Documentation/video4linux/pxa_camera.txt - kernel/msm-4.9 - Gitiles

                               PXA-Camera Host Driver
                               ======================

 Constraints
 -----------
   a) Image size for YUV422P format
      All YUV422P images are enforced to have width x height % 16 = 0.
      This is due to DMA constraints, which transfers only planes of 8 byte
      multiples.


 Global video workflow
 ---------------------
   a) QCI stopped
      Initialy, the QCI interface is stopped.
      When a buffer is queued (pxa_videobuf_ops->buf_queue), the QCI starts.

   b) QCI started
      More buffers can be queued while the QCI is started without halting the
      capture.  The new buffers are "appended" at the tail of the DMA chain, and
      smoothly captured one frame after the other.

      Once a buffer is filled in the QCI interface, it is marked as "DONE" and
      removed from the active buffers list. It can be then requeud or dequeued by
      userland application.

      Once the last buffer is filled in, the QCI interface stops.


 DMA usage
 ---------
   a) DMA flow
      - first buffer queued for capture
        Once a first buffer is queued for capture, the QCI is started, but data
        transfer is not started. On "End Of Frame" interrupt, the irq handler
        starts the DMA chain.
      - capture of one videobuffer
        The DMA chain starts transfering data into videobuffer RAM pages.
        When all pages are transfered, the DMA irq is raised on "ENDINTR" status
      - finishing one videobuffer
        The DMA irq handler marks the videobuffer as "done", and removes it from
        the active running queue
        Meanwhile, the next videobuffer (if there is one), is transfered by DMA
      - finishing the last videobuffer
        On the DMA irq of the last videobuffer, the QCI is stopped.

   b) DMA prepared buffer will have this structure

      +------------+-----+---------------+-----------------+
      | desc-sg[0] | ... | desc-sg[last] | finisher/linker |
      +------------+-----+---------------+-----------------+

      This structure is pointed by dma->sg_cpu.
      The descriptors are used as follows :
       - desc-sg[i]: i-th descriptor, transfering the i-th sg
         element to the video buffer scatter gather
       - finisher: has ddadr=DADDR_STOP, dcmd=ENDIRQEN
       - linker: has ddadr= desc-sg[0] of next video buffer, dcmd=0

      For the next schema, let's assume d0=desc-sg[0] .. dN=desc-sg[N],
      "f" stands for finisher and "l" for linker.
      A typical running chain is :

          Videobuffer 1         Videobuffer 2
      +---------+----+---+  +----+----+----+---+
      | d0 | .. | dN | l |  | d0 | .. | dN | f |
      +---------+----+-|-+  ^----+----+----+---+
                       |    |
                       +----+

      After the chaining is finished, the chain looks like :

          Videobuffer 1         Videobuffer 2         Videobuffer 3
      +---------+----+---+  +----+----+----+---+  +----+----+----+---+
      | d0 | .. | dN | l |  | d0 | .. | dN | l |  | d0 | .. | dN | f |
      +---------+----+-|-+  ^----+----+----+-|-+  ^----+----+----+---+
                       |    |                |    |
                       +----+                +----+
                                            new_link

   c) DMA hot chaining timeslice issue

      As DMA chaining is done while DMA _is_ running, the linking may be done
      while the DMA jumps from one Videobuffer to another. On the schema, that
      would be a problem if the following sequence is encountered :

       - DMA chain is Videobuffer1 + Videobuffer2
       - pxa_videobuf_queue() is called to queue Videobuffer3
       - DMA controller finishes Videobuffer2, and DMA stops
       =>
          Videobuffer 1         Videobuffer 2
      +---------+----+---+  +----+----+----+---+
      | d0 | .. | dN | l |  | d0 | .. | dN | f |
      +---------+----+-|-+  ^----+----+----+-^-+
                       |    |                |
                       +----+                +-- DMA DDADR loads DDADR_STOP

       - pxa_dma_add_tail_buf() is called, the Videobuffer2 "finisher" is
         replaced by a "linker" to Videobuffer3 (creation of new_link)
       - pxa_videobuf_queue() finishes
       - the DMA irq handler is called, which terminates Videobuffer2
       - Videobuffer3 capture is not scheduled on DMA chain (as it stopped !!!)

          Videobuffer 1         Videobuffer 2         Videobuffer 3
      +---------+----+---+  +----+----+----+---+  +----+----+----+---+
      | d0 | .. | dN | l |  | d0 | .. | dN | l |  | d0 | .. | dN | f |
      +---------+----+-|-+  ^----+----+----+-|-+  ^----+----+----+---+
                       |    |                |    |
                       +----+                +----+
                                            new_link
                                           DMA DDADR still is DDADR_STOP

       - pxa_camera_check_link_miss() is called
         This checks if the DMA is finished and a buffer is still on the
         pcdev->capture list. If that's the case, the capture will be restarted,
         and Videobuffer3 is scheduled on DMA chain.
       - the DMA irq handler finishes

      Note: if DMA stops just after pxa_camera_check_link_miss() reads DDADR()
      value, we have the guarantee that the DMA irq handler will be called back
      when the DMA will finish the buffer, and pxa_camera_check_link_miss() will
      be called again, to reschedule Videobuffer3.

 --
 Author: Robert Jarzmik <robert.jarzmik@free.fr>
	PXA-Camera Host Driver
	======================

	Constraints
	-----------
	a) Image size for YUV422P format
	All YUV422P images are enforced to have width x height % 16 = 0.
	This is due to DMA constraints, which transfers only planes of 8 byte
	multiples.


	Global video workflow
	---------------------
	a) QCI stopped
	Initialy, the QCI interface is stopped.
	When a buffer is queued (pxa_videobuf_ops->buf_queue), the QCI starts.

	b) QCI started
	More buffers can be queued while the QCI is started without halting the
	capture. The new buffers are "appended" at the tail of the DMA chain, and
	smoothly captured one frame after the other.

	Once a buffer is filled in the QCI interface, it is marked as "DONE" and
	removed from the active buffers list. It can be then requeud or dequeued by
	userland application.

	Once the last buffer is filled in, the QCI interface stops.


	DMA usage
	---------
	a) DMA flow
	- first buffer queued for capture
	Once a first buffer is queued for capture, the QCI is started, but data
	transfer is not started. On "End Of Frame" interrupt, the irq handler
	starts the DMA chain.
	- capture of one videobuffer
	The DMA chain starts transfering data into videobuffer RAM pages.
	When all pages are transfered, the DMA irq is raised on "ENDINTR" status
	- finishing one videobuffer
	The DMA irq handler marks the videobuffer as "done", and removes it from
	the active running queue
	Meanwhile, the next videobuffer (if there is one), is transfered by DMA
	- finishing the last videobuffer
	On the DMA irq of the last videobuffer, the QCI is stopped.

	b) DMA prepared buffer will have this structure

	+------------+-----+---------------+-----------------+
	\| desc-sg[0] \| ... \| desc-sg[last] \| finisher/linker \|
	+------------+-----+---------------+-----------------+

	This structure is pointed by dma->sg_cpu.
	The descriptors are used as follows :
	- desc-sg[i]: i-th descriptor, transfering the i-th sg
	element to the video buffer scatter gather
	- finisher: has ddadr=DADDR_STOP, dcmd=ENDIRQEN
	- linker: has ddadr= desc-sg[0] of next video buffer, dcmd=0

	For the next schema, let's assume d0=desc-sg[0] .. dN=desc-sg[N],
	"f" stands for finisher and "l" for linker.
	A typical running chain is :

	Videobuffer 1 Videobuffer 2
	+---------+----+---+ +----+----+----+---+
	\| d0 \| .. \| dN \| l \| \| d0 \| .. \| dN \| f \|
	+---------+----+-\|-+ ^----+----+----+---+
	\| \|
	+----+

	After the chaining is finished, the chain looks like :

	Videobuffer 1 Videobuffer 2 Videobuffer 3
	+---------+----+---+ +----+----+----+---+ +----+----+----+---+
	\| d0 \| .. \| dN \| l \| \| d0 \| .. \| dN \| l \| \| d0 \| .. \| dN \| f \|
	+---------+----+-\|-+ ^----+----+----+-\|-+ ^----+----+----+---+
	\| \| \| \|
	+----+ +----+
	new_link

	c) DMA hot chaining timeslice issue

	As DMA chaining is done while DMA _is_ running, the linking may be done
	while the DMA jumps from one Videobuffer to another. On the schema, that
	would be a problem if the following sequence is encountered :

	- DMA chain is Videobuffer1 + Videobuffer2
	- pxa_videobuf_queue() is called to queue Videobuffer3
	- DMA controller finishes Videobuffer2, and DMA stops
	=>
	Videobuffer 1 Videobuffer 2
	+---------+----+---+ +----+----+----+---+
	\| d0 \| .. \| dN \| l \| \| d0 \| .. \| dN \| f \|
	+---------+----+-\|-+ ^----+----+----+-^-+
	\| \| \|
	+----+ +-- DMA DDADR loads DDADR_STOP

	- pxa_dma_add_tail_buf() is called, the Videobuffer2 "finisher" is
	replaced by a "linker" to Videobuffer3 (creation of new_link)
	- pxa_videobuf_queue() finishes
	- the DMA irq handler is called, which terminates Videobuffer2
	- Videobuffer3 capture is not scheduled on DMA chain (as it stopped !!!)

	Videobuffer 1 Videobuffer 2 Videobuffer 3
	+---------+----+---+ +----+----+----+---+ +----+----+----+---+
	\| d0 \| .. \| dN \| l \| \| d0 \| .. \| dN \| l \| \| d0 \| .. \| dN \| f \|
	+---------+----+-\|-+ ^----+----+----+-\|-+ ^----+----+----+---+
	\| \| \| \|
	+----+ +----+
	new_link
	DMA DDADR still is DDADR_STOP

	- pxa_camera_check_link_miss() is called
	This checks if the DMA is finished and a buffer is still on the
	pcdev->capture list. If that's the case, the capture will be restarted,
	and Videobuffer3 is scheduled on DMA chain.
	- the DMA irq handler finishes

	Note: if DMA stops just after pxa_camera_check_link_miss() reads DDADR()
	value, we have the guarantee that the DMA irq handler will be called back
	when the DMA will finish the buffer, and pxa_camera_check_link_miss() will
	be called again, to reschedule Videobuffer3.

	--
	Author: Robert Jarzmik <robert.jarzmik@free.fr>