gpu/command_buffer/common/shared_image_usage.h - chromium/src - Git at Google

 // Copyright 2018 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef GPU_COMMAND_BUFFER_COMMON_SHARED_IMAGE_USAGE_H_
 #define GPU_COMMAND_BUFFER_COMMON_SHARED_IMAGE_USAGE_H_

 #include <stdint.h>

 #include <initializer_list>
 #include <string>

 #include "gpu/command_buffer/common/gpu_command_buffer_common_export.h"

 namespace gpu {

 // Please update the function, CreateLabelForSharedImageUsage, when adding a new
 // enum value.
 enum SharedImageUsage : uint32_t {
   // Image will be read via GLES2Interface
   SHARED_IMAGE_USAGE_GLES2_READ = 1 << 0,
   // Image will be read via RasterInterface
   SHARED_IMAGE_USAGE_RASTER_READ = 1 << 1,
   // Image will be read from inside Display Compositor
   SHARED_IMAGE_USAGE_DISPLAY_READ = 1 << 2,
   // Image will be written to inside Display Compositor
   SHARED_IMAGE_USAGE_DISPLAY_WRITE = 1 << 3,
   // Image will be used as a scanout buffer (overlay)
   SHARED_IMAGE_USAGE_SCANOUT = 1 << 4,
   // Image will be used in OOP rasterization. This flag is used on top of
   // SHARED_IMAGE_USAGE_RASTER_{READ, WRITE} to indicate that the client will
   // only use RasterInterface for OOP rasterization. TODO(backer): Eliminate
   // once we can CPU raster to SkImage via RasterInterface.
   SHARED_IMAGE_USAGE_OOP_RASTERIZATION = 1 << 5,
   // Image will be read by Dawn (for WebGPU)
   SHARED_IMAGE_USAGE_WEBGPU_READ = 1 << 6,
   // Image may use concurrent read/write access. Used by single buffered canvas.
   // TODO(crbug.com/41462072): This usage is currently not supported in
   // GL/Vulkan
   // interop cases.
   SHARED_IMAGE_USAGE_CONCURRENT_READ_WRITE = 1 << 7,
   // Image will be used for video decode acceleration on Chrome OS.
   SHARED_IMAGE_USAGE_VIDEO_DECODE = 1 << 8,
   // Image will be used as a WebGPU swapbuffer
   SHARED_IMAGE_USAGE_WEBGPU_SWAP_CHAIN_TEXTURE = 1 << 9,
   // The image was created by VideoToolbox on macOS, and is backed by a
   // CVPixelBuffer's IOSurface. Because of this backing, IOSurfaceIsInUse will
   // always return true.
   SHARED_IMAGE_USAGE_MACOS_VIDEO_TOOLBOX = 1 << 10,
   // Image will be used with mipmap enabled.
   SHARED_IMAGE_USAGE_MIPMAP = 1 << 11,
   // Image will be used for CPU Writes by client. Normally write usage also
   // implies read. Hence adding ONLY tag to clarify that its write only in this
   // case.
   SHARED_IMAGE_USAGE_CPU_WRITE_ONLY = 1 << 12,
   // Image will be used in RasterInterface with RawDraw.
   SHARED_IMAGE_USAGE_RAW_DRAW = 1 << 13,
   // Image will be created on the high performance GPU if supported.
   SHARED_IMAGE_USAGE_HIGH_PERFORMANCE_GPU = 1 << 14,
   // Windows only: image will be backed by a DComp surface. A swap chain is
   // preferred when an image is opaque and expected to update frequently and
   // independently of other overlays. This flag is incompatible with
   // DISPLAY_READ and SCANOUT_DXGI_SWAP_CHAIN.
   SHARED_IMAGE_USAGE_SCANOUT_DCOMP_SURFACE = 1 << 15,
   // Windows only: image will be backed by a DXGI swap chain. This flag is
   // incompatible with SCANOUT_DCOMP_SURFACE.
   SHARED_IMAGE_USAGE_SCANOUT_DXGI_SWAP_CHAIN = 1 << 16,

   // Image will be used as a WebGPU storage texture.
   SHARED_IMAGE_USAGE_WEBGPU_STORAGE_TEXTURE = 1 << 17,

   // Image will be written via GLES2Interface
   SHARED_IMAGE_USAGE_GLES2_WRITE = 1 << 18,

   // Image will be written via RasterInterface
   SHARED_IMAGE_USAGE_RASTER_WRITE = 1 << 19,

   // Image will be written by Dawn (for WebGPU)
   SHARED_IMAGE_USAGE_WEBGPU_WRITE = 1 << 20,

   // The image will be used by GLES2 only for raster over the GLES2 interface.
   // Specified in conjunction with GLES2_READ and/or GLES2_WRITE.
   SHARED_IMAGE_USAGE_GLES2_FOR_RASTER_ONLY = 1 << 21,

   // The image will be used by raster only over the GLES2 interface.
   // Specified in conjunction with RASTER_READ and/or RASTER_WRITE.
   SHARED_IMAGE_USAGE_RASTER_OVER_GLES2_ONLY = 1 << 22,

   // Image will contain protected content to be scanned out. Note that this type
   // of image
   // won't necessarily be written to by a hardware video decoder, but will
   // instead be written
   // to by a preprocessing step that converts the image's pixel format into
   // something the
   // display controller understands.
   SHARED_IMAGE_USAGE_PROTECTED_VIDEO = 1 << 23,

   // Image will be used as a WebGPU shared buffer
   SHARED_IMAGE_USAGE_WEBGPU_SHARED_BUFFER = 1 << 24,

   // Image will be used only by the CPU for Read and Writes by the client.
   // Note that this flag is a special case and will be used in cases where
   // clients wants a MappableSharedImage which needs to be mapped in the
   // CPU for read/write but is not importable/texturable in the GPU. Once such
   // use case is CrOs where client CameraBufferFactory uses BufferFormat::R_8
   // to create a MappableSI but that format is non-texturable.
   SHARED_IMAGE_USAGE_CPU_ONLY_READ_WRITE = 1 << 25,

   // Image will be used as a WebNN shared tensor
   SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR = 1 << 26,

   // Image will be used by one copy raster for raster source access.
   SHARED_IMAGE_USAGE_RASTER_COPY_SOURCE = 1 << 27,

   // Image will be used for CPU Reads by client.
   SHARED_IMAGE_USAGE_CPU_READ = 1 << 28,

   // Image will be read by WebNN.
   SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR_READ = 1 << 29,

   // Image will be written by WebNN.
   SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR_WRITE = 1 << 30,

   // Start service side only usage flags after this entry. They must be larger
   // than `LAST_CLIENT_USAGE`.
   LAST_CLIENT_USAGE = SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR_WRITE,

   // Image will have pixels uploaded from CPU. The backing must implement
   // `UploadFromMemory()` if it supports this usage. Clients should specify
   // SHARED_IMAGE_USAGE_CPU_WRITE_ONLY if they need to write pixels to the
   // image.
   SHARED_IMAGE_USAGE_CPU_UPLOAD = 1u << 31,

   LAST_SHARED_IMAGE_USAGE = SHARED_IMAGE_USAGE_CPU_UPLOAD
 };

 class GPU_COMMAND_BUFFER_COMMON_EXPORT SharedImageUsageSet {
  public:
   constexpr SharedImageUsageSet() = default;
   // Permanent nolint to allow for natural conversion from mask to set.
   // NOLINTBEGIN(google-explicit-constructor)
   constexpr SharedImageUsageSet(SharedImageUsage mask) : set_storage_(mask) {}
   // NOLINTEND(google-explicit-constructor)

   // TODO(crbug.com/343347288): Eventually we should deprecate this constructor
   // and replace its usage with a function named something like
   // 'UntypedMaskCast'. This will allow easly track any remaining non typed
   // usage.
   explicit constexpr SharedImageUsageSet(uint32_t mask) : set_storage_(mask) {}

   constexpr SharedImageUsageSet(
       std::initializer_list<SharedImageUsage> usages) {
     for (auto usage : usages) {
       set_storage_ |= usage;
     }
   }

   // Unions with 'set_b' and stores result in self.
   inline constexpr void PutAll(gpu::SharedImageUsageSet set_b) {
     set_storage_ = set_storage_ | static_cast<uint32_t>(set_b);
   }

   // Removes all elements of input set from this set.
   inline constexpr void RemoveAll(gpu::SharedImageUsageSet set_b) {
     uint32_t negation_mask = ~set_b.set_storage_;
     set_storage_ &= negation_mask;
   }

   // Returns true iff our set is empty.
   constexpr bool empty() const { return set_storage_ == 0; }

   // The semantic expectation here is that 'Has' is for set testing of single
   // elements.
   inline constexpr bool Has(gpu::SharedImageUsage set_b) const {
     return (set_storage_ & set_b) == set_b;
   }

   // These function are intentionally deleted. Use the 'Has' function as
   // 'SharedImageUsage' is conceptually not a set.
   inline constexpr bool HasAll(gpu::SharedImageUsage set_b) const = delete;
   inline constexpr bool HasAny(gpu::SharedImageUsage set_b) const = delete;

   // Test set membership via intersection. Returns true if 'set_b' is a subset.
   inline constexpr bool HasAll(gpu::SharedImageUsageSet set_b) const {
     return (set_storage_ & set_b.set_storage_) == set_b.set_storage_;
   }

   // Test set membership via intersection.
   inline constexpr bool HasAny(gpu::SharedImageUsageSet set_b) const {
     return (set_storage_ & set_b.set_storage_) != 0;
   }

   inline constexpr void operator|=(gpu::SharedImageUsageSet mask_b) {
     PutAll(mask_b);
   }

   // Temporary exception to allow for existing, non type safe, conversions.
   // TODO(crbug.com/343347288): Remove after all usage has been converted to
   // `SharedImageUsageSet`.
   // NOLINTBEGIN(google-explicit-constructor)
   inline constexpr operator uint32_t() const { return set_storage_; }
   // NOLINTEND(google-explicit-constructor)

   std::string ToString() const;

  private:
   friend inline constexpr bool operator==(gpu::SharedImageUsageSet set_a,
                                           gpu::SharedImageUsageSet set_b);

   friend inline constexpr gpu::SharedImageUsageSet operator|(
       gpu::SharedImageUsageSet set_a,
       gpu::SharedImageUsage mask_b);
   friend inline constexpr gpu::SharedImageUsageSet operator|(
       gpu::SharedImageUsage mask_a,
       gpu::SharedImageUsageSet set_b);
   friend inline constexpr gpu::SharedImageUsageSet operator|(
       gpu::SharedImageUsage mask_a,
       gpu::SharedImageUsage mask_b);

   friend inline constexpr const SharedImageUsageSet Intersection(
       gpu::SharedImageUsageSet set_a,
       gpu::SharedImageUsageSet set_b);
   uint32_t set_storage_ = 0;
 };

 inline constexpr const SharedImageUsageSet Intersection(
     gpu::SharedImageUsageSet set_a,
     gpu::SharedImageUsageSet set_b) {
   return SharedImageUsageSet(set_a.set_storage_ & set_b.set_storage_);
 }
 // The global operators below cause 'SharedImageUsage' operations to result in
 // 'SharedImageUsageSet' and avoid the ambiguity with uint32_t.
 inline constexpr gpu::SharedImageUsageSet operator|(
     gpu::SharedImageUsageSet set_a,
     gpu::SharedImageUsageSet set_b) {
   set_a.PutAll(set_b);
   return set_a;
 }

 inline constexpr gpu::SharedImageUsageSet operator|(
     gpu::SharedImageUsageSet set_a,
     gpu::SharedImageUsage mask_b) {
   set_a.PutAll(mask_b);
   return set_a;
 }

 inline constexpr gpu::SharedImageUsageSet operator|(
     gpu::SharedImageUsage mask_a,
     gpu::SharedImageUsageSet set_b) {
   // Set union is order independent.
   return set_b | mask_a;
 }

 inline constexpr gpu::SharedImageUsageSet operator|(
     gpu::SharedImageUsage mask_a,
     gpu::SharedImageUsage mask_b) {
   return gpu::SharedImageUsageSet(mask_a) | mask_b;
 }

 inline constexpr bool operator==(gpu::SharedImageUsageSet set_a,
                                  gpu::SharedImageUsageSet set_b) {
   return set_a.set_storage_ == set_b.set_storage_;
 }

 // This is used as the debug_label prefix for all shared images created by
 // importing buffers in Exo. This prefix is checked in the GPU process when
 // reporting if memory for shared images is attributed to exo imports or not.
 GPU_COMMAND_BUFFER_COMMON_EXPORT extern const char kExoTextureLabelPrefix[];

 // Returns true if usage is a valid client usage.
 GPU_COMMAND_BUFFER_COMMON_EXPORT bool IsValidClientUsage(
     SharedImageUsageSet usage);

 // Returns true iff usage includes SHARED_IMAGE_USAGE_GLES2_READ or
 // SHARED_IMAGE_USAGE_GLES2_WRITE.
 GPU_COMMAND_BUFFER_COMMON_EXPORT bool HasGLES2ReadOrWriteUsage(
     SharedImageUsageSet usage);

 // Create a string to label SharedImageUsage.
 GPU_COMMAND_BUFFER_COMMON_EXPORT std::string CreateLabelForSharedImageUsage(
     SharedImageUsageSet usage);

 }  // namespace gpu

 #endif  // GPU_COMMAND_BUFFER_COMMON_SHARED_IMAGE_USAGE_H_
	// Copyright 2018 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef GPU_COMMAND_BUFFER_COMMON_SHARED_IMAGE_USAGE_H_
	#define GPU_COMMAND_BUFFER_COMMON_SHARED_IMAGE_USAGE_H_

	#include <stdint.h>

	#include <initializer_list>
	#include <string>

	#include "gpu/command_buffer/common/gpu_command_buffer_common_export.h"

	namespace gpu {

	// Please update the function, CreateLabelForSharedImageUsage, when adding a new
	// enum value.
	enum SharedImageUsage : uint32_t {
	// Image will be read via GLES2Interface
	SHARED_IMAGE_USAGE_GLES2_READ = 1 << 0,
	// Image will be read via RasterInterface
	SHARED_IMAGE_USAGE_RASTER_READ = 1 << 1,
	// Image will be read from inside Display Compositor
	SHARED_IMAGE_USAGE_DISPLAY_READ = 1 << 2,
	// Image will be written to inside Display Compositor
	SHARED_IMAGE_USAGE_DISPLAY_WRITE = 1 << 3,
	// Image will be used as a scanout buffer (overlay)
	SHARED_IMAGE_USAGE_SCANOUT = 1 << 4,
	// Image will be used in OOP rasterization. This flag is used on top of
	// SHARED_IMAGE_USAGE_RASTER_{READ, WRITE} to indicate that the client will
	// only use RasterInterface for OOP rasterization. TODO(backer): Eliminate
	// once we can CPU raster to SkImage via RasterInterface.
	SHARED_IMAGE_USAGE_OOP_RASTERIZATION = 1 << 5,
	// Image will be read by Dawn (for WebGPU)
	SHARED_IMAGE_USAGE_WEBGPU_READ = 1 << 6,
	// Image may use concurrent read/write access. Used by single buffered canvas.
	// TODO(crbug.com/41462072): This usage is currently not supported in
	// GL/Vulkan
	// interop cases.
	SHARED_IMAGE_USAGE_CONCURRENT_READ_WRITE = 1 << 7,
	// Image will be used for video decode acceleration on Chrome OS.
	SHARED_IMAGE_USAGE_VIDEO_DECODE = 1 << 8,
	// Image will be used as a WebGPU swapbuffer
	SHARED_IMAGE_USAGE_WEBGPU_SWAP_CHAIN_TEXTURE = 1 << 9,
	// The image was created by VideoToolbox on macOS, and is backed by a
	// CVPixelBuffer's IOSurface. Because of this backing, IOSurfaceIsInUse will
	// always return true.
	SHARED_IMAGE_USAGE_MACOS_VIDEO_TOOLBOX = 1 << 10,
	// Image will be used with mipmap enabled.
	SHARED_IMAGE_USAGE_MIPMAP = 1 << 11,
	// Image will be used for CPU Writes by client. Normally write usage also
	// implies read. Hence adding ONLY tag to clarify that its write only in this
	// case.
	SHARED_IMAGE_USAGE_CPU_WRITE_ONLY = 1 << 12,
	// Image will be used in RasterInterface with RawDraw.
	SHARED_IMAGE_USAGE_RAW_DRAW = 1 << 13,
	// Image will be created on the high performance GPU if supported.
	SHARED_IMAGE_USAGE_HIGH_PERFORMANCE_GPU = 1 << 14,
	// Windows only: image will be backed by a DComp surface. A swap chain is
	// preferred when an image is opaque and expected to update frequently and
	// independently of other overlays. This flag is incompatible with
	// DISPLAY_READ and SCANOUT_DXGI_SWAP_CHAIN.
	SHARED_IMAGE_USAGE_SCANOUT_DCOMP_SURFACE = 1 << 15,
	// Windows only: image will be backed by a DXGI swap chain. This flag is
	// incompatible with SCANOUT_DCOMP_SURFACE.
	SHARED_IMAGE_USAGE_SCANOUT_DXGI_SWAP_CHAIN = 1 << 16,

	// Image will be used as a WebGPU storage texture.
	SHARED_IMAGE_USAGE_WEBGPU_STORAGE_TEXTURE = 1 << 17,

	// Image will be written via GLES2Interface
	SHARED_IMAGE_USAGE_GLES2_WRITE = 1 << 18,

	// Image will be written via RasterInterface
	SHARED_IMAGE_USAGE_RASTER_WRITE = 1 << 19,

	// Image will be written by Dawn (for WebGPU)
	SHARED_IMAGE_USAGE_WEBGPU_WRITE = 1 << 20,

	// The image will be used by GLES2 only for raster over the GLES2 interface.
	// Specified in conjunction with GLES2_READ and/or GLES2_WRITE.
	SHARED_IMAGE_USAGE_GLES2_FOR_RASTER_ONLY = 1 << 21,

	// The image will be used by raster only over the GLES2 interface.
	// Specified in conjunction with RASTER_READ and/or RASTER_WRITE.
	SHARED_IMAGE_USAGE_RASTER_OVER_GLES2_ONLY = 1 << 22,

	// Image will contain protected content to be scanned out. Note that this type
	// of image
	// won't necessarily be written to by a hardware video decoder, but will
	// instead be written
	// to by a preprocessing step that converts the image's pixel format into
	// something the
	// display controller understands.
	SHARED_IMAGE_USAGE_PROTECTED_VIDEO = 1 << 23,

	// Image will be used as a WebGPU shared buffer
	SHARED_IMAGE_USAGE_WEBGPU_SHARED_BUFFER = 1 << 24,

	// Image will be used only by the CPU for Read and Writes by the client.
	// Note that this flag is a special case and will be used in cases where
	// clients wants a MappableSharedImage which needs to be mapped in the
	// CPU for read/write but is not importable/texturable in the GPU. Once such
	// use case is CrOs where client CameraBufferFactory uses BufferFormat::R_8
	// to create a MappableSI but that format is non-texturable.
	SHARED_IMAGE_USAGE_CPU_ONLY_READ_WRITE = 1 << 25,

	// Image will be used as a WebNN shared tensor
	SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR = 1 << 26,

	// Image will be used by one copy raster for raster source access.
	SHARED_IMAGE_USAGE_RASTER_COPY_SOURCE = 1 << 27,

	// Image will be used for CPU Reads by client.
	SHARED_IMAGE_USAGE_CPU_READ = 1 << 28,

	// Image will be read by WebNN.
	SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR_READ = 1 << 29,

	// Image will be written by WebNN.
	SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR_WRITE = 1 << 30,

	// Start service side only usage flags after this entry. They must be larger
	// than `LAST_CLIENT_USAGE`.
	LAST_CLIENT_USAGE = SHARED_IMAGE_USAGE_WEBNN_SHARED_TENSOR_WRITE,

	// Image will have pixels uploaded from CPU. The backing must implement
	// `UploadFromMemory()` if it supports this usage. Clients should specify
	// SHARED_IMAGE_USAGE_CPU_WRITE_ONLY if they need to write pixels to the
	// image.
	SHARED_IMAGE_USAGE_CPU_UPLOAD = 1u << 31,

	LAST_SHARED_IMAGE_USAGE = SHARED_IMAGE_USAGE_CPU_UPLOAD
	};

	class GPU_COMMAND_BUFFER_COMMON_EXPORT SharedImageUsageSet {
	public:
	constexpr SharedImageUsageSet() = default;
	// Permanent nolint to allow for natural conversion from mask to set.
	// NOLINTBEGIN(google-explicit-constructor)
	constexpr SharedImageUsageSet(SharedImageUsage mask) : set_storage_(mask) {}
	// NOLINTEND(google-explicit-constructor)

	// TODO(crbug.com/343347288): Eventually we should deprecate this constructor
	// and replace its usage with a function named something like
	// 'UntypedMaskCast'. This will allow easly track any remaining non typed
	// usage.
	explicit constexpr SharedImageUsageSet(uint32_t mask) : set_storage_(mask) {}

	constexpr SharedImageUsageSet(
	std::initializer_list<SharedImageUsage> usages) {
	for (auto usage : usages) {
	set_storage_ \|= usage;
	}
	}

	// Unions with 'set_b' and stores result in self.
	inline constexpr void PutAll(gpu::SharedImageUsageSet set_b) {
	set_storage_ = set_storage_ \| static_cast<uint32_t>(set_b);
	}

	// Removes all elements of input set from this set.
	inline constexpr void RemoveAll(gpu::SharedImageUsageSet set_b) {
	uint32_t negation_mask = ~set_b.set_storage_;
	set_storage_ &= negation_mask;
	}

	// Returns true iff our set is empty.
	constexpr bool empty() const { return set_storage_ == 0; }

	// The semantic expectation here is that 'Has' is for set testing of single
	// elements.
	inline constexpr bool Has(gpu::SharedImageUsage set_b) const {
	return (set_storage_ & set_b) == set_b;
	}

	// These function are intentionally deleted. Use the 'Has' function as
	// 'SharedImageUsage' is conceptually not a set.
	inline constexpr bool HasAll(gpu::SharedImageUsage set_b) const = delete;
	inline constexpr bool HasAny(gpu::SharedImageUsage set_b) const = delete;

	// Test set membership via intersection. Returns true if 'set_b' is a subset.
	inline constexpr bool HasAll(gpu::SharedImageUsageSet set_b) const {
	return (set_storage_ & set_b.set_storage_) == set_b.set_storage_;
	}

	// Test set membership via intersection.
	inline constexpr bool HasAny(gpu::SharedImageUsageSet set_b) const {
	return (set_storage_ & set_b.set_storage_) != 0;
	}

	inline constexpr void operator\|=(gpu::SharedImageUsageSet mask_b) {
	PutAll(mask_b);
	}

	// Temporary exception to allow for existing, non type safe, conversions.
	// TODO(crbug.com/343347288): Remove after all usage has been converted to
	// `SharedImageUsageSet`.
	// NOLINTBEGIN(google-explicit-constructor)
	inline constexpr operator uint32_t() const { return set_storage_; }
	// NOLINTEND(google-explicit-constructor)

	std::string ToString() const;

	private:
	friend inline constexpr bool operator==(gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsageSet set_b);

	friend inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsage mask_b);
	friend inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsage mask_a,
	gpu::SharedImageUsageSet set_b);
	friend inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsage mask_a,
	gpu::SharedImageUsage mask_b);

	friend inline constexpr const SharedImageUsageSet Intersection(
	gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsageSet set_b);
	uint32_t set_storage_ = 0;
	};

	inline constexpr const SharedImageUsageSet Intersection(
	gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsageSet set_b) {
	return SharedImageUsageSet(set_a.set_storage_ & set_b.set_storage_);
	}
	// The global operators below cause 'SharedImageUsage' operations to result in
	// 'SharedImageUsageSet' and avoid the ambiguity with uint32_t.
	inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsageSet set_b) {
	set_a.PutAll(set_b);
	return set_a;
	}

	inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsage mask_b) {
	set_a.PutAll(mask_b);
	return set_a;
	}

	inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsage mask_a,
	gpu::SharedImageUsageSet set_b) {
	// Set union is order independent.
	return set_b \| mask_a;
	}

	inline constexpr gpu::SharedImageUsageSet operator\|(
	gpu::SharedImageUsage mask_a,
	gpu::SharedImageUsage mask_b) {
	return gpu::SharedImageUsageSet(mask_a) \| mask_b;
	}

	inline constexpr bool operator==(gpu::SharedImageUsageSet set_a,
	gpu::SharedImageUsageSet set_b) {
	return set_a.set_storage_ == set_b.set_storage_;
	}

	// This is used as the debug_label prefix for all shared images created by
	// importing buffers in Exo. This prefix is checked in the GPU process when
	// reporting if memory for shared images is attributed to exo imports or not.
	GPU_COMMAND_BUFFER_COMMON_EXPORT extern const char kExoTextureLabelPrefix[];

	// Returns true if usage is a valid client usage.
	GPU_COMMAND_BUFFER_COMMON_EXPORT bool IsValidClientUsage(
	SharedImageUsageSet usage);

	// Returns true iff usage includes SHARED_IMAGE_USAGE_GLES2_READ or
	// SHARED_IMAGE_USAGE_GLES2_WRITE.
	GPU_COMMAND_BUFFER_COMMON_EXPORT bool HasGLES2ReadOrWriteUsage(
	SharedImageUsageSet usage);

	// Create a string to label SharedImageUsage.
	GPU_COMMAND_BUFFER_COMMON_EXPORT std::string CreateLabelForSharedImageUsage(
	SharedImageUsageSet usage);

	} // namespace gpu

	#endif // GPU_COMMAND_BUFFER_COMMON_SHARED_IMAGE_USAGE_H_