(0, 2), standard[2])
         && nearly_equal(toXYZD50.getFloat(1, 0), standard[3])
         && nearly_equal(toXYZD50.getFloat(1, 1), standard[4])
         && nearly_equal(toXYZD50.getFloat(1, 2), standard[5])
         && nearly_equal(toXYZD50.getFloat(2, 0), standard[6])
         && nearly_equal(toXYZD50.getFloat(2, 1), standard[7])
         && nearly_equal(toXYZD50.getFloat(2, 2), standard[8])
         && nearly_equal(toXYZD50.getFloat(0, 3), 0.0f)
         && nearly_equal(toXYZD50.getFloat(1, 3), 0.0f)
         && nearly_equal(toXYZD50.getFloat(2, 3), 0.0f)
         && nearly_equal(toXYZD50.getFloat(3, 0), 0.0f)
         && nearly_equal(toXYZD50.getFloat(3, 1), 0.0f)
         && nearly_equal(toXYZD50.getFloat(3, 2), 0.0f)
         && nearly_equal(toXYZD50.getFloat(3, 3), 1.0f);
 }

 // Return nullptr if the color profile doen't have a special name.
 const char* get_color_profile_description(const SkColorSpaceTransferFn& fn,
                                           const SkMatrix44& toXYZD50) {
     bool srgb_xfer = nearly_equal(fn, gSRGB_TransferFn);
     bool srgb_gamut = nearly_equal(toXYZD50, gSRGB_toXYZD50);
     if (srgb_xfer && srgb_gamut) {
         return "sRGB";
     }
     bool line_xfer = nearly_equal(fn, gLinear_TransferFn);
     if (line_xfer && srgb_gamut) {
         return "Linear Transfer with sRGB Gamut";
     }
     bool twoDotTwo = nearly_equal(fn, g2Dot2_TransferFn);
     if (twoDotTwo && srgb_gamut) {
         return "2.2 Transfer with sRGB Gamut";
     }
     if (twoDotTwo && nearly_equal(toXYZD50, gAdobeRGB_toXYZD50)) {
         return "AdobeRGB";
     }
     bool dcip3_gamut = nearly_equal(toXYZD50, gDCIP3_toXYZD50);
     if (srgb_xfer || line_xfer) {
         if (srgb_xfer && dcip3_gamut) {
             return "sRGB Transfer with DCI-P3 Gamut";
         }
         if (line_xfer && dcip3_gamut) {
             return "Linear Transfer with DCI-P3 Gamut";
         }
         bool rec2020 = nearly_equal(toXYZD50, gRec2020_toXYZD50);
         if (srgb_xfer && rec2020) {
             return "sRGB Transfer with Rec-BT-2020 Gamut";
         }
         if (line_xfer && rec2020) {
             return "Linear Transfer with Rec-BT-2020 Gamut";
         }
     }
     if (dcip3_gamut && nearly_equal(fn, gDCIP3_TransferFn)) {
         return "DCI-P3";
     }
     return nullptr;
 }

 static void get_color_profile_tag(char dst[kICCDescriptionTagSize],
                                  const SkColorSpaceTransferFn& fn,
                                  const SkMatrix44& toXYZD50) {
     SkASSERT(dst);
     if (const char* description = get_color_profile_description(fn, toXYZD50)) {
         SkASSERT(strlen(description) < kICCDescriptionTagSize);
         strncpy(dst, description, kICCDescriptionTagSize);
         // "If the length of src is less than n, strncpy() writes additional
         // null bytes to dest to ensure that a total of n bytes are written."
     } else {
         strncpy(dst, kDescriptionTagBodyPrefix, sizeof(kDescriptionTagBodyPrefix));
         SkMD5 md5;
         for (int i = 0; i < 3; ++i) {
             for (int j = 0; j < 3; ++j) {
                 float value = toXYZD50.getFloat(i,j);
                 md5.write(&value, sizeof(value));
             }
         }
         static_assert(sizeof(fn) == sizeof(float) * 7, "packed");
         md5.write(&fn, sizeof(fn));
         SkMD5::Digest digest;
         md5.finish(digest);
         char* ptr = dst + sizeof(kDescriptionTagBodyPrefix);
         for (unsigned i = 0; i < sizeof(SkMD5::Digest); ++i) {
             uint8_t byte = digest.data[i];
             *ptr++ = SkHexadecimalDigits::gUpper[byte >> 4];
             *ptr++ = SkHexadecimalDigits::gUpper[byte & 0xF];
         }
         SkASSERT(ptr == dst + kICCDescriptionTagSize);
     }
 }

 SkString SkICCGetColorProfileTag(const SkColorSpaceTransferFn& fn,
                                  const SkMatrix44& toXYZD50) {
     char tag[kICCDescriptionTagSize];
     get_color_profile_tag(tag, fn, toXYZD50);
     size_t len = kICCDescriptionTagSize;
     while (len > 0 && tag[len - 1] == '\0') {
         --len;  // tag is padded out with zeros
     }
     SkASSERT(len != 0);
     return SkString(tag, len);
 }

 // returns pointer just beyond where we just wrote.
 static uint8_t* string_copy_ascii_to_utf16be(uint8_t* dst, const char* src, size_t count) {
     while (count-- > 0) {
         *dst++ = 0;
         *dst++ = (uint8_t)(*src++);
     }
     return dst;
 }

 sk_sp<SkData> SkICC::WriteToICC(const SkColorSpaceTransferFn& fn, const SkMatrix44& toXYZD50) {
     if (!is_3x3(toXYZD50) || !is_valid_transfer_fn(fn)) {
         return nullptr;
     }

     SkAutoMalloc profile(kICCProfileSize);
     uint8_t* ptr = (uint8_t*) profile.get();

     // Write profile header
     memcpy(ptr, kICCHeader, sizeof(kICCHeader));
     ptr += sizeof(kICCHeader);

     // Write tag table
     memcpy(ptr, kICCTagTable, sizeof(kICCTagTable));
     ptr += sizeof(kICCTagTable);

     // Write profile description tag
     memcpy(ptr, kDescriptionTagHeader, sizeof(kDescriptionTagHeader));
     ptr += sizeof(kDescriptionTagHeader);
     {
         char colorProfileTag[kICCDescriptionTagSize];
         get_color_profile_tag(colorProfileTag, fn, toXYZD50);
         ptr = string_copy_ascii_to_utf16be(ptr, colorProfileTag, kICCDescriptionTagSize);
     }

     // Write XYZ tags
     write_xyz_tag((uint32_t*) ptr, toXYZD50, 0);
     ptr += kTAG_XYZ_Bytes;
     write_xyz_tag((uint32_t*) ptr, toXYZD50, 1);
     ptr += kTAG_XYZ_Bytes;
     write_xyz_tag((uint32_t*) ptr, toXYZD50, 2);
     ptr += kTAG_XYZ_Bytes;

     // Write TRC tag
     write_trc_tag((uint32_t*) ptr, fn);
     ptr += kTAG_TRC_Bytes;

     // Write white point tag (must be D50)
     memcpy(ptr, kWhitePointTag, sizeof(kWhitePointTag));
     ptr += sizeof(kWhitePointTag);

     // Write copyright tag
     memcpy(ptr, kCopyrightTagHeader, sizeof(kCopyrightTagHeader));
     ptr += sizeof(kCopyrightTagHeader);
     memcpy(ptr, kCopyrightTagBody, sizeof(kCopyrightTagBody));
     ptr += sizeof(kCopyrightTagBody);

     SkASSERT(kICCProfileSize == ptr - (uint8_t*) profile.get());
     return SkData::MakeFromMalloc(profile.release(), kICCProfileSize);
 }
	/*
	* 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 "SkAutoMalloc.h"
	#include "SkColorSpacePriv.h"
	#include "SkColorSpaceXformPriv.h"
	#include "SkColorSpace_XYZ.h"
	#include "SkEndian.h"
	#include "SkFixed.h"
	#include "SkICC.h"
	#include "SkICCPriv.h"
	#include "SkMD5.h"
	#include "SkString.h"
	#include "SkUtils.h"

	SkICC::SkICC(sk_sp<SkColorSpace> colorSpace)
	: fColorSpace(std::move(colorSpace))
	{}

	sk_sp<SkICC> SkICC::Make(const void* ptr, size_t len) {
	sk_sp<SkColorSpace> colorSpace = SkColorSpace::MakeICC(ptr, len);
	if (!colorSpace) {
	return nullptr;
	}

	return sk_sp<SkICC>(new SkICC(std::move(colorSpace)));
	}

	bool SkICC::toXYZD50(SkMatrix44* toXYZD50) const {
	return fColorSpace->toXYZD50(toXYZD50);
	}

	bool SkICC::isNumericalTransferFn(SkColorSpaceTransferFn* coeffs) const {
	return fColorSpace->isNumericalTransferFn(coeffs);
	}

	static const int kDefaultTableSize = 512; // Arbitrary

	void fn_to_table(float* tablePtr, const SkColorSpaceTransferFn& fn) {
	// Y = (aX + b)^g + e for X >= d
	// Y = cX + f otherwise
	for (int i = 0; i < kDefaultTableSize; i++) {
	float x = ((float) i) / ((float) (kDefaultTableSize - 1));
	if (x >= fn.fD) {
	tablePtr[i] = clamp_0_1(powf(fn.fA * x + fn.fB, fn.fG) + fn.fE);
	} else {
	tablePtr[i] = clamp_0_1(fn.fC * x + fn.fF);
	}
	}
	}

	void copy_to_table(float* tablePtr, const SkGammas* gammas, int index) {
	SkASSERT(gammas->isTable(index));
	const float* ptr = gammas->table(index);
	const size_t bytes = gammas->tableSize(index) * sizeof(float);
	memcpy(tablePtr, ptr, bytes);
	}

	bool SkICC::rawTransferFnData(Tables* tables) const {
	if (!fColorSpace->toXYZD50()) {
	return false; // Can't even dream of handling A2B here...
	}
	SkColorSpace_XYZ* colorSpace = (SkColorSpace_XYZ*) fColorSpace.get();

	SkColorSpaceTransferFn fn;
	if (this->isNumericalTransferFn(&fn)) {
	tables->fStorage = SkData::MakeUninitialized(kDefaultTableSize * sizeof(float));
	fn_to_table((float*) tables->fStorage->writable_data(), fn);
	tables->fRed.fOffset = tables->fGreen.fOffset = tables->fBlue.fOffset = 0;
	tables->fRed.fCount = tables->fGreen.fCount = tables->fBlue.fCount = kDefaultTableSize;
	return true;
	}

	const SkGammas* gammas = colorSpace->gammas();
	SkASSERT(gammas);
	if (gammas->allChannelsSame()) {
	SkASSERT(gammas->isTable(0));
	tables->fStorage = SkData::MakeUninitialized(gammas->tableSize(0) * sizeof(float));
	copy_to_table((float*) tables->fStorage->writable_data(), gammas, 0);
	tables->fRed.fOffset = tables->fGreen.fOffset = tables->fBlue.fOffset = 0;
	tables->fRed.fCount = tables->fGreen.fCount = tables->fBlue.fCount = gammas->tableSize(0);
	return true;
	}

	// Determine the storage size.
	size_t storageSize = 0;
	for (int i = 0; i < 3; i++) {
	if (gammas->isTable(i)) {
	storageSize += gammas->tableSize(i) * sizeof(float);
	} else {
	storageSize += kDefaultTableSize * sizeof(float);
	}
	}

	// Fill in the tables.
	tables->fStorage = SkData::MakeUninitialized(storageSize);
	float* ptr = (float*) tables->fStorage->writable_data();
	size_t offset = 0;
	Channel rgb[3];
	for (int i = 0; i < 3; i++) {
	if (gammas->isTable(i)) {
	copy_to_table(ptr, gammas, i);
	rgb[i].fOffset = offset;
	rgb[i].fCount = gammas->tableSize(i);
	offset += rgb[i].fCount * sizeof(float);
	ptr += rgb[i].fCount;
	continue;
	}

	if (gammas->isNamed(i)) {
	SkAssertResult(named_to_parametric(&fn, gammas->data(i).fNamed));
	} else if (gammas->isValue(i)) {
	value_to_parametric(&fn, gammas->data(i).fValue);
	} else {
	SkASSERT(gammas->isParametric(i));
	fn = gammas->params(i);
	}

	fn_to_table(ptr, fn);
	rgb[i].fOffset = offset;
	rgb[i].fCount = kDefaultTableSize;
	offset += kDefaultTableSize * sizeof(float);
	ptr += kDefaultTableSize;
	}

	tables->fRed = rgb[0];
	tables->fGreen = rgb[1];
	tables->fBlue = rgb[2];
	return true;
	}

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

	static constexpr char kDescriptionTagBodyPrefix[12] =
	{ 'G', 'o', 'o', 'g', 'l', 'e', '/', 'S', 'k', 'i', 'a' , '/'};

	static constexpr size_t kICCDescriptionTagSize = 44;

	static_assert(kICCDescriptionTagSize ==
	sizeof(kDescriptionTagBodyPrefix) + 2 * sizeof(SkMD5::Digest), "");
	static constexpr size_t kDescriptionTagBodySize = kICCDescriptionTagSize * 2; // ascii->utf16be

	static_assert(SkIsAlign4(kDescriptionTagBodySize), "Description must be aligned to 4-bytes.");
	static constexpr uint32_t kDescriptionTagHeader[7] {
	SkEndian_SwapBE32(kTAG_TextType), // Type signature
	0, // Reserved
	SkEndian_SwapBE32(1), // Number of records
	SkEndian_SwapBE32(12), // Record size (must be 12)
	SkEndian_SwapBE32(SkSetFourByteTag('e', 'n', 'U', 'S')), // English USA
	SkEndian_SwapBE32(kDescriptionTagBodySize), // Length of string
	SkEndian_SwapBE32(28), // Offset of string
	};

	static constexpr uint32_t kWhitePointTag[5] {
	SkEndian_SwapBE32(kXYZ_PCSSpace),
	0,
	SkEndian_SwapBE32(0x0000f6d6), // X = 0.96420 (D50)
	SkEndian_SwapBE32(0x00010000), // Y = 1.00000 (D50)
	SkEndian_SwapBE32(0x0000d32d), // Z = 0.82491 (D50)
	};

	// Google Inc. 2016 (UTF-16)
	static constexpr uint8_t kCopyrightTagBody[] = {
	0x00, 0x47, 0x00, 0x6f, 0x00, 0x6f, 0x00, 0x67, 0x00, 0x6c, 0x00, 0x65, 0x00, 0x20, 0x00,
	0x49, 0x00, 0x6e, 0x00, 0x63, 0x00, 0x2e, 0x00, 0x20, 0x00, 0x32, 0x00, 0x30, 0x00, 0x31,
	0x00, 0x36,
	};
	static_assert(SkIsAlign4(sizeof(kCopyrightTagBody)), "Copyright must be aligned to 4-bytes.");
	static constexpr uint32_t kCopyrightTagHeader[7] {
	SkEndian_SwapBE32(kTAG_TextType), // Type signature
	0, // Reserved
	SkEndian_SwapBE32(1), // Number of records
	SkEndian_SwapBE32(12), // Record size (must be 12)
	SkEndian_SwapBE32(SkSetFourByteTag('e', 'n', 'U', 'S')), // English USA
	SkEndian_SwapBE32(sizeof(kCopyrightTagBody)), // Length of string
	SkEndian_SwapBE32(28), // Offset of string
	};

	// We will write a profile with the minimum nine required tags.
	static constexpr uint32_t kICCNumEntries = 9;

	static constexpr uint32_t kTAG_desc = SkSetFourByteTag('d', 'e', 's', 'c');
	static constexpr uint32_t kTAG_desc_Bytes = sizeof(kDescriptionTagHeader) +
	kDescriptionTagBodySize;
	static constexpr uint32_t kTAG_desc_Offset = kICCHeaderSize +
	kICCNumEntries * kICCTagTableEntrySize;

	static constexpr uint32_t kTAG_XYZ_Bytes = 20;
	static constexpr uint32_t kTAG_rXYZ_Offset = kTAG_desc_Offset + kTAG_desc_Bytes;
	static constexpr uint32_t kTAG_gXYZ_Offset = kTAG_rXYZ_Offset + kTAG_XYZ_Bytes;
	static constexpr uint32_t kTAG_bXYZ_Offset = kTAG_gXYZ_Offset + kTAG_XYZ_Bytes;

	static constexpr uint32_t kTAG_TRC_Bytes = 40;
	static constexpr uint32_t kTAG_rTRC_Offset = kTAG_bXYZ_Offset + kTAG_XYZ_Bytes;
	static constexpr uint32_t kTAG_gTRC_Offset = kTAG_rTRC_Offset;
	static constexpr uint32_t kTAG_bTRC_Offset = kTAG_rTRC_Offset;

	static constexpr uint32_t kTAG_wtpt = SkSetFourByteTag('w', 't', 'p', 't');
	static constexpr uint32_t kTAG_wtpt_Offset = kTAG_bTRC_Offset + kTAG_TRC_Bytes;

	static constexpr uint32_t kTAG_cprt = SkSetFourByteTag('c', 'p', 'r', 't');
	static constexpr uint32_t kTAG_cprt_Bytes = sizeof(kCopyrightTagHeader) +
	sizeof(kCopyrightTagBody);
	static constexpr uint32_t kTAG_cprt_Offset = kTAG_wtpt_Offset + kTAG_XYZ_Bytes;

	static constexpr uint32_t kICCProfileSize = kTAG_cprt_Offset + kTAG_cprt_Bytes;

	static constexpr uint32_t kICCHeader[kICCHeaderSize / 4] {
	SkEndian_SwapBE32(kICCProfileSize), // Size of the profile
	0, // Preferred CMM type (ignored)
	SkEndian_SwapBE32(0x02100000), // Version 2.1
	SkEndian_SwapBE32(kDisplay_Profile), // Display device profile
	SkEndian_SwapBE32(kRGB_ColorSpace), // RGB input color space
	SkEndian_SwapBE32(kXYZ_PCSSpace), // XYZ profile connection space
	0, 0, 0, // Date and time (ignored)
	SkEndian_SwapBE32(kACSP_Signature), // Profile signature
	0, // Platform target (ignored)
	0x00000000, // Flags: not embedded, can be used independently
	0, // Device manufacturer (ignored)
	0, // Device model (ignored)
	0, 0, // Device attributes (ignored)
	SkEndian_SwapBE32(1), // Relative colorimetric rendering intent
	SkEndian_SwapBE32(0x0000f6d6), // D50 standard illuminant (X)
	SkEndian_SwapBE32(0x00010000), // D50 standard illuminant (Y)
	SkEndian_SwapBE32(0x0000d32d), // D50 standard illuminant (Z)
	0, // Profile creator (ignored)
	0, 0, 0, 0, // Profile id checksum (ignored)
	0, 0, 0, 0, 0, 0, 0, // Reserved (ignored)
	SkEndian_SwapBE32(kICCNumEntries), // Number of tags
	};

	static constexpr uint32_t kICCTagTable[3 * kICCNumEntries] {
	// Profile description
	SkEndian_SwapBE32(kTAG_desc),
	SkEndian_SwapBE32(kTAG_desc_Offset),
	SkEndian_SwapBE32(kTAG_desc_Bytes),

	// rXYZ
	SkEndian_SwapBE32(kTAG_rXYZ),
	SkEndian_SwapBE32(kTAG_rXYZ_Offset),
	SkEndian_SwapBE32(kTAG_XYZ_Bytes),

	// gXYZ
	SkEndian_SwapBE32(kTAG_gXYZ),
	SkEndian_SwapBE32(kTAG_gXYZ_Offset),
	SkEndian_SwapBE32(kTAG_XYZ_Bytes),

	// bXYZ
	SkEndian_SwapBE32(kTAG_bXYZ),
	SkEndian_SwapBE32(kTAG_bXYZ_Offset),
	SkEndian_SwapBE32(kTAG_XYZ_Bytes),

	// rTRC
	SkEndian_SwapBE32(kTAG_rTRC),
	SkEndian_SwapBE32(kTAG_rTRC_Offset),
	SkEndian_SwapBE32(kTAG_TRC_Bytes),

	// gTRC
	SkEndian_SwapBE32(kTAG_gTRC),
	SkEndian_SwapBE32(kTAG_gTRC_Offset),
	SkEndian_SwapBE32(kTAG_TRC_Bytes),

	// bTRC
	SkEndian_SwapBE32(kTAG_bTRC),
	SkEndian_SwapBE32(kTAG_bTRC_Offset),
	SkEndian_SwapBE32(kTAG_TRC_Bytes),

	// White point
	SkEndian_SwapBE32(kTAG_wtpt),
	SkEndian_SwapBE32(kTAG_wtpt_Offset),
	SkEndian_SwapBE32(kTAG_XYZ_Bytes),

	// Copyright
	SkEndian_SwapBE32(kTAG_cprt),
	SkEndian_SwapBE32(kTAG_cprt_Offset),
	SkEndian_SwapBE32(kTAG_cprt_Bytes),
	};

	// This is like SkFloatToFixed, but rounds to nearest, preserving as much accuracy as possible
	// when going float -> fixed -> float (it has the same accuracy when going fixed -> float -> fixed).
	// The use of double is necessary to accomodate the full potential 32-bit mantissa of the 16.16
	// SkFixed value, and so avoiding rounding problems with float. Also, see the comment in SkFixed.h.
	static SkFixed float_round_to_fixed(float x) {
	return sk_float_saturate2int((float)floor((double)x * SK_Fixed1 + 0.5));
	}

	static void write_xyz_tag(uint32_t* ptr, const SkMatrix44& toXYZ, int col) {
	ptr[0] = SkEndian_SwapBE32(kXYZ_PCSSpace);
	ptr[1] = 0;
	ptr[2] = SkEndian_SwapBE32(float_round_to_fixed(toXYZ.getFloat(0, col)));
	ptr[3] = SkEndian_SwapBE32(float_round_to_fixed(toXYZ.getFloat(1, col)));
	ptr[4] = SkEndian_SwapBE32(float_round_to_fixed(toXYZ.getFloat(2, col)));
	}

	static void write_trc_tag(uint32_t* ptr, const SkColorSpaceTransferFn& fn) {
	ptr[0] = SkEndian_SwapBE32(kTAG_ParaCurveType);
	ptr[1] = 0;
	ptr[2] = (uint32_t) (SkEndian_SwapBE16(kGABCDEF_ParaCurveType));
	ptr[3] = SkEndian_SwapBE32(float_round_to_fixed(fn.fG));
	ptr[4] = SkEndian_SwapBE32(float_round_to_fixed(fn.fA));
	ptr[5] = SkEndian_SwapBE32(float_round_to_fixed(fn.fB));
	ptr[6] = SkEndian_SwapBE32(float_round_to_fixed(fn.fC));
	ptr[7] = SkEndian_SwapBE32(float_round_to_fixed(fn.fD));
	ptr[8] = SkEndian_SwapBE32(float_round_to_fixed(fn.fE));
	ptr[9] = SkEndian_SwapBE32(float_round_to_fixed(fn.fF));
	}

	static bool is_3x3(const SkMatrix44& toXYZD50) {
	return 0.0f == toXYZD50.get(3, 0) && 0.0f == toXYZD50.get(3, 1) && 0.0f == toXYZD50.get(3, 2) &&
	0.0f == toXYZD50.get(0, 3) && 0.0f == toXYZD50.get(1, 3) && 0.0f == toXYZD50.get(2, 3) &&
	1.0f == toXYZD50.get(3, 3);
	}

	static bool nearly_equal(float x, float y) {
	// A note on why I chose this tolerance: transfer_fn_almost_equal() uses a
	// tolerance of 0.001f, which doesn't seem to be enough to distinguish
	// between similar transfer functions, for example: gamma2.2 and sRGB.
	//
	// If the tolerance is 0.0f, then this we can't distinguish between two
	// different encodings of what is clearly the same colorspace. Some
	// experimentation with example files lead to this number:
	static constexpr float kTolerance = 1.0f / (1 << 11);
	return ::fabsf(x - y) <= kTolerance;
	}

	static bool nearly_equal(const SkColorSpaceTransferFn& u,
	const SkColorSpaceTransferFn& v) {
	return nearly_equal(u.fG, v.fG)
	&& nearly_equal(u.fA, v.fA)
	&& nearly_equal(u.fB, v.fB)
	&& nearly_equal(u.fC, v.fC)
	&& nearly_equal(u.fD, v.fD)
	&& nearly_equal(u.fE, v.fE)
	&& nearly_equal(u.fF, v.fF);
	}

	static bool nearly_equal(const SkMatrix44& toXYZD50, const float standard[9]) {
	return nearly_equal(toXYZD50.getFloat(0, 0), standard[0])
	&& nearly_equal(toXYZD50.getFloat(0, 1), standard[1])
	&& nearly_equal(toXYZD50.getFloat(0, 2), standard[2])
	&& nearly_equal(toXYZD50.getFloat(1, 0), standard[3])
	&& nearly_equal(toXYZD50.getFloat(1, 1), standard[4])
	&& nearly_equal(toXYZD50.getFloat(1, 2), standard[5])
	&& nearly_equal(toXYZD50.getFloat(2, 0), standard[6])
	&& nearly_equal(toXYZD50.getFloat(2, 1), standard[7])
	&& nearly_equal(toXYZD50.getFloat(2, 2), standard[8])
	&& nearly_equal(toXYZD50.getFloat(0, 3), 0.0f)
	&& nearly_equal(toXYZD50.getFloat(1, 3), 0.0f)
	&& nearly_equal(toXYZD50.getFloat(2, 3), 0.0f)
	&& nearly_equal(toXYZD50.getFloat(3, 0), 0.0f)
	&& nearly_equal(toXYZD50.getFloat(3, 1), 0.0f)
	&& nearly_equal(toXYZD50.getFloat(3, 2), 0.0f)
	&& nearly_equal(toXYZD50.getFloat(3, 3), 1.0f);
	}

	// Return nullptr if the color profile doen't have a special name.
	const char* get_color_profile_description(const SkColorSpaceTransferFn& fn,
	const SkMatrix44& toXYZD50) {
	bool srgb_xfer = nearly_equal(fn, gSRGB_TransferFn);
	bool srgb_gamut = nearly_equal(toXYZD50, gSRGB_toXYZD50);
	if (srgb_xfer && srgb_gamut) {
	return "sRGB";
	}
	bool line_xfer = nearly_equal(fn, gLinear_TransferFn);
	if (line_xfer && srgb_gamut) {
	return "Linear Transfer with sRGB Gamut";
	}
	bool twoDotTwo = nearly_equal(fn, g2Dot2_TransferFn);
	if (twoDotTwo && srgb_gamut) {
	return "2.2 Transfer with sRGB Gamut";
	}
	if (twoDotTwo && nearly_equal(toXYZD50, gAdobeRGB_toXYZD50)) {
	return "AdobeRGB";
	}
	bool dcip3_gamut = nearly_equal(toXYZD50, gDCIP3_toXYZD50);
	if (srgb_xfer \|\| line_xfer) {
	if (srgb_xfer && dcip3_gamut) {
	return "sRGB Transfer with DCI-P3 Gamut";
	}
	if (line_xfer && dcip3_gamut) {
	return "Linear Transfer with DCI-P3 Gamut";
	}
	bool rec2020 = nearly_equal(toXYZD50, gRec2020_toXYZD50);
	if (srgb_xfer && rec2020) {
	return "sRGB Transfer with Rec-BT-2020 Gamut";
	}
	if (line_xfer && rec2020) {
	return "Linear Transfer with Rec-BT-2020 Gamut";
	}
	}
	if (dcip3_gamut && nearly_equal(fn, gDCIP3_TransferFn)) {
	return "DCI-P3";
	}
	return nullptr;
	}

	static void get_color_profile_tag(char dst[kICCDescriptionTagSize],
	const SkColorSpaceTransferFn& fn,
	const SkMatrix44& toXYZD50) {
	SkASSERT(dst);
	if (const char* description = get_color_profile_description(fn, toXYZD50)) {
	SkASSERT(strlen(description) < kICCDescriptionTagSize);
	strncpy(dst, description, kICCDescriptionTagSize);
	// "If the length of src is less than n, strncpy() writes additional
	// null bytes to dest to ensure that a total of n bytes are written."
	} else {
	strncpy(dst, kDescriptionTagBodyPrefix, sizeof(kDescriptionTagBodyPrefix));
	SkMD5 md5;
	for (int i = 0; i < 3; ++i) {
	for (int j = 0; j < 3; ++j) {
	float value = toXYZD50.getFloat(i,j);
	md5.write(&value, sizeof(value));
	}
	}
	static_assert(sizeof(fn) == sizeof(float) * 7, "packed");
	md5.write(&fn, sizeof(fn));
	SkMD5::Digest digest;
	md5.finish(digest);
	char* ptr = dst + sizeof(kDescriptionTagBodyPrefix);
	for (unsigned i = 0; i < sizeof(SkMD5::Digest); ++i) {
	uint8_t byte = digest.data[i];
	*ptr++ = SkHexadecimalDigits::gUpper[byte >> 4];
	*ptr++ = SkHexadecimalDigits::gUpper[byte & 0xF];
	}
	SkASSERT(ptr == dst + kICCDescriptionTagSize);
	}
	}

	SkString SkICCGetColorProfileTag(const SkColorSpaceTransferFn& fn,
	const SkMatrix44& toXYZD50) {
	char tag[kICCDescriptionTagSize];
	get_color_profile_tag(tag, fn, toXYZD50);
	size_t len = kICCDescriptionTagSize;
	while (len > 0 && tag[len - 1] == '\0') {
	--len; // tag is padded out with zeros
	}
	SkASSERT(len != 0);
	return SkString(tag, len);
	}

	// returns pointer just beyond where we just wrote.
	static uint8_t* string_copy_ascii_to_utf16be(uint8_t* dst, const char* src, size_t count) {
	while (count-- > 0) {
	*dst++ = 0;
	dst++ = (uint8_t)(src++);
	}
	return dst;
	}

	sk_sp<SkData> SkICC::WriteToICC(const SkColorSpaceTransferFn& fn, const SkMatrix44& toXYZD50) {
	if (!is_3x3(toXYZD50) \|\| !is_valid_transfer_fn(fn)) {
	return nullptr;
	}

	SkAutoMalloc profile(kICCProfileSize);
	uint8_t* ptr = (uint8_t*) profile.get();

	// Write profile header
	memcpy(ptr, kICCHeader, sizeof(kICCHeader));
	ptr += sizeof(kICCHeader);

	// Write tag table
	memcpy(ptr, kICCTagTable, sizeof(kICCTagTable));
	ptr += sizeof(kICCTagTable);

	// Write profile description tag
	memcpy(ptr, kDescriptionTagHeader, sizeof(kDescriptionTagHeader));
	ptr += sizeof(kDescriptionTagHeader);
	{
	char colorProfileTag[kICCDescriptionTagSize];
	get_color_profile_tag(colorProfileTag, fn, toXYZD50);
	ptr = string_copy_ascii_to_utf16be(ptr, colorProfileTag, kICCDescriptionTagSize);
	}

	// Write XYZ tags
	write_xyz_tag((uint32_t*) ptr, toXYZD50, 0);
	ptr += kTAG_XYZ_Bytes;
	write_xyz_tag((uint32_t*) ptr, toXYZD50, 1);
	ptr += kTAG_XYZ_Bytes;
	write_xyz_tag((uint32_t*) ptr, toXYZD50, 2);
	ptr += kTAG_XYZ_Bytes;

	// Write TRC tag
	write_trc_tag((uint32_t*) ptr, fn);
	ptr += kTAG_TRC_Bytes;

	// Write white point tag (must be D50)
	memcpy(ptr, kWhitePointTag, sizeof(kWhitePointTag));
	ptr += sizeof(kWhitePointTag);

	// Write copyright tag
	memcpy(ptr, kCopyrightTagHeader, sizeof(kCopyrightTagHeader));
	ptr += sizeof(kCopyrightTagHeader);
	memcpy(ptr, kCopyrightTagBody, sizeof(kCopyrightTagBody));
	ptr += sizeof(kCopyrightTagBody);

	SkASSERT(kICCProfileSize == ptr - (uint8_t*) profile.get());
	return SkData::MakeFromMalloc(profile.release(), kICCProfileSize);
	}