5. Devices and Queues
Once Vulkan is initialized, devices and queues are the primary objects used to interact with a Vulkan implementation.
Vulkan separates the concept of physical and logical devices. A physical device usually represents a single complete implementation of Vulkan (excluding instance-level functionality) available to the host, of which there are a finite number. A logical device represents an instance of that implementation with its own state and resources independent of other logical devices.
Physical devices are represented by VkPhysicalDevice
handles:
// Provided by VK_VERSION_1_0
VK_DEFINE_HANDLE(VkPhysicalDevice)
5.1. Physical Devices
To retrieve a list of physical device objects representing the physical devices installed in the system, call:
// Provided by VK_VERSION_1_0
VkResult vkEnumeratePhysicalDevices(
VkInstance instance,
uint32_t* pPhysicalDeviceCount,
VkPhysicalDevice* pPhysicalDevices);
-
instance
is a handle to a Vulkan instance previously created with vkCreateInstance. -
pPhysicalDeviceCount
is a pointer to an integer related to the number of physical devices available or queried, as described below. -
pPhysicalDevices
is eitherNULL
or a pointer to an array ofVkPhysicalDevice
handles.
If pPhysicalDevices
is NULL
, then the number of physical devices
available is returned in pPhysicalDeviceCount
.
Otherwise, pPhysicalDeviceCount
must point to a variable set by the
user to the number of elements in the pPhysicalDevices
array, and on
return the variable is overwritten with the number of handles actually
written to pPhysicalDevices
.
If pPhysicalDeviceCount
is less than the number of physical devices
available, at most pPhysicalDeviceCount
structures will be written,
and VK_INCOMPLETE
will be returned instead of VK_SUCCESS
, to
indicate that not all the available physical devices were returned.
To query general properties of physical devices once enumerated, call:
// Provided by VK_VERSION_1_0
void vkGetPhysicalDeviceProperties(
VkPhysicalDevice physicalDevice,
VkPhysicalDeviceProperties* pProperties);
-
physicalDevice
is the handle to the physical device whose properties will be queried. -
pProperties
is a pointer to a VkPhysicalDeviceProperties structure in which properties are returned.
The VkPhysicalDeviceProperties
structure is defined as:
// Provided by VK_VERSION_1_0
typedef struct VkPhysicalDeviceProperties {
uint32_t apiVersion;
uint32_t driverVersion;
uint32_t vendorID;
uint32_t deviceID;
VkPhysicalDeviceType deviceType;
char deviceName[VK_MAX_PHYSICAL_DEVICE_NAME_SIZE];
uint8_t pipelineCacheUUID[VK_UUID_SIZE];
VkPhysicalDeviceLimits limits;
VkPhysicalDeviceSparseProperties sparseProperties;
} VkPhysicalDeviceProperties;
-
apiVersion
is the version of Vulkan supported by the device, encoded as described in Version Numbers. -
driverVersion
is the vendor-specified version of the driver. -
vendorID
is a unique identifier for the vendor (see below) of the physical device. -
deviceID
is a unique identifier for the physical device among devices available from the vendor. -
deviceType
is a VkPhysicalDeviceType specifying the type of device. -
deviceName
is an array ofVK_MAX_PHYSICAL_DEVICE_NAME_SIZE
char
containing a null-terminated UTF-8 string which is the name of the device. -
pipelineCacheUUID
is an array ofVK_UUID_SIZE
uint8_t
values representing a universally unique identifier for the device. -
limits
is the VkPhysicalDeviceLimits structure specifying device-specific limits of the physical device. See Limits for details. -
sparseProperties
is the VkPhysicalDeviceSparseProperties structure specifying various sparse related properties of the physical device. See Sparse Properties for details.
Note
The value of |
Note
The encoding of |
On implementations that claim support for the Roadmap 2022
profile, the major and minor version expressed by apiVersion
must be
at least Vulkan 1.3.
The vendorID
and deviceID
fields are provided to allow
applications to adapt to device characteristics that are not adequately
exposed by other Vulkan queries.
Note
These may include performance profiles, hardware errata, or other characteristics. |
The vendor identified by vendorID
is the entity responsible for the
most salient characteristics of the underlying implementation of the
VkPhysicalDevice being queried.
Note
For example, in the case of a discrete GPU implementation, this should be the GPU chipset vendor. In the case of a hardware accelerator integrated into a system-on-chip (SoC), this should be the supplier of the silicon IP used to create the accelerator. |
If the vendor has a PCI
vendor ID, the low 16 bits of vendorID
must contain that PCI vendor
ID, and the remaining bits must be set to zero.
Otherwise, the value returned must be a valid Khronos vendor ID, obtained
as described in the Vulkan Documentation and Extensions:
Procedures and Conventions document in the section “Registering a Vendor
ID with Khronos”.
Khronos vendor IDs are allocated starting at 0x10000, to distinguish them
from the PCI vendor ID namespace.
Khronos vendor IDs are symbolically defined in the VkVendorId type.
The vendor is also responsible for the value returned in deviceID
.
If the implementation is driven primarily by a PCI
device with a PCI device ID, the low 16 bits of
deviceID
must contain that PCI device ID, and the remaining bits
must be set to zero.
Otherwise, the choice of what values to return may be dictated by operating
system or platform policies - but should uniquely identify both the device
version and any major configuration options (for example, core count in the
case of multicore devices).
Note
The same device ID should be used for all physical implementations of that device version and configuration. For example, all uses of a specific silicon IP GPU version and configuration should use the same device ID, even if those uses occur in different SoCs. |
Khronos vendor IDs which may be returned in
VkPhysicalDeviceProperties::vendorID
are:
// Provided by VK_VERSION_1_0
typedef enum VkVendorId {
VK_VENDOR_ID_VIV = 0x10001,
VK_VENDOR_ID_VSI = 0x10002,
VK_VENDOR_ID_KAZAN = 0x10003,
VK_VENDOR_ID_CODEPLAY = 0x10004,
VK_VENDOR_ID_MESA = 0x10005,
VK_VENDOR_ID_POCL = 0x10006,
VK_VENDOR_ID_MOBILEYE = 0x10007,
} VkVendorId;
Note
Khronos vendor IDs may be allocated by vendors at any time.
Only the latest canonical versions of this Specification, of the
corresponding Only Khronos vendor IDs are given symbolic names at present. PCI vendor IDs returned by the implementation can be looked up in the PCI-SIG database. |
VK_MAX_PHYSICAL_DEVICE_NAME_SIZE
is the length in char
values of
an array containing a physical device name string, as returned in
VkPhysicalDeviceProperties::deviceName
.
#define VK_MAX_PHYSICAL_DEVICE_NAME_SIZE 256U
The physical device types which may be returned in
VkPhysicalDeviceProperties::deviceType
are:
// Provided by VK_VERSION_1_0
typedef enum VkPhysicalDeviceType {
VK_PHYSICAL_DEVICE_TYPE_OTHER = 0,
VK_PHYSICAL_DEVICE_TYPE_INTEGRATED_GPU = 1,
VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU = 2,
VK_PHYSICAL_DEVICE_TYPE_VIRTUAL_GPU = 3,
VK_PHYSICAL_DEVICE_TYPE_CPU = 4,
} VkPhysicalDeviceType;
-
VK_PHYSICAL_DEVICE_TYPE_OTHER
- the device does not match any other available types. -
VK_PHYSICAL_DEVICE_TYPE_INTEGRATED_GPU
- the device is typically one embedded in or tightly coupled with the host. -
VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU
- the device is typically a separate processor connected to the host via an interlink. -
VK_PHYSICAL_DEVICE_TYPE_VIRTUAL_GPU
- the device is typically a virtual node in a virtualization environment. -
VK_PHYSICAL_DEVICE_TYPE_CPU
- the device is typically running on the same processors as the host.
The physical device type is advertised for informational purposes only, and does not directly affect the operation of the system. However, the device type may correlate with other advertised properties or capabilities of the system, such as how many memory heaps there are.
To query general properties of physical devices once enumerated, call:
// Provided by VK_VERSION_1_1
void vkGetPhysicalDeviceProperties2(
VkPhysicalDevice physicalDevice,
VkPhysicalDeviceProperties2* pProperties);
or the equivalent command
// Provided by VK_KHR_get_physical_device_properties2
void vkGetPhysicalDeviceProperties2KHR(
VkPhysicalDevice physicalDevice,
VkPhysicalDeviceProperties2* pProperties);
-
physicalDevice
is the handle to the physical device whose properties will be queried. -
pProperties
is a pointer to a VkPhysicalDeviceProperties2 structure in which properties are returned.
Each structure in pProperties
and its pNext
chain contains
members corresponding to implementation-dependent properties, behaviors, or
limits.
vkGetPhysicalDeviceProperties2
fills in each member to specify the
corresponding value for the implementation.
The VkPhysicalDeviceProperties2
structure is defined as:
// Provided by VK_VERSION_1_1
typedef struct VkPhysicalDeviceProperties2 {
VkStructureType sType;
void* pNext;
VkPhysicalDeviceProperties properties;
} VkPhysicalDeviceProperties2;
or the equivalent
// Provided by VK_KHR_get_physical_device_properties2
typedef VkPhysicalDeviceProperties2 VkPhysicalDeviceProperties2KHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
properties
is a VkPhysicalDeviceProperties structure describing properties of the physical device. This structure is written with the same values as if it were written by vkGetPhysicalDeviceProperties.
The pNext
chain of this structure is used to extend the structure with
properties defined by extensions.
The VkPhysicalDeviceVulkan11Properties
structure is defined as:
// Provided by VK_VERSION_1_2
typedef struct VkPhysicalDeviceVulkan11Properties {
VkStructureType sType;
void* pNext;
uint8_t deviceUUID[VK_UUID_SIZE];
uint8_t driverUUID[VK_UUID_SIZE];
uint8_t deviceLUID[VK_LUID_SIZE];
uint32_t deviceNodeMask;
VkBool32 deviceLUIDValid;
uint32_t subgroupSize;
VkShaderStageFlags subgroupSupportedStages;
VkSubgroupFeatureFlags subgroupSupportedOperations;
VkBool32 subgroupQuadOperationsInAllStages;
VkPointClippingBehavior pointClippingBehavior;
uint32_t maxMultiviewViewCount;
uint32_t maxMultiviewInstanceIndex;
VkBool32 protectedNoFault;
uint32_t maxPerSetDescriptors;
VkDeviceSize maxMemoryAllocationSize;
} VkPhysicalDeviceVulkan11Properties;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure.
-
deviceUUID
is an array ofVK_UUID_SIZE
uint8_t
values representing a universally unique identifier for the device. -
driverUUID
is an array ofVK_UUID_SIZE
uint8_t
values representing a universally unique identifier for the driver build in use by the device. -
deviceLUID
is an array ofVK_LUID_SIZE
uint8_t
values representing a locally unique identifier for the device. -
deviceNodeMask
is auint32_t
bitfield identifying the node within a linked device adapter corresponding to the device. -
deviceLUIDValid
is a boolean value that will beVK_TRUE
ifdeviceLUID
contains a valid LUID anddeviceNodeMask
contains a valid node mask, andVK_FALSE
if they do not. -
subgroupSize
is the default number of invocations in each subgroup.subgroupSize
is at least 1 if any of the physical device’s queues supportVK_QUEUE_GRAPHICS_BIT
orVK_QUEUE_COMPUTE_BIT
.subgroupSize
is a power-of-two. -
subgroupSupportedStages
is a bitfield of VkShaderStageFlagBits describing the shader stages that group operations with subgroup scope are supported in.subgroupSupportedStages
will have theVK_SHADER_STAGE_COMPUTE_BIT
bit set if any of the physical device’s queues supportVK_QUEUE_COMPUTE_BIT
. -
subgroupSupportedOperations
is a bitmask of VkSubgroupFeatureFlagBits specifying the sets of group operations with subgroup scope supported on this device.subgroupSupportedOperations
will have theVK_SUBGROUP_FEATURE_BASIC_BIT
bit set if any of the physical device’s queues supportVK_QUEUE_GRAPHICS_BIT
orVK_QUEUE_COMPUTE_BIT
. -
subgroupQuadOperationsInAllStages
is a boolean specifying whether quad group operations are available in all stages, or are restricted to fragment and compute stages. -
pointClippingBehavior
is a VkPointClippingBehavior value specifying the point clipping behavior supported by the implementation. -
maxMultiviewViewCount
is one greater than the maximum view index that can be used in a subpass. -
maxMultiviewInstanceIndex
is the maximum valid value of instance index allowed to be generated by a drawing command recorded within a subpass of a multiview render pass instance. -
protectedNoFault
specifies how an implementation behaves when an application attempts to write to unprotected memory in a protected queue operation, read from protected memory in an unprotected queue operation, or perform a query in a protected queue operation. If this limit isVK_TRUE
, such writes will be discarded or have undefined values written, reads and queries will return undefined values. If this limit isVK_FALSE
, applications must not perform these operations. See Protected Memory Access Rules for more information. -
maxPerSetDescriptors
is a maximum number of descriptors (summed over all descriptor types) in a single descriptor set that is guaranteed to satisfy any implementation-dependent constraints on the size of a descriptor set itself. Applications can query whether a descriptor set that goes beyond this limit is supported using vkGetDescriptorSetLayoutSupport. -
maxMemoryAllocationSize
is the maximum size of a memory allocation that can be created, even if there is more space available in the heap.
If the VkPhysicalDeviceVulkan11Properties
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These properties correspond to Vulkan 1.1 functionality.
The members of VkPhysicalDeviceVulkan11Properties
have the same values
as the corresponding members of VkPhysicalDeviceIDProperties,
VkPhysicalDeviceSubgroupProperties,
VkPhysicalDevicePointClippingProperties,
VkPhysicalDeviceMultiviewProperties,
VkPhysicalDeviceProtectedMemoryProperties, and
VkPhysicalDeviceMaintenance3Properties.
The VkPhysicalDeviceVulkan12Properties
structure is defined as:
// Provided by VK_VERSION_1_2
typedef struct VkPhysicalDeviceVulkan12Properties {
VkStructureType sType;
void* pNext;
VkDriverId driverID;
char driverName[VK_MAX_DRIVER_NAME_SIZE];
char driverInfo[VK_MAX_DRIVER_INFO_SIZE];
VkConformanceVersion conformanceVersion;
VkShaderFloatControlsIndependence denormBehaviorIndependence;
VkShaderFloatControlsIndependence roundingModeIndependence;
VkBool32 shaderSignedZeroInfNanPreserveFloat16;
VkBool32 shaderSignedZeroInfNanPreserveFloat32;
VkBool32 shaderSignedZeroInfNanPreserveFloat64;
VkBool32 shaderDenormPreserveFloat16;
VkBool32 shaderDenormPreserveFloat32;
VkBool32 shaderDenormPreserveFloat64;
VkBool32 shaderDenormFlushToZeroFloat16;
VkBool32 shaderDenormFlushToZeroFloat32;
VkBool32 shaderDenormFlushToZeroFloat64;
VkBool32 shaderRoundingModeRTEFloat16;
VkBool32 shaderRoundingModeRTEFloat32;
VkBool32 shaderRoundingModeRTEFloat64;
VkBool32 shaderRoundingModeRTZFloat16;
VkBool32 shaderRoundingModeRTZFloat32;
VkBool32 shaderRoundingModeRTZFloat64;
uint32_t maxUpdateAfterBindDescriptorsInAllPools;
VkBool32 shaderUniformBufferArrayNonUniformIndexingNative;
VkBool32 shaderSampledImageArrayNonUniformIndexingNative;
VkBool32 shaderStorageBufferArrayNonUniformIndexingNative;
VkBool32 shaderStorageImageArrayNonUniformIndexingNative;
VkBool32 shaderInputAttachmentArrayNonUniformIndexingNative;
VkBool32 robustBufferAccessUpdateAfterBind;
VkBool32 quadDivergentImplicitLod;
uint32_t maxPerStageDescriptorUpdateAfterBindSamplers;
uint32_t maxPerStageDescriptorUpdateAfterBindUniformBuffers;
uint32_t maxPerStageDescriptorUpdateAfterBindStorageBuffers;
uint32_t maxPerStageDescriptorUpdateAfterBindSampledImages;
uint32_t maxPerStageDescriptorUpdateAfterBindStorageImages;
uint32_t maxPerStageDescriptorUpdateAfterBindInputAttachments;
uint32_t maxPerStageUpdateAfterBindResources;
uint32_t maxDescriptorSetUpdateAfterBindSamplers;
uint32_t maxDescriptorSetUpdateAfterBindUniformBuffers;
uint32_t maxDescriptorSetUpdateAfterBindUniformBuffersDynamic;
uint32_t maxDescriptorSetUpdateAfterBindStorageBuffers;
uint32_t maxDescriptorSetUpdateAfterBindStorageBuffersDynamic;
uint32_t maxDescriptorSetUpdateAfterBindSampledImages;
uint32_t maxDescriptorSetUpdateAfterBindStorageImages;
uint32_t maxDescriptorSetUpdateAfterBindInputAttachments;
VkResolveModeFlags supportedDepthResolveModes;
VkResolveModeFlags supportedStencilResolveModes;
VkBool32 independentResolveNone;
VkBool32 independentResolve;
VkBool32 filterMinmaxSingleComponentFormats;
VkBool32 filterMinmaxImageComponentMapping;
uint64_t maxTimelineSemaphoreValueDifference;
VkSampleCountFlags framebufferIntegerColorSampleCounts;
} VkPhysicalDeviceVulkan12Properties;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure.
-
driverID
is a unique identifier for the driver of the physical device. -
driverName
is an array ofVK_MAX_DRIVER_NAME_SIZE
char
containing a null-terminated UTF-8 string which is the name of the driver. -
driverInfo
is an array ofVK_MAX_DRIVER_INFO_SIZE
char
containing a null-terminated UTF-8 string with additional information about the driver. -
conformanceVersion
is the version of the Vulkan conformance test this driver is conformant against (see VkConformanceVersion). -
denormBehaviorIndependence
is a VkShaderFloatControlsIndependence value indicating whether, and how, denorm behavior can be set independently for different bit widths. -
roundingModeIndependence
is a VkShaderFloatControlsIndependence value indicating whether, and how, rounding modes can be set independently for different bit widths. -
shaderSignedZeroInfNanPreserveFloat16
is a boolean value indicating whether sign of a zero, Nans and can be preserved in 16-bit floating-point computations. It also indicates whether theSignedZeroInfNanPreserve
execution mode can be used for 16-bit floating-point types. -
shaderSignedZeroInfNanPreserveFloat32
is a boolean value indicating whether sign of a zero, Nans and can be preserved in 32-bit floating-point computations. It also indicates whether theSignedZeroInfNanPreserve
execution mode can be used for 32-bit floating-point types. -
shaderSignedZeroInfNanPreserveFloat64
is a boolean value indicating whether sign of a zero, Nans and can be preserved in 64-bit floating-point computations. It also indicates whether theSignedZeroInfNanPreserve
execution mode can be used for 64-bit floating-point types. -
shaderDenormPreserveFloat16
is a boolean value indicating whether denormals can be preserved in 16-bit floating-point computations. It also indicates whether theDenormPreserve
execution mode can be used for 16-bit floating-point types. -
shaderDenormPreserveFloat32
is a boolean value indicating whether denormals can be preserved in 32-bit floating-point computations. It also indicates whether theDenormPreserve
execution mode can be used for 32-bit floating-point types. -
shaderDenormPreserveFloat64
is a boolean value indicating whether denormals can be preserved in 64-bit floating-point computations. It also indicates whether theDenormPreserve
execution mode can be used for 64-bit floating-point types. -
shaderDenormFlushToZeroFloat16
is a boolean value indicating whether denormals can be flushed to zero in 16-bit floating-point computations. It also indicates whether theDenormFlushToZero
execution mode can be used for 16-bit floating-point types. -
shaderDenormFlushToZeroFloat32
is a boolean value indicating whether denormals can be flushed to zero in 32-bit floating-point computations. It also indicates whether theDenormFlushToZero
execution mode can be used for 32-bit floating-point types. -
shaderDenormFlushToZeroFloat64
is a boolean value indicating whether denormals can be flushed to zero in 64-bit floating-point computations. It also indicates whether theDenormFlushToZero
execution mode can be used for 64-bit floating-point types. -
shaderRoundingModeRTEFloat16
is a boolean value indicating whether an implementation supports the round-to-nearest-even rounding mode for 16-bit floating-point arithmetic and conversion instructions. It also indicates whether theRoundingModeRTE
execution mode can be used for 16-bit floating-point types. -
shaderRoundingModeRTEFloat32
is a boolean value indicating whether an implementation supports the round-to-nearest-even rounding mode for 32-bit floating-point arithmetic and conversion instructions. It also indicates whether theRoundingModeRTE
execution mode can be used for 32-bit floating-point types. -
shaderRoundingModeRTEFloat64
is a boolean value indicating whether an implementation supports the round-to-nearest-even rounding mode for 64-bit floating-point arithmetic and conversion instructions. It also indicates whether theRoundingModeRTE
execution mode can be used for 64-bit floating-point types. -
shaderRoundingModeRTZFloat16
is a boolean value indicating whether an implementation supports the round-towards-zero rounding mode for 16-bit floating-point arithmetic and conversion instructions. It also indicates whether theRoundingModeRTZ
execution mode can be used for 16-bit floating-point types. -
shaderRoundingModeRTZFloat32
is a boolean value indicating whether an implementation supports the round-towards-zero rounding mode for 32-bit floating-point arithmetic and conversion instructions. It also indicates whether theRoundingModeRTZ
execution mode can be used for 32-bit floating-point types. -
shaderRoundingModeRTZFloat64
is a boolean value indicating whether an implementation supports the round-towards-zero rounding mode for 64-bit floating-point arithmetic and conversion instructions. It also indicates whether theRoundingModeRTZ
execution mode can be used for 64-bit floating-point types. -
maxUpdateAfterBindDescriptorsInAllPools
is the maximum number of descriptors (summed over all descriptor types) that can be created across all pools that are created with theVK_DESCRIPTOR_POOL_CREATE_UPDATE_AFTER_BIND_BIT
bit set. Pool creation may fail when this limit is exceeded, or when the space this limit represents is unable to satisfy a pool creation due to fragmentation. -
shaderUniformBufferArrayNonUniformIndexingNative
is a boolean value indicating whether uniform buffer descriptors natively support nonuniform indexing. If this isVK_FALSE
, then a single dynamic instance of an instruction that nonuniformly indexes an array of uniform buffers may execute multiple times in order to access all the descriptors. -
shaderSampledImageArrayNonUniformIndexingNative
is a boolean value indicating whether sampler and image descriptors natively support nonuniform indexing. If this isVK_FALSE
, then a single dynamic instance of an instruction that nonuniformly indexes an array of samplers or images may execute multiple times in order to access all the descriptors. -
shaderStorageBufferArrayNonUniformIndexingNative
is a boolean value indicating whether storage buffer descriptors natively support nonuniform indexing. If this isVK_FALSE
, then a single dynamic instance of an instruction that nonuniformly indexes an array of storage buffers may execute multiple times in order to access all the descriptors. -
shaderStorageImageArrayNonUniformIndexingNative
is a boolean value indicating whether storage image descriptors natively support nonuniform indexing. If this isVK_FALSE
, then a single dynamic instance of an instruction that nonuniformly indexes an array of storage images may execute multiple times in order to access all the descriptors. -
shaderInputAttachmentArrayNonUniformIndexingNative
is a boolean value indicating whether input attachment descriptors natively support nonuniform indexing. If this isVK_FALSE
, then a single dynamic instance of an instruction that nonuniformly indexes an array of input attachments may execute multiple times in order to access all the descriptors. -
robustBufferAccessUpdateAfterBind
is a boolean value indicating whetherrobustBufferAccess
can be enabled on a device simultaneously withdescriptorBindingUniformBufferUpdateAfterBind
,descriptorBindingStorageBufferUpdateAfterBind
,descriptorBindingUniformTexelBufferUpdateAfterBind
, and/ordescriptorBindingStorageTexelBufferUpdateAfterBind
. If this isVK_FALSE
, then eitherrobustBufferAccess
must be disabled or all of these update-after-bind features must be disabled. -
quadDivergentImplicitLod
is a boolean value indicating whether implicit LOD calculations for image operations have well-defined results when the image and/or sampler objects used for the instruction are not uniform within a quad. See Derivative Image Operations. -
maxPerStageDescriptorUpdateAfterBindSamplers
is similar tomaxPerStageDescriptorSamplers
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxPerStageDescriptorUpdateAfterBindUniformBuffers
is similar tomaxPerStageDescriptorUniformBuffers
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxPerStageDescriptorUpdateAfterBindStorageBuffers
is similar tomaxPerStageDescriptorStorageBuffers
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxPerStageDescriptorUpdateAfterBindSampledImages
is similar tomaxPerStageDescriptorSampledImages
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxPerStageDescriptorUpdateAfterBindStorageImages
is similar tomaxPerStageDescriptorStorageImages
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxPerStageDescriptorUpdateAfterBindInputAttachments
is similar tomaxPerStageDescriptorInputAttachments
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxPerStageUpdateAfterBindResources
is similar tomaxPerStageResources
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetUpdateAfterBindSamplers
is similar tomaxDescriptorSetSamplers
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetUpdateAfterBindUniformBuffers
is similar tomaxDescriptorSetUniformBuffers
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetUpdateAfterBindUniformBuffersDynamic
is similar tomaxDescriptorSetUniformBuffersDynamic
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. While an application can allocate dynamic uniform buffer descriptors from a pool created with theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
, bindings for these descriptors must not be present in any descriptor set layout that includes bindings created withVK_DESCRIPTOR_BINDING_UPDATE_AFTER_BIND_BIT
. -
maxDescriptorSetUpdateAfterBindStorageBuffers
is similar tomaxDescriptorSetStorageBuffers
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetUpdateAfterBindStorageBuffersDynamic
is similar tomaxDescriptorSetStorageBuffersDynamic
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. While an application can allocate dynamic storage buffer descriptors from a pool created with theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
, bindings for these descriptors must not be present in any descriptor set layout that includes bindings created withVK_DESCRIPTOR_BINDING_UPDATE_AFTER_BIND_BIT
. -
maxDescriptorSetUpdateAfterBindSampledImages
is similar tomaxDescriptorSetSampledImages
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetUpdateAfterBindStorageImages
is similar tomaxDescriptorSetStorageImages
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetUpdateAfterBindInputAttachments
is similar tomaxDescriptorSetInputAttachments
but counts descriptors from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
supportedDepthResolveModes
is a bitmask of VkResolveModeFlagBits indicating the set of supported depth resolve modes.VK_RESOLVE_MODE_SAMPLE_ZERO_BIT
must be included in the set but implementations may support additional modes. -
supportedStencilResolveModes
is a bitmask of VkResolveModeFlagBits indicating the set of supported stencil resolve modes.VK_RESOLVE_MODE_SAMPLE_ZERO_BIT
must be included in the set but implementations may support additional modes.VK_RESOLVE_MODE_AVERAGE_BIT
must not be included in the set. -
independentResolveNone
isVK_TRUE
if the implementation supports setting the depth and stencil resolve modes to different values when one of those modes isVK_RESOLVE_MODE_NONE
. Otherwise the implementation only supports setting both modes to the same value. -
independentResolve
isVK_TRUE
if the implementation supports all combinations of the supported depth and stencil resolve modes, including setting either depth or stencil resolve mode toVK_RESOLVE_MODE_NONE
. An implementation that supportsindependentResolve
must also supportindependentResolveNone
. -
filterMinmaxSingleComponentFormats
is a boolean value indicating whether a minimum set of required formats support min/max filtering. -
filterMinmaxImageComponentMapping
is a boolean value indicating whether the implementation supports non-identity component mapping of the image when doing min/max filtering. -
maxTimelineSemaphoreValueDifference
indicates the maximum difference allowed by the implementation between the current value of a timeline semaphore and any pending signal or wait operations. -
framebufferIntegerColorSampleCounts
is a bitmask of VkSampleCountFlagBits indicating the color sample counts that are supported for all framebuffer color attachments with integer formats.
If the VkPhysicalDeviceVulkan12Properties
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These properties correspond to Vulkan 1.2 functionality.
The members of VkPhysicalDeviceVulkan12Properties
must have the same
values as the corresponding members of
VkPhysicalDeviceDriverProperties,
VkPhysicalDeviceFloatControlsProperties,
VkPhysicalDeviceDescriptorIndexingProperties,
VkPhysicalDeviceDepthStencilResolveProperties,
VkPhysicalDeviceSamplerFilterMinmaxProperties, and
VkPhysicalDeviceTimelineSemaphoreProperties.
The VkPhysicalDeviceVulkan13Properties
structure is defined as:
// Provided by VK_VERSION_1_3
typedef struct VkPhysicalDeviceVulkan13Properties {
VkStructureType sType;
void* pNext;
uint32_t minSubgroupSize;
uint32_t maxSubgroupSize;
uint32_t maxComputeWorkgroupSubgroups;
VkShaderStageFlags requiredSubgroupSizeStages;
uint32_t maxInlineUniformBlockSize;
uint32_t maxPerStageDescriptorInlineUniformBlocks;
uint32_t maxPerStageDescriptorUpdateAfterBindInlineUniformBlocks;
uint32_t maxDescriptorSetInlineUniformBlocks;
uint32_t maxDescriptorSetUpdateAfterBindInlineUniformBlocks;
uint32_t maxInlineUniformTotalSize;
VkBool32 integerDotProduct8BitUnsignedAccelerated;
VkBool32 integerDotProduct8BitSignedAccelerated;
VkBool32 integerDotProduct8BitMixedSignednessAccelerated;
VkBool32 integerDotProduct4x8BitPackedUnsignedAccelerated;
VkBool32 integerDotProduct4x8BitPackedSignedAccelerated;
VkBool32 integerDotProduct4x8BitPackedMixedSignednessAccelerated;
VkBool32 integerDotProduct16BitUnsignedAccelerated;
VkBool32 integerDotProduct16BitSignedAccelerated;
VkBool32 integerDotProduct16BitMixedSignednessAccelerated;
VkBool32 integerDotProduct32BitUnsignedAccelerated;
VkBool32 integerDotProduct32BitSignedAccelerated;
VkBool32 integerDotProduct32BitMixedSignednessAccelerated;
VkBool32 integerDotProduct64BitUnsignedAccelerated;
VkBool32 integerDotProduct64BitSignedAccelerated;
VkBool32 integerDotProduct64BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating8BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating8BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating8BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating4x8BitPackedUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating4x8BitPackedSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating4x8BitPackedMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating16BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating16BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating16BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating32BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating32BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating32BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating64BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating64BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating64BitMixedSignednessAccelerated;
VkDeviceSize storageTexelBufferOffsetAlignmentBytes;
VkBool32 storageTexelBufferOffsetSingleTexelAlignment;
VkDeviceSize uniformTexelBufferOffsetAlignmentBytes;
VkBool32 uniformTexelBufferOffsetSingleTexelAlignment;
VkDeviceSize maxBufferSize;
} VkPhysicalDeviceVulkan13Properties;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure.
-
minSubgroupSize
is the minimum subgroup size supported by this device.minSubgroupSize
is at least one if any of the physical device’s queues supportVK_QUEUE_GRAPHICS_BIT
orVK_QUEUE_COMPUTE_BIT
.minSubgroupSize
is a power-of-two.minSubgroupSize
is less than or equal tomaxSubgroupSize
.minSubgroupSize
is less than or equal tosubgroupSize
. -
maxSubgroupSize
is the maximum subgroup size supported by this device.maxSubgroupSize
is at least one if any of the physical device’s queues supportVK_QUEUE_GRAPHICS_BIT
orVK_QUEUE_COMPUTE_BIT
.maxSubgroupSize
is a power-of-two.maxSubgroupSize
is greater than or equal tominSubgroupSize
.maxSubgroupSize
is greater than or equal tosubgroupSize
. -
maxComputeWorkgroupSubgroups
is the maximum number of subgroups supported by the implementation within a workgroup. -
requiredSubgroupSizeStages
is a bitfield of what shader stages support having a required subgroup size specified. -
maxInlineUniformBlockSize
is the maximum size in bytes of an inline uniform block binding. -
maxPerStageDescriptorInlineUniformBlocks
is the maximum number of inline uniform block bindings that can be accessible to a single shader stage in a pipeline layout. Descriptor bindings with a descriptor type ofVK_DESCRIPTOR_TYPE_INLINE_UNIFORM_BLOCK
count against this limit. Only descriptor bindings in descriptor set layouts created without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set count against this limit. -
maxPerStageDescriptorUpdateAfterBindInlineUniformBlocks
is similar tomaxPerStageDescriptorInlineUniformBlocks
but counts descriptor bindings from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxDescriptorSetInlineUniformBlocks
is the maximum number of inline uniform block bindings that can be included in descriptor bindings in a pipeline layout across all pipeline shader stages and descriptor set numbers. Descriptor bindings with a descriptor type ofVK_DESCRIPTOR_TYPE_INLINE_UNIFORM_BLOCK
count against this limit. Only descriptor bindings in descriptor set layouts created without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set count against this limit. -
maxDescriptorSetUpdateAfterBindInlineUniformBlocks
is similar tomaxDescriptorSetInlineUniformBlocks
but counts descriptor bindings from descriptor sets created with or without theVK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT
bit set. -
maxInlineUniformTotalSize
is the maximum total size in bytes of all inline uniform block bindings, across all pipeline shader stages and descriptor set numbers, that can be included in a pipeline layout. Descriptor bindings with a descriptor type ofVK_DESCRIPTOR_TYPE_INLINE_UNIFORM_BLOCK
count against this limit. -
integerDotProduct8BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct8BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct8BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct4x8BitPackedUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned dot product operations from operands packed into 32-bit integers using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct4x8BitPackedSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed dot product operations from operands packed into 32-bit integers using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct4x8BitPackedMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness dot product operations from operands packed into 32-bit integers using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct16BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct16BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct16BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct32BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct32BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct32BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct64BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct64BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct64BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating8BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating8BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating8BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating4x8BitPackedUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned accumulating saturating dot product operations from operands packed into 32-bit integers using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating4x8BitPackedSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed accumulating saturating dot product operations from operands packed into 32-bit integers using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating4x8BitPackedMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness accumulating saturating dot product operations from operands packed into 32-bit integers using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating16BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating16BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating16BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating32BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating32BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating32BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating64BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating64BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating64BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
storageTexelBufferOffsetAlignmentBytes
is a byte alignment that is sufficient for a storage texel buffer of any format. The value must be a power of two. -
storageTexelBufferOffsetSingleTexelAlignment
indicates whether single texel alignment is sufficient for a storage texel buffer of any format. -
uniformTexelBufferOffsetAlignmentBytes
is a byte alignment that is sufficient for a uniform texel buffer of any format. The value must be a power of two. -
uniformTexelBufferOffsetSingleTexelAlignment
indicates whether single texel alignment is sufficient for a uniform texel buffer of any format. -
maxBufferSize
is the maximum sizeVkBuffer
that can be created.
If the VkPhysicalDeviceVulkan13Properties
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These properties correspond to Vulkan 1.3 functionality.
The members of VkPhysicalDeviceVulkan13Properties
must have the same
values as the corresponding members of
VkPhysicalDeviceInlineUniformBlockProperties and
VkPhysicalDeviceSubgroupSizeControlProperties.
The VkPhysicalDeviceIDProperties
structure is defined as:
// Provided by VK_VERSION_1_1
typedef struct VkPhysicalDeviceIDProperties {
VkStructureType sType;
void* pNext;
uint8_t deviceUUID[VK_UUID_SIZE];
uint8_t driverUUID[VK_UUID_SIZE];
uint8_t deviceLUID[VK_LUID_SIZE];
uint32_t deviceNodeMask;
VkBool32 deviceLUIDValid;
} VkPhysicalDeviceIDProperties;
or the equivalent
// Provided by VK_KHR_external_fence_capabilities, VK_KHR_external_memory_capabilities, VK_KHR_external_semaphore_capabilities
typedef VkPhysicalDeviceIDProperties VkPhysicalDeviceIDPropertiesKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure.
-
deviceUUID
is an array ofVK_UUID_SIZE
uint8_t
values representing a universally unique identifier for the device. -
driverUUID
is an array ofVK_UUID_SIZE
uint8_t
values representing a universally unique identifier for the driver build in use by the device. -
deviceLUID
is an array ofVK_LUID_SIZE
uint8_t
values representing a locally unique identifier for the device. -
deviceNodeMask
is auint32_t
bitfield identifying the node within a linked device adapter corresponding to the device. -
deviceLUIDValid
is a boolean value that will beVK_TRUE
ifdeviceLUID
contains a valid LUID anddeviceNodeMask
contains a valid node mask, andVK_FALSE
if they do not.
If the VkPhysicalDeviceIDProperties
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
deviceUUID
must be immutable for a given device across instances,
processes, driver APIs, driver versions, and system reboots.
Applications can compare the driverUUID
value across instance and
process boundaries, and can make similar queries in external APIs to
determine whether they are capable of sharing memory objects and resources
using them with the device.
deviceUUID
and/or driverUUID
must be used to determine whether
a particular external object can be shared between driver components, where
such a restriction exists as defined in the compatibility table for the
particular object type:
If deviceLUIDValid
is VK_FALSE
, the values of deviceLUID
and deviceNodeMask
are undefined.
If deviceLUIDValid
is VK_TRUE
and Vulkan is running on the
Windows operating system, the contents of deviceLUID
can be cast to
an LUID
object and must be equal to the locally unique identifier of a
IDXGIAdapter1
object that corresponds to physicalDevice
.
If deviceLUIDValid
is VK_TRUE
, deviceNodeMask
must
contain exactly one bit.
If Vulkan is running on an operating system that supports the Direct3D 12
API and physicalDevice
corresponds to an individual device in a linked
device adapter, deviceNodeMask
identifies the Direct3D 12 node
corresponding to physicalDevice
.
Otherwise, deviceNodeMask
must be 1
.
Note
Although they have identical descriptions,
VkPhysicalDeviceIDProperties:: Implementations should return Khronos' conformance testing is unable to guarantee that A combination of values unique to the vendor, the driver, and the hardware
environment can be used to provide a
|
Note
While VkPhysicalDeviceIDProperties:: |
VK_UUID_SIZE
is the length in uint8_t
values of an array
containing a universally unique device or driver build identifier, as
returned in VkPhysicalDeviceIDProperties::deviceUUID
and
VkPhysicalDeviceIDProperties::driverUUID
.
#define VK_UUID_SIZE 16U
VK_LUID_SIZE
is the length in uint8_t
values of an array
containing a locally unique device identifier, as returned in
VkPhysicalDeviceIDProperties::deviceLUID
.
#define VK_LUID_SIZE 8U
or the equivalent
#define VK_LUID_SIZE_KHR VK_LUID_SIZE
The VkPhysicalDeviceDriverProperties
structure is defined as:
// Provided by VK_VERSION_1_2
typedef struct VkPhysicalDeviceDriverProperties {
VkStructureType sType;
void* pNext;
VkDriverId driverID;
char driverName[VK_MAX_DRIVER_NAME_SIZE];
char driverInfo[VK_MAX_DRIVER_INFO_SIZE];
VkConformanceVersion conformanceVersion;
} VkPhysicalDeviceDriverProperties;
or the equivalent
// Provided by VK_KHR_driver_properties
typedef VkPhysicalDeviceDriverProperties VkPhysicalDeviceDriverPropertiesKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure.
-
driverID
is a unique identifier for the driver of the physical device. -
driverName
is an array ofVK_MAX_DRIVER_NAME_SIZE
char
containing a null-terminated UTF-8 string which is the name of the driver. -
driverInfo
is an array ofVK_MAX_DRIVER_INFO_SIZE
char
containing a null-terminated UTF-8 string with additional information about the driver. -
conformanceVersion
is the version of the Vulkan conformance test this driver is conformant against (see VkConformanceVersion).
If the VkPhysicalDeviceDriverProperties
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These are properties of the driver corresponding to a physical device.
driverID
must be immutable for a given driver across instances,
processes, driver versions, and system reboots.
Khronos driver IDs which may be returned in
VkPhysicalDeviceDriverProperties::driverID
are:
// Provided by VK_VERSION_1_2
typedef enum VkDriverId {
VK_DRIVER_ID_AMD_PROPRIETARY = 1,
VK_DRIVER_ID_AMD_OPEN_SOURCE = 2,
VK_DRIVER_ID_MESA_RADV = 3,
VK_DRIVER_ID_NVIDIA_PROPRIETARY = 4,
VK_DRIVER_ID_INTEL_PROPRIETARY_WINDOWS = 5,
VK_DRIVER_ID_INTEL_OPEN_SOURCE_MESA = 6,
VK_DRIVER_ID_IMAGINATION_PROPRIETARY = 7,
VK_DRIVER_ID_QUALCOMM_PROPRIETARY = 8,
VK_DRIVER_ID_ARM_PROPRIETARY = 9,
VK_DRIVER_ID_GOOGLE_SWIFTSHADER = 10,
VK_DRIVER_ID_GGP_PROPRIETARY = 11,
VK_DRIVER_ID_BROADCOM_PROPRIETARY = 12,
VK_DRIVER_ID_MESA_LLVMPIPE = 13,
VK_DRIVER_ID_MOLTENVK = 14,
VK_DRIVER_ID_COREAVI_PROPRIETARY = 15,
VK_DRIVER_ID_JUICE_PROPRIETARY = 16,
VK_DRIVER_ID_VERISILICON_PROPRIETARY = 17,
VK_DRIVER_ID_MESA_TURNIP = 18,
VK_DRIVER_ID_MESA_V3DV = 19,
VK_DRIVER_ID_MESA_PANVK = 20,
VK_DRIVER_ID_SAMSUNG_PROPRIETARY = 21,
VK_DRIVER_ID_MESA_VENUS = 22,
VK_DRIVER_ID_MESA_DOZEN = 23,
VK_DRIVER_ID_MESA_NVK = 24,
VK_DRIVER_ID_IMAGINATION_OPEN_SOURCE_MESA = 25,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_AMD_PROPRIETARY_KHR = VK_DRIVER_ID_AMD_PROPRIETARY,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_AMD_OPEN_SOURCE_KHR = VK_DRIVER_ID_AMD_OPEN_SOURCE,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_MESA_RADV_KHR = VK_DRIVER_ID_MESA_RADV,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_NVIDIA_PROPRIETARY_KHR = VK_DRIVER_ID_NVIDIA_PROPRIETARY,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_INTEL_PROPRIETARY_WINDOWS_KHR = VK_DRIVER_ID_INTEL_PROPRIETARY_WINDOWS,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_INTEL_OPEN_SOURCE_MESA_KHR = VK_DRIVER_ID_INTEL_OPEN_SOURCE_MESA,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_IMAGINATION_PROPRIETARY_KHR = VK_DRIVER_ID_IMAGINATION_PROPRIETARY,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_QUALCOMM_PROPRIETARY_KHR = VK_DRIVER_ID_QUALCOMM_PROPRIETARY,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_ARM_PROPRIETARY_KHR = VK_DRIVER_ID_ARM_PROPRIETARY,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_GOOGLE_SWIFTSHADER_KHR = VK_DRIVER_ID_GOOGLE_SWIFTSHADER,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_GGP_PROPRIETARY_KHR = VK_DRIVER_ID_GGP_PROPRIETARY,
// Provided by VK_KHR_driver_properties
VK_DRIVER_ID_BROADCOM_PROPRIETARY_KHR = VK_DRIVER_ID_BROADCOM_PROPRIETARY,
} VkDriverId;
or the equivalent
// Provided by VK_KHR_driver_properties
typedef VkDriverId VkDriverIdKHR;
Note
Khronos driver IDs may be allocated by vendors at any time.
There may be multiple driver IDs for the same vendor, representing different
drivers (for e.g. different platforms, proprietary or open source, etc.).
Only the latest canonical versions of this Specification, of the
corresponding Only driver IDs registered with Khronos are given symbolic names. There may be unregistered driver IDs returned. |
VK_MAX_DRIVER_NAME_SIZE
is the length in char
values of an array
containing a driver name string, as returned in
VkPhysicalDeviceDriverProperties::driverName
.
#define VK_MAX_DRIVER_NAME_SIZE 256U
or the equivalent
#define VK_MAX_DRIVER_NAME_SIZE_KHR VK_MAX_DRIVER_NAME_SIZE
VK_MAX_DRIVER_INFO_SIZE
is the length in char
values of an array
containing a driver information string, as returned in
VkPhysicalDeviceDriverProperties::driverInfo
.
#define VK_MAX_DRIVER_INFO_SIZE 256U
or the equivalent
#define VK_MAX_DRIVER_INFO_SIZE_KHR VK_MAX_DRIVER_INFO_SIZE
The conformance test suite version an implementation is compliant with is
described with the VkConformanceVersion
structure:
// Provided by VK_VERSION_1_2
typedef struct VkConformanceVersion {
uint8_t major;
uint8_t minor;
uint8_t subminor;
uint8_t patch;
} VkConformanceVersion;
or the equivalent
// Provided by VK_KHR_driver_properties
typedef VkConformanceVersion VkConformanceVersionKHR;
-
major
is the major version number of the conformance test suite. -
minor
is the minor version number of the conformance test suite. -
subminor
is the subminor version number of the conformance test suite. -
patch
is the patch version number of the conformance test suite.
The VkPhysicalDevicePCIBusInfoPropertiesEXT
structure is defined as:
// Provided by VK_EXT_pci_bus_info
typedef struct VkPhysicalDevicePCIBusInfoPropertiesEXT {
VkStructureType sType;
void* pNext;
uint32_t pciDomain;
uint32_t pciBus;
uint32_t pciDevice;
uint32_t pciFunction;
} VkPhysicalDevicePCIBusInfoPropertiesEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
pciDomain
is the PCI bus domain. -
pciBus
is the PCI bus identifier. -
pciDevice
is the PCI device identifier. -
pciFunction
is the PCI device function identifier.
If the VkPhysicalDevicePCIBusInfoPropertiesEXT
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These are properties of the PCI bus information of a physical device.
The VkPhysicalDeviceDrmPropertiesEXT
structure is defined as:
// Provided by VK_EXT_physical_device_drm
typedef struct VkPhysicalDeviceDrmPropertiesEXT {
VkStructureType sType;
void* pNext;
VkBool32 hasPrimary;
VkBool32 hasRender;
int64_t primaryMajor;
int64_t primaryMinor;
int64_t renderMajor;
int64_t renderMinor;
} VkPhysicalDeviceDrmPropertiesEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
hasPrimary
is a boolean indicating whether the physical device has a DRM primary node. -
hasRender
is a boolean indicating whether the physical device has a DRM render node. -
primaryMajor
is the DRM primary node major number, if any. -
primaryMinor
is the DRM primary node minor number, if any. -
renderMajor
is the DRM render node major number, if any. -
renderMinor
is the DRM render node minor number, if any.
If the VkPhysicalDeviceDrmPropertiesEXT
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These are properties of the DRM information of a physical device.
The VkPhysicalDeviceShaderIntegerDotProductProperties
structure is
defined as:
// Provided by VK_VERSION_1_3
typedef struct VkPhysicalDeviceShaderIntegerDotProductProperties {
VkStructureType sType;
void* pNext;
VkBool32 integerDotProduct8BitUnsignedAccelerated;
VkBool32 integerDotProduct8BitSignedAccelerated;
VkBool32 integerDotProduct8BitMixedSignednessAccelerated;
VkBool32 integerDotProduct4x8BitPackedUnsignedAccelerated;
VkBool32 integerDotProduct4x8BitPackedSignedAccelerated;
VkBool32 integerDotProduct4x8BitPackedMixedSignednessAccelerated;
VkBool32 integerDotProduct16BitUnsignedAccelerated;
VkBool32 integerDotProduct16BitSignedAccelerated;
VkBool32 integerDotProduct16BitMixedSignednessAccelerated;
VkBool32 integerDotProduct32BitUnsignedAccelerated;
VkBool32 integerDotProduct32BitSignedAccelerated;
VkBool32 integerDotProduct32BitMixedSignednessAccelerated;
VkBool32 integerDotProduct64BitUnsignedAccelerated;
VkBool32 integerDotProduct64BitSignedAccelerated;
VkBool32 integerDotProduct64BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating8BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating8BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating8BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating4x8BitPackedUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating4x8BitPackedSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating4x8BitPackedMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating16BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating16BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating16BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating32BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating32BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating32BitMixedSignednessAccelerated;
VkBool32 integerDotProductAccumulatingSaturating64BitUnsignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating64BitSignedAccelerated;
VkBool32 integerDotProductAccumulatingSaturating64BitMixedSignednessAccelerated;
} VkPhysicalDeviceShaderIntegerDotProductProperties;
or the equivalent
// Provided by VK_KHR_shader_integer_dot_product
typedef VkPhysicalDeviceShaderIntegerDotProductProperties VkPhysicalDeviceShaderIntegerDotProductPropertiesKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure.
-
integerDotProduct8BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct8BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct8BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct4x8BitPackedUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned dot product operations from operands packed into 32-bit integers using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct4x8BitPackedSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed dot product operations from operands packed into 32-bit integers using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct4x8BitPackedMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness dot product operations from operands packed into 32-bit integers using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct16BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct16BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct16BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct32BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct32BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct32BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct64BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit unsigned dot product operations using theOpUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct64BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit signed dot product operations using theOpSDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProduct64BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit mixed signedness dot product operations using theOpSUDotKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating8BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating8BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating8BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating4x8BitPackedUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit unsigned accumulating saturating dot product operations from operands packed into 32-bit integers using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating4x8BitPackedSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit signed accumulating saturating dot product operations from operands packed into 32-bit integers using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating4x8BitPackedMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 8-bit mixed signedness accumulating saturating dot product operations from operands packed into 32-bit integers using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating16BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating16BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating16BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 16-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating32BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating32BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating32BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 32-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating64BitUnsignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit unsigned accumulating saturating dot product operations using theOpUDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating64BitSignedAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit signed accumulating saturating dot product operations using theOpSDotAccSatKHR
SPIR-V instruction is accelerated as defined below. -
integerDotProductAccumulatingSaturating64BitMixedSignednessAccelerated
is a boolean that will beVK_TRUE
if the support for 64-bit mixed signedness accumulating saturating dot product operations using theOpSUDotAccSatKHR
SPIR-V instruction is accelerated as defined below.
If the VkPhysicalDeviceShaderIntegerDotProductProperties
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These are properties of the integer dot product acceleration information of a physical device.
Note
A dot product operation is deemed accelerated if its implementation provides a performance advantage over application-provided code composed from elementary instructions and/or other dot product instructions, either because the implementation uses optimized machine code sequences whose generation from application-provided code cannot be guaranteed or because it uses hardware features that cannot otherwise be targeted from application-provided code. |
The VkPhysicalDeviceImageProcessingPropertiesQCOM
structure is defined
as:
// Provided by VK_QCOM_image_processing
typedef struct VkPhysicalDeviceImageProcessingPropertiesQCOM {
VkStructureType sType;
void* pNext;
uint32_t maxWeightFilterPhases;
VkExtent2D maxWeightFilterDimension;
VkExtent2D maxBlockMatchRegion;
VkExtent2D maxBoxFilterBlockSize;
} VkPhysicalDeviceImageProcessingPropertiesQCOM;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
maxWeightFilterPhases
is the maximum value that can be specified for VkImageViewSampleWeightCreateInfoQCOM::numPhases
. in weight image sampling operations. -
maxWeightFilterDimension
is a VkExtent2D describing the largest dimensions (width
andheight
) that can be specified for VkImageViewSampleWeightCreateInfoQCOM::filterSize
. -
maxBlockMatchRegion
is a VkExtent2D describing the largest dimensions (width
andheight
) that can be specified forblockSize
in block matching operations. -
maxBoxFilterBlockSize
is a VkExtent2D describing the maximum dimensions (width
andheight
) that can be specified forblocksize
in box filter sampling operations.
If the VkPhysicalDeviceImageProcessingPropertiesQCOM
structure is included in the pNext
chain of the
VkPhysicalDeviceProperties2 structure passed to
vkGetPhysicalDeviceProperties2, it is filled in with each
corresponding implementation-dependent property.
These are properties of the image processing information of a physical device.
To query properties of queues available on a physical device, call:
// Provided by VK_VERSION_1_0
void vkGetPhysicalDeviceQueueFamilyProperties(
VkPhysicalDevice physicalDevice,
uint32_t* pQueueFamilyPropertyCount,
VkQueueFamilyProperties* pQueueFamilyProperties);
-
physicalDevice
is the handle to the physical device whose properties will be queried. -
pQueueFamilyPropertyCount
is a pointer to an integer related to the number of queue families available or queried, as described below. -
pQueueFamilyProperties
is eitherNULL
or a pointer to an array of VkQueueFamilyProperties structures.
If pQueueFamilyProperties
is NULL
, then the number of queue families
available is returned in pQueueFamilyPropertyCount
.
Implementations must support at least one queue family.
Otherwise, pQueueFamilyPropertyCount
must point to a variable set by
the user to the number of elements in the pQueueFamilyProperties
array, and on return the variable is overwritten with the number of
structures actually written to pQueueFamilyProperties
.
If pQueueFamilyPropertyCount
is less than the number of queue families
available, at most pQueueFamilyPropertyCount
structures will be
written.
The VkQueueFamilyProperties
structure is defined as:
// Provided by VK_VERSION_1_0
typedef struct VkQueueFamilyProperties {
VkQueueFlags queueFlags;
uint32_t queueCount;
uint32_t timestampValidBits;
VkExtent3D minImageTransferGranularity;
} VkQueueFamilyProperties;
-
queueFlags
is a bitmask of VkQueueFlagBits indicating capabilities of the queues in this queue family. -
queueCount
is the unsigned integer count of queues in this queue family. Each queue family must support at least one queue. -
timestampValidBits
is the unsigned integer count of meaningful bits in the timestamps written via vkCmdWriteTimestamp2 or vkCmdWriteTimestamp. The valid range for the count is 36 to 64 bits, or a value of 0, indicating no support for timestamps. Bits outside the valid range are guaranteed to be zeros. -
minImageTransferGranularity
is the minimum granularity supported for image transfer operations on the queues in this queue family.
The value returned in minImageTransferGranularity
has a unit of
compressed texel blocks for images having a block-compressed format, and a
unit of texels otherwise.
Possible values of minImageTransferGranularity
are:
-
(0,0,0) specifies that only whole mip levels must be transferred using the image transfer operations on the corresponding queues. In this case, the following restrictions apply to all offset and extent parameters of image transfer operations:
-
The
x
,y
, andz
members of a VkOffset3D parameter must always be zero. -
The
width
,height
, anddepth
members of a VkExtent3D parameter must always match the width, height, and depth of the image subresource corresponding to the parameter, respectively.
-
-
(Ax, Ay, Az) where Ax, Ay, and Az are all integer powers of two. In this case the following restrictions apply to all image transfer operations:
-
x
,y
, andz
of a VkOffset3D parameter must be integer multiples of Ax, Ay, and Az, respectively. -
width
of a VkExtent3D parameter must be an integer multiple of Ax, or elsex
+width
must equal the width of the image subresource corresponding to the parameter. -
height
of a VkExtent3D parameter must be an integer multiple of Ay, or elsey
+height
must equal the height of the image subresource corresponding to the parameter. -
depth
of a VkExtent3D parameter must be an integer multiple of Az, or elsez
+depth
must equal the depth of the image subresource corresponding to the parameter. -
If the format of the image corresponding to the parameters is one of the block-compressed formats then for the purposes of the above calculations the granularity must be scaled up by the compressed texel block dimensions.
-
Queues supporting graphics and/or compute operations must report
(1,1,1) in minImageTransferGranularity
, meaning that there are
no additional restrictions on the granularity of image transfer operations
for these queues.
Other queues supporting image transfer operations are only required to
support whole mip level transfers, thus minImageTransferGranularity
for queues belonging to such queue families may be (0,0,0).
The Device Memory section describes memory properties queried from the physical device.
For physical device feature queries see the Features chapter.
Bits which may be set in VkQueueFamilyProperties::queueFlags
,
indicating capabilities of queues in a queue family are:
// Provided by VK_VERSION_1_0
typedef enum VkQueueFlagBits {
VK_QUEUE_GRAPHICS_BIT = 0x00000001,
VK_QUEUE_COMPUTE_BIT = 0x00000002,
VK_QUEUE_TRANSFER_BIT = 0x00000004,
VK_QUEUE_SPARSE_BINDING_BIT = 0x00000008,
// Provided by VK_VERSION_1_1
VK_QUEUE_PROTECTED_BIT = 0x00000010,
// Provided by VK_KHR_video_decode_queue
VK_QUEUE_VIDEO_DECODE_BIT_KHR = 0x00000020,
#ifdef VK_ENABLE_BETA_EXTENSIONS
// Provided by VK_KHR_video_encode_queue
VK_QUEUE_VIDEO_ENCODE_BIT_KHR = 0x00000040,
#endif
// Provided by VK_NV_optical_flow
VK_QUEUE_OPTICAL_FLOW_BIT_NV = 0x00000100,
} VkQueueFlagBits;
-
VK_QUEUE_GRAPHICS_BIT
specifies that queues in this queue family support graphics operations. -
VK_QUEUE_COMPUTE_BIT
specifies that queues in this queue family support compute operations. -
VK_QUEUE_TRANSFER_BIT
specifies that queues in this queue family support transfer operations. -
VK_QUEUE_SPARSE_BINDING_BIT
specifies that queues in this queue family support sparse memory management operations (see Sparse Resources). If any of the sparse resource features are enabled, then at least one queue family must support this bit. -
VK_QUEUE_VIDEO_DECODE_BIT_KHR
specifies that queues in this queue family support video decode operations. -
VK_QUEUE_VIDEO_ENCODE_BIT_KHR
specifies that queues in this queue family support video encode operations. -
VK_QUEUE_OPTICAL_FLOW_BIT_NV
specifies that queues in this queue family support optical flow operations. -
VK_QUEUE_PROTECTED_BIT
specifies that queues in this queue family support theVK_DEVICE_QUEUE_CREATE_PROTECTED_BIT
bit. (see Protected Memory). If the physical device supports theprotectedMemory
feature, at least one of its queue families must support this bit.
If an implementation exposes any queue family that supports graphics operations, at least one queue family of at least one physical device exposed by the implementation must support both graphics and compute operations.
Furthermore, if the protectedMemory
physical device feature is supported, then at least one queue family of at
least one physical device exposed by the implementation must support
graphics operations, compute operations, and protected memory operations.
Note
All commands that are allowed on a queue that supports transfer operations
are also allowed on a queue that supports either graphics or compute
operations.
Thus, if the capabilities of a queue family include
|
For further details see Queues.
// Provided by VK_VERSION_1_0
typedef VkFlags VkQueueFlags;
VkQueueFlags
is a bitmask type for setting a mask of zero or more
VkQueueFlagBits.
To query properties of queues available on a physical device, call:
// Provided by VK_VERSION_1_1
void vkGetPhysicalDeviceQueueFamilyProperties2(
VkPhysicalDevice physicalDevice,
uint32_t* pQueueFamilyPropertyCount,
VkQueueFamilyProperties2* pQueueFamilyProperties);
or the equivalent command
// Provided by VK_KHR_get_physical_device_properties2
void vkGetPhysicalDeviceQueueFamilyProperties2KHR(
VkPhysicalDevice physicalDevice,
uint32_t* pQueueFamilyPropertyCount,
VkQueueFamilyProperties2* pQueueFamilyProperties);
-
physicalDevice
is the handle to the physical device whose properties will be queried. -
pQueueFamilyPropertyCount
is a pointer to an integer related to the number of queue families available or queried, as described in vkGetPhysicalDeviceQueueFamilyProperties. -
pQueueFamilyProperties
is eitherNULL
or a pointer to an array of VkQueueFamilyProperties2 structures.
vkGetPhysicalDeviceQueueFamilyProperties2
behaves similarly to
vkGetPhysicalDeviceQueueFamilyProperties, with the ability to return
extended information in a pNext
chain of output structures.
The VkQueueFamilyProperties2
structure is defined as:
// Provided by VK_VERSION_1_1
typedef struct VkQueueFamilyProperties2 {
VkStructureType sType;
void* pNext;
VkQueueFamilyProperties queueFamilyProperties;
} VkQueueFamilyProperties2;
or the equivalent
// Provided by VK_KHR_get_physical_device_properties2
typedef VkQueueFamilyProperties2 VkQueueFamilyProperties2KHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
queueFamilyProperties
is a VkQueueFamilyProperties structure which is populated with the same values as in vkGetPhysicalDeviceQueueFamilyProperties.
The definition of VkQueueFamilyGlobalPriorityPropertiesKHR is:
// Provided by VK_KHR_global_priority
typedef struct VkQueueFamilyGlobalPriorityPropertiesKHR {
VkStructureType sType;
void* pNext;
uint32_t priorityCount;
VkQueueGlobalPriorityKHR priorities[VK_MAX_GLOBAL_PRIORITY_SIZE_KHR];
} VkQueueFamilyGlobalPriorityPropertiesKHR;
or the equivalent
// Provided by VK_EXT_global_priority_query
typedef VkQueueFamilyGlobalPriorityPropertiesKHR VkQueueFamilyGlobalPriorityPropertiesEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
priorityCount
is the number of supported global queue priorities in this queue family, and it must be greater than 0. -
priorities
is an array ofVK_MAX_GLOBAL_PRIORITY_SIZE_EXT
VkQueueGlobalPriorityEXT enums representing all supported global queue priorities in this queue family. The firstpriorityCount
elements of the array will be valid.
If the VkQueueFamilyGlobalPriorityPropertiesKHR
structure is included
in the pNext
chain of the VkQueueFamilyProperties2 structure
passed to vkGetPhysicalDeviceQueueFamilyProperties2, it is filled in
with the list of supported global queue priorities for the indicated family.
The valid elements of priorities
must not contain any duplicate
values.
The valid elements of priorities
must be a continuous sequence of
VkQueueGlobalPriorityKHR enums in the ascending order.
Note
For example, returning |
VK_MAX_GLOBAL_PRIORITY_SIZE_KHR
is the length of an array of
VkQueueGlobalPriorityKHR enumerants representing supported queue
priorities, as returned in
VkQueueFamilyGlobalPriorityPropertiesKHR::priorities
.
#define VK_MAX_GLOBAL_PRIORITY_SIZE_KHR 16U
or the equivalent
#define VK_MAX_GLOBAL_PRIORITY_SIZE_EXT VK_MAX_GLOBAL_PRIORITY_SIZE_KHR
The VkQueueFamilyCheckpointProperties2NV structure is defined as:
// Provided by VK_KHR_synchronization2 with VK_NV_device_diagnostic_checkpoints
typedef struct VkQueueFamilyCheckpointProperties2NV {
VkStructureType sType;
void* pNext;
VkPipelineStageFlags2 checkpointExecutionStageMask;
} VkQueueFamilyCheckpointProperties2NV;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
checkpointExecutionStageMask
is a mask indicating which pipeline stages the implementation can execute checkpoint markers in.
Additional queue family information can be queried by setting
VkQueueFamilyProperties2::pNext
to point to a
VkQueueFamilyCheckpointProperties2NV
structure.
The VkQueueFamilyCheckpointPropertiesNV structure is defined as:
// Provided by VK_NV_device_diagnostic_checkpoints
typedef struct VkQueueFamilyCheckpointPropertiesNV {
VkStructureType sType;
void* pNext;
VkPipelineStageFlags checkpointExecutionStageMask;
} VkQueueFamilyCheckpointPropertiesNV;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
checkpointExecutionStageMask
is a mask indicating which pipeline stages the implementation can execute checkpoint markers in.
Additional queue family information can be queried by setting
VkQueueFamilyProperties2::pNext
to point to a
VkQueueFamilyCheckpointPropertiesNV
structure.
The VkQueueFamilyVideoPropertiesKHR structure is defined as:
// Provided by VK_KHR_video_queue
typedef struct VkQueueFamilyVideoPropertiesKHR {
VkStructureType sType;
void* pNext;
VkVideoCodecOperationFlagsKHR videoCodecOperations;
} VkQueueFamilyVideoPropertiesKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
videoCodecOperations
is a bitmask of VkVideoCodecOperationFlagBitsKHR that indicates the set of video codec operations supported by the queue family.
If this structure is included in the pNext
chain of the
VkQueueFamilyProperties2 structure passed to
vkGetPhysicalDeviceQueueFamilyProperties2, then it is filled with the
set of video codec operations supported by the specified queue family.
The VkQueueFamilyQueryResultStatusPropertiesKHR structure is defined as:
// Provided by VK_KHR_video_queue
typedef struct VkQueueFamilyQueryResultStatusPropertiesKHR {
VkStructureType sType;
void* pNext;
VkBool32 queryResultStatusSupport;
} VkQueueFamilyQueryResultStatusPropertiesKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
queryResultStatusSupport
reportsVK_TRUE
if query typeVK_QUERY_TYPE_RESULT_STATUS_ONLY_KHR
and use ofVK_QUERY_RESULT_WITH_STATUS_BIT_KHR
are supported.
If this structure is included in the pNext
chain of the
VkQueueFamilyProperties2 structure passed to
vkGetPhysicalDeviceQueueFamilyProperties2, then it is filled with
information about whether result status
queries are supported by the specified queue family.
To enumerate the performance query counters available on a queue family of a physical device, call:
// Provided by VK_KHR_performance_query
VkResult vkEnumeratePhysicalDeviceQueueFamilyPerformanceQueryCountersKHR(
VkPhysicalDevice physicalDevice,
uint32_t queueFamilyIndex,
uint32_t* pCounterCount,
VkPerformanceCounterKHR* pCounters,
VkPerformanceCounterDescriptionKHR* pCounterDescriptions);
-
physicalDevice
is the handle to the physical device whose queue family performance query counter properties will be queried. -
queueFamilyIndex
is the index into the queue family of the physical device we want to get properties for. -
pCounterCount
is a pointer to an integer related to the number of counters available or queried, as described below. -
pCounters
is eitherNULL
or a pointer to an array of VkPerformanceCounterKHR structures. -
pCounterDescriptions
is eitherNULL
or a pointer to an array of VkPerformanceCounterDescriptionKHR structures.
If pCounters
is NULL
and pCounterDescriptions
is NULL
, then
the number of counters available is returned in pCounterCount
.
Otherwise, pCounterCount
must point to a variable set by the user to
the number of elements in the pCounters
, pCounterDescriptions
,
or both arrays and on return the variable is overwritten with the number of
structures actually written out.
If pCounterCount
is less than the number of counters available, at
most pCounterCount
structures will be written, and VK_INCOMPLETE
will be returned instead of VK_SUCCESS
, to indicate that not all the
available counters were returned.
The VkPerformanceCounterKHR
structure is defined as:
// Provided by VK_KHR_performance_query
typedef struct VkPerformanceCounterKHR {
VkStructureType sType;
void* pNext;
VkPerformanceCounterUnitKHR unit;
VkPerformanceCounterScopeKHR scope;
VkPerformanceCounterStorageKHR storage;
uint8_t uuid[VK_UUID_SIZE];
} VkPerformanceCounterKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
unit
is a VkPerformanceCounterUnitKHR specifying the unit that the counter data will record. -
scope
is a VkPerformanceCounterScopeKHR specifying the scope that the counter belongs to. -
storage
is a VkPerformanceCounterStorageKHR specifying the storage type that the counter’s data uses. -
uuid
is an array of sizeVK_UUID_SIZE
, containing 8-bit values that represent a universally unique identifier for the counter of the physical device.
Performance counters have an associated unit. This unit describes how to interpret the performance counter result.
The performance counter unit types which may be returned in
VkPerformanceCounterKHR::unit
are:
// Provided by VK_KHR_performance_query
typedef enum VkPerformanceCounterUnitKHR {
VK_PERFORMANCE_COUNTER_UNIT_GENERIC_KHR = 0,
VK_PERFORMANCE_COUNTER_UNIT_PERCENTAGE_KHR = 1,
VK_PERFORMANCE_COUNTER_UNIT_NANOSECONDS_KHR = 2,
VK_PERFORMANCE_COUNTER_UNIT_BYTES_KHR = 3,
VK_PERFORMANCE_COUNTER_UNIT_BYTES_PER_SECOND_KHR = 4,
VK_PERFORMANCE_COUNTER_UNIT_KELVIN_KHR = 5,
VK_PERFORMANCE_COUNTER_UNIT_WATTS_KHR = 6,
VK_PERFORMANCE_COUNTER_UNIT_VOLTS_KHR = 7,
VK_PERFORMANCE_COUNTER_UNIT_AMPS_KHR = 8,
VK_PERFORMANCE_COUNTER_UNIT_HERTZ_KHR = 9,
VK_PERFORMANCE_COUNTER_UNIT_CYCLES_KHR = 10,
} VkPerformanceCounterUnitKHR;
-
VK_PERFORMANCE_COUNTER_UNIT_GENERIC_KHR
- the performance counter unit is a generic data point. -
VK_PERFORMANCE_COUNTER_UNIT_PERCENTAGE_KHR
- the performance counter unit is a percentage (%). -
VK_PERFORMANCE_COUNTER_UNIT_NANOSECONDS_KHR
- the performance counter unit is a value of nanoseconds (ns). -
VK_PERFORMANCE_COUNTER_UNIT_BYTES_KHR
- the performance counter unit is a value of bytes. -
VK_PERFORMANCE_COUNTER_UNIT_BYTES_PER_SECOND_KHR
- the performance counter unit is a value of bytes/s. -
VK_PERFORMANCE_COUNTER_UNIT_KELVIN_KHR
- the performance counter unit is a temperature reported in Kelvin. -
VK_PERFORMANCE_COUNTER_UNIT_WATTS_KHR
- the performance counter unit is a value of watts (W). -
VK_PERFORMANCE_COUNTER_UNIT_VOLTS_KHR
- the performance counter unit is a value of volts (V). -
VK_PERFORMANCE_COUNTER_UNIT_AMPS_KHR
- the performance counter unit is a value of amps (A). -
VK_PERFORMANCE_COUNTER_UNIT_HERTZ_KHR
- the performance counter unit is a value of hertz (Hz). -
VK_PERFORMANCE_COUNTER_UNIT_CYCLES_KHR
- the performance counter unit is a value of cycles.
Performance counters have an associated scope. This scope describes the granularity of a performance counter.
The performance counter scope types which may be returned in
VkPerformanceCounterKHR::scope
are:
// Provided by VK_KHR_performance_query
typedef enum VkPerformanceCounterScopeKHR {
VK_PERFORMANCE_COUNTER_SCOPE_COMMAND_BUFFER_KHR = 0,
VK_PERFORMANCE_COUNTER_SCOPE_RENDER_PASS_KHR = 1,
VK_PERFORMANCE_COUNTER_SCOPE_COMMAND_KHR = 2,
VK_QUERY_SCOPE_COMMAND_BUFFER_KHR = VK_PERFORMANCE_COUNTER_SCOPE_COMMAND_BUFFER_KHR,
VK_QUERY_SCOPE_RENDER_PASS_KHR = VK_PERFORMANCE_COUNTER_SCOPE_RENDER_PASS_KHR,
VK_QUERY_SCOPE_COMMAND_KHR = VK_PERFORMANCE_COUNTER_SCOPE_COMMAND_KHR,
} VkPerformanceCounterScopeKHR;
-
VK_PERFORMANCE_COUNTER_SCOPE_COMMAND_BUFFER_KHR
- the performance counter scope is a single complete command buffer. -
VK_PERFORMANCE_COUNTER_SCOPE_RENDER_PASS_KHR
- the performance counter scope is zero or more complete render passes. The performance query containing the performance counter must begin and end outside a render pass instance. -
VK_PERFORMANCE_COUNTER_SCOPE_COMMAND_KHR
- the performance counter scope is zero or more commands.
Performance counters have an associated storage. This storage describes the payload of a counter result.
The performance counter storage types which may be returned in
VkPerformanceCounterKHR::storage
are:
// Provided by VK_KHR_performance_query
typedef enum VkPerformanceCounterStorageKHR {
VK_PERFORMANCE_COUNTER_STORAGE_INT32_KHR = 0,
VK_PERFORMANCE_COUNTER_STORAGE_INT64_KHR = 1,
VK_PERFORMANCE_COUNTER_STORAGE_UINT32_KHR = 2,
VK_PERFORMANCE_COUNTER_STORAGE_UINT64_KHR = 3,
VK_PERFORMANCE_COUNTER_STORAGE_FLOAT32_KHR = 4,
VK_PERFORMANCE_COUNTER_STORAGE_FLOAT64_KHR = 5,
} VkPerformanceCounterStorageKHR;
-
VK_PERFORMANCE_COUNTER_STORAGE_INT32_KHR
- the performance counter storage is a 32-bit signed integer. -
VK_PERFORMANCE_COUNTER_STORAGE_INT64_KHR
- the performance counter storage is a 64-bit signed integer. -
VK_PERFORMANCE_COUNTER_STORAGE_UINT32_KHR
- the performance counter storage is a 32-bit unsigned integer. -
VK_PERFORMANCE_COUNTER_STORAGE_UINT64_KHR
- the performance counter storage is a 64-bit unsigned integer. -
VK_PERFORMANCE_COUNTER_STORAGE_FLOAT32_KHR
- the performance counter storage is a 32-bit floating-point. -
VK_PERFORMANCE_COUNTER_STORAGE_FLOAT64_KHR
- the performance counter storage is a 64-bit floating-point.
The VkPerformanceCounterDescriptionKHR
structure is defined as:
// Provided by VK_KHR_performance_query
typedef struct VkPerformanceCounterDescriptionKHR {
VkStructureType sType;
void* pNext;
VkPerformanceCounterDescriptionFlagsKHR flags;
char name[VK_MAX_DESCRIPTION_SIZE];
char category[VK_MAX_DESCRIPTION_SIZE];
char description[VK_MAX_DESCRIPTION_SIZE];
} VkPerformanceCounterDescriptionKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
flags
is a bitmask of VkPerformanceCounterDescriptionFlagBitsKHR indicating the usage behavior for the counter. -
name
is an array of sizeVK_MAX_DESCRIPTION_SIZE
, containing a null-terminated UTF-8 string specifying the name of the counter. -
category
is an array of sizeVK_MAX_DESCRIPTION_SIZE
, containing a null-terminated UTF-8 string specifying the category of the counter. -
description
is an array of sizeVK_MAX_DESCRIPTION_SIZE
, containing a null-terminated UTF-8 string specifying the description of the counter.
Bits which can be set in
VkPerformanceCounterDescriptionKHR::flags
, specifying usage
behavior of a performance counter, are:
// Provided by VK_KHR_performance_query
typedef enum VkPerformanceCounterDescriptionFlagBitsKHR {
VK_PERFORMANCE_COUNTER_DESCRIPTION_PERFORMANCE_IMPACTING_BIT_KHR = 0x00000001,
VK_PERFORMANCE_COUNTER_DESCRIPTION_CONCURRENTLY_IMPACTED_BIT_KHR = 0x00000002,
VK_PERFORMANCE_COUNTER_DESCRIPTION_PERFORMANCE_IMPACTING_KHR = VK_PERFORMANCE_COUNTER_DESCRIPTION_PERFORMANCE_IMPACTING_BIT_KHR,
VK_PERFORMANCE_COUNTER_DESCRIPTION_CONCURRENTLY_IMPACTED_KHR = VK_PERFORMANCE_COUNTER_DESCRIPTION_CONCURRENTLY_IMPACTED_BIT_KHR,
} VkPerformanceCounterDescriptionFlagBitsKHR;
-
VK_PERFORMANCE_COUNTER_DESCRIPTION_PERFORMANCE_IMPACTING_BIT_KHR
specifies that recording the counter may have a noticeable performance impact. -
VK_PERFORMANCE_COUNTER_DESCRIPTION_CONCURRENTLY_IMPACTED_BIT_KHR
specifies that concurrently recording the counter while other submitted command buffers are running may impact the accuracy of the recording.
// Provided by VK_KHR_performance_query
typedef VkFlags VkPerformanceCounterDescriptionFlagsKHR;
VkPerformanceCounterDescriptionFlagsKHR is a bitmask type for setting a mask of zero or more VkPerformanceCounterDescriptionFlagBitsKHR.
5.2. Devices
Device objects represent logical connections to physical devices. Each device exposes a number of queue families each having one or more queues. All queues in a queue family support the same operations.
As described in Physical Devices, a Vulkan application will first query for all physical devices in a system. Each physical device can then be queried for its capabilities, including its queue and queue family properties. Once an acceptable physical device is identified, an application will create a corresponding logical device. The created logical device is then the primary interface to the physical device.
How to enumerate the physical devices in a system and query those physical devices for their queue family properties is described in the Physical Device Enumeration section above.
A single logical device can be created from multiple physical devices, if those physical devices belong to the same device group. A device group is a set of physical devices that support accessing each other’s memory and recording a single command buffer that can be executed on all the physical devices. Device groups are enumerated by calling vkEnumeratePhysicalDeviceGroups, and a logical device is created from a subset of the physical devices in a device group by passing the physical devices through VkDeviceGroupDeviceCreateInfo. For two physical devices to be in the same device group, they must support identical extensions, features, and properties.
Note
Physical devices in the same device group must be so similar because there
are no rules for how different features/properties would interact.
They must return the same values for nearly every invariant
|
To retrieve a list of the device groups present in the system, call:
// Provided by VK_VERSION_1_1
VkResult vkEnumeratePhysicalDeviceGroups(
VkInstance instance,
uint32_t* pPhysicalDeviceGroupCount,
VkPhysicalDeviceGroupProperties* pPhysicalDeviceGroupProperties);
or the equivalent command
// Provided by VK_KHR_device_group_creation
VkResult vkEnumeratePhysicalDeviceGroupsKHR(
VkInstance instance,
uint32_t* pPhysicalDeviceGroupCount,
VkPhysicalDeviceGroupProperties* pPhysicalDeviceGroupProperties);
-
instance
is a handle to a Vulkan instance previously created with vkCreateInstance. -
pPhysicalDeviceGroupCount
is a pointer to an integer related to the number of device groups available or queried, as described below. -
pPhysicalDeviceGroupProperties
is eitherNULL
or a pointer to an array of VkPhysicalDeviceGroupProperties structures.
If pPhysicalDeviceGroupProperties
is NULL
, then the number of device
groups available is returned in pPhysicalDeviceGroupCount
.
Otherwise, pPhysicalDeviceGroupCount
must point to a variable set by
the user to the number of elements in the
pPhysicalDeviceGroupProperties
array, and on return the variable is
overwritten with the number of structures actually written to
pPhysicalDeviceGroupProperties
.
If pPhysicalDeviceGroupCount
is less than the number of device groups
available, at most pPhysicalDeviceGroupCount
structures will be
written, and VK_INCOMPLETE
will be returned instead of
VK_SUCCESS
, to indicate that not all the available device groups were
returned.
Every physical device must be in exactly one device group.
The VkPhysicalDeviceGroupProperties
structure is defined as:
// Provided by VK_VERSION_1_1
typedef struct VkPhysicalDeviceGroupProperties {
VkStructureType sType;
void* pNext;
uint32_t physicalDeviceCount;
VkPhysicalDevice physicalDevices[VK_MAX_DEVICE_GROUP_SIZE];
VkBool32 subsetAllocation;
} VkPhysicalDeviceGroupProperties;
or the equivalent
// Provided by VK_KHR_device_group_creation
typedef VkPhysicalDeviceGroupProperties VkPhysicalDeviceGroupPropertiesKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
physicalDeviceCount
is the number of physical devices in the group. -
physicalDevices
is an array ofVK_MAX_DEVICE_GROUP_SIZE
VkPhysicalDevice handles representing all physical devices in the group. The firstphysicalDeviceCount
elements of the array will be valid. -
subsetAllocation
specifies whether logical devices created from the group support allocating device memory on a subset of devices, via thedeviceMask
member of the VkMemoryAllocateFlagsInfo. If this isVK_FALSE
, then all device memory allocations are made across all physical devices in the group. IfphysicalDeviceCount
is1
, thensubsetAllocation
must beVK_FALSE
.
VK_MAX_DEVICE_GROUP_SIZE
is the length of an array containing
VkPhysicalDevice handle values representing all physical devices in a
group, as returned in
VkPhysicalDeviceGroupProperties::physicalDevices
.
#define VK_MAX_DEVICE_GROUP_SIZE 32U
or the equivalent
#define VK_MAX_DEVICE_GROUP_SIZE_KHR VK_MAX_DEVICE_GROUP_SIZE
5.2.1. Device Creation
Logical devices are represented by VkDevice
handles:
// Provided by VK_VERSION_1_0
VK_DEFINE_HANDLE(VkDevice)
A logical device is created as a connection to a physical device. To create a logical device, call:
// Provided by VK_VERSION_1_0
VkResult vkCreateDevice(
VkPhysicalDevice physicalDevice,
const VkDeviceCreateInfo* pCreateInfo,
const VkAllocationCallbacks* pAllocator,
VkDevice* pDevice);
-
physicalDevice
must be one of the device handles returned from a call tovkEnumeratePhysicalDevices
(see Physical Device Enumeration). -
pCreateInfo
is a pointer to a VkDeviceCreateInfo structure containing information about how to create the device. -
pAllocator
controls host memory allocation as described in the Memory Allocation chapter. -
pDevice
is a pointer to a handle in which the created VkDevice is returned.
vkCreateDevice
verifies that extensions and features requested in the
ppEnabledExtensionNames
and pEnabledFeatures
members of
pCreateInfo
, respectively, are supported by the implementation.
If any requested extension is not supported, vkCreateDevice
must
return VK_ERROR_EXTENSION_NOT_PRESENT
.
If any requested feature is not supported, vkCreateDevice
must return
VK_ERROR_FEATURE_NOT_PRESENT
.
Support for extensions can be checked before creating a device by querying
vkEnumerateDeviceExtensionProperties.
Support for features can similarly be checked by querying
vkGetPhysicalDeviceFeatures.
After verifying and enabling the extensions the VkDevice
object is
created and returned to the application.
Multiple logical devices can be created from the same physical device.
Logical device creation may fail due to lack of device-specific resources
(in addition to other errors).
If that occurs, vkCreateDevice
will return
VK_ERROR_TOO_MANY_OBJECTS
.
The VkDeviceCreateInfo
structure is defined as:
// Provided by VK_VERSION_1_0
typedef struct VkDeviceCreateInfo {
VkStructureType sType;
const void* pNext;
VkDeviceCreateFlags flags;
uint32_t queueCreateInfoCount;
const VkDeviceQueueCreateInfo* pQueueCreateInfos;
uint32_t enabledLayerCount;
const char* const* ppEnabledLayerNames;
uint32_t enabledExtensionCount;
const char* const* ppEnabledExtensionNames;
const VkPhysicalDeviceFeatures* pEnabledFeatures;
} VkDeviceCreateInfo;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
flags
is reserved for future use. -
queueCreateInfoCount
is the unsigned integer size of thepQueueCreateInfos
array. Refer to the Queue Creation section below for further details. -
pQueueCreateInfos
is a pointer to an array of VkDeviceQueueCreateInfo structures describing the queues that are requested to be created along with the logical device. Refer to the Queue Creation section below for further details. -
enabledLayerCount
is deprecated and ignored. -
ppEnabledLayerNames
is deprecated and ignored. See Device Layer Deprecation. -
enabledExtensionCount
is the number of device extensions to enable. -
ppEnabledExtensionNames
is a pointer to an array ofenabledExtensionCount
null-terminated UTF-8 strings containing the names of extensions to enable for the created device. See the Extensions section for further details. -
pEnabledFeatures
isNULL
or a pointer to a VkPhysicalDeviceFeatures structure containing boolean indicators of all the features to be enabled. Refer to the Features section for further details.
// Provided by VK_VERSION_1_0
typedef VkFlags VkDeviceCreateFlags;
VkDeviceCreateFlags
is a bitmask type for setting a mask, but is
currently reserved for future use.
A logical device can be created that connects to one or more physical
devices by adding a VkDeviceGroupDeviceCreateInfo
structure to the
pNext
chain of VkDeviceCreateInfo.
The VkDeviceGroupDeviceCreateInfo
structure is defined as:
// Provided by VK_VERSION_1_1
typedef struct VkDeviceGroupDeviceCreateInfo {
VkStructureType sType;
const void* pNext;
uint32_t physicalDeviceCount;
const VkPhysicalDevice* pPhysicalDevices;
} VkDeviceGroupDeviceCreateInfo;
or the equivalent
// Provided by VK_KHR_device_group_creation
typedef VkDeviceGroupDeviceCreateInfo VkDeviceGroupDeviceCreateInfoKHR;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
physicalDeviceCount
is the number of elements in thepPhysicalDevices
array. -
pPhysicalDevices
is a pointer to an array of physical device handles belonging to the same device group.
The elements of the pPhysicalDevices
array are an ordered list of the
physical devices that the logical device represents.
These must be a subset of a single device group, and need not be in the
same order as they were enumerated.
The order of the physical devices in the pPhysicalDevices
array
determines the device index of each physical device, with element i
being assigned a device index of i.
Certain commands and structures refer to one or more physical devices by
using device indices or device masks formed using device indices.
A logical device created without using VkDeviceGroupDeviceCreateInfo
,
or with physicalDeviceCount
equal to zero, is equivalent to a
physicalDeviceCount
of one and pPhysicalDevices
pointing to the
physicalDevice
parameter to vkCreateDevice.
In particular, the device index of that physical device is zero.
To specify whether device memory allocation is allowed beyond the size
reported by VkPhysicalDeviceMemoryProperties, add a
VkDeviceMemoryOverallocationCreateInfoAMD structure to the pNext
chain of the VkDeviceCreateInfo structure.
If this structure is not specified, it is as if the
VK_MEMORY_OVERALLOCATION_BEHAVIOR_DEFAULT_AMD
value is used.
// Provided by VK_AMD_memory_overallocation_behavior
typedef struct VkDeviceMemoryOverallocationCreateInfoAMD {
VkStructureType sType;
const void* pNext;
VkMemoryOverallocationBehaviorAMD overallocationBehavior;
} VkDeviceMemoryOverallocationCreateInfoAMD;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
overallocationBehavior
is the desired overallocation behavior.
Possible values for
VkDeviceMemoryOverallocationCreateInfoAMD::overallocationBehavior
include:
// Provided by VK_AMD_memory_overallocation_behavior
typedef enum VkMemoryOverallocationBehaviorAMD {
VK_MEMORY_OVERALLOCATION_BEHAVIOR_DEFAULT_AMD = 0,
VK_MEMORY_OVERALLOCATION_BEHAVIOR_ALLOWED_AMD = 1,
VK_MEMORY_OVERALLOCATION_BEHAVIOR_DISALLOWED_AMD = 2,
} VkMemoryOverallocationBehaviorAMD;
-
VK_MEMORY_OVERALLOCATION_BEHAVIOR_DEFAULT_AMD
lets the implementation decide if overallocation is allowed. -
VK_MEMORY_OVERALLOCATION_BEHAVIOR_ALLOWED_AMD
specifies overallocation is allowed if platform permits. -
VK_MEMORY_OVERALLOCATION_BEHAVIOR_DISALLOWED_AMD
specifies the application is not allowed to allocate device memory beyond the heap sizes reported by VkPhysicalDeviceMemoryProperties. Allocations that are not explicitly made by the application within the scope of the Vulkan instance are not accounted for.
When using the Nsight™ Aftermath SDK, to configure how device crash
dumps are created, add a VkDeviceDiagnosticsConfigCreateInfoNV
structure to the pNext
chain of the VkDeviceCreateInfo
structure.
// Provided by VK_NV_device_diagnostics_config
typedef struct VkDeviceDiagnosticsConfigCreateInfoNV {
VkStructureType sType;
const void* pNext;
VkDeviceDiagnosticsConfigFlagsNV flags;
} VkDeviceDiagnosticsConfigCreateInfoNV;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
flags
is a bitmask of VkDeviceDiagnosticsConfigFlagBitsNV specifying additional parameters for configuring diagnostic tools.
Bits which can be set in
VkDeviceDiagnosticsConfigCreateInfoNV::flags
include:
// Provided by VK_NV_device_diagnostics_config
typedef enum VkDeviceDiagnosticsConfigFlagBitsNV {
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_SHADER_DEBUG_INFO_BIT_NV = 0x00000001,
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_RESOURCE_TRACKING_BIT_NV = 0x00000002,
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_AUTOMATIC_CHECKPOINTS_BIT_NV = 0x00000004,
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_SHADER_ERROR_REPORTING_BIT_NV = 0x00000008,
} VkDeviceDiagnosticsConfigFlagBitsNV;
-
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_SHADER_DEBUG_INFO_BIT_NV
enables the generation of debug information for shaders. -
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_RESOURCE_TRACKING_BIT_NV
enables driver side tracking of resources (images, buffers, etc.) used to augment the device fault information. -
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_AUTOMATIC_CHECKPOINTS_BIT_NV
enables automatic insertion of diagnostic checkpoints for draw calls, dispatches, trace rays, and copies. The CPU call stack at the time of the command will be associated as the marker data for the automatically inserted checkpoints. -
VK_DEVICE_DIAGNOSTICS_CONFIG_ENABLE_SHADER_ERROR_REPORTING_BIT_NV
enables shader error reporting.
// Provided by VK_NV_device_diagnostics_config
typedef VkFlags VkDeviceDiagnosticsConfigFlagsNV;
VkDeviceDiagnosticsConfigFlagsNV
is a bitmask type for setting a mask
of zero or more VkDeviceDiagnosticsConfigFlagBitsNV.
To register callbacks for underlying device memory events of type
VkDeviceMemoryReportEventTypeEXT, add one or multiple
VkDeviceDeviceMemoryReportCreateInfoEXT structures to the pNext
chain of the VkDeviceCreateInfo structure.
// Provided by VK_EXT_device_memory_report
typedef struct VkDeviceDeviceMemoryReportCreateInfoEXT {
VkStructureType sType;
const void* pNext;
VkDeviceMemoryReportFlagsEXT flags;
PFN_vkDeviceMemoryReportCallbackEXT pfnUserCallback;
void* pUserData;
} VkDeviceDeviceMemoryReportCreateInfoEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
flags
is 0 and reserved for future use. -
pfnUserCallback
is the application callback function to call. -
pUserData
is user data to be passed to the callback.
The callback may be called from multiple threads simultaneously.
The callback must be called only once by the implementation when a VkDeviceMemoryReportEventTypeEXT event occurs.
Note
The callback could be called from a background thread other than the thread calling the Vulkan commands. |
The prototype for the
VkDeviceDeviceMemoryReportCreateInfoEXT::pfnUserCallback
function implemented by the application is:
// Provided by VK_EXT_device_memory_report
typedef void (VKAPI_PTR *PFN_vkDeviceMemoryReportCallbackEXT)(
const VkDeviceMemoryReportCallbackDataEXT* pCallbackData,
void* pUserData);
-
pCallbackData
contains all the callback related data in the VkDeviceMemoryReportCallbackDataEXT structure. -
pUserData
is the user data provided when the VkDeviceDeviceMemoryReportCreateInfoEXT was created.
The callback must not make calls to any Vulkan commands.
The definition of VkDeviceMemoryReportCallbackDataEXT
is:
// Provided by VK_EXT_device_memory_report
typedef struct VkDeviceMemoryReportCallbackDataEXT {
VkStructureType sType;
void* pNext;
VkDeviceMemoryReportFlagsEXT flags;
VkDeviceMemoryReportEventTypeEXT type;
uint64_t memoryObjectId;
VkDeviceSize size;
VkObjectType objectType;
uint64_t objectHandle;
uint32_t heapIndex;
} VkDeviceMemoryReportCallbackDataEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
flags
is 0 and reserved for future use. -
type
is a VkDeviceMemoryReportEventTypeEXT type specifying the type of event reported in thisVkDeviceMemoryReportCallbackDataEXT
structure. -
memoryObjectId
is the unique id for the underlying memory object as described below. -
size
is the size of the memory object in bytes. Iftype
isVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATE_EXT
,VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_IMPORT_EXT
orVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATION_FAILED_EXT
,size
is a valid VkDeviceSize value. Otherwise,size
is undefined. -
objectType
is a VkObjectType value specifying the type of the object associated with this device memory report event. Iftype
isVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATE_EXT
,VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_FREE_EXT
,VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_IMPORT_EXT
,VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_UNIMPORT_EXT
orVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATION_FAILED_EXT
,objectType
is a valid VkObjectType enum. Otherwise,objectType
is undefined. -
objectHandle
is the object this device memory report event is attributed to. Iftype
isVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATE_EXT
,VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_FREE_EXT
,VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_IMPORT_EXT
orVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_UNIMPORT_EXT
,objectHandle
is a valid Vulkan handle of the type associated withobjectType
as defined in theVkObjectType
and Vulkan Handle Relationship table. Otherwise,objectHandle
is undefined. -
heapIndex
describes which memory heap this device memory allocation is made from. Iftype
isVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATE_EXT
orVK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATION_FAILED_EXT
,heapIndex
corresponds to one of the valid heaps from the VkPhysicalDeviceMemoryProperties structure. Otherwise,heapIndex
is undefined.
memoryObjectId
is used to avoid double-counting on the same memory
object.
If an internally-allocated device memory object or a VkDeviceMemory
cannot be exported, memoryObjectId
must be unique in the
VkDevice.
If an internally-allocated device memory object or a VkDeviceMemory
supports being exported, memoryObjectId
must be unique system wide.
If an internal device memory object or a VkDeviceMemory is backed by
an imported external memory object, memoryObjectId
must be unique
system wide.
Note
This structure should only be considered valid during the lifetime of the triggered callback. For |
// Provided by VK_EXT_device_memory_report
typedef VkFlags VkDeviceMemoryReportFlagsEXT;
VkDeviceMemoryReportFlagsEXT
is a bitmask type for setting a mask, but
is currently reserved for future use.
Possible values of VkDeviceMemoryReportCallbackDataEXT::type
,
specifying event types which cause the device driver to call the callback,
are:
// Provided by VK_EXT_device_memory_report
typedef enum VkDeviceMemoryReportEventTypeEXT {
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATE_EXT = 0,
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_FREE_EXT = 1,
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_IMPORT_EXT = 2,
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_UNIMPORT_EXT = 3,
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATION_FAILED_EXT = 4,
} VkDeviceMemoryReportEventTypeEXT;
-
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATE_EXT
specifies this event corresponds to the allocation of an internal device memory object or a VkDeviceMemory. -
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_FREE_EXT
specifies this event corresponds to the deallocation of an internally-allocated device memory object or a VkDeviceMemory. -
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_IMPORT_EXT
specifies this event corresponds to the import of an external memory object. -
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_UNIMPORT_EXT
specifies this event is the release of an imported external memory object. -
VK_DEVICE_MEMORY_REPORT_EVENT_TYPE_ALLOCATION_FAILED_EXT
specifies this event corresponds to the failed allocation of an internal device memory object or a VkDeviceMemory.
To reserve private data storage slots, add a
VkDevicePrivateDataCreateInfo structure to the pNext
chain of
the VkDeviceCreateInfo structure.
Reserving slots in this manner is not strictly necessary, but doing so may
improve performance.
// Provided by VK_VERSION_1_3
typedef struct VkDevicePrivateDataCreateInfo {
VkStructureType sType;
const void* pNext;
uint32_t privateDataSlotRequestCount;
} VkDevicePrivateDataCreateInfo;
or the equivalent
// Provided by VK_EXT_private_data
typedef VkDevicePrivateDataCreateInfo VkDevicePrivateDataCreateInfoEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
privateDataSlotRequestCount
is the amount of slots to reserve.
5.2.2. Device Use
The following is a high-level list of VkDevice
uses along with
references on where to find more information:
-
Creation of queues. See the Queues section below for further details.
-
Creation and tracking of various synchronization constructs. See Synchronization and Cache Control for further details.
-
Allocating, freeing, and managing memory. See Memory Allocation and Resource Creation for further details.
-
Creation and destruction of command buffers and command buffer pools. See Command Buffers for further details.
-
Creation, destruction, and management of graphics state. See Pipelines and Resource Descriptors, among others, for further details.
5.2.3. Lost Device
A logical device may become lost for a number of implementation-specific reasons, indicating that pending and future command execution may fail and cause resources and backing memory to become undefined.
Note
Typical reasons for device loss will include things like execution timing out (to prevent denial of service), power management events, platform resource management, implementation errors. Applications not adhering to valid usage may also result in device loss being reported, however this is not guaranteed. Even if device loss is reported, the system may be in an unrecoverable state, and further usage of the API is still considered invalid. |
When this happens, certain commands will return VK_ERROR_DEVICE_LOST
.
After any such event, the logical device is considered lost.
It is not possible to reset the logical device to a non-lost state, however
the lost state is specific to a logical device (VkDevice
), and the
corresponding physical device (VkPhysicalDevice
) may be otherwise
unaffected.
In some cases, the physical device may also be lost, and attempting to
create a new logical device will fail, returning VK_ERROR_DEVICE_LOST
.
This is usually indicative of a problem with the underlying implementation,
or its connection to the host.
If the physical device has not been lost, and a new logical device is
successfully created from that physical device, it must be in the non-lost
state.
Note
Whilst logical device loss may be recoverable, in the case of physical device loss, it is unlikely that an application will be able to recover unless additional, unaffected physical devices exist on the system. The error is largely informational and intended only to inform the user that a platform issue has occurred, and should be investigated further. For example, underlying hardware may have developed a fault or become physically disconnected from the rest of the system. In many cases, physical device loss may cause other more serious issues such as the operating system crashing; in which case it may not be reported via the Vulkan API. |
When a device is lost, its child objects are not implicitly destroyed and their handles are still valid. Those objects must still be destroyed before their parents or the device can be destroyed (see the Object Lifetime section). The host address space corresponding to device memory mapped using vkMapMemory is still valid, and host memory accesses to these mapped regions are still valid, but the contents are undefined. It is still legal to call any API command on the device and child objects.
Once a device is lost, command execution may fail, and certain commands
that return a VkResult may return VK_ERROR_DEVICE_LOST
.
These commands can be identified by the inclusion of
VK_ERROR_DEVICE_LOST
in the Return Codes section for each command.
Commands that do not allow runtime errors must still operate correctly for
valid usage and, if applicable, return valid data.
Commands that wait indefinitely for device execution (namely
vkDeviceWaitIdle, vkQueueWaitIdle, vkWaitForFences
or vkAcquireNextImageKHR
with a maximum timeout
, and vkGetQueryPoolResults with the
VK_QUERY_RESULT_WAIT_BIT
bit set in flags
) must return in
finite time even in the case of a lost device, and return either
VK_SUCCESS
or VK_ERROR_DEVICE_LOST
.
For any command that may return VK_ERROR_DEVICE_LOST
, for the purpose
of determining whether a command buffer is in the
pending state, or whether resources are
considered in-use by the device, a return value of
VK_ERROR_DEVICE_LOST
is equivalent to VK_SUCCESS
.
The content of any external memory objects that have been exported from or
imported to a lost device become undefined.
Objects on other logical devices or in other APIs which are associated with
the same underlying memory resource as the external memory objects on the
lost device are unaffected other than their content becoming undefined.
The layout of subresources of images on other logical devices that are bound
to VkDeviceMemory
objects associated with the same underlying memory
resources as external memory objects on the lost device becomes
VK_IMAGE_LAYOUT_UNDEFINED
.
The state of VkSemaphore
objects on other logical devices created by
importing a semaphore payload with
temporary permanence which was exported from the lost device is undefined.
The state of VkSemaphore
objects on other logical devices that
permanently share a semaphore payload with a VkSemaphore
object on the
lost device is undefined, and remains undefined following any subsequent
signal operations.
Implementations must ensure pending and subsequently submitted wait
operations on such semaphores behave as defined in
Semaphore State Requirements For
Wait Operations for external semaphores not in a valid state for a wait
operation.
editing-note
TODO (piman) - I do not think we are very clear about what “in-use by the device” means. |
5.2.4. Device Destruction
To destroy a device, call:
// Provided by VK_VERSION_1_0
void vkDestroyDevice(
VkDevice device,
const VkAllocationCallbacks* pAllocator);
-
device
is the logical device to destroy. -
pAllocator
controls host memory allocation as described in the Memory Allocation chapter.
To ensure that no work is active on the device, vkDeviceWaitIdle can
be used to gate the destruction of the device.
Prior to destroying a device, an application is responsible for
destroying/freeing any Vulkan objects that were created using that device as
the first parameter of the corresponding vkCreate*
or
vkAllocate*
command.
Note
The lifetime of each of these objects is bound by the lifetime of the
|
5.3. Queues
5.3.1. Queue Family Properties
As discussed in the Physical Device Enumeration section above, the vkGetPhysicalDeviceQueueFamilyProperties command is used to retrieve details about the queue families and queues supported by a device.
Each index in the pQueueFamilyProperties
array returned by
vkGetPhysicalDeviceQueueFamilyProperties describes a unique queue
family on that physical device.
These indices are used when creating queues, and they correspond directly
with the queueFamilyIndex
that is passed to the vkCreateDevice
command via the VkDeviceQueueCreateInfo structure as described in the
Queue Creation section below.
Grouping of queue families within a physical device is implementation-dependent.
Note
The general expectation is that a physical device groups all queues of matching capabilities into a single family. However, while implementations should do this, it is possible that a physical device may return two separate queue families with the same capabilities. |
Once an application has identified a physical device with the queue(s) that it desires to use, it will create those queues in conjunction with a logical device. This is described in the following section.
5.3.2. Queue Creation
Creating a logical device also creates the queues associated with that
device.
The queues to create are described by a set of VkDeviceQueueCreateInfo
structures that are passed to vkCreateDevice in
pQueueCreateInfos
.
Queues are represented by VkQueue
handles:
// Provided by VK_VERSION_1_0
VK_DEFINE_HANDLE(VkQueue)
The VkDeviceQueueCreateInfo
structure is defined as:
// Provided by VK_VERSION_1_0
typedef struct VkDeviceQueueCreateInfo {
VkStructureType sType;
const void* pNext;
VkDeviceQueueCreateFlags flags;
uint32_t queueFamilyIndex;
uint32_t queueCount;
const float* pQueuePriorities;
} VkDeviceQueueCreateInfo;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
flags
is a bitmask indicating behavior of the queues. -
queueFamilyIndex
is an unsigned integer indicating the index of the queue family in which to create the queues on this device. This index corresponds to the index of an element of thepQueueFamilyProperties
array that was returned byvkGetPhysicalDeviceQueueFamilyProperties
. -
queueCount
is an unsigned integer specifying the number of queues to create in the queue family indicated byqueueFamilyIndex
, and with the behavior specified byflags
. -
pQueuePriorities
is a pointer to an array ofqueueCount
normalized floating point values, specifying priorities of work that will be submitted to each created queue. See Queue Priority for more information.
Bits which can be set in VkDeviceQueueCreateInfo::flags
,
specifying usage behavior of a queue, are:
// Provided by VK_VERSION_1_1
typedef enum VkDeviceQueueCreateFlagBits {
// Provided by VK_VERSION_1_1
VK_DEVICE_QUEUE_CREATE_PROTECTED_BIT = 0x00000001,
} VkDeviceQueueCreateFlagBits;
-
VK_DEVICE_QUEUE_CREATE_PROTECTED_BIT
specifies that the device queue is a protected-capable queue.
// Provided by VK_VERSION_1_0
typedef VkFlags VkDeviceQueueCreateFlags;
VkDeviceQueueCreateFlags
is a bitmask type for setting a mask of zero
or more VkDeviceQueueCreateFlagBits.
Queues can be created with a system-wide priority by adding a
VkDeviceQueueGlobalPriorityCreateInfoKHR
structure to the pNext
chain of VkDeviceQueueCreateInfo.
The VkDeviceQueueGlobalPriorityCreateInfoKHR
structure is defined as:
// Provided by VK_KHR_global_priority
typedef struct VkDeviceQueueGlobalPriorityCreateInfoKHR {
VkStructureType sType;
const void* pNext;
VkQueueGlobalPriorityKHR globalPriority;
} VkDeviceQueueGlobalPriorityCreateInfoKHR;
or the equivalent
// Provided by VK_EXT_global_priority
typedef VkDeviceQueueGlobalPriorityCreateInfoKHR VkDeviceQueueGlobalPriorityCreateInfoEXT;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. -
globalPriority
is the system-wide priority associated to these queues as specified by VkQueueGlobalPriorityEXT
Queues created without specifying
VkDeviceQueueGlobalPriorityCreateInfoKHR
will default to
VK_QUEUE_GLOBAL_PRIORITY_MEDIUM_KHR
.
Possible values of
VkDeviceQueueGlobalPriorityCreateInfoKHR::globalPriority
,
specifying a system-wide priority level are:
// Provided by VK_KHR_global_priority
typedef enum VkQueueGlobalPriorityKHR {
VK_QUEUE_GLOBAL_PRIORITY_LOW_KHR = 128,
VK_QUEUE_GLOBAL_PRIORITY_MEDIUM_KHR = 256,
VK_QUEUE_GLOBAL_PRIORITY_HIGH_KHR = 512,
VK_QUEUE_GLOBAL_PRIORITY_REALTIME_KHR = 1024,
VK_QUEUE_GLOBAL_PRIORITY_LOW_EXT = VK_QUEUE_GLOBAL_PRIORITY_LOW_KHR,
VK_QUEUE_GLOBAL_PRIORITY_MEDIUM_EXT = VK_QUEUE_GLOBAL_PRIORITY_MEDIUM_KHR,
VK_QUEUE_GLOBAL_PRIORITY_HIGH_EXT = VK_QUEUE_GLOBAL_PRIORITY_HIGH_KHR,
VK_QUEUE_GLOBAL_PRIORITY_REALTIME_EXT = VK_QUEUE_GLOBAL_PRIORITY_REALTIME_KHR,
} VkQueueGlobalPriorityKHR;
or the equivalent
// Provided by VK_EXT_global_priority
typedef VkQueueGlobalPriorityKHR VkQueueGlobalPriorityEXT;
Priority values are sorted in ascending order. A comparison operation on the enum values can be used to determine the priority order.
-
VK_QUEUE_GLOBAL_PRIORITY_LOW_KHR
is below the system default. Useful for non-interactive tasks. -
VK_QUEUE_GLOBAL_PRIORITY_MEDIUM_KHR
is the system default priority. -
VK_QUEUE_GLOBAL_PRIORITY_HIGH_KHR
is above the system default. -
VK_QUEUE_GLOBAL_PRIORITY_REALTIME_KHR
is the highest priority. Useful for critical tasks.
Queues with higher system priority may be allotted more processing time than queues with lower priority. An implementation may allow a higher-priority queue to starve a lower-priority queue until the higher-priority queue has no further commands to execute.
Priorities imply no ordering or scheduling constraints.
No specific guarantees are made about higher priority queues receiving more processing time or better quality of service than lower priority queues.
The global priority level of a queue takes precedence over the per-process
queue priority (VkDeviceQueueCreateInfo::pQueuePriorities
).
Abuse of this feature may result in starving the rest of the system of
implementation resources.
Therefore, the driver implementation may deny requests to acquire a
priority above the default priority
(VK_QUEUE_GLOBAL_PRIORITY_MEDIUM_KHR
) if the caller does not have
sufficient privileges.
In this scenario VK_ERROR_NOT_PERMITTED_KHR
is returned.
The driver implementation may fail the queue allocation request if
resources required to complete the operation have been exhausted (either by
the same process or a different process).
In this scenario VK_ERROR_INITIALIZATION_FAILED
is returned.
If the globalPriorityQuery
feature
is enabled and the requested global priority is not reported via
VkQueueFamilyGlobalPriorityPropertiesKHR, the driver implementation
must fail the queue creation.
In this scenario, VK_ERROR_INITIALIZATION_FAILED
is returned.
To retrieve a handle to a VkQueue object, call:
// Provided by VK_VERSION_1_0
void vkGetDeviceQueue(
VkDevice device,
uint32_t queueFamilyIndex,
uint32_t queueIndex,
VkQueue* pQueue);
-
device
is the logical device that owns the queue. -
queueFamilyIndex
is the index of the queue family to which the queue belongs. -
queueIndex
is the index within this queue family of the queue to retrieve. -
pQueue
is a pointer to a VkQueue object that will be filled with the handle for the requested queue.
vkGetDeviceQueue
must only be used to get queues that were created
with the flags
parameter of VkDeviceQueueCreateInfo set to zero.
To get queues that were created with a non-zero flags
parameter use
vkGetDeviceQueue2.
To retrieve a handle to a VkQueue object with specific VkDeviceQueueCreateFlags creation flags, call:
// Provided by VK_VERSION_1_1
void vkGetDeviceQueue2(
VkDevice device,
const VkDeviceQueueInfo2* pQueueInfo,
VkQueue* pQueue);
-
device
is the logical device that owns the queue. -
pQueueInfo
is a pointer to a VkDeviceQueueInfo2 structure, describing parameters of the device queue to be retrieved. -
pQueue
is a pointer to a VkQueue object that will be filled with the handle for the requested queue.
The VkDeviceQueueInfo2
structure is defined as:
// Provided by VK_VERSION_1_1
typedef struct VkDeviceQueueInfo2 {
VkStructureType sType;
const void* pNext;
VkDeviceQueueCreateFlags flags;
uint32_t queueFamilyIndex;
uint32_t queueIndex;
} VkDeviceQueueInfo2;
-
sType
is a VkStructureType value identifying this structure. -
pNext
isNULL
or a pointer to a structure extending this structure. ThepNext
chain ofVkDeviceQueueInfo2
can be used to provide additional device queue parameters tovkGetDeviceQueue2
. -
flags
is a VkDeviceQueueCreateFlags value indicating the flags used to create the device queue. -
queueFamilyIndex
is the index of the queue family to which the queue belongs. -
queueIndex
is the index of the queue to retrieve from within the set of queues that share both the queue family and flags specified.
The queue returned by vkGetDeviceQueue2
must have the same
flags
value from this structure as that used at device creation time
in a VkDeviceQueueCreateInfo structure.
Note
Normally, if you create both protected-capable and non-protected-capable
queues with the same family, they are treated as separate lists of queues
and For such divergent implementations, the maximum value of Such implementations will return This behaviour will not be observed on any driver that has passed Vulkan
conformance test suite version 1.3.3.0, or any subsequent version.
This information can be found by querying
|
5.3.3. Queue Family Index
The queue family index is used in multiple places in Vulkan in order to tie operations to a specific family of queues.
When retrieving a handle to the queue via vkGetDeviceQueue
, the queue
family index is used to select which queue family to retrieve the
VkQueue
handle from as described in the previous section.
When creating a VkCommandPool
object (see
Command Pools), a queue family index is specified
in the VkCommandPoolCreateInfo structure.
Command buffers from this pool can only be submitted on queues
corresponding to this queue family.
When creating VkImage
(see Images) and
VkBuffer
(see Buffers) resources, a set of queue
families is included in the VkImageCreateInfo and
VkBufferCreateInfo structures to specify the queue families that can
access the resource.
When inserting a VkBufferMemoryBarrier or VkImageMemoryBarrier (see Pipeline Barriers), a source and destination queue family index is specified to allow the ownership of a buffer or image to be transferred from one queue family to another. See the Resource Sharing section for details.
5.3.4. Queue Priority
Each queue is assigned a priority, as set in the VkDeviceQueueCreateInfo structures when creating the device. The priority of each queue is a normalized floating point value between 0.0 and 1.0, which is then translated to a discrete priority level by the implementation. Higher values indicate a higher priority, with 0.0 being the lowest priority and 1.0 being the highest.
Within the same device, queues with higher priority may be allotted more processing time than queues with lower priority. The implementation makes no guarantees with regards to ordering or scheduling among queues with the same priority, other than the constraints defined by any explicit synchronization primitives. The implementation makes no guarantees with regards to queues across different devices.
An implementation may allow a higher-priority queue to starve a
lower-priority queue on the same VkDevice
until the higher-priority
queue has no further commands to execute.
The relationship of queue priorities must not cause queues on one
VkDevice
to starve queues on another VkDevice
.
No specific guarantees are made about higher priority queues receiving more processing time or better quality of service than lower priority queues.
5.3.5. Queue Submission
Work is submitted to a queue via queue submission commands such as vkQueueSubmit2 or vkQueueSubmit. Queue submission commands define a set of queue operations to be executed by the underlying physical device, including synchronization with semaphores and fences.
Submission commands take as parameters a target queue, zero or more batches of work, and an optional fence to signal upon completion. Each batch consists of three distinct parts:
-
Zero or more semaphores to wait on before execution of the rest of the batch.
-
If present, these describe a semaphore wait operation.
-
-
Zero or more work items to execute.
-
If present, these describe a queue operation matching the work described.
-
-
Zero or more semaphores to signal upon completion of the work items.
-
If present, these describe a semaphore signal operation.
-
If a fence is present in a queue submission, it describes a fence signal operation.
All work described by a queue submission command must be submitted to the queue before the command returns.
Sparse Memory Binding
In Vulkan it is possible to sparsely bind memory to buffers and images as
described in the Sparse Resource chapter.
Sparse memory binding is a queue operation.
A queue whose flags include the VK_QUEUE_SPARSE_BINDING_BIT
must be
able to support the mapping of a virtual address to a physical address on
the device.
This causes an update to the page table mappings on the device.
This update must be synchronized on a queue to avoid corrupting page table
mappings during execution of graphics commands.
By binding the sparse memory resources on queues, all commands that are
dependent on the updated bindings are synchronized to only execute after the
binding is updated.
See the Synchronization and Cache Control chapter for
how this synchronization is accomplished.