Vulkan-Docs/doc/specs/vulkan/chapters/sparsemem.txt

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// Copyright (c) 2015-2017 Khronos Group. This work is licensed under a
// Creative Commons Attribution 4.0 International License; see
// http://creativecommons.org/licenses/by/4.0/
[[sparsememory]]
= Sparse Resources
As documented in <<resources-association,Resource Memory Association>>,
sname:VkBuffer and sname:VkImage resources in Vulkan must: be bound
completely and contiguously to a single sname:VkDeviceMemory object.
This binding must: be done before the resource is used, and the binding is
immutable for the lifetime of the resource.
_Sparse resources_ relax these restrictions and provide these additional
features:
* Sparse resources can: be bound non-contiguously to one or more
sname:VkDeviceMemory allocations.
* Sparse resources can: be re-bound to different memory allocations over
the lifetime of the resource.
* Sparse resources can: have descriptors generated and used orthogonally
with memory binding commands.
[[sparsememory-sparseresourcefeatures]]
== Sparse Resource Features
Sparse resources have several features that must: be enabled explicitly at
resource creation time.
The features are enabled by including bits in the pname:flags parameter of
slink:VkImageCreateInfo or slink:VkBufferCreateInfo.
Each feature also has one or more corresponding feature enables specified in
slink:VkPhysicalDeviceFeatures.
* <<features-features-sparseBinding,Sparse binding>> is the base feature,
and provides the following capabilities:
** Resources can: be bound at some defined (sparse block) granularity.
** The entire resource must: be bound to memory before use regardless of
regions actually accessed.
** No specific mapping of image region to memory offset is defined, i.e.
the location that each texel corresponds to in memory is
implementation-dependent.
** Sparse buffers have a well-defined mapping of buffer range to memory
range, where an offset into a range of the buffer that is bound to a
single contiguous range of memory corresponds to an identical offset
within that range of memory.
** Requested via the ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT and
ename:VK_BUFFER_CREATE_SPARSE_BINDING_BIT bits.
** A sparse image created using ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT
(but not ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT) supports all
formats that non-sparse usage supports, and supports both
ename:VK_IMAGE_TILING_OPTIMAL and ename:VK_IMAGE_TILING_LINEAR tiling.
* _Sparse Residency_ builds on (and requires) the pname:sparseBinding
feature.
It includes the following capabilities:
** Resources do not have to be completely bound to memory before use on
the device.
** Images have a prescribed sparse image block layout, allowing specific
rectangular regions of the image to be bound to specific offsets in
memory allocations.
** Consistency of access to unbound regions of the resource is defined by
the absence or presence of
sname:VkPhysicalDeviceSparseProperties::pname:residencyNonResidentStrict.
If this property is present, accesses to unbound regions of the
resource are well defined and behave as if the data bound is populated
with all zeros; writes are discarded.
When this property is absent, accesses are considered safe, but reads
will return undefined values.
** Requested via the ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT and
ename:VK_BUFFER_CREATE_SPARSE_RESIDENCY_BIT bits.
** [[features-features-sparseResidency]] Sparse residency support is
advertised on a finer grain via the following features:
+
*** <<features-features-sparseResidencyBuffer,pname:sparseResidencyBuffer>>:
Support for creating sname:VkBuffer objects with the
ename:VK_BUFFER_CREATE_SPARSE_RESIDENCY_BIT.
*** <<features-features-sparseResidencyImage2D,pname:sparseResidencyImage2D>>:
Support for creating 2D single-sampled sname:VkImage objects with
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
*** <<features-features-sparseResidencyImage3D,pname:sparseResidencyImage3D>>:
Support for creating 3D sname:VkImage objects with
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
*** <<features-features-sparseResidency2Samples,pname:sparseResidency2Samples>>:
Support for creating 2D sname:VkImage objects with 2 samples and
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
*** <<features-features-sparseResidency4Samples,pname:sparseResidency4Samples>>:
Support for creating 2D sname:VkImage objects with 4 samples and
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
*** <<features-features-sparseResidency8Samples,pname:sparseResidency8Samples>>:
Support for creating 2D sname:VkImage objects with 8 samples and
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
*** <<features-features-sparseResidency16Samples,pname:sparseResidency16Samples>>:
Support for creating 2D sname:VkImage objects with 16 samples and
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
+
Implementations supporting pname:sparseResidencyImage2D are only required:
to support sparse 2D, single-sampled images.
Support is not required: for sparse 3D and MSAA images and is enabled via
pname:sparseResidencyImage3D, pname:sparseResidency2Samples,
pname:sparseResidency4Samples, pname:sparseResidency8Samples, and
pname:sparseResidency16Samples.
** A sparse image created using ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT
supports all non-compressed color formats with power-of-two element
size that non-sparse usage supports.
Additional formats may: also be supported and can: be queried via
flink:vkGetPhysicalDeviceSparseImageFormatProperties.
ename:VK_IMAGE_TILING_LINEAR tiling is not supported.
* <<features-features-sparseResidencyAliased,Sparse aliasing>> provides
the following capability that can: be enabled per resource:
+
Allows physical memory ranges to be shared between multiple locations in the
same sparse resource or between multiple sparse resources, with each binding
of a memory location observing a consistent interpretation of the memory
contents.
+
See <<sparsememory-sparse-memory-aliasing,Sparse Memory Aliasing>> for more
information.
[[sparsememory-fully-resident]]
== Sparse Buffers and Fully-Resident Images
Both sname:VkBuffer and sname:VkImage objects created with the
ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT or
ename:VK_BUFFER_CREATE_SPARSE_BINDING_BIT bits can: be thought of as a
linear region of address space.
In the sname:VkImage case if ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT is
not used, this linear region is entirely opaque, meaning that there is no
application-visible mapping between pixel location and memory offset.
Unless ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT or
ename:VK_BUFFER_CREATE_SPARSE_RESIDENCY_BIT are also used, the entire
resource must: be bound to one or more sname:VkDeviceMemory objects before
use.
=== Sparse Buffer and Fully-Resident Image Block Size
The sparse block size in bytes for sparse buffers and fully-resident images
is reported as sname:VkMemoryRequirements::pname:alignment.
pname:alignment represents both the memory alignment requirement and the
binding granularity (in bytes) for sparse resources.
[[sparsememory-partially-resident-buffers]]
== Sparse Partially-Resident Buffers
sname:VkBuffer objects created with the
ename:VK_BUFFER_CREATE_SPARSE_RESIDENCY_BIT bit allow the buffer to be made
only partially resident.
Partially resident sname:VkBuffer objects are allocated and bound
identically to sname:VkBuffer objects using only the
ename:VK_BUFFER_CREATE_SPARSE_BINDING_BIT feature.
The only difference is the ability for some regions of the buffer to be
unbound during device use.
[[sparsememory-partially-resident-images]]
== Sparse Partially-Resident Images
sname:VkImage objects created with the
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT bit allow specific rectangular
regions of the image called sparse image blocks to be bound to specific
ranges of memory.
This allows the application to manage residency at either image subresource
or sparse image block granularity.
Each image subresource (outside of the <<sparsememory-miptail,mip tail>>)
starts on a sparse block boundary and has dimensions that are integer
multiples of the corresponding dimensions of the sparse image block.
[NOTE]
.Note
====
Applications can: use these types of images to control LOD based on total
memory consumption.
If memory pressure becomes an issue the application can: unbind and disable
specific mipmap levels of images without having to recreate resources or
modify pixel data of unaffected levels.
The application can: also use this functionality to access subregions of the
image in a "`megatexture`" fashion.
The application can: create a large image and only populate the region of
the image that is currently being used in the scene.
====
[[sparsememory-accessing-unbound]]
=== Accessing Unbound Regions
The following member of sname:VkPhysicalDeviceSparseProperties affects how
data in unbound regions of sparse resources are handled by the
implementation:
* pname:residencyNonResidentStrict
If this property is not present, reads of unbound regions of the image will
return undefined values.
Both reads and writes are still considered _safe_ and will not affect other
resources or populated regions of the image.
If this property is present, all reads of unbound regions of the image will
behave as if the region was bound to memory populated with all zeros; writes
will be discarded.
Formatted accesses to unbound memory may: still alter some component values
in the natural way for those accesses, e.g. substituting a value of one for
alpha in formats that do not have an alpha component.
=======
Example: Reading the alpha component of an unbacked ename:VK_FORMAT_R8_UNORM
image will return a value of [eq]#1.0f#.
=======
See <<devsandqueues-physical-device-enumeration,Physical Device
Enumeration>> for instructions for retrieving physical device properties.
ifdef::implementation-guide[]
.Implementor's Note
****
For hardware that cannot: natively handle access to unbound regions of a
resource, the implementation may: allocate and bind memory to the unbound
regions.
Reads and writes to unbound regions will access the implementation-managed
memory instead of causing a hardware fault.
Given that reads of unbound regions are undefined in this scenario,
implementations may: use the same physical memory for unbound regions of
multiple resources within the same process.
****
endif::implementation-guide[]
[[sparsememory-miptail]]
=== Mip Tail Regions
Sparse images created using ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT
(without also using ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT) have no
specific mapping of image region or image subresource to memory offset
defined, so the entire image can: be thought of as a linear opaque address
region.
However, images created with ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT do
have a prescribed sparse image block layout, and hence each image
subresource must: start on a sparse block boundary.
Within each array layer, the set of mip levels that have a smaller size than
the sparse block size in bytes are grouped together into a _mip tail
region_.
If the ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT flag is present in
the pname:flags member of sname:VkSparseImageFormatProperties, for the
image's pname:format, then any mip level which has dimensions that are not
integer multiples of the corresponding dimensions of the sparse image block,
and all subsequent mip levels, are also included in the mip tail region.
The following member of sname:VkPhysicalDeviceSparseProperties may: affect
how the implementation places mip levels in the mip tail region:
* pname:residencyAlignedMipSize
Each mip tail region is bound to memory as an opaque region (i.e. must: be
bound using a slink:VkSparseImageOpaqueMemoryBindInfo structure) and may: be
of a size greater than or equal to the sparse block size in bytes.
This size is guaranteed to be an integer multiple of the sparse block size
in bytes.
An implementation may: choose to allow each array-layer's mip tail region to
be bound to memory independently or require that all array-layer's mip tail
regions be treated as one.
This is dictated by ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT in
sname:VkSparseImageMemoryRequirements::pname:flags.
The following diagrams depict how
ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT and
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT alter memory usage and
requirements.
image::images/sparseimage.svg[align="center", title="Sparse Image"]
In the absence of ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT and
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT, each array layer contains a
mip tail region containing pixel data for all mip levels smaller than the
sparse image block in any dimension.
Mip levels that are as large or larger than a sparse image block in all
dimensions can: be bound individually.
Right-edges and bottom-edges of each level are allowed to have partially
used sparse blocks.
Any bound partially-used-sparse-blocks must: still have their full sparse
block size in bytes allocated in memory.
image::images/sparseimage_singlemiptail.svg[align="center", title="Sparse Image with Single Mip Tail"]
When ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT is present all array
layers will share a single mip tail region.
image::images/sparseimage_alignedmipsize.svg[align="center", title="Sparse Image with Aligned Mip Size"]
[NOTE]
.Note
====
The mip tail regions are presented here in 2D arrays simply for figure size
reasons.
Each mip tail is logically a single array of sparse blocks with an
implementation-dependent mapping of pixels to sparse blocks.
====
When ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT is present the first
mip level that would contain partially used sparse blocks begins the mip
tail region.
This level and all subsequent levels are placed in the mip tail.
Only the first [eq]#N# mip levels whose dimensions are an exact multiple of
the sparse image block dimensions can: be bound and unbound on a sparse
block basis.
image::images/sparseimage_alignedmipsize_singlemiptail.svg[align="center", title="Sparse Image with Aligned Mip Size and Single Mip Tail"]
[NOTE]
.Note
====
The mip tail region is presented here in a 2D array simply for figure size
reasons.
It is logically a single array of sparse blocks with an
implementation-dependent mapping of pixels to sparse blocks.
====
When both ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT and
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT are present the constraints
from each of these flags are in effect.
[[sparsememory-standard-shapes]]
=== Standard Sparse Image Block Shapes
Standard sparse image block shapes define a standard set of dimensions for
sparse image blocks that depend on the format of the image.
Layout of pixels within a sparse image block is implementation dependent.
All currently defined standard sparse image block shapes are 64 KB in size.
For block-compressed formats (e.g. ename:VK_FORMAT_BC5_UNORM_BLOCK), the
pixel size is the size of the compressed texel block (128-bit for etext:BC5)
thus the dimensions of the standard sparse image block shapes apply in terms
of compressed texel blocks.
[NOTE]
.Note
====
For block-compressed formats, the dimensions of a sparse image block in
terms of texels can: be calculated by multiplying the sparse image block
dimensions by the compressed texel block dimensions.
====
<<<
[[sparsememory-sparseblockshapessingle]]
.Standard Sparse Image Block Shapes (Single Sample)
[options="header"]
|====
| PIXEL SIZE (bits) | Block Shape (2D) | Block Shape (3D)
| *8-Bit* | 256 {times} 256 {times} 1 | 64 {times} 32 {times} 32
| *16-Bit* | 256 {times} 128 {times} 1 | 32 {times} 32 {times} 32
| *32-Bit* | 128 {times} 128 {times} 1 | 32 {times} 32 {times} 16
| *64-Bit* | 128 {times} 64 {times} 1 | 32 {times} 16 {times} 16
| *128-Bit* | 64 {times} 64 {times} 1 | 16 {times} 16 {times} 16
|====
[[sparsememory-sparseblockshapesmsaa]]
.Standard Sparse Image Block Shapes (MSAA)
[options="header"]
|====
| PIXEL SIZE (bits)| Block Shape (2X) | Block Shape (4X) | Block Shape (8X) | Block Shape (16X)
| *8-Bit* | 128 {times} 256 {times} 1 | 128 {times} 128 {times} 1 | 64 {times} 128 {times} 1 | 64 {times} 64 {times} 1
| *16-Bit* | 128 {times} 128 {times} 1 | 128 {times} 64 {times} 1 | 64 {times} 64 {times} 1 | 64 {times} 32 {times} 1
| *32-Bit* | 64 {times} 128 {times} 1 | 64 {times} 64 {times} 1 | 32 {times} 64 {times} 1 | 32 {times} 32 {times} 1
| *64-Bit* | 64 {times} 64 {times} 1 | 64 {times} 32 {times} 1 | 32 {times} 32 {times} 1 | 32 {times} 16 {times} 1
| *128-Bit* | 32 {times} 64 {times} 1 | 32 {times} 32 {times} 1 | 16 {times} 32 {times} 1 | 16 {times} 16 {times} 1
|====
Implementations that support the standard sparse image block shape for all
applicable formats may: advertise the following
sname:VkPhysicalDeviceSparseProperties:
* pname:residencyStandard2DBlockShape
* pname:residencyStandard2DMultisampleBlockShape
* pname:residencyStandard3DBlockShape
Reporting each of these features does _not_ imply that all possible image
types are supported as sparse.
Instead, this indicates that no supported sparse image of the corresponding
type will use custom sparse image block dimensions for any formats that have
a corresponding standard sparse image block shape.
[[sparsememory-custom-shapes]]
=== Custom Sparse Image Block Shapes
An implementation that does not support a standard image block shape for a
particular sparse partially-resident image may: choose to support a custom
sparse image block shape for it instead.
The dimensions of such a custom sparse image block shape are reported in
sname:VkSparseImageFormatProperties::pname:imageGranularity.
As with standard sparse image block shapes, the size in bytes of the custom
sparse image block shape will be reported in
sname:VkMemoryRequirements::pname:alignment.
Custom sparse image block dimensions are reported through
fname:vkGetPhysicalDeviceSparseImageFormatProperties and
fname:vkGetImageSparseMemoryRequirements.
An implementation must: not support both the standard sparse image block
shape and a custom sparse image block shape for the same image.
The standard sparse image block shape must: be used if it is supported.
[[sparsememory-multiaspect]]
=== Multiple Aspects
Partially resident images are allowed to report separate sparse properties
for different aspects of the image.
One example is for depth/stencil images where the implementation separates
the depth and stencil data into separate planes.
Another reason for multiple aspects is to allow the application to manage
memory allocation for implementation-private _metadata_ associated with the
image.
See the figure below:
image::images/sparseimage_multiaspect.svg[align="center",title="Multiple Aspect Sparse Image"]
[NOTE]
.Note
====
The mip tail regions are presented here in 2D arrays simply for figure size
reasons.
Each mip tail is logically a single array of sparse blocks with an
implementation-dependent mapping of pixels to sparse blocks.
====
In the figure above the depth, stencil, and metadata aspects all have unique
sparse properties.
The per-pixel stencil data is [eq]#{onequarter}# the size of the depth data,
hence the stencil sparse blocks include [eq]#4 {times}# the number of
pixels.
The sparse block size in bytes for all of the aspects is identical and
defined by sname:VkMemoryRequirements::pname:alignment.
==== Metadata
The metadata aspect of an image has the following constraints:
* All metadata is reported in the mip tail region of the metadata aspect.
* All metadata must: be bound prior to device use of the sparse image.
[[sparsememory-sparse-memory-aliasing]]
== Sparse Memory Aliasing
By default sparse resources have the same aliasing rules as non-sparse
resources.
See <<resources-memory-aliasing,Memory Aliasing>> for more information.
sname:VkDevice objects that have the
<<features-features-sparseResidencyAliased,sparseResidencyAliased>> feature
enabled are able to use the ename:VK_BUFFER_CREATE_SPARSE_ALIASED_BIT and
ename:VK_IMAGE_CREATE_SPARSE_ALIASED_BIT flags for resource creation.
These flags allow resources to access physical memory bound into multiple
locations within one or more sparse resources in a _data consistent_
fashion.
This means that reading physical memory from multiple aliased locations will
return the same value.
Care must: be taken when performing a write operation to aliased physical
memory.
Memory dependencies must: be used to separate writes to one alias from reads
or writes to another alias.
Writes to aliased memory that are not properly guarded against accesses to
different aliases will have undefined results for all accesses to the
aliased memory.
Applications that wish to make use of data consistent sparse memory aliasing
must: abide by the following guidelines:
* All sparse resources that are bound to aliased physical memory must: be
created with the ename:VK_BUFFER_CREATE_SPARSE_ALIASED_BIT /
ename:VK_IMAGE_CREATE_SPARSE_ALIASED_BIT flag.
* All resources that access aliased physical memory must: interpret the
memory in the same way.
This implies the following:
** Buffers and images cannot: alias the same physical memory in a data
consistent fashion.
The physical memory ranges must: be used exclusively by buffers or used
exclusively by images for data consistency to be guaranteed.
** Memory in sparse image mip tail regions cannot: access aliased memory
in a data consistent fashion.
** Sparse images that alias the same physical memory must: have compatible
formats and be using the same sparse image block shape in order to
access aliased memory in a data consistent fashion.
Failure to follow any of the above guidelines will require the application
to abide by the normal, non-sparse resource <<resources-memory-aliasing,
aliasing rules>>.
In this case memory cannot: be accessed in a data consistent fashion.
[NOTE]
.Note
====
Enabling sparse resource memory aliasing can: be a way to lower physical
memory use, but it may: reduce performance on some implementations.
An application developer can: test on their target HW and balance the memory
/ performance trade-offs measured.
====
ifdef::implementation-guide[]
== Sparse Resource Implementation Guidelines
****
This section is Informative.
It is included to aid in implementors' understanding of sparse resources.
.Device Virtual Address
The basic pname:sparseBinding feature allows the resource to reserve its own
device virtual address range at resource creation time rather than relying
on a bind operation to set this.
Without any other creation flags, no other constraints are relaxed compared
to normal resources.
All pages must: be bound to physical memory before the device accesses the
resource.
The <<features-features-sparseResidency,sparse residency>> features allow
sparse resources to be used even when not all pages are bound to memory.
Hardware that supports access to unbound pages without causing a fault may:
support pname:residencyNonResidentStrict.
Not faulting on access to unbound pages is not enough to support
pname:residencyNonResidentStrict.
An implementation must: also guarantee that reads after writes to unbound
regions of the resource always return data for the read as if the memory
contains zeros.
Depending on the cache implementation of the hardware this may: not always
be possible.
Hardware that does not fault, but does not guarantee correct read values
will not require dummy pages, but also must: not support
pname:residencyNonResidentStrict.
Hardware that cannot: access unbound pages without causing a fault will
require the implementation to bind the entire device virtual address range
to physical memory.
Any pages that the application does not bind to memory may: be bound to one
(or more) "`dummy`" physical page(s) allocated by the implementation.
Given the following properties:
* A process must: not access memory from another process
* Reads return undefined values
It is sufficient for each host process to allocate these dummy pages and use
them for all resources in that process.
Implementations may: allocate more often (per instance, per device, or per
resource).
.Binding Memory
The byte size reported in sname:VkMemoryRequirements::pname:size must: be
greater than or equal to the amount of physical memory required: to fully
populate the resource.
Some hardware requires "`holes`" in the device virtual address range that
are never accessed.
These holes may: be included in the pname:size reported for the resource.
Including or not including the device virtual address holes in the resource
size will alter how the implementation provides support for
sname:VkSparseImageOpaqueMemoryBindInfo.
This operation must: be supported for all sparse images, even ones created
with ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
ifdef::editing-notes[]
[NOTE]
.editing-note
====
@ntrevett suggested expanding the NOTE tag below to encompass everything
from "`The cost is...`" in the first bullet point through the current note.
TBD.
====
endif::editing-notes[]
* If the holes are included in the size, this bind function becomes very
easy.
In most cases the pname:resourceOffset is simply a device virtual
address offset and the implementation does not require any sophisticated
logic to determine what device virtual address to bind.
The cost is that the application can: allocate more physical memory for
the resource than it needs.
* If the holes are not included in the size, the application can: allocate
less physical memory than otherwise for the resource.
However, in this case the implementation must: account for the holes
when mapping pname:resourceOffset to the actual device virtual address
intended to be mapped.
[NOTE]
.Note
====
If the application always uses sname:VkSparseImageMemoryBindInfo to bind
memory for the non-tail mip levels, any holes that are present in the
resource size may: never be bound.
Since sname:VkSparseImageMemoryBindInfo uses pixel locations to determine
which device virtual addresses to bind, it is impossible to bind device
virtual address holes with this operation.
====
.Binding Metadata Memory
All metadata for sparse images have their own sparse properties and are
embedded in the mip tail region for said properties.
See the <<sparsememory-multiaspect,Multiaspect>> section for details.
Given that metadata is in a mip tail region, and the mip tail region must:
be reported as contiguous (either globally or per-array-layer), some
implementations will have to resort to complicated offset -> device virtual
address mapping for handling sname:VkSparseImageOpaqueMemoryBindInfo.
To make this easier on the implementation, the
ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT explicitly denotes when metadata is
bound with sname:VkSparseImageOpaqueMemoryBindInfo.
When this flag is not present, the pname:resourceOffset may: be treated as a
strict device virtual address offset.
When ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT is present, the
pname:resourceOffset must: have been derived explicitly from the
pname:imageMipTailOffset in the sparse resource properties returned for the
metadata aspect.
By manipulating the value returned for pname:imageMipTailOffset, the
pname:resourceOffset does not have to correlate directly to a device virtual
address offset, and may: instead be whatever values makes it easiest for the
implementation to derive the correct device virtual address.
****
endif::implementation-guide[]
[[sparsememory-resourceapi]]
== Sparse Resource API
The APIs related to sparse resources are grouped into the following
categories:
* <<sparsememory-physicalfeatures,Physical Device Features>>
* <<sparsememory-physicalprops,Physical Device Sparse Properties>>
* <<sparsememory-format-props,Sparse Image Format Properties>>
* <<sparsememory-resource-creation,Sparse Resource Creation>>
* <<sparsememory-memory-requirements,Sparse Resource Memory Requirements>>
* <<sparsememory-resource-binding,Binding Resource Memory>>
[[sparsememory-physicalfeatures]]
=== Physical Device Features
Some sparse-resource related features are reported and enabled in
sname:VkPhysicalDeviceFeatures.
These features must: be supported and enabled on the sname:VkDevice object
before applications can: use them.
See <<features-features,Physical Device Features>> for information on how to
get and set enabled device features, and for more detailed explanations of
these features.
==== Sparse Physical Device Features
* pname:sparseBinding: Support for creating sname:VkBuffer and
sname:VkImage objects with the ename:VK_BUFFER_CREATE_SPARSE_BINDING_BIT
and ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT flags, respectively.
* pname:sparseResidencyBuffer: Support for creating sname:VkBuffer objects
with the ename:VK_BUFFER_CREATE_SPARSE_RESIDENCY_BIT flag.
* pname:sparseResidencyImage2D: Support for creating 2D single-sampled
sname:VkImage objects with ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
* pname:sparseResidencyImage3D: Support for creating 3D sname:VkImage
objects with ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
* pname:sparseResidency2Samples: Support for creating 2D sname:VkImage
objects with 2 samples and ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
* pname:sparseResidency4Samples: Support for creating 2D sname:VkImage
objects with 4 samples and ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
* pname:sparseResidency8Samples: Support for creating 2D sname:VkImage
objects with 8 samples and ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
* pname:sparseResidency16Samples: Support for creating 2D sname:VkImage
objects with 16 samples and ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT.
* pname:sparseResidencyAliased: Support for creating sname:VkBuffer and
sname:VkImage objects with the ename:VK_BUFFER_CREATE_SPARSE_ALIASED_BIT
and ename:VK_IMAGE_CREATE_SPARSE_ALIASED_BIT flags, respectively.
[[sparsememory-physicalprops]]
=== Physical Device Sparse Properties
Some features of the implementation are not possible to disable, and are
reported to allow applications to alter their sparse resource usage
accordingly.
These read-only capabilities are reported in the
slink:VkPhysicalDeviceProperties::pname:sparseProperties member, which is a
structure of type sname:VkPhysicalDeviceSparseProperties.
[open,refpage='VkPhysicalDeviceSparseProperties',desc='Structure specifying physical device sparse memory properties',type='structs']
--
The sname:VkPhysicalDeviceSparseProperties structure is defined as:
include::../api/structs/VkPhysicalDeviceSparseProperties.txt[]
* pname:residencyStandard2DBlockShape is ename:VK_TRUE if the physical
device will access all single-sample 2D sparse resources using the
standard sparse image block shapes (based on image format), as described
in the <<sparsememory-sparseblockshapessingle,Standard Sparse Image
Block Shapes (Single Sample)>> table.
If this property is not supported the value returned in the
pname:imageGranularity member of the sname:VkSparseImageFormatProperties
structure for single-sample 2D images is not required: to match the
standard sparse image block dimensions listed in the table.
* pname:residencyStandard2DMultisampleBlockShape is ename:VK_TRUE if the
physical device will access all multisample 2D sparse resources using
the standard sparse image block shapes (based on image format), as
described in the <<sparsememory-sparseblockshapesmsaa,Standard Sparse
Image Block Shapes (MSAA)>> table.
If this property is not supported, the value returned in the
pname:imageGranularity member of the sname:VkSparseImageFormatProperties
structure for multisample 2D images is not required: to match the
standard sparse image block dimensions listed in the table.
* pname:residencyStandard3DBlockShape is ename:VK_TRUE if the physical
device will access all 3D sparse resources using the standard sparse
image block shapes (based on image format), as described in the
<<sparsememory-sparseblockshapessingle,Standard Sparse Image Block
Shapes (Single Sample)>> table.
If this property is not supported, the value returned in the
pname:imageGranularity member of the sname:VkSparseImageFormatProperties
structure for 3D images is not required: to match the standard sparse
image block dimensions listed in the table.
* pname:residencyAlignedMipSize is ename:VK_TRUE if images with mip level
dimensions that are not integer multiples of the corresponding
dimensions of the sparse image block may: be placed in the mip tail.
If this property is not reported, only mip levels with dimensions
smaller than the pname:imageGranularity member of the
sname:VkSparseImageFormatProperties structure will be placed in the mip
tail.
If this property is reported the implementation is allowed to return
ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT in the pname:flags
member of sname:VkSparseImageFormatProperties, indicating that mip level
dimensions that are not integer multiples of the corresponding
dimensions of the sparse image block will be placed in the mip tail.
* pname:residencyNonResidentStrict specifies whether the physical device
can: consistently access non-resident regions of a resource.
If this property is ename:VK_TRUE, access to non-resident regions of
resources will be guaranteed to return values as if the resource were
populated with 0; writes to non-resident regions will be discarded.
include::../validity/structs/VkPhysicalDeviceSparseProperties.txt[]
--
[[sparsememory-format-props]]
=== Sparse Image Format Properties
Given that certain aspects of sparse image support, including the sparse
image block dimensions, may: be implementation-dependent,
flink:vkGetPhysicalDeviceSparseImageFormatProperties can: be used to query
for sparse image format properties prior to resource creation.
This command is used to check whether a given set of sparse image parameters
is supported and what the sparse image block shape will be.
==== Sparse Image Format Properties API
[open,refpage='VkSparseImageFormatProperties',desc='Structure specifying sparse image format properties',type='structs']
--
The sname:VkSparseImageFormatProperties structure is defined as:
include::../api/structs/VkSparseImageFormatProperties.txt[]
* pname:aspectMask is a bitmask elink:VkImageAspectFlagBits specifying
which aspects of the image the properties apply to.
* pname:imageGranularity is the width, height, and depth of the sparse
image block in texels or compressed texel blocks.
* pname:flags is a bitmask of elink:VkSparseImageFormatFlagBits specifying
additional information about the sparse resource.
include::../validity/structs/VkSparseImageFormatProperties.txt[]
--
[open,refpage='VkSparseImageFormatFlagBits',desc='Bitmask specifying additional information about a sparse image resource',type='enums']
--
Bits which can: be set in slink:VkSparseImageFormatProperties::pname:flags,
specifying additional information about the sparse resource, are:
include::../api/enums/VkSparseImageFormatFlagBits.txt[]
* ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT specifies that the image
uses a single mip tail region for all array layers.
* ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT specifies that the
first mip level whose dimensions are not integer multiples of the
corresponding dimensions of the sparse image block begins the mip tail
region.
* ename:VK_SPARSE_IMAGE_FORMAT_NONSTANDARD_BLOCK_SIZE_BIT specifies that
the image uses non-standard sparse image block dimensions, and the
pname:imageGranularity values do not match the standard sparse image
block dimensions for the given pixel format.
--
[open,refpage='vkGetPhysicalDeviceSparseImageFormatProperties',desc='Retrieve properties of an image format applied to sparse images',type='protos']
--
fname:vkGetPhysicalDeviceSparseImageFormatProperties returns an array of
slink:VkSparseImageFormatProperties.
Each element will describe properties for one set of image aspects that are
bound simultaneously in the image.
This is usually one element for each aspect in the image, but for
interleaved depth/stencil images there is only one element describing the
combined aspects.
include::../api/protos/vkGetPhysicalDeviceSparseImageFormatProperties.txt[]
* pname:physicalDevice is the physical device from which to query the
sparse image capabilities.
* pname:format is the image format.
* pname:type is the dimensionality of image.
* pname:samples is the number of samples per pixel as defined in
elink:VkSampleCountFlagBits.
* pname:usage is a bitmask describing the intended usage of the image.
* pname:tiling is the tiling arrangement of the data elements in memory.
* pname:pPropertyCount is a pointer to an integer related to the number of
sparse format properties available or queried, as described below.
* pname:pProperties is either `NULL` or a pointer to an array of
slink:VkSparseImageFormatProperties structures.
If pname:pProperties is `NULL`, then the number of sparse format properties
available is returned in pname:pPropertyCount.
Otherwise, pname:pPropertyCount must: point to a variable set by the user to
the number of elements in the pname:pProperties array, and on return the
variable is overwritten with the number of structures actually written to
pname:pProperties.
If pname:pPropertyCount is less than the number of sparse format properties
available, at most pname:pPropertyCount structures will be written.
If ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT is not supported for the given
arguments, pname:pPropertyCount will be set to zero upon return, and no data
will be written to pname:pProperties.
Multiple aspects are returned for depth/stencil images that are implemented
as separate planes by the implementation.
The depth and stencil data planes each have unique
sname:VkSparseImageFormatProperties data.
Depth/stencil images with depth and stencil data interleaved into a single
plane will return a single sname:VkSparseImageFormatProperties structure
with the pname:aspectMask set to ename:VK_IMAGE_ASPECT_DEPTH_BIT |
ename:VK_IMAGE_ASPECT_STENCIL_BIT.
.Valid Usage
****
* [[VUID-vkGetPhysicalDeviceSparseImageFormatProperties-samples-01094]]
pname:samples must: be a bit value that is set in
sname:VkImageFormatProperties::pname:sampleCounts returned by
fname:vkGetPhysicalDeviceImageFormatProperties with pname:format,
pname:type, pname:tiling, and pname:usage equal to those in this command
and pname:flags equal to the value that is set in
sname:VkImageCreateInfo::pname:flags when the image is created
****
include::../validity/protos/vkGetPhysicalDeviceSparseImageFormatProperties.txt[]
--
ifdef::VK_KHR_get_physical_device_properties2[]
[open,refpage='vkGetPhysicalDeviceSparseImageFormatProperties2KHR',desc='Retrieve properties of an image format applied to sparse images',type='protos']
--
fname:vkGetPhysicalDeviceSparseImageFormatProperties2KHR returns an array of
slink:VkSparseImageFormatProperties2KHR.
Each element will describe properties for one set of image aspects that are
bound simultaneously in the image.
This is usually one element for each aspect in the image, but for
interleaved depth/stencil images there is only one element describing the
combined aspects.
include::../api/protos/vkGetPhysicalDeviceSparseImageFormatProperties2KHR.txt[]
* pname:physicalDevice is the physical device from which to query the
sparse image capabilities.
* pname:pFormatInfo is a pointer to a structure of type
slink:VkPhysicalDeviceSparseImageFormatInfo2KHR containing input
parameters to the command.
* pname:pPropertyCount is a pointer to an integer related to the number of
sparse format properties available or queried, as described below.
* pname:pProperties is either `NULL` or a pointer to an array of
slink:VkSparseImageFormatProperties2KHR structures.
fname:vkGetPhysicalDeviceSparseImageFormatProperties2KHR behaves identically
to flink:vkGetPhysicalDeviceSparseImageFormatProperties, with the ability to
return extended information by adding extension structures to the
pname:pNext chain of its pname:pProperties parameter.
include::../validity/protos/vkGetPhysicalDeviceSparseImageFormatProperties2KHR.txt[]
--
[open,refpage='VkPhysicalDeviceSparseImageFormatInfo2KHR',desc='Structure specifying sparse image format inputs',type='structs']
--
The sname:VkPhysicalDeviceSparseImageFormatInfo2KHR structure is defined as:
include::../api/structs/VkPhysicalDeviceSparseImageFormatInfo2KHR.txt[]
* pname:sType is the type of this structure.
* pname:pNext is `NULL` or a pointer to an extension-specific structure.
* pname:format is the image format.
* pname:type is the dimensionality of image.
* pname:samples is the number of samples per pixel as defined in
elink:VkSampleCountFlagBits.
* pname:usage is a bitmask describing the intended usage of the image.
* pname:tiling is the tiling arrangement of the data elements in memory.
.Valid Usage
****
* [[VUID-VkPhysicalDeviceSparseImageFormatInfo2KHR-samples-01095]]
pname:samples must: be a bit value that is set in
sname:VkImageFormatProperties::pname:sampleCounts returned by
fname:vkGetPhysicalDeviceImageFormatProperties with pname:format,
pname:type, pname:tiling, and pname:usage equal to those in this command
and pname:flags equal to the value that is set in
sname:VkImageCreateInfo::pname:flags when the image is created
****
include::../validity/structs/VkPhysicalDeviceSparseImageFormatInfo2KHR.txt[]
--
[open,refpage='VkSparseImageFormatProperties2KHR',desc='Structure specifying sparse image format properties',type='structs']
--
The sname:VkSparseImageFormatProperties2KHR structure is defined as:
include::../api/structs/VkSparseImageFormatProperties2KHR.txt[]
* pname:sType is the type of this structure.
* pname:pNext is `NULL` or a pointer to an extension-specific structure.
* pname:properties is a structure of type
slink:VkSparseImageFormatProperties which is populated with the same
values as in flink:vkGetPhysicalDeviceSparseImageFormatProperties.
include::../validity/structs/VkSparseImageFormatProperties2KHR.txt[]
--
endif::VK_KHR_get_physical_device_properties2[]
[[sparsememory-resource-creation]]
=== Sparse Resource Creation
Sparse resources require that one or more sparse feature flags be specified
(as part of the sname:VkPhysicalDeviceFeatures structure described
previously in the <<sparsememory-physicalfeatures,Physical Device Features>>
section) at CreateDevice time.
When the appropriate device features are enabled, the
etext:VK_BUFFER_CREATE_SPARSE_* and etext:VK_IMAGE_CREATE_SPARSE_* flags
can: be used.
See flink:vkCreateBuffer and flink:vkCreateImage for details of the resource
creation APIs.
[NOTE]
.Note
====
Specifying ename:VK_BUFFER_CREATE_SPARSE_RESIDENCY_BIT or
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT requires specifying
ename:VK_BUFFER_CREATE_SPARSE_BINDING_BIT or
ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT, respectively, as well.
This means that resources must: be created with the appropriate
etext:*_SPARSE_BINDING_BIT to be used with the sparse binding command
(fname:vkQueueBindSparse).
====
[[sparsememory-memory-requirements]]
=== Sparse Resource Memory Requirements
Sparse resources have specific memory requirements related to binding sparse
memory.
These memory requirements are reported differently for sname:VkBuffer
objects and sname:VkImage objects.
[[sparsememory-memory-buffer-fully-resident]]
==== Buffer and Fully-Resident Images
Buffers (both fully and partially resident) and fully-resident images can:
be bound to memory using only the data from sname:VkMemoryRequirements.
For all sparse resources the sname:VkMemoryRequirements::pname:alignment
member denotes both the bindable sparse block size in bytes and required:
alignment of sname:VkDeviceMemory.
[[sparsememory-memory-partially-resident]]
==== Partially Resident Images
Partially resident images have a different method for binding memory.
As with buffers and fully resident images, the
sname:VkMemoryRequirements::pname:alignment field denotes the bindable
sparse block size in bytes for the image.
Requesting sparse memory requirements for sname:VkImage objects using
fname:vkGetImageSparseMemoryRequirements will return an array of one or more
sname:VkSparseImageMemoryRequirements structures.
Each structure describes the sparse memory requirements for a group of
aspects of the image.
The sparse image must: have been created using the
ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT flag to retrieve valid sparse
image memory requirements.
==== Sparse Image Memory Requirements
[open,refpage='VkSparseImageMemoryRequirements',desc='Structure specifying sparse image memory requirements',type='structs']
--
The sname:VkSparseImageMemoryRequirements structure is defined as:
include::../api/structs/VkSparseImageMemoryRequirements.txt[]
* pname:formatProperties.aspectMask is the set of aspects of the image
that this sparse memory requirement applies to.
This will usually have a single aspect specified.
However, depth/stencil images may: have depth and stencil data
interleaved in the same sparse block, in which case both
ename:VK_IMAGE_ASPECT_DEPTH_BIT and ename:VK_IMAGE_ASPECT_STENCIL_BIT
would be present.
* pname:formatProperties.imageGranularity describes the dimensions of a
single bindable sparse image block in pixel units.
For aspect ename:VK_IMAGE_ASPECT_METADATA_BIT, all dimensions will be
zero pixels.
All metadata is located in the mip tail region.
* pname:formatProperties.flags is a bitmask of
elink:VkSparseImageFormatFlagBits:
** If ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT is set the image
uses a single mip tail region for all array layers.
** If ename:VK_SPARSE_IMAGE_FORMAT_ALIGNED_MIP_SIZE_BIT is set the
dimensions of mip levels must: be integer multiples of the
corresponding dimensions of the sparse image block for levels not
located in the mip tail.
** If ename:VK_SPARSE_IMAGE_FORMAT_NONSTANDARD_BLOCK_SIZE_BIT is set the
image uses non-standard sparse image block dimensions.
The pname:formatProperties.imageGranularity values do not match the
standard sparse image block dimension corresponding to the image's
pixel format.
* pname:imageMipTailFirstLod is the first mip level at which image
subresources are included in the mip tail region.
* pname:imageMipTailSize is the memory size (in bytes) of the mip tail
region.
If pname:formatProperties.flags contains
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT, this is the size of the
whole mip tail, otherwise this is the size of the mip tail of a single
array layer.
This value is guaranteed to be a multiple of the sparse block size in
bytes.
* pname:imageMipTailOffset is the opaque memory offset used with
slink:VkSparseImageOpaqueMemoryBindInfo to bind the mip tail region(s).
* pname:imageMipTailStride is the offset stride between each array-layer's
mip tail, if pname:formatProperties.flags does not contain
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT (otherwise the value is
undefined).
include::../validity/structs/VkSparseImageMemoryRequirements.txt[]
--
[open,refpage='vkGetImageSparseMemoryRequirements',desc='Query the memory requirements for a sparse image',type='protos']
--
To query sparse memory requirements for an image, call:
include::../api/protos/vkGetImageSparseMemoryRequirements.txt[]
* pname:device is the logical device that owns the image.
* pname:image is the sname:VkImage object to get the memory requirements
for.
* pname:pSparseMemoryRequirementCount is a pointer to an integer related
to the number of sparse memory requirements available or queried, as
described below.
* pname:pSparseMemoryRequirements is either `NULL` or a pointer to an
array of sname:VkSparseImageMemoryRequirements structures.
If pname:pSparseMemoryRequirements is `NULL`, then the number of sparse
memory requirements available is returned in
pname:pSparseMemoryRequirementCount.
Otherwise, pname:pSparseMemoryRequirementCount must: point to a variable set
by the user to the number of elements in the pname:pSparseMemoryRequirements
array, and on return the variable is overwritten with the number of
structures actually written to pname:pSparseMemoryRequirements.
If pname:pSparseMemoryRequirementCount is less than the number of sparse
memory requirements available, at most pname:pSparseMemoryRequirementCount
structures will be written.
If the image was not created with ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT
then pname:pSparseMemoryRequirementCount will be set to zero and
pname:pSparseMemoryRequirements will not be written to.
[NOTE]
.Note
====
It is legal for an implementation to report a larger value in
sname:VkMemoryRequirements::pname:size than would be obtained by adding
together memory sizes for all sname:VkSparseImageMemoryRequirements returned
by fname:vkGetImageSparseMemoryRequirements.
This may: occur when the hardware requires unused padding in the address
range describing the resource.
====
include::../validity/protos/vkGetImageSparseMemoryRequirements.txt[]
--
[[sparsememory-resource-binding]]
=== Binding Resource Memory
Non-sparse resources are backed by a single physical allocation prior to
device use (via fname:vkBindImageMemory or fname:vkBindBufferMemory), and
their backing must: not be changed.
On the other hand, sparse resources can: be bound to memory non-contiguously
and these bindings can: be altered during the lifetime of the resource.
[NOTE]
.Note
====
It is important to note that freeing a sname:VkDeviceMemory object with
fname:vkFreeMemory will not cause resources (or resource regions) bound to
the memory object to become unbound.
Access to resources that are bound to memory objects that have been freed
will result in undefined behavior, potentially including application
termination.
Implementations must: ensure that no access to physical memory owned by the
system or another process will occur in this scenario.
In other words, accessing resources bound to freed memory may: result in
application termination, but must: not result in system termination or in
reading non-process-accessible memory.
====
Sparse memory bindings execute on a queue that includes the
ename:VK_QUEUE_SPARSE_BINDING_BIT bit.
Applications must: use <<synchronization,synchronization primitives>> to
guarantee that other queues do not access ranges of memory concurrently with
a binding change.
Accessing memory in a range while it is being rebound results in undefined
behavior.
It is valid to access other ranges of the same resource while a bind
operation is executing.
[NOTE]
.Note
====
Implementations must: provide a guarantee that simultaneously binding sparse
blocks while another queue accesses those same sparse blocks via a sparse
resource must: not access memory owned by another process or otherwise
corrupt the system.
====
While some implementations may: include ename:VK_QUEUE_SPARSE_BINDING_BIT
support in queue families that also include graphics and compute support,
other implementations may: only expose a
ename:VK_QUEUE_SPARSE_BINDING_BIT-only queue family.
In either case, applications must: use <<synchronization,synchronization
primitives>> to explicitly request any ordering dependencies between sparse
memory binding operations and other graphics/compute/transfer operations, as
sparse binding operations are not automatically ordered against command
buffer execution, even within a single queue.
When binding memory explicitly for the ename:VK_IMAGE_ASPECT_METADATA_BIT
the application must: use the ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT in
the sname:VkSparseMemoryBind::pname:flags field when binding memory.
Binding memory for metadata is done the same way as binding memory for the
mip tail, with the addition of the ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT
flag.
Binding the mip tail for any aspect must: only be performed using
slink:VkSparseImageOpaqueMemoryBindInfo.
If pname:formatProperties.flags contains
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT, then it can: be bound with
a single slink:VkSparseMemoryBind structure, with pname:resourceOffset =
pname:imageMipTailOffset and pname:size = pname:imageMipTailSize.
If pname:formatProperties.flags does not contain
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT then the offset for the mip
tail in each array layer is given as:
[source,c++]
---------------------------------------------------
arrayMipTailOffset = imageMipTailOffset + arrayLayer * imageMipTailStride;
---------------------------------------------------
and the mip tail can: be bound with code:layerCount slink:VkSparseMemoryBind
structures, each using pname:size = pname:imageMipTailSize and
pname:resourceOffset = ptext:arrayMipTailOffset as defined above.
Sparse memory binding is handled by the following APIs and related data
structures.
[[sparsemem-memory-binding]]
==== Sparse Memory Binding Functions
[open,refpage='VkSparseMemoryBind',desc='Structure specifying a sparse memory bind operation',type='structs']
--
The sname:VkSparseMemoryBind structure is defined as:
include::../api/structs/VkSparseMemoryBind.txt[]
* pname:resourceOffset is the offset into the resource.
* pname:size is the size of the memory region to be bound.
* pname:memory is the sname:VkDeviceMemory object that the range of the
resource is bound to.
If pname:memory is dlink:VK_NULL_HANDLE, the range is unbound.
* pname:memoryOffset is the offset into the sname:VkDeviceMemory object to
bind the resource range to.
If pname:memory is dlink:VK_NULL_HANDLE, this value is ignored.
* pname:flags is a bitmask of elink:VkSparseMemoryBindFlagBits specifying
usage of the binding operation.
The _binding range_ [eq]#[pname:resourceOffset, pname:resourceOffset {plus}
pname:size)# has different constraints based on pname:flags.
If pname:flags contains ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT, the
binding range must: be within the mip tail region of the metadata aspect.
This metadata region is defined by:
:: [eq]#metadataRegion = [base, base {plus} pname:imageMipTailSize)#
:: [eq]#base = pname:imageMipTailOffset {plus} pname:imageMipTailStride
{times} n#
and pname:imageMipTailOffset, pname:imageMipTailSize, and
pname:imageMipTailStride values are from the
slink:VkSparseImageMemoryRequirements corresponding to the metadata aspect
of the image, and [eq]#n# is a valid array layer index for the image,
pname:imageMipTailStride is considered to be zero for aspects where
sname:VkSparseImageMemoryRequirements::pname:formatProperties.flags contains
ename:VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT.
If pname:flags does not contain ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT,
the binding range must: be within the range
[eq]#[0,slink:VkMemoryRequirements::pname:size)#.
.Valid Usage
****
* [[VUID-VkSparseMemoryBind-memory-01096]]
If pname:memory is not dlink:VK_NULL_HANDLE, pname:memory and
pname:memoryOffset must: match the memory requirements of the resource,
as described in section <<resources-association>>
* [[VUID-VkSparseMemoryBind-memory-01097]]
If pname:memory is not dlink:VK_NULL_HANDLE, pname:memory must: not have
been created with a memory type that reports
ename:VK_MEMORY_PROPERTY_LAZILY_ALLOCATED_BIT bit set
* [[VUID-VkSparseMemoryBind-size-01098]]
pname:size must: be greater than `0`
* [[VUID-VkSparseMemoryBind-resourceOffset-01099]]
pname:resourceOffset must: be less than the size of the resource
* [[VUID-VkSparseMemoryBind-size-01100]]
pname:size must: be less than or equal to the size of the resource minus
pname:resourceOffset
* [[VUID-VkSparseMemoryBind-memoryOffset-01101]]
pname:memoryOffset must: be less than the size of pname:memory
* [[VUID-VkSparseMemoryBind-size-01102]]
pname:size must: be less than or equal to the size of pname:memory minus
pname:memoryOffset
****
include::../validity/structs/VkSparseMemoryBind.txt[]
--
[open,refpage='VkSparseMemoryBindFlagBits',desc='Bitmask specifying usage of a sparse memory binding operation',type='enums']
--
Bits which can: be set in slink:VkSparseMemoryBind::pname:flags, specifying
usage of a sparse memory binding operation, are:
include::../api/enums/VkSparseMemoryBindFlagBits.txt[]
* ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT specifies that the memory being
bound is only for the metadata aspect.
--
[open,refpage='VkSparseBufferMemoryBindInfo',desc='Structure specifying a sparse buffer memory bind operation',type='structs']
--
Memory is bound to sname:VkBuffer objects created with the
ename:VK_BUFFER_CREATE_SPARSE_BINDING_BIT flag using the following
structure:
include::../api/structs/VkSparseBufferMemoryBindInfo.txt[]
* pname:buffer is the sname:VkBuffer object to be bound.
* pname:bindCount is the number of sname:VkSparseMemoryBind structures in
the pname:pBinds array.
* pname:pBinds is a pointer to array of sname:VkSparseMemoryBind
structures.
include::../validity/structs/VkSparseBufferMemoryBindInfo.txt[]
--
[open,refpage='VkSparseImageOpaqueMemoryBindInfo',desc='Structure specifying sparse image opaque memory bind info',type='structs']
--
Memory is bound to opaque regions of sname:VkImage objects created with the
ename:VK_IMAGE_CREATE_SPARSE_BINDING_BIT flag using the following structure:
include::../api/structs/VkSparseImageOpaqueMemoryBindInfo.txt[]
* pname:image is the sname:VkImage object to be bound.
* pname:bindCount is the number of sname:VkSparseMemoryBind structures in
the pname:pBinds array.
* pname:pBinds is a pointer to array of sname:VkSparseMemoryBind
structures.
.Valid Usage
****
* [[VUID-VkSparseImageOpaqueMemoryBindInfo-pBinds-01103]]
If the pname:flags member of any element of pname:pBinds contains
ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT, the binding range defined
must: be within the mip tail region of the metadata aspect of
pname:image
****
include::../validity/structs/VkSparseImageOpaqueMemoryBindInfo.txt[]
--
[NOTE]
.Note
==================
This operation is normally used to bind memory to fully-resident sparse
images or for mip tail regions of partially resident images.
However, it can: also be used to bind memory for the entire binding range of
partially resident images.
In case pname:flags does not contain
ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT, the pname:resourceOffset is in the
range [eq]#[0, slink:VkMemoryRequirements::pname:size)#, This range includes
data from all aspects of the image, including metadata.
For most implementations this will probably mean that the
pname:resourceOffset is a simple device address offset within the resource.
It is possible for an application to bind a range of memory that includes
both resource data and metadata.
However, the application would not know what part of the image the memory is
used for, or if any range is being used for metadata.
When pname:flags contains ename:VK_SPARSE_MEMORY_BIND_METADATA_BIT, the
binding range specified must: be within the mip tail region of the metadata
aspect.
In this case the pname:resourceOffset is not required: to be a simple device
address offset within the resource.
However, it _is_ defined to be within [eq]#[imageMipTailOffset,
imageMipTailOffset {plus} imageMipTailSize)# for the metadata aspect.
See slink:VkSparseMemoryBind for the full constraints on binding region with
this flag present.
==================
ifdef::editing-notes[]
[NOTE]
.editing-note
====
(Jon) The preceding NOTE refers to pname:flags, which is presumably a
reference to slink:VkSparseMemoryBind above, even though that is not
contextually clear.
====
endif::editing-notes[]
[open,refpage='VkSparseImageMemoryBindInfo',desc='Structure specifying sparse image memory bind info',type='structs']
--
Memory can: be bound to sparse image blocks of sname:VkImage objects created
with the ename:VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT flag using the following
structure:
include::../api/structs/VkSparseImageMemoryBindInfo.txt[]
* pname:image is the sname:VkImage object to be bound
* pname:bindCount is the number of sname:VkSparseImageMemoryBind
structures in pBinds array
* pname:pBinds is a pointer to array of sname:VkSparseImageMemoryBind
structures
include::../validity/structs/VkSparseImageMemoryBindInfo.txt[]
--
[open,refpage='VkSparseImageMemoryBind',desc='Structure specifying sparse image memory bind',type='structs']
--
The sname:VkSparseImageMemoryBind structure is defined as:
include::../api/structs/VkSparseImageMemoryBind.txt[]
* pname:subresource is the aspectMask and region of interest in the image.
* pname:offset are the coordinates of the first texel within the image
subresource to bind.
* pname:extent is the size in texels of the region within the image
subresource to bind.
The extent must: be a multiple of the sparse image block dimensions,
except when binding sparse image blocks along the edge of an image
subresource it can: instead be such that any coordinate of
[eq]#pname:offset {plus} pname:extent# equals the corresponding
dimensions of the image subresource.
* pname:memory is the sname:VkDeviceMemory object that the sparse image
blocks of the image are bound to.
If pname:memory is dlink:VK_NULL_HANDLE, the sparse image blocks are
unbound.
* pname:memoryOffset is an offset into sname:VkDeviceMemory object.
If pname:memory is dlink:VK_NULL_HANDLE, this value is ignored.
* pname:flags are sparse memory binding flags.
.Valid Usage
****
* [[VUID-VkSparseImageMemoryBind-memory-01104]]
If the <<features-features-sparseResidencyAliased,sparse aliased
residency>> feature is not enabled, and if any other resources are bound
to ranges of pname:memory, the range of pname:memory being bound must:
not overlap with those bound ranges
* [[VUID-VkSparseImageMemoryBind-memory-01105]]
pname:memory and pname:memoryOffset must: match the memory requirements
of the calling command's pname:image, as described in section
<<resources-association>>
* [[VUID-VkSparseImageMemoryBind-subresource-01106]]
pname:subresource must: be a valid image subresource for pname:image
(see <<resources-image-views>>)
* [[VUID-VkSparseImageMemoryBind-offset-01107]]
pname:offset.x must: be a multiple of the sparse image block width
(sname:VkSparseImageFormatProperties::pname:imageGranularity.width) of
the image
* [[VUID-VkSparseImageMemoryBind-extent-01108]]
pname:extent.width must: either be a multiple of the sparse image block
width of the image, or else [eq]#(pname:extent.width {plus}
pname:offset.x)# must: equal the width of the image subresource
* [[VUID-VkSparseImageMemoryBind-offset-01109]]
pname:offset.y must: be a multiple of the sparse image block height
(sname:VkSparseImageFormatProperties::pname:imageGranularity.height) of
the image
* [[VUID-VkSparseImageMemoryBind-extent-01110]]
pname:extent.height must: either be a multiple of the sparse image block
height of the image, or else [eq]#(pname:extent.height {plus}
pname:offset.y)# must: equal the height of the image subresource
* [[VUID-VkSparseImageMemoryBind-offset-01111]]
pname:offset.z must: be a multiple of the sparse image block depth
(sname:VkSparseImageFormatProperties::pname:imageGranularity.depth) of
the image
* [[VUID-VkSparseImageMemoryBind-extent-01112]]
pname:extent.depth must: either be a multiple of the sparse image block
depth of the image, or else [eq]#(pname:extent.depth {plus}
pname:offset.z)# must: equal the depth of the image subresource
****
include::../validity/structs/VkSparseImageMemoryBind.txt[]
--
[open,refpage='vkQueueBindSparse',desc='Bind device memory to a sparse resource object',type='protos']
--
To submit sparse binding operations to a queue, call:
include::../api/protos/vkQueueBindSparse.txt[]
* pname:queue is the queue that the sparse binding operations will be
submitted to.
* pname:bindInfoCount is the number of elements in the pname:pBindInfo
array.
* pname:pBindInfo is an array of slink:VkBindSparseInfo structures, each
specifying a sparse binding submission batch.
* pname:fence is an optional: handle to a fence to be signaled.
If pname:fence is not dlink:VK_NULL_HANDLE, it defines a
<<synchronization-fences-signaling, fence signal operation>>.
fname:vkQueueBindSparse is a <<devsandqueues-submission,queue submission
command>>, with each batch defined by an element of pname:pBindInfo as an
instance of the slink:VkBindSparseInfo structure.
Batches begin execution in the order they appear in pname:pBindInfo, but
may: complete out of order.
Within a batch, a given range of a resource must: not be bound more than
once.
Across batches, if a range is to be bound to one allocation and offset and
then to another allocation and offset, then the application must: guarantee
(usually using semaphores) that the binding operations are executed in the
correct order, as well as to order binding operations against the execution
of command buffer submissions.
As no operation to flink:vkQueueBindSparse causes any pipeline stage to
access memory, synchronization primitives used in this command effectively
only define execution dependencies.
Additional information about fence and semaphore operation is described in
<<synchronization, the synchronization chapter>>.
.Valid Usage
****
* [[VUID-vkQueueBindSparse-fence-01113]]
If pname:fence is not dlink:VK_NULL_HANDLE, pname:fence must: be
unsignaled
* [[VUID-vkQueueBindSparse-fence-01114]]
If pname:fence is not dlink:VK_NULL_HANDLE, pname:fence must: not be
associated with any other queue command that has not yet completed
execution on that queue
* [[VUID-vkQueueBindSparse-pSignalSemaphores-01115]]
Each element of the pname:pSignalSemaphores member of each element of
pname:pBindInfo must: be unsignaled when the semaphore signal operation
it defines is executed on the device
* [[VUID-vkQueueBindSparse-pWaitSemaphores-01116]]
When a semaphore unsignal operation defined by any element of the
pname:pWaitSemaphores member of any element of pname:pBindInfo executes
on pname:queue, no other queue must: be waiting on the same semaphore.
* [[VUID-vkQueueBindSparse-pWaitSemaphores-01117]]
All elements of the pname:pWaitSemaphores member of all elements of
pname:pBindInfo must: be semaphores that are signaled, or have
<<synchronization-semaphores-signaling, semaphore signal operations>>
previously submitted for execution.
****
include::../validity/protos/vkQueueBindSparse.txt[]
--
[open,refpage='VkBindSparseInfo',desc='Structure specifying a sparse binding operation',type='structs']
--
The sname:VkBindSparseInfo structure is defined as:
include::../api/structs/VkBindSparseInfo.txt[]
* pname:sType is the type of this structure.
* pname:pNext is `NULL` or a pointer to an extension-specific structure.
* pname:waitSemaphoreCount is the number of semaphores upon which to wait
before executing the sparse binding operations for the batch.
* pname:pWaitSemaphores is a pointer to an array of semaphores upon which
to wait on before the sparse binding operations for this batch begin
execution.
If semaphores to wait on are provided, they define a
<<synchronization-semaphores-waiting, semaphore wait operation>>.
* pname:bufferBindCount is the number of sparse buffer bindings to perform
in the batch.
* pname:pBufferBinds is a pointer to an array of
slink:VkSparseBufferMemoryBindInfo structures.
* pname:imageOpaqueBindCount is the number of opaque sparse image bindings
to perform.
* pname:pImageOpaqueBinds is a pointer to an array of
slink:VkSparseImageOpaqueMemoryBindInfo structures, indicating opaque
sparse image bindings to perform.
* pname:imageBindCount is the number of sparse image bindings to perform.
* pname:pImageBinds is a pointer to an array of
slink:VkSparseImageMemoryBindInfo structures, indicating sparse image
bindings to perform.
* pname:signalSemaphoreCount is the number of semaphores to be signaled
once the sparse binding operations specified by the structure have
completed execution.
* pname:pSignalSemaphores is a pointer to an array of semaphores which
will be signaled when the sparse binding operations for this batch have
completed execution.
If semaphores to be signaled are provided, they define a
<<synchronization-semaphores-signaling, semaphore signal operation>>.
include::../validity/structs/VkBindSparseInfo.txt[]
--
ifdef::VK_KHX_device_group[]
[open,refpage='VkDeviceGroupBindSparseInfoKHX',desc='Structure indicating which instances are bound',type='structs']
--
If the pname:pNext chain of slink:VkBindSparseInfo includes a
sname:VkDeviceGroupBindSparseInfoKHX structure, then that structure includes
device indices specifying which instance of the resources and memory are
bound.
The sname:VkDeviceGroupBindSparseInfoKHX structure is defined as:
include::../api/structs/VkDeviceGroupBindSparseInfoKHX.txt[]
* pname:sType is the type of this structure.
* pname:pNext is `NULL` or a pointer to an extension-specific structure.
* pname:resourceDeviceIndex is a device index indicating which instance of
the resource is bound.
* pname:memoryDeviceIndex is a device index indicating which instance of
the memory the resource instance is bound to.
These device indices apply to all buffer and image memory binds included in
the batch that points to this structure.
The semaphore waits and signals for the batch are executed only by the
physical device specified by the pname:resourceDeviceIndex.
If this structure is not present, pname:resourceDeviceIndex and
pname:memoryDeviceIndex are assumed to be zero.
.Valid Usage
****
* [[VUID-VkDeviceGroupBindSparseInfoKHX-resourceDeviceIndex-01118]]
pname:resourceDeviceIndex and pname:memoryDeviceIndex must: both be
valid device indices.
* [[VUID-VkDeviceGroupBindSparseInfoKHX-memoryDeviceIndex-01119]]
Each memory allocation bound in this batch must: have allocated an
instance for pname:memoryDeviceIndex.
****
include::../validity/structs/VkDeviceGroupBindSparseInfoKHX.txt[]
--
endif::VK_KHX_device_group[]
[[sparsememory-examples]]
== Examples
The following examples illustrate basic creation of sparse images and
binding them to physical memory.
[[sparsememory-examples-basic]]
=== Basic Sparse Resources
This basic example creates a normal sname:VkImage object but uses
fine-grained memory allocation to back the resource with multiple memory
ranges.
[source,c++]
---------------------------------------------------
VkDevice device;
VkQueue queue;
VkImage sparseImage;
VkAllocationCallbacks* pAllocator = NULL;
VkMemoryRequirements memoryRequirements = {};
VkDeviceSize offset = 0;
VkSparseMemoryBind binds[MAX_CHUNKS] = {}; // MAX_CHUNKS is NOT part of Vulkan
uint32_t bindCount = 0;
// ...
// Allocate image object
const VkImageCreateInfo sparseImageInfo =
{
VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO, // sType
NULL, // pNext
VK_IMAGE_CREATE_SPARSE_BINDING_BIT | ..., // flags
...
};
vkCreateImage(device, &sparseImageInfo, pAllocator, &sparseImage);
// Get memory requirements
vkGetImageMemoryRequirements(
device,
sparseImage,
&memoryRequirements);
// Bind memory in fine-grained fashion, find available memory ranges
// from potentially multiple VkDeviceMemory pools.
// (Illustration purposes only, can be optimized for perf)
while (memoryRequirements.size && bindCount < MAX_CHUNKS)
{
VkSparseMemoryBind* pBind = &binds[bindCount];
pBind->resourceOffset = offset;
AllocateOrGetMemoryRange(
device,
&memoryRequirements,
&pBind->memory,
&pBind->memoryOffset,
&pBind->size);
// memory ranges must be sized as multiples of the alignment
assert(IsMultiple(pBind->size, memoryRequirements.alignment));
assert(IsMultiple(pBind->memoryOffset, memoryRequirements.alignment));
memoryRequirements.size -= pBind->size;
offset += pBind->size;
bindCount++;
}
// Ensure all image has backing
if (memoryRequirements.size)
{
// Error condition - too many chunks
}
const VkSparseImageOpaqueMemoryBindInfo opaqueBindInfo =
{
sparseImage, // image
bindCount, // bindCount
binds // pBinds
};
const VkBindSparseInfo bindSparseInfo =
{
VK_STRUCTURE_TYPE_BIND_SPARSE_INFO, // sType
NULL, // pNext
...
1, // imageOpaqueBindCount
&opaqueBindInfo, // pImageOpaqueBinds
...
};
// vkQueueBindSparse is externally synchronized per queue object.
AcquireQueueOwnership(queue);
// Actually bind memory
vkQueueBindSparse(queue, 1, &bindSparseInfo, VK_NULL_HANDLE);
ReleaseQueueOwnership(queue);
---------------------------------------------------
[[sparsememory-examples-advanced]]
=== Advanced Sparse Resources
This more advanced example creates an arrayed color attachment / texture
image and binds only LOD zero and the required: metadata to physical memory.
[source,c++]
---------------------------------------------------
VkDevice device;
VkQueue queue;
VkImage sparseImage;
VkAllocationCallbacks* pAllocator = NULL;
VkMemoryRequirements memoryRequirements = {};
uint32_t sparseRequirementsCount = 0;
VkSparseImageMemoryRequirements* pSparseReqs = NULL;
VkSparseMemoryBind binds[MY_IMAGE_ARRAY_SIZE] = {};
VkSparseImageMemoryBind imageBinds[MY_IMAGE_ARRAY_SIZE] = {};
uint32_t bindCount = 0;
// Allocate image object (both renderable and sampleable)
const VkImageCreateInfo sparseImageInfo =
{
VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO, // sType
NULL, // pNext
VK_IMAGE_CREATE_SPARSE_RESIDENCY_BIT | ..., // flags
...
VK_FORMAT_R8G8B8A8_UNORM, // format
...
MY_IMAGE_ARRAY_SIZE, // arrayLayers
...
VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT |
VK_IMAGE_USAGE_SAMPLED_BIT, // usage
...
};
vkCreateImage(device, &sparseImageInfo, pAllocator, &sparseImage);
// Get memory requirements
vkGetImageMemoryRequirements(
device,
sparseImage,
&memoryRequirements);
// Get sparse image aspect properties
vkGetImageSparseMemoryRequirements(
device,
sparseImage,
&sparseRequirementsCount,
NULL);
pSparseReqs = (VkSparseImageMemoryRequirements*)
malloc(sparseRequirementsCount * sizeof(VkSparseImageMemoryRequirements));
vkGetImageSparseMemoryRequirements(
device,
sparseImage,
&sparseRequirementsCount,
pSparseReqs);
// Bind LOD level 0 and any required metadata to memory
for (uint32_t i = 0; i < sparseRequirementsCount; ++i)
{
if (pSparseReqs[i].formatProperties.aspectMask &
VK_IMAGE_ASPECT_METADATA_BIT)
{
// Metadata must not be combined with other aspects
assert(pSparseReqs[i].formatProperties.aspectMask ==
VK_IMAGE_ASPECT_METADATA_BIT);
if (pSparseReqs[i].formatProperties.flags &
VK_SPARSE_IMAGE_FORMAT_SINGLE_MIPTAIL_BIT)
{
VkSparseMemoryBind* pBind = &binds[bindCount];
pBind->memorySize = pSparseReqs[i].imageMipTailSize;
bindCount++;
// ... Allocate memory range
pBind->resourceOffset = pSparseReqs[i].imageMipTailOffset;
pBind->memoryOffset = /* allocated memoryOffset */;
pBind->memory = /* allocated memory */;
pBind->flags = VK_SPARSE_MEMORY_BIND_METADATA_BIT;
}
else
{
// Need a mip tail region per array layer.
for (uint32_t a = 0; a < sparseImageInfo.arrayLayers; ++a)
{
VkSparseMemoryBind* pBind = &binds[bindCount];
pBind->memorySize = pSparseReqs[i].imageMipTailSize;
bindCount++;
// ... Allocate memory range
pBind->resourceOffset = pSparseReqs[i].imageMipTailOffset +
(a * pSparseReqs[i].imageMipTailStride);
pBind->memoryOffset = /* allocated memoryOffset */;
pBind->memory = /* allocated memory */
pBind->flags = VK_SPARSE_MEMORY_BIND_METADATA_BIT;
}
}
}
else
{
// resource data
VkExtent3D lod0BlockSize =
{
AlignedDivide(
sparseImageInfo.extent.width,
pSparseReqs[i].formatProperties.imageGranularity.width);
AlignedDivide(
sparseImageInfo.extent.height,
pSparseReqs[i].formatProperties.imageGranularity.height);
AlignedDivide(
sparseImageInfo.extent.depth,
pSparseReqs[i].formatProperties.imageGranularity.depth);
}
size_t totalBlocks =
lod0BlockSize.width *
lod0BlockSize.height *
lod0BlockSize.depth;
// Each block is the same size as the alignment requirement,
// calculate total memory size for level 0
VkDeviceSize lod0MemSize = totalBlocks * memoryRequirements.alignment;
// Allocate memory for each array layer
for (uint32_t a = 0; a < sparseImageInfo.arrayLayers; ++a)
{
// ... Allocate memory range
VkSparseImageMemoryBind* pBind = &imageBinds[a];
pBind->subresource.aspectMask = pSparseReqs[i].formatProperties.aspectMask;
pBind->subresource.mipLevel = 0;
pBind->subresource.arrayLayer = a;
pBind->offset = (VkOffset3D){0, 0, 0};
pBind->extent = sparseImageInfo.extent;
pBind->memoryOffset = /* allocated memoryOffset */;
pBind->memory = /* allocated memory */;
pBind->flags = 0;
}
}
free(pSparseReqs);
}
const VkSparseImageOpaqueMemoryBindInfo opaqueBindInfo =
{
sparseImage, // image
bindCount, // bindCount
binds // pBinds
};
const VkSparseImageMemoryBindInfo imageBindInfo =
{
sparseImage, // image
sparseImageInfo.arrayLayers, // bindCount
imageBinds // pBinds
};
const VkBindSparseInfo bindSparseInfo =
{
VK_STRUCTURE_TYPE_BIND_SPARSE_INFO, // sType
NULL, // pNext
...
1, // imageOpaqueBindCount
&opaqueBindInfo, // pImageOpaqueBinds
1, // imageBindCount
&imageBindInfo, // pImageBinds
...
};
// vkQueueBindSparse is externally synchronized per queue object.
AcquireQueueOwnership(queue);
// Actually bind memory
vkQueueBindSparse(queue, 1, &bindSparseInfo, VK_NULL_HANDLE);
ReleaseQueueOwnership(queue);
---------------------------------------------------