// 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; int preferSize = 0; int postproc = 0; int postprocflag = 0; SkImageDecoder::Mode mode = SkImageDecoder::kDecodePixels_Mode; SkBitmap::Config prefConfig = SkBitmap::kARGB_8888_Config; bool doDither = true; bool isMutable = false; bool isPurgeable = forcePurgeable || (allowPurgeable && optionsPurgeable(env, options)); bool preferQualityOverSpeed = false; jobject javaBitmap = NULL; if (NULL != options) { 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); postproc = env->GetBooleanField(options, gOptions_postprocFieldID); postprocflag = env->GetIntField(options, gOptions_postprocflagFieldID); javaBitmap = env->GetObjectField(options, gOptions_bitmapFieldID); } SkImageDecoder* decoder = SkImageDecoder::Factory(stream); if (NULL == decoder) { return nullObjectReturn("SkImageDecoder::Factory returned null"); } decoder->setSampleSize(sampleSize); decoder->setDitherImage(doDither); decoder->setPreferQualityOverSpeed(preferQualityOverSpeed); decoder->setPreferSize(preferSize); decoder->setPostProcFlag((postproc | (postprocflag << 4))); 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(); } Res_png_9patch dummy9Patch; 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 (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, javaBitmap != NULL)) { 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 autodeleter, 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(); } 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 GraphicsJNI::createBitmap(env, bitmap, javaAllocator.getStorageObj(), isMutable, ninePatchChunk); }
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); }