/* * Copyright 2023 Google LLC * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "src/gpu/ganesh/image/GrImageUtils.h" #include "include/core/SkAlphaType.h" #include "include/core/SkBitmap.h" #include "include/core/SkColorSpace.h" #include "include/core/SkImage.h" #include "include/core/SkImageInfo.h" #include "include/core/SkPixmap.h" #include "include/core/SkPoint.h" #include "include/core/SkRect.h" #include "include/core/SkSamplingOptions.h" #include "include/core/SkScalar.h" #include "include/core/SkSize.h" #include "include/core/SkSurface.h" #include "include/core/SkTypes.h" #include "include/core/SkYUVAInfo.h" #include "include/core/SkYUVAPixmaps.h" #include "include/gpu/GpuTypes.h" #include "include/gpu/GrBackendSurface.h" #include "include/gpu/GrContextOptions.h" #include "include/gpu/GrRecordingContext.h" #include "include/gpu/GrTypes.h" #include "include/gpu/ganesh/SkSurfaceGanesh.h" #include "include/private/SkIDChangeListener.h" #include "include/private/base/SkMutex.h" #include "include/private/gpu/ganesh/GrImageContext.h" #include "include/private/gpu/ganesh/GrTextureGenerator.h" #include "include/private/gpu/ganesh/GrTypesPriv.h" #include "src/core/SkBlurEngine.h" #include "src/core/SkCachedData.h" #include "src/core/SkImageFilterCache.h" #include "src/core/SkImageFilterTypes.h" #include "src/core/SkSamplingPriv.h" #include "src/core/SkSpecialImage.h" #include "src/gpu/ResourceKey.h" #include "src/gpu/SkBackingFit.h" #include "src/gpu/Swizzle.h" #include "src/gpu/ganesh/Device.h" #include "src/gpu/ganesh/GrBlurUtils.h" #include "src/gpu/ganesh/GrCaps.h" #include "src/gpu/ganesh/GrColorSpaceXform.h" #include "src/gpu/ganesh/GrFragmentProcessor.h" #include "src/gpu/ganesh/GrImageInfo.h" #include "src/gpu/ganesh/GrProxyProvider.h" #include "src/gpu/ganesh/GrRecordingContextPriv.h" #include "src/gpu/ganesh/GrSamplerState.h" #include "src/gpu/ganesh/GrSurfaceProxy.h" #include "src/gpu/ganesh/GrSurfaceProxyView.h" #include "src/gpu/ganesh/GrTextureProxy.h" #include "src/gpu/ganesh/GrThreadSafeCache.h" #include "src/gpu/ganesh/GrYUVATextureProxies.h" #include "src/gpu/ganesh/SkGr.h" #include "src/gpu/ganesh/SurfaceDrawContext.h" #include "src/gpu/ganesh/SurfaceFillContext.h" #include "src/gpu/ganesh/effects/GrBicubicEffect.h" #include "src/gpu/ganesh/effects/GrTextureEffect.h" #include "src/gpu/ganesh/effects/GrYUVtoRGBEffect.h" #include "src/gpu/ganesh/image/SkImage_Ganesh.h" #include "src/gpu/ganesh/image/SkImage_GaneshBase.h" #include "src/gpu/ganesh/image/SkImage_RasterPinnable.h" #include "src/gpu/ganesh/image/SkSpecialImage_Ganesh.h" #include "src/image/SkImage_Base.h" #include "src/image/SkImage_Lazy.h" #include "src/image/SkImage_Picture.h" #include "src/image/SkImage_Raster.h" #include #include class SkDevice; class SkMatrix; class SkSurfaceProps; enum SkColorType : int; namespace skgpu::ganesh { GrSurfaceProxyView CopyView(GrRecordingContext* context, GrSurfaceProxyView src, skgpu::Mipmapped mipmapped, GrImageTexGenPolicy policy, std::string_view label) { skgpu::Budgeted budgeted = policy == GrImageTexGenPolicy::kNew_Uncached_Budgeted ? skgpu::Budgeted::kYes : skgpu::Budgeted::kNo; return GrSurfaceProxyView::Copy(context, std::move(src), mipmapped, SkBackingFit::kExact, budgeted, /*label=*/label); } std::tuple RasterAsView(GrRecordingContext* rContext, const SkImage_Raster* raster, skgpu::Mipmapped mipmapped, GrImageTexGenPolicy policy) { if (policy == GrImageTexGenPolicy::kDraw) { // If the draw doesn't require mipmaps but this SkImage has them go ahead and make a // mipmapped texture. There are three reasons for this: // 1) Avoiding another texture creation if a later draw requires mipmaps. // 2) Ensuring we upload the bitmap's levels instead of generating on the GPU from the base. if (raster->hasMipmaps()) { mipmapped = skgpu::Mipmapped::kYes; } return GrMakeCachedBitmapProxyView(rContext, raster->bitmap(), /*label=*/"TextureForImageRasterWithPolicyEqualKDraw", mipmapped); } auto budgeted = (policy == GrImageTexGenPolicy::kNew_Uncached_Unbudgeted) ? skgpu::Budgeted::kNo : skgpu::Budgeted::kYes; return GrMakeUncachedBitmapProxyView( rContext, raster->bitmap(), mipmapped, SkBackingFit::kExact, budgeted); } // Returns the GrColorType to use with the GrTextureProxy returned from lockTextureProxy. This // may be different from the color type on the image in the case where we need up upload CPU // data to a texture but the GPU doesn't support the format of CPU data. In this case we convert // the data to RGBA_8888 unorm on the CPU then upload that. GrColorType ColorTypeOfLockTextureProxy(const GrCaps* caps, SkColorType sct) { GrColorType ct = SkColorTypeToGrColorType(sct); GrBackendFormat format = caps->getDefaultBackendFormat(ct, GrRenderable::kNo); if (!format.isValid()) { ct = GrColorType::kRGBA_8888; } return ct; } static GrSurfaceOrigin get_origin(const SkImage_Lazy* img) { SkASSERT(img->generator()); if (!img->generator()->isTextureGenerator()) { return kTopLeft_GrSurfaceOrigin; } // origin should be thread safe return static_cast(img->generator()->fGenerator.get())->origin(); } static GrSurfaceProxyView texture_proxy_view_from_planes(GrRecordingContext* ctx, const SkImage_Lazy* img, skgpu::Budgeted budgeted) { auto supportedDataTypes = SupportedTextureFormats(*ctx); SkYUVAPixmaps yuvaPixmaps; sk_sp dataStorage = img->getPlanes(supportedDataTypes, &yuvaPixmaps); if (!dataStorage) { return {}; } GrSurfaceProxyView views[SkYUVAInfo::kMaxPlanes]; GrColorType pixmapColorTypes[SkYUVAInfo::kMaxPlanes]; for (int i = 0; i < yuvaPixmaps.numPlanes(); ++i) { // If the sizes of the components are not all the same we choose to create exact-match // textures for the smaller ones rather than add a texture domain to the draw. // TODO: revisit this decision to improve texture reuse? SkBackingFit fit = yuvaPixmaps.plane(i).dimensions() == img->dimensions() ? SkBackingFit::kApprox : SkBackingFit::kExact; // We grab a ref to cached yuv data. When the SkBitmap we create below goes away it will // call releaseProc which will release this ref. // DDL TODO: Currently we end up creating a lazy proxy that will hold onto a ref to the // SkImage in its lambda. This means that we'll keep the ref on the YUV data around for the // life time of the proxy and not just upload. For non-DDL draws we should look into // releasing this SkImage after uploads (by deleting the lambda after instantiation). auto releaseProc = [](void*, void* data) { auto cachedData = static_cast(data); SkASSERT(cachedData); cachedData->unref(); }; SkBitmap bitmap; bitmap.installPixels(yuvaPixmaps.plane(i).info(), yuvaPixmaps.plane(i).writable_addr(), yuvaPixmaps.plane(i).rowBytes(), releaseProc, SkRef(dataStorage.get())); bitmap.setImmutable(); std::tie(views[i], std::ignore) = GrMakeUncachedBitmapProxyView(ctx, bitmap, skgpu::Mipmapped::kNo, fit); if (!views[i]) { return {}; } pixmapColorTypes[i] = SkColorTypeToGrColorType(bitmap.colorType()); } // TODO: investigate preallocating mip maps here GrImageInfo info(SkColorTypeToGrColorType(img->colorType()), kPremul_SkAlphaType, /*color space*/ nullptr, img->dimensions()); auto sfc = ctx->priv().makeSFC(info, "ImageLazy_TextureProxyViewFromPlanes", SkBackingFit::kExact, 1, skgpu::Mipmapped::kNo, GrProtected::kNo, kTopLeft_GrSurfaceOrigin, budgeted); if (!sfc) { return {}; } GrYUVATextureProxies yuvaProxies(yuvaPixmaps.yuvaInfo(), views, pixmapColorTypes); SkAssertResult(yuvaProxies.isValid()); std::unique_ptr fp = GrYUVtoRGBEffect::Make( yuvaProxies, GrSamplerState::Filter::kNearest, *ctx->priv().caps()); // The pixels after yuv->rgb will be in the generator's color space. // If onMakeColorTypeAndColorSpace has been called then this will not match this image's // color space. To correct this, apply a color space conversion from the generator's color // space to this image's color space. SkColorSpace* srcColorSpace = img->generator()->getInfo().colorSpace(); SkColorSpace* dstColorSpace = img->colorSpace(); // If the caller expects the pixels in a different color space than the one from the image, // apply a color conversion to do this. fp = GrColorSpaceXformEffect::Make(std::move(fp), srcColorSpace, kOpaque_SkAlphaType, dstColorSpace, kOpaque_SkAlphaType); sfc->fillWithFP(std::move(fp)); return sfc->readSurfaceView(); } static GrSurfaceProxyView generate_picture_texture(GrRecordingContext* ctx, const SkImage_Picture* img, skgpu::Mipmapped mipmapped, GrImageTexGenPolicy texGenPolicy) { SkASSERT(ctx); SkASSERT(img); skgpu::Budgeted budgeted = texGenPolicy == GrImageTexGenPolicy::kNew_Uncached_Unbudgeted ? skgpu::Budgeted::kNo : skgpu::Budgeted::kYes; auto surface = SkSurfaces::RenderTarget(ctx, budgeted, img->imageInfo(), 0, kTopLeft_GrSurfaceOrigin, img->props(), mipmapped == skgpu::Mipmapped::kYes); if (!surface) { return {}; } img->replay(surface->getCanvas()); sk_sp image(surface->makeImageSnapshot()); if (!image) { return {}; } auto [view, ct] = AsView(ctx, image, mipmapped); SkASSERT(view); SkASSERT(mipmapped == skgpu::Mipmapped::kNo || view.asTextureProxy()->mipmapped() == skgpu::Mipmapped::kYes); return view; } // Returns the texture proxy. We will always cache the generated texture on success. // We have 4 ways to try to return a texture (in sorted order) // // 1. Check the cache for a pre-existing one // 2. Ask the generator to natively create one // 3. Ask the generator to return YUV planes, which the GPU can convert // 4. Ask the generator to return RGB(A) data, which the GPU can convert GrSurfaceProxyView LockTextureProxyView(GrRecordingContext* rContext, const SkImage_Lazy* img, GrImageTexGenPolicy texGenPolicy, skgpu::Mipmapped mipmapped) { // Values representing the various texture lock paths we can take. Used for logging the path // taken to a histogram. enum LockTexturePath { kFailure_LockTexturePath, kPreExisting_LockTexturePath, kNative_LockTexturePath, kCompressed_LockTexturePath, // Deprecated kYUV_LockTexturePath, kRGBA_LockTexturePath, }; enum { kLockTexturePathCount = kRGBA_LockTexturePath + 1 }; skgpu::UniqueKey key; if (texGenPolicy == GrImageTexGenPolicy::kDraw) { GrMakeKeyFromImageID(&key, img->uniqueID(), SkIRect::MakeSize(img->dimensions())); } const GrCaps* caps = rContext->priv().caps(); GrProxyProvider* proxyProvider = rContext->priv().proxyProvider(); auto installKey = [&](const GrSurfaceProxyView& view) { SkASSERT(view && view.asTextureProxy()); if (key.isValid()) { auto listener = GrMakeUniqueKeyInvalidationListener(&key, rContext->priv().contextID()); img->addUniqueIDListener(std::move(listener)); proxyProvider->assignUniqueKeyToProxy(key, view.asTextureProxy()); } }; auto ct = ColorTypeOfLockTextureProxy(caps, img->colorType()); // 1. Check the cache for a pre-existing one. if (key.isValid()) { auto proxy = proxyProvider->findOrCreateProxyByUniqueKey(key); if (proxy) { skgpu::Swizzle swizzle = caps->getReadSwizzle(proxy->backendFormat(), ct); GrSurfaceOrigin origin = get_origin(img); GrSurfaceProxyView view(std::move(proxy), origin, swizzle); if (mipmapped == skgpu::Mipmapped::kNo || view.asTextureProxy()->mipmapped() == skgpu::Mipmapped::kYes) { return view; } else { // We need a mipped proxy, but we found a cached proxy that wasn't mipped. Thus we // generate a new mipped surface and copy the original proxy into the base layer. We // will then let the gpu generate the rest of the mips. auto mippedView = GrCopyBaseMipMapToView(rContext, view); if (!mippedView) { // We failed to make a mipped proxy with the base copied into it. This could // have been from failure to make the proxy or failure to do the copy. Thus we // will fall back to just using the non mipped proxy; See skbug.com/7094. return view; } proxyProvider->removeUniqueKeyFromProxy(view.asTextureProxy()); installKey(mippedView); return mippedView; } } } // 2. Ask the generator to natively create one (if it knows how) { if (img->type() == SkImage_Base::Type::kLazyPicture) { if (auto view = generate_picture_texture(rContext, static_cast(img), mipmapped, texGenPolicy)) { installKey(view); return view; } } else if (img->generator()->isTextureGenerator()) { auto sharedGenerator = img->generator(); SkAutoMutexExclusive mutex(sharedGenerator->fMutex); auto textureGen = static_cast(sharedGenerator->fGenerator.get()); if (auto view = textureGen->generateTexture(rContext, img->imageInfo(), mipmapped, texGenPolicy)) { installKey(view); return view; } } } // 3. Ask the generator to return YUV planes, which the GPU can convert. If we will be mipping // the texture we skip this step so the CPU generate non-planar MIP maps for us. if (mipmapped == skgpu::Mipmapped::kNo && !rContext->priv().options().fDisableGpuYUVConversion) { // TODO: Update to create the mipped surface in the textureProxyViewFromPlanes generator and // draw the base layer directly into the mipped surface. skgpu::Budgeted budgeted = texGenPolicy == GrImageTexGenPolicy::kNew_Uncached_Unbudgeted ? skgpu::Budgeted::kNo : skgpu::Budgeted::kYes; auto view = texture_proxy_view_from_planes(rContext, img, budgeted); if (view) { installKey(view); return view; } } // 4. Ask the generator to return a bitmap, which the GPU can convert. auto hint = texGenPolicy == GrImageTexGenPolicy::kDraw ? SkImage::CachingHint::kAllow_CachingHint : SkImage::CachingHint::kDisallow_CachingHint; if (SkBitmap bitmap; img->getROPixels(nullptr, &bitmap, hint)) { // We always make an uncached bitmap here because we will cache it based on passed in policy // with *our* key, not a key derived from bitmap. We're just making the proxy here. auto budgeted = texGenPolicy == GrImageTexGenPolicy::kNew_Uncached_Unbudgeted ? skgpu::Budgeted::kNo : skgpu::Budgeted::kYes; auto view = std::get<0>(GrMakeUncachedBitmapProxyView(rContext, bitmap, mipmapped, SkBackingFit::kExact, budgeted)); if (view) { installKey(view); return view; } } return {}; } static std::tuple lazy_as_view(GrRecordingContext* context, const SkImage_Lazy* img, skgpu::Mipmapped mipmapped, GrImageTexGenPolicy policy) { GrColorType ct = ColorTypeOfLockTextureProxy(context->priv().caps(), img->colorType()); return {LockTextureProxyView(context, img, policy, mipmapped), ct}; } std::tuple AsView(GrRecordingContext* rContext, const SkImage* img, skgpu::Mipmapped mipmapped, GrImageTexGenPolicy policy) { SkASSERT(img); if (!rContext) { return {}; } if (!rContext->priv().caps()->mipmapSupport() || img->dimensions().area() <= 1) { mipmapped = skgpu::Mipmapped::kNo; } auto ib = static_cast(img); if (ib->type() == SkImage_Base::Type::kRaster) { return skgpu::ganesh::RasterAsView( rContext, static_cast(ib), mipmapped, policy); } else if (ib->type() == SkImage_Base::Type::kRasterPinnable) { auto rp = static_cast(img); return rp->asView(rContext, mipmapped, policy); } else if (ib->isGaneshBacked()) { auto gb = static_cast(img); return gb->asView(rContext, mipmapped, policy); } else if (ib->isLazyGenerated()) { return lazy_as_view(rContext, static_cast(ib), mipmapped, policy); } SkDEBUGFAIL("Unsupported image type to make a View"); return {}; } static std::unique_ptr make_fp_from_view(GrRecordingContext* rContext, GrSurfaceProxyView view, SkAlphaType at, SkSamplingOptions sampling, const SkTileMode tileModes[2], const SkMatrix& m, const SkRect* subset, const SkRect* domain) { if (!view) { return nullptr; } const GrCaps& caps = *rContext->priv().caps(); auto wmx = SkTileModeToWrapMode(tileModes[0]); auto wmy = SkTileModeToWrapMode(tileModes[1]); if (sampling.useCubic) { if (subset) { if (domain) { return GrBicubicEffect::MakeSubset(std::move(view), at, m, wmx, wmy, *subset, *domain, sampling.cubic, GrBicubicEffect::Direction::kXY, *rContext->priv().caps()); } return GrBicubicEffect::MakeSubset(std::move(view), at, m, wmx, wmy, *subset, sampling.cubic, GrBicubicEffect::Direction::kXY, *rContext->priv().caps()); } return GrBicubicEffect::Make(std::move(view), at, m, wmx, wmy, sampling.cubic, GrBicubicEffect::Direction::kXY, *rContext->priv().caps()); } if (sampling.isAniso()) { if (!rContext->priv().caps()->anisoSupport()) { // Fallback to linear sampling = SkSamplingPriv::AnisoFallback(view.mipmapped() == skgpu::Mipmapped::kYes); } } else if (view.mipmapped() == skgpu::Mipmapped::kNo) { sampling = SkSamplingOptions(sampling.filter); } GrSamplerState sampler; if (sampling.isAniso()) { sampler = GrSamplerState::Aniso(wmx, wmy, sampling.maxAniso, view.mipmapped()); } else { sampler = GrSamplerState(wmx, wmy, sampling.filter, sampling.mipmap); } if (subset) { if (domain) { return GrTextureEffect::MakeSubset( std::move(view), at, m, sampler, *subset, *domain, caps); } return GrTextureEffect::MakeSubset(std::move(view), at, m, sampler, *subset, caps); } else { return GrTextureEffect::Make(std::move(view), at, m, sampler, caps); } } std::unique_ptr raster_as_fp(GrRecordingContext* rContext, const SkImage_Raster* img, SkSamplingOptions sampling, const SkTileMode tileModes[2], const SkMatrix& m, const SkRect* subset, const SkRect* domain) { auto mm = sampling.mipmap == SkMipmapMode::kNone ? skgpu::Mipmapped::kNo : skgpu::Mipmapped::kYes; return make_fp_from_view(rContext, std::get<0>(AsView(rContext, img, mm)), img->alphaType(), sampling, tileModes, m, subset, domain); } std::unique_ptr AsFragmentProcessor(GrRecordingContext* rContext, const SkImage* img, SkSamplingOptions sampling, const SkTileMode tileModes[2], const SkMatrix& m, const SkRect* subset, const SkRect* domain) { if (!rContext) { return {}; } if (sampling.useCubic && !GrValidCubicResampler(sampling.cubic)) { return {}; } if (sampling.mipmap != SkMipmapMode::kNone && (!rContext->priv().caps()->mipmapSupport() || img->dimensions().area() <= 1)) { sampling = SkSamplingOptions(sampling.filter); } auto ib = static_cast(img); if (ib->isRasterBacked()) { return raster_as_fp(rContext, static_cast(ib), sampling, tileModes, m, subset, domain); } else if (ib->isGaneshBacked()) { auto gb = static_cast(img); return gb->asFragmentProcessor(rContext, sampling, tileModes, m, subset, domain); } else if (ib->isLazyGenerated()) { // TODO: If the CPU data is extracted as planes return a FP that reconstructs the image from // the planes. auto mm = sampling.mipmap == SkMipmapMode::kNone ? skgpu::Mipmapped::kNo : skgpu::Mipmapped::kYes; return MakeFragmentProcessorFromView(rContext, std::get<0>(AsView(rContext, img, mm)), img->alphaType(), sampling, tileModes, m, subset, domain); } SkDEBUGFAIL("Unsupported image type to make a FragmentProcessor"); return {}; } std::unique_ptr MakeFragmentProcessorFromView( GrRecordingContext* rContext, GrSurfaceProxyView view, SkAlphaType at, SkSamplingOptions sampling, const SkTileMode tileModes[2], const SkMatrix& m, const SkRect* subset, const SkRect* domain) { if (!view) { return nullptr; } const GrCaps& caps = *rContext->priv().caps(); auto wmx = SkTileModeToWrapMode(tileModes[0]); auto wmy = SkTileModeToWrapMode(tileModes[1]); if (sampling.useCubic) { if (subset) { if (domain) { return GrBicubicEffect::MakeSubset(std::move(view), at, m, wmx, wmy, *subset, *domain, sampling.cubic, GrBicubicEffect::Direction::kXY, *rContext->priv().caps()); } return GrBicubicEffect::MakeSubset(std::move(view), at, m, wmx, wmy, *subset, sampling.cubic, GrBicubicEffect::Direction::kXY, *rContext->priv().caps()); } return GrBicubicEffect::Make(std::move(view), at, m, wmx, wmy, sampling.cubic, GrBicubicEffect::Direction::kXY, *rContext->priv().caps()); } if (sampling.isAniso()) { if (!rContext->priv().caps()->anisoSupport()) { // Fallback to linear sampling = SkSamplingPriv::AnisoFallback(view.mipmapped() == skgpu::Mipmapped::kYes); } } else if (view.mipmapped() == skgpu::Mipmapped::kNo) { sampling = SkSamplingOptions(sampling.filter); } GrSamplerState sampler; if (sampling.isAniso()) { sampler = GrSamplerState::Aniso(wmx, wmy, sampling.maxAniso, view.mipmapped()); } else { sampler = GrSamplerState(wmx, wmy, sampling.filter, sampling.mipmap); } if (subset) { if (domain) { return GrTextureEffect::MakeSubset(std::move(view), at, m, sampler, *subset, *domain, caps); } return GrTextureEffect::MakeSubset(std::move(view), at, m, sampler, *subset, caps); } else { return GrTextureEffect::Make(std::move(view), at, m, sampler, caps); } } GrSurfaceProxyView FindOrMakeCachedMipmappedView(GrRecordingContext* rContext, GrSurfaceProxyView view, uint32_t imageUniqueID) { SkASSERT(rContext); SkASSERT(imageUniqueID != SK_InvalidUniqueID); if (!view || view.proxy()->asTextureProxy()->mipmapped() == skgpu::Mipmapped::kYes) { return view; } GrProxyProvider* proxyProvider = rContext->priv().proxyProvider(); skgpu::UniqueKey baseKey; GrMakeKeyFromImageID(&baseKey, imageUniqueID, SkIRect::MakeSize(view.dimensions())); SkASSERT(baseKey.isValid()); skgpu::UniqueKey mipmappedKey; static const skgpu::UniqueKey::Domain kMipmappedDomain = skgpu::UniqueKey::GenerateDomain(); { // No extra values beyond the domain are required. Must name the var to please // clang-tidy. skgpu::UniqueKey::Builder b(&mipmappedKey, baseKey, kMipmappedDomain, 0); } SkASSERT(mipmappedKey.isValid()); if (sk_sp cachedMippedView = proxyProvider->findOrCreateProxyByUniqueKey(mipmappedKey)) { return {std::move(cachedMippedView), view.origin(), view.swizzle()}; } auto copy = GrCopyBaseMipMapToView(rContext, view); if (!copy) { return view; } // TODO: If we move listeners up from SkImage_Lazy to SkImage_Base then add one here. proxyProvider->assignUniqueKeyToProxy(mipmappedKey, copy.asTextureProxy()); return copy; } using DataType = SkYUVAPixmapInfo::DataType; SkYUVAPixmapInfo::SupportedDataTypes SupportedTextureFormats(const GrImageContext& context) { SkYUVAPixmapInfo::SupportedDataTypes dataTypes; const auto isValid = [&context](DataType dt, int n) { return context.defaultBackendFormat(SkYUVAPixmapInfo::DefaultColorTypeForDataType(dt, n), GrRenderable::kNo).isValid(); }; for (int n = 1; n <= 4; ++n) { if (isValid(DataType::kUnorm8, n)) { dataTypes.enableDataType(DataType::kUnorm8, n); } if (isValid(DataType::kUnorm16, n)) { dataTypes.enableDataType(DataType::kUnorm16, n); } if (isValid(DataType::kFloat16, n)) { dataTypes.enableDataType(DataType::kFloat16, n); } if (isValid(DataType::kUnorm10_Unorm2, n)) { dataTypes.enableDataType(DataType::kUnorm10_Unorm2, n); } } return dataTypes; } } // namespace skgpu::ganesh namespace skif { namespace { class GaneshBackend : public Backend, private SkBlurEngine, private SkBlurEngine::Algorithm { public: GaneshBackend(sk_sp context, GrSurfaceOrigin origin, const SkSurfaceProps& surfaceProps, SkColorType colorType) : Backend(SkImageFilterCache::Create(SkImageFilterCache::kDefaultTransientSize), surfaceProps, colorType) , fContext(std::move(context)) , fOrigin(origin) {} // Backend sk_sp makeDevice(SkISize size, sk_sp colorSpace, const SkSurfaceProps* props) const override { SkImageInfo imageInfo = SkImageInfo::Make(size, this->colorType(), kPremul_SkAlphaType, std::move(colorSpace)); return fContext->priv().createDevice(skgpu::Budgeted::kYes, imageInfo, SkBackingFit::kApprox, 1, skgpu::Mipmapped::kNo, GrProtected::kNo, fOrigin, props ? *props : this->surfaceProps(), skgpu::ganesh::Device::InitContents::kUninit); } sk_sp makeImage(const SkIRect& subset, sk_sp image) const override { return SkSpecialImages::MakeFromTextureImage( fContext.get(), subset, image, this->surfaceProps()); } sk_sp getCachedBitmap(const SkBitmap& data) const override { // This uses the thread safe cache (instead of GrMakeCachedBitmapProxyView) so that image // filters can be evaluated on other threads with DDLs. auto threadSafeCache = fContext->priv().threadSafeCache(); skgpu::UniqueKey key; SkIRect subset = SkIRect::MakePtSize(data.pixelRefOrigin(), data.dimensions()); GrMakeKeyFromImageID(&key, data.getGenerationID(), subset); auto view = threadSafeCache->find(key); if (!view) { view = std::get<0>(GrMakeUncachedBitmapProxyView(fContext.get(), data)); if (!view) { return nullptr; } threadSafeCache->add(key, view); } return sk_make_sp(fContext, data.getGenerationID(), std::move(view), data.info().colorInfo()); } const SkBlurEngine* getBlurEngine() const override { return this; } // SkBlurEngine const SkBlurEngine::Algorithm* findAlgorithm(SkSize sigma, SkColorType colorType) const override { // GrBlurUtils supports all tile modes and color types return this; } // SkBlurEngine::Algorithm float maxSigma() const override { // GrBlurUtils handles resizing at the moment return SK_ScalarInfinity; } bool supportsOnlyDecalTiling() const override { return false; } sk_sp blur(SkSize sigma, sk_sp input, const SkIRect& srcRect, SkTileMode tileMode, const SkIRect& dstRect) const override { GrSurfaceProxyView inputView = SkSpecialImages::AsView(fContext.get(), input); if (!inputView.proxy()) { return nullptr; } SkASSERT(inputView.asTextureProxy()); // Update srcRect and dstRect to be relative to the underlying texture proxy of 'input'. auto proxyOffset = input->subset().topLeft() - srcRect.topLeft(); auto sdc = GrBlurUtils::GaussianBlur( fContext.get(), std::move(inputView), SkColorTypeToGrColorType(input->colorType()), input->alphaType(), sk_ref_sp(input->getColorSpace()), dstRect.makeOffset(proxyOffset), srcRect.makeOffset(proxyOffset), sigma.width(), sigma.height(), tileMode); if (!sdc) { return nullptr; } return SkSpecialImages::MakeDeferredFromGpu(fContext.get(), SkIRect::MakeSize(dstRect.size()), kNeedNewImageUniqueID_SpecialImage, sdc->readSurfaceView(), sdc->colorInfo(), this->surfaceProps()); } private: sk_sp fContext; GrSurfaceOrigin fOrigin; }; } // anonymous namespace sk_sp MakeGaneshBackend(sk_sp context, GrSurfaceOrigin origin, const SkSurfaceProps& surfaceProps, SkColorType colorType) { SkASSERT(context); return sk_make_sp(std::move(context), origin, surfaceProps, colorType); } } // namespace skif