bbff2f321a
Currently, AF_XDP only supports a fixed frame-size memory scheme where each frame is referenced via an index (idx). A user passes the frame index to the kernel, and the kernel acts upon the data. Some NICs, however, do not have a fixed frame-size model, instead they have a model where a memory window is passed to the hardware and multiple frames are filled into that window (referred to as the "type-writer" model). By changing the descriptor format from the current frame index addressing scheme, AF_XDP can in the future be extended to support these kinds of NICs. In the index-based model, an idx refers to a frame of size frame_size. Addressing a frame in the UMEM is done by offseting the UMEM starting address by a global offset, idx * frame_size + offset. Communicating via the fill- and completion-rings are done by means of idx. In this commit, the idx is removed in favor of an address (addr), which is a relative address ranging over the UMEM. To convert an idx-based address to the new addr is simply: addr = idx * frame_size + offset. We also stop referring to the UMEM "frame" as a frame. Instead it is simply called a chunk. To transfer ownership of a chunk to the kernel, the addr of the chunk is passed in the fill-ring. Note, that the kernel will mask addr to make it chunk aligned, so there is no need for userspace to do that. E.g., for a chunk size of 2k, passing an addr of 2048, 2050 or 3000 to the fill-ring will refer to the same chunk. On the completion-ring, the addr will match that of the Tx descriptor, passed to the kernel. Changing the descriptor format to use chunks/addr will allow for future changes to move to a type-writer based model, where multiple frames can reside in one chunk. In this model passing one single chunk into the fill-ring, would potentially result in multiple Rx descriptors. This commit changes the uapi of AF_XDP sockets, and updates the documentation. Signed-off-by: Björn Töpel <bjorn.topel@intel.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
312 lines
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ReStructuredText
312 lines
11 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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======
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AF_XDP
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======
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Overview
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========
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AF_XDP is an address family that is optimized for high performance
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packet processing.
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This document assumes that the reader is familiar with BPF and XDP. If
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not, the Cilium project has an excellent reference guide at
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http://cilium.readthedocs.io/en/latest/bpf/.
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Using the XDP_REDIRECT action from an XDP program, the program can
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redirect ingress frames to other XDP enabled netdevs, using the
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bpf_redirect_map() function. AF_XDP sockets enable the possibility for
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XDP programs to redirect frames to a memory buffer in a user-space
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application.
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An AF_XDP socket (XSK) is created with the normal socket()
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syscall. Associated with each XSK are two rings: the RX ring and the
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TX ring. A socket can receive packets on the RX ring and it can send
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packets on the TX ring. These rings are registered and sized with the
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setsockopts XDP_RX_RING and XDP_TX_RING, respectively. It is mandatory
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to have at least one of these rings for each socket. An RX or TX
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descriptor ring points to a data buffer in a memory area called a
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UMEM. RX and TX can share the same UMEM so that a packet does not have
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to be copied between RX and TX. Moreover, if a packet needs to be kept
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for a while due to a possible retransmit, the descriptor that points
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to that packet can be changed to point to another and reused right
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away. This again avoids copying data.
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The UMEM consists of a number of equally sized chunks. A descriptor in
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one of the rings references a frame by referencing its addr. The addr
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is simply an offset within the entire UMEM region. The user space
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allocates memory for this UMEM using whatever means it feels is most
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appropriate (malloc, mmap, huge pages, etc). This memory area is then
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registered with the kernel using the new setsockopt XDP_UMEM_REG. The
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UMEM also has two rings: the FILL ring and the COMPLETION ring. The
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fill ring is used by the application to send down addr for the kernel
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to fill in with RX packet data. References to these frames will then
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appear in the RX ring once each packet has been received. The
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completion ring, on the other hand, contains frame addr that the
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kernel has transmitted completely and can now be used again by user
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space, for either TX or RX. Thus, the frame addrs appearing in the
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completion ring are addrs that were previously transmitted using the
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TX ring. In summary, the RX and FILL rings are used for the RX path
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and the TX and COMPLETION rings are used for the TX path.
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The socket is then finally bound with a bind() call to a device and a
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specific queue id on that device, and it is not until bind is
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completed that traffic starts to flow.
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The UMEM can be shared between processes, if desired. If a process
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wants to do this, it simply skips the registration of the UMEM and its
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corresponding two rings, sets the XDP_SHARED_UMEM flag in the bind
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call and submits the XSK of the process it would like to share UMEM
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with as well as its own newly created XSK socket. The new process will
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then receive frame addr references in its own RX ring that point to
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this shared UMEM. Note that since the ring structures are
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single-consumer / single-producer (for performance reasons), the new
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process has to create its own socket with associated RX and TX rings,
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since it cannot share this with the other process. This is also the
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reason that there is only one set of FILL and COMPLETION rings per
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UMEM. It is the responsibility of a single process to handle the UMEM.
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How is then packets distributed from an XDP program to the XSKs? There
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is a BPF map called XSKMAP (or BPF_MAP_TYPE_XSKMAP in full). The
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user-space application can place an XSK at an arbitrary place in this
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map. The XDP program can then redirect a packet to a specific index in
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this map and at this point XDP validates that the XSK in that map was
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indeed bound to that device and ring number. If not, the packet is
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dropped. If the map is empty at that index, the packet is also
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dropped. This also means that it is currently mandatory to have an XDP
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program loaded (and one XSK in the XSKMAP) to be able to get any
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traffic to user space through the XSK.
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AF_XDP can operate in two different modes: XDP_SKB and XDP_DRV. If the
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driver does not have support for XDP, or XDP_SKB is explicitly chosen
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when loading the XDP program, XDP_SKB mode is employed that uses SKBs
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together with the generic XDP support and copies out the data to user
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space. A fallback mode that works for any network device. On the other
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hand, if the driver has support for XDP, it will be used by the AF_XDP
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code to provide better performance, but there is still a copy of the
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data into user space.
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Concepts
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========
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In order to use an AF_XDP socket, a number of associated objects need
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to be setup.
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Jonathan Corbet has also written an excellent article on LWN,
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"Accelerating networking with AF_XDP". It can be found at
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https://lwn.net/Articles/750845/.
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UMEM
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----
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UMEM is a region of virtual contiguous memory, divided into
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equal-sized frames. An UMEM is associated to a netdev and a specific
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queue id of that netdev. It is created and configured (chunk size,
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headroom, start address and size) by using the XDP_UMEM_REG setsockopt
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system call. A UMEM is bound to a netdev and queue id, via the bind()
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system call.
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An AF_XDP is socket linked to a single UMEM, but one UMEM can have
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multiple AF_XDP sockets. To share an UMEM created via one socket A,
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the next socket B can do this by setting the XDP_SHARED_UMEM flag in
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struct sockaddr_xdp member sxdp_flags, and passing the file descriptor
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of A to struct sockaddr_xdp member sxdp_shared_umem_fd.
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The UMEM has two single-producer/single-consumer rings, that are used
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to transfer ownership of UMEM frames between the kernel and the
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user-space application.
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Rings
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-----
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There are a four different kind of rings: Fill, Completion, RX and
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TX. All rings are single-producer/single-consumer, so the user-space
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application need explicit synchronization of multiple
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processes/threads are reading/writing to them.
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The UMEM uses two rings: Fill and Completion. Each socket associated
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with the UMEM must have an RX queue, TX queue or both. Say, that there
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is a setup with four sockets (all doing TX and RX). Then there will be
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one Fill ring, one Completion ring, four TX rings and four RX rings.
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The rings are head(producer)/tail(consumer) based rings. A producer
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writes the data ring at the index pointed out by struct xdp_ring
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producer member, and increasing the producer index. A consumer reads
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the data ring at the index pointed out by struct xdp_ring consumer
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member, and increasing the consumer index.
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The rings are configured and created via the _RING setsockopt system
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calls and mmapped to user-space using the appropriate offset to mmap()
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(XDP_PGOFF_RX_RING, XDP_PGOFF_TX_RING, XDP_UMEM_PGOFF_FILL_RING and
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XDP_UMEM_PGOFF_COMPLETION_RING).
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The size of the rings need to be of size power of two.
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UMEM Fill Ring
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~~~~~~~~~~~~~~
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The Fill ring is used to transfer ownership of UMEM frames from
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user-space to kernel-space. The UMEM addrs are passed in the ring. As
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an example, if the UMEM is 64k and each chunk is 4k, then the UMEM has
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16 chunks and can pass addrs between 0 and 64k.
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Frames passed to the kernel are used for the ingress path (RX rings).
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The user application produces UMEM addrs to this ring. Note that the
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kernel will mask the incoming addr. E.g. for a chunk size of 2k, the
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log2(2048) LSB of the addr will be masked off, meaning that 2048, 2050
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and 3000 refers to the same chunk.
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UMEM Completetion Ring
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~~~~~~~~~~~~~~~~~~~~~~
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The Completion Ring is used transfer ownership of UMEM frames from
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kernel-space to user-space. Just like the Fill ring, UMEM indicies are
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used.
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Frames passed from the kernel to user-space are frames that has been
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sent (TX ring) and can be used by user-space again.
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The user application consumes UMEM addrs from this ring.
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RX Ring
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~~~~~~~
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The RX ring is the receiving side of a socket. Each entry in the ring
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is a struct xdp_desc descriptor. The descriptor contains UMEM offset
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(addr) and the length of the data (len).
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If no frames have been passed to kernel via the Fill ring, no
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descriptors will (or can) appear on the RX ring.
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The user application consumes struct xdp_desc descriptors from this
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ring.
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TX Ring
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~~~~~~~
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The TX ring is used to send frames. The struct xdp_desc descriptor is
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filled (index, length and offset) and passed into the ring.
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To start the transfer a sendmsg() system call is required. This might
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be relaxed in the future.
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The user application produces struct xdp_desc descriptors to this
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ring.
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XSKMAP / BPF_MAP_TYPE_XSKMAP
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----------------------------
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On XDP side there is a BPF map type BPF_MAP_TYPE_XSKMAP (XSKMAP) that
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is used in conjunction with bpf_redirect_map() to pass the ingress
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frame to a socket.
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The user application inserts the socket into the map, via the bpf()
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system call.
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Note that if an XDP program tries to redirect to a socket that does
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not match the queue configuration and netdev, the frame will be
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dropped. E.g. an AF_XDP socket is bound to netdev eth0 and
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queue 17. Only the XDP program executing for eth0 and queue 17 will
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successfully pass data to the socket. Please refer to the sample
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application (samples/bpf/) in for an example.
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Usage
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=====
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In order to use AF_XDP sockets there are two parts needed. The
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user-space application and the XDP program. For a complete setup and
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usage example, please refer to the sample application. The user-space
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side is xdpsock_user.c and the XDP side xdpsock_kern.c.
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Naive ring dequeue and enqueue could look like this::
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// struct xdp_rxtx_ring {
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// __u32 *producer;
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// __u32 *consumer;
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// struct xdp_desc *desc;
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// };
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// struct xdp_umem_ring {
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// __u32 *producer;
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// __u32 *consumer;
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// __u64 *desc;
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// };
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// typedef struct xdp_rxtx_ring RING;
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// typedef struct xdp_umem_ring RING;
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// typedef struct xdp_desc RING_TYPE;
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// typedef __u64 RING_TYPE;
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int dequeue_one(RING *ring, RING_TYPE *item)
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{
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__u32 entries = *ring->producer - *ring->consumer;
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if (entries == 0)
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return -1;
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// read-barrier!
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*item = ring->desc[*ring->consumer & (RING_SIZE - 1)];
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(*ring->consumer)++;
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return 0;
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}
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int enqueue_one(RING *ring, const RING_TYPE *item)
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{
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u32 free_entries = RING_SIZE - (*ring->producer - *ring->consumer);
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if (free_entries == 0)
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return -1;
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ring->desc[*ring->producer & (RING_SIZE - 1)] = *item;
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// write-barrier!
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(*ring->producer)++;
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return 0;
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}
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For a more optimized version, please refer to the sample application.
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Sample application
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==================
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There is a xdpsock benchmarking/test application included that
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demonstrates how to use AF_XDP sockets with both private and shared
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UMEMs. Say that you would like your UDP traffic from port 4242 to end
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up in queue 16, that we will enable AF_XDP on. Here, we use ethtool
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for this::
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ethtool -N p3p2 rx-flow-hash udp4 fn
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ethtool -N p3p2 flow-type udp4 src-port 4242 dst-port 4242 \
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action 16
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Running the rxdrop benchmark in XDP_DRV mode can then be done
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using::
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samples/bpf/xdpsock -i p3p2 -q 16 -r -N
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For XDP_SKB mode, use the switch "-S" instead of "-N" and all options
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can be displayed with "-h", as usual.
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Credits
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=======
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- Björn Töpel (AF_XDP core)
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- Magnus Karlsson (AF_XDP core)
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- Alexander Duyck
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- Alexei Starovoitov
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- Daniel Borkmann
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- Jesper Dangaard Brouer
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- John Fastabend
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- Jonathan Corbet (LWN coverage)
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- Michael S. Tsirkin
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- Qi Z Zhang
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- Willem de Bruijn
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