src/codec/SkBmpCodec.cpp - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/codec/SkBmpCodec.h"

 #include "include/core/SkImageInfo.h"
 #include "include/core/SkSize.h"
 #include "include/core/SkStream.h"
 #include "include/private/SkEncodedInfo.h"
 #include "src/codec/SkBmpMaskCodec.h"
 #include "src/codec/SkBmpRLECodec.h"
 #include "src/codec/SkBmpStandardCodec.h"
 #include "src/codec/SkCodecPriv.h"
 #include "src/codec/SkMasks.h"

 #include <cstring>
 #include <memory>
 #include <type_traits>
 #include <utility>

 /*
  * Defines the version and type of the second bitmap header
  */
 enum BmpHeaderType {
     kInfoV1_BmpHeaderType,
     kInfoV2_BmpHeaderType,
     kInfoV3_BmpHeaderType,
     kInfoV4_BmpHeaderType,
     kInfoV5_BmpHeaderType,
     kOS2V1_BmpHeaderType,
     kOS2VX_BmpHeaderType,
     kUnknown_BmpHeaderType
 };

 /*
  * Possible bitmap compression types
  */
 enum BmpCompressionMethod {
     kNone_BmpCompressionMethod =          0,
     k8BitRLE_BmpCompressionMethod =       1,
     k4BitRLE_BmpCompressionMethod =       2,
     kBitMasks_BmpCompressionMethod =      3,
     kJpeg_BmpCompressionMethod =          4,
     kPng_BmpCompressionMethod =           5,
     kAlphaBitMasks_BmpCompressionMethod = 6,
     kCMYK_BmpCompressionMethod =          11,
     kCMYK8BitRLE_BmpCompressionMethod =   12,
     kCMYK4BitRLE_BmpCompressionMethod =   13
 };

 /*
  * Used to define the input format of the bmp
  */
 enum BmpInputFormat {
     kStandard_BmpInputFormat,
     kRLE_BmpInputFormat,
     kBitMask_BmpInputFormat,
     kUnknown_BmpInputFormat
 };

 /*
  * Checks the start of the stream to see if the image is a bitmap
  */
 bool SkBmpCodec::IsBmp(const void* buffer, size_t bytesRead) {
     // TODO: Support "IC", "PT", "CI", "CP", "BA"
     const char bmpSig[] = { 'B', 'M' };
     return bytesRead >= sizeof(bmpSig) && !memcmp(buffer, bmpSig, sizeof(bmpSig));
 }

 /*
  * Assumes IsBmp was called and returned true
  * Creates a bmp decoder
  * Reads enough of the stream to determine the image format
  */
 std::unique_ptr<SkCodec> SkBmpCodec::MakeFromStream(std::unique_ptr<SkStream> stream,
                                                     Result* result) {
     return SkBmpCodec::MakeFromStream(std::move(stream), result, false);
 }

 /*
  * Creates a bmp decoder for a bmp embedded in ico
  * Reads enough of the stream to determine the image format
  */
 std::unique_ptr<SkCodec> SkBmpCodec::MakeFromIco(std::unique_ptr<SkStream> stream, Result* result) {
     return SkBmpCodec::MakeFromStream(std::move(stream), result, true);
 }

 // Header size constants
 static constexpr uint32_t kBmpHeaderBytes = 14;
 static constexpr uint32_t kBmpHeaderBytesPlusFour = kBmpHeaderBytes + 4;
 static constexpr uint32_t kBmpOS2V1Bytes = 12;
 static constexpr uint32_t kBmpOS2V2Bytes = 64;
 static constexpr uint32_t kBmpInfoBaseBytes = 16;
 static constexpr uint32_t kBmpInfoV1Bytes = 40;
 static constexpr uint32_t kBmpInfoV2Bytes = 52;
 static constexpr uint32_t kBmpInfoV3Bytes = 56;
 static constexpr uint32_t kBmpInfoV4Bytes = 108;
 static constexpr uint32_t kBmpInfoV5Bytes = 124;
 static constexpr uint32_t kBmpMaskBytes = 12;

 static BmpHeaderType get_header_type(size_t infoBytes) {
     if (infoBytes >= kBmpInfoBaseBytes) {
         // Check the version of the header
         switch (infoBytes) {
             case kBmpInfoV1Bytes:
                 return kInfoV1_BmpHeaderType;
             case kBmpInfoV2Bytes:
                 return kInfoV2_BmpHeaderType;
             case kBmpInfoV3Bytes:
                 return kInfoV3_BmpHeaderType;
             case kBmpInfoV4Bytes:
                 return kInfoV4_BmpHeaderType;
             case kBmpInfoV5Bytes:
                 return kInfoV5_BmpHeaderType;
             case 16:
             case 20:
             case 24:
             case 28:
             case 32:
             case 36:
             case 42:
             case 46:
             case 48:
             case 60:
             case kBmpOS2V2Bytes:
                 return kOS2VX_BmpHeaderType;
             default:
                 SkCodecPrintf("Error: unknown bmp header format.\n");
                 return kUnknown_BmpHeaderType;
         }
     } if (infoBytes >= kBmpOS2V1Bytes) {
         // The OS2V1 is treated separately because it has a unique format
         return kOS2V1_BmpHeaderType;
     } else {
         // There are no valid bmp headers
         SkCodecPrintf("Error: second bitmap header size is invalid.\n");
         return kUnknown_BmpHeaderType;
     }
 }

 SkCodec::Result SkBmpCodec::ReadHeader(SkStream* stream, bool inIco,
         std::unique_ptr<SkCodec>* codecOut) {
     // The total bytes in the bmp file
     // We only need to use this value for RLE decoding, so we will only
     // check that it is valid in the RLE case.
     uint32_t totalBytes;
     // The offset from the start of the file where the pixel data begins
     uint32_t offset;
     // The size of the second (info) header in bytes
     uint32_t infoBytes;

     // Bmps embedded in Icos skip the first Bmp header
     if (!inIco) {
         // Read the first header and the size of the second header
         uint8_t hBuffer[kBmpHeaderBytesPlusFour];
         if (stream->read(hBuffer, kBmpHeaderBytesPlusFour) !=
                 kBmpHeaderBytesPlusFour) {
             SkCodecPrintf("Error: unable to read first bitmap header.\n");
             return kIncompleteInput;
         }

         totalBytes = get_int(hBuffer, 2);
         offset = get_int(hBuffer, 10);
         if (offset < kBmpHeaderBytes + kBmpOS2V1Bytes) {
             SkCodecPrintf("Error: invalid starting location for pixel data\n");
             return kInvalidInput;
         }

         // The size of the second (info) header in bytes
         // The size is the first field of the second header, so we have already
         // read the first four infoBytes.
         infoBytes = get_int(hBuffer, 14);
         if (infoBytes < kBmpOS2V1Bytes) {
             SkCodecPrintf("Error: invalid second header size.\n");
             return kInvalidInput;
         }
     } else {
         // This value is only used by RLE compression.  Bmp in Ico files do not
         // use RLE.  If the compression field is incorrectly signaled as RLE,
         // we will catch this and signal an error below.
         totalBytes = 0;

         // Bmps in Ico cannot specify an offset.  We will always assume that
         // pixel data begins immediately after the color table.  This value
         // will be corrected below.
         offset = 0;

         // Read the size of the second header
         uint8_t hBuffer[4];
         if (stream->read(hBuffer, 4) != 4) {
             SkCodecPrintf("Error: unable to read size of second bitmap header.\n");
             return kIncompleteInput;
         }
         infoBytes = get_int(hBuffer, 0);
         if (infoBytes < kBmpOS2V1Bytes) {
             SkCodecPrintf("Error: invalid second header size.\n");
             return kInvalidInput;
         }
     }

     // Determine image information depending on second header format
     const BmpHeaderType headerType = get_header_type(infoBytes);
     if (kUnknown_BmpHeaderType == headerType) {
         return kInvalidInput;
     }

     // We already read the first four bytes of the info header to get the size
     const uint32_t infoBytesRemaining = infoBytes - 4;

     // Read the second header
     std::unique_ptr<uint8_t[]> iBuffer(new uint8_t[infoBytesRemaining]);
     if (stream->read(iBuffer.get(), infoBytesRemaining) != infoBytesRemaining) {
         SkCodecPrintf("Error: unable to read second bitmap header.\n");
         return kIncompleteInput;
     }

     // The number of bits used per pixel in the pixel data
     uint16_t bitsPerPixel;

     // The compression method for the pixel data
     uint32_t compression = kNone_BmpCompressionMethod;

     // Number of colors in the color table, defaults to 0 or max (see below)
     uint32_t numColors = 0;

     // Bytes per color in the color table, early versions use 3, most use 4
     uint32_t bytesPerColor;

     // The image width and height
     int width, height;

     switch (headerType) {
         case kInfoV1_BmpHeaderType:
         case kInfoV2_BmpHeaderType:
         case kInfoV3_BmpHeaderType:
         case kInfoV4_BmpHeaderType:
         case kInfoV5_BmpHeaderType:
         case kOS2VX_BmpHeaderType:
             // We check the size of the header before entering the if statement.
             // We should not reach this point unless the size is large enough for
             // these required fields.
             SkASSERT(infoBytesRemaining >= 12);
             width = get_int(iBuffer.get(), 0);
             height = get_int(iBuffer.get(), 4);
             bitsPerPixel = get_short(iBuffer.get(), 10);

             // Some versions do not have these fields, so we check before
             // overwriting the default value.
             if (infoBytesRemaining >= 16) {
                 compression = get_int(iBuffer.get(), 12);
                 if (infoBytesRemaining >= 32) {
                     numColors = get_int(iBuffer.get(), 28);
                 }
             }

             // All of the headers that reach this point, store color table entries
             // using 4 bytes per pixel.
             bytesPerColor = 4;
             break;
         case kOS2V1_BmpHeaderType:
             // The OS2V1 is treated separately because it has a unique format
             width = (int) get_short(iBuffer.get(), 0);
             height = (int) get_short(iBuffer.get(), 2);
             bitsPerPixel = get_short(iBuffer.get(), 6);
             bytesPerColor = 3;
             break;
         case kUnknown_BmpHeaderType:
             // We'll exit above in this case.
             SkASSERT(false);
             return kInvalidInput;
     }

     // Check for valid dimensions from header
     SkCodec::SkScanlineOrder rowOrder = SkCodec::kBottomUp_SkScanlineOrder;
     if (height < 0) {
         // We can't negate INT32_MIN.
         if (height == INT32_MIN) {
             return kInvalidInput;
         }

         height = -height;
         rowOrder = SkCodec::kTopDown_SkScanlineOrder;
     }
     // The height field for bmp in ico is double the actual height because they
     // contain an XOR mask followed by an AND mask
     if (inIco) {
         height /= 2;
     }

     // Arbitrary maximum. Matches Chromium.
     constexpr int kMaxDim = 1 << 16;
     if (width <= 0 || height <= 0 || width >= kMaxDim || height >= kMaxDim) {
         SkCodecPrintf("Error: invalid bitmap dimensions.\n");
         return kInvalidInput;
     }

     // Create mask struct
     SkMasks::InputMasks inputMasks;
     memset(&inputMasks, 0, sizeof(SkMasks::InputMasks));

     // Determine the input compression format and set bit masks if necessary
     uint32_t maskBytes = 0;
     BmpInputFormat inputFormat = kUnknown_BmpInputFormat;
     switch (compression) {
         case kNone_BmpCompressionMethod:
             inputFormat = kStandard_BmpInputFormat;

             // In addition to more standard pixel compression formats, bmp supports
             // the use of bit masks to determine pixel components.  The standard
             // format for representing 16-bit colors is 555 (XRRRRRGGGGGBBBBB),
             // which does not map well to any Skia color formats.  For this reason,
             // we will always enable mask mode with 16 bits per pixel.
             if (16 == bitsPerPixel) {
                 inputMasks.red = 0x7C00;
                 inputMasks.green = 0x03E0;
                 inputMasks.blue = 0x001F;
                 inputFormat = kBitMask_BmpInputFormat;
             }
             break;
         case k8BitRLE_BmpCompressionMethod:
             if (bitsPerPixel != 8) {
                 SkCodecPrintf("Warning: correcting invalid bitmap format.\n");
                 bitsPerPixel = 8;
             }
             inputFormat = kRLE_BmpInputFormat;
             break;
         case k4BitRLE_BmpCompressionMethod:
             if (bitsPerPixel != 4) {
                 SkCodecPrintf("Warning: correcting invalid bitmap format.\n");
                 bitsPerPixel = 4;
             }
             inputFormat = kRLE_BmpInputFormat;
             break;
         case kAlphaBitMasks_BmpCompressionMethod:
         case kBitMasks_BmpCompressionMethod:
             // Load the masks
             inputFormat = kBitMask_BmpInputFormat;
             switch (headerType) {
                 case kInfoV1_BmpHeaderType: {
                     // The V1 header stores the bit masks after the header
                     uint8_t buffer[kBmpMaskBytes];
                     if (stream->read(buffer, kBmpMaskBytes) != kBmpMaskBytes) {
                         SkCodecPrintf("Error: unable to read bit inputMasks.\n");
                         return kIncompleteInput;
                     }
                     maskBytes = kBmpMaskBytes;
                     inputMasks.red = get_int(buffer, 0);
                     inputMasks.green = get_int(buffer, 4);
                     inputMasks.blue = get_int(buffer, 8);
                     break;
                 }
                 case kInfoV2_BmpHeaderType:
                 case kInfoV3_BmpHeaderType:
                 case kInfoV4_BmpHeaderType:
                 case kInfoV5_BmpHeaderType:
                     // Header types are matched based on size.  If the header
                     // is V2+, we are guaranteed to be able to read at least
                     // this size.
                     SkASSERT(infoBytesRemaining >= 48);
                     inputMasks.red = get_int(iBuffer.get(), 36);
                     inputMasks.green = get_int(iBuffer.get(), 40);
                     inputMasks.blue = get_int(iBuffer.get(), 44);

                     if (kInfoV2_BmpHeaderType == headerType ||
                             (kInfoV3_BmpHeaderType == headerType && !inIco)) {
                         break;
                     }

                     // V3+ bmp files introduce an alpha mask and allow the creator of the image
                     // to use the alpha channels.  However, many of these images leave the
                     // alpha channel blank and expect to be rendered as opaque.  This is the
                     // case for almost all V3 images, so we ignore the alpha mask.  For V4+
                     // images in kMask mode, we will use the alpha mask.  Additionally, V3
                     // bmp-in-ico expect us to use the alpha mask.
                     //
                     // skbug.com/4116: We should perhaps also apply the alpha mask in kStandard
                     //                 mode.  We just haven't seen any images that expect this
                     //                 behavior.
                     //
                     // Header types are matched based on size.  If the header is
                     // V3+, we are guaranteed to be able to read at least this size.
                     SkASSERT(infoBytesRemaining >= 52);
                     inputMasks.alpha = get_int(iBuffer.get(), 48);
                     break;
                 case kOS2VX_BmpHeaderType:
                     // TODO: Decide if we intend to support this.
                     //       It is unsupported in the previous version and
                     //       in chromium.  I have not come across a test case
                     //       that uses this format.
                     SkCodecPrintf("Error: huffman format unsupported.\n");
                     return kUnimplemented;
                 default:
                    SkCodecPrintf("Error: invalid bmp bit masks header.\n");
                    return kInvalidInput;
             }
             break;
         case kJpeg_BmpCompressionMethod:
             if (24 == bitsPerPixel) {
                 inputFormat = kRLE_BmpInputFormat;
                 break;
             }
             [[fallthrough]];
         case kPng_BmpCompressionMethod:
             // TODO: Decide if we intend to support this.
             //       It is unsupported in the previous version and
             //       in chromium.  I think it is used mostly for printers.
             SkCodecPrintf("Error: compression format not supported.\n");
             return kUnimplemented;
         case kCMYK_BmpCompressionMethod:
         case kCMYK8BitRLE_BmpCompressionMethod:
         case kCMYK4BitRLE_BmpCompressionMethod:
             // TODO: Same as above.
             SkCodecPrintf("Error: CMYK not supported for bitmap decoding.\n");
             return kUnimplemented;
         default:
             SkCodecPrintf("Error: invalid format for bitmap decoding.\n");
             return kInvalidInput;
     }
     iBuffer.reset();

     // Calculate the number of bytes read so far
     const uint32_t bytesRead = kBmpHeaderBytes + infoBytes + maskBytes;
     if (!inIco && offset < bytesRead) {
         // TODO (msarett): Do we really want to fail if the offset in the header is invalid?
         //                 Seems like we can just assume that the offset is zero and try to decode?
         //                 Maybe we don't want to try to decode corrupt images?
         SkCodecPrintf("Error: pixel data offset less than header size.\n");
         return kInvalidInput;
     }


     switch (inputFormat) {
         case kStandard_BmpInputFormat: {
             // BMPs are generally opaque, however BMPs-in-ICOs may contain
             // a transparency mask after the image.  Therefore, we mark the
             // alpha as kBinary if the BMP is contained in an ICO.
             // We use |isOpaque| to indicate if the BMP itself is opaque.
             SkEncodedInfo::Alpha alpha = inIco ? SkEncodedInfo::kBinary_Alpha :
                     SkEncodedInfo::kOpaque_Alpha;
             bool isOpaque = true;

             SkEncodedInfo::Color color;
             uint8_t bitsPerComponent;
             switch (bitsPerPixel) {
                 // Palette formats
                 case 1:
                 case 2:
                 case 4:
                 case 8:
                     // In the case of ICO, kBGRA is actually the closest match,
                     // since we will need to apply a transparency mask.
                     if (inIco) {
                         color = SkEncodedInfo::kBGRA_Color;
                         bitsPerComponent = 8;
                     } else {
                         color = SkEncodedInfo::kPalette_Color;
                         bitsPerComponent = (uint8_t) bitsPerPixel;
                     }
                     break;
                 case 24:
                     // In the case of ICO, kBGRA is actually the closest match,
                     // since we will need to apply a transparency mask.
                     color = inIco ? SkEncodedInfo::kBGRA_Color : SkEncodedInfo::kBGR_Color;
                     bitsPerComponent = 8;
                     break;
                 case 32:
                     // 32-bit BMP-in-ICOs actually use the alpha channel in place of a
                     // transparency mask.
                     if (inIco) {
                         isOpaque = false;
                         alpha = SkEncodedInfo::kUnpremul_Alpha;
                         color = SkEncodedInfo::kBGRA_Color;
                     } else {
                         color = SkEncodedInfo::kBGRX_Color;
                     }
                     bitsPerComponent = 8;
                     break;
                 default:
                     SkCodecPrintf("Error: invalid input value for bits per pixel.\n");
                     return kInvalidInput;
             }

             if (codecOut) {
                 // We require streams to have a memory base for Bmp-in-Ico decodes.
                 SkASSERT(!inIco || nullptr != stream->getMemoryBase());

                 // Set the image info and create a codec.
                 auto info = SkEncodedInfo::Make(width, height, color, alpha, bitsPerComponent);
                 *codecOut = std::make_unique<SkBmpStandardCodec>(std::move(info),
                                                        std::unique_ptr<SkStream>(stream),
                                                        bitsPerPixel, numColors, bytesPerColor,
                                                        offset - bytesRead, rowOrder, isOpaque,
                                                        inIco);
                 return static_cast<SkBmpStandardCodec*>(codecOut->get())->didCreateSrcBuffer()
                         ? kSuccess : kInvalidInput;
             }
             return kSuccess;
         }

         case kBitMask_BmpInputFormat: {
             // Bmp-in-Ico must be standard mode
             if (inIco) {
                 SkCodecPrintf("Error: Icos may not use bit mask format.\n");
                 return kInvalidInput;
             }

             switch (bitsPerPixel) {
                 case 16:
                 case 24:
                 case 32:
                     break;
                 default:
                     SkCodecPrintf("Error: invalid input value for bits per pixel.\n");
                     return kInvalidInput;
             }

             // Skip to the start of the pixel array.
             // We can do this here because there is no color table to read
             // in bit mask mode.
             if (stream->skip(offset - bytesRead) != offset - bytesRead) {
                 SkCodecPrintf("Error: unable to skip to image data.\n");
                 return kIncompleteInput;
             }

             if (codecOut) {
                 // Check that input bit masks are valid and create the masks object
                 SkASSERT(bitsPerPixel % 8 == 0);
                 std::unique_ptr<SkMasks> masks(SkMasks::CreateMasks(inputMasks, bitsPerPixel/8));
                 if (nullptr == masks) {
                     SkCodecPrintf("Error: invalid input masks.\n");
                     return kInvalidInput;
                 }

                 // Masked bmps are not a great fit for SkEncodedInfo, since they have
                 // arbitrary component orderings and bits per component.  Here we choose
                 // somewhat reasonable values - it's ok that we don't match exactly
                 // because SkBmpMaskCodec has its own mask swizzler anyway.
                 SkEncodedInfo::Color color;
                 SkEncodedInfo::Alpha alpha;
                 if (masks->getAlphaMask()) {
                     color = SkEncodedInfo::kBGRA_Color;
                     alpha = SkEncodedInfo::kUnpremul_Alpha;
                 } else {
                     color = SkEncodedInfo::kBGR_Color;
                     alpha = SkEncodedInfo::kOpaque_Alpha;
                 }
                 auto info = SkEncodedInfo::Make(width, height, color, alpha, 8);
                 *codecOut = std::make_unique<SkBmpMaskCodec>(std::move(info),
                                                    std::unique_ptr<SkStream>(stream), bitsPerPixel,
                                                    masks.release(), rowOrder);
                 return static_cast<SkBmpMaskCodec*>(codecOut->get())->didCreateSrcBuffer()
                         ? kSuccess : kInvalidInput;
             }
             return kSuccess;
         }

         case kRLE_BmpInputFormat: {
             // We should not reach this point without a valid value of bitsPerPixel.
             SkASSERT(4 == bitsPerPixel || 8 == bitsPerPixel || 24 == bitsPerPixel);

             // Check for a valid number of total bytes when in RLE mode
             if (totalBytes <= offset) {
                 SkCodecPrintf("Error: RLE requires valid input size.\n");
                 return kInvalidInput;
             }

             // Bmp-in-Ico must be standard mode
             // When inIco is true, this line cannot be reached, since we
             // require that RLE Bmps have a valid number of totalBytes, and
             // Icos skip the header that contains totalBytes.
             SkASSERT(!inIco);

             if (codecOut) {
                 // RLE inputs may skip pixels, leaving them as transparent.  This
                 // is uncommon, but we cannot be certain that an RLE bmp will be
                 // opaque or that we will be able to represent it with a palette.
                 // For that reason, we always indicate that we are kBGRA.
                 auto info = SkEncodedInfo::Make(width, height, SkEncodedInfo::kBGRA_Color,
                                                 SkEncodedInfo::kBinary_Alpha, 8);
                 *codecOut = std::make_unique<SkBmpRLECodec>(std::move(info),
                                                   std::unique_ptr<SkStream>(stream), bitsPerPixel,
                                                   numColors, bytesPerColor, offset - bytesRead,
                                                   rowOrder);
             }
             return kSuccess;
         }
         default:
             SkASSERT(false);
             return kInvalidInput;
     }
 }

 /*
  * Creates a bmp decoder
  * Reads enough of the stream to determine the image format
  */
 std::unique_ptr<SkCodec> SkBmpCodec::MakeFromStream(std::unique_ptr<SkStream> stream,
                                                     Result* result, bool inIco) {
     std::unique_ptr<SkCodec> codec;
     *result = ReadHeader(stream.get(), inIco, &codec);
     if (codec) {
         // codec has taken ownership of stream, so we do not need to delete it.
         stream.release();
     }
     return kSuccess == *result ? std::move(codec) : nullptr;
 }

 SkBmpCodec::SkBmpCodec(SkEncodedInfo&& info, std::unique_ptr<SkStream> stream,
         uint16_t bitsPerPixel, SkCodec::SkScanlineOrder rowOrder)
     : INHERITED(std::move(info), kXformSrcColorFormat, std::move(stream))
     , fBitsPerPixel(bitsPerPixel)
     , fRowOrder(rowOrder)
     , fSrcRowBytes(SkAlign4(compute_row_bytes(this->dimensions().width(), fBitsPerPixel)))
     , fXformBuffer(nullptr)
 {}

 bool SkBmpCodec::onRewind() {
     return SkBmpCodec::ReadHeader(this->stream(), this->inIco(), nullptr) == kSuccess;
 }

 int32_t SkBmpCodec::getDstRow(int32_t y, int32_t height) const {
     if (SkCodec::kTopDown_SkScanlineOrder == fRowOrder) {
         return y;
     }
     SkASSERT(SkCodec::kBottomUp_SkScanlineOrder == fRowOrder);
     return height - y - 1;
 }

 SkCodec::Result SkBmpCodec::prepareToDecode(const SkImageInfo& dstInfo,
         const SkCodec::Options& options) {
     return this->onPrepareToDecode(dstInfo, options);
 }

 SkCodec::Result SkBmpCodec::onStartScanlineDecode(const SkImageInfo& dstInfo,
         const SkCodec::Options& options) {
     return prepareToDecode(dstInfo, options);
 }

 int SkBmpCodec::onGetScanlines(void* dst, int count, size_t rowBytes) {
     // Create a new image info representing the portion of the image to decode
     SkImageInfo rowInfo = this->dstInfo().makeWH(this->dstInfo().width(), count);

     // Decode the requested rows
     return this->decodeRows(rowInfo, dst, rowBytes, this->options());
 }

 bool SkBmpCodec::skipRows(int count) {
     const size_t bytesToSkip = count * fSrcRowBytes;
     return this->stream()->skip(bytesToSkip) == bytesToSkip;
 }

 bool SkBmpCodec::onSkipScanlines(int count) {
     return this->skipRows(count);
 }
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/codec/SkBmpCodec.h"

	#include "include/core/SkImageInfo.h"
	#include "include/core/SkSize.h"
	#include "include/core/SkStream.h"
	#include "include/private/SkEncodedInfo.h"
	#include "src/codec/SkBmpMaskCodec.h"
	#include "src/codec/SkBmpRLECodec.h"
	#include "src/codec/SkBmpStandardCodec.h"
	#include "src/codec/SkCodecPriv.h"
	#include "src/codec/SkMasks.h"

	#include <cstring>
	#include <memory>
	#include <type_traits>
	#include <utility>

	/*
	* Defines the version and type of the second bitmap header
	*/
	enum BmpHeaderType {
	kInfoV1_BmpHeaderType,
	kInfoV2_BmpHeaderType,
	kInfoV3_BmpHeaderType,
	kInfoV4_BmpHeaderType,
	kInfoV5_BmpHeaderType,
	kOS2V1_BmpHeaderType,
	kOS2VX_BmpHeaderType,
	kUnknown_BmpHeaderType
	};

	/*
	* Possible bitmap compression types
	*/
	enum BmpCompressionMethod {
	kNone_BmpCompressionMethod = 0,
	k8BitRLE_BmpCompressionMethod = 1,
	k4BitRLE_BmpCompressionMethod = 2,
	kBitMasks_BmpCompressionMethod = 3,
	kJpeg_BmpCompressionMethod = 4,
	kPng_BmpCompressionMethod = 5,
	kAlphaBitMasks_BmpCompressionMethod = 6,
	kCMYK_BmpCompressionMethod = 11,
	kCMYK8BitRLE_BmpCompressionMethod = 12,
	kCMYK4BitRLE_BmpCompressionMethod = 13
	};

	/*
	* Used to define the input format of the bmp
	*/
	enum BmpInputFormat {
	kStandard_BmpInputFormat,
	kRLE_BmpInputFormat,
	kBitMask_BmpInputFormat,
	kUnknown_BmpInputFormat
	};

	/*
	* Checks the start of the stream to see if the image is a bitmap
	*/
	bool SkBmpCodec::IsBmp(const void* buffer, size_t bytesRead) {
	// TODO: Support "IC", "PT", "CI", "CP", "BA"
	const char bmpSig[] = { 'B', 'M' };
	return bytesRead >= sizeof(bmpSig) && !memcmp(buffer, bmpSig, sizeof(bmpSig));
	}

	/*
	* Assumes IsBmp was called and returned true
	* Creates a bmp decoder
	* Reads enough of the stream to determine the image format
	*/
	std::unique_ptr<SkCodec> SkBmpCodec::MakeFromStream(std::unique_ptr<SkStream> stream,
	Result* result) {
	return SkBmpCodec::MakeFromStream(std::move(stream), result, false);
	}

	/*
	* Creates a bmp decoder for a bmp embedded in ico
	* Reads enough of the stream to determine the image format
	*/
	std::unique_ptr<SkCodec> SkBmpCodec::MakeFromIco(std::unique_ptr<SkStream> stream, Result* result) {
	return SkBmpCodec::MakeFromStream(std::move(stream), result, true);
	}

	// Header size constants
	static constexpr uint32_t kBmpHeaderBytes = 14;
	static constexpr uint32_t kBmpHeaderBytesPlusFour = kBmpHeaderBytes + 4;
	static constexpr uint32_t kBmpOS2V1Bytes = 12;
	static constexpr uint32_t kBmpOS2V2Bytes = 64;
	static constexpr uint32_t kBmpInfoBaseBytes = 16;
	static constexpr uint32_t kBmpInfoV1Bytes = 40;
	static constexpr uint32_t kBmpInfoV2Bytes = 52;
	static constexpr uint32_t kBmpInfoV3Bytes = 56;
	static constexpr uint32_t kBmpInfoV4Bytes = 108;
	static constexpr uint32_t kBmpInfoV5Bytes = 124;
	static constexpr uint32_t kBmpMaskBytes = 12;

	static BmpHeaderType get_header_type(size_t infoBytes) {
	if (infoBytes >= kBmpInfoBaseBytes) {
	// Check the version of the header
	switch (infoBytes) {
	case kBmpInfoV1Bytes:
	return kInfoV1_BmpHeaderType;
	case kBmpInfoV2Bytes:
	return kInfoV2_BmpHeaderType;
	case kBmpInfoV3Bytes:
	return kInfoV3_BmpHeaderType;
	case kBmpInfoV4Bytes:
	return kInfoV4_BmpHeaderType;
	case kBmpInfoV5Bytes:
	return kInfoV5_BmpHeaderType;
	case 16:
	case 20:
	case 24:
	case 28:
	case 32:
	case 36:
	case 42:
	case 46:
	case 48:
	case 60:
	case kBmpOS2V2Bytes:
	return kOS2VX_BmpHeaderType;
	default:
	SkCodecPrintf("Error: unknown bmp header format.\n");
	return kUnknown_BmpHeaderType;
	}
	} if (infoBytes >= kBmpOS2V1Bytes) {
	// The OS2V1 is treated separately because it has a unique format
	return kOS2V1_BmpHeaderType;
	} else {
	// There are no valid bmp headers
	SkCodecPrintf("Error: second bitmap header size is invalid.\n");
	return kUnknown_BmpHeaderType;
	}
	}

	SkCodec::Result SkBmpCodec::ReadHeader(SkStream* stream, bool inIco,
	std::unique_ptr<SkCodec>* codecOut) {
	// The total bytes in the bmp file
	// We only need to use this value for RLE decoding, so we will only
	// check that it is valid in the RLE case.
	uint32_t totalBytes;
	// The offset from the start of the file where the pixel data begins
	uint32_t offset;
	// The size of the second (info) header in bytes
	uint32_t infoBytes;

	// Bmps embedded in Icos skip the first Bmp header
	if (!inIco) {
	// Read the first header and the size of the second header
	uint8_t hBuffer[kBmpHeaderBytesPlusFour];
	if (stream->read(hBuffer, kBmpHeaderBytesPlusFour) !=
	kBmpHeaderBytesPlusFour) {
	SkCodecPrintf("Error: unable to read first bitmap header.\n");
	return kIncompleteInput;
	}

	totalBytes = get_int(hBuffer, 2);
	offset = get_int(hBuffer, 10);
	if (offset < kBmpHeaderBytes + kBmpOS2V1Bytes) {
	SkCodecPrintf("Error: invalid starting location for pixel data\n");
	return kInvalidInput;
	}

	// The size of the second (info) header in bytes
	// The size is the first field of the second header, so we have already
	// read the first four infoBytes.
	infoBytes = get_int(hBuffer, 14);
	if (infoBytes < kBmpOS2V1Bytes) {
	SkCodecPrintf("Error: invalid second header size.\n");
	return kInvalidInput;
	}
	} else {
	// This value is only used by RLE compression. Bmp in Ico files do not
	// use RLE. If the compression field is incorrectly signaled as RLE,
	// we will catch this and signal an error below.
	totalBytes = 0;

	// Bmps in Ico cannot specify an offset. We will always assume that
	// pixel data begins immediately after the color table. This value
	// will be corrected below.
	offset = 0;

	// Read the size of the second header
	uint8_t hBuffer[4];
	if (stream->read(hBuffer, 4) != 4) {
	SkCodecPrintf("Error: unable to read size of second bitmap header.\n");
	return kIncompleteInput;
	}
	infoBytes = get_int(hBuffer, 0);
	if (infoBytes < kBmpOS2V1Bytes) {
	SkCodecPrintf("Error: invalid second header size.\n");
	return kInvalidInput;
	}
	}

	// Determine image information depending on second header format
	const BmpHeaderType headerType = get_header_type(infoBytes);
	if (kUnknown_BmpHeaderType == headerType) {
	return kInvalidInput;
	}

	// We already read the first four bytes of the info header to get the size
	const uint32_t infoBytesRemaining = infoBytes - 4;

	// Read the second header
	std::unique_ptr<uint8_t[]> iBuffer(new uint8_t[infoBytesRemaining]);
	if (stream->read(iBuffer.get(), infoBytesRemaining) != infoBytesRemaining) {
	SkCodecPrintf("Error: unable to read second bitmap header.\n");
	return kIncompleteInput;
	}

	// The number of bits used per pixel in the pixel data
	uint16_t bitsPerPixel;

	// The compression method for the pixel data
	uint32_t compression = kNone_BmpCompressionMethod;

	// Number of colors in the color table, defaults to 0 or max (see below)
	uint32_t numColors = 0;

	// Bytes per color in the color table, early versions use 3, most use 4
	uint32_t bytesPerColor;

	// The image width and height
	int width, height;

	switch (headerType) {
	case kInfoV1_BmpHeaderType:
	case kInfoV2_BmpHeaderType:
	case kInfoV3_BmpHeaderType:
	case kInfoV4_BmpHeaderType:
	case kInfoV5_BmpHeaderType:
	case kOS2VX_BmpHeaderType:
	// We check the size of the header before entering the if statement.
	// We should not reach this point unless the size is large enough for
	// these required fields.
	SkASSERT(infoBytesRemaining >= 12);
	width = get_int(iBuffer.get(), 0);
	height = get_int(iBuffer.get(), 4);
	bitsPerPixel = get_short(iBuffer.get(), 10);

	// Some versions do not have these fields, so we check before
	// overwriting the default value.
	if (infoBytesRemaining >= 16) {
	compression = get_int(iBuffer.get(), 12);
	if (infoBytesRemaining >= 32) {
	numColors = get_int(iBuffer.get(), 28);
	}
	}

	// All of the headers that reach this point, store color table entries
	// using 4 bytes per pixel.
	bytesPerColor = 4;
	break;
	case kOS2V1_BmpHeaderType:
	// The OS2V1 is treated separately because it has a unique format
	width = (int) get_short(iBuffer.get(), 0);
	height = (int) get_short(iBuffer.get(), 2);
	bitsPerPixel = get_short(iBuffer.get(), 6);
	bytesPerColor = 3;
	break;
	case kUnknown_BmpHeaderType:
	// We'll exit above in this case.
	SkASSERT(false);
	return kInvalidInput;
	}

	// Check for valid dimensions from header
	SkCodec::SkScanlineOrder rowOrder = SkCodec::kBottomUp_SkScanlineOrder;
	if (height < 0) {
	// We can't negate INT32_MIN.
	if (height == INT32_MIN) {
	return kInvalidInput;
	}

	height = -height;
	rowOrder = SkCodec::kTopDown_SkScanlineOrder;
	}
	// The height field for bmp in ico is double the actual height because they
	// contain an XOR mask followed by an AND mask
	if (inIco) {
	height /= 2;
	}

	// Arbitrary maximum. Matches Chromium.
	constexpr int kMaxDim = 1 << 16;
	if (width <= 0 \|\| height <= 0 \|\| width >= kMaxDim \|\| height >= kMaxDim) {
	SkCodecPrintf("Error: invalid bitmap dimensions.\n");
	return kInvalidInput;
	}

	// Create mask struct
	SkMasks::InputMasks inputMasks;
	memset(&inputMasks, 0, sizeof(SkMasks::InputMasks));

	// Determine the input compression format and set bit masks if necessary
	uint32_t maskBytes = 0;
	BmpInputFormat inputFormat = kUnknown_BmpInputFormat;
	switch (compression) {
	case kNone_BmpCompressionMethod:
	inputFormat = kStandard_BmpInputFormat;

	// In addition to more standard pixel compression formats, bmp supports
	// the use of bit masks to determine pixel components. The standard
	// format for representing 16-bit colors is 555 (XRRRRRGGGGGBBBBB),
	// which does not map well to any Skia color formats. For this reason,
	// we will always enable mask mode with 16 bits per pixel.
	if (16 == bitsPerPixel) {
	inputMasks.red = 0x7C00;
	inputMasks.green = 0x03E0;
	inputMasks.blue = 0x001F;
	inputFormat = kBitMask_BmpInputFormat;
	}
	break;
	case k8BitRLE_BmpCompressionMethod:
	if (bitsPerPixel != 8) {
	SkCodecPrintf("Warning: correcting invalid bitmap format.\n");
	bitsPerPixel = 8;
	}
	inputFormat = kRLE_BmpInputFormat;
	break;
	case k4BitRLE_BmpCompressionMethod:
	if (bitsPerPixel != 4) {
	SkCodecPrintf("Warning: correcting invalid bitmap format.\n");
	bitsPerPixel = 4;
	}
	inputFormat = kRLE_BmpInputFormat;
	break;
	case kAlphaBitMasks_BmpCompressionMethod:
	case kBitMasks_BmpCompressionMethod:
	// Load the masks
	inputFormat = kBitMask_BmpInputFormat;
	switch (headerType) {
	case kInfoV1_BmpHeaderType: {
	// The V1 header stores the bit masks after the header
	uint8_t buffer[kBmpMaskBytes];
	if (stream->read(buffer, kBmpMaskBytes) != kBmpMaskBytes) {
	SkCodecPrintf("Error: unable to read bit inputMasks.\n");
	return kIncompleteInput;
	}
	maskBytes = kBmpMaskBytes;
	inputMasks.red = get_int(buffer, 0);
	inputMasks.green = get_int(buffer, 4);
	inputMasks.blue = get_int(buffer, 8);
	break;
	}
	case kInfoV2_BmpHeaderType:
	case kInfoV3_BmpHeaderType:
	case kInfoV4_BmpHeaderType:
	case kInfoV5_BmpHeaderType:
	// Header types are matched based on size. If the header
	// is V2+, we are guaranteed to be able to read at least
	// this size.
	SkASSERT(infoBytesRemaining >= 48);
	inputMasks.red = get_int(iBuffer.get(), 36);
	inputMasks.green = get_int(iBuffer.get(), 40);
	inputMasks.blue = get_int(iBuffer.get(), 44);

	if (kInfoV2_BmpHeaderType == headerType \|\|
	(kInfoV3_BmpHeaderType == headerType && !inIco)) {
	break;
	}

	// V3+ bmp files introduce an alpha mask and allow the creator of the image
	// to use the alpha channels. However, many of these images leave the
	// alpha channel blank and expect to be rendered as opaque. This is the
	// case for almost all V3 images, so we ignore the alpha mask. For V4+
	// images in kMask mode, we will use the alpha mask. Additionally, V3
	// bmp-in-ico expect us to use the alpha mask.
	//
	// skbug.com/4116: We should perhaps also apply the alpha mask in kStandard
	// mode. We just haven't seen any images that expect this
	// behavior.
	//
	// Header types are matched based on size. If the header is
	// V3+, we are guaranteed to be able to read at least this size.
	SkASSERT(infoBytesRemaining >= 52);
	inputMasks.alpha = get_int(iBuffer.get(), 48);
	break;
	case kOS2VX_BmpHeaderType:
	// TODO: Decide if we intend to support this.
	// It is unsupported in the previous version and
	// in chromium. I have not come across a test case
	// that uses this format.
	SkCodecPrintf("Error: huffman format unsupported.\n");
	return kUnimplemented;
	default:
	SkCodecPrintf("Error: invalid bmp bit masks header.\n");
	return kInvalidInput;
	}
	break;
	case kJpeg_BmpCompressionMethod:
	if (24 == bitsPerPixel) {
	inputFormat = kRLE_BmpInputFormat;
	break;
	}
	[[fallthrough]];
	case kPng_BmpCompressionMethod:
	// TODO: Decide if we intend to support this.
	// It is unsupported in the previous version and
	// in chromium. I think it is used mostly for printers.
	SkCodecPrintf("Error: compression format not supported.\n");
	return kUnimplemented;
	case kCMYK_BmpCompressionMethod:
	case kCMYK8BitRLE_BmpCompressionMethod:
	case kCMYK4BitRLE_BmpCompressionMethod:
	// TODO: Same as above.
	SkCodecPrintf("Error: CMYK not supported for bitmap decoding.\n");
	return kUnimplemented;
	default:
	SkCodecPrintf("Error: invalid format for bitmap decoding.\n");
	return kInvalidInput;
	}
	iBuffer.reset();

	// Calculate the number of bytes read so far
	const uint32_t bytesRead = kBmpHeaderBytes + infoBytes + maskBytes;
	if (!inIco && offset < bytesRead) {
	// TODO (msarett): Do we really want to fail if the offset in the header is invalid?
	// Seems like we can just assume that the offset is zero and try to decode?
	// Maybe we don't want to try to decode corrupt images?
	SkCodecPrintf("Error: pixel data offset less than header size.\n");
	return kInvalidInput;
	}



	switch (inputFormat) {
	case kStandard_BmpInputFormat: {
	// BMPs are generally opaque, however BMPs-in-ICOs may contain
	// a transparency mask after the image. Therefore, we mark the
	// alpha as kBinary if the BMP is contained in an ICO.
	// We use \|isOpaque\| to indicate if the BMP itself is opaque.
	SkEncodedInfo::Alpha alpha = inIco ? SkEncodedInfo::kBinary_Alpha :
	SkEncodedInfo::kOpaque_Alpha;
	bool isOpaque = true;

	SkEncodedInfo::Color color;
	uint8_t bitsPerComponent;
	switch (bitsPerPixel) {
	// Palette formats
	case 1:
	case 2:
	case 4:
	case 8:
	// In the case of ICO, kBGRA is actually the closest match,
	// since we will need to apply a transparency mask.
	if (inIco) {
	color = SkEncodedInfo::kBGRA_Color;
	bitsPerComponent = 8;
	} else {
	color = SkEncodedInfo::kPalette_Color;
	bitsPerComponent = (uint8_t) bitsPerPixel;
	}
	break;
	case 24:
	// In the case of ICO, kBGRA is actually the closest match,
	// since we will need to apply a transparency mask.
	color = inIco ? SkEncodedInfo::kBGRA_Color : SkEncodedInfo::kBGR_Color;
	bitsPerComponent = 8;
	break;
	case 32:
	// 32-bit BMP-in-ICOs actually use the alpha channel in place of a
	// transparency mask.
	if (inIco) {
	isOpaque = false;
	alpha = SkEncodedInfo::kUnpremul_Alpha;
	color = SkEncodedInfo::kBGRA_Color;
	} else {
	color = SkEncodedInfo::kBGRX_Color;
	}
	bitsPerComponent = 8;
	break;
	default:
	SkCodecPrintf("Error: invalid input value for bits per pixel.\n");
	return kInvalidInput;
	}

	if (codecOut) {
	// We require streams to have a memory base for Bmp-in-Ico decodes.
	SkASSERT(!inIco \|\| nullptr != stream->getMemoryBase());

	// Set the image info and create a codec.
	auto info = SkEncodedInfo::Make(width, height, color, alpha, bitsPerComponent);
	*codecOut = std::make_unique<SkBmpStandardCodec>(std::move(info),
	std::unique_ptr<SkStream>(stream),
	bitsPerPixel, numColors, bytesPerColor,
	offset - bytesRead, rowOrder, isOpaque,
	inIco);
	return static_cast<SkBmpStandardCodec*>(codecOut->get())->didCreateSrcBuffer()
	? kSuccess : kInvalidInput;
	}
	return kSuccess;
	}

	case kBitMask_BmpInputFormat: {
	// Bmp-in-Ico must be standard mode
	if (inIco) {
	SkCodecPrintf("Error: Icos may not use bit mask format.\n");
	return kInvalidInput;
	}

	switch (bitsPerPixel) {
	case 16:
	case 24:
	case 32:
	break;
	default:
	SkCodecPrintf("Error: invalid input value for bits per pixel.\n");
	return kInvalidInput;
	}

	// Skip to the start of the pixel array.
	// We can do this here because there is no color table to read
	// in bit mask mode.
	if (stream->skip(offset - bytesRead) != offset - bytesRead) {
	SkCodecPrintf("Error: unable to skip to image data.\n");
	return kIncompleteInput;
	}

	if (codecOut) {
	// Check that input bit masks are valid and create the masks object
	SkASSERT(bitsPerPixel % 8 == 0);
	std::unique_ptr<SkMasks> masks(SkMasks::CreateMasks(inputMasks, bitsPerPixel/8));
	if (nullptr == masks) {
	SkCodecPrintf("Error: invalid input masks.\n");
	return kInvalidInput;
	}

	// Masked bmps are not a great fit for SkEncodedInfo, since they have
	// arbitrary component orderings and bits per component. Here we choose
	// somewhat reasonable values - it's ok that we don't match exactly
	// because SkBmpMaskCodec has its own mask swizzler anyway.
	SkEncodedInfo::Color color;
	SkEncodedInfo::Alpha alpha;
	if (masks->getAlphaMask()) {
	color = SkEncodedInfo::kBGRA_Color;
	alpha = SkEncodedInfo::kUnpremul_Alpha;
	} else {
	color = SkEncodedInfo::kBGR_Color;
	alpha = SkEncodedInfo::kOpaque_Alpha;
	}
	auto info = SkEncodedInfo::Make(width, height, color, alpha, 8);
	*codecOut = std::make_unique<SkBmpMaskCodec>(std::move(info),
	std::unique_ptr<SkStream>(stream), bitsPerPixel,
	masks.release(), rowOrder);
	return static_cast<SkBmpMaskCodec*>(codecOut->get())->didCreateSrcBuffer()
	? kSuccess : kInvalidInput;
	}
	return kSuccess;
	}

	case kRLE_BmpInputFormat: {
	// We should not reach this point without a valid value of bitsPerPixel.
	SkASSERT(4 == bitsPerPixel \|\| 8 == bitsPerPixel \|\| 24 == bitsPerPixel);

	// Check for a valid number of total bytes when in RLE mode
	if (totalBytes <= offset) {
	SkCodecPrintf("Error: RLE requires valid input size.\n");
	return kInvalidInput;
	}

	// Bmp-in-Ico must be standard mode
	// When inIco is true, this line cannot be reached, since we
	// require that RLE Bmps have a valid number of totalBytes, and
	// Icos skip the header that contains totalBytes.
	SkASSERT(!inIco);

	if (codecOut) {
	// RLE inputs may skip pixels, leaving them as transparent. This
	// is uncommon, but we cannot be certain that an RLE bmp will be
	// opaque or that we will be able to represent it with a palette.
	// For that reason, we always indicate that we are kBGRA.
	auto info = SkEncodedInfo::Make(width, height, SkEncodedInfo::kBGRA_Color,
	SkEncodedInfo::kBinary_Alpha, 8);
	*codecOut = std::make_unique<SkBmpRLECodec>(std::move(info),
	std::unique_ptr<SkStream>(stream), bitsPerPixel,
	numColors, bytesPerColor, offset - bytesRead,
	rowOrder);
	}
	return kSuccess;
	}
	default:
	SkASSERT(false);
	return kInvalidInput;
	}
	}

	/*
	* Creates a bmp decoder
	* Reads enough of the stream to determine the image format
	*/
	std::unique_ptr<SkCodec> SkBmpCodec::MakeFromStream(std::unique_ptr<SkStream> stream,
	Result* result, bool inIco) {
	std::unique_ptr<SkCodec> codec;
	*result = ReadHeader(stream.get(), inIco, &codec);
	if (codec) {
	// codec has taken ownership of stream, so we do not need to delete it.
	stream.release();
	}
	return kSuccess == *result ? std::move(codec) : nullptr;
	}

	SkBmpCodec::SkBmpCodec(SkEncodedInfo&& info, std::unique_ptr<SkStream> stream,
	uint16_t bitsPerPixel, SkCodec::SkScanlineOrder rowOrder)
	: INHERITED(std::move(info), kXformSrcColorFormat, std::move(stream))
	, fBitsPerPixel(bitsPerPixel)
	, fRowOrder(rowOrder)
	, fSrcRowBytes(SkAlign4(compute_row_bytes(this->dimensions().width(), fBitsPerPixel)))
	, fXformBuffer(nullptr)
	{}

	bool SkBmpCodec::onRewind() {
	return SkBmpCodec::ReadHeader(this->stream(), this->inIco(), nullptr) == kSuccess;
	}

	int32_t SkBmpCodec::getDstRow(int32_t y, int32_t height) const {
	if (SkCodec::kTopDown_SkScanlineOrder == fRowOrder) {
	return y;
	}
	SkASSERT(SkCodec::kBottomUp_SkScanlineOrder == fRowOrder);
	return height - y - 1;
	}

	SkCodec::Result SkBmpCodec::prepareToDecode(const SkImageInfo& dstInfo,
	const SkCodec::Options& options) {
	return this->onPrepareToDecode(dstInfo, options);
	}

	SkCodec::Result SkBmpCodec::onStartScanlineDecode(const SkImageInfo& dstInfo,
	const SkCodec::Options& options) {
	return prepareToDecode(dstInfo, options);
	}

	int SkBmpCodec::onGetScanlines(void* dst, int count, size_t rowBytes) {
	// Create a new image info representing the portion of the image to decode
	SkImageInfo rowInfo = this->dstInfo().makeWH(this->dstInfo().width(), count);

	// Decode the requested rows
	return this->decodeRows(rowInfo, dst, rowBytes, this->options());
	}

	bool SkBmpCodec::skipRows(int count) {
	const size_t bytesToSkip = count * fSrcRowBytes;
	return this->stream()->skip(bytesToSkip) == bytesToSkip;
	}

	bool SkBmpCodec::onSkipScanlines(int count) {
	return this->skipRows(count);
	}