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Vulkan Validation Overview

Note

The purpose of this section is to give a full overview of how Vulkan deals with valid usage of the API.

Valid Usage (VU)

A VU is explicitly defined in the Vulkan Spec as:

Note

set of conditions that must be met in order to achieve well-defined run-time behavior in an application.

One of the main advantages of Vulkan, as an explicit API, is that the implementation (driver) doesn’t waste time checking for valid input. In OpenGL, the implementation would have to always check for valid usage which added noticeable overhead. There is no glGetError equivalent in Vulkan.

The valid usages will be listed in the spec after every function and structure. For example, if a VUID checks for an invalid VkImage at VkBindImageMemory then the valid usage in the spec is found under VkBindImageMemory. This is because the Validation Layers will only know about all the information at VkBindImageMemory during the execution of the application.

Undefined Behavior

When an application supplies invalid input, according to the valid usages in the spec, the result is undefined behavior. In this state, Vulkan makes no guarantees as anything is possible with undefined behavior.

VERY IMPORTANT: While undefined behavior might seem to work on one implementation, there is a good chance it will fail on another.

Valid Usage ID (VUID)

A VUID is an unique ID given to each valid usage. This allows a way to point to a valid usage in the spec easily.

Using VUID-vkBindImageMemory-memoryOffset-01046 as an example, it is as simple as adding the VUID to an anchor in the HMTL version of the spec (vkspec.html#VUID-vkBindImageMemory-memoryOffset-01046) and it will jump right to the VUID.

Khronos Validation Layer

Since Vulkan doesn’t do any error checking, it is very important, when developing, to enable the Validation Layers right away to help catch invalid behavior. Applications should also never ship the Validation Layers with their application as they noticeably reduce performance and are designed for the development phase.

Note

The Khronos Validation Layer used to consist of multiple layers but now has been unified to a single VK_LAYER_KHRONOS_validition layer. More details explained in LunarG’s whitepaper.

Getting Validation Layers

The Validation Layers are constantly being updated and improved so it is always possible to grab the source and build it yourself. In case you want a prebuilt version there are various options for all supported platforms:

  • Android - Binaries are released on GitHub with most up to date version. The NDK will also comes with the Validation Layers built and information on how to use them.

  • Linux - The Vulkan SDK comes with the Validation Layers built and instructions on how to use them on Linux.

  • MacOS - The Vulkan SDK comes with the Validation Layers built and instructions on how to use them on MacOS.

  • Windows - The Vulkan SDK comes with the Validation Layers built and instructions on how to use them on Windows.

Breaking Down a Validation Error Message

The Validation Layers attempt to supply as much useful information as possible when an error occurs. The following examples are to help show how to get the most information out of the Validation Layers

Example 1 - Implicit Valid Usage

This example shows a case where an implicit VU is triggered. There will not be a number at the end of the VUID.

Validation Error: [ VUID-vkBindBufferMemory-memory-parameter ] Object 0: handle =
0x20c8650, type = VK_OBJECT_TYPE_INSTANCE; | MessageID = 0xe9199965 | Invalid
VkDeviceMemory Object 0x60000000006. The Vulkan spec states: memory must be a valid
VkDeviceMemory handle (https://registry.khronos.org/vulkan/specs/1.1-extensions/
html/vkspec.html#VUID-vkBindBufferMemory-memory-parameter)
  • The first thing to notice is the VUID is listed first in the message (VUID-vkBindBufferMemory-memory-parameter)

    • There is also a link at the end of the message to the VUID in the spec

  • The Vulkan spec states: is the quoted VUID from the spec.

  • The VK_OBJECT_TYPE_INSTANCE is the VkObjectType

  • Invalid VkDeviceMemory Object 0x60000000006 is the Dispatchable Handle to help show which VkDeviceMemory handle was the cause of the error.

Example 2 - Explicit Valid Usage

This example shows an error where some VkImage is trying to be bound to 2 different VkDeviceMemory objects

Validation Error: [ VUID-vkBindImageMemory-image-01044 ] Object 0: handle =
0x90000000009, name = myTextureMemory, type = VK_OBJECT_TYPE_DEVICE_MEMORY; Object 1:
handle = 0x70000000007, type = VK_OBJECT_TYPE_IMAGE; Object 2: handle = 0x90000000006,
name = myIconMemory, type = VK_OBJECT_TYPE_DEVICE_MEMORY; | MessageID = 0x6f3eac96 |
In vkBindImageMemory(), attempting to bind VkDeviceMemory 0x90000000009[myTextureMemory]
to VkImage 0x70000000007[] which has already been bound to VkDeviceMemory
0x90000000006[myIconMemory]. The Vulkan spec states: image must not already be
backed by a memory object (https://registry.khronos.org/vulkan/specs/1.1-extensions/
html/vkspec.html#VUID-vkBindImageMemory-image-01044)
  • Example 2 is about the same as Example 1 with the exception that the name that was attached to the object (name = myTextureMemory). This was done using the VK_EXT_debug_util extension (Sample of how to use the extension). Note that the old way of using VK_EXT_debug_report might be needed on legacy devices that don’t support VK_EXT_debug_util.

  • There were 3 objects involved in causing this error.

    • Object 0 is a VkDeviceMemory named myTextureMemory

    • Object 1 is a VkImage with no name

    • Object 2 is a VkDeviceMemory named myIconMemory

  • With the names it is easy to see “In vkBindImageMemory(), the myTextureMemory memory was attempting to bind to an image already been bound to the myIconMemory memory”.

Each error message contains a uniform logging pattern. This allows information to be easily found in any error. The pattern is as followed:

  • Log status (ex. Error:, Warning:, etc)

  • The VUID

  • Array of objects involved

    • Index of array

    • Dispatch Handle value

    • Optional name

    • Object Type

  • Function or struct error occurred in

  • Message the layer has created to help describe the issue

  • The full Valid Usage from the spec

  • Link to the Valid Usage

Multiple VUIDs

Note

The following is not ideal and is being looked into how to make it simpler

Currently, the spec is designed to only show the VUIDs depending on the version and extensions the spec was built with. Simply put, additions of extensions and versions may alter the VU language enough (from new API items added) that a separate VUID is created.

An example of this from the Vulkan-Docs where the spec in generated from

  * [[VUID-VkPipelineLayoutCreateInfo-pSetLayouts-00287]]
    ...

What this creates is two very similar VUIDs

In this example, both VUIDs are very similar and the only difference is the fact VK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT is referenced in one and not this other. This is because the enum was added with the addition of VK_EXT_descriptor_indexing which is now part of Vulkan 1.2.

This means the 2 valid html links to the spec would look like

  • 1.1/html/vkspec.html#VUID-VkPipelineLayoutCreateInfo-pSetLayouts-00287

  • 1.2/html/vkspec.html#VUID-VkPipelineLayoutCreateInfo-descriptorType-03016

The Validation Layer uses the device properties of the application in order to decide which one to display. So in this case, if you are running on a Vulkan 1.2 implementation or a device that supports VK_EXT_descriptor_indexing it will display the VUID 03016.

Special Usage Tags

The Best Practices layer will produce warnings when an application tries to use any extension with special usage tags. An example of such an extension is VK_EXT_transform_feedback which is only designed for emulation layers. If an application’s intended usage corresponds to one of the special use cases, the following approach will allow you to ignore the warnings.

Ignoring Special Usage Warnings with VK_EXT_debug_report

VkBool32 DebugReportCallbackEXT(/* ... */ const char* pMessage /* ... */)
{
    // If pMessage contains "specialuse-extension", then exit
    if(strstr(pMessage, "specialuse-extension") != NULL) {
        return VK_FALSE;
    }

    // Handle remaining validation messages
}

Ignoring Special Usage Warnings with VK_EXT_debug_utils

VkBool32 DebugUtilsMessengerCallbackEXT(/* ... */ const VkDebugUtilsMessengerCallbackDataEXT* pCallbackData /* ... */)
{
    // If pMessageIdName contains "specialuse-extension", then exit
    if(strstr(pCallbackData->pMessageIdName, "specialuse-extension") != NULL) {
        return VK_FALSE;
    }

    // Handle remaining validation messages
}