cc/tiles/gpu_image_decode_controller.h - chromium/src - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef CC_TILES_GPU_IMAGE_DECODE_CONTROLLER_H_
 #define CC_TILES_GPU_IMAGE_DECODE_CONTROLLER_H_

 #include <memory>
 #include <unordered_map>
 #include <vector>

 #include "base/containers/mru_cache.h"
 #include "base/memory/discardable_memory.h"
 #include "base/synchronization/lock.h"
 #include "base/trace_event/memory_dump_provider.h"
 #include "cc/base/cc_export.h"
 #include "cc/resources/resource_format.h"
 #include "cc/tiles/image_decode_controller.h"
 #include "third_party/skia/include/core/SkRefCnt.h"

 class SkImageTextureData;

 namespace cc {

 class ContextProvider;

 // OVERVIEW:
 //
 // GpuImageDecodeController handles the decode and upload of images that will
 // be used by Skia's GPU raster path. It also maintains a cache of these
 // decoded/uploaded images for later re-use.
 //
 // Generally, when an image is required for raster, GpuImageDecodeController
 // creates two tasks, one to decode the image, and one to upload the image to
 // the GPU. These tasks are completed before the raster task which depends on
 // the image. We need to seperate decode and upload tasks, as decode can occur
 // simultaneously on multiple threads, while upload requires the GL context
 // lock must happen on our non-concurrent raster thread.
 //
 // Decoded and Uploaded image data share a single cache entry. Depending on how
 // far we've progressed, this cache entry may contain CPU-side decoded data,
 // GPU-side uploaded data, or both. Because CPU-side decoded data is stored in
 // discardable memory, and is only locked for short periods of time (until the
 // upload completes), this memory is not counted against our sized cache
 // limits. Uploaded GPU memory, being non-discardable, always counts against
 // our limits.
 //
 // In cases where the number of images needed exceeds our cache limits, we
 // operate in an "at-raster" mode. In this mode, there are no decode/upload
 // tasks, and images are decoded/uploaded as needed, immediately before being
 // used in raster. Cache entries for at-raster tasks are marked as such, which
 // prevents future tasks from taking a dependency on them and extending their
 // lifetime longer than is necessary.
 //
 // RASTER-SCALE CACHING:
 //
 // In order to save memory, images which are going to be scaled may be uploaded
 // at lower than original resolution. In these cases, we may later need to
 // re-upload the image at a higher resolution. To handle multiple images of
 // different scales being in use at the same time, we have a two-part caching
 // system.
 //
 // The first cache, |persistent_cache_|, stores one ImageData per image id.
 // These ImageDatas are not necessarily associated with a given DrawImage, and
 // are saved (persisted) even when their ref-count reaches zero (assuming they
 // fit in the current memory budget). This allows for future re-use of image
 // resources.
 //
 // The second cache, |in_use_cache_|, stores one image data per DrawImage -
 // this may be the same ImageData that is in the persistent_cache_.  These
 // cache entries are more transient and are deleted as soon as all refs to the
 // given DrawImage are released (the image is no longer in-use).
 //
 // For examples of raster-scale caching, see https://goo.gl/0zCd9Z
 //
 // REF COUNTING:
 //
 // In dealing with the two caches in GpuImageDecodeController, there are three
 // ref-counting concepts in use:
 //   1) ImageData upload/decode ref-counts.
 //      These ref-counts represent the overall number of references to the
 //      upload or decode portion of an ImageData. These ref-counts control
 //      both whether the upload/decode data can be freed, as well as whether an
 //      ImageData can be removed from the |persistent_cache_|. ImageDatas are
 //      only removed from the |persistent_cache_| if their upload/decode
 //      ref-counts are zero or if they are orphaned and replaced by a new entry.
 //   2) InUseCacheEntry ref-counts.
 //      These ref-counts represent the number of references to an
 //      InUseCacheEntry from a specific DrawImage. When the InUseCacheEntry's
 //      ref-count reaches 0 it will be deleted.
 //   3) scoped_refptr ref-counts.
 //      Because both the persistent_cache_ and the in_use_cache_ point at the
 //      same ImageDatas (and may need to keep these ImageDatas alive independent
 //      of each other), they hold ImageDatas by scoped_refptr. The scoped_refptr
 //      keeps an ImageData alive while it is present in either the
 //      |persistent_cache_| or |in_use_cache_|.
 //
 class CC_EXPORT GpuImageDecodeController
     : public ImageDecodeController,
       public base::trace_event::MemoryDumpProvider {
  public:
   explicit GpuImageDecodeController(ContextProvider* context,
                                     ResourceFormat decode_format,
                                     size_t max_gpu_image_bytes);
   ~GpuImageDecodeController() override;

   // ImageDecodeController overrides.

   // Finds the existing uploaded image for the provided DrawImage. Creates an
   // upload task to upload the image if an exsiting image does not exist.
   bool GetTaskForImageAndRef(const DrawImage& image,
                              const TracingInfo& tracing_info,
                              scoped_refptr<TileTask>* task) override;
   void UnrefImage(const DrawImage& image) override;
   DecodedDrawImage GetDecodedImageForDraw(const DrawImage& draw_image) override;
   void DrawWithImageFinished(const DrawImage& image,
                              const DecodedDrawImage& decoded_image) override;
   void ReduceCacheUsage() override;
   void SetShouldAggressivelyFreeResources(
       bool aggressively_free_resources) override;

   // MemoryDumpProvider overrides.
   bool OnMemoryDump(const base::trace_event::MemoryDumpArgs& args,
                     base::trace_event::ProcessMemoryDump* pmd) override;

   // Called by Decode / Upload tasks.
   void DecodeImage(const DrawImage& image);
   void UploadImage(const DrawImage& image);

   // Called by Decode / Upload tasks when tasks are finished.
   void OnImageDecodeTaskCompleted(const DrawImage& image);
   void OnImageUploadTaskCompleted(const DrawImage& image);

   // For testing only.
   void SetCachedItemLimitForTesting(size_t limit) {
     cached_items_limit_ = limit;
   }
   void SetCachedBytesLimitForTesting(size_t limit) {
     cached_bytes_limit_ = limit;
   }
   size_t GetBytesUsedForTesting() const { return bytes_used_; }
   size_t GetDrawImageSizeForTesting(const DrawImage& image);
   void SetImageDecodingFailedForTesting(const DrawImage& image);
   bool DiscardableIsLockedForTesting(const DrawImage& image);

  private:
   enum class DecodedDataMode { GPU, CPU };

   // Stores the CPU-side decoded bits of an image and supporting fields.
   struct DecodedImageData {
     DecodedImageData();
     ~DecodedImageData();

     bool is_locked() const { return is_locked_; }
     bool Lock();
     void Unlock();
     void SetLockedData(std::unique_ptr<base::DiscardableMemory> data);
     void ResetData();
     base::DiscardableMemory* data() const { return data_.get(); }
     void mark_used() { usage_stats_.used = true; }

     uint32_t ref_count = 0;
     // Set to true if the image was corrupt and could not be decoded.
     bool decode_failure = false;
     // If non-null, this is the pending decode task for this image.
     scoped_refptr<TileTask> task;

    private:
     struct UsageStats {
       int lock_count = 1;
       bool used = false;
       bool first_lock_wasted = false;
     };

     void ReportUsageStats() const;

     std::unique_ptr<base::DiscardableMemory> data_;
     bool is_locked_ = false;
     UsageStats usage_stats_;
   };

   // Stores the GPU-side image and supporting fields.
   struct UploadedImageData {
     UploadedImageData();
     ~UploadedImageData();

     void SetImage(sk_sp<SkImage> image);
     const sk_sp<SkImage>& image() const { return image_; }

     void mark_used() { usage_stats_.used = true; }
     void notify_ref_reached_zero() {
       if (++usage_stats_.ref_reached_zero_count == 1)
         usage_stats_.first_ref_wasted = !usage_stats_.used;
     }

     // True if the image is counting against our memory limits.
     bool budgeted = false;
     uint32_t ref_count = 0;
     // If non-null, this is the pending upload task for this image.
     scoped_refptr<TileTask> task;

    private:
     struct UsageStats {
       bool used = false;
       bool first_ref_wasted = false;
       int ref_reached_zero_count = 0;
     };

     void ReportUsageStats() const;

     // May be null if image not yet uploaded / prepared.
     sk_sp<SkImage> image_;
     UsageStats usage_stats_;
   };

   struct ImageData : public base::RefCounted<ImageData> {
     ImageData(DecodedDataMode mode,
               size_t size,
               int upload_scale_mip_level,
               SkFilterQuality upload_scale_filter_quality);

     const DecodedDataMode mode;
     const size_t size;
     bool is_at_raster = false;

     // Variables used to identify/track multiple scale levels of a single image.
     int upload_scale_mip_level = 0;
     SkFilterQuality upload_scale_filter_quality = kNone_SkFilterQuality;
     // If true, this image is no longer in our |persistent_cache_| and will be
     // deleted as soon as its ref count reaches zero.
     bool is_orphaned = false;

     DecodedImageData decode;
     UploadedImageData upload;

    private:
     friend class base::RefCounted<ImageData>;
     ~ImageData();
   };

   // A ref-count and ImageData, used to associate the ImageData with a specific
   // DrawImage in the |in_use_cache_|.
   struct InUseCacheEntry {
     explicit InUseCacheEntry(scoped_refptr<ImageData> image_data);
     InUseCacheEntry(const InUseCacheEntry& other);
     InUseCacheEntry(InUseCacheEntry&& other);
     ~InUseCacheEntry();

     uint32_t ref_count = 0;
     scoped_refptr<ImageData> image_data;
   };

   // Uniquely identifies (without collisions) a specific DrawImage for use in
   // the |in_use_cache_|.
   using InUseCacheKey = uint64_t;

   // All private functions should only be called while holding |lock_|. Some
   // functions also require the |context_| lock. These are indicated by
   // additional comments.

   // Similar to GetTaskForImageAndRef, but gets the dependent decode task
   // rather than the upload task, if necessary.
   scoped_refptr<TileTask> GetImageDecodeTaskAndRef(
       const DrawImage& image,
       const TracingInfo& tracing_info);

   void RefImageDecode(const DrawImage& draw_image);
   void UnrefImageDecode(const DrawImage& draw_image);
   void RefImage(const DrawImage& draw_image);
   void UnrefImageInternal(const DrawImage& draw_image);

   // Called any time the ownership of an object changed. This includes changes
   // to ref-count or to orphaned status.
   void OwnershipChanged(ImageData* image_data);

   // Ensures that the cache can hold an element of |required_size|, freeing
   // unreferenced cache entries if necessary to make room.
   bool EnsureCapacity(size_t required_size);
   bool CanFitSize(size_t size) const;
   bool ExceedsPreferredCount() const;

   void DecodeImageIfNecessary(const DrawImage& draw_image,
                               ImageData* image_data);

   scoped_refptr<GpuImageDecodeController::ImageData> CreateImageData(
       const DrawImage& image);
   SkImageInfo CreateImageInfoForDrawImage(const DrawImage& draw_image,
                                           int upload_scale_mip_level) const;

   // Finds the ImageData that should be used for the given DrawImage. Looks
   // first in the |in_use_cache_|, and then in the |persistent_cache_|.
   ImageData* GetImageDataForDrawImage(const DrawImage& image);

   // Returns true if the given ImageData can be used to draw the specified
   // DrawImage.
   bool IsCompatible(const ImageData* image_data,
                     const DrawImage& draw_image) const;

   // The following two functions also require the |context_| lock to be held.
   void UploadImageIfNecessary(const DrawImage& draw_image,
                               ImageData* image_data);
   void DeletePendingImages();

   const ResourceFormat format_;
   ContextProvider* context_;
   sk_sp<GrContextThreadSafeProxy> context_threadsafe_proxy_;

   // All members below this point must only be accessed while holding |lock_|.
   base::Lock lock_;

   // |persistent_cache_| represents the long-lived cache, keeping a certain
   // budget of ImageDatas alive even when their ref count reaches zero.
   using PersistentCache = base::MRUCache<uint32_t, scoped_refptr<ImageData>>;
   PersistentCache persistent_cache_;

   // |in_use_cache_| represents the in-use (short-lived) cache. Entries are
   // cleaned up as soon as their ref count reaches zero.
   using InUseCache = std::unordered_map<InUseCacheKey, InUseCacheEntry>;
   InUseCache in_use_cache_;

   size_t cached_items_limit_;
   size_t cached_bytes_limit_;
   size_t bytes_used_;
   const size_t max_gpu_image_bytes_;

   // We can't release GPU backed SkImages without holding the context lock,
   // so we add them to this list and defer deletion until the next time the lock
   // is held.
   std::vector<sk_sp<SkImage>> images_pending_deletion_;
 };

 }  // namespace cc

 #endif  // CC_TILES_GPU_IMAGE_DECODE_CONTROLLER_H_
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef CC_TILES_GPU_IMAGE_DECODE_CONTROLLER_H_
	#define CC_TILES_GPU_IMAGE_DECODE_CONTROLLER_H_

	#include <memory>
	#include <unordered_map>
	#include <vector>

	#include "base/containers/mru_cache.h"
	#include "base/memory/discardable_memory.h"
	#include "base/synchronization/lock.h"
	#include "base/trace_event/memory_dump_provider.h"
	#include "cc/base/cc_export.h"
	#include "cc/resources/resource_format.h"
	#include "cc/tiles/image_decode_controller.h"
	#include "third_party/skia/include/core/SkRefCnt.h"

	class SkImageTextureData;

	namespace cc {

	class ContextProvider;

	// OVERVIEW:
	//
	// GpuImageDecodeController handles the decode and upload of images that will
	// be used by Skia's GPU raster path. It also maintains a cache of these
	// decoded/uploaded images for later re-use.
	//
	// Generally, when an image is required for raster, GpuImageDecodeController
	// creates two tasks, one to decode the image, and one to upload the image to
	// the GPU. These tasks are completed before the raster task which depends on
	// the image. We need to seperate decode and upload tasks, as decode can occur
	// simultaneously on multiple threads, while upload requires the GL context
	// lock must happen on our non-concurrent raster thread.
	//
	// Decoded and Uploaded image data share a single cache entry. Depending on how
	// far we've progressed, this cache entry may contain CPU-side decoded data,
	// GPU-side uploaded data, or both. Because CPU-side decoded data is stored in
	// discardable memory, and is only locked for short periods of time (until the
	// upload completes), this memory is not counted against our sized cache
	// limits. Uploaded GPU memory, being non-discardable, always counts against
	// our limits.
	//
	// In cases where the number of images needed exceeds our cache limits, we
	// operate in an "at-raster" mode. In this mode, there are no decode/upload
	// tasks, and images are decoded/uploaded as needed, immediately before being
	// used in raster. Cache entries for at-raster tasks are marked as such, which
	// prevents future tasks from taking a dependency on them and extending their
	// lifetime longer than is necessary.
	//
	// RASTER-SCALE CACHING:
	//
	// In order to save memory, images which are going to be scaled may be uploaded
	// at lower than original resolution. In these cases, we may later need to
	// re-upload the image at a higher resolution. To handle multiple images of
	// different scales being in use at the same time, we have a two-part caching
	// system.
	//
	// The first cache, \|persistent_cache_\|, stores one ImageData per image id.
	// These ImageDatas are not necessarily associated with a given DrawImage, and
	// are saved (persisted) even when their ref-count reaches zero (assuming they
	// fit in the current memory budget). This allows for future re-use of image
	// resources.
	//
	// The second cache, \|in_use_cache_\|, stores one image data per DrawImage -
	// this may be the same ImageData that is in the persistent_cache_. These
	// cache entries are more transient and are deleted as soon as all refs to the
	// given DrawImage are released (the image is no longer in-use).
	//
	// For examples of raster-scale caching, see https://goo.gl/0zCd9Z
	//
	// REF COUNTING:
	//
	// In dealing with the two caches in GpuImageDecodeController, there are three
	// ref-counting concepts in use:
	// 1) ImageData upload/decode ref-counts.
	// These ref-counts represent the overall number of references to the
	// upload or decode portion of an ImageData. These ref-counts control
	// both whether the upload/decode data can be freed, as well as whether an
	// ImageData can be removed from the \|persistent_cache_\|. ImageDatas are
	// only removed from the \|persistent_cache_\| if their upload/decode
	// ref-counts are zero or if they are orphaned and replaced by a new entry.
	// 2) InUseCacheEntry ref-counts.
	// These ref-counts represent the number of references to an
	// InUseCacheEntry from a specific DrawImage. When the InUseCacheEntry's
	// ref-count reaches 0 it will be deleted.
	// 3) scoped_refptr ref-counts.
	// Because both the persistent_cache_ and the in_use_cache_ point at the
	// same ImageDatas (and may need to keep these ImageDatas alive independent
	// of each other), they hold ImageDatas by scoped_refptr. The scoped_refptr
	// keeps an ImageData alive while it is present in either the
	// \|persistent_cache_\| or \|in_use_cache_\|.
	//
	class CC_EXPORT GpuImageDecodeController
	: public ImageDecodeController,
	public base::trace_event::MemoryDumpProvider {
	public:
	explicit GpuImageDecodeController(ContextProvider* context,
	ResourceFormat decode_format,
	size_t max_gpu_image_bytes);
	~GpuImageDecodeController() override;

	// ImageDecodeController overrides.

	// Finds the existing uploaded image for the provided DrawImage. Creates an
	// upload task to upload the image if an exsiting image does not exist.
	bool GetTaskForImageAndRef(const DrawImage& image,
	const TracingInfo& tracing_info,
	scoped_refptr<TileTask>* task) override;
	void UnrefImage(const DrawImage& image) override;
	DecodedDrawImage GetDecodedImageForDraw(const DrawImage& draw_image) override;
	void DrawWithImageFinished(const DrawImage& image,
	const DecodedDrawImage& decoded_image) override;
	void ReduceCacheUsage() override;
	void SetShouldAggressivelyFreeResources(
	bool aggressively_free_resources) override;

	// MemoryDumpProvider overrides.
	bool OnMemoryDump(const base::trace_event::MemoryDumpArgs& args,
	base::trace_event::ProcessMemoryDump* pmd) override;

	// Called by Decode / Upload tasks.
	void DecodeImage(const DrawImage& image);
	void UploadImage(const DrawImage& image);

	// Called by Decode / Upload tasks when tasks are finished.
	void OnImageDecodeTaskCompleted(const DrawImage& image);
	void OnImageUploadTaskCompleted(const DrawImage& image);

	// For testing only.
	void SetCachedItemLimitForTesting(size_t limit) {
	cached_items_limit_ = limit;
	}
	void SetCachedBytesLimitForTesting(size_t limit) {
	cached_bytes_limit_ = limit;
	}
	size_t GetBytesUsedForTesting() const { return bytes_used_; }
	size_t GetDrawImageSizeForTesting(const DrawImage& image);
	void SetImageDecodingFailedForTesting(const DrawImage& image);
	bool DiscardableIsLockedForTesting(const DrawImage& image);

	private:
	enum class DecodedDataMode { GPU, CPU };

	// Stores the CPU-side decoded bits of an image and supporting fields.
	struct DecodedImageData {
	DecodedImageData();
	~DecodedImageData();

	bool is_locked() const { return is_locked_; }
	bool Lock();
	void Unlock();
	void SetLockedData(std::unique_ptr<base::DiscardableMemory> data);
	void ResetData();
	base::DiscardableMemory* data() const { return data_.get(); }
	void mark_used() { usage_stats_.used = true; }

	uint32_t ref_count = 0;
	// Set to true if the image was corrupt and could not be decoded.
	bool decode_failure = false;
	// If non-null, this is the pending decode task for this image.
	scoped_refptr<TileTask> task;

	private:
	struct UsageStats {
	int lock_count = 1;
	bool used = false;
	bool first_lock_wasted = false;
	};

	void ReportUsageStats() const;

	std::unique_ptr<base::DiscardableMemory> data_;
	bool is_locked_ = false;
	UsageStats usage_stats_;
	};

	// Stores the GPU-side image and supporting fields.
	struct UploadedImageData {
	UploadedImageData();
	~UploadedImageData();

	void SetImage(sk_sp<SkImage> image);
	const sk_sp<SkImage>& image() const { return image_; }

	void mark_used() { usage_stats_.used = true; }
	void notify_ref_reached_zero() {
	if (++usage_stats_.ref_reached_zero_count == 1)
	usage_stats_.first_ref_wasted = !usage_stats_.used;
	}

	// True if the image is counting against our memory limits.
	bool budgeted = false;
	uint32_t ref_count = 0;
	// If non-null, this is the pending upload task for this image.
	scoped_refptr<TileTask> task;

	private:
	struct UsageStats {
	bool used = false;
	bool first_ref_wasted = false;
	int ref_reached_zero_count = 0;
	};

	void ReportUsageStats() const;

	// May be null if image not yet uploaded / prepared.
	sk_sp<SkImage> image_;
	UsageStats usage_stats_;
	};

	struct ImageData : public base::RefCounted<ImageData> {
	ImageData(DecodedDataMode mode,
	size_t size,
	int upload_scale_mip_level,
	SkFilterQuality upload_scale_filter_quality);

	const DecodedDataMode mode;
	const size_t size;
	bool is_at_raster = false;

	// Variables used to identify/track multiple scale levels of a single image.
	int upload_scale_mip_level = 0;
	SkFilterQuality upload_scale_filter_quality = kNone_SkFilterQuality;
	// If true, this image is no longer in our \|persistent_cache_\| and will be
	// deleted as soon as its ref count reaches zero.
	bool is_orphaned = false;

	DecodedImageData decode;
	UploadedImageData upload;

	private:
	friend class base::RefCounted<ImageData>;
	~ImageData();
	};

	// A ref-count and ImageData, used to associate the ImageData with a specific
	// DrawImage in the \|in_use_cache_\|.
	struct InUseCacheEntry {
	explicit InUseCacheEntry(scoped_refptr<ImageData> image_data);
	InUseCacheEntry(const InUseCacheEntry& other);
	InUseCacheEntry(InUseCacheEntry&& other);
	~InUseCacheEntry();

	uint32_t ref_count = 0;
	scoped_refptr<ImageData> image_data;
	};

	// Uniquely identifies (without collisions) a specific DrawImage for use in
	// the \|in_use_cache_\|.
	using InUseCacheKey = uint64_t;

	// All private functions should only be called while holding \|lock_\|. Some
	// functions also require the \|context_\| lock. These are indicated by
	// additional comments.

	// Similar to GetTaskForImageAndRef, but gets the dependent decode task
	// rather than the upload task, if necessary.
	scoped_refptr<TileTask> GetImageDecodeTaskAndRef(
	const DrawImage& image,
	const TracingInfo& tracing_info);

	void RefImageDecode(const DrawImage& draw_image);
	void UnrefImageDecode(const DrawImage& draw_image);
	void RefImage(const DrawImage& draw_image);
	void UnrefImageInternal(const DrawImage& draw_image);

	// Called any time the ownership of an object changed. This includes changes
	// to ref-count or to orphaned status.
	void OwnershipChanged(ImageData* image_data);

	// Ensures that the cache can hold an element of \|required_size\|, freeing
	// unreferenced cache entries if necessary to make room.
	bool EnsureCapacity(size_t required_size);
	bool CanFitSize(size_t size) const;
	bool ExceedsPreferredCount() const;

	void DecodeImageIfNecessary(const DrawImage& draw_image,
	ImageData* image_data);

	scoped_refptr<GpuImageDecodeController::ImageData> CreateImageData(
	const DrawImage& image);
	SkImageInfo CreateImageInfoForDrawImage(const DrawImage& draw_image,
	int upload_scale_mip_level) const;

	// Finds the ImageData that should be used for the given DrawImage. Looks
	// first in the \|in_use_cache_\|, and then in the \|persistent_cache_\|.
	ImageData* GetImageDataForDrawImage(const DrawImage& image);

	// Returns true if the given ImageData can be used to draw the specified
	// DrawImage.
	bool IsCompatible(const ImageData* image_data,
	const DrawImage& draw_image) const;

	// The following two functions also require the \|context_\| lock to be held.
	void UploadImageIfNecessary(const DrawImage& draw_image,
	ImageData* image_data);
	void DeletePendingImages();

	const ResourceFormat format_;
	ContextProvider* context_;
	sk_sp<GrContextThreadSafeProxy> context_threadsafe_proxy_;

	// All members below this point must only be accessed while holding \|lock_\|.
	base::Lock lock_;

	// \|persistent_cache_\| represents the long-lived cache, keeping a certain
	// budget of ImageDatas alive even when their ref count reaches zero.
	using PersistentCache = base::MRUCache<uint32_t, scoped_refptr<ImageData>>;
	PersistentCache persistent_cache_;

	// \|in_use_cache_\| represents the in-use (short-lived) cache. Entries are
	// cleaned up as soon as their ref count reaches zero.
	using InUseCache = std::unordered_map<InUseCacheKey, InUseCacheEntry>;
	InUseCache in_use_cache_;

	size_t cached_items_limit_;
	size_t cached_bytes_limit_;
	size_t bytes_used_;
	const size_t max_gpu_image_bytes_;

	// We can't release GPU backed SkImages without holding the context lock,
	// so we add them to this list and defer deletion until the next time the lock
	// is held.
	std::vector<sk_sp<SkImage>> images_pending_deletion_;
	};

	} // namespace cc

	#endif // CC_TILES_GPU_IMAGE_DECODE_CONTROLLER_H_