mirror of
https://github.com/AuxXxilium/linux_dsm_epyc7002.git
synced 2024-12-04 03:16:41 +07:00
496322bc91
Pull networking updates from David Miller:
"This is a re-do of the net-next pull request for the current merge
window. The only difference from the one I made the other day is that
this has Eliezer's interface renames and the timeout handling changes
made based upon your feedback, as well as a few bug fixes that have
trickeled in.
Highlights:
1) Low latency device polling, eliminating the cost of interrupt
handling and context switches. Allows direct polling of a network
device from socket operations, such as recvmsg() and poll().
Currently ixgbe, mlx4, and bnx2x support this feature.
Full high level description, performance numbers, and design in
commit 0a4db187a9
("Merge branch 'll_poll'")
From Eliezer Tamir.
2) With the routing cache removed, ip_check_mc_rcu() gets exercised
more than ever before in the case where we have lots of multicast
addresses. Use a hash table instead of a simple linked list, from
Eric Dumazet.
3) Add driver for Atheros CQA98xx 802.11ac wireless devices, from
Bartosz Markowski, Janusz Dziedzic, Kalle Valo, Marek Kwaczynski,
Marek Puzyniak, Michal Kazior, and Sujith Manoharan.
4) Support reporting the TUN device persist flag to userspace, from
Pavel Emelyanov.
5) Allow controlling network device VF link state using netlink, from
Rony Efraim.
6) Support GRE tunneling in openvswitch, from Pravin B Shelar.
7) Adjust SOCK_MIN_RCVBUF and SOCK_MIN_SNDBUF for modern times, from
Daniel Borkmann and Eric Dumazet.
8) Allow controlling of TCP quickack behavior on a per-route basis,
from Cong Wang.
9) Several bug fixes and improvements to vxlan from Stephen
Hemminger, Pravin B Shelar, and Mike Rapoport. In particular,
support receiving on multiple UDP ports.
10) Major cleanups, particular in the area of debugging and cookie
lifetime handline, to the SCTP protocol code. From Daniel
Borkmann.
11) Allow packets to cross network namespaces when traversing tunnel
devices. From Nicolas Dichtel.
12) Allow monitoring netlink traffic via AF_PACKET sockets, in a
manner akin to how we monitor real network traffic via ptype_all.
From Daniel Borkmann.
13) Several bug fixes and improvements for the new alx device driver,
from Johannes Berg.
14) Fix scalability issues in the netem packet scheduler's time queue,
by using an rbtree. From Eric Dumazet.
15) Several bug fixes in TCP loss recovery handling, from Yuchung
Cheng.
16) Add support for GSO segmentation of MPLS packets, from Simon
Horman.
17) Make network notifiers have a real data type for the opaque
pointer that's passed into them. Use this to properly handle
network device flag changes in arp_netdev_event(). From Jiri
Pirko and Timo Teräs.
18) Convert several drivers over to module_pci_driver(), from Peter
Huewe.
19) tcp_fixup_rcvbuf() can loop 500 times over loopback, just use a
O(1) calculation instead. From Eric Dumazet.
20) Support setting of explicit tunnel peer addresses in ipv6, just
like ipv4. From Nicolas Dichtel.
21) Protect x86 BPF JIT against spraying attacks, from Eric Dumazet.
22) Prevent a single high rate flow from overruning an individual cpu
during RX packet processing via selective flow shedding. From
Willem de Bruijn.
23) Don't use spinlocks in TCP md5 signing fast paths, from Eric
Dumazet.
24) Don't just drop GSO packets which are above the TBF scheduler's
burst limit, chop them up so they are in-bounds instead. Also
from Eric Dumazet.
25) VLAN offloads are missed when configured on top of a bridge, fix
from Vlad Yasevich.
26) Support IPV6 in ping sockets. From Lorenzo Colitti.
27) Receive flow steering targets should be updated at poll() time
too, from David Majnemer.
28) Fix several corner case regressions in PMTU/redirect handling due
to the routing cache removal, from Timo Teräs.
29) We have to be mindful of ipv4 mapped ipv6 sockets in
upd_v6_push_pending_frames(). From Hannes Frederic Sowa.
30) Fix L2TP sequence number handling bugs, from James Chapman."
* git://git.kernel.org/pub/scm/linux/kernel/git/davem/net-next: (1214 commits)
drivers/net: caif: fix wrong rtnl_is_locked() usage
drivers/net: enic: release rtnl_lock on error-path
vhost-net: fix use-after-free in vhost_net_flush
net: mv643xx_eth: do not use port number as platform device id
net: sctp: confirm route during forward progress
virtio_net: fix race in RX VQ processing
virtio: support unlocked queue poll
net/cadence/macb: fix bug/typo in extracting gem_irq_read_clear bit
Documentation: Fix references to defunct linux-net@vger.kernel.org
net/fs: change busy poll time accounting
net: rename low latency sockets functions to busy poll
bridge: fix some kernel warning in multicast timer
sfc: Fix memory leak when discarding scattered packets
sit: fix tunnel update via netlink
dt:net:stmmac: Add dt specific phy reset callback support.
dt:net:stmmac: Add support to dwmac version 3.610 and 3.710
dt:net:stmmac: Allocate platform data only if its NULL.
net:stmmac: fix memleak in the open method
ipv6: rt6_check_neigh should successfully verify neigh if no NUD information are available
net: ipv6: fix wrong ping_v6_sendmsg return value
...
340 lines
11 KiB
Plaintext
340 lines
11 KiB
Plaintext
This file documents how to use memory mapped I/O with netlink.
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Author: Patrick McHardy <kaber@trash.net>
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Overview
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--------
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Memory mapped netlink I/O can be used to increase throughput and decrease
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overhead of unicast receive and transmit operations. Some netlink subsystems
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require high throughput, these are mainly the netfilter subsystems
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nfnetlink_queue and nfnetlink_log, but it can also help speed up large
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dump operations of f.i. the routing database.
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Memory mapped netlink I/O used two circular ring buffers for RX and TX which
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are mapped into the processes address space.
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The RX ring is used by the kernel to directly construct netlink messages into
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user-space memory without copying them as done with regular socket I/O,
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additionally as long as the ring contains messages no recvmsg() or poll()
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syscalls have to be issued by user-space to get more message.
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The TX ring is used to process messages directly from user-space memory, the
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kernel processes all messages contained in the ring using a single sendmsg()
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call.
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Usage overview
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--------------
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In order to use memory mapped netlink I/O, user-space needs three main changes:
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- ring setup
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- conversion of the RX path to get messages from the ring instead of recvmsg()
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- conversion of the TX path to construct messages into the ring
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Ring setup is done using setsockopt() to provide the ring parameters to the
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kernel, then a call to mmap() to map the ring into the processes address space:
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- setsockopt(fd, SOL_NETLINK, NETLINK_RX_RING, ¶ms, sizeof(params));
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- setsockopt(fd, SOL_NETLINK, NETLINK_TX_RING, ¶ms, sizeof(params));
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- ring = mmap(NULL, size, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0)
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Usage of either ring is optional, but even if only the RX ring is used the
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mapping still needs to be writable in order to update the frame status after
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processing.
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Conversion of the reception path involves calling poll() on the file
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descriptor, once the socket is readable the frames from the ring are
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processsed in order until no more messages are available, as indicated by
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a status word in the frame header.
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On kernel side, in order to make use of memory mapped I/O on receive, the
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originating netlink subsystem needs to support memory mapped I/O, otherwise
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it will use an allocated socket buffer as usual and the contents will be
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copied to the ring on transmission, nullifying most of the performance gains.
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Dumps of kernel databases automatically support memory mapped I/O.
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Conversion of the transmit path involves changing message construction to
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use memory from the TX ring instead of (usually) a buffer declared on the
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stack and setting up the frame header approriately. Optionally poll() can
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be used to wait for free frames in the TX ring.
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Structured and definitions for using memory mapped I/O are contained in
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<linux/netlink.h>.
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RX and TX rings
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----------------
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Each ring contains a number of continuous memory blocks, containing frames of
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fixed size dependent on the parameters used for ring setup.
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Ring: [ block 0 ]
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[ frame 0 ]
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[ frame 1 ]
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[ block 1 ]
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[ frame 2 ]
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[ frame 3 ]
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...
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[ block n ]
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[ frame 2 * n ]
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[ frame 2 * n + 1 ]
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The blocks are only visible to the kernel, from the point of view of user-space
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the ring just contains the frames in a continuous memory zone.
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The ring parameters used for setting up the ring are defined as follows:
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struct nl_mmap_req {
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unsigned int nm_block_size;
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unsigned int nm_block_nr;
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unsigned int nm_frame_size;
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unsigned int nm_frame_nr;
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};
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Frames are grouped into blocks, where each block is a continuous region of memory
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and holds nm_block_size / nm_frame_size frames. The total number of frames in
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the ring is nm_frame_nr. The following invariants hold:
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- frames_per_block = nm_block_size / nm_frame_size
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- nm_frame_nr = frames_per_block * nm_block_nr
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Some parameters are constrained, specifically:
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- nm_block_size must be a multiple of the architectures memory page size.
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The getpagesize() function can be used to get the page size.
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- nm_frame_size must be equal or larger to NL_MMAP_HDRLEN, IOW a frame must be
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able to hold at least the frame header
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- nm_frame_size must be smaller or equal to nm_block_size
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- nm_frame_size must be a multiple of NL_MMAP_MSG_ALIGNMENT
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- nm_frame_nr must equal the actual number of frames as specified above.
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When the kernel can't allocate physically continuous memory for a ring block,
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it will fall back to use physically discontinuous memory. This might affect
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performance negatively, in order to avoid this the nm_frame_size parameter
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should be chosen to be as small as possible for the required frame size and
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the number of blocks should be increased instead.
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Ring frames
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------------
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Each frames contain a frame header, consisting of a synchronization word and some
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meta-data, and the message itself.
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Frame: [ header message ]
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The frame header is defined as follows:
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struct nl_mmap_hdr {
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unsigned int nm_status;
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unsigned int nm_len;
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__u32 nm_group;
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/* credentials */
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__u32 nm_pid;
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__u32 nm_uid;
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__u32 nm_gid;
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};
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- nm_status is used for synchronizing processing between the kernel and user-
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space and specifies ownership of the frame as well as the operation to perform
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- nm_len contains the length of the message contained in the data area
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- nm_group specified the destination multicast group of message
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- nm_pid, nm_uid and nm_gid contain the netlink pid, UID and GID of the sending
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process. These values correspond to the data available using SOCK_PASSCRED in
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the SCM_CREDENTIALS cmsg.
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The possible values in the status word are:
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- NL_MMAP_STATUS_UNUSED:
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RX ring: frame belongs to the kernel and contains no message
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for user-space. Approriate action is to invoke poll()
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to wait for new messages.
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TX ring: frame belongs to user-space and can be used for
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message construction.
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- NL_MMAP_STATUS_RESERVED:
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RX ring only: frame is currently used by the kernel for message
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construction and contains no valid message yet.
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Appropriate action is to invoke poll() to wait for
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new messages.
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- NL_MMAP_STATUS_VALID:
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RX ring: frame contains a valid message. Approriate action is
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to process the message and release the frame back to
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the kernel by setting the status to
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NL_MMAP_STATUS_UNUSED or queue the frame by setting the
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status to NL_MMAP_STATUS_SKIP.
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TX ring: the frame contains a valid message from user-space to
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be processed by the kernel. After completing processing
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the kernel will release the frame back to user-space by
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setting the status to NL_MMAP_STATUS_UNUSED.
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- NL_MMAP_STATUS_COPY:
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RX ring only: a message is ready to be processed but could not be
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stored in the ring, either because it exceeded the
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frame size or because the originating subsystem does
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not support memory mapped I/O. Appropriate action is
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to invoke recvmsg() to receive the message and release
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the frame back to the kernel by setting the status to
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NL_MMAP_STATUS_UNUSED.
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- NL_MMAP_STATUS_SKIP:
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RX ring only: user-space queued the message for later processing, but
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processed some messages following it in the ring. The
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kernel should skip this frame when looking for unused
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frames.
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The data area of a frame begins at a offset of NL_MMAP_HDRLEN relative to the
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frame header.
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TX limitations
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--------------
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Kernel processing usually involves validation of the message received by
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user-space, then processing its contents. The kernel must assure that
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userspace is not able to modify the message contents after they have been
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validated. In order to do so, the message is copied from the ring frame
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to an allocated buffer if either of these conditions is false:
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- only a single mapping of the ring exists
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- the file descriptor is not shared between processes
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This means that for threaded programs, the kernel will fall back to copying.
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Example
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-------
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Ring setup:
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unsigned int block_size = 16 * getpagesize();
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struct nl_mmap_req req = {
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.nm_block_size = block_size,
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.nm_block_nr = 64,
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.nm_frame_size = 16384,
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.nm_frame_nr = 64 * block_size / 16384,
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};
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unsigned int ring_size;
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void *rx_ring, *tx_ring;
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/* Configure ring parameters */
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if (setsockopt(fd, NETLINK_RX_RING, &req, sizeof(req)) < 0)
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exit(1);
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if (setsockopt(fd, NETLINK_TX_RING, &req, sizeof(req)) < 0)
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exit(1)
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/* Calculate size of each invididual ring */
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ring_size = req.nm_block_nr * req.nm_block_size;
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/* Map RX/TX rings. The TX ring is located after the RX ring */
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rx_ring = mmap(NULL, 2 * ring_size, PROT_READ | PROT_WRITE,
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MAP_SHARED, fd, 0);
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if ((long)rx_ring == -1L)
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exit(1);
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tx_ring = rx_ring + ring_size:
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Message reception:
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This example assumes some ring parameters of the ring setup are available.
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unsigned int frame_offset = 0;
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struct nl_mmap_hdr *hdr;
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struct nlmsghdr *nlh;
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unsigned char buf[16384];
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ssize_t len;
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while (1) {
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struct pollfd pfds[1];
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pfds[0].fd = fd;
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pfds[0].events = POLLIN | POLLERR;
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pfds[0].revents = 0;
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if (poll(pfds, 1, -1) < 0 && errno != -EINTR)
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exit(1);
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/* Check for errors. Error handling omitted */
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if (pfds[0].revents & POLLERR)
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<handle error>
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/* If no new messages, poll again */
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if (!(pfds[0].revents & POLLIN))
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continue;
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/* Process all frames */
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while (1) {
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/* Get next frame header */
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hdr = rx_ring + frame_offset;
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if (hdr->nm_status == NL_MMAP_STATUS_VALID) {
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/* Regular memory mapped frame */
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nlh = (void *)hdr + NL_MMAP_HDRLEN;
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len = hdr->nm_len;
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/* Release empty message immediately. May happen
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* on error during message construction.
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*/
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if (len == 0)
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goto release;
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} else if (hdr->nm_status == NL_MMAP_STATUS_COPY) {
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/* Frame queued to socket receive queue */
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len = recv(fd, buf, sizeof(buf), MSG_DONTWAIT);
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if (len <= 0)
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break;
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nlh = buf;
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} else
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/* No more messages to process, continue polling */
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break;
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process_msg(nlh);
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release:
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/* Release frame back to the kernel */
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hdr->nm_status = NL_MMAP_STATUS_UNUSED;
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/* Advance frame offset to next frame */
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frame_offset = (frame_offset + frame_size) % ring_size;
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}
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}
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Message transmission:
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This example assumes some ring parameters of the ring setup are available.
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A single message is constructed and transmitted, to send multiple messages
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at once they would be constructed in consecutive frames before a final call
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to sendto().
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unsigned int frame_offset = 0;
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struct nl_mmap_hdr *hdr;
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struct nlmsghdr *nlh;
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struct sockaddr_nl addr = {
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.nl_family = AF_NETLINK,
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};
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hdr = tx_ring + frame_offset;
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if (hdr->nm_status != NL_MMAP_STATUS_UNUSED)
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/* No frame available. Use poll() to avoid. */
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exit(1);
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nlh = (void *)hdr + NL_MMAP_HDRLEN;
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/* Build message */
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build_message(nlh);
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/* Fill frame header: length and status need to be set */
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hdr->nm_len = nlh->nlmsg_len;
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hdr->nm_status = NL_MMAP_STATUS_VALID;
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if (sendto(fd, NULL, 0, 0, &addr, sizeof(addr)) < 0)
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exit(1);
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/* Advance frame offset to next frame */
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frame_offset = (frame_offset + frame_size) % ring_size;
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