/* * Copyright 2010 The Android Open Source Project * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkPDFImage.h" #include "SkBitmap.h" #include "SkColor.h" #include "SkColorPriv.h" #include "SkData.h" #include "SkFlate.h" #include "SkPDFCatalog.h" #include "SkPixelRef.h" #include "SkRect.h" #include "SkStream.h" #include "SkString.h" #include "SkUnPreMultiply.h" static const int kNoColorTransform = 0; static bool skip_compression(SkPDFCatalog* catalog) { return SkToBool(catalog->getDocumentFlags() & SkPDFDocument::kFavorSpeedOverSize_Flags); } static size_t get_uncompressed_size(const SkBitmap& bitmap, const SkIRect& srcRect) { switch (bitmap.colorType()) { case kIndex_8_SkColorType: return srcRect.width() * srcRect.height(); case kARGB_4444_SkColorType: return ((srcRect.width() * 3 + 1) / 2) * srcRect.height(); case kRGB_565_SkColorType: return srcRect.width() * 3 * srcRect.height(); case kRGBA_8888_SkColorType: case kBGRA_8888_SkColorType: return srcRect.width() * 3 * srcRect.height(); case kAlpha_8_SkColorType: return 1; default: SkASSERT(false); return 0; } } static SkStream* extract_index8_image(const SkBitmap& bitmap, const SkIRect& srcRect) { const int rowBytes = srcRect.width(); SkStream* stream = SkNEW_ARGS(SkMemoryStream, (get_uncompressed_size(bitmap, srcRect))); uint8_t* dst = (uint8_t*)stream->getMemoryBase(); for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { memcpy(dst, bitmap.getAddr8(srcRect.fLeft, y), rowBytes); dst += rowBytes; } return stream; } static SkStream* extract_argb4444_data(const SkBitmap& bitmap, const SkIRect& srcRect, bool extractAlpha, bool* isOpaque, bool* isTransparent) { SkStream* stream; uint8_t* dst = NULL; if (extractAlpha) { const int alphaRowBytes = (srcRect.width() + 1) / 2; stream = SkNEW_ARGS(SkMemoryStream, (alphaRowBytes * srcRect.height())); } else { stream = SkNEW_ARGS(SkMemoryStream, (get_uncompressed_size(bitmap, srcRect))); } dst = (uint8_t*)stream->getMemoryBase(); for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { uint16_t* src = bitmap.getAddr16(0, y); int x; for (x = srcRect.fLeft; x + 1 < srcRect.fRight; x += 2) { if (extractAlpha) { dst[0] = (SkGetPackedA4444(src[x]) << 4) | SkGetPackedA4444(src[x + 1]); *isOpaque &= dst[0] == SK_AlphaOPAQUE; *isTransparent &= dst[0] == SK_AlphaTRANSPARENT; dst++; } else { dst[0] = (SkGetPackedR4444(src[x]) << 4) | SkGetPackedG4444(src[x]); dst[1] = (SkGetPackedB4444(src[x]) << 4) | SkGetPackedR4444(src[x + 1]); dst[2] = (SkGetPackedG4444(src[x + 1]) << 4) | SkGetPackedB4444(src[x + 1]); dst += 3; } } if (srcRect.width() & 1) { if (extractAlpha) { dst[0] = (SkGetPackedA4444(src[x]) << 4); *isOpaque &= dst[0] == (SK_AlphaOPAQUE & 0xF0); *isTransparent &= dst[0] == (SK_AlphaTRANSPARENT & 0xF0); dst++; } else { dst[0] = (SkGetPackedR4444(src[x]) << 4) | SkGetPackedG4444(src[x]); dst[1] = (SkGetPackedB4444(src[x]) << 4); dst += 2; } } } return stream; } static SkStream* extract_rgb565_image(const SkBitmap& bitmap, const SkIRect& srcRect) { SkStream* stream = SkNEW_ARGS(SkMemoryStream, (get_uncompressed_size(bitmap, srcRect))); uint8_t* dst = (uint8_t*)stream->getMemoryBase(); for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { uint16_t* src = bitmap.getAddr16(0, y); for (int x = srcRect.fLeft; x < srcRect.fRight; x++) { dst[0] = SkGetPackedR16(src[x]); dst[1] = SkGetPackedG16(src[x]); dst[2] = SkGetPackedB16(src[x]); dst += 3; } } return stream; } static uint32_t get_argb8888_neighbor_avg_color(const SkBitmap& bitmap, int xOrig, int yOrig); static SkStream* extract_argb8888_data(const SkBitmap& bitmap, const SkIRect& srcRect, bool extractAlpha, bool* isOpaque, bool* isTransparent) { size_t streamSize = extractAlpha ? srcRect.width() * srcRect.height() : get_uncompressed_size(bitmap, srcRect); SkStream* stream = SkNEW_ARGS(SkMemoryStream, (streamSize)); uint8_t* dst = (uint8_t*)stream->getMemoryBase(); const SkUnPreMultiply::Scale* scaleTable = SkUnPreMultiply::GetScaleTable(); for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { uint32_t* src = bitmap.getAddr32(0, y); for (int x = srcRect.fLeft; x < srcRect.fRight; x++) { SkPMColor c = src[x]; U8CPU alpha = SkGetPackedA32(c); if (extractAlpha) { *isOpaque &= alpha == SK_AlphaOPAQUE; *isTransparent &= alpha == SK_AlphaTRANSPARENT; *dst++ = alpha; } else { if (SK_AlphaTRANSPARENT == alpha) { // It is necessary to average the color component of // transparent pixels with their surrounding neighbors // since the PDF renderer may separately re-sample the // alpha and color channels when the image is not // displayed at its native resolution. Since an alpha of // zero gives no information about the color component, // the pathological case is a white image with sharp // transparency bounds - the color channel goes to black, // and the should-be-transparent pixels are rendered // as grey because of the separate soft mask and color // resizing. c = get_argb8888_neighbor_avg_color(bitmap, x, y); *dst++ = SkGetPackedR32(c); *dst++ = SkGetPackedG32(c); *dst++ = SkGetPackedB32(c); } else { SkUnPreMultiply::Scale s = scaleTable[alpha]; *dst++ = SkUnPreMultiply::ApplyScale(s, SkGetPackedR32(c)); *dst++ = SkUnPreMultiply::ApplyScale(s, SkGetPackedG32(c)); *dst++ = SkUnPreMultiply::ApplyScale(s, SkGetPackedB32(c)); } } } } SkASSERT(dst == streamSize + (uint8_t*)stream->getMemoryBase()); return stream; } static SkStream* extract_a8_alpha(const SkBitmap& bitmap, const SkIRect& srcRect, bool* isOpaque, bool* isTransparent) { const int alphaRowBytes = srcRect.width(); SkStream* stream = SkNEW_ARGS(SkMemoryStream, (alphaRowBytes * srcRect.height())); uint8_t* alphaDst = (uint8_t*)stream->getMemoryBase(); for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { uint8_t* src = bitmap.getAddr8(0, y); for (int x = srcRect.fLeft; x < srcRect.fRight; x++) { alphaDst[0] = src[x]; *isOpaque &= alphaDst[0] == SK_AlphaOPAQUE; *isTransparent &= alphaDst[0] == SK_AlphaTRANSPARENT; alphaDst++; } } return stream; } static SkStream* create_black_image() { SkStream* stream = SkNEW_ARGS(SkMemoryStream, (1)); ((uint8_t*)stream->getMemoryBase())[0] = 0; return stream; } /** * Extract either the color or image data from a SkBitmap into a SkStream. * @param bitmap Bitmap to extract data from. * @param srcRect Region in the bitmap to extract. * @param extractAlpha Set to true to extract the alpha data or false to * extract the color data. * @param isTransparent Pointer to a bool to output whether the alpha is * completely transparent. May be NULL. Only valid when * extractAlpha == true. * @return Unencoded image data, or NULL if either data was not * available or alpha data was requested but the image was * entirely transparent or opaque. */ static SkStream* extract_image_data(const SkBitmap& bitmap, const SkIRect& srcRect, bool extractAlpha, bool* isTransparent) { SkColorType colorType = bitmap.colorType(); if (extractAlpha && (kIndex_8_SkColorType == colorType || kRGB_565_SkColorType == colorType)) { if (isTransparent != NULL) { *isTransparent = false; } return NULL; } bool isOpaque = true; bool transparent = extractAlpha; SkStream* stream = NULL; SkAutoLockPixels lock(bitmap); if (NULL == bitmap.getPixels()) { return NULL; } switch (colorType) { case kIndex_8_SkColorType: if (!extractAlpha) { stream = extract_index8_image(bitmap, srcRect); } break; case kARGB_4444_SkColorType: stream = extract_argb4444_data(bitmap, srcRect, extractAlpha, &isOpaque, &transparent); break; case kRGB_565_SkColorType: if (!extractAlpha) { stream = extract_rgb565_image(bitmap, srcRect); } break; case kN32_SkColorType: stream = extract_argb8888_data(bitmap, srcRect, extractAlpha, &isOpaque, &transparent); break; case kAlpha_8_SkColorType: if (!extractAlpha) { stream = create_black_image(); } else { stream = extract_a8_alpha(bitmap, srcRect, &isOpaque, &transparent); } break; default: SkASSERT(false); } if (isTransparent != NULL) { *isTransparent = transparent; } if (extractAlpha && (transparent || isOpaque)) { SkSafeUnref(stream); return NULL; } return stream; } static SkPDFArray* make_indexed_color_space(SkColorTable* table) { SkPDFArray* result = new SkPDFArray(); result->reserve(4); result->appendName("Indexed"); result->appendName("DeviceRGB"); result->appendInt(table->count() - 1); // Potentially, this could be represented in fewer bytes with a stream. // Max size as a string is 1.5k. SkString index; for (int i = 0; i < table->count(); i++) { char buf[3]; SkColor color = SkUnPreMultiply::PMColorToColor((*table)[i]); buf[0] = SkGetPackedR32(color); buf[1] = SkGetPackedG32(color); buf[2] = SkGetPackedB32(color); index.append(buf, 3); } result->append(new SkPDFString(index))->unref(); return result; } /** * Removes the alpha component of an ARGB color (including unpremultiply) while * keeping the output in the same format as the input. */ static uint32_t remove_alpha_argb8888(uint32_t pmColor) { SkColor color = SkUnPreMultiply::PMColorToColor(pmColor); return SkPackARGB32NoCheck(SK_AlphaOPAQUE, SkColorGetR(color), SkColorGetG(color), SkColorGetB(color)); } static uint16_t remove_alpha_argb4444(uint16_t pmColor) { return SkPixel32ToPixel4444( remove_alpha_argb8888(SkPixel4444ToPixel32(pmColor))); } static uint32_t get_argb8888_neighbor_avg_color(const SkBitmap& bitmap, int xOrig, int yOrig) { uint8_t count = 0; uint16_t r = 0; uint16_t g = 0; uint16_t b = 0; for (int y = yOrig - 1; y <= yOrig + 1; y++) { if (y < 0 || y >= bitmap.height()) { continue; } uint32_t* src = bitmap.getAddr32(0, y); for (int x = xOrig - 1; x <= xOrig + 1; x++) { if (x < 0 || x >= bitmap.width()) { continue; } if (SkGetPackedA32(src[x]) != SK_AlphaTRANSPARENT) { uint32_t color = remove_alpha_argb8888(src[x]); r += SkGetPackedR32(color); g += SkGetPackedG32(color); b += SkGetPackedB32(color); count++; } } } if (count == 0) { return SkPackARGB32NoCheck(SK_AlphaOPAQUE, 0, 0, 0); } else { return SkPackARGB32NoCheck(SK_AlphaOPAQUE, r / count, g / count, b / count); } } static uint16_t get_argb4444_neighbor_avg_color(const SkBitmap& bitmap, int xOrig, int yOrig) { uint8_t count = 0; uint8_t r = 0; uint8_t g = 0; uint8_t b = 0; for (int y = yOrig - 1; y <= yOrig + 1; y++) { if (y < 0 || y >= bitmap.height()) { continue; } uint16_t* src = bitmap.getAddr16(0, y); for (int x = xOrig - 1; x <= xOrig + 1; x++) { if (x < 0 || x >= bitmap.width()) { continue; } if ((SkGetPackedA4444(src[x]) & 0x0F) != SK_AlphaTRANSPARENT) { uint16_t color = remove_alpha_argb4444(src[x]); r += SkGetPackedR4444(color); g += SkGetPackedG4444(color); b += SkGetPackedB4444(color); count++; } } } if (count == 0) { return SkPackARGB4444(SK_AlphaOPAQUE & 0x0F, 0, 0, 0); } else { return SkPackARGB4444(SK_AlphaOPAQUE & 0x0F, r / count, g / count, b / count); } } static SkBitmap unpremultiply_bitmap(const SkBitmap& bitmap, const SkIRect& srcRect) { SkBitmap outBitmap; outBitmap.allocPixels(bitmap.info().makeWH(srcRect.width(), srcRect.height())); int dstRow = 0; SkAutoLockPixels outBitmapPixelLock(outBitmap); SkAutoLockPixels bitmapPixelLock(bitmap); switch (bitmap.colorType()) { case kARGB_4444_SkColorType: { for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { uint16_t* dst = outBitmap.getAddr16(0, dstRow); uint16_t* src = bitmap.getAddr16(0, y); for (int x = srcRect.fLeft; x < srcRect.fRight; x++) { uint8_t a = SkGetPackedA4444(src[x]); // It is necessary to average the color component of // transparent pixels with their surrounding neighbors // since the PDF renderer may separately re-sample the // alpha and color channels when the image is not // displayed at its native resolution. Since an alpha of // zero gives no information about the color component, // the pathological case is a white image with sharp // transparency bounds - the color channel goes to black, // and the should-be-transparent pixels are rendered // as grey because of the separate soft mask and color // resizing. if (a == (SK_AlphaTRANSPARENT & 0x0F)) { *dst = get_argb4444_neighbor_avg_color(bitmap, x, y); } else { *dst = remove_alpha_argb4444(src[x]); } dst++; } dstRow++; } break; } case kN32_SkColorType: { for (int y = srcRect.fTop; y < srcRect.fBottom; y++) { uint32_t* dst = outBitmap.getAddr32(0, dstRow); uint32_t* src = bitmap.getAddr32(0, y); for (int x = srcRect.fLeft; x < srcRect.fRight; x++) { uint8_t a = SkGetPackedA32(src[x]); if (a == SK_AlphaTRANSPARENT) { *dst = get_argb8888_neighbor_avg_color(bitmap, x, y); } else { *dst = remove_alpha_argb8888(src[x]); } dst++; } dstRow++; } break; } default: SkASSERT(false); } outBitmap.setImmutable(); return outBitmap; } // static SkPDFImage* SkPDFImage::CreateImage(const SkBitmap& bitmap, const SkIRect& srcRect, SkPicture::EncodeBitmap encoder) { if (bitmap.colorType() == kUnknown_SkColorType) { return NULL; } bool isTransparent = false; SkAutoTUnref alphaData; if (!bitmap.isOpaque()) { // Note that isOpaque is not guaranteed to return false for bitmaps // with alpha support but a completely opaque alpha channel, // so alphaData may still be NULL if we have a completely opaque // (or transparent) bitmap. alphaData.reset( extract_image_data(bitmap, srcRect, true, &isTransparent)); } if (isTransparent) { return NULL; } SkPDFImage* image; SkColorType colorType = bitmap.colorType(); if (alphaData.get() != NULL && (kN32_SkColorType == colorType || kARGB_4444_SkColorType == colorType)) { if (kN32_SkColorType == colorType) { image = SkNEW_ARGS(SkPDFImage, (NULL, bitmap, false, SkIRect::MakeWH(srcRect.width(), srcRect.height()), encoder)); } else { SkBitmap unpremulBitmap = unpremultiply_bitmap(bitmap, srcRect); image = SkNEW_ARGS(SkPDFImage, (NULL, unpremulBitmap, false, SkIRect::MakeWH(srcRect.width(), srcRect.height()), encoder)); } } else { image = SkNEW_ARGS(SkPDFImage, (NULL, bitmap, false, srcRect, encoder)); } if (alphaData.get() != NULL) { SkAutoTUnref mask( SkNEW_ARGS(SkPDFImage, (alphaData.get(), bitmap, true, srcRect, NULL))); image->addSMask(mask); } return image; } SkPDFImage::~SkPDFImage() { fResources.unrefAll(); } SkPDFImage* SkPDFImage::addSMask(SkPDFImage* mask) { fResources.push(mask); mask->ref(); insert("SMask", new SkPDFObjRef(mask))->unref(); return mask; } void SkPDFImage::getResources(const SkTSet& knownResourceObjects, SkTSet* newResourceObjects) { GetResourcesHelper(&fResources, knownResourceObjects, newResourceObjects); } SkPDFImage::SkPDFImage(SkStream* stream, const SkBitmap& bitmap, bool isAlpha, const SkIRect& srcRect, SkPicture::EncodeBitmap encoder) : fIsAlpha(isAlpha), fSrcRect(srcRect), fEncoder(encoder) { if (bitmap.isImmutable()) { fBitmap = bitmap; } else { bitmap.deepCopyTo(&fBitmap); fBitmap.setImmutable(); } if (stream != NULL) { this->setData(stream); fStreamValid = true; } else { fStreamValid = false; } SkColorType colorType = fBitmap.colorType(); insertName("Type", "XObject"); insertName("Subtype", "Image"); bool alphaOnly = (kAlpha_8_SkColorType == colorType); if (!isAlpha && alphaOnly) { // For alpha only images, we stretch a single pixel of black for // the color/shape part. SkAutoTUnref one(new SkPDFInt(1)); insert("Width", one.get()); insert("Height", one.get()); } else { insertInt("Width", fSrcRect.width()); insertInt("Height", fSrcRect.height()); } if (isAlpha || alphaOnly) { insertName("ColorSpace", "DeviceGray"); } else if (kIndex_8_SkColorType == colorType) { SkAutoLockPixels alp(fBitmap); insert("ColorSpace", make_indexed_color_space(fBitmap.getColorTable()))->unref(); } else { insertName("ColorSpace", "DeviceRGB"); } int bitsPerComp = 8; if (kARGB_4444_SkColorType == colorType) { bitsPerComp = 4; } insertInt("BitsPerComponent", bitsPerComp); if (kRGB_565_SkColorType == colorType) { SkASSERT(!isAlpha); SkAutoTUnref zeroVal(new SkPDFInt(0)); SkAutoTUnref scale5Val( new SkPDFScalar(8.2258f)); // 255/2^5-1 SkAutoTUnref scale6Val( new SkPDFScalar(4.0476f)); // 255/2^6-1 SkAutoTUnref decodeValue(new SkPDFArray()); decodeValue->reserve(6); decodeValue->append(zeroVal.get()); decodeValue->append(scale5Val.get()); decodeValue->append(zeroVal.get()); decodeValue->append(scale6Val.get()); decodeValue->append(zeroVal.get()); decodeValue->append(scale5Val.get()); insert("Decode", decodeValue.get()); } } SkPDFImage::SkPDFImage(SkPDFImage& pdfImage) : SkPDFStream(pdfImage), fBitmap(pdfImage.fBitmap), fIsAlpha(pdfImage.fIsAlpha), fSrcRect(pdfImage.fSrcRect), fEncoder(pdfImage.fEncoder), fStreamValid(pdfImage.fStreamValid) { // Nothing to do here - the image params are already copied in SkPDFStream's // constructor, and the bitmap will be regenerated and encoded in // populate. } bool SkPDFImage::populate(SkPDFCatalog* catalog) { if (getState() == kUnused_State) { // Initializing image data for the first time. if (!skip_compression(catalog) && fEncoder && get_uncompressed_size(fBitmap, fSrcRect) > 1) { SkBitmap subset; // Extract subset if (!fBitmap.extractSubset(&subset, fSrcRect)) { return false; } size_t pixelRefOffset = 0; SkAutoTUnref data(fEncoder(&pixelRefOffset, subset)); if (data.get() && data->size() < get_uncompressed_size(fBitmap, fSrcRect)) { this->setData(data.get()); insertName("Filter", "DCTDecode"); insertInt("ColorTransform", kNoColorTransform); insertInt("Length", this->dataSize()); setState(kCompressed_State); return true; } } // Fallback method if (!fStreamValid) { SkAutoTUnref stream( extract_image_data(fBitmap, fSrcRect, fIsAlpha, NULL)); this->setData(stream); fStreamValid = true; } return INHERITED::populate(catalog); } else if (getState() == kNoCompression_State && !skip_compression(catalog) && (SkFlate::HaveFlate() || fEncoder)) { // Compression has not been requested when the stream was first created, // but the new catalog wants it compressed. if (!getSubstitute()) { SkPDFStream* substitute = SkNEW_ARGS(SkPDFImage, (*this)); setSubstitute(substitute); catalog->setSubstitute(this, substitute); } return false; } return true; } #if 0 // reenable when we can figure out the JPEG colorspace namespace { /** * This PDFObject assumes that its constructor was handed * Jpeg-encoded data that can be directly embedded into a PDF. */ class PDFJPEGImage : public SkPDFObject { SkAutoTUnref fData; int fWidth; int fHeight; public: PDFJPEGImage(SkData* data, int width, int height) : fData(SkRef(data)), fWidth(width), fHeight(height) {} virtual void getResources(const SkTSet&, SkTSet*) SK_OVERRIDE {} virtual void emitObject( SkWStream* stream, SkPDFCatalog* catalog, bool indirect) SK_OVERRIDE { if (indirect) { this->emitIndirectObject(stream, catalog); return; } SkASSERT(fData.get()); const char kPrefaceFormat[] = "<<" "/Type /XObject\n" "/Subtype /Image\n" "/Width %d\n" "/Height %d\n" "/ColorSpace /DeviceRGB\n" // or DeviceGray "/BitsPerComponent 8\n" "/Filter /DCTDecode\n" "/ColorTransform 0\n" "/Length " SK_SIZE_T_SPECIFIER "\n" ">> stream\n"; SkString preface( SkStringPrintf(kPrefaceFormat, fWidth, fHeight, fData->size())); const char kPostface[] = "\nendstream"; stream->write(preface.c_str(), preface.size()); stream->write(fData->data(), fData->size()); stream->write(kPostface, sizeof(kPostface)); } }; /** * If the bitmap is not subsetted, return its encoded data, if * availible. */ static inline SkData* ref_encoded_data(const SkBitmap& bm) { if ((NULL == bm.pixelRef()) || !bm.pixelRefOrigin().isZero() || (bm.info().dimensions() != bm.pixelRef()->info().dimensions())) { return NULL; } return bm.pixelRef()->refEncodedData(); } /* * This functions may give false negatives but no false positives. */ static bool is_jfif_jpeg(SkData* data) { if (!data || (data->size() < 11)) { return false; } const uint8_t bytesZeroToThree[] = {0xFF, 0xD8, 0xFF, 0xE0}; const uint8_t bytesSixToTen[] = {'J', 'F', 'I', 'F', 0}; // 0 1 2 3 4 5 6 7 8 9 10 // FF D8 FF E0 ?? ?? 'J' 'F' 'I' 'F' 00 ... return ((0 == memcmp(data->bytes(), bytesZeroToThree, sizeof(bytesZeroToThree))) && (0 == memcmp(data->bytes() + 6, bytesSixToTen, sizeof(bytesSixToTen)))); } } // namespace #endif SkPDFObject* SkPDFCreateImageObject( const SkBitmap& bitmap, const SkIRect& subset, SkPicture::EncodeBitmap encoder) { #if 0 // reenable when we can figure out the JPEG colorspace if (SkIRect::MakeWH(bitmap.width(), bitmap.height()) == subset) { SkAutoTUnref encodedData(ref_encoded_data(bitmap)); if (is_jfif_jpeg(encodedData)) { return SkNEW_ARGS(PDFJPEGImage, (encodedData, bitmap.width(), bitmap.height())); } } #endif return SkPDFImage::CreateImage(bitmap, subset, encoder); }