Re: DRM Atomic property for color-space conversion

From: Sharma, Shashank
Date: Thu Mar 16 2017 - 11:15:50 EST


Regards

Shashank


On 3/16/2017 4:37 PM, Local user for Liviu Dudau wrote:
On Thu, Mar 16, 2017 at 04:30:59PM +0200, Ville SyrjÃlà wrote:
On Thu, Mar 16, 2017 at 04:20:29PM +0200, Sharma, Shashank wrote:
Regards

Shashank


On 3/16/2017 4:07 PM, Ville SyrjÃlà wrote:
On Tue, Jan 31, 2017 at 03:55:41PM +0000, Brian Starkey wrote:
On Tue, Jan 31, 2017 at 05:15:46PM +0200, Ville SyrjÃlà wrote:
On Tue, Jan 31, 2017 at 12:33:29PM +0000, Brian Starkey wrote:
Hi,

On Mon, Jan 30, 2017 at 03:35:13PM +0200, Ville SyrjÃlà wrote:
On Fri, Jan 27, 2017 at 05:23:24PM +0000, Brian Starkey wrote:
Hi,

We're looking to enable the per-plane color management hardware in
Mali-DP with atomic properties, which has sparked some conversation
around how to handle YCbCr formats.

As it stands today, it's assumed that a driver will implicitly "do the
right thing" to display a YCbCr buffer.

YCbCr data often uses different gamma curves and signal ranges (e.g.
BT.609, BT.701, BT.2020, studio range, full-range), so its desirable
to be able to explicitly control the YCbCr to RGB conversion process
from userspace.

We're proposing adding a "CSC" (color-space conversion) property to
control this - primarily per-plane for framebuffer->pipeline CSC, but
perhaps one per CRTC too for devices which have an RGB pipeline and
want to output in YUV to the display:

Name: "CSC"
Type: ENUM | ATOMIC;
Enum values (representative):
"default":
Same behaviour as now. "Some kind" of YCbCr->RGB conversion
for YCbCr buffers, bypass for RGB buffers
"disable":
Explicitly disable all colorspace conversion (i.e. use an
identity matrix).
"YCbCr to RGB: BT.709":
Only valid for YCbCr formats. CSC in accordance with BT.709
using [16..235] for (8-bit) luma values, and [16..240] for
8-bit chroma values. For 10-bit formats, the range limits are
multiplied by 4.
"YCbCr to RGB: BT.709 full-swing":
Only valid for YCbCr formats. CSC in accordance with BT.709,
but using the full range of each channel.
"YCbCr to RGB: Use CTM":*
Only valid for YCbCr formats. Use the matrix applied via the
plane's CTM property
"RGB to RGB: Use CTM":*
Only valid for RGB formats. Use the matrix applied via the
plane's CTM property
"Use CTM":*
Valid for any format. Use the matrix applied via the plane's
CTM property
... any other values for BT.601, BT.2020, RGB to YCbCr etc. etc. as
they are required.
Having some RGB2RGB and YCBCR2RGB things in the same property seems
weird. I would just go with something very simple like:

YCBCR_TO_RGB_CSC:
* BT.601
* BT.709
* custom matrix

I think we've agreed in #dri-devel that this CSC property
can't/shouldn't be mapped on-to the existing (hardware implementing
the) CTM property - even in the case of per-plane color management -
because CSC needs to be done before DEGAMMA.

So, I'm in favour of going with what you suggested in the first place:

A new YCBCR_TO_RGB_CSC property, enum type, with a list of fixed
conversions. I'd drop the custom matrix for now, as we'd need to add
another property to attach the custom matrix blob too.

I still think we need a way to specify whether the source data range
is broadcast/full-range, so perhaps the enum list should be expanded
to all combinations of BT.601/BT.709 + broadcast/full-range.
Sounds reasonable. Not that much full range YCbCr stuff out there
perhaps. Well, apart from jpegs I suppose. But no harm in being able
to deal with it.

(I'm not sure what the canonical naming for broadcast/full-range is,
we call them narrow and wide)
We tend to call them full vs. limited range. That's how our
"Broadcast RGB" property is defined as well.

OK, using the same ones sounds sensible.

And trying to use the same thing for the crtc stuff is probably not
going to end well. Like Daniel said we already have the
'Broadcast RGB' property muddying the waters there, and that stuff
also ties in with what colorspace we signal to the sink via
infoframes/whatever the DP thing was called. So my gut feeling is
that trying to use the same property everywhere will just end up
messy.
Yeah, agreed. If/when someone wants to add CSC on the output of a CRTC
(after GAMMA), we can add a new property.

That makes me wonder about calling this one SOURCE_YCBCR_TO_RGB_CSC to
be explicit that it describes the source data. Then we can later add
SINK_RGB_TO_YCBCR_CSC, and it will be reasonably obvious that its
value describes the output data rather than the input data.
Source and sink have a slight connotation in my mind wrt. the box that
produces the display signal and the box that eats the signal. So trying
to use the same terms to describe the internals of the pipeline inside
the "source box" migth lead to some confusion. But we do probably need
some decent names for these to make the layout of the pipeline clear.
Input/output are the other names that popped to my mind but those aren't
necessarily any better. But in the end I think I could live with whatever
names we happen to pick, as long as we document the pipeline clearly.

Long ago I did wonder if we should just start indexing these things
somehow, and then just looking at the index should tell you the order
of the operations. But we already have the ctm/gamma w/o any indexes so
that idea probably isn't so great anymore.

I want to avoid confusion caused by ending up with two
{CS}_TO_{CS}_CSC properties, where one is describing the data to the
left of it, and the other describing the data to the right of it, with
no real way of telling which way around it is.
Not really sure what you mean. It should always be
<left>_to_<right>_csc.
Agreed, left-to-right. But for instance on a CSC property representing
a CRTC output CSC (just before hitting the connector), which happens
to be converting RGB to YCbCr:

CRTC -> GAMMA -> RGB_TO_YCBCR_CSC

...the enum value "BT.601 Limited" means that the data on the *right*
of RGB_TO_YCBCR_CSC is "BT.601 Limited"

On the other hand for a CSC on the input of a plane, which happens to
be converting YCbCr to RGB:

RAM -> YCBCR_TO_RGB_CSC -> DEGAMMA

...the enum value "BT.601 Limited" means that the data on the *left*
of YCBCR_TO_RGB_CSC is "BT.601 Limited".

Indicating in the property name whether its value is describing the
data on the left or the right is needed (and I don't think inferring
that "it's always the YCBCR one" is the correct approach).

In my example above, "SOURCE_xxx" would mean the enum value is
describing the "source" data (i.e. the data on the left) and
"SINK_xxx" would mean the enum value is describing the "sink" data
(i.e. the data on the right). This doesn't necessarily need to infer a
particular point in the pipeline.
Right, so I guess you want the values to be named "<a> to <b>" as well?
Yes, I think we'll be wanting that as well.

So what we might need is something like:
enum YCBCR_TO_RGB_CSC
* YCbCr BT.601 limited to RGB BT.709 full
* YCbCr BT.709 limited to RGB BT.709 full <this would be the likely default value IMO>
* YCbCr BT.601 limited to RGB BT.2020 full
* YCbCr BT.709 limited to RGB BT.2020 full
* YCbCr BT.2020 limited to RGB BT.2020 full

And thanks to BT.2020 we'll need a RGB->RGB CSC property as well. Eg:
enum RGB_TO_RGB_CSC
* bypass (or separate 709->709, 2020->2020?) <this would be the default>
* RGB BT.709 full to RGB BT.2020 full

Alternatives would involve two properties to define the input and output
from the CSC separately, but then you lose the capability to see which
combinations are actually supoorted.
I was thinking about this too, or would it make more sense to create two
properties:
- one for gamut mapping (cases like RGB709->RGB2020)
- other one for Color space conversion (cases lile YUV 709 -> RGB 709)

Gamut mapping can represent any of the fix function mapping, wereas CSC
can bring up any programmable matrix

Internally these properties can use the same HW unit or even same function.
Does it sound any good ?
It's certainly possible. One problem is that we can't inform userspace
upfront which combinations are supported. Whether that's a real problem
I'm not sure. With atomic userspace can of course check upfront if
something can be done or not, but the main problem is then coming up
with a fallback strategy that doesn't suck too badly.

Anyways, I don't think I have any strong favorites here. Would be nice
to hear what everyone else thinks.
I confess to a lack of experience in the subject here, but what is the more common
request coming from userspace: converting YUV <-> RGB but keeping the gammut mapping
separate, or YUV (gammut x) <-> RGB (gammut y) ? In other words: I can see the usefulness
of having an explicit way of decomposing the color mapping process and control the
parameters, but how often do apps or compositors go through the whole chain?
Right now, more or less the interest is on the RGB->YUV conversion side, coz till now BT 2020 gamut was not in
picture. REC 601 and 709 have very close gamuts, so it was ok to blend frames mostly without bothering about
gamut, but going fwd, ones REC 2020 comes into picture, we need to bother about mapping gamuts too, else
blending Rec709 buffers and Rec2020 buffers together would cause very visible gamut mismatch.

So considering futuristic developments, it might be ok to consider both. Still, as Ville mentioned, it would be good
to hear from other too.

- Shashank

Best regards,
Liviu

--
Ville SyrjÃlÃ
Intel OTC