/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "Logging.h" #include "SourceSurfaceSkia.h" #include "HelpersSkia.h" #include "DrawTargetSkia.h" #include "DataSurfaceHelpers.h" #include "skia/include/core/SkData.h" #include "skia/include/core/SkImage.h" #include "skia/include/core/SkSurface.h" #include "mozilla/CheckedInt.h" namespace mozilla::gfx { SourceSurfaceSkia::SourceSurfaceSkia() : mFormat(SurfaceFormat::UNKNOWN), mStride(0), mDrawTarget(nullptr), mChangeMutex("SourceSurfaceSkia::mChangeMutex"), mIsMapped(false) {} SourceSurfaceSkia::~SourceSurfaceSkia() { // if mIsMapped is true then mChangeMutex will be locked // which will cause problems during destruction. MOZ_RELEASE_ASSERT(!mIsMapped); } IntSize SourceSurfaceSkia::GetSize() const { return mSize; } SurfaceFormat SourceSurfaceSkia::GetFormat() const { return mFormat; } // This is only ever called by the DT destructor, which can only ever happen // from one place at a time. Therefore it doesn't need to hold the ChangeMutex // as mSurface is never read to directly and is just there to keep the object // alive, which itself is refcounted in a thread-safe manner. void SourceSurfaceSkia::GiveSurface(SkSurface* aSurface) { mSurface.reset(aSurface); mDrawTarget = nullptr; } sk_sp SourceSurfaceSkia::GetImage(Maybe* aLock) { // If we were provided a lock object, we can let the caller access // a shared SkImage and we know it won't go away while the lock is held. // Otherwise we need to call DrawTargetWillChange to ensure we have our // own SkImage. if (aLock) { MOZ_ASSERT(aLock->isNothing()); aLock->emplace(mChangeMutex); // Now that we are locked, we can check mDrawTarget. If it's null, then // we're not shared and we can unlock eagerly. if (!mDrawTarget) { aLock->reset(); } } else { DrawTargetWillChange(); } sk_sp image = mImage; return image; } static sk_sp MakeSkData(void* aData, int32_t aHeight, size_t aStride) { CheckedInt size = aStride; size *= aHeight; if (size.isValid()) { void* mem = sk_malloc_flags(size.value(), 0); if (mem) { if (aData) { memcpy(mem, aData, size.value()); } return SkData::MakeFromMalloc(mem, size.value()); } } return nullptr; } static sk_sp ReadSkImage(const sk_sp& aImage, const SkImageInfo& aInfo, size_t aStride) { if (sk_sp data = MakeSkData(nullptr, aInfo.height(), aStride)) { if (aImage->readPixels(aInfo, data->writable_data(), aStride, 0, 0, SkImage::kDisallow_CachingHint)) { return SkImage::MakeRasterData(aInfo, data, aStride); } } return nullptr; } bool SourceSurfaceSkia::InitFromData(unsigned char* aData, const IntSize& aSize, int32_t aStride, SurfaceFormat aFormat) { sk_sp data = MakeSkData(aData, aSize.height, aStride); if (!data) { return false; } SkImageInfo info = MakeSkiaImageInfo(aSize, aFormat); mImage = SkImage::MakeRasterData(info, data, aStride); if (!mImage) { return false; } mSize = aSize; mFormat = aFormat; mStride = aStride; return true; } bool SourceSurfaceSkia::InitFromImage(const sk_sp& aImage, SurfaceFormat aFormat, DrawTargetSkia* aOwner) { if (!aImage) { return false; } mSize = IntSize(aImage->width(), aImage->height()); // For the raster image case, we want to use the format and stride // information that the underlying raster image is using, which is // reliable. // For the GPU case (for which peekPixels is false), we can't easily // figure this information out. It is better to report the originally // intended format and stride that we will convert to if this GPU // image is ever read back into a raster image. SkPixmap pixmap; if (aImage->peekPixels(&pixmap)) { mFormat = aFormat != SurfaceFormat::UNKNOWN ? aFormat : SkiaColorTypeToGfxFormat(pixmap.colorType(), pixmap.alphaType()); mStride = pixmap.rowBytes(); } else if (aFormat != SurfaceFormat::UNKNOWN) { mFormat = aFormat; SkImageInfo info = MakeSkiaImageInfo(mSize, mFormat); mStride = SkAlign4(info.minRowBytes()); } else { return false; } mImage = aImage; if (aOwner) { mDrawTarget = aOwner; } return true; } uint8_t* SourceSurfaceSkia::GetData() { if (!mImage) { return nullptr; } SkPixmap pixmap; if (!mImage->peekPixels(&pixmap)) { gfxCriticalError() << "Failed accessing pixels for Skia raster image"; } return reinterpret_cast(pixmap.writable_addr()); } bool SourceSurfaceSkia::Map(MapType, MappedSurface* aMappedSurface) { mChangeMutex.Lock(); aMappedSurface->mData = GetData(); aMappedSurface->mStride = Stride(); mIsMapped = !!aMappedSurface->mData; bool isMapped = mIsMapped; if (!mIsMapped) { mChangeMutex.Unlock(); } return isMapped; } void SourceSurfaceSkia::Unmap() { MOZ_ASSERT(mIsMapped); mIsMapped = false; mChangeMutex.Unlock(); } void SourceSurfaceSkia::DrawTargetWillChange() { MutexAutoLock lock(mChangeMutex); if (mDrawTarget.exchange(nullptr)) { // Raster snapshots do not use Skia's internal copy-on-write mechanism, // so we need to do an explicit copy here. // GPU snapshots, for which peekPixels is false, will already be dealt // with automatically via the internal copy-on-write mechanism, so we // don't need to do anything for them here. SkPixmap pixmap; if (mImage->peekPixels(&pixmap)) { mImage = ReadSkImage(mImage, pixmap.info(), pixmap.rowBytes()); if (!mImage) { gfxCriticalError() << "Failed copying Skia raster snapshot"; } } } } } // namespace mozilla::gfx