drm/fourcc: Add AFBC yuv fourccs for Mali
As we look to enable AFBC using DRM format modifiers, we run into problems which we've historically handled via vendor-private details (i.e. gralloc, on Android). AFBC (as an encoding) is fully flexible, and for example YUV data can be encoded into 1, 2 or 3 encoded "planes", much like the linear equivalents. Component order is also meaningful, as AFBC doesn't necessarily care about what each "channel" of the data it encodes contains. Therefore ABGR8888 and RGBA8888 can be encoded in AFBC with different representations. Similarly, 'X' components may be encoded into AFBC streams in cases where a decoder expects to decode a 4th component. In addition, AFBC is a licensable IP, meaning that to support the ecosystem we need to ensure that _all_ AFBC users are able to describe the encodings that they need. This is much better achieved by preserving meaning in the fourcc codes when they are combined with an AFBC modifier. In essence, we want to use the modifier to describe the parameters of the AFBC encode/decode, and use the fourcc code to describe the data being encoded/decoded. To do anything different would be to introduce redundancy - we would need to duplicate in the modifier information which is _already_ conveyed clearly and non-ambigiously by a fourcc code. I hope that for RGB this is non-controversial. (BGRA8888 + MODIFIER_AFBC) is a different format from (RGBA8888 + MODIFIER_AFBC). Possibly more controversial is that (XBGR8888 + MODIFIER_AFBC) is different from (BGR888 + MODIFIER_AFBC). I understand that in some schemes it is not the case - but in AFBC it is so. Where we run into problems is where there are not already fourcc codes which represent the data which the AFBC encoder/decoder is processing. To that end, we want to introduce new fourcc codes to describe the data being encoded/decoded, in the places where none of the existing fourcc codes are applicable. Where we don't support an equivalent non-compressed layout, or where no "obvious" linear layout exists, we are proposing adding fourcc codes which have no associated linear layout - because any layout we proposed would be completely arbitrary. Some formats are following the naming conventions from [2]. The summary of the new formats is: DRM_FORMAT_VUY888 - Packed 8-bit YUV 444. Y followed by U then V. DRM_FORMAT_VUY101010 - Packed 10-bit YUV 444. Y followed by U then V. No defined linear encoding. DRM_FORMAT_Y210 - Packed 10-bit YUV 422. Y followed by U (then Y) then V. 10-bit samples in 16-bit words. DRM_FORMAT_Y410 - Packed 10-bit YUV 444, with 2-bit alpha. DRM_FORMAT_P210 - Semi-planar 10-bit YUV 422. Y plane, followed by interleaved U-then-V plane. 10-bit samples in 16-bit words. DRM_FORMAT_YUV420_8BIT - Packed 8-bit YUV 420. Y followed by U then V. No defined linear encoding DRM_FORMAT_YUV420_10BIT - Packed 10-bit YUV 420. Y followed by U then V. No defined linear encoding Please also note that in the absence of AFBC, we would still need to add Y410, Y210 and P210. Full rationale follows: YUV 444 8-bit, 1-plane ---------------------- The currently defined AYUV format encodes a 4th alpha component, which makes it unsuitable for representing a 3-component YUV 444 AFBC stream. The proposed[1] XYUV format which is supported by Mali-DP in linear layout is also unsuitable, because the component order is the opposite of the AFBC version, and it encodes a 4th 'X' component. DRM_FORMAT_VUY888 is the "obvious" format for a 3-component, packed, YUV 444 8-bit format, with the component order which our HW expects to encode/decode. It conforms to the same naming convention as the existing packed YUV 444 format. The naming here is meant to be consistent with DRM_FORMAT_AYUV and DRM_FORMAT_XYUV[1] YUV 444 10-bit, 1-plane ----------------------- There is no currently-defined YUV 444 10-bit format in drm_fourcc.h, irrespective of number of planes. The proposed[1] XVYU2101010 format which is supported by Mali-DP in linear layout uses the wrong component order, and also encodes a 4th 'X' component, which doesn't match the AFBC version of YUV 444 10-bit which we support. DRM_FORMAT_Y410 is the same layout as XVYU2101010, but with 2 bits of alpha. This format is supported with linear layout by Mali GPUs. The naming follows[2]. There is no "obvious" linear encoding for a 3-component 10:10:10 packed format, and so DRM_FORMAT_VUY101010 defines a component order, but not a bit encoding. Again, the naming is meant to be consistent with DRM_FORMAT_AYUV. YUV 422 8-bit, 1-plane ---------------------- The existing DRM_FORMAT_YUYV (and the other component orders) are single-planar YUV 422 8-bit formats. Following the convention of the component orders of the RGB formats, YUYV has the correct component order for our AFBC encoding (Y followed by U followed by V). We can use YUYV for AFBC YUV 422 8-bit. YUV 422 10-bit, 1-plane ----------------------- There is no currently-defined YUV 422 10-bit format in drm_fourcc.h DRM_FORMAT_Y210 is analogous to YUYV, but with 10-bits per sample packed into the upper 10-bits of 16-bit samples. This format is supported in both linear and AFBC by Mali GPUs. YUV 422 10-bit, 2-plane ----------------------- The recently defined DRM_FORMAT_P010 format is a 10-bit semi-planar YUV 420 format, which has the correct component ordering for an AFBC 2-plane YUV 420 buffer. The linear layout contains meaningless padding bits, which will not be encoded in an AFBC stream. YUV 420 8-bit, 1-plane ---------------------- There is no currently defined single-planar YUV 420, 8-bit format in drm_fourcc.h. There's differing opinions on whether using the existing fourcc-implied n_planes where possible is a good idea or not when using modifiers. For me, it's much more "obvious" to use NV12 for 2-plane AFBC and YUV420 for 3-plane AFBC. This keeps the aforementioned separation between the AFBC codec settings (in the modifier) and the pixel data format (in the fourcc). With different vendors using AFBC, this helps to ensure that there is no confusion in interoperation. It also ensures that the AFBC modifiers describe AFBC itself (which is a licensable component), and not implementation details which are not defined by AFBC. The proposed[1] X0L0 format which Mali-DP supports with Linear layout is unsuitable, as it contains a 4th 'X' component, and our AFBC decoder expects only 3 components. To that end, we propose a new YUV 420 8-bit format. There is no "obvious" linear encoding for a 3-component 8:8:8, 420, packed format, and so DRM_FORMAT_YUV420_8BIT defines a component order, but not a bit encoding. I'm happy to hear different naming suggestions. YUV 420 8-bit, 2-, 3-plane -------------------------- These already exist, we can use NV12 and YUV420. YUV 420 10-bit, 1-plane ----------------------- As above, no current definition exists, and X0L2 encodes a 4th 'X' channel. Analogous to DRM_FORMAT_YUV420_8BIT, we define DRM_FORMAT_YUV420_10BIT. [1] https://lists.freedesktop.org/archives/dri-devel/2018-July/184598.html [2] https://docs.microsoft.com/en-us/windows/desktop/medfound/10-bit-and-16-bit-yuv-video-formats Changes since RFC v1: - Fix confusing subsampling vs bit-depth X:X:X notation in descriptions (danvet) - Rename DRM_FORMAT_AVYU1101010 to DRM_FORMAT_Y410 (Lisa Wu) - Add drm_format_info structures for the new formats, using the new 'bpp' field for those with non-integer bytes-per-pixel - Rebase, including Juha-Pekka Heikkila's format definitions Changes since RFC v2: - Rebase on top of latest changes in drm-misc-next - Change the description of DRM_FORMAT_P210 in __drm_format_info and drm_fourcc.h so as to make it consistent with other DRM_FORMAT_PXXX formats. Changes since v3: - Added the ack - Rebased on the latest drm-misc-next Signed-off-by: Brian Starkey <brian.starkey@arm.com> Signed-off-by: Ayan Kumar Halder <ayan.halder@arm.com> Reviewed-by: Liviu Dudau <liviu.dudau@arm.com> Acked-by: Alyssa Rosenzweig <alyssa@rosenzweig.io> Link: https://patchwork.freedesktop.org/patch/291759/?series=57895&rev=1
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@ -225,6 +225,9 @@ const struct drm_format_info *__drm_format_info(u32 format)
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{ .format = DRM_FORMAT_UYVY, .depth = 0, .num_planes = 1, .cpp = { 2, 0, 0 }, .hsub = 2, .vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_VYUY, .depth = 0, .num_planes = 1, .cpp = { 2, 0, 0 }, .hsub = 2, .vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_XYUV8888, .depth = 0, .num_planes = 1, .cpp = { 4, 0, 0 }, .hsub = 1, .vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_Y210, .depth = 0, .num_planes = 1, .cpp = { 4, 0, 0 }, .hsub = 2, .vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_VUY888, .depth = 0, .num_planes = 1, .cpp = { 3, 0, 0 }, .hsub = 1, .vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_Y410, .depth = 0, .num_planes = 1, .cpp = { 4, 0, 0 }, .hsub = 1, .vsub = 1, .has_alpha = true, .is_yuv = true },
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{ .format = DRM_FORMAT_AYUV, .depth = 0, .num_planes = 1, .cpp = { 4, 0, 0 }, .hsub = 1, .vsub = 1, .has_alpha = true, .is_yuv = true },
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{ .format = DRM_FORMAT_Y210, .depth = 0, .num_planes = 1, .cpp = { 4, 0, 0 }, .hsub = 2, .vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_Y212, .depth = 0, .num_planes = 1, .cpp = { 4, 0, 0 }, .hsub = 2, .vsub = 1, .is_yuv = true },
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@ -253,6 +256,19 @@ const struct drm_format_info *__drm_format_info(u32 format)
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{ .format = DRM_FORMAT_P016, .depth = 0, .num_planes = 2,
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.char_per_block = { 2, 4, 0 }, .block_w = { 1, 0, 0 }, .block_h = { 1, 0, 0 },
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.hsub = 2, .vsub = 2, .is_yuv = true},
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{ .format = DRM_FORMAT_P210, .depth = 0,
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.num_planes = 2, .char_per_block = { 2, 4, 0 },
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.block_w = { 1, 0, 0 }, .block_h = { 1, 0, 0 }, .hsub = 2,
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.vsub = 1, .is_yuv = true },
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{ .format = DRM_FORMAT_VUY101010, .depth = 0,
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.num_planes = 1, .cpp = { 0, 0, 0 }, .hsub = 1, .vsub = 1,
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.is_yuv = true },
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{ .format = DRM_FORMAT_YUV420_8BIT, .depth = 0,
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.num_planes = 1, .cpp = { 0, 0, 0 }, .hsub = 2, .vsub = 2,
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.is_yuv = true },
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{ .format = DRM_FORMAT_YUV420_10BIT, .depth = 0,
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.num_planes = 1, .cpp = { 0, 0, 0 }, .hsub = 2, .vsub = 2,
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.is_yuv = true },
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};
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unsigned int i;
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@ -149,9 +149,13 @@ extern "C" {
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#define DRM_FORMAT_YVYU fourcc_code('Y', 'V', 'Y', 'U') /* [31:0] Cb0:Y1:Cr0:Y0 8:8:8:8 little endian */
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#define DRM_FORMAT_UYVY fourcc_code('U', 'Y', 'V', 'Y') /* [31:0] Y1:Cr0:Y0:Cb0 8:8:8:8 little endian */
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#define DRM_FORMAT_VYUY fourcc_code('V', 'Y', 'U', 'Y') /* [31:0] Y1:Cb0:Y0:Cr0 8:8:8:8 little endian */
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#define DRM_FORMAT_Y210 fourcc_code('Y', '2', '1', '0') /* [63:0] Cr0:0:Y1:0:Cb0:0:Y0:0 10:6:10:6:10:6:10:6 little endian */
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#define DRM_FORMAT_AYUV fourcc_code('A', 'Y', 'U', 'V') /* [31:0] A:Y:Cb:Cr 8:8:8:8 little endian */
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#define DRM_FORMAT_XYUV8888 fourcc_code('X', 'Y', 'U', 'V') /* [31:0] X:Y:Cb:Cr 8:8:8:8 little endian */
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#define DRM_FORMAT_VUY888 fourcc_code('V', 'U', '2', '4') /* [23:0] Cr:Cb:Y 8:8:8 little endian */
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#define DRM_FORMAT_Y410 fourcc_code('Y', '4', '1', '0') /* [31:0] A:Cr:Y:Cb 2:10:10:10 little endian */
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#define DRM_FORMAT_VUY101010 fourcc_code('V', 'U', '3', '0') /* Y followed by U then V, 10:10:10. Non-linear modifier only */
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/*
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* packed Y2xx indicate for each component, xx valid data occupy msb
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@ -183,6 +187,15 @@ extern "C" {
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/* [63:0] X3:X2:Y3:Cr0:Y2:X1:X0:Y1:Cb0:Y0 1:1:10:10:10:1:1:10:10:10 little endian */
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#define DRM_FORMAT_X0L2 fourcc_code('X', '0', 'L', '2')
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/*
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* 1-plane YUV 4:2:0
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* In these formats, the component ordering is specified (Y, followed by U
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* then V), but the exact Linear layout is undefined.
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* These formats can only be used with a non-Linear modifier.
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*/
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#define DRM_FORMAT_YUV420_8BIT fourcc_code('Y', 'U', '0', '8')
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#define DRM_FORMAT_YUV420_10BIT fourcc_code('Y', 'U', '1', '0')
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/*
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* 2 plane RGB + A
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* index 0 = RGB plane, same format as the corresponding non _A8 format has
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@ -211,6 +224,13 @@ extern "C" {
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#define DRM_FORMAT_NV24 fourcc_code('N', 'V', '2', '4') /* non-subsampled Cr:Cb plane */
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#define DRM_FORMAT_NV42 fourcc_code('N', 'V', '4', '2') /* non-subsampled Cb:Cr plane */
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/*
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* 2 plane YCbCr MSB aligned
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* index 0 = Y plane, [15:0] Y:x [10:6] little endian
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* index 1 = Cr:Cb plane, [31:0] Cr:x:Cb:x [10:6:10:6] little endian
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*/
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#define DRM_FORMAT_P210 fourcc_code('P', '2', '1', '0') /* 2x1 subsampled Cr:Cb plane, 10 bit per channel */
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/*
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* 2 plane YCbCr MSB aligned
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* index 0 = Y plane, [15:0] Y:x [10:6] little endian
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