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Quelle SkPDFBitmap.cpp Sprache: C |
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/* * 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/pdf/SkPDFBitmap.h" #include "include/codec/SkCodec.h" #include "include/codec/SkEncodedOrigin.h" #include "include/codec/SkJpegDecoder.h" #include "include/core/SkAlphaType.h" #include "include/core/SkBitmap.h" #include "include/core/SkColor.h" #include "include/core/SkColorPriv.h" #include "include/core/SkColorSpace.h" #include "include/core/SkColorType.h" #include "include/core/SkData.h" #include "include/core/SkExecutor.h" #include "include/core/SkImage.h" #include "include/core/SkImageInfo.h" #include "include/core/SkPixmap.h" #include "include/core/SkSize.h" #include "include/core/SkStream.h" #include "include/docs/SkPDFDocument.h" #include "include/encode/SkICC.h" #include "include/encode/SkJpegEncoder.h" #include "include/private/SkEncodedInfo.h" #include "include/private/base/SkAssert.h" #include "include/private/base/SkMutex.h" #include "include/private/base/SkTo.h" #include "modules/skcms/skcms.h" #include "src/core/SkTHash.h" #include "src/pdf/SkDeflate.h" #include "src/pdf/SkPDFDocumentPriv.h" #include "src/pdf/SkPDFTypes.h" #include "src/pdf/SkPDFUnion.h" #include <algorithm> #include <array> #include <cstring> #include <functional> #include <memory> #include <optional> #include <utility> /*static*/ const SkEncodedInfo& SkPDFBitmap::GetEncodedInfo(SkCodec& codec) { return codec.getEncodedInfo(); } namespace { // write a single byte to a stream n times. void fill_stream(SkWStream* out, char value, size_t n) { char buffer[4096]; memset(buffer, value, sizeof(buffer)); for (size_t i = 0; i < n / sizeof(buffer); ++i) { out->write(buffer, sizeof(buffer)); } out->write(buffer, n % sizeof(buffer)); } /* 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. e.g.: gm/bitmappremul.cpp */ SkColor get_neighbor_avg_color(const SkPixmap& bm, int xOrig, int yOrig) { SkASSERT(kBGRA_8888_SkColorType == bm.colorType()); unsigned r = 0, g = 0, b = 0, n = 0; // Clamp the range to the edge of the bitmap. int ymin = std::max(0, yOrig - 1); int ymax = std::min(yOrig + 1, bm.height() - 1); int xmin = std::max(0, xOrig - 1); int xmax = std::min(xOrig + 1, bm.width() - 1); for (int y = ymin; y <= ymax; ++y) { const SkColor* scanline = bm.addr32(0, y); for (int x = xmin; x <= xmax; ++x) { SkColor color = scanline[x]; if (color != SK_ColorTRANSPARENT) { r += SkColorGetR(color); g += SkColorGetG(color); b += SkColorGetB(color); n++; } } } return n > 0 ? SkColorSetRGB(SkToU8(r / n), SkToU8(g / n), SkToU8(b / n)) : SK_ColorTRANSPARENT; } enum class SkPDFStreamFormat { DCT, Flate, Uncompressed }; template <typename T> void emit_image_stream(SkPDFDocument* doc, SkPDFIndirectReference ref, T writeStream, SkISize size, SkPDFUnion&& colorSpace, SkPDFIndirectReference sMask, int length, SkPDFStreamFormat format) { SkPDFDict pdfDict("XObject"); pdfDict.insertName("Subtype", "Image"); pdfDict.insertInt("Width", size.width()); pdfDict.insertInt("Height", size.height()); pdfDict.insertUnion("ColorSpace", std::move(colorSpace)); if (sMask) { pdfDict.insertRef("SMask", sMask); } pdfDict.insertInt("BitsPerComponent", 8); #ifdef SK_PDF_BASE85_BINARY auto filters = SkPDFMakeArray(); filters->appendName("ASCII85Decode"); switch (format) { case SkPDFStreamFormat::DCT: filters->appendName("DCTDecode"); break; case SkPDFStreamFormat::Flate: filters->appendName("FlateDecode"); break; case SkPDFStreamFormat::Uncompressed: break; } pdfDict.insertObject("Filter", std::move(filters)); #else switch (format) { case SkPDFStreamFormat::DCT: pdfDict.insertName("Filter", "DCTDecode"); break; case SkPDFStreamFormat::Flate: pdfDict.insertName("Filter", "FlateDecode"); break; case SkPDFStreamFormat::Uncompressed: break; } #endif if (format == SkPDFStreamFormat::DCT) { pdfDict.insertInt("ColorTransform", 0); } pdfDict.insertInt("Length", length); doc->emitStream(pdfDict, std::move(writeStream), ref); } void do_deflated_alpha(const SkPixmap& pm, SkPDFDocument* doc, SkPDFIndirectRefere SkPDF::Metadata::CompressionLevel compressionLevel = doc->metadata().fCompressionLev SkPDFStreamFormat format = compressionLevel == SkPDF::Metadata::CompressionLevel::Non ? SkPDFStreamFormat::Uncompressed : SkPDFStreamFormat::Flate; SkDynamicMemoryWStream buffer; SkWStream* stream = &buffer; std::optional<SkDeflateWStream> deflateWStream; if (format == SkPDFStreamFormat::Flate) { deflateWStream.emplace(&buffer, SkToInt(compressionLevel)); stream = &*deflateWStream; } if (kAlpha_8_SkColorType == pm.colorType()) { SkASSERT(pm.rowBytes() == (size_t)pm.width()); stream->write(pm.addr8(), pm.width() * pm.height()); } else { SkASSERT(pm.alphaType() == kUnpremul_SkAlphaType); SkASSERT(pm.colorType() == kBGRA_8888_SkColorType); SkASSERT(pm.rowBytes() == (size_t)pm.width() * 4); const uint32_t* ptr = pm.addr32(); const uint32_t* stop = ptr + pm.height() * pm.width(); uint8_t byteBuffer[4092]; uint8_t* bufferStop = byteBuffer + std::size(byteBuffer); uint8_t* dst = byteBuffer; while (ptr != stop) { *dst++ = 0xFF & ((*ptr++) >> SK_BGRA_A32_SHIFT); if (dst == bufferStop) { stream->write(byteBuffer, sizeof(byteBuffer)); dst = byteBuffer; } } stream->write(byteBuffer, dst - byteBuffer); } if (deflateWStream) { deflateWStream->finalize(); } #ifdef SK_PDF_BASE85_BINARY SkPDFUtils::Base85Encode(buffer.detachAsStream(), &buffer); #endif int length = SkToInt(buffer.bytesWritten()); emit_image_stream(doc, ref, [&buffer](SkWStream* stream) { buffer.writeToAndReset(stream); }, pm.info().dimensions(), SkPDFUnion::Name("DeviceGray"), SkPDFIndirectReference(), length, format); } SkPDFUnion write_icc_profile(SkPDFDocument* doc, sk_sp<SkData>&& icc, int channels) { SkPDFIndirectReference iccStreamRef; { static SkMutex iccProfileMapMutex; SkAutoMutexExclusive lock(iccProfileMapMutex); SkPDFIndirectReference* ref = doc->fICCProfileMap.find(SkPDFIccProfileKey{icc, channe if (ref) { iccStreamRef = *ref; } else { std::unique_ptr<SkPDFDict> iccStreamDict = SkPDFMakeDict(); iccStreamDict->insertInt("N", channels); iccStreamRef = SkPDFStreamOut(std::move(iccStreamDict), SkMemoryStream::Make(icc), d doc->fICCProfileMap.set(SkPDFIccProfileKey{icc, channels}, iccStreamRef); } } std::unique_ptr<SkPDFArray> iccPDF = SkPDFMakeArray(); iccPDF->appendName("ICCBased"); iccPDF->appendRef(iccStreamRef); return SkPDFUnion::Object(std::move(iccPDF)); } bool icc_channel_mismatch(const skcms_ICCProfile* iccProfile, int expectedChannels) { int iccChannels = -1; if (iccProfile) { iccChannels = skcms_GetInputChannelCount(iccProfile); } return 0 < iccChannels && expectedChannels != iccChannels; } void do_deflated_image(const SkPixmap& pm, SkPDFDocument* doc, bool isOpaque, SkPDFIndirectReference ref) { SkPDFIndirectReference sMask; if (!isOpaque) { sMask = doc->reserveRef(); } SkPDF::Metadata::CompressionLevel compressionLevel = doc->metadata().fCompressionLev SkPDFStreamFormat format = compressionLevel == SkPDF::Metadata::CompressionLevel::Non ? SkPDFStreamFormat::Uncompressed : SkPDFStreamFormat::Flate; SkDynamicMemoryWStream buffer; SkWStream* stream = &buffer; std::optional<SkDeflateWStream> deflateWStream; if (format == SkPDFStreamFormat::Flate) { deflateWStream.emplace(&buffer, SkToInt(compressionLevel)); stream = &*deflateWStream; } SkPDFUnion colorSpace = SkPDFUnion::Name("DeviceGray"); int channels; switch (pm.colorType()) { case kAlpha_8_SkColorType: channels = 1; fill_stream(stream, '\x00', pm.width() * pm.height()); break; case kGray_8_SkColorType: channels = 1; SkASSERT(sMask.fValue = -1); SkASSERT(pm.rowBytes() == (size_t)pm.width()); stream->write(pm.addr8(), pm.width() * pm.height()); break; default: colorSpace = SkPDFUnion::Name("DeviceRGB"); channels = 3; SkASSERT(pm.alphaType() == kUnpremul_SkAlphaType); SkASSERT(pm.colorType() == kBGRA_8888_SkColorType); SkASSERT(pm.rowBytes() == (size_t)pm.width() * 4); uint8_t byteBuffer[3072]; static_assert(std::size(byteBuffer) % 3 == 0, ""); uint8_t* bufferStop = byteBuffer + std::size(byteBuffer); uint8_t* dst = byteBuffer; for (int y = 0; y < pm.height(); ++y) { const SkColor* src = pm.addr32(0, y); for (int x = 0; x < pm.width(); ++x) { SkColor color = *src++; if (SkColorGetA(color) == SK_AlphaTRANSPARENT) { color = get_neighbor_avg_color(pm, x, y); } *dst++ = SkColorGetR(color); *dst++ = SkColorGetG(color); *dst++ = SkColorGetB(color); if (dst == bufferStop) { stream->write(byteBuffer, sizeof(byteBuffer)); dst = byteBuffer; } } } stream->write(byteBuffer, dst - byteBuffer); } if (deflateWStream) { deflateWStream->finalize(); } if (pm.colorSpace()) { skcms_ICCProfile iccProfile; pm.colorSpace()->toProfile(&iccProfile); if (!icc_channel_mismatch(&iccProfile, channels)) { sk_sp<SkData> iccData = SkWriteICCProfile(&iccProfile, ""); colorSpace = write_icc_profile(doc, std::move(iccData), channels); } } #ifdef SK_PDF_BASE85_BINARY SkPDFUtils::Base85Encode(buffer.detachAsStream(), &buffer); #endif int length = SkToInt(buffer.bytesWritten()); emit_image_stream(doc, ref, [&buffer](SkWStream* stream) { buffer.writeToAndReset(stream); }, pm.info().dimensions(), std::move(colorSpace), sMask, length, format); if (!isOpaque) { do_deflated_alpha(pm, doc, sMask); } } bool do_jpeg(sk_sp<SkData> data, SkColorSpace* imageColorSpace, SkPDFDocument* doc, SkISi SkPDFIndirectReference ref) { #ifdef MOZ_SKIA return false; #else static constexpr const SkCodecs::Decoder decoders[] = { SkJpegDecoder::Decoder(), }; std::unique_ptr<SkCodec> codec = SkCodec::MakeFromData(data, decoders); if (!codec) { return false; } SkISize jpegSize = codec->dimensions(); const SkEncodedInfo& encodedInfo = SkPDFBitmap::GetEncodedInfo(*codec); SkEncodedInfo::Color jpegColorType = encodedInfo.color(); SkEncodedOrigin exifOrientation = codec->getOrigin(); bool yuv = jpegColorType == SkEncodedInfo::kYUV_Color; bool goodColorType = yuv || jpegColorType == SkEncodedInfo::kGray_Color; if (jpegSize != size // Safety check. || !goodColorType || kTopLeft_SkEncodedOrigin != exifOrientation) { return false; } #ifdef SK_PDF_BASE85_BINARY SkDynamicMemoryWStream buffer; SkPDFUtils::Base85Encode(SkMemoryStream::MakeDirect(data->data(), data->size()), &buffer); data = buffer.detachAsData(); #endif int channels = yuv ? 3 : 1; SkPDFUnion colorSpace = yuv ? SkPDFUnion::Name("DeviceRGB") : SkPDFUnion::Name("DeviceG if (sk_sp<SkData> encodedIccProfileData = encodedInfo.profileData(); encodedIccProfileData && !icc_channel_mismatch(encodedInfo.profile(), channels)) { colorSpace = write_icc_profile(doc, std::move(encodedIccProfileData), channels); } else if (const skcms_ICCProfile* codecIccProfile = codec->getICCProfile(); codecIccProfile && !icc_channel_mismatch(codecIccProfile, channels)) { sk_sp<SkData> codecIccData = SkWriteICCProfile(codecIccProfile, ""); colorSpace = write_icc_profile(doc, std::move(codecIccData), channels); } else if (imageColorSpace) { skcms_ICCProfile imageIccProfile; imageColorSpace->toProfile(&imageIccProfile); if (!icc_channel_mismatch(&imageIccProfile, channels)) { sk_sp<SkData> imageIccData = SkWriteICCProfile(&imageIccProfile, ""); colorSpace = write_icc_profile(doc, std::move(imageIccData), channels); } } emit_image_stream(doc, ref, [&data](SkWStream* dst) { dst->write(data->data(), data->size()); }, jpegSize, std::move(colorSpace), SkPDFIndirectReference(), SkToInt(data->size()), SkPDFStreamFormat::DCT); return true; #endif } SkBitmap to_pixels(const SkImage* image) { SkBitmap bm; int w = image->width(), h = image->height(); switch (image->colorType()) { case kAlpha_8_SkColorType: bm.allocPixels(SkImageInfo::MakeA8(w, h)); break; case kGray_8_SkColorType: bm.allocPixels(SkImageInfo::Make(w, h, kGray_8_SkColorType, kOpaque_SkAlphaType)); break; default: { // TODO: makeColorSpace(sRGB) or actually tag the images SkAlphaType at = bm.isOpaque() ? kOpaque_SkAlphaType : kUnpremul_SkAlphaType; bm.allocPixels( SkImageInfo::Make(w, h, kBGRA_8888_SkColorType, at, image->refColorSpace())); } } // TODO: support GPU images in PDFs if (!image->readPixels(nullptr, bm.pixmap(), 0, 0)) { bm.eraseColor(SkColorSetARGB(0xFF, 0, 0, 0)); } return bm; } void serialize_image(const SkImage* img, int encodingQuality, SkPDFDocument* doc, SkPDFIndirectReference ref) { SkASSERT(img); SkASSERT(doc); SkASSERT(encodingQuality >= 0); SkISize dimensions = img->dimensions(); if (sk_sp<SkData> data = img->refEncodedData()) { if (do_jpeg(std::move(data), img->colorSpace(), doc, dimensions, ref)) { return; } } SkBitmap bm = to_pixels(img); const SkPixmap& pm = bm.pixmap(); bool isOpaque = pm.isOpaque() || pm.computeIsOpaque(); if (encodingQuality <= 100 && isOpaque) { SkJpegEncoder::Options jOpts; jOpts.fQuality = encodingQuality; SkDynamicMemoryWStream stream; if (SkJpegEncoder::Encode(&stream, pm, jOpts)) { if (do_jpeg(stream.detachAsData(), pm.colorSpace(), doc, dimensions, ref)) { return; } } } do_deflated_image(pm, doc, isOpaque, ref); } } // namespace SkPDFIndirectReference SkPDFSerializeImage(const SkImage* img, SkPDFDocument* doc, int encodingQuality) { SkASSERT(img); SkASSERT(doc); SkPDFIndirectReference ref = doc->reserveRef(); if (SkExecutor* executor = doc->executor()) { SkRef(img); doc->incrementJobCount(); executor->add([img, encodingQuality, doc, ref]() { serialize_image(img, encodingQuality, doc, ref); SkSafeUnref(img); doc->signalJobComplete(); }); return ref; } serialize_image(img, encodingQuality, doc, ref); return ref; }
¤ Dauer der Verarbeitung: 0.12 Sekunden (vorverarbeitet) ¤*© Formatika GbR, Deutschland |
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2026-04-06