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Acked-by: Iago Toral Quiroga <itoral@igalia.com> Part-of: <https://gitlab.freedesktop.org/mesa/mesa/-/merge_requests/15472>
306 lines
13 KiB
ReStructuredText
306 lines
13 KiB
ReStructuredText
Dispatch
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=============
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This chapter attemtps to document the Vulkan dispatch infrastructure in the
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Mesa Vulkan runtime. There are a lot of moving pieces here but the end
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result has proven quite effective for implementing all the various Vulkan
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API requirements.
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Extension tables
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----------------
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The Vulkan runtime defines two extension table structures, one for instance
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extensions and one for device extensions which contain a Boolean per
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extension. The device table looks like this:
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.. code-block:: c
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#define VK_DEVICE_EXTENSION_COUNT 238
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struct vk_device_extension_table {
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union {
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bool extensions[VK_DEVICE_EXTENSION_COUNT];
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struct {
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bool KHR_8bit_storage;
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bool KHR_16bit_storage;
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bool KHR_acceleration_structure;
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bool KHR_bind_memory2;
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...
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};
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};
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};
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The instance extension table is similar except that it includes the
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instance level extensions. Both tables are actually unions so that you can
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access the table either by name or as an array. Accessing by name is
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typically better for human-written code which needs to query for specific
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enabled extensions or declare a table of which extensions a driver
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supports. The array form is convenient for more automatic code which wants
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to iterate over the table.
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These tables are are generated automatically using a bit of python code that
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parses the vk.xml from the `Vulkan-Docs repo
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<https://github.com/KhronosGroup/Vulkan-docs/>`_, enumerates the
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extensions, sorts them by instance vs. device and generates the table.
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Generating it from XML means that we never have to manually maintain any of
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these data structures; they get automatically updated when someone imports
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a new version of vk.xml. We also generates a matching pair of tables of
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``VkExtensionProperties``. This makes it easy to implement
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``vkEnumerate*ExtensionProperties()`` with a simple loop that walks a table
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of supported extensions and copies the VkExtensionProperties for each
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enabled entry. Similarly, we can have a loop in ``vkCreateInstance()`` or
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``vkCreateDevice()`` which takes the ``ppEnabledExtensionNames`` and fills
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out the table with all enabled extensions.
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Entrypoint and dispatch tables
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------------------------------
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Entrypoint tables contain a function pointer for every Vulkan entrypoint
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within a particular scope. There are separate tables for instance,
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physical device, and device-level functionality. The device entrypoint
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table looks like this:
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.. code-block:: c
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struct vk_device_entrypoint_table {
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PFN_vkGetDeviceProcAddr GetDeviceProcAddr;
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PFN_vkDestroyDevice DestroyDevice;
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PFN_vkGetDeviceQueue GetDeviceQueue;
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PFN_vkQueueSubmit QueueSubmit;
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...
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#ifdef VK_USE_PLATFORM_WIN32_KHR
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PFN_vkGetSemaphoreWin32HandleKHR GetSemaphoreWin32HandleKHR;
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#else
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PFN_vkVoidFunction GetSemaphoreWin32HandleKHR;
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# endif
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...
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};
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Every entry that requires some sort of platform define is wrapped in an
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``#ifdef`` and declared as the actual function pointer type if the platform
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define is set and declared as a void function otherwise. This ensures that
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the layout of the structure doesn't change based on preprocessor symbols
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but anyone who has the platform defines set gets the real prototype and
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anyone who doesn't can use the table without needing to pull in all the
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platform headers.
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Dispatch tables are similar to entrypoint tables except that they're
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de-duplicated so that aliased entrypoints have only one entry in the table.
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The device dispatch table looks like this:
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.. code-block:: c
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struct vk_device_dispatch_table {
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PFN_vkGetDeviceProcAddr GetDeviceProcAddr;
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PFN_vkDestroyDevice DestroyDevice;
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PFN_vkGetDeviceQueue GetDeviceQueue;
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PFN_vkQueueSubmit QueueSubmit;
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...
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union {
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PFN_vkResetQueryPool ResetQueryPool;
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PFN_vkResetQueryPoolEXT ResetQueryPoolEXT;
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};
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...
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};
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In order to allow code to use any of the aliases for a given entrypoint,
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such entrypoints are wrapped in a union. This is important because we need
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to be able to add new aliases potentially at any Vulkan release and we want
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to do so without having to update all the driver code which uses one of the
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newly aliased entrypoints. We could require that everyone use the first
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name an entrypoint ever has but that gets weird if, for instance, it's
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introduced in an EXT extension and some driver only ever implements the KHR
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or core version of the feature. It's easier for everyone if we make all
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the entrypoint names work.
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An entrypoint table can be converted to a dispatch table by compacting it
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with one of the ``vk_*_dispatch_table_from_entrypoints()`` family of
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functions:
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.. code-block:: c
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void vk_instance_dispatch_table_from_entrypoints(
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struct vk_instance_dispatch_table *dispatch_table,
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const struct vk_instance_entrypoint_table *entrypoint_table,
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bool overwrite);
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void vk_physical_device_dispatch_table_from_entrypoints(
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struct vk_physical_device_dispatch_table *dispatch_table,
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const struct vk_physical_device_entrypoint_table *entrypoint_table,
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bool overwrite);
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void vk_device_dispatch_table_from_entrypoints(
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struct vk_device_dispatch_table *dispatch_table,
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const struct vk_device_entrypoint_table *entrypoint_table,
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bool overwrite);
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Generating driver dispatch tables
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---------------------------------
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Entrypoint tables can be easily auto-generated for your driver. Simply put
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the following in the driver's ``meson.build``, modified as necessary:
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.. code-block::
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drv_entrypoints = custom_target(
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'drv_entrypoints',
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input : [vk_entrypoints_gen, vk_api_xml],
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output : ['drv_entrypoints.h', 'drv_entrypoints.c'],
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command : [
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prog_python, '@INPUT0@', '--xml', '@INPUT1@', '--proto', '--weak',
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'--out-h', '@OUTPUT0@', '--out-c', '@OUTPUT1@', '--prefix', 'drv',
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],
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depend_files : vk_entrypoints_gen_depend_files,
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)
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The generated ``drv_entrypoints.h`` fill will contain prototypes for every
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Vulkan entrypoint, prefixed with what you passed to ``--prefix`` above.
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For instance, if you set ``--prefix drv`` and the entrypoint name is
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``vkCreateDevice()``, the driver entrypoint will be named
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``drv_CreateDevice()``. The ``--prefix`` flag can be specified multiple
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times if you want more than one table. It also generates an entrypoint
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table for each prefix and each dispatch level (instance, physical device,
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and device) which is populated using the driver's functions. Thanks to our
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use of weak function pointers (or something roughly equivalent for MSVC),
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any entrypoints which are not implented will automatically show up as
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``NULL`` entries in the table rather than resulting in linking errors.
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The above generates entrypoint tables because, thanks to aliasing and the C
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rules around const struct declarations, it's not practical to generate a
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dispatch table directly. Before they can be passed into the relevant
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``vk_*_init()`` function, the entrypoint table will have to be converted to
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a dispatch table. The typical pattern for this inside a driver looks
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something like this:
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.. code-block:: c
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struct vk_instance_dispatch_table dispatch_table;
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vk_instance_dispatch_table_from_entrypoints(
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&dispatch_table, &anv_instance_entrypoints, true);
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vk_instance_dispatch_table_from_entrypoints(
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&dispatch_table, &wsi_instance_entrypoints, false);
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result = vk_instance_init(&instance->vk, &instance_extensions,
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&dispatch_table, pCreateInfo, pAllocator);
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if (result != VK_SUCCESS) {
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vk_free(pAllocator, instance);
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return result;
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}
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The ``vk_*_dispatch_table_from_entrypoints()`` functions are designed so
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that they can be layered like this. In this case, it starts with the
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instance entrypoints from the Intel vulkan driver and then adds in the WSI
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entrypoints. If there are any entrypoints duplicated between the two, the
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first one to define the entrypoint wins.
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Common Vulkan entrypoints
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-------------------------
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For the Vulkan runtime itself, there is a dispatch table with the
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``vk_common`` prefix used to provide common implementations of various
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entrypoints. This entrypoint table is added last as part of
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``vk_*_init()`` so that the driver implementation will always be used, if
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there is one.
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This is used to implement a bunch of things on behalf of the driver. The
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most common case is whenever there are ``vkFoo()`` and ``vkFoo2()``
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entrypoints. We provide wrappers for nearly all of these that implement
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``vkFoo()`` in terms of ``vkFoo2()`` so a driver can switch to the new one
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and throw the old one away. For instance, ``vk_common_BindBufferMemory()``
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looks like this:
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.. code-block:: c
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VKAPI_ATTR VkResult VKAPI_CALL
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vk_common_BindBufferMemory(VkDevice _device,
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VkBuffer buffer,
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VkDeviceMemory memory,
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VkDeviceSize memoryOffset)
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{
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VK_FROM_HANDLE(vk_device, device, _device);
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VkBindBufferMemoryInfo bind = {
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.sType = VK_STRUCTURE_TYPE_BIND_BUFFER_MEMORY_INFO,
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.buffer = buffer,
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.memory = memory,
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.memoryOffset = memoryOffset,
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};
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return device->dispatch_table.BindBufferMemory2(_device, 1, &bind);
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}
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There are, of course, far more complicated cases of implementing
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``vkFoo()`` in terms of ``vkFoo2()`` such as the
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``vk_common_QueueSubmit()`` implementation. We also implement far less
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trivial functionality as ``vk_common_*`` entrypoints. For instance, we
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have full implementations of ``VkFence``, ``VkSemaphore``, and
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``vkQueueSubmit2()``.
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Entrypoint lookup
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-----------------
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Implementing ``vkGet*ProcAddr()`` is quite complicated because of the
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Vulkan 1.2 rules around exactly when they have to return ``NULL``. When a
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client calls `vkGet*ProcAddr()`, we go through a three step process resolve
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the function pointer:
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1. A static (generated at compile time) hash table is used to map the
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entrypoint name to an index into the corresponding entry point table.
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2. Optionally, the index is passed to an auto-generated function that
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checks against the enabled core API version and extensions. We use an
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index into the entrypoint table, not the dispatch table, because the
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rules for when an entrypoint should be exposed are per-entrypoint. For
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instance, `vkBindImageMemory2` is available on Vulkan 1.1 and later but
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`vkBindImageMemory2KHR` is available if VK_KHR_bind_memory2 is enabled.
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3. A compaction table is used to map from the entrypoint table index to
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the dispatch table index and the function is finally fetched from the
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dispatch table.
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All of this is encapsulated within the ``vk_*_dispatch_table_get()`` and
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``vk_*_dispatch_table_get_if_supported()`` families of functions. The
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``_if_supported`` versions take a core version and one or more extension
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tables. The driver has to provide ``vk_icdGet*ProcAddr()`` entrypoints
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which wrap these functions because those have to be exposed as actual
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symbols from the ``.so`` or ``.dll`` as part of the loader interface. It
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also has to provide its own ``drv_GetInstanceProcAddr()`` because it needs
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to pass the supported instance extension table to
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:cpp:func:`vk_instance_get_proc_addr`. The runtime will provide
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``vk_common_GetDeviceProcAddr()`` implementations.
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Populating layer or client dispatch tables
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------------------------------------------
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The entrypoint and dispatch tables actually live in ``src/vulkan/util``,
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not ``src/vulkan/runtime`` so they can be used by layers and clients (such
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as Zink) as well as the runtime. Layers and clients may wish to populate
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dispatch tables from an underlying Vulkan implementation. This can be done
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via the ``vk_*_dispatch_table_load()`` family of functions:
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.. code-block:: c
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void
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vk_instance_dispatch_table_load(struct vk_instance_dispatch_table *table,
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PFN_vkGetInstanceProcAddr gpa,
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VkInstance instance);
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void
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vk_physical_device_dispatch_table_load(struct vk_physical_device_dispatch_table *table,
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PFN_vkGetInstanceProcAddr gpa,
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VkInstance instance);
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void
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vk_device_dispatch_table_load(struct vk_device_dispatch_table *table,
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PFN_vkGetDeviceProcAddr gpa,
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VkDevice device);
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These call the given ``vkGet*ProcAddr`` function to populate the dispatch
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table. For aliased entrypoints, it will try each variant in succession to
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ensure that the dispatch table entry gets populated no matter which version
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of the feature you have enabled.
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