460 lines
20 KiB
Plaintext
460 lines
20 KiB
Plaintext
// Copyright (c) 2018 Khronos Group. This work is licensed under a
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// Creative Commons Attribution 4.0 International License; see
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// http://creativecommons.org/licenses/by/4.0/
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include::meta/VK_EXT_image_drm_format_modifier.txt[]
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*Last Modified Date*::
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2018-08-29
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*IP Status*::
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No known IP claims.
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*Contributors*::
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- Antoine Labour, Google
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- Chad Versace, Google
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- James Jones, NVIDIA
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- Jason Ekstrand, Intel
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- Jőrg Wagner, ARM
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- Kristian Høgsberg Kristensen, Google
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- Ray Smith, ARM
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=== Overview
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==== Summary
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This extension provides the ability to use _DRM format modifiers_ with
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images, enabling Vulkan to better integrate with the Linux ecosystem of
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graphics, video, and display APIs.
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Its functionality closely overlaps with
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`EGL_EXT_image_dma_buf_import_modifiers`^<<VK_EXT_image_drm_format_modifier-fn2,2>>^
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and
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`EGL_MESA_image_dma_buf_export`^<<VK_EXT_image_drm_format_modifier-fn3,3>>^.
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Unlike the EGL extensions, this extension does not require the use of a
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specific handle type (such as a dma_buf) for external memory and provides
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more explicit control of image creation.
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==== Introduction to DRM Format Modifiers
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A _DRM format modifier_ is a 64-bit, vendor-prefixed, semi-opaque unsigned
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integer.
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Most _modifiers_ represent a concrete, vendor-specific tiling format for
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images.
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Some exceptions are etext:DRM_FORMAT_MOD_LINEAR (which is not
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vendor-specific); etext:DRM_FORMAT_MOD_NONE (which is an alias of
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etext:DRM_FORMAT_MOD_LINEAR due to historical accident); and
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etext:DRM_FORMAT_MOD_INVALID (which does not represent a tiling format).
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The _modifier's_ vendor prefix consists of the 8 most signficant bits.
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The canonical list of _modifiers_ and vendor prefixes is found in
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https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/include/uapi/drm/drm_fourcc.h[`drm_fourcc.h`]
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in the Linux kernel source.
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The other dominant source of _modifiers_ are vendor kernel trees.
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One goal of _modifiers_ in the Linux ecosystem is to enumerate for each
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vendor a reasonably sized set of tiling formats that are appropriate for
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images shared across processes, APIs, and/or devices, where each
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participating component may possibly be from different vendors.
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A non-goal is to enumerate all tiling formats supported by all vendors.
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Some tiling formats used internally by vendors are inappropriate for
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sharing; no _modifiers_ should be assigned to such tiling formats.
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Modifier values typically do not _describe_ memory layouts.
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More precisely, a _modifier_'s lower 56 bits usually have no structure.
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Instead, modifiers _name_ memory layouts; they name a small set of
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vendor-preferred layouts for image sharing.
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As a consequence, in each vendor namespace the modifier values are often
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sequentially allocated starting at 1.
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Each _modifier_ is usually supported by a single vendor and its name matches
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the pattern `{VENDOR}_FORMAT_MOD_*` or `DRM_FORMAT_MOD_{VENDOR}_*`.
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Examples are etext:I915_FORMAT_MOD_X_TILED and
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etext:DRM_FORMAT_MOD_BROADCOM_VC4_T_TILED.
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An exception is etext:DRM_FORMAT_MOD_LINEAR, which is supported by most
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vendors.
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Many APIs in Linux use _modifiers_ to negotiate and specify the memory
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layout of shared images.
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For example, a Wayland compositor and Wayland client may, by relaying
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_modifiers_ over the Wayland protocol `zwp_linux_dmabuf_v1`, negotiate a
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vendor-specific tiling format for a shared stext:wl_buffer.
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The client may allocate the underlying memory for the stext:wl_buffer with
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GBM, providing the chosen _modifier_ to fname:gbm_bo_create_with_modifiers.
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The client may then import the stext:wl_buffer into Vulkan for producing
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image content, providing the resource's dma_buf to
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slink:VkImportMemoryFdInfo and its _modifier_ to
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slink:VkImageDrmFormatModifierExplicitCreateInfoEXT.
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The compositor may then import the stext:wl_buffer into OpenGL for sampling,
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providing the resource's dma_buf and _modifier_ to fname:eglCreateImage.
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The compositor may also bypass OpenGL and submit the stext:wl_buffer
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directly to the kernel's display API, providing the dma_buf and _modifier_
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through stext:drm_mode_fb_cmd2.
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==== Format Translation
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_Modifier_-capable APIs often pair _modifiers_ with DRM formats, which are
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defined in
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https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/include/uapi/drm/drm_fourcc.h[`drm_fourcc.h`].
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However, `VK_EXT_image_drm_format_modifier` uses elink:VkFormat instead of
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DRM formats.
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The application must convert between elink:VkFormat and DRM format when it
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sends or receives a DRM format to or from an external API.
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The mapping from elink:VkFormat to DRM format is lossy.
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Therefore, when receiving a DRM format from an external API, often the
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application must use information from the external API to accurately map the
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DRM format to a elink:VkFormat.
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For example, DRM formats do not distinguish between RGB and sRGB (as of
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2018-03-28); external information is required to identify the image's
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colorspace.
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The mapping between elink:VkFormat and DRM format is also incomplete.
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For some DRM formats there exist no corresponding Vulkan format, and for
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some Vulkan formats there exist no corresponding DRM format.
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==== Usage Patterns
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Three primary usage patterns are intended for this extension:
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* *Negotiation.* The application negotiates with _modifier_-aware,
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external components to determine sets of image creation parameters
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supported among all components.
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+
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--
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In the Linux ecosystem, the negotiation usually assumes the image is a 2D,
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single-sampled, non-mipmapped, non-array image; this extension permits that
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assumption but does not require it.
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The result of the negotiation usually resembles a set of tuples such as
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_(drmFormat, drmFormatModifier)_, where each participating component
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supports all tuples in the set.
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Many details of this negotiation—such as the protocol used during
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negotiation, the set of image creation parameters expressable in the
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protocol, and how the protocol chooses which process and which API will
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create the image—are outside the scope of this specification.
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In this extension, flink:vkGetPhysicalDeviceFormatProperties2 with
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slink:VkDrmFormatModifierPropertiesListEXT serves a primary role during the
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negotiation, and flink:vkGetPhysicalDeviceImageFormatProperties2 with
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slink:VkPhysicalDeviceImageDrmFormatModifierInfoEXT serves a secondary role.
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--
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* *Import.* The application imports an image with a _modifier_.
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+
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--
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In this pattern, the application receives from an external source the
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image's memory and its creation parameters, which are often the result of
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the negotiation described above.
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Some image creation parameters are implicitly defined by the external
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source; for example, ename:VK_IMAGE_TYPE_2D is often assumed.
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Some image creation parameters are usually explicit, such as the image's
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pname:format, pname:drmFormatModifier, and pname:extent; and each plane's
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pname:offset and pname:rowPitch.
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Before creating the image, the application first verifies that the physical
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device supports the received creation parameters by querying
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flink:vkGetPhysicalDeviceFormatProperties2 with
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slink:VkDrmFormatModifierPropertiesListEXT and
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flink:vkGetPhysicalDeviceImageFormatProperties2 with
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slink:VkPhysicalDeviceImageDrmFormatModifierInfoEXT.
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Then the application creates the image by chaining
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slink:VkImageDrmFormatModifierExplicitCreateInfoEXT and
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slink:VkExternalMemoryImageCreateInfo onto slink:VkImageCreateInfo.
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--
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* *Export.* The application creates an image and allocates its memory.
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Then the application exports to _modifier_-aware consumers the image's
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memory handles; its creation parameters; its _modifier_; and the
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<<VkSubresourceLayout,pname:offset>>,
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<<VkSubresourceLayout,pname:size>>, and
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<<VkSubresourceLayout,pname:rowPitch>> of each _memory plane_.
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+
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--
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In this pattern, the Vulkan device is the authority for the image; it is the
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allocator of the image's memory and the decider of the image's creation
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parameters.
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When choosing the image's creation parameters, the application usually
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chooses a tuple _(format, drmFormatModifier)_ from the result of the
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negotiation described above.
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The negotiation's result often contains multiple tuples that share the same
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format but differ in their _modifier_.
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In this case, the application should defer the choice of the image's
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_modifier_ to the Vulkan implementation by providing all such _modifiers_ to
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slink:VkImageDrmFormatModifierListCreateInfoEXT::pname:pDrmFormatModifiers;
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and the implementation should choose from pname:pDrmFormatModifiers the
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optimal _modifier_ in consideration with the other image parameters.
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The application creates the image by chaining
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slink:VkImageDrmFormatModifierListCreateInfoEXT and
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slink:VkExternalMemoryImageCreateInfo onto slink:VkImageCreateInfo.
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The protocol and APIs by which the application will share the image with
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external consumers will likely determine the value of
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slink:VkExternalMemoryImageCreateInfo::pname:handleTypes.
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The implementation chooses for the image an optimal _modifier_ from
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slink:VkImageDrmFormatModifierListCreateInfoEXT::pname:pDrmFormatModifiers.
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The application then queries the implementation-chosen _modifier_ with
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flink:vkGetImageDrmFormatModifierPropertiesEXT, and queries the memory
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layout of each plane with flink:vkGetImageSubresourceLayout.
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The application then allocates the image's memory with
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slink:VkMemoryAllocateInfo, adding chained extension structures for external
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memory; binds it to the image; and exports the memory, for example, with
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flink:vkGetMemoryFd.
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Finally, the application sends the image's creation parameters, its
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_modifier_, its per-plane memory layout, and the exported memory handle to
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the external consumers.
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The details of how the application transmits this information to external
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consumers is outside the scope of this specification.
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--
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==== Prior Art
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Extension
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`EGL_EXT_image_dma_buf_import`^<<VK_EXT_image_drm_format_modifier-fn1,1>>^
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introduced the ability to create an stext:EGLImage by importing for each
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plane a dma_buf, offset, and row pitch.
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Later, extension
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`EGL_EXT_image_dma_buf_import_modifiers`^<<VK_EXT_image_drm_format_modifier-fn2,2>>^
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introduced the ability to query which combination of formats and _modifiers_
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the implementation supports and to specify _modifiers_ during creation of
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the stext:EGLImage.
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Extension
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`EGL_MESA_image_dma_buf_export`^<<VK_EXT_image_drm_format_modifier-fn3,3>>^
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is the inverse of `EGL_EXT_image_dma_buf_import_modifiers`.
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The Linux kernel modesetting API (KMS), when configuring the display's
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framebuffer with `struct
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drm_mode_fb_cmd2`^<<VK_EXT_image_drm_format_modifier-fn4,4>>^, allows one to
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specify the frambuffer's _modifier_ as well as a per-plane memory handle,
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offset, and row pitch.
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GBM, a graphics buffer manager for Linux, allows creation of a `gbm_bo`
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(that is, a graphics _buffer object_) by importing data similar to that in
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`EGL_EXT_image_dma_buf_import_modifiers`^<<VK_EXT_image_drm_format_modifier-fn1,1>>^;
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and symmetrically allows exporting the same data from the `gbm_bo`.
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See the references to _modifier_ and _plane_ in
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`gbm.h`^<<VK_EXT_image_drm_format_modifier-fn5,5>>^.
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=== New Object Types
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None.
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=== New Enum Constants
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* Extending elink:VkResult:
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** ename:VK_ERROR_INVALID_DRM_FORMAT_MODIFIER_PLANE_LAYOUT_EXT
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* Extending elink:VkStructureType:
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** ename:VK_STRUCTURE_TYPE_DRM_FORMAT_MODIFIER_PROPERTIES_LIST_EXT
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** ename:VK_STRUCTURE_TYPE_DRM_FORMAT_MODIFIER_PROPERTIES_EXT
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** ename:VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_IMAGE_DRM_FORMAT_MODIFIER_INFO_EXT
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** ename:VK_STRUCTURE_TYPE_IMAGE_DRM_FORMAT_MODIFIER_LIST_CREATE_INFO_EXT
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** ename:VK_STRUCTURE_TYPE_IMAGE_EXPLICIT_DRM_FORMAT_MODIFIER_CREATE_INFO_EXT
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** ename:VK_STRUCTURE_TYPE_IMAGE_DRM_FORMAT_MODIFIER_PROPERTIES_EXT
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* Extending elink:VkImageTiling:
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** ename:VK_IMAGE_TILING_DRM_FORMAT_MODIFIER_EXT
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* Extending elink:VkImageAspectFlagBits:
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** ename:VK_IMAGE_ASPECT_MEMORY_PLANE_0_BIT_EXT
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** ename:VK_IMAGE_ASPECT_MEMORY_PLANE_1_BIT_EXT
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** ename:VK_IMAGE_ASPECT_MEMORY_PLANE_2_BIT_EXT
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** ename:VK_IMAGE_ASPECT_MEMORY_PLANE_3_BIT_EXT
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=== New Enums
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None.
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=== New Structures
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* Extends elink:VkFormatProperties2:
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** slink:VkDrmFormatModifierPropertiesListEXT
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* Member of slink:VkDrmFormatModifierPropertiesListEXT:
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** slink:VkDrmFormatModifierPropertiesEXT
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* Extends slink:VkPhysicalDeviceImageFormatInfo2:
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** slink:VkPhysicalDeviceImageDrmFormatModifierInfoEXT
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* Extends slink:VkImageCreateInfo:
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** slink:VkImageDrmFormatModifierListCreateInfoEXT
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** slink:VkImageDrmFormatModifierExplicitCreateInfoEXT
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* Parameter to flink:vkGetImageDrmFormatModifierPropertiesEXT:
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** slink:VkImageDrmFormatModifierPropertiesEXT
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=== New Functions
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* flink:vkGetImageDrmFormatModifierPropertiesEXT
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=== Issues
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1) Should this extension define a single DRM format modifier per
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sname:VkImage? Or define one per plane?
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+
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--
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*RESOLVED*: There exists a single DRM format modifier per sname:VkImage.
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*DISCUSSION*: Prior art, such as
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`EGL_EXT_image_dma_buf_import_modifiers`^<<VK_EXT_image_drm_format_modifier-fn2,2>>^,
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`struct drm_mode_fb_cmd2`^<<VK_EXT_image_drm_format_modifier-fn4,4>>^, and
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`struct
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gbm_import_fd_modifier_data`^<<VK_EXT_image_drm_format_modifier-fn5,5>>^,
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allows defining one _modifier_ per plane.
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However, developers of the GBM and kernel APIs concede it was a mistake.
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Beginning in Linux 4.10, the kernel requires that the application provide
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the same DRM format _modifier_ for each plane.
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(See Linux commit
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https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/?id=bae781b259269590109e8a4a8227331362b88212[bae781b259269590109e8a4a8227331362b88212]).
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And GBM provides an entrypoint, ftext:gbm_bo_get_modifier, for querying the
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_modifier_ of the image but does not provide one to query the modifier of
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individual planes.
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--
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2) When creating an image with
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slink:VkImageDrmFormatModifierExplicitCreateInfoEXT, which is typically
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used when _importing_ an image, should the application explicitly provide
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the size of each plane?
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+
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--
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*RESOLVED*: No.
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The application must: not provide the size.
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To enforce this, the API requires that
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slink:VkImageDrmFormatModifierExplicitCreateInfoEXT::pname:pPlaneLayouts::<<VkSubresourceLayout,pname:size>>
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must: be 0.
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*DISCUSSION*: Prior art, such as
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`EGL_EXT_image_dma_buf_import_modifiers`^<<VK_EXT_image_drm_format_modifier-fn2,2>>^,
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`struct drm_mode_fb_cmd2`^<<VK_EXT_image_drm_format_modifier-fn4,4>>^, and
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`struct
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gbm_import_fd_modifier_data`^<<VK_EXT_image_drm_format_modifier-fn5,5>>^,
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omits from the API the size of each plane.
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Instead, the APIs infer each plane's size from the import parameters, which
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include the image's pixel format and a dma_buf, offset, and row pitch for
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each plane.
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However, Vulkan differs from EGL and GBM with regards to image creation in
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the following ways:
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.Differences in Image Creation
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- *Undedicated allocation by default.* When importing or exporting a set
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of dma_bufs as an stext:EGLImage or stext:gbm_bo, common practice
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mandates that each dma_buf's memory be dedicated (in the sense of
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`VK_KHR_dedicated_allocation`) to the image (though not necessarily
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dedicated to a single plane).
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In particular, neither the GBM documentation nor the EGL extension
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specifications explicitly state this requirement, but in light of common
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practice this is likely due to under-specification rather than
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intentional omission.
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In contrast, `VK_EXT_image_drm_format_modifier` permits, but does not
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require, the implementation to require dedicated allocations for images
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created with ename:VK_IMAGE_TILING_DRM_FORMAT_MODIFIER_EXT.
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- *Separation of image creation and memory allocation.* When importing a
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set of dma_bufs as an stext:EGLImage or stext:gbm_bo, EGL and GBM create
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the image resource and bind it to memory (the dma_bufs) simultaneously.
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This allows EGL and GBM to query each dma_buf's size during image
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creation.
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In Vulkan, image creation and memory allocation are independent unless a
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dedicated allocation is used (as in `VK_KHR_dedicated_allocation`).
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Therefore, without requiring dedicated allocation, Vulkan cannot query
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the size of each dma_buf (or other external handle) when calculating the
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image's memory layout.
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Even if dedication allocation were required, Vulkan cannot calculate the
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image's memory layout until after the image is bound to its dma_ufs.
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The above differences complicate the potential inference of plane size in
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Vulkan.
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Consider the following problematic cases:
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.Problematic Plane Size Calculations
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- *Padding.* Some plane of the image may require implementation-dependent
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padding.
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- *Metadata.* For some _modifiers_, the image may have a metadata plane
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which requires a non-trivial calculation to determine its size.
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- *Mipmapped, array, and 3D images.* The implementation may support
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ename:VK_IMAGE_TILING_DRM_FORMAT_MODIFIER_EXT for images whose
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pname:mipLevels, pname:arrayLayers, or pname:depth is greater than 1.
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For such images with certain _modifiers_, the calculation of each
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plane's size may be non-trivial.
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However, an application-provided plane size solves none of the above
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problems.
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For simplicity, consider an external image with a single memory plane.
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The implementation is obviously capable calculating the image's size when
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its tiling is ename:VK_IMAGE_TILING_OPTIMAL.
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Likewise, any reasonable implementation is capable of calculating the
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image's size when its tiling uses a supported _modifier_.
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Suppose that the external image's size is smaller than the
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implementation-calculated size.
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If the application provided the external image's size to
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slink:vkCreateImage, the implementation would observe the mismatched size
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and recognize its inability to comprehend the external image's layout
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(unless the implementation used the application-provided size to select a
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refinement of the tiling layout indicated by the _modifier_, which is
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strongly discouraged).
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The implementation would observe the conflict, and reject image creation
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with ename:VK_ERROR_INVALID_DRM_FORMAT_MODIFIER_PLANE_LAYOUT_EXT.
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On the other hand, if the application did not provide the external image's
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size to slink:vkCreateImage, then the application would observe after
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calling flink:vkGetImageMemoryRequirements that the external image's size is
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less than the size required by the implementation.
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The application would observe the conflict and refuse to bind the
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sname:VkImage to the external memory.
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In both cases, the result is explicit failure.
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Suppose that the external image's size is larger than the
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implementation-calculated size.
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If the application provided the external image's size to
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slink:vkCreateImage, for reasons similar to above the implementation would
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observe the mismatched size and recognize its inability to comprehend the
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image data residing in the extra size.
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The implementation, however, must assume that image data resides in the
|
|
entire size provided by the application.
|
|
The implementation would observe the conflict and reject image creation with
|
|
ename:VK_ERROR_INVALID_DRM_FORMAT_MODIFIER_PLANE_LAYOUT_EXT.
|
|
On the other hand, if the application did not provide the external image's
|
|
size to flink:vkCreateImage, then the application would observe after
|
|
calling flink:vkGetImageMemoryRequirements that the external image's size is
|
|
larger than the implementation-usable size.
|
|
The application would observe the conflict and refuse to bind the
|
|
sname:VkImage to the external memory.
|
|
In both cases, the result is explicit failure.
|
|
|
|
Therefore, an application-provided size provides no benefit, and this
|
|
extension should not require it.
|
|
This decision renders slink:VkSubresourceLayout::pname:size an unused field
|
|
during image creation, and thus introduces a risk that implementations may
|
|
require applications to submit sideband creation parameters in the unused
|
|
field.
|
|
To prevent implementations from relying on sideband data, this extension
|
|
_requires_ the application to set pname:size to 0.
|
|
--
|
|
|
|
==== References
|
|
|
|
. [[VK_EXT_image_drm_format_modifier-fn1]]
|
|
https://www.khronos.org/registry/EGL/extensions/EXT/EGL_EXT_image_dma_buf_import.txt[EGL_EXT_image_dma_buf_import]
|
|
. [[VK_EXT_image_drm_format_modifier-fn2]]
|
|
https://www.khronos.org/registry/EGL/extensions/EXT/EGL_EXT_image_dma_buf_import_modifiers.txt[EGL_EXT_image_dma_buf_import_modifiers]
|
|
. [[VK_EXT_image_drm_format_modifier-fn3]]
|
|
https://www.khronos.org/registry/EGL/extensions/MESA/EGL_MESA_image_dma_buf_export.txt[EGL_MESA_image_dma_buf_export]
|
|
. [[VK_EXT_image_drm_format_modifier-fn4]]
|
|
https://git.kernel.org/cgit/linux/kernel/git/torvalds/linux.git/tree/include/uapi/drm/drm_mode.h?id=refs/tags/v4.10#n392[struct
|
|
drm_mode_fb_cmd2]
|
|
. [[VK_EXT_image_drm_format_modifier-fn5]]
|
|
https://cgit.freedesktop.org/mesa/mesa/tree/src/gbm/main/gbm.h?id=refs/tags/mesa-18.0.0-rc1[gbm.h]
|
|
|
|
==== Version History
|
|
|
|
* Revision 1.0, 2018-08-29 (Chad Versace)
|
|
- First stable revision
|