.. SPDX-License-Identifier: GPL-2.0 ============================ PCI Peer-to-Peer DMA Support ============================ The PCI bus has pretty decent support for performing DMA transfers between two devices on the bus. This type of transaction is henceforth called Peer-to-Peer (or P2P). However, there are a number of issues that make P2P transactions tricky to do in a perfectly safe way. For PCIe the routing of Transaction Layer Packets (TLPs) is well-defined up until they reach a host bridge or root port. If the path includes PCIe switches then based on the ACS settings the transaction can route entirely within the PCIe hierarchy and never reach the root port. The kernel will evaluate the PCIe topology and always permit P2P in these well-defined cases. However, if the P2P transaction reaches the host bridge then it might have to hairpin back out the same root port, be routed inside the CPU SOC to another PCIe root port, or routed internally to the SOC. The PCIe specification doesn't define the forwarding of transactions between hierarchy domains and kernel defaults to blocking such routing. There is an allow list to allow detecting known-good HW, in which case P2P between any two PCIe devices will be permitted. Since P2P inherently is doing transactions between two devices it requires two drivers to be co-operating inside the kernel. The providing driver has to convey its MMIO to the consuming driver. To meet the driver model lifecycle rules the MMIO must have all DMA mapping removed, all CPU accesses prevented, all page table mappings undone before the providing driver completes remove(). This requires the providing and consuming driver to actively work together to guarantee that the consuming driver has stopped using the MMIO during a removal cycle. This is done by either a synchronous invalidation shutdown or waiting for all usage refcounts to reach zero. At the lowest level the P2P subsystem offers a naked struct p2p_provider that delegates lifecycle management to the providing driver. It is expected that drivers using this option will wrap their MMIO memory in DMABUF and use DMABUF to provide an invalidation shutdown. These MMIO addresess have no struct page, and if used with mmap() must create special PTEs. As such there are very few kernel uAPIs that can accept pointers to them; in particular they cannot be used with read()/write(), including O_DIRECT. Building on this, the subsystem offers a layer to wrap the MMIO in a ZONE_DEVICE pgmap of MEMORY_DEVICE_PCI_P2PDMA to create struct pages. The lifecycle of pgmap ensures that when the pgmap is destroyed all other drivers have stopped using the MMIO. This option works with O_DIRECT flows, in some cases, if the underlying subsystem supports handling MEMORY_DEVICE_PCI_P2PDMA through FOLL_PCI_P2PDMA. The use of FOLL_LONGTERM is prevented. As this relies on pgmap it also relies on architecture support along with alignment and minimum size limitations. Driver Writer's Guide ===================== In a given P2P implementation there may be three or more different types of kernel drivers in play: * Provider - A driver which provides or publishes P2P resources like memory or doorbell registers to other drivers. * Client - A driver which makes use of a resource by setting up a DMA transaction to or from it. * Orchestrator - A driver which orchestrates the flow of data between clients and providers. In many cases there could be overlap between these three types (i.e., it may be typical for a driver to be both a provider and a client). For example, in the NVMe Target Copy Offload implementation: * The NVMe PCI driver is both a client, provider and orchestrator in that it exposes any CMB (Controller Memory Buffer) as a P2P memory resource (provider), it accepts P2P memory pages as buffers in requests to be used directly (client) and it can also make use of the CMB as submission queue entries (orchestrator). * The RDMA driver is a client in this arrangement so that an RNIC can DMA directly to the memory exposed by the NVMe device. * The NVMe Target driver (nvmet) can orchestrate the data from the RNIC to the P2P memory (CMB) and then to the NVMe device (and vice versa). This is currently the only arrangement supported by the kernel but one could imagine slight tweaks to this that would allow for the same functionality. For example, if a specific RNIC added a BAR with some memory behind it, its driver could add support as a P2P provider and then the NVMe Target could use the RNIC's memory instead of the CMB in cases where the NVMe cards in use do not have CMB support. Provider Drivers ---------------- A provider simply needs to register a BAR (or a portion of a BAR) as a P2P DMA resource using :c:func:`pci_p2pdma_add_resource()`. This will register struct pages for all the specified memory. After that it may optionally publish all of its resources as P2P memory using :c:func:`pci_p2pmem_publish()`. This will allow any orchestrator drivers to find and use the memory. When marked in this way, the resource must be regular memory with no side effects. For the time being this is fairly rudimentary in that all resources are typically going to be P2P memory. Future work will likely expand this to include other types of resources like doorbells. Client Drivers -------------- A client driver only has to use the mapping API :c:func:`dma_map_sg()` and :c:func:`dma_unmap_sg()` functions as usual, and the implementation will do the right thing for the P2P capable memory. Orchestrator Drivers -------------------- The first task an orchestrator driver must do is compile a list of all client devices that will be involved in a given transaction. For example, the NVMe Target driver creates a list including the namespace block device and the RNIC in use. If the orchestrator has access to a specific P2P provider to use it may check compatibility using :c:func:`pci_p2pdma_distance()` otherwise it may find a memory provider that's compatible with all clients using :c:func:`pci_p2pmem_find()`. If more than one provider is supported, the one nearest to all the clients will be chosen first. If more than one provider is an equal distance away, the one returned will be chosen at random (it is not an arbitrary but truly random). This function returns the PCI device to use for the provider with a reference taken and therefore when it's no longer needed it should be returned with pci_dev_put(). Once a provider is selected, the orchestrator can then use :c:func:`pci_alloc_p2pmem()` and :c:func:`pci_free_p2pmem()` to allocate P2P memory from the provider. :c:func:`pci_p2pmem_alloc_sgl()` and :c:func:`pci_p2pmem_free_sgl()` are convenience functions for allocating scatter-gather lists with P2P memory. Struct Page Caveats ------------------- While the MEMORY_DEVICE_PCI_P2PDMA pages can be installed in VMAs, pin_user_pages() and related will not return them unless FOLL_PCI_P2PDMA is set. The MEMORY_DEVICE_PCI_P2PDMA pages require care to support in the kernel. The KVA is still MMIO and must still be accessed through the normal readX()/writeX()/etc helpers. Direct CPU access (e.g. memcpy) is forbidden, just like any other MMIO mapping. While this will actually work on some architectures, others will experience corruption or just crash in the kernel. Supporting FOLL_PCI_P2PDMA in a subsystem requires scrubbing it to ensure no CPU access happens. Usage With DMABUF ================= DMABUF provides an alternative to the above struct page-based client/provider/orchestrator system and should be used when struct page doesn't exist. In this mode the exporting driver will wrap some of its MMIO in a DMABUF and give the DMABUF FD to userspace. Userspace can then pass the FD to an importing driver which will ask the exporting driver to map it to the importer. In this case the initiator and target pci_devices are known and the P2P subsystem is used to determine the mapping type. The phys_addr_t-based DMA API is used to establish the dma_addr_t. Lifecycle is controlled by DMABUF move_notify(). When the exporting driver wants to remove() it must deliver an invalidation shutdown to all DMABUF importing drivers through move_notify() and synchronously DMA unmap all the MMIO. No importing driver can continue to have a DMA map to the MMIO after the exporting driver has destroyed its p2p_provider. P2P DMA Support Library ======================= .. kernel-doc:: drivers/pci/p2pdma.c :export: