| /* |
| * 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 "SkColorSpace.h" |
| #include "SkColorSpace_Base.h" |
| #include "SkColorSpacePriv.h" |
| #include "SkEndian.h" |
| #include "SkFixed.h" |
| #include "SkTemplates.h" |
| |
| #define return_if_false(pred, msg) \ |
| do { \ |
| if (!(pred)) { \ |
| SkColorSpacePrintf("Invalid ICC Profile: %s.\n", (msg)); \ |
| return false; \ |
| } \ |
| } while (0) |
| |
| #define return_null(msg) \ |
| do { \ |
| SkColorSpacePrintf("Invalid ICC Profile: %s.\n", (msg)); \ |
| return nullptr; \ |
| } while (0) |
| |
| static uint16_t read_big_endian_u16(const uint8_t* ptr) { |
| return ptr[0] << 8 | ptr[1]; |
| } |
| |
| static uint32_t read_big_endian_u32(const uint8_t* ptr) { |
| return ptr[0] << 24 | ptr[1] << 16 | ptr[2] << 8 | ptr[3]; |
| } |
| |
| static int32_t read_big_endian_i32(const uint8_t* ptr) { |
| return (int32_t) read_big_endian_u32(ptr); |
| } |
| |
| // This is equal to the header size according to the ICC specification (128) |
| // plus the size of the tag count (4). We include the tag count since we |
| // always require it to be present anyway. |
| static constexpr size_t kICCHeaderSize = 132; |
| |
| // Contains a signature (4), offset (4), and size (4). |
| static constexpr size_t kICCTagTableEntrySize = 12; |
| |
| static constexpr uint32_t kRGB_ColorSpace = SkSetFourByteTag('R', 'G', 'B', ' '); |
| static constexpr uint32_t kDisplay_Profile = SkSetFourByteTag('m', 'n', 't', 'r'); |
| static constexpr uint32_t kInput_Profile = SkSetFourByteTag('s', 'c', 'n', 'r'); |
| static constexpr uint32_t kOutput_Profile = SkSetFourByteTag('p', 'r', 't', 'r'); |
| static constexpr uint32_t kColorSpace_Profile = SkSetFourByteTag('s', 'p', 'a', 'c'); |
| static constexpr uint32_t kXYZ_PCSSpace = SkSetFourByteTag('X', 'Y', 'Z', ' '); |
| static constexpr uint32_t kACSP_Signature = SkSetFourByteTag('a', 'c', 's', 'p'); |
| |
| struct ICCProfileHeader { |
| uint32_t fSize; |
| |
| // No reason to care about the preferred color management module (ex: Adobe, Apple, etc.). |
| // We're always going to use this one. |
| uint32_t fCMMType_ignored; |
| |
| uint32_t fVersion; |
| uint32_t fProfileClass; |
| uint32_t fInputColorSpace; |
| uint32_t fPCS; |
| uint32_t fDateTime_ignored[3]; |
| uint32_t fSignature; |
| |
| // Indicates the platform that this profile was created for (ex: Apple, Microsoft). This |
| // doesn't really matter to us. |
| uint32_t fPlatformTarget_ignored; |
| |
| // Flags can indicate: |
| // (1) Whether this profile was embedded in a file. This flag is consistently wrong. |
| // Ex: The profile came from a file but indicates that it did not. |
| // (2) Whether we are allowed to use the profile independently of the color data. If set, |
| // this may allow us to use the embedded profile for testing separate from the original |
| // image. |
| uint32_t fFlags_ignored; |
| |
| // We support many output devices. It doesn't make sense to think about the attributes of |
| // the device in the context of the image profile. |
| uint32_t fDeviceManufacturer_ignored; |
| uint32_t fDeviceModel_ignored; |
| uint32_t fDeviceAttributes_ignored[2]; |
| |
| uint32_t fRenderingIntent; |
| int32_t fIlluminantXYZ[3]; |
| |
| // We don't care who created the profile. |
| uint32_t fCreator_ignored; |
| |
| // This is an MD5 checksum. Could be useful for checking if profiles are equal. |
| uint32_t fProfileId_ignored[4]; |
| |
| // Reserved for future use. |
| uint32_t fReserved_ignored[7]; |
| |
| uint32_t fTagCount; |
| |
| void init(const uint8_t* src, size_t len) { |
| SkASSERT(kICCHeaderSize == sizeof(*this)); |
| |
| uint32_t* dst = (uint32_t*) this; |
| for (uint32_t i = 0; i < kICCHeaderSize / 4; i++, src+=4) { |
| dst[i] = read_big_endian_u32(src); |
| } |
| } |
| |
| bool valid() const { |
| return_if_false(fSize >= kICCHeaderSize, "Size is too small"); |
| |
| uint8_t majorVersion = fVersion >> 24; |
| return_if_false(majorVersion <= 4, "Unsupported version"); |
| |
| // These are the four basic classes of profiles that we might expect to see embedded |
| // in images. Additional classes exist, but they generally are used as a convenient |
| // way for CMMs to store calculated transforms. |
| return_if_false(fProfileClass == kDisplay_Profile || |
| fProfileClass == kInput_Profile || |
| fProfileClass == kOutput_Profile || |
| fProfileClass == kColorSpace_Profile, |
| "Unsupported profile"); |
| |
| // TODO (msarett): |
| // All the profiles we've tested so far use RGB as the input color space. |
| return_if_false(fInputColorSpace == kRGB_ColorSpace, "Unsupported color space"); |
| |
| // TODO (msarett): |
| // All the profiles we've tested so far use XYZ as the profile connection space. |
| return_if_false(fPCS == kXYZ_PCSSpace, "Unsupported PCS space"); |
| |
| return_if_false(fSignature == kACSP_Signature, "Bad signature"); |
| |
| // TODO (msarett): |
| // Should we treat different rendering intents differently? |
| // Valid rendering intents include kPerceptual (0), kRelative (1), |
| // kSaturation (2), and kAbsolute (3). |
| if (fRenderingIntent > 3) { |
| // Warn rather than fail here. Occasionally, we see perfectly |
| // normal profiles with wacky rendering intents. |
| SkColorSpacePrintf("Warning, bad rendering intent.\n"); |
| } |
| |
| return_if_false(color_space_almost_equal(SkFixedToFloat(fIlluminantXYZ[0]), 0.96420f) && |
| color_space_almost_equal(SkFixedToFloat(fIlluminantXYZ[1]), 1.00000f) && |
| color_space_almost_equal(SkFixedToFloat(fIlluminantXYZ[2]), 0.82491f), |
| "Illuminant must be D50"); |
| |
| return_if_false(fTagCount <= 100, "Too many tags"); |
| |
| return true; |
| } |
| }; |
| |
| template <class T> |
| static bool safe_add(T arg1, T arg2, size_t* result) { |
| SkASSERT(arg1 >= 0); |
| SkASSERT(arg2 >= 0); |
| if (arg1 >= 0 && arg2 <= std::numeric_limits<T>::max() - arg1) { |
| T sum = arg1 + arg2; |
| if (sum <= std::numeric_limits<size_t>::max()) { |
| *result = static_cast<size_t>(sum); |
| return true; |
| } |
| } |
| return false; |
| } |
| |
| static bool safe_mul(uint32_t arg1, uint32_t arg2, uint32_t* result) { |
| uint64_t product64 = (uint64_t) arg1 * (uint64_t) arg2; |
| uint32_t product32 = (uint32_t) product64; |
| if (product32 != product64) { |
| return false; |
| } |
| |
| *result = product32; |
| return true; |
| } |
| |
| struct ICCTag { |
| uint32_t fSignature; |
| uint32_t fOffset; |
| uint32_t fLength; |
| |
| const uint8_t* init(const uint8_t* src) { |
| fSignature = read_big_endian_u32(src); |
| fOffset = read_big_endian_u32(src + 4); |
| fLength = read_big_endian_u32(src + 8); |
| return src + 12; |
| } |
| |
| bool valid(size_t len) { |
| size_t tagEnd; |
| return_if_false(safe_add(fOffset, fLength, &tagEnd), |
| "Tag too large, overflows integer addition"); |
| return_if_false(tagEnd <= len, "Tag too large for ICC profile"); |
| return true; |
| } |
| |
| const uint8_t* addr(const uint8_t* src) const { |
| return src + fOffset; |
| } |
| |
| static const ICCTag* Find(const ICCTag tags[], int count, uint32_t signature) { |
| for (int i = 0; i < count; ++i) { |
| if (tags[i].fSignature == signature) { |
| return &tags[i]; |
| } |
| } |
| return nullptr; |
| } |
| }; |
| |
| static constexpr uint32_t kTAG_rXYZ = SkSetFourByteTag('r', 'X', 'Y', 'Z'); |
| static constexpr uint32_t kTAG_gXYZ = SkSetFourByteTag('g', 'X', 'Y', 'Z'); |
| static constexpr uint32_t kTAG_bXYZ = SkSetFourByteTag('b', 'X', 'Y', 'Z'); |
| static constexpr uint32_t kTAG_rTRC = SkSetFourByteTag('r', 'T', 'R', 'C'); |
| static constexpr uint32_t kTAG_gTRC = SkSetFourByteTag('g', 'T', 'R', 'C'); |
| static constexpr uint32_t kTAG_bTRC = SkSetFourByteTag('b', 'T', 'R', 'C'); |
| static constexpr uint32_t kTAG_A2B0 = SkSetFourByteTag('A', '2', 'B', '0'); |
| |
| static bool load_xyz(float dst[3], const uint8_t* src, size_t len) { |
| if (len < 20) { |
| SkColorSpacePrintf("XYZ tag is too small (%d bytes)", len); |
| return false; |
| } |
| |
| dst[0] = SkFixedToFloat(read_big_endian_i32(src + 8)); |
| dst[1] = SkFixedToFloat(read_big_endian_i32(src + 12)); |
| dst[2] = SkFixedToFloat(read_big_endian_i32(src + 16)); |
| SkColorSpacePrintf("XYZ %g %g %g\n", dst[0], dst[1], dst[2]); |
| return true; |
| } |
| |
| static constexpr uint32_t kTAG_CurveType = SkSetFourByteTag('c', 'u', 'r', 'v'); |
| static constexpr uint32_t kTAG_ParaCurveType = SkSetFourByteTag('p', 'a', 'r', 'a'); |
| |
| static SkGammas::Type set_gamma_value(SkGammas::Data* data, float value) { |
| if (color_space_almost_equal(2.2f, value)) { |
| data->fNamed = k2Dot2Curve_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| |
| if (color_space_almost_equal(1.0f, value)) { |
| data->fNamed = kLinear_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| |
| if (color_space_almost_equal(0.0f, value)) { |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| data->fValue = value; |
| return SkGammas::Type::kValue_Type; |
| } |
| |
| static float read_big_endian_16_dot_16(const uint8_t buf[4]) { |
| // It just so happens that SkFixed is also 16.16! |
| return SkFixedToFloat(read_big_endian_i32(buf)); |
| } |
| |
| /** |
| * @param outData Set to the appropriate value on success. If we have table or |
| * parametric gamma, it is the responsibility of the caller to set |
| * fOffset. |
| * @param outParams If this is a parametric gamma, this is set to the appropriate |
| * parameters on success. |
| * @param outTagBytes Will be set to the length of the tag on success. |
| * @src Pointer to tag data. |
| * @len Length of tag data in bytes. |
| * |
| * @return kNone_Type on failure, otherwise the type of the gamma tag. |
| */ |
| static SkGammas::Type parse_gamma(SkGammas::Data* outData, SkGammas::Params* outParams, |
| size_t* outTagBytes, const uint8_t* src, size_t len) { |
| if (len < 12) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| // In the case of consecutive gamma tags, we need to count the number of bytes in the |
| // tag, so that we can move on to the next tag. |
| size_t tagBytes; |
| |
| uint32_t type = read_big_endian_u32(src); |
| // Bytes 4-7 are reserved and should be set to zero. |
| switch (type) { |
| case kTAG_CurveType: { |
| uint32_t count = read_big_endian_u32(src + 8); |
| |
| // tagBytes = 12 + 2 * count |
| // We need to do safe addition here to avoid integer overflow. |
| if (!safe_add(count, count, &tagBytes) || |
| !safe_add((size_t) 12, tagBytes, &tagBytes)) |
| { |
| SkColorSpacePrintf("Invalid gamma count"); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| if (len < tagBytes) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| *outTagBytes = tagBytes; |
| |
| if (0 == count) { |
| // Some tags require a gamma curve, but the author doesn't actually want |
| // to transform the data. In this case, it is common to see a curve with |
| // a count of 0. |
| outData->fNamed = kLinear_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| |
| const uint16_t* table = (const uint16_t*) (src + 12); |
| if (1 == count) { |
| // The table entry is the gamma (with a bias of 256). |
| float value = (read_big_endian_u16((const uint8_t*) table)) / 256.0f; |
| SkColorSpacePrintf("gamma %g\n", value); |
| |
| return set_gamma_value(outData, value); |
| } |
| |
| // Check for frequently occurring sRGB curves. |
| // We do this by sampling a few values and see if they match our expectation. |
| // A more robust solution would be to compare each value in this curve against |
| // an sRGB curve to see if we remain below an error threshold. At this time, |
| // we haven't seen any images in the wild that make this kind of |
| // calculation necessary. We encounter identical gamma curves over and |
| // over again, but relatively few variations. |
| if (1024 == count) { |
| // The magic values were chosen because they match both the very common |
| // HP sRGB gamma table and the less common Canon sRGB gamma table (which use |
| // different rounding rules). |
| if (0 == read_big_endian_u16((const uint8_t*) &table[0]) && |
| 3366 == read_big_endian_u16((const uint8_t*) &table[257]) && |
| 14116 == read_big_endian_u16((const uint8_t*) &table[513]) && |
| 34318 == read_big_endian_u16((const uint8_t*) &table[768]) && |
| 65535 == read_big_endian_u16((const uint8_t*) &table[1023])) { |
| outData->fNamed = kSRGB_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| } |
| |
| if (26 == count) { |
| // The magic values were chosen because they match a very common LCMS sRGB |
| // gamma table. |
| if (0 == read_big_endian_u16((const uint8_t*) &table[0]) && |
| 3062 == read_big_endian_u16((const uint8_t*) &table[6]) && |
| 12824 == read_big_endian_u16((const uint8_t*) &table[12]) && |
| 31237 == read_big_endian_u16((const uint8_t*) &table[18]) && |
| 65535 == read_big_endian_u16((const uint8_t*) &table[25])) { |
| outData->fNamed = kSRGB_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| } |
| |
| if (4096 == count) { |
| // The magic values were chosen because they match Nikon, Epson, and |
| // LCMS sRGB gamma tables (all of which use different rounding rules). |
| if (0 == read_big_endian_u16((const uint8_t*) &table[0]) && |
| 950 == read_big_endian_u16((const uint8_t*) &table[515]) && |
| 3342 == read_big_endian_u16((const uint8_t*) &table[1025]) && |
| 14079 == read_big_endian_u16((const uint8_t*) &table[2051]) && |
| 65535 == read_big_endian_u16((const uint8_t*) &table[4095])) { |
| outData->fNamed = kSRGB_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| } |
| |
| // Otherwise, we will represent gamma with a table. |
| outData->fTable.fSize = count; |
| return SkGammas::Type::kTable_Type; |
| } |
| case kTAG_ParaCurveType: { |
| enum ParaCurveType { |
| kExponential_ParaCurveType = 0, |
| kGAB_ParaCurveType = 1, |
| kGABC_ParaCurveType = 2, |
| kGABDE_ParaCurveType = 3, |
| kGABCDEF_ParaCurveType = 4, |
| }; |
| |
| // Determine the format of the parametric curve tag. |
| uint16_t format = read_big_endian_u16(src + 8); |
| if (format > kGABCDEF_ParaCurveType) { |
| SkColorSpacePrintf("Unsupported gamma tag type %d\n", type); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| if (kExponential_ParaCurveType == format) { |
| tagBytes = 12 + 4; |
| if (len < tagBytes) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| // Y = X^g |
| float g = read_big_endian_16_dot_16(src + 12); |
| |
| *outTagBytes = tagBytes; |
| return set_gamma_value(outData, g); |
| } |
| |
| // Here's where the real parametric gammas start. There are many |
| // permutations of the same equations. |
| // |
| // Y = (aX + b)^g + c for X >= d |
| // Y = eX + f otherwise |
| // |
| // We will fill in with zeros as necessary to always match the above form. |
| if (len < 24) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| float g = read_big_endian_16_dot_16(src + 12); |
| float a = read_big_endian_16_dot_16(src + 16); |
| float b = read_big_endian_16_dot_16(src + 20); |
| float c = 0.0f, d = 0.0f, e = 0.0f, f = 0.0f; |
| switch(format) { |
| case kGAB_ParaCurveType: |
| tagBytes = 12 + 12; |
| |
| // Y = (aX + b)^g for X >= -b/a |
| // Y = 0 otherwise |
| d = -b / a; |
| break; |
| case kGABC_ParaCurveType: |
| tagBytes = 12 + 16; |
| if (len < tagBytes) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| // Y = (aX + b)^g + c for X >= -b/a |
| // Y = c otherwise |
| c = read_big_endian_16_dot_16(src + 24); |
| d = -b / a; |
| f = c; |
| break; |
| case kGABDE_ParaCurveType: |
| tagBytes = 12 + 20; |
| if (len < tagBytes) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| // Y = (aX + b)^g for X >= d |
| // Y = eX otherwise |
| d = read_big_endian_16_dot_16(src + 28); |
| |
| // Not a bug! We define |e| to always be the coefficient on X in the |
| // second equation. The spec calls this |c| in this particular equation. |
| // We don't follow their convention because then |c| would have a |
| // different meaning in each of our cases. |
| e = read_big_endian_16_dot_16(src + 24); |
| break; |
| case kGABCDEF_ParaCurveType: |
| tagBytes = 12 + 28; |
| if (len < tagBytes) { |
| SkColorSpacePrintf("gamma tag is too small (%d bytes)", len); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| // Y = (aX + b)^g + c for X >= d |
| // Y = eX + f otherwise |
| // NOTE: The ICC spec writes "cX" in place of "eX" but I think |
| // it's a typo. |
| c = read_big_endian_16_dot_16(src + 24); |
| d = read_big_endian_16_dot_16(src + 28); |
| e = read_big_endian_16_dot_16(src + 32); |
| f = read_big_endian_16_dot_16(src + 36); |
| break; |
| default: |
| SkASSERT(false); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| // Recognize and simplify a very common parametric representation of sRGB gamma. |
| if (color_space_almost_equal(0.9479f, a) && |
| color_space_almost_equal(0.0521f, b) && |
| color_space_almost_equal(0.0000f, c) && |
| color_space_almost_equal(0.0405f, d) && |
| color_space_almost_equal(0.0774f, e) && |
| color_space_almost_equal(0.0000f, f) && |
| color_space_almost_equal(2.4000f, g)) { |
| outData->fNamed = kSRGB_SkGammaNamed; |
| return SkGammas::Type::kNamed_Type; |
| } |
| |
| // Fail on invalid gammas. |
| if (SkScalarIsNaN(d)) { |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| if (d <= 0.0f) { |
| // Y = (aX + b)^g + c for always |
| if (0.0f == a || 0.0f == g) { |
| SkColorSpacePrintf("A or G is zero, constant gamma function " |
| "is nonsense"); |
| return SkGammas::Type::kNone_Type; |
| } |
| } |
| |
| if (d >= 1.0f) { |
| // Y = eX + f for always |
| if (0.0f == e) { |
| SkColorSpacePrintf("E is zero, constant gamma function is " |
| "nonsense"); |
| return SkGammas::Type::kNone_Type; |
| } |
| } |
| |
| if ((0.0f == a || 0.0f == g) && 0.0f == e) { |
| SkColorSpacePrintf("A or G, and E are zero, constant gamma function " |
| "is nonsense"); |
| return SkGammas::Type::kNone_Type; |
| } |
| |
| *outTagBytes = tagBytes; |
| |
| outParams->fG = g; |
| outParams->fA = a; |
| outParams->fB = b; |
| outParams->fC = c; |
| outParams->fD = d; |
| outParams->fE = e; |
| outParams->fF = f; |
| return SkGammas::Type::kParam_Type; |
| } |
| default: |
| SkColorSpacePrintf("Unsupported gamma tag type %d\n", type); |
| return SkGammas::Type::kNone_Type; |
| } |
| } |
| |
| /** |
| * Returns the additional size in bytes needed to store the gamma tag. |
| */ |
| static size_t gamma_alloc_size(SkGammas::Type type, const SkGammas::Data& data) { |
| switch (type) { |
| case SkGammas::Type::kNamed_Type: |
| case SkGammas::Type::kValue_Type: |
| return 0; |
| case SkGammas::Type::kTable_Type: |
| return sizeof(float) * data.fTable.fSize; |
| case SkGammas::Type::kParam_Type: |
| return sizeof(SkGammas::Params); |
| default: |
| SkASSERT(false); |
| return 0; |
| } |
| } |
| |
| /** |
| * Sets invalid gamma to the default value. |
| */ |
| static void handle_invalid_gamma(SkGammas::Type* type, SkGammas::Data* data) { |
| if (SkGammas::Type::kNone_Type == *type) { |
| *type = SkGammas::Type::kNamed_Type; |
| |
| // Guess sRGB in the case of a malformed transfer function. |
| data->fNamed = kSRGB_SkGammaNamed; |
| } |
| } |
| |
| /** |
| * Finish loading the gammas, now that we have allocated memory for the SkGammas struct. |
| * |
| * There's nothing to do for the simple cases, but for table gammas we need to actually |
| * read the table into heap memory. And for parametric gammas, we need to copy over the |
| * parameter values. |
| * |
| * @param memory Pointer to start of the SkGammas memory block |
| * @param offset Bytes of memory (after the SkGammas struct) that are already in use. |
| * @param data In-out variable. Will fill in the offset to the table or parameters |
| * if necessary. |
| * @param params Parameters for gamma curve. Only initialized/used when we have a |
| * parametric gamma. |
| * @param src Pointer to start of the gamma tag. |
| * |
| * @return Additional bytes of memory that are being used by this gamma curve. |
| */ |
| static size_t load_gammas(void* memory, size_t offset, SkGammas::Type type, |
| SkGammas::Data* data, const SkGammas::Params& params, |
| const uint8_t* src) { |
| void* storage = SkTAddOffset<void>(memory, offset + sizeof(SkGammas)); |
| |
| switch (type) { |
| case SkGammas::Type::kNamed_Type: |
| case SkGammas::Type::kValue_Type: |
| // Nothing to do here. |
| return 0; |
| case SkGammas::Type::kTable_Type: { |
| data->fTable.fOffset = offset; |
| |
| float* outTable = (float*) storage; |
| const uint16_t* inTable = (const uint16_t*) (src + 12); |
| for (int i = 0; i < data->fTable.fSize; i++) { |
| outTable[i] = (read_big_endian_u16((const uint8_t*) &inTable[i])) / 65535.0f; |
| } |
| |
| return sizeof(float) * data->fTable.fSize; |
| } |
| case SkGammas::Type::kParam_Type: |
| data->fTable.fOffset = offset; |
| memcpy(storage, ¶ms, sizeof(SkGammas::Params)); |
| return sizeof(SkGammas::Params); |
| default: |
| SkASSERT(false); |
| return 0; |
| } |
| } |
| |
| static constexpr uint32_t kTAG_AtoBType = SkSetFourByteTag('m', 'A', 'B', ' '); |
| |
| static bool load_color_lut(sk_sp<SkColorLookUpTable>* colorLUT, uint32_t inputChannels, |
| const uint8_t* src, size_t len) { |
| // 16 bytes reserved for grid points, 2 for precision, 2 for padding. |
| // The color LUT data follows after this header. |
| static constexpr uint32_t kColorLUTHeaderSize = 20; |
| if (len < kColorLUTHeaderSize) { |
| SkColorSpacePrintf("Color LUT tag is too small (%d bytes).", len); |
| return false; |
| } |
| size_t dataLen = len - kColorLUTHeaderSize; |
| |
| SkASSERT(3 == inputChannels); |
| uint8_t gridPoints[3]; |
| uint32_t numEntries = 1; |
| for (uint32_t i = 0; i < inputChannels; i++) { |
| gridPoints[i] = src[i]; |
| if (0 == src[i]) { |
| SkColorSpacePrintf("Each input channel must have at least one grid point."); |
| return false; |
| } |
| |
| if (!safe_mul(numEntries, src[i], &numEntries)) { |
| SkColorSpacePrintf("Too many entries in Color LUT."); |
| return false; |
| } |
| } |
| |
| if (!safe_mul(numEntries, SkColorLookUpTable::kOutputChannels, &numEntries)) { |
| SkColorSpacePrintf("Too many entries in Color LUT."); |
| return false; |
| } |
| |
| // Space is provided for a maximum of the 16 input channels. Now we determine the precision |
| // of the table values. |
| uint8_t precision = src[16]; |
| switch (precision) { |
| case 1: // 8-bit data |
| case 2: // 16-bit data |
| break; |
| default: |
| SkColorSpacePrintf("Color LUT precision must be 8-bit or 16-bit.\n"); |
| return false; |
| } |
| |
| uint32_t clutBytes; |
| if (!safe_mul(numEntries, precision, &clutBytes)) { |
| SkColorSpacePrintf("Too many entries in Color LUT."); |
| return false; |
| } |
| |
| if (dataLen < clutBytes) { |
| SkColorSpacePrintf("Color LUT tag is too small (%d bytes).", len); |
| return false; |
| } |
| |
| // Movable struct colorLUT has ownership of fTable. |
| void* memory = sk_malloc_throw(sizeof(SkColorLookUpTable) + sizeof(float) * numEntries); |
| *colorLUT = sk_sp<SkColorLookUpTable>(new (memory) SkColorLookUpTable(inputChannels, |
| gridPoints)); |
| |
| float* table = SkTAddOffset<float>(memory, sizeof(SkColorLookUpTable)); |
| const uint8_t* ptr = src + kColorLUTHeaderSize; |
| for (uint32_t i = 0; i < numEntries; i++, ptr += precision) { |
| if (1 == precision) { |
| table[i] = ((float) ptr[i]) / 255.0f; |
| } else { |
| table[i] = ((float) read_big_endian_u16(ptr)) / 65535.0f; |
| } |
| } |
| |
| return true; |
| } |
| |
| static bool load_matrix(SkMatrix44* toXYZ, const uint8_t* src, size_t len) { |
| if (len < 48) { |
| SkColorSpacePrintf("Matrix tag is too small (%d bytes).", len); |
| return false; |
| } |
| |
| // For this matrix to behave like our "to XYZ D50" matrices, it needs to be scaled. |
| constexpr float scale = 65535.0 / 32768.0; |
| float array[16]; |
| array[ 0] = scale * SkFixedToFloat(read_big_endian_i32(src)); |
| array[ 1] = scale * SkFixedToFloat(read_big_endian_i32(src + 4)); |
| array[ 2] = scale * SkFixedToFloat(read_big_endian_i32(src + 8)); |
| array[ 3] = scale * SkFixedToFloat(read_big_endian_i32(src + 36)); // translate R |
| array[ 4] = scale * SkFixedToFloat(read_big_endian_i32(src + 12)); |
| array[ 5] = scale * SkFixedToFloat(read_big_endian_i32(src + 16)); |
| array[ 6] = scale * SkFixedToFloat(read_big_endian_i32(src + 20)); |
| array[ 7] = scale * SkFixedToFloat(read_big_endian_i32(src + 40)); // translate G |
| array[ 8] = scale * SkFixedToFloat(read_big_endian_i32(src + 24)); |
| array[ 9] = scale * SkFixedToFloat(read_big_endian_i32(src + 28)); |
| array[10] = scale * SkFixedToFloat(read_big_endian_i32(src + 32)); |
| array[11] = scale * SkFixedToFloat(read_big_endian_i32(src + 44)); // translate B |
| array[12] = 0.0f; |
| array[13] = 0.0f; |
| array[14] = 0.0f; |
| array[15] = 1.0f; |
| toXYZ->setRowMajorf(array); |
| return true; |
| } |
| |
| static inline SkGammaNamed is_named(const sk_sp<SkGammas>& gammas) { |
| if (gammas->isNamed(0) && gammas->isNamed(1) && gammas->isNamed(2) && |
| gammas->fRedData.fNamed == gammas->fGreenData.fNamed && |
| gammas->fRedData.fNamed == gammas->fBlueData.fNamed) |
| { |
| return gammas->fRedData.fNamed; |
| } |
| |
| return kNonStandard_SkGammaNamed; |
| } |
| |
| |
| static bool load_a2b0(sk_sp<SkColorLookUpTable>* colorLUT, SkGammaNamed* gammaNamed, |
| sk_sp<SkGammas>* gammas, SkMatrix44* toXYZ, const uint8_t* src, size_t len) { |
| if (len < 32) { |
| SkColorSpacePrintf("A to B tag is too small (%d bytes).", len); |
| return false; |
| } |
| |
| uint32_t type = read_big_endian_u32(src); |
| if (kTAG_AtoBType != type) { |
| // FIXME (msarett): Need to support lut8Type and lut16Type. |
| SkColorSpacePrintf("Unsupported A to B tag type.\n"); |
| return false; |
| } |
| |
| // Read the number of channels. The four bytes that we skipped are reserved and |
| // must be zero. |
| uint8_t inputChannels = src[8]; |
| uint8_t outputChannels = src[9]; |
| if (3 != inputChannels || SkColorLookUpTable::kOutputChannels != outputChannels) { |
| // We only handle (supposedly) RGB inputs and RGB outputs. The numbers of input |
| // channels and output channels both must be 3. |
| // TODO (msarett): |
| // Support different numbers of input channels. Ex: CMYK (4). |
| SkColorSpacePrintf("Input and output channels must equal 3 in A to B tag.\n"); |
| return false; |
| } |
| |
| // Read the offsets of each element in the A to B tag. With the exception of A curves and |
| // B curves (which we do not yet support), we will handle these elements in the order in |
| // which they should be applied (rather than the order in which they occur in the tag). |
| // If the offset is non-zero it indicates that the element is present. |
| uint32_t offsetToACurves = read_big_endian_i32(src + 28); |
| uint32_t offsetToBCurves = read_big_endian_i32(src + 12); |
| if ((0 != offsetToACurves) || (0 != offsetToBCurves)) { |
| // FIXME (msarett): Handle A and B curves. |
| // Note that the A curve is technically required in order to have a color LUT. |
| // However, all the A curves I have seen so far have are just placeholders that |
| // don't actually transform the data. |
| SkColorSpacePrintf("Ignoring A and/or B curve. Output may be wrong.\n"); |
| } |
| |
| uint32_t offsetToColorLUT = read_big_endian_i32(src + 24); |
| if (0 != offsetToColorLUT && offsetToColorLUT < len) { |
| if (!load_color_lut(colorLUT, inputChannels, src + offsetToColorLUT, |
| len - offsetToColorLUT)) { |
| SkColorSpacePrintf("Failed to read color LUT from A to B tag.\n"); |
| } |
| } |
| |
| uint32_t offsetToMCurves = read_big_endian_i32(src + 20); |
| if (0 != offsetToMCurves && offsetToMCurves < len) { |
| const uint8_t* rTagPtr = src + offsetToMCurves; |
| size_t tagLen = len - offsetToMCurves; |
| |
| SkGammas::Data rData; |
| SkGammas::Params rParams; |
| |
| // On an invalid first gamma, tagBytes remains set as zero. This causes the two |
| // subsequent to be treated as identical (which is what we want). |
| size_t tagBytes = 0; |
| SkGammas::Type rType = parse_gamma(&rData, &rParams, &tagBytes, rTagPtr, tagLen); |
| handle_invalid_gamma(&rType, &rData); |
| size_t alignedTagBytes = SkAlign4(tagBytes); |
| |
| if ((3 * alignedTagBytes <= tagLen) && |
| !memcmp(rTagPtr, rTagPtr + 1 * alignedTagBytes, tagBytes) && |
| !memcmp(rTagPtr, rTagPtr + 2 * alignedTagBytes, tagBytes)) |
| { |
| if (SkGammas::Type::kNamed_Type == rType) { |
| *gammaNamed = rData.fNamed; |
| } else { |
| size_t allocSize = sizeof(SkGammas); |
| return_if_false(safe_add(allocSize, gamma_alloc_size(rType, rData), &allocSize), |
| "SkGammas struct is too large to allocate"); |
| void* memory = sk_malloc_throw(allocSize); |
| *gammas = sk_sp<SkGammas>(new (memory) SkGammas()); |
| load_gammas(memory, 0, rType, &rData, rParams, rTagPtr); |
| |
| (*gammas)->fRedType = rType; |
| (*gammas)->fGreenType = rType; |
| (*gammas)->fBlueType = rType; |
| |
| (*gammas)->fRedData = rData; |
| (*gammas)->fGreenData = rData; |
| (*gammas)->fBlueData = rData; |
| } |
| } else { |
| const uint8_t* gTagPtr = rTagPtr + alignedTagBytes; |
| tagLen = tagLen > alignedTagBytes ? tagLen - alignedTagBytes : 0; |
| SkGammas::Data gData; |
| SkGammas::Params gParams; |
| tagBytes = 0; |
| SkGammas::Type gType = parse_gamma(&gData, &gParams, &tagBytes, gTagPtr, |
| tagLen); |
| handle_invalid_gamma(&gType, &gData); |
| |
| alignedTagBytes = SkAlign4(tagBytes); |
| const uint8_t* bTagPtr = gTagPtr + alignedTagBytes; |
| tagLen = tagLen > alignedTagBytes ? tagLen - alignedTagBytes : 0; |
| SkGammas::Data bData; |
| SkGammas::Params bParams; |
| SkGammas::Type bType = parse_gamma(&bData, &bParams, &tagBytes, bTagPtr, |
| tagLen); |
| handle_invalid_gamma(&bType, &bData); |
| |
| size_t allocSize = sizeof(SkGammas); |
| return_if_false(safe_add(allocSize, gamma_alloc_size(rType, rData), &allocSize), |
| "SkGammas struct is too large to allocate"); |
| return_if_false(safe_add(allocSize, gamma_alloc_size(gType, gData), &allocSize), |
| "SkGammas struct is too large to allocate"); |
| return_if_false(safe_add(allocSize, gamma_alloc_size(bType, bData), &allocSize), |
| "SkGammas struct is too large to allocate"); |
| void* memory = sk_malloc_throw(allocSize); |
| *gammas = sk_sp<SkGammas>(new (memory) SkGammas()); |
| |
| uint32_t offset = 0; |
| (*gammas)->fRedType = rType; |
| offset += load_gammas(memory, offset, rType, &rData, rParams, rTagPtr); |
| |
| (*gammas)->fGreenType = gType; |
| offset += load_gammas(memory, offset, gType, &gData, gParams, gTagPtr); |
| |
| (*gammas)->fBlueType = bType; |
| load_gammas(memory, offset, bType, &bData, bParams, bTagPtr); |
| |
| (*gammas)->fRedData = rData; |
| (*gammas)->fGreenData = gData; |
| (*gammas)->fBlueData = bData; |
| } |
| } else { |
| // Guess sRGB if the chunk is missing a transfer function. |
| *gammaNamed = kSRGB_SkGammaNamed; |
| } |
| |
| if (kNonStandard_SkGammaNamed == *gammaNamed) { |
| *gammaNamed = is_named(*gammas); |
| if (kNonStandard_SkGammaNamed != *gammaNamed) { |
| // No need to keep the gammas struct, the enum is enough. |
| *gammas = nullptr; |
| } |
| } |
| |
| uint32_t offsetToMatrix = read_big_endian_i32(src + 16); |
| if (0 != offsetToMatrix && offsetToMatrix < len) { |
| if (!load_matrix(toXYZ, src + offsetToMatrix, len - offsetToMatrix)) { |
| SkColorSpacePrintf("Failed to read matrix from A to B tag.\n"); |
| toXYZ->setIdentity(); |
| } |
| } |
| |
| return true; |
| } |
| |
| static bool tag_equals(const ICCTag* a, const ICCTag* b, const uint8_t* base) { |
| if (!a || !b) { |
| return a == b; |
| } |
| |
| if (a->fLength != b->fLength) { |
| return false; |
| } |
| |
| if (a->fOffset == b->fOffset) { |
| return true; |
| } |
| |
| return !memcmp(a->addr(base), b->addr(base), a->fLength); |
| } |
| |
| sk_sp<SkColorSpace> SkColorSpace::NewICC(const void* input, size_t len) { |
| if (!input || len < kICCHeaderSize) { |
| return_null("Data is null or not large enough to contain an ICC profile"); |
| } |
| |
| // Create our own copy of the input. |
| void* memory = sk_malloc_throw(len); |
| memcpy(memory, input, len); |
| sk_sp<SkData> data = SkData::MakeFromMalloc(memory, len); |
| const uint8_t* base = data->bytes(); |
| const uint8_t* ptr = base; |
| |
| // Read the ICC profile header and check to make sure that it is valid. |
| ICCProfileHeader header; |
| header.init(ptr, len); |
| if (!header.valid()) { |
| return nullptr; |
| } |
| |
| // Adjust ptr and len before reading the tags. |
| if (len < header.fSize) { |
| SkColorSpacePrintf("ICC profile might be truncated.\n"); |
| } else if (len > header.fSize) { |
| SkColorSpacePrintf("Caller provided extra data beyond the end of the ICC profile.\n"); |
| len = header.fSize; |
| } |
| ptr += kICCHeaderSize; |
| len -= kICCHeaderSize; |
| |
| // Parse tag headers. |
| uint32_t tagCount = header.fTagCount; |
| SkColorSpacePrintf("ICC profile contains %d tags.\n", tagCount); |
| if (len < kICCTagTableEntrySize * tagCount) { |
| return_null("Not enough input data to read tag table entries"); |
| } |
| |
| SkAutoTArray<ICCTag> tags(tagCount); |
| for (uint32_t i = 0; i < tagCount; i++) { |
| ptr = tags[i].init(ptr); |
| SkColorSpacePrintf("[%d] %c%c%c%c %d %d\n", i, (tags[i].fSignature >> 24) & 0xFF, |
| (tags[i].fSignature >> 16) & 0xFF, (tags[i].fSignature >> 8) & 0xFF, |
| (tags[i].fSignature >> 0) & 0xFF, tags[i].fOffset, tags[i].fLength); |
| |
| if (!tags[i].valid(kICCHeaderSize + len)) { |
| return_null("Tag is too large to fit in ICC profile"); |
| } |
| } |
| |
| switch (header.fInputColorSpace) { |
| case kRGB_ColorSpace: { |
| // Recognize the rXYZ, gXYZ, and bXYZ tags. |
| const ICCTag* r = ICCTag::Find(tags.get(), tagCount, kTAG_rXYZ); |
| const ICCTag* g = ICCTag::Find(tags.get(), tagCount, kTAG_gXYZ); |
| const ICCTag* b = ICCTag::Find(tags.get(), tagCount, kTAG_bXYZ); |
| if (r && g && b) { |
| float toXYZ[9]; |
| if (!load_xyz(&toXYZ[0], r->addr(base), r->fLength) || |
| !load_xyz(&toXYZ[3], g->addr(base), g->fLength) || |
| !load_xyz(&toXYZ[6], b->addr(base), b->fLength)) |
| { |
| return_null("Need valid rgb tags for XYZ space"); |
| } |
| SkMatrix44 mat(SkMatrix44::kUninitialized_Constructor); |
| mat.set3x3(toXYZ[0], toXYZ[1], toXYZ[2], |
| toXYZ[3], toXYZ[4], toXYZ[5], |
| toXYZ[6], toXYZ[7], toXYZ[8]); |
| |
| r = ICCTag::Find(tags.get(), tagCount, kTAG_rTRC); |
| g = ICCTag::Find(tags.get(), tagCount, kTAG_gTRC); |
| b = ICCTag::Find(tags.get(), tagCount, kTAG_bTRC); |
| |
| // If some, but not all, of the gamma tags are missing, assume that all |
| // gammas are meant to be the same. This behavior is an arbitrary guess, |
| // but it simplifies the code below. |
| if ((!r || !g || !b) && (r || g || b)) { |
| if (!r) { |
| r = g ? g : b; |
| } |
| |
| if (!g) { |
| g = r ? r : b; |
| } |
| |
| if (!b) { |
| b = r ? r : g; |
| } |
| } |
| |
| SkGammaNamed gammaNamed = kNonStandard_SkGammaNamed; |
| sk_sp<SkGammas> gammas = nullptr; |
| size_t tagBytes; |
| if (r && g && b) { |
| if (tag_equals(r, g, base) && tag_equals(g, b, base)) { |
| SkGammas::Data data; |
| SkGammas::Params params; |
| SkGammas::Type type = |
| parse_gamma(&data, ¶ms, &tagBytes, r->addr(base), r->fLength); |
| handle_invalid_gamma(&type, &data); |
| |
| if (SkGammas::Type::kNamed_Type == type) { |
| gammaNamed = data.fNamed; |
| } else { |
| size_t allocSize = sizeof(SkGammas); |
| if (!safe_add(allocSize, gamma_alloc_size(type, data), &allocSize)) { |
| return_null("SkGammas struct is too large to allocate"); |
| } |
| void* memory = sk_malloc_throw(allocSize); |
| gammas = sk_sp<SkGammas>(new (memory) SkGammas()); |
| load_gammas(memory, 0, type, &data, params, r->addr(base)); |
| |
| gammas->fRedType = type; |
| gammas->fGreenType = type; |
| gammas->fBlueType = type; |
| |
| gammas->fRedData = data; |
| gammas->fGreenData = data; |
| gammas->fBlueData = data; |
| } |
| } else { |
| SkGammas::Data rData; |
| SkGammas::Params rParams; |
| SkGammas::Type rType = |
| parse_gamma(&rData, &rParams, &tagBytes, r->addr(base), r->fLength); |
| handle_invalid_gamma(&rType, &rData); |
| |
| SkGammas::Data gData; |
| SkGammas::Params gParams; |
| SkGammas::Type gType = |
| parse_gamma(&gData, &gParams, &tagBytes, g->addr(base), g->fLength); |
| handle_invalid_gamma(&gType, &gData); |
| |
| SkGammas::Data bData; |
| SkGammas::Params bParams; |
| SkGammas::Type bType = |
| parse_gamma(&bData, &bParams, &tagBytes, b->addr(base), b->fLength); |
| handle_invalid_gamma(&bType, &bData); |
| |
| size_t allocSize = sizeof(SkGammas); |
| if (!safe_add(allocSize, gamma_alloc_size(rType, rData), &allocSize) || |
| !safe_add(allocSize, gamma_alloc_size(gType, gData), &allocSize) || |
| !safe_add(allocSize, gamma_alloc_size(bType, bData), &allocSize)) |
| { |
| return_null("SkGammas struct is too large to allocate"); |
| } |
| void* memory = sk_malloc_throw(allocSize); |
| gammas = sk_sp<SkGammas>(new (memory) SkGammas()); |
| |
| uint32_t offset = 0; |
| gammas->fRedType = rType; |
| offset += load_gammas(memory, offset, rType, &rData, rParams, |
| r->addr(base)); |
| |
| gammas->fGreenType = gType; |
| offset += load_gammas(memory, offset, gType, &gData, gParams, |
| g->addr(base)); |
| |
| gammas->fBlueType = bType; |
| load_gammas(memory, offset, bType, &bData, bParams, b->addr(base)); |
| |
| gammas->fRedData = rData; |
| gammas->fGreenData = gData; |
| gammas->fBlueData = bData; |
| } |
| } else { |
| // Guess sRGB if the profile is missing transfer functions. |
| gammaNamed = kSRGB_SkGammaNamed; |
| } |
| |
| if (kNonStandard_SkGammaNamed == gammaNamed) { |
| // It's possible that we'll initially detect non-matching gammas, only for |
| // them to evaluate to the same named gamma curve. |
| gammaNamed = is_named(gammas); |
| if (kNonStandard_SkGammaNamed == gammaNamed) { |
| return sk_sp<SkColorSpace>(new SkColorSpace_Base(nullptr, gammaNamed, |
| std::move(gammas), mat, |
| std::move(data))); |
| } |
| } |
| |
| return SkColorSpace_Base::NewRGB(gammaNamed, mat); |
| } |
| |
| // Recognize color profile specified by A2B0 tag. |
| const ICCTag* a2b0 = ICCTag::Find(tags.get(), tagCount, kTAG_A2B0); |
| if (a2b0) { |
| SkGammaNamed gammaNamed = kNonStandard_SkGammaNamed; |
| sk_sp<SkGammas> gammas = nullptr; |
| sk_sp<SkColorLookUpTable> colorLUT = nullptr; |
| SkMatrix44 toXYZ(SkMatrix44::kUninitialized_Constructor); |
| if (!load_a2b0(&colorLUT, &gammaNamed, &gammas, &toXYZ, a2b0->addr(base), |
| a2b0->fLength)) { |
| return_null("Failed to parse A2B0 tag"); |
| } |
| |
| if (colorLUT || kNonStandard_SkGammaNamed == gammaNamed) { |
| return sk_sp<SkColorSpace>(new SkColorSpace_Base(std::move(colorLUT), |
| gammaNamed, std::move(gammas), |
| toXYZ, std::move(data))); |
| } |
| |
| return SkColorSpace_Base::NewRGB(gammaNamed, toXYZ); |
| } |
| } |
| default: |
| break; |
| } |
| |
| return_null("ICC profile contains unsupported colorspace"); |
| } |
| |
| /////////////////////////////////////////////////////////////////////////////////////////////////// |
| |
| // 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 = 12; |
| 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 = 14; |
| static constexpr uint32_t kTAG_rTRC_Offset = kTAG_bXYZ_Offset + kTAG_XYZ_Bytes; |
| static constexpr uint32_t kTAG_gTRC_Offset = kTAG_rTRC_Offset + SkAlign4(kTAG_TRC_Bytes); |
| static constexpr uint32_t kTAG_bTRC_Offset = kTAG_gTRC_Offset + SkAlign4(kTAG_TRC_Bytes); |
| |
| static constexpr uint32_t kTAG_wtpt = SkSetFourByteTag('w', 't', 'p', 't'); |
| static constexpr uint32_t kTAG_wtpt_Offset = kTAG_bTRC_Offset + SkAlign4(kTAG_TRC_Bytes); |
| |
| static constexpr uint32_t kTAG_cprt = SkSetFourByteTag('c', 'p', 'r', 't'); |
| static constexpr uint32_t kTAG_cprt_Bytes = 12; |
| 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 gICCHeader[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 gICCTagTable[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), |
| }; |
| |
| static constexpr uint32_t kTAG_TextType = SkSetFourByteTag('m', 'l', 'u', 'c'); |
| static constexpr uint32_t gEmptyTextTag[3] { |
| SkEndian_SwapBE32(kTAG_TextType), // Type signature |
| 0, // Reserved |
| 0, // Zero records |
| }; |
| |
| 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(SkFloatToFixed(toXYZ.getFloat(0, col))); |
| ptr[3] = SkEndian_SwapBE32(SkFloatToFixed(toXYZ.getFloat(1, col))); |
| ptr[4] = SkEndian_SwapBE32(SkFloatToFixed(toXYZ.getFloat(2, col))); |
| } |
| |
| static void write_trc_tag(uint32_t* ptr, float value) { |
| ptr[0] = SkEndian_SwapBE32(kTAG_CurveType); |
| ptr[1] = 0; |
| |
| // Gamma will be specified with a single value. |
| ptr[2] = SkEndian_SwapBE32(1); |
| |
| // Convert gamma to 16-bit fixed point. |
| uint16_t* ptr16 = (uint16_t*) (ptr + 3); |
| ptr16[0] = SkEndian_SwapBE16((uint16_t) (value * 256.0f)); |
| |
| // Pad tag with zero. |
| ptr16[1] = 0; |
| } |
| |
| sk_sp<SkData> SkColorSpace_Base::writeToICC() const { |
| // Return if this object was created from a profile, or if we have already serialized |
| // the profile. |
| if (fProfileData) { |
| return fProfileData; |
| } |
| |
| // The client may create an SkColorSpace using an SkMatrix44, but currently we only |
| // support writing profiles with 3x3 matrices. |
| // TODO (msarett): Fix this! |
| if (0.0f != fToXYZD50.getFloat(3, 0) || 0.0f != fToXYZD50.getFloat(3, 1) || |
| 0.0f != fToXYZD50.getFloat(3, 2) || 0.0f != fToXYZD50.getFloat(0, 3) || |
| 0.0f != fToXYZD50.getFloat(1, 3) || 0.0f != fToXYZD50.getFloat(2, 3)) |
| { |
| return nullptr; |
| } |
| |
| SkAutoMalloc profile(kICCProfileSize); |
| uint8_t* ptr = (uint8_t*) profile.get(); |
| |
| // Write profile header |
| memcpy(ptr, gICCHeader, sizeof(gICCHeader)); |
| ptr += sizeof(gICCHeader); |
| |
| // Write tag table |
| memcpy(ptr, gICCTagTable, sizeof(gICCTagTable)); |
| ptr += sizeof(gICCTagTable); |
| |
| // Write profile description tag |
| memcpy(ptr, gEmptyTextTag, sizeof(gEmptyTextTag)); |
| ptr += sizeof(gEmptyTextTag); |
| |
| // Write XYZ tags |
| write_xyz_tag((uint32_t*) ptr, fToXYZD50, 0); |
| ptr += kTAG_XYZ_Bytes; |
| write_xyz_tag((uint32_t*) ptr, fToXYZD50, 1); |
| ptr += kTAG_XYZ_Bytes; |
| write_xyz_tag((uint32_t*) ptr, fToXYZD50, 2); |
| ptr += kTAG_XYZ_Bytes; |
| |
| // Write TRC tags |
| SkGammaNamed gammaNamed = this->gammaNamed(); |
| if (kNonStandard_SkGammaNamed == gammaNamed) { |
| // FIXME (msarett): |
| // Write the correct gamma representation rather than 2.2f. |
| write_trc_tag((uint32_t*) ptr, 2.2f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| write_trc_tag((uint32_t*) ptr, 2.2f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| write_trc_tag((uint32_t*) ptr, 2.2f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| } else { |
| switch (gammaNamed) { |
| case kSRGB_SkGammaNamed: |
| // FIXME (msarett): |
| // kSRGB cannot be represented by a value. Here we fall through to 2.2f, |
| // which is a close guess. To be more accurate, we need to represent sRGB |
| // gamma with a parametric curve. |
| case k2Dot2Curve_SkGammaNamed: |
| write_trc_tag((uint32_t*) ptr, 2.2f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| write_trc_tag((uint32_t*) ptr, 2.2f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| write_trc_tag((uint32_t*) ptr, 2.2f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| break; |
| case kLinear_SkGammaNamed: |
| write_trc_tag((uint32_t*) ptr, 1.0f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| write_trc_tag((uint32_t*) ptr, 1.0f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| write_trc_tag((uint32_t*) ptr, 1.0f); |
| ptr += SkAlign4(kTAG_TRC_Bytes); |
| break; |
| default: |
| SkASSERT(false); |
| break; |
| } |
| } |
| |
| // Write white point tag |
| uint32_t* ptr32 = (uint32_t*) ptr; |
| ptr32[0] = SkEndian_SwapBE32(kXYZ_PCSSpace); |
| ptr32[1] = 0; |
| // TODO (msarett): These values correspond to the D65 white point. This may not always be |
| // correct. |
| ptr32[2] = SkEndian_SwapBE32(0x0000f351); |
| ptr32[3] = SkEndian_SwapBE32(0x00010000); |
| ptr32[4] = SkEndian_SwapBE32(0x000116cc); |
| ptr += kTAG_XYZ_Bytes; |
| |
| // Write copyright tag |
| memcpy(ptr, gEmptyTextTag, sizeof(gEmptyTextTag)); |
| |
| // TODO (msarett): Should we try to hold onto the data so we can return immediately if |
| // the client calls again? |
| return SkData::MakeFromMalloc(profile.release(), kICCProfileSize); |
| } |