src/Vulkan/VkImage.hpp - SwiftShader - Git at Google

 // Copyright 2018 The SwiftShader Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef VK_IMAGE_HPP_
 #define VK_IMAGE_HPP_

 #include "VkFormat.hpp"
 #include "VkObject.hpp"

 #include "marl/mutex.h"

 #ifdef __ANDROID__
 #	include <vulkan/vk_android_native_buffer.h>  // For VkSwapchainImageUsageFlagsANDROID and buffer_handle_t
 #endif

 #include <unordered_set>

 namespace vk {

 class Buffer;
 class Device;
 class DeviceMemory;
 class ImageView;

 #ifdef __ANDROID__
 struct BackingMemory
 {
 	int stride = 0;
 	bool externalMemory = false;
 	buffer_handle_t nativeHandle = nullptr;
 	VkSwapchainImageUsageFlagsANDROID androidUsage = 0;
 };
 #endif

 class Image : public Object<Image, VkImage>
 {
 public:
 	Image(const VkImageCreateInfo *pCreateInfo, void *mem, Device *device);
 	void destroy(const VkAllocationCallbacks *pAllocator);

 #ifdef __ANDROID__
 	VkResult prepareForExternalUseANDROID() const;
 #endif

 	static size_t ComputeRequiredAllocationSize(const VkImageCreateInfo *pCreateInfo);

 	const VkMemoryRequirements getMemoryRequirements() const;
 	size_t getSizeInBytes(const VkImageSubresourceRange &subresourceRange) const;
 	void getSubresourceLayout(const VkImageSubresource *pSubresource, VkSubresourceLayout *pLayout) const;
 	void bind(DeviceMemory *pDeviceMemory, VkDeviceSize pMemoryOffset);
 	void copyTo(Image *dstImage, const VkImageCopy &pRegion) const;
 	void copyTo(Buffer *dstBuffer, const VkBufferImageCopy &region);
 	void copyFrom(Buffer *srcBuffer, const VkBufferImageCopy &region);

 	void blitTo(Image *dstImage, const VkImageBlit &region, VkFilter filter) const;
 	void copyTo(uint8_t *dst, unsigned int dstPitch) const;
 	void resolveTo(Image *dstImage, const VkImageResolve &region) const;
 	void resolveDepthStencilTo(const ImageView *src, ImageView *dst, const VkSubpassDescriptionDepthStencilResolve &depthStencilResolve) const;
 	void clear(const VkClearValue &clearValue, const vk::Format &viewFormat, const VkRect2D &renderArea, const VkImageSubresourceRange &subresourceRange);
 	void clear(const VkClearColorValue &color, const VkImageSubresourceRange &subresourceRange);
 	void clear(const VkClearDepthStencilValue &color, const VkImageSubresourceRange &subresourceRange);

 	// Get the last layer and mipmap level, handling VK_REMAINING_ARRAY_LAYERS and
 	// VK_REMAINING_MIP_LEVELS, respectively. Note VkImageSubresourceLayers does not
 	// allow these symbolic values, so only VkImageSubresourceRange is accepted.
 	uint32_t getLastLayerIndex(const VkImageSubresourceRange &subresourceRange) const;
 	uint32_t getLastMipLevel(const VkImageSubresourceRange &subresourceRange) const;

 	VkImageType getImageType() const { return imageType; }
 	const Format &getFormat() const { return format; }
 	Format getFormat(VkImageAspectFlagBits aspect) const;
 	uint32_t getArrayLayers() const { return arrayLayers; }
 	uint32_t getMipLevels() const { return mipLevels; }
 	VkImageUsageFlags getUsage() const { return usage; }
 	VkImageCreateFlags getFlags() const { return flags; }
 	VkSampleCountFlagBits getSampleCountFlagBits() const { return samples; }
 	const VkExtent3D &getExtent() const { return extent; }
 	VkExtent3D getMipLevelExtent(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	int rowPitchBytes(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	int slicePitchBytes(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	void *getTexelPointer(const VkOffset3D &offset, const VkImageSubresource &subresource) const;
 	bool isCubeCompatible() const;
 	bool is3DSlice() const;
 	uint8_t *end() const;
 	VkDeviceSize getLayerSize(VkImageAspectFlagBits aspect) const;
 	VkDeviceSize getMipLevelSize(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	bool canBindToMemory(DeviceMemory *pDeviceMemory) const;

 	void prepareForSampling(const VkImageSubresourceRange &subresourceRange);
 	enum ContentsChangedContext
 	{
 		DIRECT_MEMORY_ACCESS = 0,
 		USING_STORAGE = 1
 	};
 	void contentsChanged(const VkImageSubresourceRange &subresourceRange, ContentsChangedContext contentsChangedContext = DIRECT_MEMORY_ACCESS);
 	const Image *getSampledImage(const vk::Format &imageViewFormat) const;

 #ifdef __ANDROID__
 	void setBackingMemory(BackingMemory &bm)
 	{
 		backingMemory = bm;
 	}
 	bool hasExternalMemory() const { return backingMemory.externalMemory; }
 	VkDeviceMemory getExternalMemory() const;
 	VkExternalMemoryHandleTypeFlags getSupportedExternalMemoryHandleTypes() const { return supportedExternalMemoryHandleTypes; }
 #endif

 	DeviceMemory *deviceMemory = nullptr;

 private:
 	void copy(Buffer *buffer, const VkBufferImageCopy &region, bool bufferIsSource);
 	VkDeviceSize getStorageSize(VkImageAspectFlags flags) const;
 	VkDeviceSize getMultiSampledLevelSize(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	VkDeviceSize getLayerOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	VkDeviceSize getMemoryOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
 	VkDeviceSize getMemoryOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel, uint32_t layer) const;
 	VkDeviceSize texelOffsetBytesInStorage(const VkOffset3D &offset, const VkImageSubresource &subresource) const;
 	VkDeviceSize getMemoryOffset(VkImageAspectFlagBits aspect) const;
 	VkExtent3D imageExtentInBlocks(const VkExtent3D &extent, VkImageAspectFlagBits aspect) const;
 	VkOffset3D imageOffsetInBlocks(const VkOffset3D &offset, VkImageAspectFlagBits aspect) const;
 	VkExtent2D bufferExtentInBlocks(const VkExtent2D &extent, const VkBufferImageCopy &region) const;
 	VkFormat getClearFormat() const;
 	void clear(void *pixelData, VkFormat pixelFormat, const vk::Format &viewFormat, const VkImageSubresourceRange &subresourceRange, const VkRect2D &renderArea);
 	int borderSize() const;
 	bool requiresPreprocessing() const;
 	void decompress(const VkImageSubresource &subresource);
 	bool updateCube(const VkImageSubresource &subresource);
 	void decodeETC2(const VkImageSubresource &subresource);
 	void decodeBC(const VkImageSubresource &subresource);
 	void decodeASTC(const VkImageSubresource &subresource);

 	const Device *const device = nullptr;
 	VkDeviceSize memoryOffset = 0;
 	VkImageCreateFlags flags = 0;
 	VkImageType imageType = VK_IMAGE_TYPE_2D;
 	Format format;
 	VkExtent3D extent = { 0, 0, 0 };
 	uint32_t mipLevels = 0;
 	uint32_t arrayLayers = 0;
 	VkSampleCountFlagBits samples = VK_SAMPLE_COUNT_1_BIT;
 	VkImageTiling tiling = VK_IMAGE_TILING_OPTIMAL;
 	VkImageUsageFlags usage = (VkImageUsageFlags)0;
 	Image *decompressedImage = nullptr;
 #ifdef __ANDROID__
 	BackingMemory backingMemory = {};
 #endif

 	VkExternalMemoryHandleTypeFlags supportedExternalMemoryHandleTypes = (VkExternalMemoryHandleTypeFlags)0;

 	// VkImageSubresource wrapper for use in unordered_set
 	class Subresource
 	{
 	public:
 		Subresource()
 		    : subresource{ (VkImageAspectFlags)0, 0, 0 }
 		{}
 		Subresource(const VkImageSubresource &subres)
 		    : subresource(subres)
 		{}
 		inline operator VkImageSubresource() const { return subresource; }

 		bool operator==(const Subresource &other) const
 		{
 			return (subresource.aspectMask == other.subresource.aspectMask) &&
 			       (subresource.mipLevel == other.subresource.mipLevel) &&
 			       (subresource.arrayLayer == other.subresource.arrayLayer);
 		};

 		size_t operator()(const Subresource &other) const
 		{
 			return static_cast<size_t>(other.subresource.aspectMask) ^
 			       static_cast<size_t>(other.subresource.mipLevel) ^
 			       static_cast<size_t>(other.subresource.arrayLayer);
 		};

 	private:
 		VkImageSubresource subresource;
 	};

 	marl::mutex mutex;
 	std::unordered_set<Subresource, Subresource> dirtySubresources GUARDED_BY(mutex);
 };

 static inline Image *Cast(VkImage object)
 {
 	return Image::Cast(object);
 }

 }  // namespace vk

 inline bool operator==(const VkExtent3D &lhs, const VkExtent3D &rhs)
 {
 	return lhs.width == rhs.width &&
 	       lhs.height == rhs.height &&
 	       lhs.depth == rhs.depth;
 }

 inline bool operator!=(const VkExtent3D &lhs, const VkExtent3D &rhs)
 {
 	return !(lhs == rhs);
 }

 inline bool operator==(const VkOffset3D &lhs, const VkOffset3D &rhs)
 {
 	return lhs.x == rhs.x &&
 	       lhs.y == rhs.y &&
 	       lhs.z == rhs.z;
 }

 inline bool operator!=(const VkOffset3D &lhs, const VkOffset3D &rhs)
 {
 	return !(lhs == rhs);
 }

 #endif  // VK_IMAGE_HPP_
	// Copyright 2018 The SwiftShader Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef VK_IMAGE_HPP_
	#define VK_IMAGE_HPP_

	#include "VkFormat.hpp"
	#include "VkObject.hpp"

	#include "marl/mutex.h"

	#ifdef __ANDROID__
	# include <vulkan/vk_android_native_buffer.h> // For VkSwapchainImageUsageFlagsANDROID and buffer_handle_t
	#endif

	#include <unordered_set>

	namespace vk {

	class Buffer;
	class Device;
	class DeviceMemory;
	class ImageView;

	#ifdef __ANDROID__
	struct BackingMemory
	{
	int stride = 0;
	bool externalMemory = false;
	buffer_handle_t nativeHandle = nullptr;
	VkSwapchainImageUsageFlagsANDROID androidUsage = 0;
	};
	#endif

	class Image : public Object<Image, VkImage>
	{
	public:
	Image(const VkImageCreateInfo pCreateInfo, void mem, Device *device);
	void destroy(const VkAllocationCallbacks *pAllocator);

	#ifdef __ANDROID__
	VkResult prepareForExternalUseANDROID() const;
	#endif

	static size_t ComputeRequiredAllocationSize(const VkImageCreateInfo *pCreateInfo);

	const VkMemoryRequirements getMemoryRequirements() const;
	size_t getSizeInBytes(const VkImageSubresourceRange &subresourceRange) const;
	void getSubresourceLayout(const VkImageSubresource pSubresource, VkSubresourceLayout pLayout) const;
	void bind(DeviceMemory *pDeviceMemory, VkDeviceSize pMemoryOffset);
	void copyTo(Image *dstImage, const VkImageCopy &pRegion) const;
	void copyTo(Buffer *dstBuffer, const VkBufferImageCopy &region);
	void copyFrom(Buffer *srcBuffer, const VkBufferImageCopy &region);

	void blitTo(Image *dstImage, const VkImageBlit &region, VkFilter filter) const;
	void copyTo(uint8_t *dst, unsigned int dstPitch) const;
	void resolveTo(Image *dstImage, const VkImageResolve &region) const;
	void resolveDepthStencilTo(const ImageView src, ImageView dst, const VkSubpassDescriptionDepthStencilResolve &depthStencilResolve) const;
	void clear(const VkClearValue &clearValue, const vk::Format &viewFormat, const VkRect2D &renderArea, const VkImageSubresourceRange &subresourceRange);
	void clear(const VkClearColorValue &color, const VkImageSubresourceRange &subresourceRange);
	void clear(const VkClearDepthStencilValue &color, const VkImageSubresourceRange &subresourceRange);

	// Get the last layer and mipmap level, handling VK_REMAINING_ARRAY_LAYERS and
	// VK_REMAINING_MIP_LEVELS, respectively. Note VkImageSubresourceLayers does not
	// allow these symbolic values, so only VkImageSubresourceRange is accepted.
	uint32_t getLastLayerIndex(const VkImageSubresourceRange &subresourceRange) const;
	uint32_t getLastMipLevel(const VkImageSubresourceRange &subresourceRange) const;

	VkImageType getImageType() const { return imageType; }
	const Format &getFormat() const { return format; }
	Format getFormat(VkImageAspectFlagBits aspect) const;
	uint32_t getArrayLayers() const { return arrayLayers; }
	uint32_t getMipLevels() const { return mipLevels; }
	VkImageUsageFlags getUsage() const { return usage; }
	VkImageCreateFlags getFlags() const { return flags; }
	VkSampleCountFlagBits getSampleCountFlagBits() const { return samples; }
	const VkExtent3D &getExtent() const { return extent; }
	VkExtent3D getMipLevelExtent(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	int rowPitchBytes(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	int slicePitchBytes(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	void *getTexelPointer(const VkOffset3D &offset, const VkImageSubresource &subresource) const;
	bool isCubeCompatible() const;
	bool is3DSlice() const;
	uint8_t *end() const;
	VkDeviceSize getLayerSize(VkImageAspectFlagBits aspect) const;
	VkDeviceSize getMipLevelSize(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	bool canBindToMemory(DeviceMemory *pDeviceMemory) const;

	void prepareForSampling(const VkImageSubresourceRange &subresourceRange);
	enum ContentsChangedContext
	{
	DIRECT_MEMORY_ACCESS = 0,
	USING_STORAGE = 1
	};
	void contentsChanged(const VkImageSubresourceRange &subresourceRange, ContentsChangedContext contentsChangedContext = DIRECT_MEMORY_ACCESS);
	const Image *getSampledImage(const vk::Format &imageViewFormat) const;

	#ifdef __ANDROID__
	void setBackingMemory(BackingMemory &bm)
	{
	backingMemory = bm;
	}
	bool hasExternalMemory() const { return backingMemory.externalMemory; }
	VkDeviceMemory getExternalMemory() const;
	VkExternalMemoryHandleTypeFlags getSupportedExternalMemoryHandleTypes() const { return supportedExternalMemoryHandleTypes; }
	#endif

	DeviceMemory *deviceMemory = nullptr;

	private:
	void copy(Buffer *buffer, const VkBufferImageCopy &region, bool bufferIsSource);
	VkDeviceSize getStorageSize(VkImageAspectFlags flags) const;
	VkDeviceSize getMultiSampledLevelSize(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	VkDeviceSize getLayerOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	VkDeviceSize getMemoryOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel) const;
	VkDeviceSize getMemoryOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel, uint32_t layer) const;
	VkDeviceSize texelOffsetBytesInStorage(const VkOffset3D &offset, const VkImageSubresource &subresource) const;
	VkDeviceSize getMemoryOffset(VkImageAspectFlagBits aspect) const;
	VkExtent3D imageExtentInBlocks(const VkExtent3D &extent, VkImageAspectFlagBits aspect) const;
	VkOffset3D imageOffsetInBlocks(const VkOffset3D &offset, VkImageAspectFlagBits aspect) const;
	VkExtent2D bufferExtentInBlocks(const VkExtent2D &extent, const VkBufferImageCopy &region) const;
	VkFormat getClearFormat() const;
	void clear(void *pixelData, VkFormat pixelFormat, const vk::Format &viewFormat, const VkImageSubresourceRange &subresourceRange, const VkRect2D &renderArea);
	int borderSize() const;
	bool requiresPreprocessing() const;
	void decompress(const VkImageSubresource &subresource);
	bool updateCube(const VkImageSubresource &subresource);
	void decodeETC2(const VkImageSubresource &subresource);
	void decodeBC(const VkImageSubresource &subresource);
	void decodeASTC(const VkImageSubresource &subresource);

	const Device *const device = nullptr;
	VkDeviceSize memoryOffset = 0;
	VkImageCreateFlags flags = 0;
	VkImageType imageType = VK_IMAGE_TYPE_2D;
	Format format;
	VkExtent3D extent = { 0, 0, 0 };
	uint32_t mipLevels = 0;
	uint32_t arrayLayers = 0;
	VkSampleCountFlagBits samples = VK_SAMPLE_COUNT_1_BIT;
	VkImageTiling tiling = VK_IMAGE_TILING_OPTIMAL;
	VkImageUsageFlags usage = (VkImageUsageFlags)0;
	Image *decompressedImage = nullptr;
	#ifdef __ANDROID__
	BackingMemory backingMemory = {};
	#endif

	VkExternalMemoryHandleTypeFlags supportedExternalMemoryHandleTypes = (VkExternalMemoryHandleTypeFlags)0;

	// VkImageSubresource wrapper for use in unordered_set
	class Subresource
	{
	public:
	Subresource()
	: subresource{ (VkImageAspectFlags)0, 0, 0 }
	{}
	Subresource(const VkImageSubresource &subres)
	: subresource(subres)
	{}
	inline operator VkImageSubresource() const { return subresource; }

	bool operator==(const Subresource &other) const
	{
	return (subresource.aspectMask == other.subresource.aspectMask) &&
	(subresource.mipLevel == other.subresource.mipLevel) &&
	(subresource.arrayLayer == other.subresource.arrayLayer);
	};

	size_t operator()(const Subresource &other) const
	{
	return static_cast<size_t>(other.subresource.aspectMask) ^
	static_cast<size_t>(other.subresource.mipLevel) ^
	static_cast<size_t>(other.subresource.arrayLayer);
	};

	private:
	VkImageSubresource subresource;
	};

	marl::mutex mutex;
	std::unordered_set<Subresource, Subresource> dirtySubresources GUARDED_BY(mutex);
	};

	static inline Image *Cast(VkImage object)
	{
	return Image::Cast(object);
	}

	} // namespace vk

	inline bool operator==(const VkExtent3D &lhs, const VkExtent3D &rhs)
	{
	return lhs.width == rhs.width &&
	lhs.height == rhs.height &&
	lhs.depth == rhs.depth;
	}

	inline bool operator!=(const VkExtent3D &lhs, const VkExtent3D &rhs)
	{
	return !(lhs == rhs);
	}

	inline bool operator==(const VkOffset3D &lhs, const VkOffset3D &rhs)
	{
	return lhs.x == rhs.x &&
	lhs.y == rhs.y &&
	lhs.z == rhs.z;
	}

	inline bool operator!=(const VkOffset3D &lhs, const VkOffset3D &rhs)
	{
	return !(lhs == rhs);
	}

	#endif // VK_IMAGE_HPP_