/* * Copyright 2018 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef GrVkMemoryAllocator_DEFINED #define GrVkMemoryAllocator_DEFINED #include "SkRefCnt.h" #include "GrTypes.h" #include "GrVkDefines.h" #include "GrVkTypes.h" class GrVkMemoryAllocator : public SkRefCnt { public: enum class AllocationPropertyFlags { kNone = 0, // Allocation will be placed in its own VkDeviceMemory and not suballocated from some larger // block. kDedicatedAllocation = 0x1, // Says that the backing memory can only be accessed by the device. Additionally the device // may lazily allocate the memory. This cannot be used with buffers that will be host // visible. Setting this flag does not guarantee that we will allocate memory that respects // it, but we will try to prefer memory that can respect it. kLazyAllocation = 0x2, // The allocation will be mapped immediately and stay mapped until it is destroyed. This // flag is only valid for buffers which are host visible (i.e. must have a usage other than // BufferUsage::kGpuOnly). kPersistentlyMapped = 0x4, }; GR_DECL_BITFIELD_CLASS_OPS_FRIENDS(AllocationPropertyFlags); enum class BufferUsage { // Buffers that will only be accessed from the device (large const buffers). Will always be // in device local memory. kGpuOnly, // Buffers that will be accessed on the host and copied to and from a GPU resource (transfer // buffers). Will always be mappable and coherent memory. kCpuOnly, // Buffers that typically will be updated multiple times by the host and read on the gpu // (e.g. uniform or vertex buffers). Will always be mappable memory, and will prefer to be // in device local memory. kCpuWritesGpuReads, // Buffers which are typically writted to by the GPU and then read on the host. Will always // be mappable memory, and will prefer coherent and cached memory. kGpuWritesCpuReads, }; virtual bool allocateMemoryForImage(VkImage image, AllocationPropertyFlags flags, GrVkBackendMemory*) = 0; virtual bool allocateMemoryForBuffer(VkBuffer buffer, BufferUsage usage, AllocationPropertyFlags flags, GrVkBackendMemory*) = 0; // Fills out the passed in GrVkAlloc struct for the passed in GrVkBackendMemory. virtual void getAllocInfo(const GrVkBackendMemory&, GrVkAlloc*) const = 0; // Maps the entire allocation and returns a pointer to the start of the allocation. The // implementation may map more memory than just the allocation, but the returned pointer must // point at the start of the memory for the requested allocation. virtual void* mapMemory(const GrVkBackendMemory&) = 0; virtual void unmapMemory(const GrVkBackendMemory&) = 0; // The following two calls are used for managing non-coherent memory. The offset is relative to // the start of the allocation and not the underlying VkDeviceMemory. Additionaly the client // must make sure that the offset + size passed in is less that or equal to the allocation size. // It is the responsibility of the implementation to make sure all alignment requirements are // followed. The client should not have to deal with any sort of alignment issues. virtual void flushMappedMemory(const GrVkBackendMemory&, VkDeviceSize offset, VkDeviceSize size) = 0; virtual void invalidateMappedMemory(const GrVkBackendMemory&, VkDeviceSize offset, VkDeviceSize size)= 0; virtual void freeMemory(const GrVkBackendMemory&) = 0; // Returns the total amount of memory that is allocated and in use by an allocation for this // allocator. virtual uint64_t totalUsedMemory() const = 0; // Returns the total amount of memory that is allocated by this allocator. virtual uint64_t totalAllocatedMemory() const = 0; }; GR_MAKE_BITFIELD_CLASS_OPS(GrVkMemoryAllocator::AllocationPropertyFlags); #endif