Re: [Linaro-mm-sig] Re: [PATCH v5 1/6] dma-buf: Add dma_buf_{begin,end}_access()

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Am 31.01.24 um 10:07 schrieb Daniel Vetter:
On Tue, Jan 30, 2024 at 02:09:45PM +0100, Christian König wrote:
Am 30.01.24 um 11:40 schrieb Daniel Vetter:
On Tue, Jan 30, 2024 at 10:48:23AM +0100, Paul Cercueil wrote:
Le mardi 30 janvier 2024 à 10:23 +0100, Christian König a écrit :
   I would say we start with the DMA-API by getting away from sg_tables
to something cleaner and state oriented.
FYI I am already adding a 'dma_vec' object in my IIO DMABUF patchset,
which is just a dead simple

struct dma_vec {
    dma_addr_t addr;
    size_t len;
};

(The rationale for introducing it in the IIO DMABUF patchset was that
the "scatterlist" wouldn't allow me to change the transfer size.)

So I believe a new "sg_table"-like could just be an array of struct
dma_vec + flags.
Yeah that's pretty much the proposal I've seen, split the sg table into
input data (struct page + len) and output data (which is the dma_addr_t +
len you have above).
I would extend that a bit and say we have an array with
dma_addr+power_of_two_order and a header structure with lower bit offset and
some DMA transaction flags.

But this is something which can be worked as an optimization later on. For a
start this proposal here looks good to me as well.

The part I don't expect to ever happen, because it hasn't the past 20 or
so years, is that the dma-api will give us information about what is
needed to keep the buffers coherency between various devices and the cpu.
Well maybe that's what we are doing wrong.

Instead of asking the dma-api about the necessary information we should give
the API the opportunity to work for us.

In other words we don't need the information about buffer coherency what we
need is that the API works for as and fulfills the requirements we have.

So the question is really what should we propose to change on the DMA-api
side to get this working as expected?
So one thing I've been pondering, kinda picking up your point about CXL,
is that we do make the coherency protocol more explicit by adding a
coherency mode to dma_buf that the exporter sets. Some ideas for values
this could have:

- ATTOMIC_COHERENT: Fully cache coherent, including device/cpu atomis.
   This would be for CXL. Non-CXL devices could still participate with the
   old model using explicit devices flushes, but must at comply with
   CPU_COHERENT.

   There's also the power9-only nvlink that would fit here, but I guess
   going forward CXL (and cache-coherent integrated gpu) would really be
   the only users of this flag.

   Peer2peer would have the same rules, otherwise doesn't really make
   sense. Also we might want to forbib non-CXL imports for these buffers
   maybe even? Not sure on that.

- CPU_COHERENT: device transactions do snoop cpu devices caches, but
   devices might do their own caching which isn't snooped by the cpu and
   needs explicit device-side invalidate/flushing. This means pcie
   importers are not allowed to use pcie no-snoop transactions, intel igpu
   wouldn't be allowed to use MOCS that do the same, similar for arm
   integrated devices.

   Importers can skip all explicit cache management apis like
   dma_buf_begin/end_cpu_access, or the newly proposed
   dma_buf_begin/end_device_access here.

   We'd need to figure out what exactly this means for peer2peer
   transactions, I have no idea whether the no-snoop flag even does
   anything for those.

   We might also want to split up CPU_COHERENT into CPU_COHERENT_WB and
   CPU_WOHERENT_WC, so that importers know whether cpu reads are going to
   be crawling or not.

- MEMORY_COHERENT: devices transactions do not snoop any caches, but
   promise that all transactions are fully flushed to system memory. Any
   devices transactions which do fill cpu caches must call the proposed
   dma_buf_begin/end_device_access functions proposed here. Any cpu access
   must be braketed by calls to dma_buf_begin/end_cpu_access.

   If your device does fill cpu caches, then essentially you'd not be able
   to import such buffers. Not sure whether we need to put the
   responsibility of checking that onto importers or exporters. Ideally
   core dma-buf.c code would check this.

   Also maybe the cpu WC mapping mode would actually need to be a sub-mode
   for MEMORY_COHERENT, because all cpu wc achieves is to avoid the need to
   call dma_buf_begin/end_cpu_access, you would still need your devices to
   be memory coherent. And if they're not, then you cannot use that
   dma-buf.

   Or maybe alternatively we need to guarantee that exporters which set
   MEMORY_COHERENT implement dma_buf_begin/end_device_access to make things
   work for these cpu-coherent but not memory-coherent devices. This
   becomes very tricky with device/arch/bus specific details I think.

- DMA_API_COHERENT: The memory is allocated or mapped by the dma-api, and
   the exact coherency mode is not know. Importers _must_ braket all cpu
   and device access with the respective dma_buf functions. This is
   essentially the "we have no idea" default.

   Note that exporters might export memory allocated with dma_map_alloc
   with MEMORY_COHERENT or CPU_COHERENT if they know how the memory exactly
   works. E.g. for most arm soc gpu/display drivers we can assume that the
   dma-api gives us MEMORY_COHERENT or CPU_COHERENT_WC, and just use that.
   Essentially this would make the current implicit assumptions explicit.

   udmabuf would need to set this, definitely if Paul's patches to add the
   explicit device flushes land.

- DEFAULT_COHERENT: This would be the backwards compat legacy yolo
   behvaior. I'm not sure whether we should alias that with
   DMA_API_COHERENT or leave it as a special value to mark exporters which
   haven't been updated for the much more explicit coherency handling yet.

   The specification for this coherency mode would be a flat out "who
   knows, just don't break existing use-cases with actual users".
   Essentially the only reason we'd have this would be to make sure we can
   avoid regressions of these existing use-cases, by keeping whatever
   horrible heuristics we have in current exporters.

   It would also allow us to convert exporters and importers on a case by
   case basis.

Note that all these coherency modes are defined in terms of bus-sepecific
device access and in terms of dma_buf apis the importer must call or can
skip. This way we'd avoid having to change the dma-api in a first step,
and if this all works out properly we could then use the resulting dma-api
as a baseline to propose dma-api extensions.

When I read this for the first time my initial impression was that the idea mostly looked good, but while thinking about it more and more I came to the conclusion that this would go into the wrong direction.

Maybe I'm repeating myself, but I think we first of all have to talk a bit about some aspects of coherency:

1. Intra device coherency. This means that intra devices caches are invalidated before beginning an operation and flushed before signaling that an operation finished.

2. Inter device and device to CPU coherency. This means that caches which sit in between devices and between devices and the CPU need to be invalidated and flushed appropriately when buffers are accessed by different parties.

Number 1 is device specific, part of the DMA-buf framework and handled by dma_fences. As far as I can see that part is actually quite well designed and I don't see any obvious need for change.

Number 2 is platform specific and I completely agree with the DMA-api folks that this doesn't belong into DMA-buf in the first place. That's why I think the begin_cpu_access()/end_cpu_access() callbacks are actually a bit misplaced. We still can use those in the exporter, but to make better buffer placement decisions, but should not invalidate any caches when they are called.

The flushing and invalidation for platform caches should really be in the DMA-buf framework and not the exporter.

So in my thinking the enumeration you outlined above should really go into struct device and explaining to everybody what the coherency properties of DMA operations of this device is.

I think starting right out with designing dma-api extension is a few
bridges too far. Both from a "how do we convince upstream" pov, but maybe
even more from a "how do we figure out what we even need" pov.

Well I totally agree on the "how do we figure out what we even need", but I disagree a bit on that we don't know what DMA-api extension we need.

We don't have the full picture yet, but as I already outlined from the DMA-api pov we have two major things on our TODO list:

1. Somehow remove the struct pages from the DMA-buf *importer* API.

    My best suggestion at the moment for this is to split sg_tables into two data structures, one for the struct pages and one for the DMA addresses.

    Mangling the addresses to ensure that no importer messes with the struct pages was a good step, but it also creates problems when dma_sync_sg_for_cpu() dma_sync_for_device() are supposed to be called.

2. Add some dma_sync_sg_between_devices(A, B....).

    And on this I think we are on the same page that we are going to need this, but we are just not clear on who is going to use it.

Regards,
Christian.


Regards,
Christian.





-Sima
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