Hi Eddie, Thank you for your work on this. Interesting to see support for this SoC :-) On 08/29/2018 11:09 PM, Eddie James wrote: > The Video Engine (VE) embedded in the Aspeed AST2400 and AST2500 SOCs > can capture and compress video data from digital or analog sources. With > the Aspeed chip acting as a service processor, the Video Engine can > capture the host processor graphics output. > > This series adds a V4L2 driver for the VE, providing a read() interface > only. The driver triggers the hardware to capture the host graphics output > and compress it to JPEG format. > > Testing on an AST2500 determined that the videobuf/streaming/mmap interface > was significantly slower than the simple read() interface, so I have not > included the streaming part. Do you know why? It should be equal or faster, not slower. I reviewed about half of the driver, but then I stopped since there were too many things missing. First of all, you need to test your driver with v4l2-compliance (available here: https://git.linuxtv.org/v4l-utils.git/). Always compile from the git repo since the versions from distros tend to be too old. Just run 'v4l2-compliance -d /dev/videoX' and fix all issues. Then run 'v4l2-compliance -s -d /dev/videoX' to test streaming. This utility checks if the driver follows the V4L2 API correctly, implements all ioctls that it should and fills in all the fields that it should. Please add the output of 'v4l2-compliance -s' to future versions of this patch series: I don't accept V4L2 drivers without a clean report of this utility. If you have any questions, then mail me or (usually quicker) ask on the #v4l freenode irc channel (I'm in the CET timezone). One thing that needs more explanation: from what I could tell from the driver the VIDIOC_G_FMT ioctl returns the detected format instead of the current format. This is wrong. Instead you should implement the VIDIOC_*_DV_TIMINGS ioctls and the V4L2_EVENT_SOURCE_CHANGE event. The normal sequence is that userspace queries the current timings with VIDIOC_QUERY_DV_TIMINGS, if it finds valid timings, then it sets these timings with _S_DV_TIMINGS. Now it can call G/S_FMT. If the timings change, then the driver should detect that and send a V4L2_EVENT_SOURCE_CHANGE event. When the application receives this event it can take action, such as increasing the size of the buffer for the jpeg data that it reads into. The reason for this sequence of events is that you can't just change the format/resolution mid-stream without giving userspace the chance to reconfigure. Regards, Hans > > It's also possible to use an automatic mode for the VE such that > re-triggering the HW every frame isn't necessary. However this wasn't > reliable on the AST2400, and probably used more CPU anyway due to excessive > interrupts. It was approximately 15% faster. > > The series also adds the necessary parent clock definitions to the Aspeed > clock driver, with both a mux and clock divider. > > Eddie James (4): > clock: aspeed: Add VIDEO reset index definition > clock: aspeed: Setup video engine clocking > dt-bindings: media: Add Aspeed Video Engine binding documentation > media: platform: Add Aspeed Video Engine driver > > .../devicetree/bindings/media/aspeed-video.txt | 23 + > drivers/clk/clk-aspeed.c | 41 +- > drivers/media/platform/Kconfig | 8 + > drivers/media/platform/Makefile | 1 + > drivers/media/platform/aspeed-video.c | 1307 ++++++++++++++++++++ > include/dt-bindings/clock/aspeed-clock.h | 1 + > 6 files changed, 1379 insertions(+), 2 deletions(-) > create mode 100644 Documentation/devicetree/bindings/media/aspeed-video.txt > create mode 100644 drivers/media/platform/aspeed-video.c >