ab0085bd79
[ Upstream commit f7306acec9aae9893d15e745c8791124d42ab10a ]
Initial creation of an AF_XDP socket requires CAP_NET_RAW capability. A
privileged process might create the socket and pass it to a non-privileged
process for later use. However, that process will be able to bind the socket
to any network interface. Even though it will not be able to receive any
traffic without modification of the BPF map, the situation is not ideal.
Sockets already have a mechanism that can be used to restrict what interface
they can be attached to. That is SO_BINDTODEVICE.
To change the SO_BINDTODEVICE binding the process will need CAP_NET_RAW.
Make xsk_bind() honor the SO_BINDTODEVICE in order to allow safer workflow
when non-privileged process is using AF_XDP.
The intended workflow is following:
1. First process creates a bare socket with socket(AF_XDP, ...).
2. First process loads the XSK program to the interface.
3. First process adds the socket fd to a BPF map.
4. First process ties socket fd to a particular interface using
SO_BINDTODEVICE.
5. First process sends socket fd to a second process.
6. Second process allocates UMEM.
7. Second process binds socket to the interface with bind(...).
8. Second process sends/receives the traffic.
All the steps above are possible today if the first process is privileged
and the second one has sufficient RLIMIT_MEMLOCK and no capabilities.
However, the second process will be able to bind the socket to any interface
it wants on step 7 and send traffic from it. With the proposed change, the
second process will be able to bind the socket only to a specific interface
chosen by the first process at step 4.
Fixes: 965a990984
("xsk: add support for bind for Rx")
Signed-off-by: Ilya Maximets <i.maximets@ovn.org>
Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
Acked-by: Magnus Karlsson <magnus.karlsson@intel.com>
Acked-by: John Fastabend <john.fastabend@gmail.com>
Acked-by: Jason Wang <jasowang@redhat.com>
Link: https://lore.kernel.org/bpf/20230703175329.3259672-1-i.maximets@ovn.org
Signed-off-by: Sasha Levin <sashal@kernel.org>
575 lines
22 KiB
ReStructuredText
575 lines
22 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. These objects and their options are explained in the
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following sections.
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For an overview on how AF_XDP works, you can also take a look at the
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Linux Plumbers paper from 2018 on the subject:
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http://vger.kernel.org/lpc_net2018_talks/lpc18_paper_af_xdp_perf-v2.pdf. Do
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NOT consult the paper from 2017 on "AF_PACKET v4", the first attempt
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at AF_XDP. Nearly everything changed since then. Jonathan Corbet has
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also written an excellent article on LWN, "Accelerating networking
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with AF_XDP". It can be found at 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, if
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running the application with aligned chunk mode, the kernel will mask
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the incoming addr. E.g. for a chunk size of 2k, the log2(2048) LSB of
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the addr will be masked off, meaning that 2048, 2050 and 3000 refers
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to the same chunk. If the user application is run in the unaligned
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chunks mode, then the incoming addr will be left untouched.
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UMEM Completion 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 indices 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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Libbpf
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======
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Libbpf is a helper library for eBPF and XDP that makes using these
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technologies a lot simpler. It also contains specific helper functions
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in tools/lib/bpf/xsk.h for facilitating the use of AF_XDP. It
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contains two types of functions: those that can be used to make the
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setup of AF_XDP socket easier and ones that can be used in the data
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plane to access the rings safely and quickly. To see an example on how
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to use this API, please take a look at the sample application in
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samples/bpf/xdpsock_usr.c which uses libbpf for both setup and data
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plane operations.
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We recommend that you use this library unless you have become a power
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user. It will make your program a lot simpler.
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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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Configuration Flags and Socket Options
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======================================
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These are the various configuration flags that can be used to control
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and monitor the behavior of AF_XDP sockets.
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XDP_COPY and XDP_ZERO_COPY bind flags
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-------------------------------------
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When you bind to a socket, the kernel will first try to use zero-copy
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copy. If zero-copy is not supported, it will fall back on using copy
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mode, i.e. copying all packets out to user space. But if you would
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like to force a certain mode, you can use the following flags. If you
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pass the XDP_COPY flag to the bind call, the kernel will force the
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socket into copy mode. If it cannot use copy mode, the bind call will
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fail with an error. Conversely, the XDP_ZERO_COPY flag will force the
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socket into zero-copy mode or fail.
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XDP_SHARED_UMEM bind flag
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-------------------------
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This flag enables you to bind multiple sockets to the same UMEM, but
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only if they share the same queue id. In this mode, each socket has
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their own RX and TX rings, but the UMEM (tied to the fist socket
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created) only has a single FILL ring and a single COMPLETION
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ring. To use this mode, create the first socket and bind it in the normal
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way. Create a second socket and create an RX and a TX ring, or at
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least one of them, but no FILL or COMPLETION rings as the ones from
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the first socket will be used. In the bind call, set he
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XDP_SHARED_UMEM option and provide the initial socket's fd in the
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sxdp_shared_umem_fd field. You can attach an arbitrary number of extra
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sockets this way.
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What socket will then a packet arrive on? This is decided by the XDP
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program. Put all the sockets in the XSK_MAP and just indicate which
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index in the array you would like to send each packet to. A simple
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round-robin example of distributing packets is shown below:
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.. code-block:: c
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#include <linux/bpf.h>
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#include "bpf_helpers.h"
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#define MAX_SOCKS 16
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struct {
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__uint(type, BPF_MAP_TYPE_XSKMAP);
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__uint(max_entries, MAX_SOCKS);
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__uint(key_size, sizeof(int));
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__uint(value_size, sizeof(int));
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} xsks_map SEC(".maps");
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static unsigned int rr;
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SEC("xdp_sock") int xdp_sock_prog(struct xdp_md *ctx)
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{
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rr = (rr + 1) & (MAX_SOCKS - 1);
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return bpf_redirect_map(&xsks_map, rr, 0);
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}
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Note, that since there is only a single set of FILL and COMPLETION
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rings, and they are single producer, single consumer rings, you need
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to make sure that multiple processes or threads do not use these rings
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concurrently. There are no synchronization primitives in the
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libbpf code that protects multiple users at this point in time.
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XDP_USE_NEED_WAKEUP bind flag
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-----------------------------
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This option adds support for a new flag called need_wakeup that is
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present in the FILL ring and the TX ring, the rings for which user
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space is a producer. When this option is set in the bind call, the
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need_wakeup flag will be set if the kernel needs to be explicitly
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woken up by a syscall to continue processing packets. If the flag is
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zero, no syscall is needed.
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If the flag is set on the FILL ring, the application needs to call
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poll() to be able to continue to receive packets on the RX ring. This
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can happen, for example, when the kernel has detected that there are no
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more buffers on the FILL ring and no buffers left on the RX HW ring of
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the NIC. In this case, interrupts are turned off as the NIC cannot
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receive any packets (as there are no buffers to put them in), and the
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need_wakeup flag is set so that user space can put buffers on the
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FILL ring and then call poll() so that the kernel driver can put these
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buffers on the HW ring and start to receive packets.
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If the flag is set for the TX ring, it means that the application
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needs to explicitly notify the kernel to send any packets put on the
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TX ring. This can be accomplished either by a poll() call, as in the
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RX path, or by calling sendto().
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An example of how to use this flag can be found in
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samples/bpf/xdpsock_user.c. An example with the use of libbpf helpers
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would look like this for the TX path:
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.. code-block:: c
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if (xsk_ring_prod__needs_wakeup(&my_tx_ring))
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sendto(xsk_socket__fd(xsk_handle), NULL, 0, MSG_DONTWAIT, NULL, 0);
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I.e., only use the syscall if the flag is set.
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We recommend that you always enable this mode as it usually leads to
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better performance especially if you run the application and the
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driver on the same core, but also if you use different cores for the
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application and the kernel driver, as it reduces the number of
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syscalls needed for the TX path.
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XDP_{RX|TX|UMEM_FILL|UMEM_COMPLETION}_RING setsockopts
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------------------------------------------------------
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These setsockopts sets the number of descriptors that the RX, TX,
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FILL, and COMPLETION rings respectively should have. It is mandatory
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to set the size of at least one of the RX and TX rings. If you set
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both, you will be able to both receive and send traffic from your
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application, but if you only want to do one of them, you can save
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resources by only setting up one of them. Both the FILL ring and the
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COMPLETION ring are mandatory if you have a UMEM tied to your socket,
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which is the normal case. But if the XDP_SHARED_UMEM flag is used, any
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socket after the first one does not have a UMEM and should in that
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case not have any FILL or COMPLETION rings created.
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XDP_UMEM_REG setsockopt
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-----------------------
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This setsockopt registers a UMEM to a socket. This is the area that
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contain all the buffers that packet can recide in. The call takes a
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pointer to the beginning of this area and the size of it. Moreover, it
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also has parameter called chunk_size that is the size that the UMEM is
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divided into. It can only be 2K or 4K at the moment. If you have an
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UMEM area that is 128K and a chunk size of 2K, this means that you
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will be able to hold a maximum of 128K / 2K = 64 packets in your UMEM
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area and that your largest packet size can be 2K.
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There is also an option to set the headroom of each single buffer in
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the UMEM. If you set this to N bytes, it means that the packet will
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start N bytes into the buffer leaving the first N bytes for the
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application to use. The final option is the flags field, but it will
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be dealt with in separate sections for each UMEM flag.
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SO_BINDTODEVICE setsockopt
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--------------------------
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This is a generic SOL_SOCKET option that can be used to tie AF_XDP
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socket to a particular network interface. It is useful when a socket
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is created by a privileged process and passed to a non-privileged one.
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Once the option is set, kernel will refuse attempts to bind that socket
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to a different interface. Updating the value requires CAP_NET_RAW.
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XDP_STATISTICS getsockopt
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-------------------------
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Gets drop statistics of a socket that can be useful for debug
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purposes. The supported statistics are shown below:
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.. code-block:: c
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struct xdp_statistics {
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__u64 rx_dropped; /* Dropped for reasons other than invalid desc */
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__u64 rx_invalid_descs; /* Dropped due to invalid descriptor */
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__u64 tx_invalid_descs; /* Dropped due to invalid descriptor */
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};
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XDP_OPTIONS getsockopt
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----------------------
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Gets options from an XDP socket. The only one supported so far is
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XDP_OPTIONS_ZEROCOPY which tells you if zero-copy is on or not.
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Usage
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=====
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In order to use AF_XDP sockets two parts are 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 is part of libbpf.
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The XDP code sample included in tools/lib/bpf/xsk.c is the following:
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.. code-block:: c
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SEC("xdp_sock") int xdp_sock_prog(struct xdp_md *ctx)
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{
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int index = ctx->rx_queue_index;
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// A set entry here means that the corresponding queue_id
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// has an active AF_XDP socket bound to it.
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if (bpf_map_lookup_elem(&xsks_map, &index))
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return bpf_redirect_map(&xsks_map, index, 0);
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return XDP_PASS;
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}
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A simple but not so performance ring dequeue and enqueue could look
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like this:
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.. code-block:: c
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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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But please use the libbpf functions as they are optimized and ready to
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use. Will make your life easier.
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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 private UMEMs. Say that
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you would like your UDP traffic from port 4242 to end up in queue 16,
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that we will enable AF_XDP on. Here, we use ethtool 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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This sample application uses libbpf to make the setup and usage of
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AF_XDP simpler. If you want to know how the raw uapi of AF_XDP is
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really used to make something more advanced, take a look at the libbpf
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code in tools/lib/bpf/xsk.[ch].
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FAQ
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=======
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Q: I am not seeing any traffic on the socket. What am I doing wrong?
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A: When a netdev of a physical NIC is initialized, Linux usually
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allocates one RX and TX queue pair per core. So on a 8 core system,
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queue ids 0 to 7 will be allocated, one per core. In the AF_XDP
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bind call or the xsk_socket__create libbpf function call, you
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specify a specific queue id to bind to and it is only the traffic
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towards that queue you are going to get on you socket. So in the
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example above, if you bind to queue 0, you are NOT going to get any
|
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traffic that is distributed to queues 1 through 7. If you are
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lucky, you will see the traffic, but usually it will end up on one
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of the queues you have not bound to.
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There are a number of ways to solve the problem of getting the
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traffic you want to the queue id you bound to. If you want to see
|
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all the traffic, you can force the netdev to only have 1 queue, queue
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id 0, and then bind to queue 0. You can use ethtool to do this::
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sudo ethtool -L <interface> combined 1
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If you want to only see part of the traffic, you can program the
|
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NIC through ethtool to filter out your traffic to a single queue id
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that you can bind your XDP socket to. Here is one example in which
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UDP traffic to and from port 4242 are sent to queue 2::
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|
sudo ethtool -N <interface> rx-flow-hash udp4 fn
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|
sudo ethtool -N <interface> flow-type udp4 src-port 4242 dst-port \
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4242 action 2
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|
A number of other ways are possible all up to the capabilities of
|
|
the NIC you have.
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|
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|
Q: Can I use the XSKMAP to implement a switch betwen different umems
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|
in copy mode?
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|
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|
A: The short answer is no, that is not supported at the moment. The
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|
XSKMAP can only be used to switch traffic coming in on queue id X
|
|
to sockets bound to the same queue id X. The XSKMAP can contain
|
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sockets bound to different queue ids, for example X and Y, but only
|
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traffic goming in from queue id Y can be directed to sockets bound
|
|
to the same queue id Y. In zero-copy mode, you should use the
|
|
switch, or other distribution mechanism, in your NIC to direct
|
|
traffic to the correct queue id and socket.
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|
Credits
|
|
=======
|
|
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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
|