Documentation/gpu/afbc.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0+

 ===================================
  Arm Framebuffer Compression (AFBC)
 ===================================

 AFBC is a proprietary lossless image compression protocol and format.
 It provides fine-grained random access and minimizes the amount of
 data transferred between IP blocks.

 AFBC can be enabled on drivers which support it via use of the AFBC
 format modifiers defined in drm_fourcc.h. See DRM_FORMAT_MOD_ARM_AFBC(*).

 All users of the AFBC modifiers must follow the usage guidelines laid
 out in this document, to ensure compatibility across different AFBC
 producers and consumers.

 Components and Ordering
 =======================

 AFBC streams can contain several components - where a component
 corresponds to a color channel (i.e. R, G, B, X, A, Y, Cb, Cr).
 The assignment of input/output color channels must be consistent
 between the encoder and the decoder for correct operation, otherwise
 the consumer will interpret the decoded data incorrectly.

 Furthermore, when the lossless colorspace transform is used
 (AFBC_FORMAT_MOD_YTR, which should be enabled for RGB buffers for
 maximum compression efficiency), the component order must be:

  * Component 0: R
  * Component 1: G
  * Component 2: B

 The component ordering is communicated via the fourcc code in the
 fourcc:modifier pair. In general, component '0' is considered to
 reside in the least-significant bits of the corresponding linear
 format. For example, COMP(bits):

  * DRM_FORMAT_ABGR8888

    * Component 0: R(8)
    * Component 1: G(8)
    * Component 2: B(8)
    * Component 3: A(8)

  * DRM_FORMAT_BGR888

    * Component 0: R(8)
    * Component 1: G(8)
    * Component 2: B(8)

  * DRM_FORMAT_YUYV

    * Component 0: Y(8)
    * Component 1: Cb(8, 2x1 subsampled)
    * Component 2: Cr(8, 2x1 subsampled)

 In AFBC, 'X' components are not treated any differently from any other
 component. Therefore, an AFBC buffer with fourcc DRM_FORMAT_XBGR8888
 encodes with 4 components, like so:

  * DRM_FORMAT_XBGR8888

    * Component 0: R(8)
    * Component 1: G(8)
    * Component 2: B(8)
    * Component 3: X(8)

 Please note, however, that the inclusion of a "wasted" 'X' channel is
 bad for compression efficiency, and so it's recommended to avoid
 formats containing 'X' bits. If a fourth component is
 required/expected by the encoder/decoder, then it is recommended to
 instead use an equivalent format with alpha, setting all alpha bits to
 '1'. If there is no requirement for a fourth component, then a format
 which doesn't include alpha can be used, e.g. DRM_FORMAT_BGR888.

 Number of Planes
 ================

 Formats which are typically multi-planar in linear layouts (e.g. YUV
 420), can be encoded into one, or multiple, AFBC planes. As with
 component order, the encoder and decoder must agree about the number
 of planes in order to correctly decode the buffer. The fourcc code is
 used to determine the number of encoded planes in an AFBC buffer,
 matching the number of planes for the linear (unmodified) format.
 Within each plane, the component ordering also follows the fourcc
 code:

 For example:

  * DRM_FORMAT_YUYV: nplanes = 1

    * Plane 0:

      * Component 0: Y(8)
      * Component 1: Cb(8, 2x1 subsampled)
      * Component 2: Cr(8, 2x1 subsampled)

  * DRM_FORMAT_NV12: nplanes = 2

    * Plane 0:

      * Component 0: Y(8)

    * Plane 1:

      * Component 0: Cb(8, 2x1 subsampled)
      * Component 1: Cr(8, 2x1 subsampled)

 Cross-device interoperability
 =============================

 For maximum compatibility across devices, the table below defines
 canonical formats for use between AFBC-enabled devices. Formats which
 are listed here must be used exactly as specified when using the AFBC
 modifiers. Formats which are not listed should be avoided.

 .. flat-table:: AFBC formats

    * - Fourcc code
      - Description
      - Planes/Components

    * - DRM_FORMAT_ABGR2101010
      - 10-bit per component RGB, with 2-bit alpha
      - Plane 0: 4 components
               * Component 0: R(10)
               * Component 1: G(10)
               * Component 2: B(10)
               * Component 3: A(2)

    * - DRM_FORMAT_ABGR8888
      - 8-bit per component RGB, with 8-bit alpha
      - Plane 0: 4 components
               * Component 0: R(8)
               * Component 1: G(8)
               * Component 2: B(8)
               * Component 3: A(8)

    * - DRM_FORMAT_BGR888
      - 8-bit per component RGB
      - Plane 0: 3 components
               * Component 0: R(8)
               * Component 1: G(8)
               * Component 2: B(8)

    * - DRM_FORMAT_BGR565
      - 5/6-bit per component RGB
      - Plane 0: 3 components
               * Component 0: R(5)
               * Component 1: G(6)
               * Component 2: B(5)

    * - DRM_FORMAT_ABGR1555
      - 5-bit per component RGB, with 1-bit alpha
      - Plane 0: 4 components
               * Component 0: R(5)
               * Component 1: G(5)
               * Component 2: B(5)
               * Component 3: A(1)

    * - DRM_FORMAT_VUY888
      - 8-bit per component YCbCr 444, single plane
      - Plane 0: 3 components
               * Component 0: Y(8)
               * Component 1: Cb(8)
               * Component 2: Cr(8)

    * - DRM_FORMAT_VUY101010
      - 10-bit per component YCbCr 444, single plane
      - Plane 0: 3 components
               * Component 0: Y(10)
               * Component 1: Cb(10)
               * Component 2: Cr(10)

    * - DRM_FORMAT_YUYV
      - 8-bit per component YCbCr 422, single plane
      - Plane 0: 3 components
               * Component 0: Y(8)
               * Component 1: Cb(8, 2x1 subsampled)
               * Component 2: Cr(8, 2x1 subsampled)

    * - DRM_FORMAT_NV16
      - 8-bit per component YCbCr 422, two plane
      - Plane 0: 1 component
               * Component 0: Y(8)
        Plane 1: 2 components
               * Component 0: Cb(8, 2x1 subsampled)
               * Component 1: Cr(8, 2x1 subsampled)

    * - DRM_FORMAT_Y210
      - 10-bit per component YCbCr 422, single plane
      - Plane 0: 3 components
               * Component 0: Y(10)
               * Component 1: Cb(10, 2x1 subsampled)
               * Component 2: Cr(10, 2x1 subsampled)

    * - DRM_FORMAT_P210
      - 10-bit per component YCbCr 422, two plane
      - Plane 0: 1 component
               * Component 0: Y(10)
        Plane 1: 2 components
               * Component 0: Cb(10, 2x1 subsampled)
               * Component 1: Cr(10, 2x1 subsampled)

    * - DRM_FORMAT_YUV420_8BIT
      - 8-bit per component YCbCr 420, single plane
      - Plane 0: 3 components
               * Component 0: Y(8)
               * Component 1: Cb(8, 2x2 subsampled)
               * Component 2: Cr(8, 2x2 subsampled)

    * - DRM_FORMAT_YUV420_10BIT
      - 10-bit per component YCbCr 420, single plane
      - Plane 0: 3 components
               * Component 0: Y(10)
               * Component 1: Cb(10, 2x2 subsampled)
               * Component 2: Cr(10, 2x2 subsampled)

    * - DRM_FORMAT_NV12
      - 8-bit per component YCbCr 420, two plane
      - Plane 0: 1 component
               * Component 0: Y(8)
        Plane 1: 2 components
               * Component 0: Cb(8, 2x2 subsampled)
               * Component 1: Cr(8, 2x2 subsampled)

    * - DRM_FORMAT_P010
      - 10-bit per component YCbCr 420, two plane
      - Plane 0: 1 component
               * Component 0: Y(10)
        Plane 1: 2 components
               * Component 0: Cb(10, 2x2 subsampled)
               * Component 1: Cr(10, 2x2 subsampled)
	.. SPDX-License-Identifier: GPL-2.0+

	===================================
	Arm Framebuffer Compression (AFBC)
	===================================

	AFBC is a proprietary lossless image compression protocol and format.
	It provides fine-grained random access and minimizes the amount of
	data transferred between IP blocks.

	AFBC can be enabled on drivers which support it via use of the AFBC
	format modifiers defined in drm_fourcc.h. See DRM_FORMAT_MOD_ARM_AFBC(*).

	All users of the AFBC modifiers must follow the usage guidelines laid
	out in this document, to ensure compatibility across different AFBC
	producers and consumers.

	Components and Ordering
	=======================

	AFBC streams can contain several components - where a component
	corresponds to a color channel (i.e. R, G, B, X, A, Y, Cb, Cr).
	The assignment of input/output color channels must be consistent
	between the encoder and the decoder for correct operation, otherwise
	the consumer will interpret the decoded data incorrectly.

	Furthermore, when the lossless colorspace transform is used
	(AFBC_FORMAT_MOD_YTR, which should be enabled for RGB buffers for
	maximum compression efficiency), the component order must be:

	* Component 0: R
	* Component 1: G
	* Component 2: B

	The component ordering is communicated via the fourcc code in the
	fourcc:modifier pair. In general, component '0' is considered to
	reside in the least-significant bits of the corresponding linear
	format. For example, COMP(bits):

	* DRM_FORMAT_ABGR8888

	* Component 0: R(8)
	* Component 1: G(8)
	* Component 2: B(8)
	* Component 3: A(8)

	* DRM_FORMAT_BGR888

	* Component 0: R(8)
	* Component 1: G(8)
	* Component 2: B(8)

	* DRM_FORMAT_YUYV

	* Component 0: Y(8)
	* Component 1: Cb(8, 2x1 subsampled)
	* Component 2: Cr(8, 2x1 subsampled)

	In AFBC, 'X' components are not treated any differently from any other
	component. Therefore, an AFBC buffer with fourcc DRM_FORMAT_XBGR8888
	encodes with 4 components, like so:

	* DRM_FORMAT_XBGR8888

	* Component 0: R(8)
	* Component 1: G(8)
	* Component 2: B(8)
	* Component 3: X(8)

	Please note, however, that the inclusion of a "wasted" 'X' channel is
	bad for compression efficiency, and so it's recommended to avoid
	formats containing 'X' bits. If a fourth component is
	required/expected by the encoder/decoder, then it is recommended to
	instead use an equivalent format with alpha, setting all alpha bits to
	'1'. If there is no requirement for a fourth component, then a format
	which doesn't include alpha can be used, e.g. DRM_FORMAT_BGR888.

	Number of Planes
	================

	Formats which are typically multi-planar in linear layouts (e.g. YUV
	420), can be encoded into one, or multiple, AFBC planes. As with
	component order, the encoder and decoder must agree about the number
	of planes in order to correctly decode the buffer. The fourcc code is
	used to determine the number of encoded planes in an AFBC buffer,
	matching the number of planes for the linear (unmodified) format.
	Within each plane, the component ordering also follows the fourcc
	code:

	For example:

	* DRM_FORMAT_YUYV: nplanes = 1

	* Plane 0:

	* Component 0: Y(8)
	* Component 1: Cb(8, 2x1 subsampled)
	* Component 2: Cr(8, 2x1 subsampled)

	* DRM_FORMAT_NV12: nplanes = 2

	* Plane 0:

	* Component 0: Y(8)

	* Plane 1:

	* Component 0: Cb(8, 2x1 subsampled)
	* Component 1: Cr(8, 2x1 subsampled)

	Cross-device interoperability
	=============================

	For maximum compatibility across devices, the table below defines
	canonical formats for use between AFBC-enabled devices. Formats which
	are listed here must be used exactly as specified when using the AFBC
	modifiers. Formats which are not listed should be avoided.

	.. flat-table:: AFBC formats

	* - Fourcc code
	- Description
	- Planes/Components

	* - DRM_FORMAT_ABGR2101010
	- 10-bit per component RGB, with 2-bit alpha
	- Plane 0: 4 components
	* Component 0: R(10)
	* Component 1: G(10)
	* Component 2: B(10)
	* Component 3: A(2)

	* - DRM_FORMAT_ABGR8888
	- 8-bit per component RGB, with 8-bit alpha
	- Plane 0: 4 components
	* Component 0: R(8)
	* Component 1: G(8)
	* Component 2: B(8)
	* Component 3: A(8)

	* - DRM_FORMAT_BGR888
	- 8-bit per component RGB
	- Plane 0: 3 components
	* Component 0: R(8)
	* Component 1: G(8)
	* Component 2: B(8)

	* - DRM_FORMAT_BGR565
	- 5/6-bit per component RGB
	- Plane 0: 3 components
	* Component 0: R(5)
	* Component 1: G(6)
	* Component 2: B(5)

	* - DRM_FORMAT_ABGR1555
	- 5-bit per component RGB, with 1-bit alpha
	- Plane 0: 4 components
	* Component 0: R(5)
	* Component 1: G(5)
	* Component 2: B(5)
	* Component 3: A(1)

	* - DRM_FORMAT_VUY888
	- 8-bit per component YCbCr 444, single plane
	- Plane 0: 3 components
	* Component 0: Y(8)
	* Component 1: Cb(8)
	* Component 2: Cr(8)

	* - DRM_FORMAT_VUY101010
	- 10-bit per component YCbCr 444, single plane
	- Plane 0: 3 components
	* Component 0: Y(10)
	* Component 1: Cb(10)
	* Component 2: Cr(10)

	* - DRM_FORMAT_YUYV
	- 8-bit per component YCbCr 422, single plane
	- Plane 0: 3 components
	* Component 0: Y(8)
	* Component 1: Cb(8, 2x1 subsampled)
	* Component 2: Cr(8, 2x1 subsampled)

	* - DRM_FORMAT_NV16
	- 8-bit per component YCbCr 422, two plane
	- Plane 0: 1 component
	* Component 0: Y(8)
	Plane 1: 2 components
	* Component 0: Cb(8, 2x1 subsampled)
	* Component 1: Cr(8, 2x1 subsampled)

	* - DRM_FORMAT_Y210
	- 10-bit per component YCbCr 422, single plane
	- Plane 0: 3 components
	* Component 0: Y(10)
	* Component 1: Cb(10, 2x1 subsampled)
	* Component 2: Cr(10, 2x1 subsampled)

	* - DRM_FORMAT_P210
	- 10-bit per component YCbCr 422, two plane
	- Plane 0: 1 component
	* Component 0: Y(10)
	Plane 1: 2 components
	* Component 0: Cb(10, 2x1 subsampled)
	* Component 1: Cr(10, 2x1 subsampled)

	* - DRM_FORMAT_YUV420_8BIT
	- 8-bit per component YCbCr 420, single plane
	- Plane 0: 3 components
	* Component 0: Y(8)
	* Component 1: Cb(8, 2x2 subsampled)
	* Component 2: Cr(8, 2x2 subsampled)

	* - DRM_FORMAT_YUV420_10BIT
	- 10-bit per component YCbCr 420, single plane
	- Plane 0: 3 components
	* Component 0: Y(10)
	* Component 1: Cb(10, 2x2 subsampled)
	* Component 2: Cr(10, 2x2 subsampled)

	* - DRM_FORMAT_NV12
	- 8-bit per component YCbCr 420, two plane
	- Plane 0: 1 component
	* Component 0: Y(8)
	Plane 1: 2 components
	* Component 0: Cb(8, 2x2 subsampled)
	* Component 1: Cr(8, 2x2 subsampled)

	* - DRM_FORMAT_P010
	- 10-bit per component YCbCr 420, two plane
	- Plane 0: 1 component
	* Component 0: Y(10)
	Plane 1: 2 components
	* Component 0: Cb(10, 2x2 subsampled)
	* Component 1: Cr(10, 2x2 subsampled)