net.rst 20 KB

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  1. ================================
  2. Documentation for /proc/sys/net/
  3. ================================
  4. Copyright
  5. Copyright (c) 1999
  6. - Terrehon Bowden <terrehon@pacbell.net>
  7. - Bodo Bauer <bb@ricochet.net>
  8. Copyright (c) 2000
  9. - Jorge Nerin <comandante@zaralinux.com>
  10. Copyright (c) 2009
  11. - Shen Feng <shen@cn.fujitsu.com>
  12. For general info and legal blurb, please look in index.rst.
  13. ------------------------------------------------------------------------------
  14. This file contains the documentation for the sysctl files in
  15. /proc/sys/net
  16. The interface to the networking parts of the kernel is located in
  17. /proc/sys/net. The following table shows all possible subdirectories. You may
  18. see only some of them, depending on your kernel's configuration.
  19. Table : Subdirectories in /proc/sys/net
  20. ========= =================== = ========== ===================
  21. Directory Content Directory Content
  22. ========= =================== = ========== ===================
  23. 802 E802 protocol mptcp Multipath TCP
  24. appletalk Appletalk protocol netfilter Network Filter
  25. ax25 AX25 netrom NET/ROM
  26. bridge Bridging rose X.25 PLP layer
  27. core General parameter tipc TIPC
  28. ethernet Ethernet protocol unix Unix domain sockets
  29. ipv4 IP version 4 vsock VSOCK sockets
  30. ipv6 IP version 6 x25 X.25 protocol
  31. ========= =================== = ========== ===================
  32. 1. /proc/sys/net/core - Network core options
  33. ============================================
  34. bpf_jit_enable
  35. --------------
  36. This enables the BPF Just in Time (JIT) compiler. BPF is a flexible
  37. and efficient infrastructure allowing to execute bytecode at various
  38. hook points. It is used in a number of Linux kernel subsystems such
  39. as networking (e.g. XDP, tc), tracing (e.g. kprobes, uprobes, tracepoints)
  40. and security (e.g. seccomp). LLVM has a BPF back end that can compile
  41. restricted C into a sequence of BPF instructions. After program load
  42. through bpf(2) and passing a verifier in the kernel, a JIT will then
  43. translate these BPF proglets into native CPU instructions. There are
  44. two flavors of JITs, the newer eBPF JIT currently supported on:
  45. - x86_64
  46. - x86_32
  47. - arm64
  48. - arm32
  49. - ppc64
  50. - ppc32
  51. - sparc64
  52. - mips64
  53. - s390x
  54. - riscv64
  55. - riscv32
  56. - loongarch64
  57. - arc
  58. And the older cBPF JIT supported on the following archs:
  59. - mips
  60. - sparc
  61. eBPF JITs are a superset of cBPF JITs, meaning the kernel will
  62. migrate cBPF instructions into eBPF instructions and then JIT
  63. compile them transparently. Older cBPF JITs can only translate
  64. tcpdump filters, seccomp rules, etc, but not mentioned eBPF
  65. programs loaded through bpf(2).
  66. Values:
  67. - 0 - disable the JIT (default value)
  68. - 1 - enable the JIT
  69. - 2 - enable the JIT and ask the compiler to emit traces on kernel log.
  70. bpf_jit_harden
  71. --------------
  72. This enables hardening for the BPF JIT compiler. Supported are eBPF
  73. JIT backends. Enabling hardening trades off performance, but can
  74. mitigate JIT spraying.
  75. Values:
  76. - 0 - disable JIT hardening (default value)
  77. - 1 - enable JIT hardening for unprivileged users only
  78. - 2 - enable JIT hardening for all users
  79. where "privileged user" in this context means a process having
  80. CAP_BPF or CAP_SYS_ADMIN in the root user name space.
  81. bpf_jit_kallsyms
  82. ----------------
  83. When BPF JIT compiler is enabled, then compiled images are unknown
  84. addresses to the kernel, meaning they neither show up in traces nor
  85. in /proc/kallsyms. This enables export of these addresses, which can
  86. be used for debugging/tracing. If bpf_jit_harden is enabled, this
  87. feature is disabled.
  88. Values :
  89. - 0 - disable JIT kallsyms export (default value)
  90. - 1 - enable JIT kallsyms export for privileged users only
  91. bpf_jit_limit
  92. -------------
  93. This enforces a global limit for memory allocations to the BPF JIT
  94. compiler in order to reject unprivileged JIT requests once it has
  95. been surpassed. bpf_jit_limit contains the value of the global limit
  96. in bytes.
  97. dev_weight
  98. ----------
  99. The maximum number of packets that kernel can handle on a NAPI interrupt,
  100. it's a Per-CPU variable. For drivers that support LRO or GRO_HW, a hardware
  101. aggregated packet is counted as one packet in this context.
  102. Default: 64
  103. dev_weight_rx_bias
  104. ------------------
  105. RPS (e.g. RFS, aRFS) processing is competing with the registered NAPI poll function
  106. of the driver for the per softirq cycle netdev_budget. This parameter influences
  107. the proportion of the configured netdev_budget that is spent on RPS based packet
  108. processing during RX softirq cycles. It is further meant for making current
  109. dev_weight adaptable for asymmetric CPU needs on RX/TX side of the network stack.
  110. (see dev_weight_tx_bias) It is effective on a per CPU basis. Determination is based
  111. on dev_weight and is calculated multiplicative (dev_weight * dev_weight_rx_bias).
  112. Default: 1
  113. dev_weight_tx_bias
  114. ------------------
  115. Scales the maximum number of packets that can be processed during a TX softirq cycle.
  116. Effective on a per CPU basis. Allows scaling of current dev_weight for asymmetric
  117. net stack processing needs. Be careful to avoid making TX softirq processing a CPU hog.
  118. Calculation is based on dev_weight (dev_weight * dev_weight_tx_bias).
  119. Default: 1
  120. default_qdisc
  121. -------------
  122. The default queuing discipline to use for network devices. This allows
  123. overriding the default of pfifo_fast with an alternative. Since the default
  124. queuing discipline is created without additional parameters so is best suited
  125. to queuing disciplines that work well without configuration like stochastic
  126. fair queue (sfq), CoDel (codel) or fair queue CoDel (fq_codel). Don't use
  127. queuing disciplines like Hierarchical Token Bucket or Deficit Round Robin
  128. which require setting up classes and bandwidths. Note that physical multiqueue
  129. interfaces still use mq as root qdisc, which in turn uses this default for its
  130. leaves. Virtual devices (like e.g. lo or veth) ignore this setting and instead
  131. default to noqueue.
  132. Default: pfifo_fast
  133. busy_read
  134. ---------
  135. Low latency busy poll timeout for socket reads. (needs CONFIG_NET_RX_BUSY_POLL)
  136. Approximate time in us to busy loop waiting for packets on the device queue.
  137. This sets the default value of the SO_BUSY_POLL socket option.
  138. Can be set or overridden per socket by setting socket option SO_BUSY_POLL,
  139. which is the preferred method of enabling. If you need to enable the feature
  140. globally via sysctl, a value of 50 is recommended.
  141. Will increase power usage.
  142. Default: 0 (off)
  143. busy_poll
  144. ----------------
  145. Low latency busy poll timeout for poll and select. (needs CONFIG_NET_RX_BUSY_POLL)
  146. Approximate time in us to busy loop waiting for events.
  147. Recommended value depends on the number of sockets you poll on.
  148. For several sockets 50, for several hundreds 100.
  149. For more than that you probably want to use epoll.
  150. Note that only sockets with SO_BUSY_POLL set will be busy polled,
  151. so you want to either selectively set SO_BUSY_POLL on those sockets or set
  152. sysctl.net.busy_read globally.
  153. Will increase power usage.
  154. Default: 0 (off)
  155. mem_pcpu_rsv
  156. ------------
  157. Per-cpu reserved forward alloc cache size in page units. Default 1MB per CPU.
  158. bypass_prot_mem
  159. ---------------
  160. Skip charging socket buffers to the global per-protocol memory
  161. accounting controlled by net.ipv4.tcp_mem, net.ipv4.udp_mem, etc.
  162. Default: 0 (off)
  163. rmem_default
  164. ------------
  165. The default setting of the socket receive buffer in bytes.
  166. rmem_max
  167. --------
  168. The maximum receive socket buffer size in bytes.
  169. Default: 4194304
  170. rps_default_mask
  171. ----------------
  172. The default RPS CPU mask used on newly created network devices. An empty
  173. mask means RPS disabled by default.
  174. tstamp_allow_data
  175. -----------------
  176. Allow processes to receive tx timestamps looped together with the original
  177. packet contents. If disabled, transmit timestamp requests from unprivileged
  178. processes are dropped unless socket option SOF_TIMESTAMPING_OPT_TSONLY is set.
  179. Default: 1 (on)
  180. wmem_default
  181. ------------
  182. The default setting (in bytes) of the socket send buffer.
  183. wmem_max
  184. --------
  185. The maximum send socket buffer size in bytes.
  186. Default: 4194304
  187. message_burst and message_cost
  188. ------------------------------
  189. These parameters are used to limit the warning messages written to the kernel
  190. log from the networking code. They enforce a rate limit to make a
  191. denial-of-service attack impossible. A higher message_cost factor, results in
  192. fewer messages that will be written. Message_burst controls when messages will
  193. be dropped. The default settings limit warning messages to one every five
  194. seconds.
  195. warnings
  196. --------
  197. This sysctl is now unused.
  198. This was used to control console messages from the networking stack that
  199. occur because of problems on the network like duplicate address or bad
  200. checksums.
  201. These messages are now emitted at KERN_DEBUG and can generally be enabled
  202. and controlled by the dynamic_debug facility.
  203. netdev_budget
  204. -------------
  205. Maximum number of packets taken from all interfaces in one polling cycle (NAPI
  206. poll). In one polling cycle interfaces which are registered to polling are
  207. probed in a round-robin manner. Also, a polling cycle may not exceed
  208. netdev_budget_usecs microseconds, even if netdev_budget has not been
  209. exhausted.
  210. netdev_budget_usecs
  211. ---------------------
  212. Maximum number of microseconds in one NAPI polling cycle. Polling
  213. will exit when either netdev_budget_usecs have elapsed during the
  214. poll cycle or the number of packets processed reaches netdev_budget.
  215. netdev_max_backlog
  216. ------------------
  217. Maximum number of packets, queued on the INPUT side, when the interface
  218. receives packets faster than kernel can process them.
  219. qdisc_max_burst
  220. ------------------
  221. Maximum number of packets that can be temporarily stored before
  222. reaching qdisc.
  223. Default: 1000
  224. netdev_rss_key
  225. --------------
  226. RSS (Receive Side Scaling) enabled drivers use a host key that
  227. is randomly generated.
  228. Some user space might need to gather its content even if drivers do not
  229. provide ethtool -x support yet.
  230. ::
  231. myhost:~# cat /proc/sys/net/core/netdev_rss_key
  232. 84:50:f4:00:a8:15:d1:a7:e9:7f:1d:60:35:c7:47:25:42:97:74:ca:56:bb:b6:a1:d8: ... (256 bytes total)
  233. File contains all nul bytes if no driver ever called netdev_rss_key_fill()
  234. function.
  235. Note:
  236. /proc/sys/net/core/netdev_rss_key contains 256 bytes of key,
  237. but many drivers only use 40 or 52 bytes of it.
  238. ::
  239. myhost:~# ethtool -x eth0
  240. RX flow hash indirection table for eth0 with 8 RX ring(s):
  241. 0: 0 1 2 3 4 5 6 7
  242. RSS hash key:
  243. 84:50:f4:00:a8:15:d1:a7:e9:7f:1d:60:35:c7:47:25:42:97:74:ca:56:bb:b6:a1:d8:43:e3:c9:0c:fd:17:55:c2:3a:4d:69:ed:f1:42:89
  244. netdev_tstamp_prequeue
  245. ----------------------
  246. If set to 0, RX packet timestamps can be sampled after RPS processing, when
  247. the target CPU processes packets. It might give some delay on timestamps, but
  248. permit to distribute the load on several cpus.
  249. If set to 1 (default), timestamps are sampled as soon as possible, before
  250. queueing.
  251. netdev_unregister_timeout_secs
  252. ------------------------------
  253. Unregister network device timeout in seconds.
  254. This option controls the timeout (in seconds) used to issue a warning while
  255. waiting for a network device refcount to drop to 0 during device
  256. unregistration. A lower value may be useful during bisection to detect
  257. a leaked reference faster. A larger value may be useful to prevent false
  258. warnings on slow/loaded systems.
  259. Default value is 10, minimum 1, maximum 3600.
  260. skb_defer_max
  261. -------------
  262. Max size (in skbs) of the per-cpu list of skbs being freed
  263. by the cpu which allocated them.
  264. Default: 128
  265. optmem_max
  266. ----------
  267. Maximum ancillary buffer size allowed per socket. Ancillary data is a sequence
  268. of struct cmsghdr structures with appended data. TCP tx zerocopy also uses
  269. optmem_max as a limit for its internal structures.
  270. Default : 128 KB
  271. fb_tunnels_only_for_init_net
  272. ----------------------------
  273. Controls if fallback tunnels (like tunl0, gre0, gretap0, erspan0,
  274. sit0, ip6tnl0, ip6gre0) are automatically created. There are 3 possibilities
  275. (a) value = 0; respective fallback tunnels are created when module is
  276. loaded in every net namespaces (backward compatible behavior).
  277. (b) value = 1; [kcmd value: initns] respective fallback tunnels are
  278. created only in init net namespace and every other net namespace will
  279. not have them.
  280. (c) value = 2; [kcmd value: none] fallback tunnels are not created
  281. when a module is loaded in any of the net namespace. Setting value to
  282. "2" is pointless after boot if these modules are built-in, so there is
  283. a kernel command-line option that can change this default. Please refer to
  284. Documentation/admin-guide/kernel-parameters.txt for additional details.
  285. Not creating fallback tunnels gives control to userspace to create
  286. whatever is needed only and avoid creating devices which are redundant.
  287. Default : 0 (for compatibility reasons)
  288. devconf_inherit_init_net
  289. ------------------------
  290. Controls if a new network namespace should inherit all current
  291. settings under /proc/sys/net/{ipv4,ipv6}/conf/{all,default}/. By
  292. default, we keep the current behavior: for IPv4 we inherit all current
  293. settings from init_net and for IPv6 we reset all settings to default.
  294. If set to 1, both IPv4 and IPv6 settings are forced to inherit from
  295. current ones in init_net. If set to 2, both IPv4 and IPv6 settings are
  296. forced to reset to their default values. If set to 3, both IPv4 and IPv6
  297. settings are forced to inherit from current ones in the netns where this
  298. new netns has been created.
  299. Default : 0 (for compatibility reasons)
  300. txrehash
  301. --------
  302. Controls default hash rethink behaviour on socket when SO_TXREHASH option is set
  303. to SOCK_TXREHASH_DEFAULT (i. e. not overridden by setsockopt).
  304. If set to 1 (default), hash rethink is performed on listening socket.
  305. If set to 0, hash rethink is not performed.
  306. txq_reselection_ms
  307. ------------------
  308. Controls how often (in ms) a busy connected flow can select another tx queue.
  309. A resection is desirable when/if user thread has migrated and XPS
  310. would select a different queue. Same can occur without XPS
  311. if the flow hash has changed.
  312. But switching txq can introduce reorders, especially if the
  313. old queue is under high pressure. Modern TCP stacks deal
  314. well with reorders if they happen not too often.
  315. To disable this feature, set the value to 0.
  316. Default : 1000
  317. gro_normal_batch
  318. ----------------
  319. Maximum number of the segments to batch up on output of GRO. When a packet
  320. exits GRO, either as a coalesced superframe or as an original packet which
  321. GRO has decided not to coalesce, it is placed on a per-NAPI list. This
  322. list is then passed to the stack when the number of segments reaches the
  323. gro_normal_batch limit.
  324. high_order_alloc_disable
  325. ------------------------
  326. By default the allocator for page frags tries to use high order pages (order-3
  327. on x86). While the default behavior gives good results in most cases, some users
  328. might have hit a contention in page allocations/freeing. This was especially
  329. true on older kernels (< 5.14) when high-order pages were not stored on per-cpu
  330. lists. This allows to opt-in for order-0 allocation instead but is now mostly of
  331. historical importance.
  332. Default: 0
  333. 2. /proc/sys/net/unix - Parameters for Unix domain sockets
  334. ----------------------------------------------------------
  335. There is only one file in this directory.
  336. unix_dgram_qlen limits the max number of datagrams queued in Unix domain
  337. socket's buffer. It will not take effect unless PF_UNIX flag is specified.
  338. 3. /proc/sys/net/ipv4 - IPV4 settings
  339. -------------------------------------
  340. Please see: Documentation/networking/ip-sysctl.rst and
  341. Documentation/admin-guide/sysctl/net.rst for descriptions of these entries.
  342. 4. Appletalk
  343. ------------
  344. The /proc/sys/net/appletalk directory holds the Appletalk configuration data
  345. when Appletalk is loaded. The configurable parameters are:
  346. aarp-expiry-time
  347. ----------------
  348. The amount of time we keep an ARP entry before expiring it. Used to age out
  349. old hosts.
  350. aarp-resolve-time
  351. -----------------
  352. The amount of time we will spend trying to resolve an Appletalk address.
  353. aarp-retransmit-limit
  354. ---------------------
  355. The number of times we will retransmit a query before giving up.
  356. aarp-tick-time
  357. --------------
  358. Controls the rate at which expires are checked.
  359. The directory /proc/net/appletalk holds the list of active Appletalk sockets
  360. on a machine.
  361. The fields indicate the DDP type, the local address (in network:node format)
  362. the remote address, the size of the transmit pending queue, the size of the
  363. received queue (bytes waiting for applications to read) the state and the uid
  364. owning the socket.
  365. /proc/net/atalk_iface lists all the interfaces configured for appletalk.It
  366. shows the name of the interface, its Appletalk address, the network range on
  367. that address (or network number for phase 1 networks), and the status of the
  368. interface.
  369. /proc/net/atalk_route lists each known network route. It lists the target
  370. (network) that the route leads to, the router (may be directly connected), the
  371. route flags, and the device the route is using.
  372. 5. TIPC
  373. -------
  374. tipc_rmem
  375. ---------
  376. The TIPC protocol now has a tunable for the receive memory, similar to the
  377. tcp_rmem - i.e. a vector of 3 INTEGERs: (min, default, max)
  378. ::
  379. # cat /proc/sys/net/tipc/tipc_rmem
  380. 4252725 34021800 68043600
  381. #
  382. The max value is set to CONN_OVERLOAD_LIMIT, and the default and min values
  383. are scaled (shifted) versions of that same value. Note that the min value
  384. is not at this point in time used in any meaningful way, but the triplet is
  385. preserved in order to be consistent with things like tcp_rmem.
  386. named_timeout
  387. -------------
  388. TIPC name table updates are distributed asynchronously in a cluster, without
  389. any form of transaction handling. This means that different race scenarios are
  390. possible. One such is that a name withdrawal sent out by one node and received
  391. by another node may arrive after a second, overlapping name publication already
  392. has been accepted from a third node, although the conflicting updates
  393. originally may have been issued in the correct sequential order.
  394. If named_timeout is nonzero, failed topology updates will be placed on a defer
  395. queue until another event arrives that clears the error, or until the timeout
  396. expires. Value is in milliseconds.
  397. 6. /proc/sys/net/vsock - VSOCK sockets
  398. --------------------------------------
  399. VSOCK sockets (AF_VSOCK) provide communication between virtual machines and
  400. their hosts. The behavior of VSOCK sockets in a network namespace is determined
  401. by the namespace's mode (``global`` or ``local``), which controls how CIDs
  402. (Context IDs) are allocated and how sockets interact across namespaces.
  403. ns_mode
  404. -------
  405. Read-only. Reports the current namespace's mode, set at namespace creation
  406. and immutable thereafter.
  407. Values:
  408. - ``global`` - the namespace shares system-wide CID allocation and
  409. its sockets can reach any VM or socket in any global namespace.
  410. Sockets in this namespace cannot reach sockets in local
  411. namespaces.
  412. - ``local`` - the namespace has private CID allocation and its
  413. sockets can only connect to VMs or sockets within the same
  414. namespace.
  415. The init_net mode is always ``global``.
  416. child_ns_mode
  417. -------------
  418. Controls what mode newly created child namespaces will inherit. At namespace
  419. creation, ``ns_mode`` is inherited from the parent's ``child_ns_mode``. The
  420. initial value matches the namespace's own ``ns_mode``.
  421. Values:
  422. - ``global`` - child namespaces will share system-wide CID allocation
  423. and their sockets will be able to reach any VM or socket in any
  424. global namespace.
  425. - ``local`` - child namespaces will have private CID allocation and
  426. their sockets will only be able to connect within their own
  427. namespace.
  428. The first write to ``child_ns_mode`` locks its value. Subsequent writes of the
  429. same value succeed, but writing a different value returns ``-EBUSY``.
  430. Changing ``child_ns_mode`` only affects namespaces created after the change;
  431. it does not modify the current namespace or any existing children.
  432. A namespace with ``ns_mode`` set to ``local`` cannot change
  433. ``child_ns_mode`` to ``global`` (returns ``-EPERM``).