drivers/staging/media/imx/TODO - linux-mtk - Git at Google


 - The Frame Interval Monitor could be exported to v4l2-core for
   general use.

 - The CSI subdevice parses its nearest upstream neighbor's device-tree
   bus config in order to setup the CSI. Laurent Pinchart argues that
   instead the CSI subdev should call its neighbor's g_mbus_config op
   (which should be propagated if necessary) to get this info. However
   Hans Verkuil is planning to remove the g_mbus_config op. For now this
   driver uses the parsed DT bus config method until this issue is
   resolved.

 - This media driver supports inheriting V4L2 controls to the
   video capture devices, from the subdevices in the capture device's
   pipeline. The controls for each capture device are updated in the
   link_notify callback when the pipeline is modified. It should be
   decided whether this feature is useful enough to make it generally
   available by exporting to v4l2-core.

 - The OF graph is walked at probe time to form the list of fwnodes to
   be passed to v4l2_async_notifier_register(), starting from the IPU
   CSI ports. And after all async subdevices have been bound,
   v4l2_fwnode_parse_link() is used to form the media links between
   the entities discovered by walking the OF graph.

   While this approach allows support for arbitrary OF graphs, there
   are some assumptions for this to work:

   1. All port parent nodes reachable in the graph from the IPU CSI
      ports bind to V4L2 async subdevice drivers.

      If a device has mixed-use ports such as video plus audio, the
      endpoints from the audio ports are followed to devices that must
      bind to V4L2 subdevice drivers, and not for example, to an ALSA
      driver or a non-V4L2 media driver. If the device were bound to
      such a driver, imx-media would never get an async completion
      notification because the device fwnode was added to the async
      list, but the driver does not interface with the V4L2 async
      framework.

   2. Every port reachable in the graph is treated as a media pad,
      owned by the V4L2 subdevice that is bound to the port's parent.

      This presents problems for devices that don't make this port = pad
      assumption. Examples are SMIAPP compatible cameras which define only
      a single output port node, but which define multiple pads owned
      by multiple subdevices (pixel-array, binner, scaler). Or video
      decoders (entity function MEDIA_ENT_F_ATV_DECODER), which also define
      only a single output port node, but define multiple pads for video,
      VBI, and audio out.

      A workaround at present is to set the port reg properties to
      correspond to the media pad index that the port represents. A
      possible long-term solution is to implement a subdev API that
      maps a port id to a media pad index.

   3. Every endpoint of a port reachable in the graph is treated as
      a media link, between V4L2 subdevices that are bound to the
      port parents of the local and remote endpoints.

      Which means a port must not contain mixed-use endpoints, they
      must all refer to media links between V4L2 subdevices.

	- The Frame Interval Monitor could be exported to v4l2-core for
	general use.

	- The CSI subdevice parses its nearest upstream neighbor's device-tree
	bus config in order to setup the CSI. Laurent Pinchart argues that
	instead the CSI subdev should call its neighbor's g_mbus_config op
	(which should be propagated if necessary) to get this info. However
	Hans Verkuil is planning to remove the g_mbus_config op. For now this
	driver uses the parsed DT bus config method until this issue is
	resolved.

	- This media driver supports inheriting V4L2 controls to the
	video capture devices, from the subdevices in the capture device's
	pipeline. The controls for each capture device are updated in the
	link_notify callback when the pipeline is modified. It should be
	decided whether this feature is useful enough to make it generally
	available by exporting to v4l2-core.

	- The OF graph is walked at probe time to form the list of fwnodes to
	be passed to v4l2_async_notifier_register(), starting from the IPU
	CSI ports. And after all async subdevices have been bound,
	v4l2_fwnode_parse_link() is used to form the media links between
	the entities discovered by walking the OF graph.

	While this approach allows support for arbitrary OF graphs, there
	are some assumptions for this to work:

	1. All port parent nodes reachable in the graph from the IPU CSI
	ports bind to V4L2 async subdevice drivers.

	If a device has mixed-use ports such as video plus audio, the
	endpoints from the audio ports are followed to devices that must
	bind to V4L2 subdevice drivers, and not for example, to an ALSA
	driver or a non-V4L2 media driver. If the device were bound to
	such a driver, imx-media would never get an async completion
	notification because the device fwnode was added to the async
	list, but the driver does not interface with the V4L2 async
	framework.

	2. Every port reachable in the graph is treated as a media pad,
	owned by the V4L2 subdevice that is bound to the port's parent.

	This presents problems for devices that don't make this port = pad
	assumption. Examples are SMIAPP compatible cameras which define only
	a single output port node, but which define multiple pads owned
	by multiple subdevices (pixel-array, binner, scaler). Or video
	decoders (entity function MEDIA_ENT_F_ATV_DECODER), which also define
	only a single output port node, but define multiple pads for video,
	VBI, and audio out.

	A workaround at present is to set the port reg properties to
	correspond to the media pad index that the port represents. A
	possible long-term solution is to implement a subdev API that
	maps a port id to a media pad index.

	3. Every endpoint of a port reachable in the graph is treated as
	a media link, between V4L2 subdevices that are bound to the
	port parents of the local and remote endpoints.

	Which means a port must not contain mixed-use endpoints, they
	must all refer to media links between V4L2 subdevices.