/* * Copyright 2015 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include #include #include #include "SkAutoPixmapStorage.h" #include "SkBitmap.h" #include "SkCanvas.h" #include "SkData.h" #include "SkImageEncoder.h" #include "SkImageGenerator.h" #include "SkImage_Base.h" #include "SkImagePriv.h" #include "SkPicture.h" #include "SkPictureRecorder.h" #include "SkPixelSerializer.h" #include "SkRRect.h" #include "SkStream.h" #include "SkSurface.h" #include "SkUtils.h" #include "Test.h" #include "sk_tool_utils.h" #if SK_SUPPORT_GPU #include "GrGpu.h" #endif using namespace sk_gpu_test; static void assert_equal(skiatest::Reporter* reporter, SkImage* a, const SkIRect* subsetA, SkImage* b) { const int widthA = subsetA ? subsetA->width() : a->width(); const int heightA = subsetA ? subsetA->height() : a->height(); REPORTER_ASSERT(reporter, widthA == b->width()); REPORTER_ASSERT(reporter, heightA == b->height()); // see https://bug.skia.org/3965 //REPORTER_ASSERT(reporter, a->isOpaque() == b->isOpaque()); // The codecs may have given us back F16, we can't read from F16 raster to N32, only S32. SkImageInfo info = SkImageInfo::MakeS32(widthA, heightA, a->alphaType()); SkAutoPixmapStorage pmapA, pmapB; pmapA.alloc(info); pmapB.alloc(info); const int srcX = subsetA ? subsetA->x() : 0; const int srcY = subsetA ? subsetA->y() : 0; REPORTER_ASSERT(reporter, a->readPixels(pmapA, srcX, srcY)); REPORTER_ASSERT(reporter, b->readPixels(pmapB, 0, 0)); const size_t widthBytes = widthA * info.bytesPerPixel(); for (int y = 0; y < heightA; ++y) { REPORTER_ASSERT(reporter, !memcmp(pmapA.addr32(0, y), pmapB.addr32(0, y), widthBytes)); } } static void draw_image_test_pattern(SkCanvas* canvas) { canvas->clear(SK_ColorWHITE); SkPaint paint; paint.setColor(SK_ColorBLACK); canvas->drawRect(SkRect::MakeXYWH(5, 5, 10, 10), paint); } static sk_sp create_image() { const SkImageInfo info = SkImageInfo::MakeN32(20, 20, kOpaque_SkAlphaType); auto surface(SkSurface::MakeRaster(info)); draw_image_test_pattern(surface->getCanvas()); return surface->makeImageSnapshot(); } static sk_sp create_image_data(SkImageInfo* info) { *info = SkImageInfo::MakeN32(20, 20, kOpaque_SkAlphaType); const size_t rowBytes = info->minRowBytes(); sk_sp data(SkData::MakeUninitialized(rowBytes * info->height())); { SkBitmap bm; bm.installPixels(*info, data->writable_data(), rowBytes); SkCanvas canvas(bm); draw_image_test_pattern(&canvas); } return data; } static sk_sp create_data_image() { SkImageInfo info; sk_sp data(create_image_data(&info)); return SkImage::MakeRasterData(info, std::move(data), info.minRowBytes()); } #if SK_SUPPORT_GPU // not gpu-specific but currently only used in GPU tests static sk_sp create_image_565() { const SkImageInfo info = SkImageInfo::Make(20, 20, kRGB_565_SkColorType, kOpaque_SkAlphaType); auto surface(SkSurface::MakeRaster(info)); draw_image_test_pattern(surface->getCanvas()); return surface->makeImageSnapshot(); } static sk_sp create_image_large(int maxTextureSize) { const SkImageInfo info = SkImageInfo::MakeN32(maxTextureSize + 1, 32, kOpaque_SkAlphaType); auto surface(SkSurface::MakeRaster(info)); surface->getCanvas()->clear(SK_ColorWHITE); SkPaint paint; paint.setColor(SK_ColorBLACK); surface->getCanvas()->drawRect(SkRect::MakeXYWH(4000, 2, 28000, 30), paint); return surface->makeImageSnapshot(); } static sk_sp create_image_ct() { SkPMColor colors[] = { SkPreMultiplyARGB(0xFF, 0xFF, 0xFF, 0x00), SkPreMultiplyARGB(0x80, 0x00, 0xA0, 0xFF), SkPreMultiplyARGB(0xFF, 0xBB, 0x00, 0xBB) }; sk_sp colorTable(new SkColorTable(colors, SK_ARRAY_COUNT(colors))); uint8_t data[] = { 0, 0, 0, 0, 0, 0, 1, 1, 1, 0, 0, 1, 2, 1, 0, 0, 1, 1, 1, 0, 0, 0, 0, 0, 0 }; SkImageInfo info = SkImageInfo::Make(5, 5, kIndex_8_SkColorType, kPremul_SkAlphaType); return SkImage::MakeRasterCopy(SkPixmap(info, data, 5, colorTable.get())); } static sk_sp create_picture_image() { SkPictureRecorder recorder; SkCanvas* canvas = recorder.beginRecording(10, 10); canvas->clear(SK_ColorCYAN); return SkImage::MakeFromPicture(recorder.finishRecordingAsPicture(), SkISize::Make(10, 10), nullptr, nullptr, SkImage::BitDepth::kU8, SkColorSpace::MakeNamed(SkColorSpace::kSRGB_Named)); }; #endif // Want to ensure that our Release is called when the owning image is destroyed struct RasterDataHolder { RasterDataHolder() : fReleaseCount(0) {} sk_sp fData; int fReleaseCount; static void Release(const void* pixels, void* context) { RasterDataHolder* self = static_cast(context); self->fReleaseCount++; self->fData.reset(); } }; static sk_sp create_rasterproc_image(RasterDataHolder* dataHolder) { SkASSERT(dataHolder); SkImageInfo info; dataHolder->fData = create_image_data(&info); return SkImage::MakeFromRaster(SkPixmap(info, dataHolder->fData->data(), info.minRowBytes()), RasterDataHolder::Release, dataHolder); } static sk_sp create_codec_image() { SkImageInfo info; sk_sp data(create_image_data(&info)); SkBitmap bitmap; bitmap.installPixels(info, data->writable_data(), info.minRowBytes()); sk_sp src(sk_tool_utils::EncodeImageToData(bitmap, SkEncodedImageFormat::kPNG, 100)); return SkImage::MakeFromEncoded(std::move(src)); } #if SK_SUPPORT_GPU static sk_sp create_gpu_image(GrContext* context) { const SkImageInfo info = SkImageInfo::MakeN32(20, 20, kOpaque_SkAlphaType); auto surface(SkSurface::MakeRenderTarget(context, SkBudgeted::kNo, info)); draw_image_test_pattern(surface->getCanvas()); return surface->makeImageSnapshot(); } #endif static void test_encode(skiatest::Reporter* reporter, SkImage* image) { const SkIRect ir = SkIRect::MakeXYWH(5, 5, 10, 10); sk_sp origEncoded(image->encode()); REPORTER_ASSERT(reporter, origEncoded); REPORTER_ASSERT(reporter, origEncoded->size() > 0); sk_sp decoded(SkImage::MakeFromEncoded(origEncoded)); if (!decoded) { ERRORF(reporter, "failed to decode image!"); return; } REPORTER_ASSERT(reporter, decoded); assert_equal(reporter, image, nullptr, decoded.get()); // Now see if we can instantiate an image from a subset of the surface/origEncoded decoded = SkImage::MakeFromEncoded(origEncoded, &ir); REPORTER_ASSERT(reporter, decoded); assert_equal(reporter, image, &ir, decoded.get()); } DEF_TEST(ImageEncode, reporter) { test_encode(reporter, create_image().get()); } #if SK_SUPPORT_GPU DEF_GPUTEST_FOR_RENDERING_CONTEXTS(ImageEncode_Gpu, reporter, ctxInfo) { test_encode(reporter, create_gpu_image(ctxInfo.grContext()).get()); } #endif DEF_TEST(Image_MakeFromRasterBitmap, reporter) { const struct { SkCopyPixelsMode fCPM; bool fExpectSameAsMutable; bool fExpectSameAsImmutable; } recs[] = { { kIfMutable_SkCopyPixelsMode, false, true }, { kAlways_SkCopyPixelsMode, false, false }, { kNever_SkCopyPixelsMode, true, true }, }; for (auto rec : recs) { SkPixmap pm; SkBitmap bm; bm.allocN32Pixels(100, 100); auto img = SkMakeImageFromRasterBitmap(bm, rec.fCPM); REPORTER_ASSERT(reporter, img->peekPixels(&pm)); const bool sameMutable = pm.addr32(0, 0) == bm.getAddr32(0, 0); REPORTER_ASSERT(reporter, rec.fExpectSameAsMutable == sameMutable); REPORTER_ASSERT(reporter, (bm.getGenerationID() == img->uniqueID()) == sameMutable); bm.notifyPixelsChanged(); // force a new generation ID bm.setImmutable(); img = SkMakeImageFromRasterBitmap(bm, rec.fCPM); REPORTER_ASSERT(reporter, img->peekPixels(&pm)); const bool sameImmutable = pm.addr32(0, 0) == bm.getAddr32(0, 0); REPORTER_ASSERT(reporter, rec.fExpectSameAsImmutable == sameImmutable); REPORTER_ASSERT(reporter, (bm.getGenerationID() == img->uniqueID()) == sameImmutable); } } namespace { const char* kSerializedData = "serialized"; class MockSerializer : public SkPixelSerializer { public: MockSerializer(sk_sp (*func)()) : fFunc(func), fDidEncode(false) { } bool didEncode() const { return fDidEncode; } protected: bool onUseEncodedData(const void*, size_t) override { return false; } SkData* onEncode(const SkPixmap&) override { fDidEncode = true; return fFunc().release(); } private: sk_sp (*fFunc)(); bool fDidEncode; typedef SkPixelSerializer INHERITED; }; } // anonymous namespace // Test that SkImage encoding observes custom pixel serializers. DEF_TEST(Image_Encode_Serializer, reporter) { MockSerializer serializer([]() -> sk_sp { return SkData::MakeWithCString(kSerializedData); }); sk_sp image(create_image()); sk_sp encoded(image->encode(&serializer)); sk_sp reference(SkData::MakeWithCString(kSerializedData)); REPORTER_ASSERT(reporter, serializer.didEncode()); REPORTER_ASSERT(reporter, encoded); REPORTER_ASSERT(reporter, encoded->size() > 0); REPORTER_ASSERT(reporter, encoded->equals(reference.get())); } // Test that image encoding failures do not break picture serialization/deserialization. DEF_TEST(Image_Serialize_Encoding_Failure, reporter) { auto surface(SkSurface::MakeRasterN32Premul(100, 100)); surface->getCanvas()->clear(SK_ColorGREEN); sk_sp image(surface->makeImageSnapshot()); REPORTER_ASSERT(reporter, image); SkPictureRecorder recorder; SkCanvas* canvas = recorder.beginRecording(100, 100); canvas->drawImage(image, 0, 0); sk_sp picture(recorder.finishRecordingAsPicture()); REPORTER_ASSERT(reporter, picture); REPORTER_ASSERT(reporter, picture->approximateOpCount() > 0); MockSerializer emptySerializer([]() -> sk_sp { return SkData::MakeEmpty(); }); MockSerializer nullSerializer([]() -> sk_sp { return nullptr; }); MockSerializer* serializers[] = { &emptySerializer, &nullSerializer }; for (size_t i = 0; i < SK_ARRAY_COUNT(serializers); ++i) { SkDynamicMemoryWStream wstream; REPORTER_ASSERT(reporter, !serializers[i]->didEncode()); picture->serialize(&wstream, serializers[i]); REPORTER_ASSERT(reporter, serializers[i]->didEncode()); std::unique_ptr rstream(wstream.detachAsStream()); sk_sp deserialized(SkPicture::MakeFromStream(rstream.get())); REPORTER_ASSERT(reporter, deserialized); REPORTER_ASSERT(reporter, deserialized->approximateOpCount() > 0); } } DEF_TEST(Image_NewRasterCopy, reporter) { const SkPMColor red = SkPackARGB32(0xFF, 0xFF, 0, 0); const SkPMColor green = SkPackARGB32(0xFF, 0, 0xFF, 0); const SkPMColor blue = SkPackARGB32(0xFF, 0, 0, 0xFF); SkPMColor colors[] = { red, green, blue, 0 }; sk_sp ctable(new SkColorTable(colors, SK_ARRAY_COUNT(colors))); // The colortable made a copy, so we can trash the original colors memset(colors, 0xFF, sizeof(colors)); const SkImageInfo srcInfo = SkImageInfo::Make(2, 2, kIndex_8_SkColorType, kPremul_SkAlphaType); const size_t srcRowBytes = 2 * sizeof(uint8_t); uint8_t indices[] = { 0, 1, 2, 3 }; auto image = SkImage::MakeRasterCopy(SkPixmap(srcInfo, indices, srcRowBytes, ctable.get())); // The image made a copy, so we can trash the original indices memset(indices, 0xFF, sizeof(indices)); const SkImageInfo dstInfo = SkImageInfo::MakeN32Premul(2, 2); const size_t dstRowBytes = 2 * sizeof(SkPMColor); SkPMColor pixels[4]; memset(pixels, 0xFF, sizeof(pixels)); // init with values we don't expect image->readPixels(dstInfo, pixels, dstRowBytes, 0, 0); REPORTER_ASSERT(reporter, red == pixels[0]); REPORTER_ASSERT(reporter, green == pixels[1]); REPORTER_ASSERT(reporter, blue == pixels[2]); REPORTER_ASSERT(reporter, 0 == pixels[3]); } // Test that a draw that only partially covers the drawing surface isn't // interpreted as covering the entire drawing surface (i.e., exercise one of the // conditions of SkCanvas::wouldOverwriteEntireSurface()). DEF_TEST(Image_RetainSnapshot, reporter) { const SkPMColor red = SkPackARGB32(0xFF, 0xFF, 0, 0); const SkPMColor green = SkPackARGB32(0xFF, 0, 0xFF, 0); SkImageInfo info = SkImageInfo::MakeN32Premul(2, 2); auto surface(SkSurface::MakeRaster(info)); surface->getCanvas()->clear(0xFF00FF00); SkPMColor pixels[4]; memset(pixels, 0xFF, sizeof(pixels)); // init with values we don't expect const SkImageInfo dstInfo = SkImageInfo::MakeN32Premul(2, 2); const size_t dstRowBytes = 2 * sizeof(SkPMColor); sk_sp image1(surface->makeImageSnapshot()); REPORTER_ASSERT(reporter, image1->readPixels(dstInfo, pixels, dstRowBytes, 0, 0)); for (size_t i = 0; i < SK_ARRAY_COUNT(pixels); ++i) { REPORTER_ASSERT(reporter, pixels[i] == green); } SkPaint paint; paint.setBlendMode(SkBlendMode::kSrc); paint.setColor(SK_ColorRED); surface->getCanvas()->drawRect(SkRect::MakeXYWH(1, 1, 1, 1), paint); sk_sp image2(surface->makeImageSnapshot()); REPORTER_ASSERT(reporter, image2->readPixels(dstInfo, pixels, dstRowBytes, 0, 0)); REPORTER_ASSERT(reporter, pixels[0] == green); REPORTER_ASSERT(reporter, pixels[1] == green); REPORTER_ASSERT(reporter, pixels[2] == green); REPORTER_ASSERT(reporter, pixels[3] == red); } ///////////////////////////////////////////////////////////////////////////////////////////////// static void make_bitmap_mutable(SkBitmap* bm) { bm->allocN32Pixels(10, 10); } static void make_bitmap_immutable(SkBitmap* bm) { bm->allocN32Pixels(10, 10); bm->setImmutable(); } DEF_TEST(image_newfrombitmap, reporter) { const struct { void (*fMakeProc)(SkBitmap*); bool fExpectPeekSuccess; bool fExpectSharedID; bool fExpectLazy; } rec[] = { { make_bitmap_mutable, true, false, false }, { make_bitmap_immutable, true, true, false }, }; for (size_t i = 0; i < SK_ARRAY_COUNT(rec); ++i) { SkBitmap bm; rec[i].fMakeProc(&bm); sk_sp image(SkImage::MakeFromBitmap(bm)); SkPixmap pmap; const bool sharedID = (image->uniqueID() == bm.getGenerationID()); REPORTER_ASSERT(reporter, sharedID == rec[i].fExpectSharedID); const bool peekSuccess = image->peekPixels(&pmap); REPORTER_ASSERT(reporter, peekSuccess == rec[i].fExpectPeekSuccess); const bool lazy = image->isLazyGenerated(); REPORTER_ASSERT(reporter, lazy == rec[i].fExpectLazy); } } /////////////////////////////////////////////////////////////////////////////////////////////////// #if SK_SUPPORT_GPU #include "SkBitmapCache.h" /* * This tests the caching (and preemptive purge) of the raster equivalent of a gpu-image. * We cache it for performance when drawing into a raster surface. * * A cleaner test would know if each drawImage call triggered a read-back from the gpu, * but we don't have that facility (at the moment) so we use a little internal knowledge * of *how* the raster version is cached, and look for that. */ DEF_GPUTEST_FOR_RENDERING_CONTEXTS(c, reporter, ctxInfo) { SkImageInfo info = SkImageInfo::MakeN32(20, 20, kOpaque_SkAlphaType); sk_sp image(create_gpu_image(ctxInfo.grContext())); const uint32_t uniqueID = image->uniqueID(); auto surface(SkSurface::MakeRaster(info)); // now we can test drawing a gpu-backed image into a cpu-backed surface { SkBitmap cachedBitmap; REPORTER_ASSERT(reporter, !SkBitmapCache::Find(uniqueID, &cachedBitmap)); } surface->getCanvas()->drawImage(image, 0, 0); { SkBitmap cachedBitmap; if (SkBitmapCache::Find(uniqueID, &cachedBitmap)) { REPORTER_ASSERT(reporter, cachedBitmap.getGenerationID() == uniqueID); REPORTER_ASSERT(reporter, cachedBitmap.isImmutable()); REPORTER_ASSERT(reporter, cachedBitmap.getPixels()); } else { // unexpected, but not really a bug, since the cache is global and this test may be // run w/ other threads competing for its budget. SkDebugf("SkImage_Gpu2Cpu : cachedBitmap was already purged\n"); } } image.reset(nullptr); { SkBitmap cachedBitmap; REPORTER_ASSERT(reporter, !SkBitmapCache::Find(uniqueID, &cachedBitmap)); } } DEF_GPUTEST_FOR_RENDERING_CONTEXTS(SkImage_makeNonTextureImage, reporter, contextInfo) { GrContext* context = contextInfo.grContext(); std::function()> imageFactories[] = { create_image, create_codec_image, create_data_image, create_picture_image, [context] { return create_gpu_image(context); }, }; for (auto factory : imageFactories) { sk_sp image = factory(); if (!image->isTextureBacked()) { REPORTER_ASSERT(reporter, image->makeNonTextureImage().get() == image.get()); continue; } auto rasterImage = image->makeNonTextureImage(); if (!rasterImage) { ERRORF(reporter, "makeNonTextureImage failed for texture-backed image."); } REPORTER_ASSERT(reporter, !rasterImage->isTextureBacked()); assert_equal(reporter, image.get(), nullptr, rasterImage.get()); } } DEF_GPUTEST_FOR_GL_RENDERING_CONTEXTS(SkImage_drawAbandonedGpuImage, reporter, contextInfo) { auto context = contextInfo.grContext(); auto image = create_gpu_image(context); auto info = SkImageInfo::MakeN32(20, 20, kOpaque_SkAlphaType); auto surface(SkSurface::MakeRenderTarget(context, SkBudgeted::kNo, info)); as_IB(image)->peekTexture()->abandon(); surface->getCanvas()->drawImage(image, 0, 0); } #endif // https://bug.skia.org/4390 DEF_TEST(ImageFromIndex8Bitmap, r) { SkPMColor pmColors[1] = {SkPreMultiplyColor(SK_ColorWHITE)}; SkBitmap bm; sk_sp ctable( new SkColorTable(pmColors, SK_ARRAY_COUNT(pmColors))); SkImageInfo info = SkImageInfo::Make(1, 1, kIndex_8_SkColorType, kPremul_SkAlphaType); bm.allocPixels(info, nullptr, ctable.get()); SkAutoLockPixels autoLockPixels(bm); *bm.getAddr8(0, 0) = 0; sk_sp img(SkImage::MakeFromBitmap(bm)); REPORTER_ASSERT(r, img != nullptr); } class EmptyGenerator : public SkImageGenerator { public: EmptyGenerator() : SkImageGenerator(SkImageInfo::MakeN32Premul(0, 0)) {} }; DEF_TEST(ImageEmpty, reporter) { const SkImageInfo info = SkImageInfo::Make(0, 0, kN32_SkColorType, kPremul_SkAlphaType); SkPixmap pmap(info, nullptr, 0); REPORTER_ASSERT(reporter, nullptr == SkImage::MakeRasterCopy(pmap)); REPORTER_ASSERT(reporter, nullptr == SkImage::MakeRasterData(info, nullptr, 0)); REPORTER_ASSERT(reporter, nullptr == SkImage::MakeFromRaster(pmap, nullptr, nullptr)); REPORTER_ASSERT(reporter, nullptr == SkImage::MakeFromGenerator(new EmptyGenerator)); } DEF_TEST(ImageDataRef, reporter) { SkImageInfo info = SkImageInfo::MakeN32Premul(1, 1); size_t rowBytes = info.minRowBytes(); size_t size = info.getSafeSize(rowBytes); sk_sp data = SkData::MakeUninitialized(size); REPORTER_ASSERT(reporter, data->unique()); sk_sp image = SkImage::MakeRasterData(info, data, rowBytes); REPORTER_ASSERT(reporter, !data->unique()); image.reset(); REPORTER_ASSERT(reporter, data->unique()); } static bool has_pixels(const SkPMColor pixels[], int count, SkPMColor expected) { for (int i = 0; i < count; ++i) { if (pixels[i] != expected) { return false; } } return true; } static void test_read_pixels(skiatest::Reporter* reporter, SkImage* image) { if (!image) { ERRORF(reporter, "Failed to create image!"); return; } const SkPMColor expected = SkPreMultiplyColor(SK_ColorWHITE); const SkPMColor notExpected = ~expected; const int w = 2, h = 2; const size_t rowBytes = w * sizeof(SkPMColor); SkPMColor pixels[w*h]; SkImageInfo info; info = SkImageInfo::MakeUnknown(w, h); REPORTER_ASSERT(reporter, !image->readPixels(info, pixels, rowBytes, 0, 0)); // out-of-bounds should fail info = SkImageInfo::MakeN32Premul(w, h); REPORTER_ASSERT(reporter, !image->readPixels(info, pixels, rowBytes, -w, 0)); REPORTER_ASSERT(reporter, !image->readPixels(info, pixels, rowBytes, 0, -h)); REPORTER_ASSERT(reporter, !image->readPixels(info, pixels, rowBytes, image->width(), 0)); REPORTER_ASSERT(reporter, !image->readPixels(info, pixels, rowBytes, 0, image->height())); // top-left should succeed sk_memset32(pixels, notExpected, w*h); REPORTER_ASSERT(reporter, image->readPixels(info, pixels, rowBytes, 0, 0)); REPORTER_ASSERT(reporter, has_pixels(pixels, w*h, expected)); // bottom-right should succeed sk_memset32(pixels, notExpected, w*h); REPORTER_ASSERT(reporter, image->readPixels(info, pixels, rowBytes, image->width() - w, image->height() - h)); REPORTER_ASSERT(reporter, has_pixels(pixels, w*h, expected)); // partial top-left should succeed sk_memset32(pixels, notExpected, w*h); REPORTER_ASSERT(reporter, image->readPixels(info, pixels, rowBytes, -1, -1)); REPORTER_ASSERT(reporter, pixels[3] == expected); REPORTER_ASSERT(reporter, has_pixels(pixels, w*h - 1, notExpected)); // partial bottom-right should succeed sk_memset32(pixels, notExpected, w*h); REPORTER_ASSERT(reporter, image->readPixels(info, pixels, rowBytes, image->width() - 1, image->height() - 1)); REPORTER_ASSERT(reporter, pixels[0] == expected); REPORTER_ASSERT(reporter, has_pixels(&pixels[1], w*h - 1, notExpected)); } DEF_TEST(ImageReadPixels, reporter) { sk_sp image(create_image()); test_read_pixels(reporter, image.get()); image = create_data_image(); test_read_pixels(reporter, image.get()); RasterDataHolder dataHolder; image = create_rasterproc_image(&dataHolder); test_read_pixels(reporter, image.get()); image.reset(); REPORTER_ASSERT(reporter, 1 == dataHolder.fReleaseCount); image = create_codec_image(); test_read_pixels(reporter, image.get()); } #if SK_SUPPORT_GPU DEF_GPUTEST_FOR_RENDERING_CONTEXTS(ImageReadPixels_Gpu, reporter, ctxInfo) { test_read_pixels(reporter, create_gpu_image(ctxInfo.grContext()).get()); } #endif static void check_legacy_bitmap(skiatest::Reporter* reporter, const SkImage* image, const SkBitmap& bitmap, SkImage::LegacyBitmapMode mode) { REPORTER_ASSERT(reporter, image->width() == bitmap.width()); REPORTER_ASSERT(reporter, image->height() == bitmap.height()); REPORTER_ASSERT(reporter, image->alphaType() == bitmap.alphaType()); if (SkImage::kRO_LegacyBitmapMode == mode) { REPORTER_ASSERT(reporter, bitmap.isImmutable()); } SkAutoLockPixels alp(bitmap); REPORTER_ASSERT(reporter, bitmap.getPixels()); const SkImageInfo info = SkImageInfo::MakeN32(1, 1, bitmap.alphaType()); SkPMColor imageColor; REPORTER_ASSERT(reporter, image->readPixels(info, &imageColor, sizeof(SkPMColor), 0, 0)); REPORTER_ASSERT(reporter, imageColor == *bitmap.getAddr32(0, 0)); } static void test_legacy_bitmap(skiatest::Reporter* reporter, const SkImage* image, SkImage::LegacyBitmapMode mode) { if (!image) { ERRORF(reporter, "Failed to create image."); return; } SkBitmap bitmap; REPORTER_ASSERT(reporter, image->asLegacyBitmap(&bitmap, mode)); check_legacy_bitmap(reporter, image, bitmap, mode); // Test subsetting to exercise the rowBytes logic. SkBitmap tmp; REPORTER_ASSERT(reporter, bitmap.extractSubset(&tmp, SkIRect::MakeWH(image->width() / 2, image->height() / 2))); sk_sp subsetImage(SkImage::MakeFromBitmap(tmp)); REPORTER_ASSERT(reporter, subsetImage.get()); SkBitmap subsetBitmap; REPORTER_ASSERT(reporter, subsetImage->asLegacyBitmap(&subsetBitmap, mode)); check_legacy_bitmap(reporter, subsetImage.get(), subsetBitmap, mode); } DEF_TEST(ImageLegacyBitmap, reporter) { const SkImage::LegacyBitmapMode modes[] = { SkImage::kRO_LegacyBitmapMode, SkImage::kRW_LegacyBitmapMode, }; for (auto& mode : modes) { sk_sp image(create_image()); test_legacy_bitmap(reporter, image.get(), mode); image = create_data_image(); test_legacy_bitmap(reporter, image.get(), mode); RasterDataHolder dataHolder; image = create_rasterproc_image(&dataHolder); test_legacy_bitmap(reporter, image.get(), mode); image.reset(); REPORTER_ASSERT(reporter, 1 == dataHolder.fReleaseCount); image = create_codec_image(); test_legacy_bitmap(reporter, image.get(), mode); } } #if SK_SUPPORT_GPU DEF_GPUTEST_FOR_RENDERING_CONTEXTS(ImageLegacyBitmap_Gpu, reporter, ctxInfo) { const SkImage::LegacyBitmapMode modes[] = { SkImage::kRO_LegacyBitmapMode, SkImage::kRW_LegacyBitmapMode, }; for (auto& mode : modes) { sk_sp image(create_gpu_image(ctxInfo.grContext())); test_legacy_bitmap(reporter, image.get(), mode); } } #endif static void test_peek(skiatest::Reporter* reporter, SkImage* image, bool expectPeekSuccess) { if (!image) { ERRORF(reporter, "Failed to create image!"); return; } SkPixmap pm; bool success = image->peekPixels(&pm); REPORTER_ASSERT(reporter, expectPeekSuccess == success); if (success) { const SkImageInfo& info = pm.info(); REPORTER_ASSERT(reporter, 20 == info.width()); REPORTER_ASSERT(reporter, 20 == info.height()); REPORTER_ASSERT(reporter, kN32_SkColorType == info.colorType()); REPORTER_ASSERT(reporter, kPremul_SkAlphaType == info.alphaType() || kOpaque_SkAlphaType == info.alphaType()); REPORTER_ASSERT(reporter, info.minRowBytes() <= pm.rowBytes()); REPORTER_ASSERT(reporter, SkPreMultiplyColor(SK_ColorWHITE) == *pm.addr32(0, 0)); } } DEF_TEST(ImagePeek, reporter) { sk_sp image(create_image()); test_peek(reporter, image.get(), true); image = create_data_image(); test_peek(reporter, image.get(), true); RasterDataHolder dataHolder; image = create_rasterproc_image(&dataHolder); test_peek(reporter, image.get(), true); image.reset(); REPORTER_ASSERT(reporter, 1 == dataHolder.fReleaseCount); image = create_codec_image(); test_peek(reporter, image.get(), false); } #if SK_SUPPORT_GPU DEF_GPUTEST_FOR_RENDERING_CONTEXTS(ImagePeek_Gpu, reporter, ctxInfo) { sk_sp image(create_gpu_image(ctxInfo.grContext())); test_peek(reporter, image.get(), false); } #endif #if SK_SUPPORT_GPU struct TextureReleaseChecker { TextureReleaseChecker() : fReleaseCount(0) {} int fReleaseCount; static void Release(void* self) { static_cast(self)->fReleaseCount++; } }; DEF_GPUTEST_FOR_GL_RENDERING_CONTEXTS(SkImage_NewFromTextureRelease, reporter, ctxInfo) { const int kWidth = 10; const int kHeight = 10; std::unique_ptr pixels(new uint32_t[kWidth * kHeight]); GrBackendTextureDesc backendDesc; backendDesc.fConfig = kRGBA_8888_GrPixelConfig; backendDesc.fFlags = kRenderTarget_GrBackendTextureFlag; backendDesc.fWidth = kWidth; backendDesc.fHeight = kHeight; backendDesc.fSampleCnt = 0; backendDesc.fTextureHandle = ctxInfo.grContext()->getGpu()->createTestingOnlyBackendTexture( pixels.get(), kWidth, kHeight, kRGBA_8888_GrPixelConfig, true); TextureReleaseChecker releaseChecker; sk_sp refImg( SkImage::MakeFromTexture(ctxInfo.grContext(), backendDesc, kPremul_SkAlphaType, TextureReleaseChecker::Release, &releaseChecker)); // Now exercise the release proc REPORTER_ASSERT(reporter, 0 == releaseChecker.fReleaseCount); refImg.reset(nullptr); // force a release of the image REPORTER_ASSERT(reporter, 1 == releaseChecker.fReleaseCount); ctxInfo.grContext()->getGpu()->deleteTestingOnlyBackendTexture(backendDesc.fTextureHandle); } static void check_images_same(skiatest::Reporter* reporter, const SkImage* a, const SkImage* b) { if (a->width() != b->width() || a->height() != b->height()) { ERRORF(reporter, "Images must have the same size"); return; } if (a->alphaType() != b->alphaType()) { ERRORF(reporter, "Images must have the same alpha type"); return; } SkImageInfo info = SkImageInfo::MakeN32Premul(a->width(), a->height()); SkAutoPixmapStorage apm; SkAutoPixmapStorage bpm; apm.alloc(info); bpm.alloc(info); if (!a->readPixels(apm, 0, 0)) { ERRORF(reporter, "Could not read image a's pixels"); return; } if (!b->readPixels(bpm, 0, 0)) { ERRORF(reporter, "Could not read image b's pixels"); return; } for (auto y = 0; y < info.height(); ++y) { for (auto x = 0; x < info.width(); ++x) { uint32_t pixelA = *apm.addr32(x, y); uint32_t pixelB = *bpm.addr32(x, y); if (pixelA != pixelB) { ERRORF(reporter, "Expected image pixels to be the same. At %d,%d 0x%08x != 0x%08x", x, y, pixelA, pixelB); return; } } } } DEF_GPUTEST_FOR_RENDERING_CONTEXTS(NewTextureFromPixmap, reporter, ctxInfo) { for (auto create : {&create_image, &create_image_565, &create_image_ct}) { sk_sp image((*create)()); if (!image) { ERRORF(reporter, "Could not create image"); return; } SkPixmap pixmap; if (!image->peekPixels(&pixmap)) { ERRORF(reporter, "peek failed"); } else { sk_sp texImage(SkImage::MakeTextureFromPixmap(ctxInfo.grContext(), pixmap, SkBudgeted::kNo)); if (!texImage) { ERRORF(reporter, "NewTextureFromPixmap failed."); } else { check_images_same(reporter, image.get(), texImage.get()); } } } } DEF_GPUTEST_FOR_RENDERING_CONTEXTS(DeferredTextureImage, reporter, ctxInfo) { GrContext* context = ctxInfo.grContext(); sk_gpu_test::TestContext* testContext = ctxInfo.testContext(); sk_sp proxy = context->threadSafeProxy(); GrContextFactory otherFactory; ContextInfo otherContextInfo = otherFactory.getContextInfo(GrContextFactory::kNativeGL_ContextType); testContext->makeCurrent(); REPORTER_ASSERT(reporter, proxy); auto createLarge = [context] { return create_image_large(context->caps()->maxTextureSize()); }; struct { std::function ()> fImageFactory; std::vector fParams; SkFilterQuality fExpectedQuality; int fExpectedScaleFactor; bool fExpectation; } testCases[] = { { create_image, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, true }, { create_codec_image, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, true }, { create_data_image, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, true }, { create_picture_image, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, false }, { [context] { return create_gpu_image(context); }, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, false }, // Create a texture image in a another GrContext. { [testContext, otherContextInfo] { otherContextInfo.testContext()->makeCurrent(); sk_sp otherContextImage = create_gpu_image(otherContextInfo.grContext()); testContext->makeCurrent(); return otherContextImage; }, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, false }, // Create an image that is too large to upload. { createLarge, {{SkMatrix::I(), kNone_SkFilterQuality, 0}}, kNone_SkFilterQuality, 1, false }, // Create an image that is too large, but is scaled to an acceptable size. { createLarge, {{SkMatrix::I(), kMedium_SkFilterQuality, 4}}, kMedium_SkFilterQuality, 16, true}, // Create an image with multiple low filter qualities, make sure we round up. { createLarge, {{SkMatrix::I(), kNone_SkFilterQuality, 4}, {SkMatrix::I(), kMedium_SkFilterQuality, 4}}, kMedium_SkFilterQuality, 16, true}, // Create an image with multiple prescale levels, make sure we chose the minimum scale. { createLarge, {{SkMatrix::I(), kMedium_SkFilterQuality, 5}, {SkMatrix::I(), kMedium_SkFilterQuality, 4}}, kMedium_SkFilterQuality, 16, true}, }; for (auto testCase : testCases) { sk_sp image(testCase.fImageFactory()); if (!image) { ERRORF(reporter, "Failed to create image!"); continue; } size_t size = image->getDeferredTextureImageData(*proxy, testCase.fParams.data(), static_cast(testCase.fParams.size()), nullptr, nullptr); static const char *const kFS[] = { "fail", "succeed" }; if (SkToBool(size) != testCase.fExpectation) { ERRORF(reporter, "This image was expected to %s but did not.", kFS[testCase.fExpectation]); } if (size) { void* buffer = sk_malloc_throw(size); void* misaligned = reinterpret_cast(reinterpret_cast(buffer) + 3); if (image->getDeferredTextureImageData(*proxy, testCase.fParams.data(), static_cast(testCase.fParams.size()), misaligned, nullptr)) { ERRORF(reporter, "Should fail when buffer is misaligned."); } if (!image->getDeferredTextureImageData(*proxy, testCase.fParams.data(), static_cast(testCase.fParams.size()), buffer, nullptr)) { ERRORF(reporter, "deferred image size succeeded but creation failed."); } else { for (auto budgeted : { SkBudgeted::kNo, SkBudgeted::kYes }) { sk_sp newImage( SkImage::MakeFromDeferredTextureImageData(context, buffer, budgeted)); REPORTER_ASSERT(reporter, newImage != nullptr); if (newImage) { // Scale the image in software for comparison. SkImageInfo scaled_info = SkImageInfo::MakeN32( image->width() / testCase.fExpectedScaleFactor, image->height() / testCase.fExpectedScaleFactor, image->alphaType()); SkAutoPixmapStorage scaled; scaled.alloc(scaled_info); image->scalePixels(scaled, testCase.fExpectedQuality); sk_sp scaledImage = SkImage::MakeRasterCopy(scaled); check_images_same(reporter, scaledImage.get(), newImage.get()); } // The other context should not be able to create images from texture data // created by the original context. sk_sp newImage2(SkImage::MakeFromDeferredTextureImageData( otherContextInfo.grContext(), buffer, budgeted)); REPORTER_ASSERT(reporter, !newImage2); testContext->makeCurrent(); } } sk_free(buffer); } } } #endif /////////////////////////////////////////////////////////////////////////////////////////////////// static void make_all_premul(SkBitmap* bm) { bm->allocPixels(SkImageInfo::MakeN32(256, 256, kPremul_SkAlphaType)); for (int a = 0; a < 256; ++a) { for (int r = 0; r < 256; ++r) { // make all valid premul combinations int c = SkTMin(a, r); *bm->getAddr32(a, r) = SkPackARGB32(a, c, c, c); } } } static bool equal(const SkBitmap& a, const SkBitmap& b) { SkASSERT(a.width() == b.width()); SkASSERT(a.height() == b.height()); for (int y = 0; y < a.height(); ++y) { for (int x = 0; x < a.width(); ++x) { SkPMColor pa = *a.getAddr32(x, y); SkPMColor pb = *b.getAddr32(x, y); if (pa != pb) { return false; } } } return true; } DEF_TEST(image_roundtrip_encode, reporter) { SkBitmap bm0; make_all_premul(&bm0); auto img0 = SkImage::MakeFromBitmap(bm0); sk_sp data(img0->encode(SkEncodedImageFormat::kPNG, 100)); auto img1 = SkImage::MakeFromEncoded(data); SkBitmap bm1; bm1.allocPixels(SkImageInfo::MakeN32(256, 256, kPremul_SkAlphaType)); img1->readPixels(bm1.info(), bm1.getPixels(), bm1.rowBytes(), 0, 0); REPORTER_ASSERT(reporter, equal(bm0, bm1)); } DEF_TEST(image_roundtrip_premul, reporter) { SkBitmap bm0; make_all_premul(&bm0); SkBitmap bm1; bm1.allocPixels(SkImageInfo::MakeN32(256, 256, kUnpremul_SkAlphaType)); bm0.readPixels(bm1.info(), bm1.getPixels(), bm1.rowBytes(), 0, 0); SkBitmap bm2; bm2.allocPixels(SkImageInfo::MakeN32(256, 256, kPremul_SkAlphaType)); bm1.readPixels(bm2.info(), bm2.getPixels(), bm2.rowBytes(), 0, 0); REPORTER_ASSERT(reporter, equal(bm0, bm2)); }