Easy to integrate Vulkan memory allocation library
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Vulkan Memory Allocator

Easy to integrate Vulkan memory allocation library.

Documentation: See Vulkan Memory Allocator (generated from Doxygen-style comments in src/vk_mem_alloc.h)

License: MIT. See LICENSE.txt

Changelog: See CHANGELOG.md

Product page: Vulkan Memory Allocator on GPUOpen

Build status:

  • Windows: Build status
  • Linux: Build Status

Problem

Memory allocation and resource (buffer and image) creation in Vulkan is difficult (comparing to older graphics API-s, like D3D11 or OpenGL) for several reasons:

  • It requires a lot of boilerplate code, just like everything else in Vulkan, because it is a low-level and high-performance API.
  • There is additional level of indirection: VkDeviceMemory is allocated separately from creating VkBuffer/VkImage and they must be bound together. The binding cannot be changed later - resource must be recreated.
  • Driver must be queried for supported memory heaps and memory types. Different IHVs provide different types of it.
  • It is recommended practice to allocate bigger chunks of memory and assign parts of them to particular resources.

Features

This library can help game developers to manage memory allocations and resource creation by offering some higher-level functions:

  1. Functions that help to choose correct and optimal memory type based on intended usage of the memory.
    • Required or preferred traits of the memory are expressed using higher-level description comparing to Vulkan flags.
  2. Functions that allocate memory blocks, reserve and return parts of them (VkDeviceMemory + offset + size) to the user.
    • Library keeps track of allocated memory blocks, used and unused ranges inside them, finds best matching unused ranges for new allocations, respects all the rules of alignment and buffer/image granularity.
  3. Functions that can create an image/buffer, allocate memory for it and bind them together - all in one call.

Additional features:

  • Well-documented - description of all functions and structures provided, along with chapters that contain general description and example code.
  • Thread-safety: Library is designed to be used by multithreaded code.
  • Configuration: Fill optional members of CreateInfo structure to provide custom CPU memory allocator, pointers to Vulkan functions and other parameters.
  • Customization: Predefine appropriate macros to provide your own implementation of all external facilities used by the library, from assert, mutex, and atomic, to vector and linked list.
  • Support for memory mapping, reference-counted internally. Support for persistently mapped memory: Just allocate with appropriate flag and you get access to mapped pointer.
  • Custom memory pools: Create a pool with desired parameters (e.g. fixed or limited maximum size) and allocate memory out of it.
  • Support for VK_KHR_dedicated_allocation extension: Just enable it and it will be used automatically by the library.
  • Defragmentation: Call one function and let the library move data around to free some memory blocks and make your allocations better compacted.
  • Lost allocations: Allocate memory with appropriate flags and let the library remove allocations that are not used for many frames to make room for new ones.
  • Statistics: Obtain detailed statistics about the amount of memory used, unused, number of allocated blocks, number of allocations etc. - globally, per memory heap, and per memory type.
  • Debug annotations: Associate string with name or opaque pointer to your own data with every allocation.
  • JSON dump: Obtain a string in JSON format with detailed map of internal state, including list of allocations and gaps between them.

Prequisites

  • Self-contained C++ library in single header file. No external dependencies other than standard C and C++ library and of course Vulkan.
  • Public interface in C, in same convention as Vulkan API. Implementation in C++.
  • Error handling implemented by returning VkResult error codes - same way as in Vulkan.
  • Interface documented using Doxygen-style comments.
  • Platform-independent, but developed and tested on Windows using Visual Studio. Continuous integration setup for Windows and Linux. Tested also on Android and MacOS.

Example

Basic usage of this library is very simple. Advanced features are optional. After you created global VmaAllocator object, a complete code needed to create a buffer may look like this:

VkBufferCreateInfo bufferInfo = { VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO };
bufferInfo.size = 65536;
bufferInfo.usage = VK_BUFFER_USAGE_VERTEX_BUFFER_BIT | VK_BUFFER_USAGE_TRANSFER_DST_BIT;

VmaAllocationCreateInfo allocInfo = {};
allocInfo.usage = VMA_MEMORY_USAGE_GPU_ONLY;

VkBuffer buffer;
VmaAllocation allocation;
vmaCreateBuffer(allocator, &bufferInfo, &allocInfo, &buffer, &allocation, nullptr);

With this one function call:

  1. VkBuffer is created.
  2. VkDeviceMemory block is allocated if needed.
  3. An unused region of the memory block is bound to this buffer.

VmaAllocation is an object that represents memory assigned to this buffer. It can be queried for parameters like Vulkan memory handle and offset.

Read more

See Documentation.

Software using this library

See also

  • Awesome Vulkan - a curated list of awesome Vulkan libraries, debuggers and resources.
  • PyVMA - Python wrapper for this library. Author: Jean-Sébastien B. (@realitix). License: Apache 2.0.
  • vulkan-malloc - Vulkan memory allocation library for Rust. Based on version 1 of this library. Author: Dylan Ede (@dylanede). License: MIT / Apache 2.0.