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146 lines
6.4 KiB
ReStructuredText
146 lines
6.4 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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============================
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PCI Peer-to-Peer DMA Support
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============================
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The PCI bus has pretty decent support for performing DMA transfers
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between two devices on the bus. This type of transaction is henceforth
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called Peer-to-Peer (or P2P). However, there are a number of issues that
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make P2P transactions tricky to do in a perfectly safe way.
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One of the biggest issues is that PCI doesn't require forwarding
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transactions between hierarchy domains, and in PCIe, each Root Port
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defines a separate hierarchy domain. To make things worse, there is no
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simple way to determine if a given Root Complex supports this or not.
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(See PCIe r4.0, sec 1.3.1). Therefore, as of this writing, the kernel
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only supports doing P2P when the endpoints involved are all behind the
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same PCI bridge, as such devices are all in the same PCI hierarchy
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domain, and the spec guarantees that all transactions within the
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hierarchy will be routable, but it does not require routing
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between hierarchies.
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The second issue is that to make use of existing interfaces in Linux,
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memory that is used for P2P transactions needs to be backed by struct
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pages. However, PCI BARs are not typically cache coherent so there are
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a few corner case gotchas with these pages so developers need to
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be careful about what they do with them.
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Driver Writer's Guide
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=====================
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In a given P2P implementation there may be three or more different
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types of kernel drivers in play:
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* Provider - A driver which provides or publishes P2P resources like
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memory or doorbell registers to other drivers.
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* Client - A driver which makes use of a resource by setting up a
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DMA transaction to or from it.
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* Orchestrator - A driver which orchestrates the flow of data between
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clients and providers.
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In many cases there could be overlap between these three types (i.e.,
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it may be typical for a driver to be both a provider and a client).
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For example, in the NVMe Target Copy Offload implementation:
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* The NVMe PCI driver is both a client, provider and orchestrator
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in that it exposes any CMB (Controller Memory Buffer) as a P2P memory
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resource (provider), it accepts P2P memory pages as buffers in requests
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to be used directly (client) and it can also make use of the CMB as
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submission queue entries (orchastrator).
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* The RDMA driver is a client in this arrangement so that an RNIC
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can DMA directly to the memory exposed by the NVMe device.
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* The NVMe Target driver (nvmet) can orchestrate the data from the RNIC
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to the P2P memory (CMB) and then to the NVMe device (and vice versa).
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This is currently the only arrangement supported by the kernel but
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one could imagine slight tweaks to this that would allow for the same
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functionality. For example, if a specific RNIC added a BAR with some
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memory behind it, its driver could add support as a P2P provider and
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then the NVMe Target could use the RNIC's memory instead of the CMB
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in cases where the NVMe cards in use do not have CMB support.
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Provider Drivers
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----------------
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A provider simply needs to register a BAR (or a portion of a BAR)
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as a P2P DMA resource using :c:func:`pci_p2pdma_add_resource()`.
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This will register struct pages for all the specified memory.
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After that it may optionally publish all of its resources as
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P2P memory using :c:func:`pci_p2pmem_publish()`. This will allow
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any orchestrator drivers to find and use the memory. When marked in
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this way, the resource must be regular memory with no side effects.
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For the time being this is fairly rudimentary in that all resources
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are typically going to be P2P memory. Future work will likely expand
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this to include other types of resources like doorbells.
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Client Drivers
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--------------
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A client driver typically only has to conditionally change its DMA map
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routine to use the mapping function :c:func:`pci_p2pdma_map_sg()` instead
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of the usual :c:func:`dma_map_sg()` function. Memory mapped in this
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way does not need to be unmapped.
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The client may also, optionally, make use of
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:c:func:`is_pci_p2pdma_page()` to determine when to use the P2P mapping
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functions and when to use the regular mapping functions. In some
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situations, it may be more appropriate to use a flag to indicate a
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given request is P2P memory and map appropriately. It is important to
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ensure that struct pages that back P2P memory stay out of code that
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does not have support for them as other code may treat the pages as
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regular memory which may not be appropriate.
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Orchestrator Drivers
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--------------------
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The first task an orchestrator driver must do is compile a list of
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all client devices that will be involved in a given transaction. For
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example, the NVMe Target driver creates a list including the namespace
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block device and the RNIC in use. If the orchestrator has access to
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a specific P2P provider to use it may check compatibility using
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:c:func:`pci_p2pdma_distance()` otherwise it may find a memory provider
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that's compatible with all clients using :c:func:`pci_p2pmem_find()`.
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If more than one provider is supported, the one nearest to all the clients will
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be chosen first. If more than one provider is an equal distance away, the
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one returned will be chosen at random (it is not an arbitrary but
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truely random). This function returns the PCI device to use for the provider
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with a reference taken and therefore when it's no longer needed it should be
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returned with pci_dev_put().
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Once a provider is selected, the orchestrator can then use
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:c:func:`pci_alloc_p2pmem()` and :c:func:`pci_free_p2pmem()` to
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allocate P2P memory from the provider. :c:func:`pci_p2pmem_alloc_sgl()`
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and :c:func:`pci_p2pmem_free_sgl()` are convenience functions for
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allocating scatter-gather lists with P2P memory.
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Struct Page Caveats
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-------------------
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Driver writers should be very careful about not passing these special
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struct pages to code that isn't prepared for it. At this time, the kernel
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interfaces do not have any checks for ensuring this. This obviously
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precludes passing these pages to userspace.
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P2P memory is also technically IO memory but should never have any side
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effects behind it. Thus, the order of loads and stores should not be important
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and ioreadX(), iowriteX() and friends should not be necessary.
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However, as the memory is not cache coherent, if access ever needs to
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be protected by a spinlock then :c:func:`mmiowb()` must be used before
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unlocking the lock. (See ACQUIRES VS I/O ACCESSES in
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Documentation/memory-barriers.txt)
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P2P DMA Support Library
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=======================
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.. kernel-doc:: drivers/pci/p2pdma.c
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:export:
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