Hi Laurent, On Thu, Feb 22, 2018 at 02:47:06PM +0200, Laurent Pinchart wrote: > Hi Jacopo, > > On Thursday, 22 February 2018 14:36:00 EET jacopo mondi wrote: > > On Thu, Feb 22, 2018 at 02:14:53PM +0200, Laurent Pinchart wrote: > > > On Thursday, 22 February 2018 14:04:12 EET jacopo mondi wrote: > > >> On Wed, Feb 21, 2018 at 10:28:06PM +0200, Laurent Pinchart wrote: > > >>> On Tuesday, 20 February 2018 10:58:57 EET jacopo mondi wrote: > > [snip] > > > >>>> This actually makes me wonder if those informations (ycbcb_enc, > > >>>> quantization and xfer_func) shouldn't actually be part of the > > >>>> supported format list... I blindly added those default fields in the > > >>>> try_fmt function, but I doubt they applies to all supported formats. > > >>>> > > >>>> Eg. the sensor supports YUYV as well as 2 RGB encodings (RGB444 and > > >>>> RGB 565) and 1 raw format (BGGR). I now have a question here: > > >>>> > > >>>> 1) ycbcr_enc transforms non-linear R'G'B' to Y'CbCr: does this > > >>>> applies to RGB and raw formats? I don't think so, and what value is > > >>>> the correct one for the ycbcr_enc field in this case? I assume > > >>>> xfer_func and quantization applies to all formats instead.. > > >>> > > >>> There's no encoding for RGB formats if I understand things correctly, > > >>> so I'd set ycbcr_enc to V4L2_YCBCR_ENC_DEFAULT. The transfer function > > >>> and the quantization apply to all formats, but I'd be surprised to find > > >>> a sensor outputting limited range for RGB. > > >> > > >> Ack, we got the same understanding for RGB formats. I wonder if for > > >> those formats we wouldn't need a V4L2_YCBCR_ENC_NONE or similar... > > > > > > That, or explicitly documenting that when the format is not YUV the field > > > should be set by both drivers and applications to V4L2_YCBCR_ENC_DEFAULT > > > when written and ignored when read. > > > > Well, if no encoding is performed because the color encoding scheme is > > RGB, the colorspace does anyway define an encoding method, so it seems > > to me the latter is more appropriate (use DEFAULT and ignore when read). > > > > That's anyway just my opinion, but I could send a patch for > > documentation and see what feedback it gets. > > > > >>> Have you been able to check whether the sensor outputs limited range > > >>> of full range YUV ? If it outputs full range you can hardcode > > >>> quantization to V4L2_QUANTIZATION_FULL_RANGE for all formats. > > >> > > >> In YUYV mode, I see values > 0xf0 ( > 240, which is the max value for > > >> CbCr samples in limited quantization range), so I assume quantization > > >> is full range. > > > > > > It should be, yes. What's the minimum and maximum values you get ? > > > > From a white surface: > > min = 0x39 > > max = 0xfc > > > > From a black surface: > > min = 0x00 (with 62 occurrences) > > max = 0x8b > > > > I guess that's indeed full range quantization > > Could you check Y and UV separately ? > > #!/usr/bin/python > > import sys > > def main(argv): > if len(argv) != 2: > print('Usage: %s <file>' % argv[0]) > return 1 > > data = open(argv[1], 'rb').read() > > y_min = 255 > y_max = 0 > uv_min = 255 > uv_max = 0 > > for i in range(len(data) // 2): > y = data[2*i] > uv = data[2*i] uv = data[2*i+1] > > y_min = min(y_min, y) > y_max = max(y_max, y) > uv_min = min(uv_min, uv) > uv_max = max(uv_max, uv) > > print('Y [%u, %u] UV [%u, %u]' % (y_min, y_max, uv_min, uv_max)) > return 0 > > if __name__ == '__main__': > sys.exit(main(sys.argv)) > White image: Y [57, 252] UV [105, 145] Black image: Y [0, 32] UV [116, 139]