static jobject doBuildTileIndex(JNIEnv* env, SkStream* stream) {
    SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
    int width, height;
    if (NULL == decoder) {
        // fail to get decoder, do not forget to free stream
        stream->unref();
        doThrowIOE(env, "Image format not supported");
        return nullObjectReturn("SkImageDecoder::Factory returned null");
    }

    JavaPixelAllocator *javaAllocator = new JavaPixelAllocator(env);
    decoder->setAllocator(javaAllocator);
    javaAllocator->unref();

    if (!decoder->buildTileIndex(stream, &width, &height)) {
        char msg[100];
        snprintf(msg, sizeof(msg), "Image failed to decode using %s decoder",
                decoder->getFormatName());
        // fail to build tile index, do not forget to free stream
        stream->unref();
        doThrowIOE(env, msg);
        return nullObjectReturn("decoder->buildTileIndex returned false");
    }

    SkBitmapRegionDecoder *bm = new SkBitmapRegionDecoder(decoder, stream, width, height);

    return GraphicsJNI::createBitmapRegionDecoder(env, bm);
}
Пример #2
0
bool SkImageRef::prepareBitmap(SkImageDecoder::Mode mode) {
    SkASSERT(&gImageRefMutex == this->mutex());

    if (fErrorInDecoding) {
        return false;
    }

    /*  As soon as we really know our config, we record it, so that on
        subsequent calls to the codec, we are sure we will always get the same
        result.
    */
    if (SkBitmap::kNo_Config != fBitmap.config()) {
        fConfig = fBitmap.config();
    }

    if (NULL != fBitmap.getPixels() ||
            (SkBitmap::kNo_Config != fBitmap.config() &&
             SkImageDecoder::kDecodeBounds_Mode == mode)) {
        return true;
    }

    SkASSERT(fBitmap.getPixels() == NULL);

    fStream->rewind();

    SkImageDecoder* codec;
    if (fFactory) {
        codec = fFactory->newDecoder(fStream);
    } else {
        codec = SkImageDecoder::Factory(fStream);
    }

    if (codec) {
        SkAutoTDelete<SkImageDecoder> ad(codec);

        codec->setSampleSize(fSampleSize);
        codec->setDitherImage(fDoDither);
        if (this->onDecode(codec, fStream, &fBitmap, fConfig, mode)) {
            return true;
        }
    }

#ifdef DUMP_IMAGEREF_LIFECYCLE
    if (NULL == codec) {
        SkDebugf("--- ImageRef: <%s> failed to find codec\n", this->getURI());
    } else {
        SkDebugf("--- ImageRef: <%s> failed in codec for %d mode\n",
                 this->getURI(), mode);
    }
#endif
    fErrorInDecoding = true;
    fBitmap.reset();
    return false;
}
Пример #3
0
    ArcsView() {
        //testparse();
        fSweep = SkIntToScalar(100);
        this->setBGColor(0xFFDDDDDD);
		SkFILEStream stream("c:/test_ba.png");
		SkImageDecoder* dec = sk_libpng_dfactory(&stream);
		//delete dec;
		SkImageDecoder *coder = SkImageDecoder::Factory(&stream);
		coder->decode(&stream, &fbmp, SkColorType::kRGBA_8888_SkColorType, SkImageDecoder::kDecodePixels_Mode);
		delete dec;
    }
Пример #4
0
bool MpoDecoder::decodeBounds()
{
    long bufferSize = mMP_Images[0]->getImageSize() + 2 + 2; //SOI + JPEG + EOI
    mMpoFileStream->rewind();
    if (false == mMpoFileStream->skip(mMP_Images[0]->getOffsetInFile()) ) {
        XLOGE("failed to jump to image data");
        return false;
    }

    char* jpegBuffer = (char*)malloc((unsigned int)bufferSize);
    if (NULL == jpegBuffer) {
        XLOGE("can not allocate memory to hold JPEG data");
        return false;
    }

    if (bufferSize != mMpoFileStream->read(jpegBuffer, bufferSize)) {
        free(jpegBuffer);
        XLOGE("read jpeg data failed");
        return false;
    }
    SkMemoryStream memStream(jpegBuffer, bufferSize);

    int sampleSize = 1;
    int preferSize = 0;
    bool doDither = true;

    SkBitmap* bitmap = new SkBitmap;
    SkBitmap::Config prefConfig = SkBitmap::kNo_Config;
    SkImageDecoder::Mode decodeMode = SkImageDecoder::kDecodeBounds_Mode;
    SkImageDecoder* decoder = SkImageDecoder::Factory(&memStream);
    if (NULL == decoder) {
        XLOGE("SkImageDecoder-Factory() returned false");
        free(jpegBuffer);
        return false;
    }

    decoder->setSampleSize(sampleSize);
    decoder->setDitherImage(doDither);
    //decoder->setPreferSize(preferSize);

    if (!decoder->decode(&memStream, bitmap, prefConfig, decodeMode)) {
        XLOGE("SkImageDecoder-decode() returned false");
        free(jpegBuffer);
        return false;
    }
    //free memory buffer
    free(jpegBuffer);
    mWidth = bitmap->width();
    mHeight = bitmap->height();
    //delete created SkBitmap
    delete bitmap;
    return true;
}
Пример #5
0
bool SkImageRef::prepareBitmap(SkImageDecoder::Mode mode) {

    if (fErrorInDecoding) {
        return false;
    }

    if (NULL != fBitmap.getPixels() ||
            (SkBitmap::kNo_Config != fBitmap.config() &&
             SkImageDecoder::kDecodeBounds_Mode == mode)) {
        return true;
    }

    SkASSERT(fBitmap.getPixels() == NULL);

    if (!fStream->rewind()) {
        SkDEBUGF(("Failed to rewind SkImageRef stream!"));
        return false;
    }

    SkImageDecoder* codec;
    if (fFactory) {
        codec = fFactory->newDecoder(fStream);
    } else {
        codec = SkImageDecoder::Factory(fStream);
    }

    if (codec) {
        SkAutoTDelete<SkImageDecoder> ad(codec);

        codec->setSampleSize(fSampleSize);
        codec->setDitherImage(fDoDither);
        codec->setRequireUnpremultipliedColors(this->info().fAlphaType == kUnpremul_SkAlphaType);
        if (this->onDecode(codec, fStream, &fBitmap, fBitmap.config(), mode)) {
            if (kOpaque_SkAlphaType == fBitmap.alphaType()) {
                this->changeAlphaType(kOpaque_SkAlphaType);
            }
            SkASSERT(this->info() == fBitmap.info());
            return true;
        }
    }

#ifdef DUMP_IMAGEREF_LIFECYCLE
    if (NULL == codec) {
        SkDebugf("--- ImageRef: <%s> failed to find codec\n", this->getURI());
    } else {
        SkDebugf("--- ImageRef: <%s> failed in codec for %d mode\n",
                 this->getURI(), mode);
    }
#endif
    fErrorInDecoding = true;
    fBitmap.reset();
    return false;
}
Пример #6
0
	DecodeView() {
        SkFILEStream stream("/skimages/index.png");
        SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
        if (codec) {
            for (size_t i = 0; i < SK_ARRAY_COUNT(gRec); i++) {
                stream.rewind();
                codec->setDitherImage(gRec[i].fDither);
                codec->decode(&stream, &fBitmap[i], gRec[i].fPrefConfig,
                              SkImageDecoder::kDecodePixels_Mode);
            }
        }
    }
Пример #7
0
bool SkImageDecoder::DecodeStream(SkStream* stream, SkBitmap* bm,
                                  SkBitmap::Config pref, Mode mode) {
    SkASSERT(stream);
    SkASSERT(bm);

    bool success = false;
    SkImageDecoder* codec = SkImageDecoder::Factory(stream);

    if (NULL != codec) {
        success = codec->decode(stream, bm, pref, mode);
        delete codec;
    }
    return success;
}
Пример #8
0
 void onOnceBeforeDraw() override {
     SkImageDecoder* codec = nullptr;
     SkString resourcePath = GetResourcePath("mandrill_512.png");
     SkFILEStream stream(resourcePath.c_str());
     if (stream.isValid()) {
         codec = SkImageDecoder::Factory(&stream);
     }
     if (codec) {
         stream.rewind();
         codec->decode(&stream, &fBM, kN32_SkColorType, SkImageDecoder::kDecodePixels_Mode);
         delete codec;
     } else {
         fBM.allocN32Pixels(1, 1);
         fBM.eraseARGB(255, 255, 0 , 0); // red == bad
     }
 }
Пример #9
0
 void makeBitmap() {
     SkImageDecoder* codec = NULL;
     SkString resourcePath = GetResourcePath(fFilename.c_str());
     SkFILEStream stream(resourcePath.c_str());
     if (stream.isValid()) {
         codec = SkImageDecoder::Factory(&stream);
     }
     if (codec) {
         stream.rewind();
         codec->decode(&stream, &fBM, kN32_SkColorType, SkImageDecoder::kDecodePixels_Mode);
         SkDELETE(codec);
     } else {
         fBM.allocN32Pixels(1, 1);
         *(fBM.getAddr32(0,0)) = 0xFF0000FF; // red == bad
     }
     fSize = fBM.height();
 }
Пример #10
0
int ResSkiaImage::ImageDataToSkBitmap(NVGcontext* ctx, const CStdString& src, CStdValVector* data) {
	int bitmap = 0;
	bool bOpaque = false;

// 	if (!data->m_data)
// 		return 0;
//
// 	SkMemoryStream* stream = data->m_data;
// 	return nvgCreateImageMem(ctx, 0, (unsigned char *)stream->getMemoryBase(), stream->getLength());
	return nvgCreateImageMem(ctx, 0, (unsigned char *)data->GetBuffer(), data->GetSize());

#if 0
	if (-1 != src.Find(L".jpg") || -1 != src.Find(L".png")) { // 这里改为不需要后缀,直接通过文件头判断是何图片类型
		bOpaque = true;
		GDIPlusDecoder(data);
	}

	SkMemoryStream* stream = data->m_data; // GDIPlusDecoder可能会更改m_data
	if (!stream)
		return NULL;

	bitmap = new SkBitmap();
	if (BMPImageReader::decode(false, stream, bitmap))
		return bitmap;
	
	delete bitmap;
	return 0;
#endif

#if 0 // 直接用skia的BMP解压器,会发现png转换而成的BMP32,会丢失alpha通道
	SkImageDecoder* coder = SkImageDecoder::Factory(stream);
	if (!coder) 
		return NULL;

	bitmap = new SkBitmap();

	if (!coder->decode(stream, bitmap, SkBitmap::kARGB_8888_Config, SkImageDecoder::kDecodePixels_Mode)) {
		delete bitmap;
		return NULL;
	}

	bitmap->setIsOpaque(bOpaque);
#endif
	return bitmap;
}
Пример #11
0
SkImageGenerator* SkImageGenerator::NewFromData(SkData* data) {
    if (NULL == data) {
        return NULL;
    }

    SkMemoryStream stream(data->data(), data->size(), false);
    SkImageDecoder* decoder = SkImageDecoder::Factory(&stream);
    if (NULL == decoder) {
        return NULL;
    }

    SkBitmap bm;
    stream.rewind();
    if (!decoder->decode(&stream, &bm, kUnknown_SkColorType, SkImageDecoder::kDecodeBounds_Mode)) {
        SkDELETE(decoder);
        return NULL;
    }

    return SkNEW_ARGS(SkImageDecoderGenerator, (bm.info(), decoder, data));
}
Пример #12
0
 SubpixelTranslateView(const char imageFilename[],
                       float horizontalVelocity,
                       float verticalVelocity)
   : fHorizontalVelocity(horizontalVelocity),
     fVerticalVelocity(verticalVelocity) {
   SkString resourcePath = GetResourcePath(imageFilename);
   SkImageDecoder* codec = NULL;
   SkFILEStream stream(resourcePath.c_str());
   if (stream.isValid()) {
       codec = SkImageDecoder::Factory(&stream);
   }
   if (codec) {
       stream.rewind();
       codec->decode(&stream, &fBM, kN32_SkColorType, SkImageDecoder::kDecodePixels_Mode);
       delete codec;
   } else {
       fBM.allocN32Pixels(1, 1);
       *(fBM.getAddr32(0,0)) = 0xFF0000FF; // red == bad
   }
   fCurPos = SkPoint::Make(0,0);
   fSize = 200;
 }
Пример #13
0
bool SkImageDecoder::DecodeStream(SkStreamRewindable* stream, SkBitmap* bm, SkColorType pref,
                                  Mode mode, Format* format) {
    SkASSERT(stream);
    SkASSERT(bm);

    bool success = false;
    SkImageDecoder* codec = SkImageDecoder::Factory(stream);

    if (codec) {
        success = codec->decode(stream, bm, pref, mode) != kFailure;
        if (success && format) {
            *format = codec->getFormat();
            if (kUnknown_Format == *format) {
                if (stream->rewind()) {
                    *format = GetStreamFormat(stream);
                }
            }
        }
        delete codec;
    }
    return success;
}
Пример #14
0
static bool decodeFile(SkBitmap* bitmap, const char srcPath[]) {
    SkFILEStream stream(srcPath);
    if (!stream.isValid()) {
        SkDebugf("ERROR: bad filename <%s>\n", srcPath);
        return false;
    }

    SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
    if (NULL == codec) {
        SkDebugf("ERROR: no codec found for <%s>\n", srcPath);
        return false;
    }

    SkAutoTDelete<SkImageDecoder> ad(codec);

    stream.rewind();
    if (!codec->decode(&stream, bitmap, SkBitmap::kARGB_8888_Config,
                       SkImageDecoder::kDecodePixels_Mode)) {
        SkDebugf("ERROR: codec failed for <%s>\n", srcPath);
        return false;
    }
    return true;
}
static void decodeFileAndWrite(const char srcPath[]) {
    SkBitmap bitmap;
    SkFILEStream stream(srcPath);
    if (!stream.isValid()) {
        return;
    }

    SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
    if (NULL == codec) {
        return;
    }

    SkAutoTDelete<SkImageDecoder> ad(codec);

    stream.rewind();

    if (!codec->decode(&stream, &bitmap, SkBitmap::kARGB_8888_Config,
                       SkImageDecoder::kDecodePixels_Mode)) {
        return;
    }

    write_bitmap(srcPath, bitmap);
}
Пример #16
0
bool get_bitmap(SkData* fileBits, DiffResource& resource, SkImageDecoder::Mode mode) {
    SkMemoryStream stream(fileBits->data(), fileBits->size());

    SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
    if (NULL == codec) {
        SkDebugf("ERROR: no codec found for <%s>\n", resource.fFullPath.c_str());
        resource.fStatus = DiffResource::kCouldNotDecode_Status;
        return false;
    }

    // In debug, the DLL will automatically be unloaded when this is deleted,
    // but that shouldn't be a problem in release mode.
    SkAutoTDelete<SkImageDecoder> ad(codec);

    stream.rewind();
    if (!codec->decode(&stream, &resource.fBitmap, SkBitmap::kARGB_8888_Config, mode)) {
        SkDebugf("ERROR: codec failed for basePath <%s>\n", resource.fFullPath.c_str());
        resource.fStatus = DiffResource::kCouldNotDecode_Status;
        return false;
    }

    resource.fStatus = DiffResource::kDecoded_Status;
    return true;
}
Пример #17
0
    virtual bool peek(const char tag[], const void* data, size_t length) {
        if (strcmp("npTc", tag) == 0 && length >= sizeof(Res_png_9patch)) {
            Res_png_9patch* patch = (Res_png_9patch*) data;
            size_t patchSize = patch->serializedSize();
            assert(length == patchSize);
            // You have to copy the data because it is owned by the png reader
            Res_png_9patch* patchNew = (Res_png_9patch*) malloc(patchSize);
            memcpy(patchNew, patch, patchSize);
            // this relies on deserialization being done in place
            Res_png_9patch::deserialize(patchNew);
            patchNew->fileToDevice();
            if (fPatchIsValid) {
                free(fPatch);
            }
            fPatch = patchNew;
            //printf("9patch: (%d,%d)-(%d,%d)\n",
            //       fPatch.sizeLeft, fPatch.sizeTop,
            //       fPatch.sizeRight, fPatch.sizeBottom);
            fPatchIsValid = true;

            // now update our host to force index or 32bit config
            // 'cause we don't want 565 predithered, since as a 9patch, we know
            // we will be stretched, and therefore we want to dither afterwards.
            static const SkBitmap::Config gNo565Pref[] = {
                SkBitmap::kIndex8_Config,
                SkBitmap::kIndex8_Config,
                SkBitmap::kARGB_8888_Config,
                SkBitmap::kARGB_8888_Config,
                SkBitmap::kARGB_8888_Config,
                SkBitmap::kARGB_8888_Config,
            };
            fHost->setPrefConfigTable(gNo565Pref);
        } else {
            fPatch = NULL;
        }
        return true;    // keep on decoding
    }
bool RenderSkinNinePatch::decodeAsset(AssetManager* am, const char* filename, NinePatch* ninepatch) {
    Asset* asset = am->open(filename, android::Asset::ACCESS_BUFFER);
    if (!asset) {
        asset = am->openNonAsset(filename, android::Asset::ACCESS_BUFFER);
        if (!asset) {
            return false;
        }
    }

    SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode;
    SkBitmap::Config prefConfig = SkBitmap::kNo_Config;
    SkMemoryStream stream(asset->getBuffer(false), asset->getLength());
    SkImageDecoder* decoder = SkImageDecoder::Factory(&stream);
    if (!decoder) {
        asset->close();
        ALOGE("RenderSkinNinePatch::Failed to create an image decoder");
        return false;
    }

    decoder->setSampleSize(1);
    decoder->setDitherImage(true);
    decoder->setPreferQualityOverSpeed(false);

    NinePatchPeeker peeker(decoder);

    SkAutoTDelete<SkImageDecoder> add(decoder);

    decoder->setPeeker(&peeker);
    if (!decoder->decode(&stream, &ninepatch->m_bitmap, prefConfig, mode, true)) {
        asset->close();
        ALOGE("RenderSkinNinePatch::Failed to decode nine patch asset");
        return false;
    }

    asset->close();
    if (!peeker.fPatch) {
        ALOGE("RenderSkinNinePatch::Patch data not valid");
        return false;
    }
    void** data = &ninepatch->m_serializedPatchData;
    *data = malloc(peeker.fPatch->serializedSize());
    peeker.fPatch->serialize(*data);
    return true;
}
/*
 * nine patch not supported
 *
 * purgeable not supported
 * reportSizeToVM not supported
 */
static jobject nativeDecodeRegion(JNIEnv* env, jobject, SkBitmapRegionDecoder *brd,
                                int start_x, int start_y, int width, int height, jobject options) {
    jobject tileBitmap = NULL;
    SkImageDecoder *decoder = brd->getDecoder();
    int sampleSize = 1;
    SkBitmap::Config prefConfig = SkBitmap::kNo_Config;
    bool doDither = true;
    bool preferQualityOverSpeed = false;

    if (NULL != options) {
        sampleSize = env->GetIntField(options, gOptions_sampleSizeFieldID);
        // initialize these, in case we fail later on
        env->SetIntField(options, gOptions_widthFieldID, -1);
        env->SetIntField(options, gOptions_heightFieldID, -1);
        env->SetObjectField(options, gOptions_mimeFieldID, 0);

        jobject jconfig = env->GetObjectField(options, gOptions_configFieldID);
        prefConfig = GraphicsJNI::getNativeBitmapConfig(env, jconfig);
        doDither = env->GetBooleanField(options, gOptions_ditherFieldID);
        preferQualityOverSpeed = env->GetBooleanField(options,
                gOptions_preferQualityOverSpeedFieldID);
        // Get the bitmap for re-use if it exists.
        tileBitmap = env->GetObjectField(options, gOptions_bitmapFieldID);
    }

    decoder->setDitherImage(doDither);
    decoder->setPreferQualityOverSpeed(preferQualityOverSpeed);
    AutoDecoderCancel   adc(options, decoder);

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (NULL != options && env->GetBooleanField(options, gOptions_mCancelID)) {
        return nullObjectReturn("gOptions_mCancelID");;
    }

    SkIRect region;
    region.fLeft = start_x;
    region.fTop = start_y;
    region.fRight = start_x + width;
    region.fBottom = start_y + height;
    SkBitmap* bitmap = NULL;
    SkTScopedPtr<SkBitmap> adb;

    if (tileBitmap != NULL) {
        // Re-use bitmap.
        bitmap = GraphicsJNI::getNativeBitmap(env, tileBitmap);
    }
    if (bitmap == NULL) {
        bitmap = new SkBitmap;
        adb.reset(bitmap);
    }

    if (!brd->decodeRegion(bitmap, region, prefConfig, sampleSize)) {
        return nullObjectReturn("decoder->decodeRegion returned false");
    }

    // update options (if any)
    if (NULL != options) {
        env->SetIntField(options, gOptions_widthFieldID, bitmap->width());
        env->SetIntField(options, gOptions_heightFieldID, bitmap->height());
        // TODO: set the mimeType field with the data from the codec.
        // but how to reuse a set of strings, rather than allocating new one
        // each time?
        env->SetObjectField(options, gOptions_mimeFieldID,
                            getMimeTypeString(env, decoder->getFormat()));
    }

    SkPixelRef* pr = bitmap->pixelRef();
    // promise we will never change our pixels (great for sharing and pictures)
    // pr->setImmutable();

    if(tileBitmap != NULL) {
      return tileBitmap;
    }

    // detach bitmap from its autodeleter, since we want to own it now
    adb.release();
    JavaPixelAllocator* allocator = (JavaPixelAllocator*) decoder->getAllocator();
    jbyteArray buff = allocator->getStorageObjAndReset();
    return GraphicsJNI::createBitmap(env, bitmap, buff, false, NULL, -1);
}
Пример #20
0
SkBitmap* MpoDecoder::decodeBuffer(JNIEnv* env, jobject options,
                                   SkStream* stream) {
    int sampleSize = 1;
    int preferSize = 0;
    int postproc = 0;
    int postprocflag = 0;
    SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode;
    SkBitmap::Config prefConfig = SkBitmap::kNo_Config;
    bool doDither = true;
    bool isPurgeable = options != NULL &&
                       env->GetBooleanField(options, options_purgeableFieldID);

    if (NULL != options) {
        sampleSize = env->GetIntField(options, options_sampleSizeFieldID);
        //preferSize = env->GetIntField(options, options_preferSizeFieldID);
        //postproc = env->GetBooleanField(options, options_postprocFieldID);
        //postprocflag = env->GetIntField(options, options_postprocflagFieldID);
        if (env->GetBooleanField(options, options_justBoundsFieldID)) {
            mode = SkImageDecoder::kDecodeBounds_Mode;
        }
        // initialize these, in case we fail later on
        env->SetIntField(options, options_widthFieldID, -1);
        env->SetIntField(options, options_heightFieldID, -1);
        env->SetObjectField(options, options_mimeFieldID, 0);

        jobject jconfig = env->GetObjectField(options, options_configFieldID);
        prefConfig = GraphicsJNI::getNativeBitmapConfig(env, jconfig);
        doDither = env->GetBooleanField(options, options_ditherFieldID);
    }

    SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
    if (NULL == decoder) {
        XLOGE("SkImageDecoder-Factory() returned false");
        return NULL;
    }

    decoder->setSampleSize(sampleSize);
    decoder->setDitherImage(doDither);
    //decoder->setPreferSize(preferSize);
    //decoder->setPostProcFlag((postproc | (postprocflag << 4)));

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (NULL != options && env->GetBooleanField(options, options_mCancelID)) {
        XLOGE("Decoding is cancelled by requestCancelDecode");
        return NULL;
    }

    SkImageDecoder::Mode decodeMode = mode;
    if (isPurgeable) {
        decodeMode = SkImageDecoder::kDecodeBounds_Mode;
    }

    SkBitmap* bitmap = new SkBitmap;

    if (!decoder->decode(stream, bitmap, prefConfig, decodeMode)) {
        XLOGE("SkImageDecoder-decode() returned false");
        return NULL;
    }

    // update options (if any)
    if (NULL != options) {
        env->SetIntField(options, options_widthFieldID, bitmap->width());
        env->SetIntField(options, options_heightFieldID, bitmap->height());
        // TODO: set the mimeType field with the data from the codec.
        // but how to reuse a set of strings, rather than allocating new one
        // each time?
        env->SetObjectField(options, options_mimeFieldID,env->NewStringUTF("image/mpo"));
    }

    // if we're in justBounds mode, return now (skip the java bitmap)
    if (SkImageDecoder::kDecodeBounds_Mode == mode) {
        delete bitmap;
        return NULL;
    } else {
        return bitmap;
    }
}
void ImageSource::setData(SharedBuffer* data, bool allDataReceived)
{
#ifdef ANDROID_ANIMATED_GIF
    // This is only necessary if we allow ourselves to partially decode GIF
    if (m_decoder.m_gifDecoder
            && !m_decoder.m_gifDecoder->failed()) {
        m_decoder.m_gifDecoder->setData(data, allDataReceived);
        return;
    }
#endif
    if (NULL == m_decoder.m_image
#ifdef ANDROID_ANIMATED_GIF
          && !m_decoder.m_gifDecoder
#endif
                                            ) {
        SkBitmap tmp;

        SkMemoryStream stream(data->data(), data->size(), false);
        SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
        SkAutoTDelete<SkImageDecoder> ad(codec);
        
        if (!codec || !codec->decode(&stream, &tmp, SkBitmap::kNo_Config,
                                       SkImageDecoder::kDecodeBounds_Mode)) {
            return;
        }

        int origW = tmp.width();
        int origH = tmp.height();

#ifdef ANDROID_ANIMATED_GIF
        // First, check to see if this is an animated GIF
        const Vector<char>& buffer = data->buffer();
        const char* contents = buffer.data();
        if (buffer.size() > 3 && strncmp(contents, "GIF8", 4) == 0 &&
                should_use_animated_gif(origW, origH)) {
            // This means we are looking at a GIF, so create special
            // GIF Decoder
            // Need to wait for all data received if we are assigning an
            // allocator (which we are not at the moment).
            if (!m_decoder.m_gifDecoder /*&& allDataReceived*/)
                m_decoder.m_gifDecoder = new GIFImageDecoder();
            if (!m_decoder.m_gifDecoder->failed())
                m_decoder.m_gifDecoder->setData(data, allDataReceived);
            return;
        }
#endif
        
        int sampleSize = computeSampleSize(tmp);
        if (sampleSize > 1) {
            codec->setSampleSize(sampleSize);
            stream.rewind();
            if (!codec->decode(&stream, &tmp, SkBitmap::kNo_Config,
                                 SkImageDecoder::kDecodeBounds_Mode)) {
                return;
            }
        }

        m_decoder.m_image = new PrivateAndroidImageSourceRec(tmp, origW, origH,
                                                     sampleSize);
        
//        SkDebugf("----- started: [%d %d] %s\n", origW, origH, m_decoder.m_url.c_str());
    }

    PrivateAndroidImageSourceRec* decoder = m_decoder.m_image;
    if (allDataReceived && !decoder->fAllDataReceived) {
        decoder->fAllDataReceived = true;

        SkBitmap* bm = &decoder->bitmap();
        SkPixelRef* ref = convertToRLE(bm, data->data(), data->size());

        if (ref) {
            bm->setPixelRef(ref)->unref();
        } else {
            BitmapAllocatorAndroid alloc(data, decoder->fSampleSize);
            if (!alloc.allocPixelRef(bm, NULL)) {
                return;
            }
            ref = bm->pixelRef();
        }

        // we promise to never change the pixels (makes picture recording fast)
        ref->setImmutable();
        // give it the URL if we have one
        ref->setURI(m_decoder.m_url);
    }
}
status_t BootAnimation::initTexture(const Animation::Frame& frame)
{
    //StopWatch watch("blah");

    SkBitmap bitmap;
    SkMemoryStream  stream(frame.map->getDataPtr(), frame.map->getDataLength());
    SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
    if (codec) {
        codec->setDitherImage(false);
        codec->decode(&stream, &bitmap,
                SkBitmap::kARGB_8888_Config,
                SkImageDecoder::kDecodePixels_Mode);
        delete codec;
    }

    // FileMap memory is never released until application exit.
    // Release it now as the texture is already loaded and the memory used for
    // the packed resource can be released.
    frame.map->release();

    // ensure we can call getPixels(). No need to call unlock, since the
    // bitmap will go out of scope when we return from this method.
    bitmap.lockPixels();

    const int w = bitmap.width();
    const int h = bitmap.height();
    const void* p = bitmap.getPixels();

    GLint crop[4] = { 0, h, w, -h };
    int tw = 1 << (31 - __builtin_clz(w));
    int th = 1 << (31 - __builtin_clz(h));
    if (tw < w) tw <<= 1;
    if (th < h) th <<= 1;

    switch (bitmap.getConfig()) {
        case SkBitmap::kARGB_8888_Config:
            if (tw != w || th != h) {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, tw, th, 0, GL_RGBA,
                        GL_UNSIGNED_BYTE, 0);
                glTexSubImage2D(GL_TEXTURE_2D, 0,
                        0, 0, w, h, GL_RGBA, GL_UNSIGNED_BYTE, p);
            } else {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, tw, th, 0, GL_RGBA,
                        GL_UNSIGNED_BYTE, p);
            }
            break;

        case SkBitmap::kRGB_565_Config:
            if (tw != w || th != h) {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, tw, th, 0, GL_RGB,
                        GL_UNSIGNED_SHORT_5_6_5, 0);
                glTexSubImage2D(GL_TEXTURE_2D, 0,
                        0, 0, w, h, GL_RGB, GL_UNSIGNED_SHORT_5_6_5, p);
            } else {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, tw, th, 0, GL_RGB,
                        GL_UNSIGNED_SHORT_5_6_5, p);
            }
            break;
        default:
            break;
    }

    glTexParameteriv(GL_TEXTURE_2D, GL_TEXTURE_CROP_RECT_OES, crop);

    return NO_ERROR;
}
Пример #23
0
// since we "may" create a purgeable imageref, we require the stream be ref'able
// i.e. dynamically allocated, since its lifetime may exceed the current stack
// frame.
static jobject doDecode(JNIEnv* env, SkStreamRewindable* stream, jobject padding,
        jobject options, bool allowPurgeable, bool forcePurgeable = false) {

    int sampleSize = 1;

    SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode;
    SkBitmap::Config prefConfig = SkBitmap::kARGB_8888_Config;

    bool doDither = true;
    bool isMutable = false;
    float scale = 1.0f;
    bool isPurgeable = forcePurgeable || (allowPurgeable && optionsPurgeable(env, options));
    bool preferQualityOverSpeed = false;
    bool requireUnpremultiplied = false;

    jobject javaBitmap = NULL;

    if (options != NULL) {
        sampleSize = env->GetIntField(options, gOptions_sampleSizeFieldID);
        if (optionsJustBounds(env, options)) {
            mode = SkImageDecoder::kDecodeBounds_Mode;
        }

        // initialize these, in case we fail later on
        env->SetIntField(options, gOptions_widthFieldID, -1);
        env->SetIntField(options, gOptions_heightFieldID, -1);
        env->SetObjectField(options, gOptions_mimeFieldID, 0);

        jobject jconfig = env->GetObjectField(options, gOptions_configFieldID);
        prefConfig = GraphicsJNI::getNativeBitmapConfig(env, jconfig);
        isMutable = env->GetBooleanField(options, gOptions_mutableFieldID);
        doDither = env->GetBooleanField(options, gOptions_ditherFieldID);
        preferQualityOverSpeed = env->GetBooleanField(options,
                gOptions_preferQualityOverSpeedFieldID);
        requireUnpremultiplied = !env->GetBooleanField(options, gOptions_premultipliedFieldID);
        javaBitmap = env->GetObjectField(options, gOptions_bitmapFieldID);

        if (env->GetBooleanField(options, gOptions_scaledFieldID)) {
            const int density = env->GetIntField(options, gOptions_densityFieldID);
            const int targetDensity = env->GetIntField(options, gOptions_targetDensityFieldID);
            const int screenDensity = env->GetIntField(options, gOptions_screenDensityFieldID);
            if (density != 0 && targetDensity != 0 && density != screenDensity) {
                scale = (float) targetDensity / density;
            }
        }
    }

    const bool willScale = scale != 1.0f;
    isPurgeable &= !willScale;

    SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
    if (decoder == NULL) {
        return nullObjectReturn("SkImageDecoder::Factory returned null");
    }

    decoder->setSampleSize(sampleSize);
    decoder->setDitherImage(doDither);
    decoder->setPreferQualityOverSpeed(preferQualityOverSpeed);
    decoder->setRequireUnpremultipliedColors(requireUnpremultiplied);

    SkBitmap* outputBitmap = NULL;
    unsigned int existingBufferSize = 0;
    if (javaBitmap != NULL) {
        outputBitmap = (SkBitmap*) env->GetIntField(javaBitmap, gBitmap_nativeBitmapFieldID);
        if (outputBitmap->isImmutable()) {
            ALOGW("Unable to reuse an immutable bitmap as an image decoder target.");
            javaBitmap = NULL;
            outputBitmap = NULL;
        } else {
            existingBufferSize = GraphicsJNI::getBitmapAllocationByteCount(env, javaBitmap);
        }
    }

    SkAutoTDelete<SkBitmap> adb(outputBitmap == NULL ? new SkBitmap : NULL);
    if (outputBitmap == NULL) outputBitmap = adb.get();

    NinePatchPeeker peeker(decoder);
    decoder->setPeeker(&peeker);

    SkImageDecoder::Mode decodeMode = isPurgeable ? SkImageDecoder::kDecodeBounds_Mode : mode;

    JavaPixelAllocator javaAllocator(env);
    RecyclingPixelAllocator recyclingAllocator(outputBitmap->pixelRef(), existingBufferSize);
    ScaleCheckingAllocator scaleCheckingAllocator(scale, existingBufferSize);
    SkBitmap::Allocator* outputAllocator = (javaBitmap != NULL) ?
            (SkBitmap::Allocator*)&recyclingAllocator : (SkBitmap::Allocator*)&javaAllocator;
    if (decodeMode != SkImageDecoder::kDecodeBounds_Mode) {
        if (!willScale) {
            // If the java allocator is being used to allocate the pixel memory, the decoder
            // need not write zeroes, since the memory is initialized to 0.
            decoder->setSkipWritingZeroes(outputAllocator == &javaAllocator);
            decoder->setAllocator(outputAllocator);
        } else if (javaBitmap != NULL) {
            // check for eventual scaled bounds at allocation time, so we don't decode the bitmap
            // only to find the scaled result too large to fit in the allocation
            decoder->setAllocator(&scaleCheckingAllocator);
        }
    }

    // Only setup the decoder to be deleted after its stack-based, refcounted
    // components (allocators, peekers, etc) are declared. This prevents RefCnt
    // asserts from firing due to the order objects are deleted from the stack.
    SkAutoTDelete<SkImageDecoder> add(decoder);

    AutoDecoderCancel adc(options, decoder);

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (options != NULL && env->GetBooleanField(options, gOptions_mCancelID)) {
        return nullObjectReturn("gOptions_mCancelID");
    }

    SkBitmap decodingBitmap;
    if (!decoder->decode(stream, &decodingBitmap, prefConfig, decodeMode)) {
        return nullObjectReturn("decoder->decode returned false");
    }

    int scaledWidth = decodingBitmap.width();
    int scaledHeight = decodingBitmap.height();

    if (willScale && mode != SkImageDecoder::kDecodeBounds_Mode) {
        scaledWidth = int(scaledWidth * scale + 0.5f);
        scaledHeight = int(scaledHeight * scale + 0.5f);
    }

    // update options (if any)
    if (options != NULL) {
        env->SetIntField(options, gOptions_widthFieldID, scaledWidth);
        env->SetIntField(options, gOptions_heightFieldID, scaledHeight);
        env->SetObjectField(options, gOptions_mimeFieldID,
                getMimeTypeString(env, decoder->getFormat()));
    }

    // if we're in justBounds mode, return now (skip the java bitmap)
    if (mode == SkImageDecoder::kDecodeBounds_Mode) {
        return NULL;
    }

    jbyteArray ninePatchChunk = NULL;
    if (peeker.fPatch != NULL) {
        if (willScale) {
            scaleNinePatchChunk(peeker.fPatch, scale);
        }

        size_t ninePatchArraySize = peeker.fPatch->serializedSize();
        ninePatchChunk = env->NewByteArray(ninePatchArraySize);
        if (ninePatchChunk == NULL) {
            return nullObjectReturn("ninePatchChunk == null");
        }

        jbyte* array = (jbyte*) env->GetPrimitiveArrayCritical(ninePatchChunk, NULL);
        if (array == NULL) {
            return nullObjectReturn("primitive array == null");
        }

        peeker.fPatch->serialize(array);
        env->ReleasePrimitiveArrayCritical(ninePatchChunk, array, 0);
    }

    jintArray layoutBounds = NULL;
    if (peeker.fLayoutBounds != NULL) {
        layoutBounds = env->NewIntArray(4);
        if (layoutBounds == NULL) {
            return nullObjectReturn("layoutBounds == null");
        }

        jint scaledBounds[4];
        if (willScale) {
            for (int i=0; i<4; i++) {
                scaledBounds[i] = (jint)((((jint*)peeker.fLayoutBounds)[i]*scale) + .5f);
            }
        } else {
            memcpy(scaledBounds, (jint*)peeker.fLayoutBounds, sizeof(scaledBounds));
        }
        env->SetIntArrayRegion(layoutBounds, 0, 4, scaledBounds);
        if (javaBitmap != NULL) {
            env->SetObjectField(javaBitmap, gBitmap_layoutBoundsFieldID, layoutBounds);
        }
    }

    if (willScale) {
        // This is weird so let me explain: we could use the scale parameter
        // directly, but for historical reasons this is how the corresponding
        // Dalvik code has always behaved. We simply recreate the behavior here.
        // The result is slightly different from simply using scale because of
        // the 0.5f rounding bias applied when computing the target image size
        const float sx = scaledWidth / float(decodingBitmap.width());
        const float sy = scaledHeight / float(decodingBitmap.height());

        // TODO: avoid copying when scaled size equals decodingBitmap size
        SkBitmap::Config config = configForScaledOutput(decodingBitmap.config());
        outputBitmap->setConfig(config, scaledWidth, scaledHeight);
        outputBitmap->setIsOpaque(decodingBitmap.isOpaque());
        if (!outputBitmap->allocPixels(outputAllocator, NULL)) {
            return nullObjectReturn("allocation failed for scaled bitmap");
        }

        // If outputBitmap's pixels are newly allocated by Java, there is no need
        // to erase to 0, since the pixels were initialized to 0.
        if (outputAllocator != &javaAllocator) {
            outputBitmap->eraseColor(0);
        }

        SkPaint paint;
        paint.setFilterBitmap(true);

        SkCanvas canvas(*outputBitmap);
        canvas.scale(sx, sy);
        canvas.drawBitmap(decodingBitmap, 0.0f, 0.0f, &paint);
    } else {
        outputBitmap->swap(decodingBitmap);
    }

    if (padding) {
        if (peeker.fPatch != NULL) {
            GraphicsJNI::set_jrect(env, padding,
                    peeker.fPatch->paddingLeft, peeker.fPatch->paddingTop,
                    peeker.fPatch->paddingRight, peeker.fPatch->paddingBottom);
        } else {
            GraphicsJNI::set_jrect(env, padding, -1, -1, -1, -1);
        }
    }

    SkPixelRef* pr;
    if (isPurgeable) {
        pr = installPixelRef(outputBitmap, stream, sampleSize, doDither);
    } else {
        // if we get here, we're in kDecodePixels_Mode and will therefore
        // already have a pixelref installed.
        pr = outputBitmap->pixelRef();
    }
    if (pr == NULL) {
        return nullObjectReturn("Got null SkPixelRef");
    }

    if (!isMutable && javaBitmap == NULL) {
        // promise we will never change our pixels (great for sharing and pictures)
        pr->setImmutable();
    }

    // detach bitmap from its autodeleter, since we want to own it now
    adb.detach();

    if (javaBitmap != NULL) {
        bool isPremultiplied = !requireUnpremultiplied;
        GraphicsJNI::reinitBitmap(env, javaBitmap, outputBitmap, isPremultiplied);
        outputBitmap->notifyPixelsChanged();
        // If a java bitmap was passed in for reuse, pass it back
        return javaBitmap;
    }

    int bitmapCreateFlags = 0x0;
    if (isMutable) bitmapCreateFlags |= GraphicsJNI::kBitmapCreateFlag_Mutable;
    if (!requireUnpremultiplied) bitmapCreateFlags |= GraphicsJNI::kBitmapCreateFlag_Premultiplied;

    // now create the java bitmap
    return GraphicsJNI::createBitmap(env, outputBitmap, javaAllocator.getStorageObj(),
            bitmapCreateFlags, ninePatchChunk, layoutBounds, -1);
}
/*
 * nine patch not supported
 *
 * purgeable not supported
 * reportSizeToVM not supported
 */
static jobject nativeDecodeRegion(JNIEnv* env, jobject, jlong brdHandle,
                                jint start_x, jint start_y, jint width, jint height, jobject options) {
    SkBitmapRegionDecoder *brd = reinterpret_cast<SkBitmapRegionDecoder*>(brdHandle);
    jobject tileBitmap = NULL;
    SkImageDecoder *decoder = brd->getDecoder();
    int sampleSize = 1;
    SkColorType prefColorType = kUnknown_SkColorType;
    bool doDither = true;
    bool preferQualityOverSpeed = false;
    bool requireUnpremultiplied = false;

    if (NULL != options) {
        sampleSize = env->GetIntField(options, gOptions_sampleSizeFieldID);
        // initialize these, in case we fail later on
        env->SetIntField(options, gOptions_widthFieldID, -1);
        env->SetIntField(options, gOptions_heightFieldID, -1);
        env->SetObjectField(options, gOptions_mimeFieldID, 0);

        jobject jconfig = env->GetObjectField(options, gOptions_configFieldID);
        prefColorType = GraphicsJNI::getNativeBitmapColorType(env, jconfig);
        doDither = env->GetBooleanField(options, gOptions_ditherFieldID);
        preferQualityOverSpeed = env->GetBooleanField(options,
                gOptions_preferQualityOverSpeedFieldID);
        // Get the bitmap for re-use if it exists.
        tileBitmap = env->GetObjectField(options, gOptions_bitmapFieldID);
        requireUnpremultiplied = !env->GetBooleanField(options, gOptions_premultipliedFieldID);
    }

    decoder->setDitherImage(doDither);
    decoder->setPreferQualityOverSpeed(preferQualityOverSpeed);
    decoder->setRequireUnpremultipliedColors(requireUnpremultiplied);
    AutoDecoderCancel adc(options, decoder);

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (NULL != options && env->GetBooleanField(options, gOptions_mCancelID)) {
        return nullObjectReturn("gOptions_mCancelID");;
    }

    SkIRect region;
    region.fLeft = start_x;
    region.fTop = start_y;
    region.fRight = start_x + width;
    region.fBottom = start_y + height;
    SkBitmap* bitmap = NULL;
    SkAutoTDelete<SkBitmap> adb;

    if (tileBitmap != NULL) {
        // Re-use bitmap.
        bitmap = GraphicsJNI::getNativeBitmap(env, tileBitmap);
    }
    if (bitmap == NULL) {
        bitmap = new SkBitmap;
        adb.reset(bitmap);
    }

    if (!brd->decodeRegion(bitmap, region, prefColorType, sampleSize)) {
        return nullObjectReturn("decoder->decodeRegion returned false");
    }

    // update options (if any)
    if (NULL != options) {
        env->SetIntField(options, gOptions_widthFieldID, bitmap->width());
        env->SetIntField(options, gOptions_heightFieldID, bitmap->height());
        // TODO: set the mimeType field with the data from the codec.
        // but how to reuse a set of strings, rather than allocating new one
        // each time?
        env->SetObjectField(options, gOptions_mimeFieldID,
                            getMimeTypeString(env, decoder->getFormat()));
    }

    if (tileBitmap != NULL) {
        return tileBitmap;
    }

    // detach bitmap from its autodeleter, since we want to own it now
    adb.detach();

    JavaPixelAllocator* allocator = (JavaPixelAllocator*) decoder->getAllocator();
    jbyteArray buff = allocator->getStorageObjAndReset();

    int bitmapCreateFlags = 0;
    if (!requireUnpremultiplied) bitmapCreateFlags |= GraphicsJNI::kBitmapCreateFlag_Premultiplied;
    return GraphicsJNI::createBitmap(env, bitmap, buff, bitmapCreateFlags, NULL, NULL, -1);
}
// since we "may" create a purgeable imageref, we require the stream be ref'able
// i.e. dynamically allocated, since its lifetime may exceed the current stack
// frame.
static jobject doDecode(JNIEnv* env, SkStream* stream, jobject padding,
                        jobject options, bool allowPurgeable, bool forcePurgeable = false,
                        bool applyScale = false, float scale = 1.0f) {

    int sampleSize = 1;

    SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode;
    SkBitmap::Config prefConfig = SkBitmap::kARGB_8888_Config;

    bool doDither = true;
    bool isMutable = false;
    bool willScale = applyScale && scale != 1.0f;
    bool isPurgeable = !willScale &&
                       (forcePurgeable || (allowPurgeable && optionsPurgeable(env, options)));
    bool preferQualityOverSpeed = false;

    jobject javaBitmap = NULL;

    if (options != NULL) {
        sampleSize = env->GetIntField(options, gOptions_sampleSizeFieldID);
        if (optionsJustBounds(env, options)) {
            mode = SkImageDecoder::kDecodeBounds_Mode;
        }

        // initialize these, in case we fail later on
        env->SetIntField(options, gOptions_widthFieldID, -1);
        env->SetIntField(options, gOptions_heightFieldID, -1);
        env->SetObjectField(options, gOptions_mimeFieldID, 0);

        jobject jconfig = env->GetObjectField(options, gOptions_configFieldID);
        prefConfig = GraphicsJNI::getNativeBitmapConfig(env, jconfig);
        isMutable = env->GetBooleanField(options, gOptions_mutableFieldID);
        doDither = env->GetBooleanField(options, gOptions_ditherFieldID);
        preferQualityOverSpeed = env->GetBooleanField(options,
                                 gOptions_preferQualityOverSpeedFieldID);
        javaBitmap = env->GetObjectField(options, gOptions_bitmapFieldID);
    }

    if (willScale && javaBitmap != NULL) {
        return nullObjectReturn("Cannot pre-scale a reused bitmap");
    }

    SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
    if (decoder == NULL) {
        return nullObjectReturn("SkImageDecoder::Factory returned null");
    }

    decoder->setSampleSize(sampleSize);
    decoder->setDitherImage(doDither);
    decoder->setPreferQualityOverSpeed(preferQualityOverSpeed);

    NinePatchPeeker peeker(decoder);
    JavaPixelAllocator javaAllocator(env);

    SkBitmap* bitmap;
    if (javaBitmap == NULL) {
        bitmap = new SkBitmap;
    } else {
        if (sampleSize != 1) {
            return nullObjectReturn("SkImageDecoder: Cannot reuse bitmap with sampleSize != 1");
        }
        bitmap = (SkBitmap*) env->GetIntField(javaBitmap, gBitmap_nativeBitmapFieldID);
        // config of supplied bitmap overrules config set in options
        prefConfig = bitmap->getConfig();
    }

    SkAutoTDelete<SkImageDecoder> add(decoder);
    SkAutoTDelete<SkBitmap> adb(bitmap, javaBitmap == NULL);

    decoder->setPeeker(&peeker);
    if (!isPurgeable) {
        decoder->setAllocator(&javaAllocator);
    }

    AutoDecoderCancel adc(options, decoder);

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (options != NULL && env->GetBooleanField(options, gOptions_mCancelID)) {
        return nullObjectReturn("gOptions_mCancelID");
    }

    SkImageDecoder::Mode decodeMode = mode;
    if (isPurgeable) {
        decodeMode = SkImageDecoder::kDecodeBounds_Mode;
    }

    SkBitmap* decoded;
    if (willScale) {
        decoded = new SkBitmap;
    } else {
        decoded = bitmap;
    }
    SkAutoTDelete<SkBitmap> adb2(willScale ? decoded : NULL);

    if (!decoder->decode(stream, decoded, prefConfig, decodeMode, javaBitmap != NULL)) {
        return nullObjectReturn("decoder->decode returned false");
    }

    int scaledWidth = decoded->width();
    int scaledHeight = decoded->height();

    if (willScale && mode != SkImageDecoder::kDecodeBounds_Mode) {
        scaledWidth = int(scaledWidth * scale + 0.5f);
        scaledHeight = int(scaledHeight * scale + 0.5f);
    }

    // update options (if any)
    if (options != NULL) {
        env->SetIntField(options, gOptions_widthFieldID, scaledWidth);
        env->SetIntField(options, gOptions_heightFieldID, scaledHeight);
        env->SetObjectField(options, gOptions_mimeFieldID,
                            getMimeTypeString(env, decoder->getFormat()));
    }

    // if we're in justBounds mode, return now (skip the java bitmap)
    if (mode == SkImageDecoder::kDecodeBounds_Mode) {
        return NULL;
    }

    jbyteArray ninePatchChunk = NULL;
    if (peeker.fPatch != NULL) {
        if (willScale) {
            scaleNinePatchChunk(peeker.fPatch, scale);
        }

        size_t ninePatchArraySize = peeker.fPatch->serializedSize();
        ninePatchChunk = env->NewByteArray(ninePatchArraySize);
        if (ninePatchChunk == NULL) {
            return nullObjectReturn("ninePatchChunk == null");
        }

        jbyte* array = (jbyte*) env->GetPrimitiveArrayCritical(ninePatchChunk, NULL);
        if (array == NULL) {
            return nullObjectReturn("primitive array == null");
        }

        peeker.fPatch->serialize(array);
        env->ReleasePrimitiveArrayCritical(ninePatchChunk, array, 0);
    }

    jintArray layoutBounds = NULL;
    if (peeker.fLayoutBounds != NULL) {
        layoutBounds = env->NewIntArray(4);
        if (layoutBounds == NULL) {
            return nullObjectReturn("layoutBounds == null");
        }

        jint scaledBounds[4];
        if (willScale) {
            for (int i=0; i<4; i++) {
                scaledBounds[i] = (jint)((((jint*)peeker.fLayoutBounds)[i]*scale) + .5f);
            }
        } else {
            memcpy(scaledBounds, (jint*)peeker.fLayoutBounds, sizeof(scaledBounds));
        }
        env->SetIntArrayRegion(layoutBounds, 0, 4, scaledBounds);
        if (javaBitmap != NULL) {
            env->SetObjectField(javaBitmap, gBitmap_layoutBoundsFieldID, layoutBounds);
        }
    }

    if (willScale) {
        // This is weird so let me explain: we could use the scale parameter
        // directly, but for historical reasons this is how the corresponding
        // Dalvik code has always behaved. We simply recreate the behavior here.
        // The result is slightly different from simply using scale because of
        // the 0.5f rounding bias applied when computing the target image size
        const float sx = scaledWidth / float(decoded->width());
        const float sy = scaledHeight / float(decoded->height());

        SkBitmap::Config config = decoded->config();
        switch (config) {
        case SkBitmap::kNo_Config:
        case SkBitmap::kIndex8_Config:
        case SkBitmap::kRLE_Index8_Config:
            config = SkBitmap::kARGB_8888_Config;
            break;
        default:
            break;
        }

        bitmap->setConfig(config, scaledWidth, scaledHeight);
        bitmap->setIsOpaque(decoded->isOpaque());
        if (!bitmap->allocPixels(&javaAllocator, NULL)) {
            return nullObjectReturn("allocation failed for scaled bitmap");
        }
        bitmap->eraseColor(0);

        SkPaint paint;
        paint.setFilterBitmap(true);

        SkCanvas canvas(*bitmap);
        canvas.scale(sx, sy);
        canvas.drawBitmap(*decoded, 0.0f, 0.0f, &paint);

        // Save off the unscaled version of bitmap to be used in later
        // transformations if it would reduce memory pressure. Only do
        // so if it is being upscaled more than 50%, is bigger than
        // 256x256, and not too big to be keeping a copy of (<1MB).
        const int numUnscaledPixels = decoded->width() * decoded->height();
        if (sx > 1.5 && numUnscaledPixels > 65536 && numUnscaledPixels < 262144) {
            bitmap->setUnscaledBitmap(decoded);
            adb2.detach(); //responsibility for freeing decoded's memory is
            //transferred to bitmap's destructor
        }
    }

    if (padding) {
        if (peeker.fPatch != NULL) {
            GraphicsJNI::set_jrect(env, padding,
                                   peeker.fPatch->paddingLeft, peeker.fPatch->paddingTop,
                                   peeker.fPatch->paddingRight, peeker.fPatch->paddingBottom);
        } else {
            GraphicsJNI::set_jrect(env, padding, -1, -1, -1, -1);
        }
    }

    SkPixelRef* pr;
    if (isPurgeable) {
        pr = installPixelRef(bitmap, stream, sampleSize, doDither);
    } else {
        // if we get here, we're in kDecodePixels_Mode and will therefore
        // already have a pixelref installed.
        pr = bitmap->pixelRef();
    }
    if (pr == NULL) {
        return nullObjectReturn("Got null SkPixelRef");
    }

    if (!isMutable) {
        // promise we will never change our pixels (great for sharing and pictures)
        pr->setImmutable();
    }

    // detach bitmap from its autodeleter, since we want to own it now
    adb.detach();

    if (javaBitmap != NULL) {
        // If a java bitmap was passed in for reuse, pass it back
        return javaBitmap;
    }
    // now create the java bitmap
    return GraphicsJNI::createBitmap(env, bitmap, javaAllocator.getStorageObj(),
                                     isMutable, ninePatchChunk, layoutBounds, -1);
}
Пример #26
0
static jobject doDecode(JNIEnv* env, SkStreamRewindable* stream, jobject padding, jobject options) {

    int sampleSize = 1;
    int preferSize = 0;
    int postproc = 0;
    int postprocflag = 0;
#ifdef MTK_IMAGE_DC_SUPPORT
	void* dc;
	bool dcflag = false;
	jint* pdynamicCon = NULL;
	jintArray dynamicCon;
	jsize size = 0;
#endif

    SkImageDecoder::Mode decodeMode = SkImageDecoder::kDecodePixels_Mode;
    SkColorType prefColorType = kN32_SkColorType;

    bool doDither = true;
    bool isMutable = false;
    float scale = 1.0f;
    bool preferQualityOverSpeed = false;
    bool requireUnpremultiplied = false;

    jobject javaBitmap = NULL;

    if (options != NULL) {
        sampleSize = env->GetIntField(options, gOptions_sampleSizeFieldID);
        if (optionsJustBounds(env, options)) {
            decodeMode = SkImageDecoder::kDecodeBounds_Mode;
        }

        // initialize these, in case we fail later on
        env->SetIntField(options, gOptions_widthFieldID, -1);
        env->SetIntField(options, gOptions_heightFieldID, -1);
        env->SetObjectField(options, gOptions_mimeFieldID, 0);

        jobject jconfig = env->GetObjectField(options, gOptions_configFieldID);
        prefColorType = GraphicsJNI::getNativeBitmapColorType(env, jconfig);
        isMutable = env->GetBooleanField(options, gOptions_mutableFieldID);
        doDither = env->GetBooleanField(options, gOptions_ditherFieldID);
        preferQualityOverSpeed = env->GetBooleanField(options,
                gOptions_preferQualityOverSpeedFieldID);
        requireUnpremultiplied = !env->GetBooleanField(options, gOptions_premultipliedFieldID);
        javaBitmap = env->GetObjectField(options, gOptions_bitmapFieldID);
        postproc = env->GetBooleanField(options, gOptions_postprocFieldID);
        postprocflag = env->GetIntField(options, gOptions_postprocflagFieldID);

#ifdef MTK_IMAGE_DC_SUPPORT
		dcflag = env->GetBooleanField(options, gOptions_dynamicConflagFieldID);
		dynamicCon = (jintArray)env->GetObjectField(options, gOptions_dynamicConFieldID);
		//pdynamicCon = (unsigned int*)env->GetIntArrayElements(dynamicCon, 0);
		pdynamicCon = env->GetIntArrayElements(dynamicCon, NULL);
		size = env->GetArrayLength(dynamicCon);
		//for (int i=0; i<size; i++)
		//{
		   //ALOGD("pdynamicCon[%d]=%d", i, pdynamicCon[i]);
		//}

		//ALOGD("BitmapFactory.cpp postproc=%d, postprocflag=%d", postproc, postprocflag);
		//ALOGD("BitmapFactory.cpp dcflag=%d", dcflag);
		//ALOGD("BitmapFactory.cpp dynamicCon=%p", dynamicCon);
		//ALOGD("BitmapFactory.cpp size=%d", size);
#endif

        if (env->GetBooleanField(options, gOptions_scaledFieldID)) {
            const int density = env->GetIntField(options, gOptions_densityFieldID);
            const int targetDensity = env->GetIntField(options, gOptions_targetDensityFieldID);
            const int screenDensity = env->GetIntField(options, gOptions_screenDensityFieldID);
            if (density != 0 && targetDensity != 0 && density != screenDensity) {
                scale = (float) targetDensity / density;
            }
        }
    }

    const bool willScale = scale != 1.0f;

    SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
    if (decoder == NULL) {
        return nullObjectReturn("SkImageDecoder::Factory returned null");
    }

    decoder->setSampleSize(sampleSize);
    decoder->setDitherImage(doDither);
    decoder->setPreferQualityOverSpeed(preferQualityOverSpeed);
    decoder->setRequireUnpremultipliedColors(requireUnpremultiplied);
    decoder->setPreferSize(preferSize);
    decoder->setPostProcFlag((postproc | (postprocflag << 4)));

#ifdef MTK_IMAGE_DC_SUPPORT
    if (dcflag == true) {
	    dc= (void*)pdynamicCon;
	    int len = (int)size;
	    decoder->setDynamicCon(dc, len);
    } else {
        dc = NULL;
        decoder->setDynamicCon(dc, 0);
    }
//	(env)->ReleaseIntArrayElements(dynamicCon, pdynamicCon, 0);
#endif

    SkBitmap* outputBitmap = NULL;
    unsigned int existingBufferSize = 0;
    if (javaBitmap != NULL) {
        outputBitmap = (SkBitmap*) env->GetLongField(javaBitmap, gBitmap_nativeBitmapFieldID);
        if (outputBitmap->isImmutable()) {
            ALOGW("Unable to reuse an immutable bitmap as an image decoder target.");
            javaBitmap = NULL;
            outputBitmap = NULL;
        } else {
            existingBufferSize = GraphicsJNI::getBitmapAllocationByteCount(env, javaBitmap);
        }
    }

    SkAutoTDelete<SkBitmap> adb(outputBitmap == NULL ? new SkBitmap : NULL);
    if (outputBitmap == NULL) outputBitmap = adb.get();

    NinePatchPeeker peeker(decoder);
    decoder->setPeeker(&peeker);

    JavaPixelAllocator javaAllocator(env);
    RecyclingPixelAllocator recyclingAllocator(outputBitmap->pixelRef(), existingBufferSize);
    ScaleCheckingAllocator scaleCheckingAllocator(scale, existingBufferSize);
    SkBitmap::Allocator* outputAllocator = (javaBitmap != NULL) ?
            (SkBitmap::Allocator*)&recyclingAllocator : (SkBitmap::Allocator*)&javaAllocator;
    if (decodeMode != SkImageDecoder::kDecodeBounds_Mode) {
        if (!willScale) {
            // If the java allocator is being used to allocate the pixel memory, the decoder
            // need not write zeroes, since the memory is initialized to 0.
            decoder->setSkipWritingZeroes(outputAllocator == &javaAllocator);
            decoder->setAllocator(outputAllocator);
        } else if (javaBitmap != NULL) {
            // check for eventual scaled bounds at allocation time, so we don't decode the bitmap
            // only to find the scaled result too large to fit in the allocation
            decoder->setAllocator(&scaleCheckingAllocator);
        }
    }

    // Only setup the decoder to be deleted after its stack-based, refcounted
    // components (allocators, peekers, etc) are declared. This prevents RefCnt
    // asserts from firing due to the order objects are deleted from the stack.
    SkAutoTDelete<SkImageDecoder> add(decoder);

    AutoDecoderCancel adc(options, decoder);

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (options != NULL && env->GetBooleanField(options, gOptions_mCancelID)) {
        return nullObjectReturn("gOptions_mCancelID");
    }

    SkBitmap decodingBitmap;
    if (!decoder->decode(stream, &decodingBitmap, prefColorType, decodeMode)) {
        return nullObjectReturn("decoder->decode returned false");
    }

    int scaledWidth = decodingBitmap.width();
    int scaledHeight = decodingBitmap.height();

    if (willScale && decodeMode != SkImageDecoder::kDecodeBounds_Mode) {
        scaledWidth = int(scaledWidth * scale + 0.5f);
        scaledHeight = int(scaledHeight * scale + 0.5f);
    }

    // update options (if any)
    if (options != NULL) {
        env->SetIntField(options, gOptions_widthFieldID, scaledWidth);
        env->SetIntField(options, gOptions_heightFieldID, scaledHeight);
        env->SetObjectField(options, gOptions_mimeFieldID,
                getMimeTypeString(env, decoder->getFormat()));
    }

    // if we're in justBounds mode, return now (skip the java bitmap)
    if (decodeMode == SkImageDecoder::kDecodeBounds_Mode) {
        return NULL;
    }

    jbyteArray ninePatchChunk = NULL;
    if (peeker.mPatch != NULL) {
        if (willScale) {
            scaleNinePatchChunk(peeker.mPatch, scale, scaledWidth, scaledHeight);
        }

        size_t ninePatchArraySize = peeker.mPatch->serializedSize();
        ninePatchChunk = env->NewByteArray(ninePatchArraySize);
        if (ninePatchChunk == NULL) {
            return nullObjectReturn("ninePatchChunk == null");
        }

        jbyte* array = (jbyte*) env->GetPrimitiveArrayCritical(ninePatchChunk, NULL);
        if (array == NULL) {
            return nullObjectReturn("primitive array == null");
        }

        memcpy(array, peeker.mPatch, peeker.mPatchSize);
        env->ReleasePrimitiveArrayCritical(ninePatchChunk, array, 0);
    }

    jobject ninePatchInsets = NULL;
    if (peeker.mHasInsets) {
        ninePatchInsets = env->NewObject(gInsetStruct_class, gInsetStruct_constructorMethodID,
                peeker.mOpticalInsets[0], peeker.mOpticalInsets[1], peeker.mOpticalInsets[2], peeker.mOpticalInsets[3],
                peeker.mOutlineInsets[0], peeker.mOutlineInsets[1], peeker.mOutlineInsets[2], peeker.mOutlineInsets[3],
                peeker.mOutlineRadius, peeker.mOutlineAlpha, scale);
        if (ninePatchInsets == NULL) {
            return nullObjectReturn("nine patch insets == null");
        }
        if (javaBitmap != NULL) {
            env->SetObjectField(javaBitmap, gBitmap_ninePatchInsetsFieldID, ninePatchInsets);
        }
    }

    if (willScale) {
        // This is weird so let me explain: we could use the scale parameter
        // directly, but for historical reasons this is how the corresponding
        // Dalvik code has always behaved. We simply recreate the behavior here.
        // The result is slightly different from simply using scale because of
        // the 0.5f rounding bias applied when computing the target image size
        const float sx = scaledWidth / float(decodingBitmap.width());
        const float sy = scaledHeight / float(decodingBitmap.height());

        // TODO: avoid copying when scaled size equals decodingBitmap size
        SkColorType colorType = colorTypeForScaledOutput(decodingBitmap.colorType());
        // FIXME: If the alphaType is kUnpremul and the image has alpha, the
        // colors may not be correct, since Skia does not yet support drawing
        // to/from unpremultiplied bitmaps.
        outputBitmap->setInfo(SkImageInfo::Make(scaledWidth, scaledHeight,
                colorType, decodingBitmap.alphaType()));
        if (!outputBitmap->allocPixels(outputAllocator, NULL)) {
            return nullObjectReturn("allocation failed for scaled bitmap");
        }

        // If outputBitmap's pixels are newly allocated by Java, there is no need
        // to erase to 0, since the pixels were initialized to 0.
        if (outputAllocator != &javaAllocator) {
            outputBitmap->eraseColor(0);
        }

        SkPaint paint;
        paint.setFilterLevel(SkPaint::kLow_FilterLevel);

        SkCanvas canvas(*outputBitmap);
        canvas.scale(sx, sy);
        canvas.drawBitmap(decodingBitmap, 0.0f, 0.0f, &paint);
    } else {
        outputBitmap->swap(decodingBitmap);
    }

    if (padding) {
        if (peeker.mPatch != NULL) {
            GraphicsJNI::set_jrect(env, padding,
                    peeker.mPatch->paddingLeft, peeker.mPatch->paddingTop,
                    peeker.mPatch->paddingRight, peeker.mPatch->paddingBottom);
        } else {
            GraphicsJNI::set_jrect(env, padding, -1, -1, -1, -1);
        }
    }

    // if we get here, we're in kDecodePixels_Mode and will therefore
    // already have a pixelref installed.
    if (outputBitmap->pixelRef() == NULL) {
        return nullObjectReturn("Got null SkPixelRef");
    }

    if (!isMutable && javaBitmap == NULL) {
        // promise we will never change our pixels (great for sharing and pictures)
        outputBitmap->setImmutable();
    }

    // detach bitmap from its autodeleter, since we want to own it now
    adb.detach();

    if (javaBitmap != NULL) {
        bool isPremultiplied = !requireUnpremultiplied;
        GraphicsJNI::reinitBitmap(env, javaBitmap, outputBitmap, isPremultiplied);
        outputBitmap->notifyPixelsChanged();
        // If a java bitmap was passed in for reuse, pass it back
        return javaBitmap;
    }

    int bitmapCreateFlags = 0x0;
    if (isMutable) bitmapCreateFlags |= GraphicsJNI::kBitmapCreateFlag_Mutable;
    if (!requireUnpremultiplied) bitmapCreateFlags |= GraphicsJNI::kBitmapCreateFlag_Premultiplied;

    // now create the java bitmap
    return GraphicsJNI::createBitmap(env, outputBitmap, javaAllocator.getStorageObj(),
            bitmapCreateFlags, ninePatchChunk, ninePatchInsets, -1);
}
void ImageSource::setData(SharedBuffer* data, bool allDataReceived)
{
#ifdef ANDROID_ANIMATED_GIF
    // This is only necessary if we allow ourselves to partially decode GIF
    bool disabledAnimatedGif = false;
    if (m_decoder.m_gifDecoder
            && !m_decoder.m_gifDecoder->failed()) {
        m_decoder.m_gifDecoder->setData(data, allDataReceived);
        if (!allDataReceived || m_decoder.m_gifDecoder->frameCount() != 1)
            return;
        disabledAnimatedGif = true;
        delete m_decoder.m_gifDecoder;
        m_decoder.m_gifDecoder = 0;
    }
#endif
    if (NULL == m_decoder.m_image
#ifdef ANDROID_ANIMATED_GIF
          && !m_decoder.m_gifDecoder
#endif
                                            ) {
        SkBitmap tmp;

        SkMemoryStream stream(data->data(), data->size(), false);
        SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
        if (!codec)
            return;

        SkAutoTDelete<SkImageDecoder> ad(codec);
		// FOR KITKAT MR2 INTEGRATION
        //codec->setPrefConfigTable(gPrefConfigTable);
        SkImageDecoder::PrefConfigTable configTable;
	    configTable.fPrefFor_8Index_NoAlpha_src = gPrefConfigTable[0];
        configTable.fPrefFor_8Index_YesAlpha_src = gPrefConfigTable[1];
        configTable.fPrefFor_8Gray_src = SkBitmap::kNo_Config;
        configTable.fPrefFor_8bpc_NoAlpha_src  = gPrefConfigTable[4];
        configTable.fPrefFor_8bpc_YesAlpha_src = gPrefConfigTable[5];
	    codec->setPrefConfigTable(configTable);
		// FOR KITKAT MR2 INTEGRATION
        
        if (!codec->decode(&stream, &tmp, SkImageDecoder::kDecodeBounds_Mode))
            return;

        int origW = tmp.width();
        int origH = tmp.height();

#ifdef ANDROID_ANIMATED_GIF
        // First, check to see if this is an animated GIF
        const char* contents = data->data();
        if (data->size() > 3 && strncmp(contents, "GIF8", 4) == 0
                && should_use_animated_gif(origW, origH)
                && !disabledAnimatedGif) {
            // This means we are looking at a GIF, so create special
            // GIF Decoder
            // Need to wait for all data received if we are assigning an
            // allocator (which we are not at the moment).
            if (!m_decoder.m_gifDecoder /*&& allDataReceived*/)
                m_decoder.m_gifDecoder = new GIFImageDecoder(m_alphaOption, m_gammaAndColorProfileOption);
            int frameCount = 0;
            if (!m_decoder.m_gifDecoder->failed()) {
                m_decoder.m_gifDecoder->setData(data, allDataReceived);
                if (!allDataReceived)
                    return;
                frameCount = m_decoder.m_gifDecoder->frameCount();
            }
            if (frameCount != 1)
                return;
            delete m_decoder.m_gifDecoder;
            m_decoder.m_gifDecoder = 0;
        }
#endif
        
        int sampleSize = computeSampleSize(tmp);
        if (sampleSize > 1) {
            codec->setSampleSize(sampleSize);
            stream.rewind();
            if (!codec->decode(&stream, &tmp,
                               SkImageDecoder::kDecodeBounds_Mode)) {
                return;
            }
        }

        m_decoder.m_image = new PrivateAndroidImageSourceRec(tmp, origW, origH,
                                                     sampleSize);
        
//        SkDebugf("----- started: [%d %d] %s\n", origW, origH, m_decoder.m_url.c_str());
    }

    PrivateAndroidImageSourceRec* decoder = m_decoder.m_image;
    if (allDataReceived && decoder && !decoder->fAllDataReceived) {
        decoder->fAllDataReceived = true;

        SkBitmap* bm = &decoder->bitmap();
// 4.2 Merge BEGIN <<
//Following code removed in 4.2
//        SkPixelRef* ref = convertToRLE(bm, data->data(), data->size()); //4.2 Merge : removed in 4.2

//        if (ref) {
//            bm->setPixelRef(ref)->unref();
//        } else {
// 4.2 Merge END >>
            BitmapAllocatorAndroid alloc(data, decoder->fSampleSize);
            if (!alloc.allocPixelRef(bm, NULL)) {
                return;
            }
        SkPixelRef* ref = bm->pixelRef();//4.2 Merge
//        }//4.3 Merge : removed in 4.2

        // we promise to never change the pixels (makes picture recording fast)
        ref->setImmutable();
        // give it the URL if we have one
        ref->setURI(m_decoder.m_url);
    }
}
Пример #28
0
status_t BootAnimation::initTexture(void* buffer, size_t len)
{
    //StopWatch watch("blah");

    SkBitmap bitmap;
    SkMemoryStream  stream(buffer, len);
    SkImageDecoder* codec = SkImageDecoder::Factory(&stream);
    codec->setDitherImage(false);
    if (codec) {
        codec->decode(&stream, &bitmap,
                SkBitmap::kRGB_565_Config,
                SkImageDecoder::kDecodePixels_Mode);
        delete codec;
    }

    // ensure we can call getPixels(). No need to call unlock, since the
    // bitmap will go out of scope when we return from this method.
    bitmap.lockPixels();

    const int w = bitmap.width();
    const int h = bitmap.height();
    const void* p = bitmap.getPixels();

    GLint crop[4] = { 0, h, w, -h };
    int tw = 1 << (31 - __builtin_clz(w));
    int th = 1 << (31 - __builtin_clz(h));
    if (tw < w) tw <<= 1;
    if (th < h) th <<= 1;

    switch (bitmap.getConfig()) {
        case SkBitmap::kARGB_8888_Config:
            if (tw != w || th != h) {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, tw, th, 0, GL_RGBA,
                        GL_UNSIGNED_BYTE, 0);
                glTexSubImage2D(GL_TEXTURE_2D, 0,
                        0, 0, w, h, GL_RGBA, GL_UNSIGNED_BYTE, p);
            } else {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, tw, th, 0, GL_RGBA,
                        GL_UNSIGNED_BYTE, p);
            }
            break;

        case SkBitmap::kRGB_565_Config:
            if (tw != w || th != h) {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, tw, th, 0, GL_RGB,
                        GL_UNSIGNED_SHORT_5_6_5, 0);
                glTexSubImage2D(GL_TEXTURE_2D, 0,
                        0, 0, w, h, GL_RGB, GL_UNSIGNED_SHORT_5_6_5, p);
            } else {
                glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, tw, th, 0, GL_RGB,
                        GL_UNSIGNED_SHORT_5_6_5, p);
            }
            break;
        default:
            break;
    }

    glTexParameteriv(GL_TEXTURE_2D, GL_TEXTURE_CROP_RECT_OES, crop);

    return NO_ERROR;
}
Пример #29
0
BitmapGlue*
BitmapFactoryGlue::doDecode(SkStream* stream, Options& options,
			    bool allowPurgeable, bool forcePurgeable)
{
	int sampleSize = 1;
	SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode;
	SkBitmap::Config prefConfig = SkBitmap::kARGB_8888_Config;
	bool doDither = true;
	bool isMutable = false;
	bool isPurgeable = forcePurgeable || (allowPurgeable && options.isPurgeable);
	BitmapGlue* javaBitmap = NULL;

	sampleSize = options.sampleSize;
	if (options.justDecodeBounds)
		mode = SkImageDecoder::kDecodeBounds_Mode;
	// initialize these, in case we fail later on
	options.width = -1;
	options.height = -1;

	prefConfig = options.config;
	isMutable = options.isMutable;
	doDither = options.doDither;
	javaBitmap = options.bitmap;

	SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
	if (NULL == decoder)
		return NULL;

	decoder->setSampleSize(sampleSize);
	decoder->setDitherImage(doDither);

	BitmapGlue* bitmap;
	if (javaBitmap == NULL) {
		bitmap = new BitmapGlue;
	} else {
		if (sampleSize != 1) {
			return NULL;
		}
		bitmap = javaBitmap;
		// config of supplied bitmap overrules config set in options
		prefConfig = bitmap->getConfig();
	}

	SkAutoTDelete<SkImageDecoder>   add(decoder);
	SkAutoTDelete<SkBitmap>         adb(bitmap, (javaBitmap == NULL));

	SkImageDecoder::Mode decodeMode = mode;
	if (isPurgeable) {
		decodeMode = SkImageDecoder::kDecodeBounds_Mode;
	}
	if (!decoder->decode(stream, bitmap, prefConfig, decodeMode))
		return NULL;

	// update options (if any)
	options.width = bitmap->width();
	options.height = bitmap->height();

	// if we're in justBounds mode, return now (skip the java bitmap)
	if (SkImageDecoder::kDecodeBounds_Mode == mode) {
		return NULL;
	}

	// detach bitmap from its autodeleter, since we want to own it now
	adb.detach();

	SkPixelRef* pr;
	if (isPurgeable) {
		pr = installPixelRef(bitmap, stream, sampleSize, doDither);
	} else {
		// if we get here, we're in kDecodePixels_Mode and will therefore
		// already have a pixelref installed.
		pr = bitmap->pixelRef();
	}

	if (!isMutable) {
		// promise we will never change our pixels (great for sharing and pictures)
		pr->setImmutable();
	}

	if (javaBitmap != NULL) {
		// If a java bitmap was passed in for reuse, pass it back
		return javaBitmap;
	}
	// now create the java bitmap
	return bitmap;
}
Пример #30
0
// since we "may" create a purgeable imageref, we require the stream be ref'able
// i.e. dynamically allocated, since its lifetime may exceed the current stack
// frame.
static jobject doDecode(JNIEnv* env, SkStream* stream, jobject padding,
                        jobject options, bool allowPurgeable,
                        bool forcePurgeable = false) {
    int sampleSize = 1;
    SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode;
    SkBitmap::Config prefConfig = SkBitmap::kNo_Config;
    bool doDither = true;
    bool isPurgeable = forcePurgeable ||
                        (allowPurgeable && optionsPurgeable(env, options));
    bool reportSizeToVM = optionsReportSizeToVM(env, options);
    bool preferQualityOverSpeed = false;
    
    if (NULL != options) {
        sampleSize = env->GetIntField(options, gOptions_sampleSizeFieldID);
        if (env->GetBooleanField(options, gOptions_justBoundsFieldID)) {
            mode = SkImageDecoder::kDecodeBounds_Mode;
        }
        // initialize these, in case we fail later on
        env->SetIntField(options, gOptions_widthFieldID, -1);
        env->SetIntField(options, gOptions_heightFieldID, -1);
        env->SetObjectField(options, gOptions_mimeFieldID, 0);
        
        jobject jconfig = env->GetObjectField(options, gOptions_configFieldID);
        prefConfig = GraphicsJNI::getNativeBitmapConfig(env, jconfig);
        doDither = env->GetBooleanField(options, gOptions_ditherFieldID);
        preferQualityOverSpeed = env->GetBooleanField(options,
                gOptions_preferQualityOverSpeedFieldID);
    }

    SkImageDecoder* decoder = SkImageDecoder::Factory(stream);
    if (NULL == decoder) {
        return nullObjectReturn("SkImageDecoder::Factory returned null");
    }
    
    decoder->setSampleSize(sampleSize);
    decoder->setDitherImage(doDither);
    decoder->setPreferQualityOverSpeed(preferQualityOverSpeed);

    NinePatchPeeker     peeker(decoder);
    JavaPixelAllocator  javaAllocator(env, reportSizeToVM);
    SkBitmap*           bitmap = new SkBitmap;
    Res_png_9patch      dummy9Patch;

    SkAutoTDelete<SkImageDecoder>   add(decoder);
    SkAutoTDelete<SkBitmap>         adb(bitmap);

    decoder->setPeeker(&peeker);
    if (!isPurgeable) {
        decoder->setAllocator(&javaAllocator);
    }

    AutoDecoderCancel   adc(options, decoder);

    // To fix the race condition in case "requestCancelDecode"
    // happens earlier than AutoDecoderCancel object is added
    // to the gAutoDecoderCancelMutex linked list.
    if (NULL != options && env->GetBooleanField(options, gOptions_mCancelID)) {
        return nullObjectReturn("gOptions_mCancelID");;
    }

    SkImageDecoder::Mode decodeMode = mode;
    if (isPurgeable) {
        decodeMode = SkImageDecoder::kDecodeBounds_Mode;
    }
    if (!decoder->decode(stream, bitmap, prefConfig, decodeMode)) {
        return nullObjectReturn("decoder->decode returned false");
    }

    // update options (if any)
    if (NULL != options) {
        env->SetIntField(options, gOptions_widthFieldID, bitmap->width());
        env->SetIntField(options, gOptions_heightFieldID, bitmap->height());
        // TODO: set the mimeType field with the data from the codec.
        // but how to reuse a set of strings, rather than allocating new one
        // each time?
        env->SetObjectField(options, gOptions_mimeFieldID,
                            getMimeTypeString(env, decoder->getFormat()));
    }

    // if we're in justBounds mode, return now (skip the java bitmap)
    if (SkImageDecoder::kDecodeBounds_Mode == mode) {
        return NULL;
    }

    jbyteArray ninePatchChunk = NULL;
    if (peeker.fPatchIsValid) {
        size_t ninePatchArraySize = peeker.fPatch->serializedSize();
        ninePatchChunk = env->NewByteArray(ninePatchArraySize);
        if (NULL == ninePatchChunk) {
            return nullObjectReturn("ninePatchChunk == null");
        }
        jbyte* array = (jbyte*)env->GetPrimitiveArrayCritical(ninePatchChunk,
                                                              NULL);
        if (NULL == array) {
            return nullObjectReturn("primitive array == null");
        }
        peeker.fPatch->serialize(array);
        env->ReleasePrimitiveArrayCritical(ninePatchChunk, array, 0);
    }

    // detach bitmap from its autotdeleter, since we want to own it now
    adb.detach();

    if (padding) {
        if (peeker.fPatchIsValid) {
            GraphicsJNI::set_jrect(env, padding,
                                   peeker.fPatch->paddingLeft,
                                   peeker.fPatch->paddingTop,
                                   peeker.fPatch->paddingRight,
                                   peeker.fPatch->paddingBottom);
        } else {
            GraphicsJNI::set_jrect(env, padding, -1, -1, -1, -1);
        }
    }

    SkPixelRef* pr;
    if (isPurgeable) {
        pr = installPixelRef(bitmap, stream, sampleSize, doDither);
    } else {
        // if we get here, we're in kDecodePixels_Mode and will therefore
        // already have a pixelref installed.
        pr = bitmap->pixelRef();
    }
    // promise we will never change our pixels (great for sharing and pictures)
    pr->setImmutable();
    // now create the java bitmap
    return GraphicsJNI::createBitmap(env, bitmap, false, ninePatchChunk);
}