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[sfrench/cifs-2.6.git] / Documentation / dmaengine / pxa_dma.txt

PXA/MMP - DMA Slave controller
==============================

Constraints
-----------
  a) Transfers hot queuing
     A driver submitting a transfer and issuing it should be granted the transfer
     is queued even on a running DMA channel.
     This implies that the queuing doesn't wait for the previous transfer end,
     and that the descriptor chaining is not only done in the irq/tasklet code
     triggered by the end of the transfer.
     A transfer which is submitted and issued on a phy doesn't wait for a phy to
     stop and restart, but is submitted on a "running channel". The other
     drivers, especially mmp_pdma waited for the phy to stop before relaunching
     a new transfer.

  b) All transfers having asked for confirmation should be signaled
     Any issued transfer with DMA_PREP_INTERRUPT should trigger a callback call.
     This implies that even if an irq/tasklet is triggered by end of tx1, but
     at the time of irq/dma tx2 is already finished, tx1->complete() and
     tx2->complete() should be called.

  c) Channel running state
     A driver should be able to query if a channel is running or not. For the
     multimedia case, such as video capture, if a transfer is submitted and then
     a check of the DMA channel reports a "stopped channel", the transfer should
     not be issued until the next "start of frame interrupt", hence the need to
     know if a channel is in running or stopped state.

  d) Bandwidth guarantee
     The PXA architecture has 4 levels of DMAs priorities : high, normal, low.
     The high priorities get twice as much bandwidth as the normal, which get twice
     as much as the low priorities.
     A driver should be able to request a priority, especially the real-time
     ones such as pxa_camera with (big) throughputs.

Design
------
  a) Virtual channels
     Same concept as in sa11x0 driver, ie. a driver was assigned a "virtual
     channel" linked to the requestor line, and the physical DMA channel is
     assigned on the fly when the transfer is issued.

  b) Transfer anatomy for a scatter-gather transfer
     +------------+-----+---------------+----------------+-----------------+
     | desc-sg[0] | ... | desc-sg[last] | status updater | finisher/linker |
     +------------+-----+---------------+----------------+-----------------+

     This structure is pointed by dma->sg_cpu.
     The descriptors are used as follows :
      - desc-sg[i]: i-th descriptor, transferring the i-th sg
        element to the video buffer scatter gather
      - status updater
        Transfers a single u32 to a well known dma coherent memory to leave
        a trace that this transfer is done. The "well known" is unique per
        physical channel, meaning that a read of this value will tell which
        is the last finished transfer at that point in time.
      - finisher: has ddadr=DADDR_STOP, dcmd=ENDIRQEN
      - linker: has ddadr= desc-sg[0] of next transfer, dcmd=0

  c) Transfers hot-chaining
     Suppose the running chain is :
         Buffer 1         Buffer 2
     +---------+----+---+  +----+----+----+---+
     | d0 | .. | dN | l |  | d0 | .. | dN | f |
     +---------+----+-|-+  ^----+----+----+---+
                      |    |
                      +----+

     After a call to dmaengine_submit(b3), the chain will look like :
          Buffer 1              Buffer 2             Buffer 3
     +---------+----+---+  +----+----+----+---+  +----+----+----+---+
     | d0 | .. | dN | l |  | d0 | .. | dN | l |  | d0 | .. | dN | f |
     +---------+----+-|-+  ^----+----+----+-|-+  ^----+----+----+---+
                      |    |                |    |
                      +----+                +----+
                                           new_link

     If while new_link was created the DMA channel stopped, it is _not_
     restarted. Hot-chaining doesn't break the assumption that
     dma_async_issue_pending() is to be used to ensure the transfer is actually started.

     One exception to this rule :
       - if Buffer1 and Buffer2 had all their addresses 8 bytes aligned
       - and if Buffer3 has at least one address not 4 bytes aligned
       - then hot-chaining cannot happen, as the channel must be stopped, the
         "align bit" must be set, and the channel restarted As a consequence,
         such a transfer tx_submit() will be queued on the submitted queue, and
         this specific case if the DMA is already running in aligned mode.

  d) Transfers completion updater
     Each time a transfer is completed on a channel, an interrupt might be
     generated or not, up to the client's request. But in each case, the last
     descriptor of a transfer, the "status updater", will write the latest
     transfer being completed into the physical channel's completion mark.

     This will speed up residue calculation, for large transfers such as video
     buffers which hold around 6k descriptors or more. This also allows without
     any lock to find out what is the latest completed transfer in a running
     DMA chain.

  e) Transfers completion, irq and tasklet
     When a transfer flagged as "DMA_PREP_INTERRUPT" is finished, the dma irq
     is raised. Upon this interrupt, a tasklet is scheduled for the physical
     channel.
     The tasklet is responsible for :
      - reading the physical channel last updater mark
      - calling all the transfer callbacks of finished transfers, based on
        that mark, and each transfer flags.
     If a transfer is completed while this handling is done, a dma irq will
     be raised, and the tasklet will be scheduled once again, having a new
     updater mark.

  f) Residue
     Residue granularity will be descriptor based. The issued but not completed
     transfers will be scanned for all of their descriptors against the
     currently running descriptor.

  g) Most complicated case of driver's tx queues
     The most tricky situation is when :
       - there are not "acked" transfers (tx0)
       - a driver submitted an aligned tx1, not chained
       - a driver submitted an aligned tx2 => tx2 is cold chained to tx1
       - a driver issued tx1+tx2 => channel is running in aligned mode
       - a driver submitted an aligned tx3 => tx3 is hot-chained
       - a driver submitted an unaligned tx4 => tx4 is put in submitted queue,
         not chained
       - a driver issued tx4 => tx4 is put in issued queue, not chained
       - a driver submitted an aligned tx5 => tx5 is put in submitted queue, not
         chained
       - a driver submitted an aligned tx6 => tx6 is put in submitted queue,
         cold chained to tx5

     This translates into (after tx4 is issued) :
       - issued queue
     +-----+ +-----+ +-----+ +-----+
     | tx1 | | tx2 | | tx3 | | tx4 |
     +---|-+ ^---|-+ ^-----+ +-----+
         |   |   |   |
         +---+   +---+
       - submitted queue
     +-----+ +-----+
     | tx5 | | tx6 |
     +---|-+ ^-----+
         |   |
         +---+
       - completed queue : empty
       - allocated queue : tx0

     It should be noted that after tx3 is completed, the channel is stopped, and
     restarted in "unaligned mode" to handle tx4.

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