/* * Copyright 2015 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef SkCodec_DEFINED #define SkCodec_DEFINED #include "include/codec/SkCodecAnimation.h" #include "include/codec/SkEncodedOrigin.h" #include "include/core/SkColor.h" #include "include/core/SkEncodedImageFormat.h" #include "include/core/SkImageInfo.h" #include "include/core/SkPixmap.h" #include "include/core/SkSize.h" #include "include/core/SkStream.h" #include "include/core/SkTypes.h" #include "include/core/SkYUVAPixmaps.h" #include "include/private/SkEncodedInfo.h" #include "include/private/SkNoncopyable.h" #include "include/private/SkTemplates.h" #include class SkAndroidCodec; class SkColorSpace; class SkData; class SkFrameHolder; class SkImage; class SkPngChunkReader; class SkSampler; namespace DM { class CodecSrc; class ColorCodecSrc; } // namespace DM /** * Abstraction layer directly on top of an image codec. */ class SK_API SkCodec : SkNoncopyable { public: /** * Minimum number of bytes that must be buffered in SkStream input. * * An SkStream passed to NewFromStream must be able to use this many * bytes to determine the image type. Then the same SkStream must be * passed to the correct decoder to read from the beginning. * * This can be accomplished by implementing peek() to support peeking * this many bytes, or by implementing rewind() to be able to rewind() * after reading this many bytes. */ static constexpr size_t MinBufferedBytesNeeded() { return 32; } /** * Error codes for various SkCodec methods. */ enum Result { /** * General return value for success. */ kSuccess, /** * The input is incomplete. A partial image was generated. */ kIncompleteInput, /** * Like kIncompleteInput, except the input had an error. * * If returned from an incremental decode, decoding cannot continue, * even with more data. */ kErrorInInput, /** * The generator cannot convert to match the request, ignoring * dimensions. */ kInvalidConversion, /** * The generator cannot scale to requested size. */ kInvalidScale, /** * Parameters (besides info) are invalid. e.g. NULL pixels, rowBytes * too small, etc. */ kInvalidParameters, /** * The input did not contain a valid image. */ kInvalidInput, /** * Fulfilling this request requires rewinding the input, which is not * supported for this input. */ kCouldNotRewind, /** * An internal error, such as OOM. */ kInternalError, /** * This method is not implemented by this codec. * FIXME: Perhaps this should be kUnsupported? */ kUnimplemented, }; /** * Readable string representing the error code. */ static const char* ResultToString(Result); /** * For container formats that contain both still images and image sequences, * instruct the decoder how the output should be selected. (Refer to comments * for each value for more details.) */ enum class SelectionPolicy { /** * If the container format contains both still images and image sequences, * SkCodec should choose one of the still images. This is the default. */ kPreferStillImage, /** * If the container format contains both still images and image sequences, * SkCodec should choose one of the image sequences for animation. */ kPreferAnimation, }; /** * If this stream represents an encoded image that we know how to decode, * return an SkCodec that can decode it. Otherwise return NULL. * * As stated above, this call must be able to peek or read * MinBufferedBytesNeeded to determine the correct format, and then start * reading from the beginning. First it will attempt to peek, and it * assumes that if less than MinBufferedBytesNeeded bytes (but more than * zero) are returned, this is because the stream is shorter than this, * so falling back to reading would not provide more data. If peek() * returns zero bytes, this call will instead attempt to read(). This * will require that the stream can be rewind()ed. * * If Result is not NULL, it will be set to either kSuccess if an SkCodec * is returned or a reason for the failure if NULL is returned. * * If SkPngChunkReader is not NULL, take a ref and pass it to libpng if * the image is a png. * * If the SkPngChunkReader is not NULL then: * If the image is not a PNG, the SkPngChunkReader will be ignored. * If the image is a PNG, the SkPngChunkReader will be reffed. * If the PNG has unknown chunks, the SkPngChunkReader will be used * to handle these chunks. SkPngChunkReader will be called to read * any unknown chunk at any point during the creation of the codec * or the decode. Note that if SkPngChunkReader fails to read a * chunk, this could result in a failure to create the codec or a * failure to decode the image. * If the PNG does not contain unknown chunks, the SkPngChunkReader * will not be used or modified. * * If NULL is returned, the stream is deleted immediately. Otherwise, the * SkCodec takes ownership of it, and will delete it when done with it. */ static std::unique_ptr MakeFromStream( std::unique_ptr, Result* = nullptr, SkPngChunkReader* = nullptr, SelectionPolicy selectionPolicy = SelectionPolicy::kPreferStillImage); /** * If this data represents an encoded image that we know how to decode, * return an SkCodec that can decode it. Otherwise return NULL. * * If the SkPngChunkReader is not NULL then: * If the image is not a PNG, the SkPngChunkReader will be ignored. * If the image is a PNG, the SkPngChunkReader will be reffed. * If the PNG has unknown chunks, the SkPngChunkReader will be used * to handle these chunks. SkPngChunkReader will be called to read * any unknown chunk at any point during the creation of the codec * or the decode. Note that if SkPngChunkReader fails to read a * chunk, this could result in a failure to create the codec or a * failure to decode the image. * If the PNG does not contain unknown chunks, the SkPngChunkReader * will not be used or modified. */ static std::unique_ptr MakeFromData(sk_sp, SkPngChunkReader* = nullptr); virtual ~SkCodec(); /** * Return a reasonable SkImageInfo to decode into. * * If the image has an ICC profile that does not map to an SkColorSpace, * the returned SkImageInfo will use SRGB. */ SkImageInfo getInfo() const { return fEncodedInfo.makeImageInfo(); } SkISize dimensions() const { return {fEncodedInfo.width(), fEncodedInfo.height()}; } SkIRect bounds() const { return SkIRect::MakeWH(fEncodedInfo.width(), fEncodedInfo.height()); } /** * Return the ICC profile of the encoded data. */ const skcms_ICCProfile* getICCProfile() const { return this->getEncodedInfo().profile(); } /** * Returns the image orientation stored in the EXIF data. * If there is no EXIF data, or if we cannot read the EXIF data, returns kTopLeft. */ SkEncodedOrigin getOrigin() const { return fOrigin; } /** * Return a size that approximately supports the desired scale factor. * The codec may not be able to scale efficiently to the exact scale * factor requested, so return a size that approximates that scale. * The returned value is the codec's suggestion for the closest valid * scale that it can natively support */ SkISize getScaledDimensions(float desiredScale) const { // Negative and zero scales are errors. SkASSERT(desiredScale > 0.0f); if (desiredScale <= 0.0f) { return SkISize::Make(0, 0); } // Upscaling is not supported. Return the original size if the client // requests an upscale. if (desiredScale >= 1.0f) { return this->dimensions(); } return this->onGetScaledDimensions(desiredScale); } /** * Return (via desiredSubset) a subset which can decoded from this codec, * or false if this codec cannot decode subsets or anything similar to * desiredSubset. * * @param desiredSubset In/out parameter. As input, a desired subset of * the original bounds (as specified by getInfo). If true is returned, * desiredSubset may have been modified to a subset which is * supported. Although a particular change may have been made to * desiredSubset to create something supported, it is possible other * changes could result in a valid subset. * If false is returned, desiredSubset's value is undefined. * @return true if this codec supports decoding desiredSubset (as * returned, potentially modified) */ bool getValidSubset(SkIRect* desiredSubset) const { return this->onGetValidSubset(desiredSubset); } /** * Format of the encoded data. */ SkEncodedImageFormat getEncodedFormat() const { return this->onGetEncodedFormat(); } /** * Whether or not the memory passed to getPixels is zero initialized. */ enum ZeroInitialized { /** * The memory passed to getPixels is zero initialized. The SkCodec * may take advantage of this by skipping writing zeroes. */ kYes_ZeroInitialized, /** * The memory passed to getPixels has not been initialized to zero, * so the SkCodec must write all zeroes to memory. * * This is the default. It will be used if no Options struct is used. */ kNo_ZeroInitialized, }; /** * Additional options to pass to getPixels. */ struct Options { Options() : fZeroInitialized(kNo_ZeroInitialized) , fSubset(nullptr) , fFrameIndex(0) , fPriorFrame(kNoFrame) {} ZeroInitialized fZeroInitialized; /** * If not NULL, represents a subset of the original image to decode. * Must be within the bounds returned by getInfo(). * If the EncodedFormat is SkEncodedImageFormat::kWEBP (the only one which * currently supports subsets), the top and left values must be even. * * In getPixels and incremental decode, we will attempt to decode the * exact rectangular subset specified by fSubset. * * In a scanline decode, it does not make sense to specify a subset * top or subset height, since the client already controls which rows * to get and which rows to skip. During scanline decodes, we will * require that the subset top be zero and the subset height be equal * to the full height. We will, however, use the values of * subset left and subset width to decode partial scanlines on calls * to getScanlines(). */ const SkIRect* fSubset; /** * The frame to decode. * * Only meaningful for multi-frame images. */ int fFrameIndex; /** * If not kNoFrame, the dst already contains the prior frame at this index. * * Only meaningful for multi-frame images. * * If fFrameIndex needs to be blended with a prior frame (as reported by * getFrameInfo[fFrameIndex].fRequiredFrame), the client can set this to * any non-kRestorePrevious frame in [fRequiredFrame, fFrameIndex) to * indicate that that frame is already in the dst. Options.fZeroInitialized * is ignored in this case. * * If set to kNoFrame, the codec will decode any necessary required frame(s) first. */ int fPriorFrame; }; /** * Decode into the given pixels, a block of memory of size at * least (info.fHeight - 1) * rowBytes + (info.fWidth * * bytesPerPixel) * * Repeated calls to this function should give the same results, * allowing the PixelRef to be immutable. * * @param info A description of the format (config, size) * expected by the caller. This can simply be identical * to the info returned by getInfo(). * * This contract also allows the caller to specify * different output-configs, which the implementation can * decide to support or not. * * A size that does not match getInfo() implies a request * to scale. If the generator cannot perform this scale, * it will return kInvalidScale. * * If the info contains a non-null SkColorSpace, the codec * will perform the appropriate color space transformation. * * If the caller passes in the SkColorSpace that maps to the * ICC profile reported by getICCProfile(), the color space * transformation is a no-op. * * If the caller passes a null SkColorSpace, no color space * transformation will be done. * * If a scanline decode is in progress, scanline mode will end, requiring the client to call * startScanlineDecode() in order to return to decoding scanlines. * * @return Result kSuccess, or another value explaining the type of failure. */ Result getPixels(const SkImageInfo& info, void* pixels, size_t rowBytes, const Options*); /** * Simplified version of getPixels() that uses the default Options. */ Result getPixels(const SkImageInfo& info, void* pixels, size_t rowBytes) { return this->getPixels(info, pixels, rowBytes, nullptr); } Result getPixels(const SkPixmap& pm, const Options* opts = nullptr) { return this->getPixels(pm.info(), pm.writable_addr(), pm.rowBytes(), opts); } /** * Return an image containing the pixels. */ std::tuple, SkCodec::Result> getImage(const SkImageInfo& info, const Options* opts = nullptr); std::tuple, SkCodec::Result> getImage(); /** * If decoding to YUV is supported, this returns true. Otherwise, this * returns false and the caller will ignore output parameter yuvaPixmapInfo. * * @param supportedDataTypes Indicates the data type/planar config combinations that are * supported by the caller. If the generator supports decoding to * YUV(A), but not as a type in supportedDataTypes, this method * returns false. * @param yuvaPixmapInfo Output parameter that specifies the planar configuration, subsampling, * orientation, chroma siting, plane color types, and row bytes. */ bool queryYUVAInfo(const SkYUVAPixmapInfo::SupportedDataTypes& supportedDataTypes, SkYUVAPixmapInfo* yuvaPixmapInfo) const; /** * Returns kSuccess, or another value explaining the type of failure. * This always attempts to perform a full decode. To get the planar * configuration without decoding use queryYUVAInfo(). * * @param yuvaPixmaps Contains preallocated pixmaps configured according to a successful call * to queryYUVAInfo(). */ Result getYUVAPlanes(const SkYUVAPixmaps& yuvaPixmaps); /** * Prepare for an incremental decode with the specified options. * * This may require a rewind. * * If kIncompleteInput is returned, may be called again after more data has * been provided to the source SkStream. * * @param dstInfo Info of the destination. If the dimensions do not match * those of getInfo, this implies a scale. * @param dst Memory to write to. Needs to be large enough to hold the subset, * if present, or the full image as described in dstInfo. * @param options Contains decoding options, including if memory is zero * initialized and whether to decode a subset. * @return Enum representing success or reason for failure. */ Result startIncrementalDecode(const SkImageInfo& dstInfo, void* dst, size_t rowBytes, const Options*); Result startIncrementalDecode(const SkImageInfo& dstInfo, void* dst, size_t rowBytes) { return this->startIncrementalDecode(dstInfo, dst, rowBytes, nullptr); } /** * Start/continue the incremental decode. * * Not valid to call before a call to startIncrementalDecode() returns * kSuccess. * * If kIncompleteInput is returned, may be called again after more data has * been provided to the source SkStream. * * Unlike getPixels and getScanlines, this does not do any filling. This is * left up to the caller, since they may be skipping lines or continuing the * decode later. In the latter case, they may choose to initialize all lines * first, or only initialize the remaining lines after the first call. * * @param rowsDecoded Optional output variable returning the total number of * lines initialized. Only meaningful if this method returns kIncompleteInput. * Otherwise the implementation may not set it. * Note that some implementations may have initialized this many rows, but * not necessarily finished those rows (e.g. interlaced PNG). This may be * useful for determining what rows the client needs to initialize. * @return kSuccess if all lines requested in startIncrementalDecode have * been completely decoded. kIncompleteInput otherwise. */ Result incrementalDecode(int* rowsDecoded = nullptr) { if (!fStartedIncrementalDecode) { return kInvalidParameters; } return this->onIncrementalDecode(rowsDecoded); } /** * The remaining functions revolve around decoding scanlines. */ /** * Prepare for a scanline decode with the specified options. * * After this call, this class will be ready to decode the first scanline. * * This must be called in order to call getScanlines or skipScanlines. * * This may require rewinding the stream. * * Not all SkCodecs support this. * * @param dstInfo Info of the destination. If the dimensions do not match * those of getInfo, this implies a scale. * @param options Contains decoding options, including if memory is zero * initialized. * @return Enum representing success or reason for failure. */ Result startScanlineDecode(const SkImageInfo& dstInfo, const Options* options); /** * Simplified version of startScanlineDecode() that uses the default Options. */ Result startScanlineDecode(const SkImageInfo& dstInfo) { return this->startScanlineDecode(dstInfo, nullptr); } /** * Write the next countLines scanlines into dst. * * Not valid to call before calling startScanlineDecode(). * * @param dst Must be non-null, and large enough to hold countLines * scanlines of size rowBytes. * @param countLines Number of lines to write. * @param rowBytes Number of bytes per row. Must be large enough to hold * a scanline based on the SkImageInfo used to create this object. * @return the number of lines successfully decoded. If this value is * less than countLines, this will fill the remaining lines with a * default value. */ int getScanlines(void* dst, int countLines, size_t rowBytes); /** * Skip count scanlines. * * Not valid to call before calling startScanlineDecode(). * * The default version just calls onGetScanlines and discards the dst. * NOTE: If skipped lines are the only lines with alpha, this default * will make reallyHasAlpha return true, when it could have returned * false. * * @return true if the scanlines were successfully skipped * false on failure, possible reasons for failure include: * An incomplete input image stream. * Calling this function before calling startScanlineDecode(). * If countLines is less than zero or so large that it moves * the current scanline past the end of the image. */ bool skipScanlines(int countLines); /** * The order in which rows are output from the scanline decoder is not the * same for all variations of all image types. This explains the possible * output row orderings. */ enum SkScanlineOrder { /* * By far the most common, this indicates that the image can be decoded * reliably using the scanline decoder, and that rows will be output in * the logical order. */ kTopDown_SkScanlineOrder, /* * This indicates that the scanline decoder reliably outputs rows, but * they will be returned in reverse order. If the scanline format is * kBottomUp, the nextScanline() API can be used to determine the actual * y-coordinate of the next output row, but the client is not forced * to take advantage of this, given that it's not too tough to keep * track independently. * * For full image decodes, it is safe to get all of the scanlines at * once, since the decoder will handle inverting the rows as it * decodes. * * For subset decodes and sampling, it is simplest to get and skip * scanlines one at a time, using the nextScanline() API. It is * possible to ask for larger chunks at a time, but this should be used * with caution. As with full image decodes, the decoder will handle * inverting the requested rows, but rows will still be delivered * starting from the bottom of the image. * * Upside down bmps are an example. */ kBottomUp_SkScanlineOrder, }; /** * An enum representing the order in which scanlines will be returned by * the scanline decoder. * * This is undefined before startScanlineDecode() is called. */ SkScanlineOrder getScanlineOrder() const { return this->onGetScanlineOrder(); } /** * Returns the y-coordinate of the next row to be returned by the scanline * decoder. * * This will equal fCurrScanline, except in the case of strangely * encoded image types (bottom-up bmps). * * Results are undefined when not in scanline decoding mode. */ int nextScanline() const { return this->outputScanline(fCurrScanline); } /** * Returns the output y-coordinate of the row that corresponds to an input * y-coordinate. The input y-coordinate represents where the scanline * is located in the encoded data. * * This will equal inputScanline, except in the case of strangely * encoded image types (bottom-up bmps, interlaced gifs). */ int outputScanline(int inputScanline) const; /** * Return the number of frames in the image. * * May require reading through the stream. */ int getFrameCount() { return this->onGetFrameCount(); } // Sentinel value used when a frame index implies "no frame": // - FrameInfo::fRequiredFrame set to this value means the frame // is independent. // - Options::fPriorFrame set to this value means no (relevant) prior frame // is residing in dst's memory. static constexpr int kNoFrame = -1; // This transitional definition was added in August 2018, and will eventually be removed. #ifdef SK_LEGACY_SKCODEC_NONE_ENUM static constexpr int kNone = kNoFrame; #endif /** * Information about individual frames in a multi-framed image. */ struct FrameInfo { /** * The frame that this frame needs to be blended with, or * kNoFrame if this frame is independent (so it can be * drawn over an uninitialized buffer). * * Note that this is the *earliest* frame that can be used * for blending. Any frame from [fRequiredFrame, i) can be * used, unless its fDisposalMethod is kRestorePrevious. */ int fRequiredFrame; /** * Number of milliseconds to show this frame. */ int fDuration; /** * Whether the end marker for this frame is contained in the stream. * * Note: this does not guarantee that an attempt to decode will be complete. * There could be an error in the stream. */ bool fFullyReceived; /** * This is conservative; it will still return non-opaque if e.g. a * color index-based frame has a color with alpha but does not use it. */ SkAlphaType fAlphaType; /** * Whether the updated rectangle contains alpha. * * This is conservative; it will still be set to true if e.g. a color * index-based frame has a color with alpha but does not use it. In * addition, it may be set to true, even if the final frame, after * blending, is opaque. */ bool fHasAlphaWithinBounds; /** * How this frame should be modified before decoding the next one. */ SkCodecAnimation::DisposalMethod fDisposalMethod; /** * How this frame should blend with the prior frame. */ SkCodecAnimation::Blend fBlend; /** * The rectangle updated by this frame. * * It may be empty, if the frame does not change the image. It will * always be contained by SkCodec::dimensions(). */ SkIRect fFrameRect; }; /** * Return info about a single frame. * * Does not read through the stream, so it should be called after * getFrameCount() to parse any frames that have not already been parsed. * * Only supported by animated (multi-frame) codecs. Note that this is a * property of the codec (the SkCodec subclass), not the image. * * To elaborate, some codecs support animation (e.g. GIF). Others do not * (e.g. BMP). Animated codecs can still represent single frame images. * Calling getFrameInfo(0, etc) will return true for a single frame GIF * even if the overall image is not animated (in that the pixels on screen * do not change over time). When incrementally decoding a GIF image, we * might only know that there's a single frame *so far*. * * For non-animated SkCodec subclasses, it's sufficient but not necessary * for this method to always return false. */ bool getFrameInfo(int index, FrameInfo* info) const { if (index < 0) { return false; } return this->onGetFrameInfo(index, info); } /** * Return info about all the frames in the image. * * May require reading through the stream to determine info about the * frames (including the count). * * As such, future decoding calls may require a rewind. * * This may return an empty vector for non-animated codecs. See the * getFrameInfo(int, FrameInfo*) comment. */ std::vector getFrameInfo(); static constexpr int kRepetitionCountInfinite = -1; /** * Return the number of times to repeat, if this image is animated. This number does not * include the first play through of each frame. For example, a repetition count of 4 means * that each frame is played 5 times and then the animation stops. * * It can return kRepetitionCountInfinite, a negative number, meaning that the animation * should loop forever. * * May require reading the stream to find the repetition count. * * As such, future decoding calls may require a rewind. * * For still (non-animated) image codecs, this will return 0. */ int getRepetitionCount() { return this->onGetRepetitionCount(); } // Register a decoder at runtime by passing two function pointers: // - peek() to return true if the span of bytes appears to be your encoded format; // - make() to attempt to create an SkCodec from the given stream. // Not thread safe. static void Register( bool (*peek)(const void*, size_t), std::unique_ptr (*make)(std::unique_ptr, SkCodec::Result*)); protected: const SkEncodedInfo& getEncodedInfo() const { return fEncodedInfo; } using XformFormat = skcms_PixelFormat; SkCodec(SkEncodedInfo&&, XformFormat srcFormat, std::unique_ptr, SkEncodedOrigin = kTopLeft_SkEncodedOrigin); void setSrcXformFormat(XformFormat pixelFormat); XformFormat getSrcXformFormat() const { return fSrcXformFormat; } virtual SkISize onGetScaledDimensions(float /*desiredScale*/) const { // By default, scaling is not supported. return this->dimensions(); } // FIXME: What to do about subsets?? /** * Subclasses should override if they support dimensions other than the * srcInfo's. */ virtual bool onDimensionsSupported(const SkISize&) { return false; } virtual SkEncodedImageFormat onGetEncodedFormat() const = 0; /** * @param rowsDecoded When the encoded image stream is incomplete, this function * will return kIncompleteInput and rowsDecoded will be set to * the number of scanlines that were successfully decoded. * This will allow getPixels() to fill the uninitialized memory. */ virtual Result onGetPixels(const SkImageInfo& info, void* pixels, size_t rowBytes, const Options&, int* rowsDecoded) = 0; virtual bool onQueryYUVAInfo(const SkYUVAPixmapInfo::SupportedDataTypes&, SkYUVAPixmapInfo*) const { return false; } virtual Result onGetYUVAPlanes(const SkYUVAPixmaps&) { return kUnimplemented; } virtual bool onGetValidSubset(SkIRect* /*desiredSubset*/) const { // By default, subsets are not supported. return false; } /** * If the stream was previously read, attempt to rewind. * * If the stream needed to be rewound, call onRewind. * @returns true if the codec is at the right position and can be used. * false if there was a failure to rewind. * * This is called by getPixels(), getYUV8Planes(), startIncrementalDecode() and * startScanlineDecode(). Subclasses may call if they need to rewind at another time. */ bool SK_WARN_UNUSED_RESULT rewindIfNeeded(); /** * Called by rewindIfNeeded, if the stream needed to be rewound. * * Subclasses should do any set up needed after a rewind. */ virtual bool onRewind() { return true; } /** * Get method for the input stream */ SkStream* stream() { return fStream.get(); } /** * The remaining functions revolve around decoding scanlines. */ /** * Most images types will be kTopDown and will not need to override this function. */ virtual SkScanlineOrder onGetScanlineOrder() const { return kTopDown_SkScanlineOrder; } const SkImageInfo& dstInfo() const { return fDstInfo; } const Options& options() const { return fOptions; } /** * Returns the number of scanlines that have been decoded so far. * This is unaffected by the SkScanlineOrder. * * Returns -1 if we have not started a scanline decode. */ int currScanline() const { return fCurrScanline; } virtual int onOutputScanline(int inputScanline) const; /** * Return whether we can convert to dst. * * Will be called for the appropriate frame, prior to initializing the colorXform. */ virtual bool conversionSupported(const SkImageInfo& dst, bool srcIsOpaque, bool needsColorXform); // Some classes never need a colorXform e.g. // - ICO uses its embedded codec's colorXform // - WBMP is just Black/White virtual bool usesColorXform() const { return true; } void applyColorXform(void* dst, const void* src, int count) const; bool colorXform() const { return fXformTime != kNo_XformTime; } bool xformOnDecode() const { return fXformTime == kDecodeRow_XformTime; } virtual int onGetFrameCount() { return 1; } virtual bool onGetFrameInfo(int, FrameInfo*) const { return false; } virtual int onGetRepetitionCount() { return 0; } private: const SkEncodedInfo fEncodedInfo; XformFormat fSrcXformFormat; std::unique_ptr fStream; bool fNeedsRewind; const SkEncodedOrigin fOrigin; SkImageInfo fDstInfo; Options fOptions; enum XformTime { kNo_XformTime, kPalette_XformTime, kDecodeRow_XformTime, }; XformTime fXformTime; XformFormat fDstXformFormat; // Based on fDstInfo. skcms_ICCProfile fDstProfile; skcms_AlphaFormat fDstXformAlphaFormat; // Only meaningful during scanline decodes. int fCurrScanline; bool fStartedIncrementalDecode; // Allows SkAndroidCodec to call handleFrameIndex (potentially decoding a prior frame and // clearing to transparent) without SkCodec calling it, too. bool fAndroidCodecHandlesFrameIndex; bool initializeColorXform(const SkImageInfo& dstInfo, SkEncodedInfo::Alpha, bool srcIsOpaque); /** * Return whether these dimensions are supported as a scale. * * The codec may choose to cache the information about scale and subset. * Either way, the same information will be passed to onGetPixels/onStart * on success. * * This must return true for a size returned from getScaledDimensions. */ bool dimensionsSupported(const SkISize& dim) { return dim == this->dimensions() || this->onDimensionsSupported(dim); } /** * For multi-framed images, return the object with information about the frames. */ virtual const SkFrameHolder* getFrameHolder() const { return nullptr; } /** * Check for a valid Options.fFrameIndex, and decode prior frames if necessary. * * If androidCodec is not null, that means this SkCodec is owned by an SkAndroidCodec. In that * case, the Options will be treated as an AndroidOptions, and SkAndroidCodec will be used to * decode a prior frame, if a prior frame is needed. When such an owned SkCodec calls * handleFrameIndex, it will immediately return kSuccess, since SkAndroidCodec already handled * it. */ Result handleFrameIndex(const SkImageInfo&, void* pixels, size_t rowBytes, const Options&, SkAndroidCodec* androidCodec = nullptr); // Methods for scanline decoding. virtual Result onStartScanlineDecode(const SkImageInfo& /*dstInfo*/, const Options& /*options*/) { return kUnimplemented; } virtual Result onStartIncrementalDecode(const SkImageInfo& /*dstInfo*/, void*, size_t, const Options&) { return kUnimplemented; } virtual Result onIncrementalDecode(int*) { return kUnimplemented; } virtual bool onSkipScanlines(int /*countLines*/) { return false; } virtual int onGetScanlines(void* /*dst*/, int /*countLines*/, size_t /*rowBytes*/) { return 0; } /** * On an incomplete decode, getPixels() and getScanlines() will call this function * to fill any uinitialized memory. * * @param dstInfo Contains the destination color type * Contains the destination alpha type * Contains the destination width * The height stored in this info is unused * @param dst Pointer to the start of destination pixel memory * @param rowBytes Stride length in destination pixel memory * @param zeroInit Indicates if memory is zero initialized * @param linesRequested Number of lines that the client requested * @param linesDecoded Number of lines that were successfully decoded */ void fillIncompleteImage(const SkImageInfo& dstInfo, void* dst, size_t rowBytes, ZeroInitialized zeroInit, int linesRequested, int linesDecoded); /** * Return an object which will allow forcing scanline decodes to sample in X. * * May create a sampler, if one is not currently being used. Otherwise, does * not affect ownership. * * Only valid during scanline decoding or incremental decoding. */ virtual SkSampler* getSampler(bool /*createIfNecessary*/) { return nullptr; } friend class DM::CodecSrc; // for fillIncompleteImage friend class SkSampledCodec; friend class SkIcoCodec; friend class SkAndroidCodec; // for fEncodedInfo }; #endif // SkCodec_DEFINED