1 ================================ 1 ================================
2 Documentation for /proc/sys/net/ 2 Documentation for /proc/sys/net/
3 ================================ 3 ================================
4 4
5 Copyright 5 Copyright
6 6
7 Copyright (c) 1999 7 Copyright (c) 1999
8 8
9 - Terrehon Bowden <terrehon@pacbell.net 9 - Terrehon Bowden <terrehon@pacbell.net>
10 - Bodo Bauer <bb@ricochet.net> 10 - Bodo Bauer <bb@ricochet.net>
11 11
12 Copyright (c) 2000 12 Copyright (c) 2000
13 13
14 - Jorge Nerin <comandante@zaralinux.com 14 - Jorge Nerin <comandante@zaralinux.com>
15 15
16 Copyright (c) 2009 16 Copyright (c) 2009
17 17
18 - Shen Feng <shen@cn.fujitsu.com> 18 - Shen Feng <shen@cn.fujitsu.com>
19 19
20 For general info and legal blurb, please look 20 For general info and legal blurb, please look in index.rst.
21 21
22 ---------------------------------------------- 22 ------------------------------------------------------------------------------
23 23
24 This file contains the documentation for the s 24 This file contains the documentation for the sysctl files in
25 /proc/sys/net 25 /proc/sys/net
26 26
27 The interface to the networking parts of 27 The interface to the networking parts of the kernel is located in
28 /proc/sys/net. The following table shows all p 28 /proc/sys/net. The following table shows all possible subdirectories. You may
29 see only some of them, depending on your kerne 29 see only some of them, depending on your kernel's configuration.
30 30
31 31
32 Table : Subdirectories in /proc/sys/net 32 Table : Subdirectories in /proc/sys/net
33 33
34 ========= =================== = ========== == 34 ========= =================== = ========== ===================
35 Directory Content Directory Co 35 Directory Content Directory Content
36 ========= =================== = ========== == 36 ========= =================== = ========== ===================
37 802 E802 protocol mptcp Mu 37 802 E802 protocol mptcp Multipath TCP
38 appletalk Appletalk protocol netfilter Ne 38 appletalk Appletalk protocol netfilter Network Filter
39 ax25 AX25 netrom NE 39 ax25 AX25 netrom NET/ROM
40 bridge Bridging rose X. 40 bridge Bridging rose X.25 PLP layer
41 core General parameter tipc TI 41 core General parameter tipc TIPC
42 ethernet Ethernet protocol unix Un 42 ethernet Ethernet protocol unix Unix domain sockets
43 ipv4 IP version 4 x25 X. 43 ipv4 IP version 4 x25 X.25 protocol
44 ipv6 IP version 6 44 ipv6 IP version 6
45 ========= =================== = ========== == 45 ========= =================== = ========== ===================
46 46
47 1. /proc/sys/net/core - Network core options 47 1. /proc/sys/net/core - Network core options
48 ============================================ 48 ============================================
49 49
50 bpf_jit_enable 50 bpf_jit_enable
51 -------------- 51 --------------
52 52
53 This enables the BPF Just in Time (JIT) compil 53 This enables the BPF Just in Time (JIT) compiler. BPF is a flexible
54 and efficient infrastructure allowing to execu 54 and efficient infrastructure allowing to execute bytecode at various
55 hook points. It is used in a number of Linux k 55 hook points. It is used in a number of Linux kernel subsystems such
56 as networking (e.g. XDP, tc), tracing (e.g. kp 56 as networking (e.g. XDP, tc), tracing (e.g. kprobes, uprobes, tracepoints)
57 and security (e.g. seccomp). LLVM has a BPF ba 57 and security (e.g. seccomp). LLVM has a BPF back end that can compile
58 restricted C into a sequence of BPF instructio 58 restricted C into a sequence of BPF instructions. After program load
59 through bpf(2) and passing a verifier in the k 59 through bpf(2) and passing a verifier in the kernel, a JIT will then
60 translate these BPF proglets into native CPU i 60 translate these BPF proglets into native CPU instructions. There are
61 two flavors of JITs, the newer eBPF JIT curren 61 two flavors of JITs, the newer eBPF JIT currently supported on:
62 62
63 - x86_64 63 - x86_64
64 - x86_32 64 - x86_32
65 - arm64 65 - arm64
66 - arm32 66 - arm32
67 - ppc64 67 - ppc64
68 - ppc32 68 - ppc32
69 - sparc64 69 - sparc64
70 - mips64 70 - mips64
71 - s390x 71 - s390x
72 - riscv64 72 - riscv64
73 - riscv32 73 - riscv32
74 - loongarch64 <<
75 - arc <<
76 74
77 And the older cBPF JIT supported on the follow 75 And the older cBPF JIT supported on the following archs:
78 76
79 - mips 77 - mips
80 - sparc 78 - sparc
81 79
82 eBPF JITs are a superset of cBPF JITs, meaning 80 eBPF JITs are a superset of cBPF JITs, meaning the kernel will
83 migrate cBPF instructions into eBPF instructio 81 migrate cBPF instructions into eBPF instructions and then JIT
84 compile them transparently. Older cBPF JITs ca 82 compile them transparently. Older cBPF JITs can only translate
85 tcpdump filters, seccomp rules, etc, but not m 83 tcpdump filters, seccomp rules, etc, but not mentioned eBPF
86 programs loaded through bpf(2). 84 programs loaded through bpf(2).
87 85
88 Values: 86 Values:
89 87
90 - 0 - disable the JIT (default value) 88 - 0 - disable the JIT (default value)
91 - 1 - enable the JIT 89 - 1 - enable the JIT
92 - 2 - enable the JIT and ask the compi 90 - 2 - enable the JIT and ask the compiler to emit traces on kernel log.
93 91
94 bpf_jit_harden 92 bpf_jit_harden
95 -------------- 93 --------------
96 94
97 This enables hardening for the BPF JIT compile 95 This enables hardening for the BPF JIT compiler. Supported are eBPF
98 JIT backends. Enabling hardening trades off pe 96 JIT backends. Enabling hardening trades off performance, but can
99 mitigate JIT spraying. 97 mitigate JIT spraying.
100 98
101 Values: 99 Values:
102 100
103 - 0 - disable JIT hardening (default v 101 - 0 - disable JIT hardening (default value)
104 - 1 - enable JIT hardening for unprivi 102 - 1 - enable JIT hardening for unprivileged users only
105 - 2 - enable JIT hardening for all use 103 - 2 - enable JIT hardening for all users
106 104
107 where "privileged user" in this context means 105 where "privileged user" in this context means a process having
108 CAP_BPF or CAP_SYS_ADMIN in the root user name 106 CAP_BPF or CAP_SYS_ADMIN in the root user name space.
109 107
110 bpf_jit_kallsyms 108 bpf_jit_kallsyms
111 ---------------- 109 ----------------
112 110
113 When BPF JIT compiler is enabled, then compile 111 When BPF JIT compiler is enabled, then compiled images are unknown
114 addresses to the kernel, meaning they neither 112 addresses to the kernel, meaning they neither show up in traces nor
115 in /proc/kallsyms. This enables export of thes 113 in /proc/kallsyms. This enables export of these addresses, which can
116 be used for debugging/tracing. If bpf_jit_hard 114 be used for debugging/tracing. If bpf_jit_harden is enabled, this
117 feature is disabled. 115 feature is disabled.
118 116
119 Values : 117 Values :
120 118
121 - 0 - disable JIT kallsyms export (def 119 - 0 - disable JIT kallsyms export (default value)
122 - 1 - enable JIT kallsyms export for p 120 - 1 - enable JIT kallsyms export for privileged users only
123 121
124 bpf_jit_limit 122 bpf_jit_limit
125 ------------- 123 -------------
126 124
127 This enforces a global limit for memory alloca 125 This enforces a global limit for memory allocations to the BPF JIT
128 compiler in order to reject unprivileged JIT r 126 compiler in order to reject unprivileged JIT requests once it has
129 been surpassed. bpf_jit_limit contains the val 127 been surpassed. bpf_jit_limit contains the value of the global limit
130 in bytes. 128 in bytes.
131 129
132 dev_weight 130 dev_weight
133 ---------- 131 ----------
134 132
135 The maximum number of packets that kernel can 133 The maximum number of packets that kernel can handle on a NAPI interrupt,
136 it's a Per-CPU variable. For drivers that supp 134 it's a Per-CPU variable. For drivers that support LRO or GRO_HW, a hardware
137 aggregated packet is counted as one packet in 135 aggregated packet is counted as one packet in this context.
138 136
139 Default: 64 137 Default: 64
140 138
141 dev_weight_rx_bias 139 dev_weight_rx_bias
142 ------------------ 140 ------------------
143 141
144 RPS (e.g. RFS, aRFS) processing is competing w 142 RPS (e.g. RFS, aRFS) processing is competing with the registered NAPI poll function
145 of the driver for the per softirq cycle netdev 143 of the driver for the per softirq cycle netdev_budget. This parameter influences
146 the proportion of the configured netdev_budget 144 the proportion of the configured netdev_budget that is spent on RPS based packet
147 processing during RX softirq cycles. It is fur 145 processing during RX softirq cycles. It is further meant for making current
148 dev_weight adaptable for asymmetric CPU needs 146 dev_weight adaptable for asymmetric CPU needs on RX/TX side of the network stack.
149 (see dev_weight_tx_bias) It is effective on a 147 (see dev_weight_tx_bias) It is effective on a per CPU basis. Determination is based
150 on dev_weight and is calculated multiplicative 148 on dev_weight and is calculated multiplicative (dev_weight * dev_weight_rx_bias).
151 149
152 Default: 1 150 Default: 1
153 151
154 dev_weight_tx_bias 152 dev_weight_tx_bias
155 ------------------ 153 ------------------
156 154
157 Scales the maximum number of packets that can 155 Scales the maximum number of packets that can be processed during a TX softirq cycle.
158 Effective on a per CPU basis. Allows scaling o 156 Effective on a per CPU basis. Allows scaling of current dev_weight for asymmetric
159 net stack processing needs. Be careful to avoi 157 net stack processing needs. Be careful to avoid making TX softirq processing a CPU hog.
160 158
161 Calculation is based on dev_weight (dev_weight 159 Calculation is based on dev_weight (dev_weight * dev_weight_tx_bias).
162 160
163 Default: 1 161 Default: 1
164 162
165 default_qdisc 163 default_qdisc
166 ------------- 164 -------------
167 165
168 The default queuing discipline to use for netw 166 The default queuing discipline to use for network devices. This allows
169 overriding the default of pfifo_fast with an a 167 overriding the default of pfifo_fast with an alternative. Since the default
170 queuing discipline is created without addition 168 queuing discipline is created without additional parameters so is best suited
171 to queuing disciplines that work well without 169 to queuing disciplines that work well without configuration like stochastic
172 fair queue (sfq), CoDel (codel) or fair queue 170 fair queue (sfq), CoDel (codel) or fair queue CoDel (fq_codel). Don't use
173 queuing disciplines like Hierarchical Token Bu 171 queuing disciplines like Hierarchical Token Bucket or Deficit Round Robin
174 which require setting up classes and bandwidth 172 which require setting up classes and bandwidths. Note that physical multiqueue
175 interfaces still use mq as root qdisc, which i 173 interfaces still use mq as root qdisc, which in turn uses this default for its
176 leaves. Virtual devices (like e.g. lo or veth) 174 leaves. Virtual devices (like e.g. lo or veth) ignore this setting and instead
177 default to noqueue. 175 default to noqueue.
178 176
179 Default: pfifo_fast 177 Default: pfifo_fast
180 178
181 busy_read 179 busy_read
182 --------- 180 ---------
183 181
184 Low latency busy poll timeout for socket reads 182 Low latency busy poll timeout for socket reads. (needs CONFIG_NET_RX_BUSY_POLL)
185 Approximate time in us to busy loop waiting fo 183 Approximate time in us to busy loop waiting for packets on the device queue.
186 This sets the default value of the SO_BUSY_POL 184 This sets the default value of the SO_BUSY_POLL socket option.
187 Can be set or overridden per socket by setting 185 Can be set or overridden per socket by setting socket option SO_BUSY_POLL,
188 which is the preferred method of enabling. If 186 which is the preferred method of enabling. If you need to enable the feature
189 globally via sysctl, a value of 50 is recommen 187 globally via sysctl, a value of 50 is recommended.
190 188
191 Will increase power usage. 189 Will increase power usage.
192 190
193 Default: 0 (off) 191 Default: 0 (off)
194 192
195 busy_poll 193 busy_poll
196 ---------------- 194 ----------------
197 Low latency busy poll timeout for poll and sel 195 Low latency busy poll timeout for poll and select. (needs CONFIG_NET_RX_BUSY_POLL)
198 Approximate time in us to busy loop waiting fo 196 Approximate time in us to busy loop waiting for events.
199 Recommended value depends on the number of soc 197 Recommended value depends on the number of sockets you poll on.
200 For several sockets 50, for several hundreds 1 198 For several sockets 50, for several hundreds 100.
201 For more than that you probably want to use ep 199 For more than that you probably want to use epoll.
202 Note that only sockets with SO_BUSY_POLL set w 200 Note that only sockets with SO_BUSY_POLL set will be busy polled,
203 so you want to either selectively set SO_BUSY_ 201 so you want to either selectively set SO_BUSY_POLL on those sockets or set
204 sysctl.net.busy_read globally. 202 sysctl.net.busy_read globally.
205 203
206 Will increase power usage. 204 Will increase power usage.
207 205
208 Default: 0 (off) 206 Default: 0 (off)
209 207
210 mem_pcpu_rsv 208 mem_pcpu_rsv
211 ------------ 209 ------------
212 210
213 Per-cpu reserved forward alloc cache size in p 211 Per-cpu reserved forward alloc cache size in page units. Default 1MB per CPU.
214 212
215 rmem_default 213 rmem_default
216 ------------ 214 ------------
217 215
218 The default setting of the socket receive buff 216 The default setting of the socket receive buffer in bytes.
219 217
220 rmem_max 218 rmem_max
221 -------- 219 --------
222 220
223 The maximum receive socket buffer size in byte 221 The maximum receive socket buffer size in bytes.
224 222
225 rps_default_mask <<
226 ---------------- <<
227 <<
228 The default RPS CPU mask used on newly created <<
229 mask means RPS disabled by default. <<
230 <<
231 tstamp_allow_data 223 tstamp_allow_data
232 ----------------- 224 -----------------
233 Allow processes to receive tx timestamps loope 225 Allow processes to receive tx timestamps looped together with the original
234 packet contents. If disabled, transmit timesta 226 packet contents. If disabled, transmit timestamp requests from unprivileged
235 processes are dropped unless socket option SOF 227 processes are dropped unless socket option SOF_TIMESTAMPING_OPT_TSONLY is set.
236 228
237 Default: 1 (on) 229 Default: 1 (on)
238 230
239 231
240 wmem_default 232 wmem_default
241 ------------ 233 ------------
242 234
243 The default setting (in bytes) of the socket s 235 The default setting (in bytes) of the socket send buffer.
244 236
245 wmem_max 237 wmem_max
246 -------- 238 --------
247 239
248 The maximum send socket buffer size in bytes. 240 The maximum send socket buffer size in bytes.
249 241
250 message_burst and message_cost 242 message_burst and message_cost
251 ------------------------------ 243 ------------------------------
252 244
253 These parameters are used to limit the warnin 245 These parameters are used to limit the warning messages written to the kernel
254 log from the networking code. They enforc 246 log from the networking code. They enforce a rate limit to make a
255 denial-of-service attack impossible. A higher 247 denial-of-service attack impossible. A higher message_cost factor, results in
256 fewer messages that will be written. Message_b 248 fewer messages that will be written. Message_burst controls when messages will
257 be dropped. The default settings limit wa 249 be dropped. The default settings limit warning messages to one every five
258 seconds. 250 seconds.
259 251
260 warnings 252 warnings
261 -------- 253 --------
262 254
263 This sysctl is now unused. 255 This sysctl is now unused.
264 256
265 This was used to control console messages from 257 This was used to control console messages from the networking stack that
266 occur because of problems on the network like 258 occur because of problems on the network like duplicate address or bad
267 checksums. 259 checksums.
268 260
269 These messages are now emitted at KERN_DEBUG a 261 These messages are now emitted at KERN_DEBUG and can generally be enabled
270 and controlled by the dynamic_debug facility. 262 and controlled by the dynamic_debug facility.
271 263
272 netdev_budget 264 netdev_budget
273 ------------- 265 -------------
274 266
275 Maximum number of packets taken from all inter 267 Maximum number of packets taken from all interfaces in one polling cycle (NAPI
276 poll). In one polling cycle interfaces which a 268 poll). In one polling cycle interfaces which are registered to polling are
277 probed in a round-robin manner. Also, a pollin 269 probed in a round-robin manner. Also, a polling cycle may not exceed
278 netdev_budget_usecs microseconds, even if netd 270 netdev_budget_usecs microseconds, even if netdev_budget has not been
279 exhausted. 271 exhausted.
280 272
281 netdev_budget_usecs 273 netdev_budget_usecs
282 --------------------- 274 ---------------------
283 275
284 Maximum number of microseconds in one NAPI pol 276 Maximum number of microseconds in one NAPI polling cycle. Polling
285 will exit when either netdev_budget_usecs have 277 will exit when either netdev_budget_usecs have elapsed during the
286 poll cycle or the number of packets processed 278 poll cycle or the number of packets processed reaches netdev_budget.
287 279
288 netdev_max_backlog 280 netdev_max_backlog
289 ------------------ 281 ------------------
290 282
291 Maximum number of packets, queued on the INPUT 283 Maximum number of packets, queued on the INPUT side, when the interface
292 receives packets faster than kernel can proces 284 receives packets faster than kernel can process them.
293 285
294 netdev_rss_key 286 netdev_rss_key
295 -------------- 287 --------------
296 288
297 RSS (Receive Side Scaling) enabled drivers use 289 RSS (Receive Side Scaling) enabled drivers use a 40 bytes host key that is
298 randomly generated. 290 randomly generated.
299 Some user space might need to gather its conte 291 Some user space might need to gather its content even if drivers do not
300 provide ethtool -x support yet. 292 provide ethtool -x support yet.
301 293
302 :: 294 ::
303 295
304 myhost:~# cat /proc/sys/net/core/netdev_rss_ 296 myhost:~# cat /proc/sys/net/core/netdev_rss_key
305 84:50:f4:00:a8:15:d1:a7:e9:7f:1d:60:35:c7:47 297 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: ... (52 bytes total)
306 298
307 File contains nul bytes if no driver ever call 299 File contains nul bytes if no driver ever called netdev_rss_key_fill() function.
308 300
309 Note: 301 Note:
310 /proc/sys/net/core/netdev_rss_key contains 5 302 /proc/sys/net/core/netdev_rss_key contains 52 bytes of key,
311 but most drivers only use 40 bytes of it. 303 but most drivers only use 40 bytes of it.
312 304
313 :: 305 ::
314 306
315 myhost:~# ethtool -x eth0 307 myhost:~# ethtool -x eth0
316 RX flow hash indirection table for eth0 with 308 RX flow hash indirection table for eth0 with 8 RX ring(s):
317 0: 0 1 2 3 4 5 309 0: 0 1 2 3 4 5 6 7
318 RSS hash key: 310 RSS hash key:
319 84:50:f4:00:a8:15:d1:a7:e9:7f:1d:60:35:c7:47 311 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
320 312
321 netdev_tstamp_prequeue 313 netdev_tstamp_prequeue
322 ---------------------- 314 ----------------------
323 315
324 If set to 0, RX packet timestamps can be sampl 316 If set to 0, RX packet timestamps can be sampled after RPS processing, when
325 the target CPU processes packets. It might giv 317 the target CPU processes packets. It might give some delay on timestamps, but
326 permit to distribute the load on several cpus. 318 permit to distribute the load on several cpus.
327 319
328 If set to 1 (default), timestamps are sampled 320 If set to 1 (default), timestamps are sampled as soon as possible, before
329 queueing. 321 queueing.
330 322
331 netdev_unregister_timeout_secs 323 netdev_unregister_timeout_secs
332 ------------------------------ 324 ------------------------------
333 325
334 Unregister network device timeout in seconds. 326 Unregister network device timeout in seconds.
335 This option controls the timeout (in seconds) 327 This option controls the timeout (in seconds) used to issue a warning while
336 waiting for a network device refcount to drop 328 waiting for a network device refcount to drop to 0 during device
337 unregistration. A lower value may be useful du 329 unregistration. A lower value may be useful during bisection to detect
338 a leaked reference faster. A larger value may 330 a leaked reference faster. A larger value may be useful to prevent false
339 warnings on slow/loaded systems. 331 warnings on slow/loaded systems.
340 Default value is 10, minimum 1, maximum 3600. 332 Default value is 10, minimum 1, maximum 3600.
341 333
342 skb_defer_max 334 skb_defer_max
343 ------------- 335 -------------
344 336
345 Max size (in skbs) of the per-cpu list of skbs 337 Max size (in skbs) of the per-cpu list of skbs being freed
346 by the cpu which allocated them. Used by TCP s 338 by the cpu which allocated them. Used by TCP stack so far.
347 339
348 Default: 64 340 Default: 64
349 341
350 optmem_max 342 optmem_max
351 ---------- 343 ----------
352 344
353 Maximum ancillary buffer size allowed per sock 345 Maximum ancillary buffer size allowed per socket. Ancillary data is a sequence
354 of struct cmsghdr structures with appended dat !! 346 of struct cmsghdr structures with appended data.
355 optmem_max as a limit for its internal structu <<
356 <<
357 Default : 128 KB <<
358 347
359 fb_tunnels_only_for_init_net 348 fb_tunnels_only_for_init_net
360 ---------------------------- 349 ----------------------------
361 350
362 Controls if fallback tunnels (like tunl0, gre0 351 Controls if fallback tunnels (like tunl0, gre0, gretap0, erspan0,
363 sit0, ip6tnl0, ip6gre0) are automatically crea 352 sit0, ip6tnl0, ip6gre0) are automatically created. There are 3 possibilities
364 (a) value = 0; respective fallback tunnels are 353 (a) value = 0; respective fallback tunnels are created when module is
365 loaded in every net namespaces (backward compa 354 loaded in every net namespaces (backward compatible behavior).
366 (b) value = 1; [kcmd value: initns] respective 355 (b) value = 1; [kcmd value: initns] respective fallback tunnels are
367 created only in init net namespace and every o 356 created only in init net namespace and every other net namespace will
368 not have them. 357 not have them.
369 (c) value = 2; [kcmd value: none] fallback tun 358 (c) value = 2; [kcmd value: none] fallback tunnels are not created
370 when a module is loaded in any of the net name 359 when a module is loaded in any of the net namespace. Setting value to
371 "2" is pointless after boot if these modules a 360 "2" is pointless after boot if these modules are built-in, so there is
372 a kernel command-line option that can change t 361 a kernel command-line option that can change this default. Please refer to
373 Documentation/admin-guide/kernel-parameters.tx 362 Documentation/admin-guide/kernel-parameters.txt for additional details.
374 363
375 Not creating fallback tunnels gives control to 364 Not creating fallback tunnels gives control to userspace to create
376 whatever is needed only and avoid creating dev 365 whatever is needed only and avoid creating devices which are redundant.
377 366
378 Default : 0 (for compatibility reasons) 367 Default : 0 (for compatibility reasons)
379 368
380 devconf_inherit_init_net 369 devconf_inherit_init_net
381 ------------------------ 370 ------------------------
382 371
383 Controls if a new network namespace should inh 372 Controls if a new network namespace should inherit all current
384 settings under /proc/sys/net/{ipv4,ipv6}/conf/ 373 settings under /proc/sys/net/{ipv4,ipv6}/conf/{all,default}/. By
385 default, we keep the current behavior: for IPv 374 default, we keep the current behavior: for IPv4 we inherit all current
386 settings from init_net and for IPv6 we reset a 375 settings from init_net and for IPv6 we reset all settings to default.
387 376
388 If set to 1, both IPv4 and IPv6 settings are f 377 If set to 1, both IPv4 and IPv6 settings are forced to inherit from
389 current ones in init_net. If set to 2, both IP 378 current ones in init_net. If set to 2, both IPv4 and IPv6 settings are
390 forced to reset to their default values. If se 379 forced to reset to their default values. If set to 3, both IPv4 and IPv6
391 settings are forced to inherit from current on 380 settings are forced to inherit from current ones in the netns where this
392 new netns has been created. 381 new netns has been created.
393 382
394 Default : 0 (for compatibility reasons) 383 Default : 0 (for compatibility reasons)
395 384
396 txrehash 385 txrehash
397 -------- 386 --------
398 387
399 Controls default hash rethink behaviour on soc !! 388 Controls default hash rethink behaviour on listening socket when SO_TXREHASH
400 to SOCK_TXREHASH_DEFAULT (i. e. not overridden !! 389 option is set to SOCK_TXREHASH_DEFAULT (i. e. not overridden by setsockopt).
401 390
402 If set to 1 (default), hash rethink is perform 391 If set to 1 (default), hash rethink is performed on listening socket.
403 If set to 0, hash rethink is not performed. 392 If set to 0, hash rethink is not performed.
404 393
405 gro_normal_batch 394 gro_normal_batch
406 ---------------- 395 ----------------
407 396
408 Maximum number of the segments to batch up on 397 Maximum number of the segments to batch up on output of GRO. When a packet
409 exits GRO, either as a coalesced superframe or 398 exits GRO, either as a coalesced superframe or as an original packet which
410 GRO has decided not to coalesce, it is placed 399 GRO has decided not to coalesce, it is placed on a per-NAPI list. This
411 list is then passed to the stack when the numb 400 list is then passed to the stack when the number of segments reaches the
412 gro_normal_batch limit. 401 gro_normal_batch limit.
413 402
414 high_order_alloc_disable 403 high_order_alloc_disable
415 ------------------------ 404 ------------------------
416 405
417 By default the allocator for page frags tries 406 By default the allocator for page frags tries to use high order pages (order-3
418 on x86). While the default behavior gives good 407 on x86). While the default behavior gives good results in most cases, some users
419 might have hit a contention in page allocation 408 might have hit a contention in page allocations/freeing. This was especially
420 true on older kernels (< 5.14) when high-order 409 true on older kernels (< 5.14) when high-order pages were not stored on per-cpu
421 lists. This allows to opt-in for order-0 alloc 410 lists. This allows to opt-in for order-0 allocation instead but is now mostly of
422 historical importance. 411 historical importance.
423 412
424 Default: 0 413 Default: 0
425 414
426 2. /proc/sys/net/unix - Parameters for Unix do 415 2. /proc/sys/net/unix - Parameters for Unix domain sockets
427 ---------------------------------------------- 416 ----------------------------------------------------------
428 417
429 There is only one file in this directory. 418 There is only one file in this directory.
430 unix_dgram_qlen limits the max number of datag 419 unix_dgram_qlen limits the max number of datagrams queued in Unix domain
431 socket's buffer. It will not take effect unles 420 socket's buffer. It will not take effect unless PF_UNIX flag is specified.
432 421
433 422
434 3. /proc/sys/net/ipv4 - IPV4 settings 423 3. /proc/sys/net/ipv4 - IPV4 settings
435 ------------------------------------- 424 -------------------------------------
436 Please see: Documentation/networking/ip-sysctl 425 Please see: Documentation/networking/ip-sysctl.rst and
437 Documentation/admin-guide/sysctl/net.rst for d 426 Documentation/admin-guide/sysctl/net.rst for descriptions of these entries.
438 427
439 428
440 4. Appletalk 429 4. Appletalk
441 ------------ 430 ------------
442 431
443 The /proc/sys/net/appletalk directory holds 432 The /proc/sys/net/appletalk directory holds the Appletalk configuration data
444 when Appletalk is loaded. The configurable par 433 when Appletalk is loaded. The configurable parameters are:
445 434
446 aarp-expiry-time 435 aarp-expiry-time
447 ---------------- 436 ----------------
448 437
449 The amount of time we keep an ARP entry bef 438 The amount of time we keep an ARP entry before expiring it. Used to age out
450 old hosts. 439 old hosts.
451 440
452 aarp-resolve-time 441 aarp-resolve-time
453 ----------------- 442 -----------------
454 443
455 The amount of time we will spend trying to res 444 The amount of time we will spend trying to resolve an Appletalk address.
456 445
457 aarp-retransmit-limit 446 aarp-retransmit-limit
458 --------------------- 447 ---------------------
459 448
460 The number of times we will retransmit a query 449 The number of times we will retransmit a query before giving up.
461 450
462 aarp-tick-time 451 aarp-tick-time
463 -------------- 452 --------------
464 453
465 Controls the rate at which expires are checked 454 Controls the rate at which expires are checked.
466 455
467 The directory /proc/net/appletalk holds the 456 The directory /proc/net/appletalk holds the list of active Appletalk sockets
468 on a machine. 457 on a machine.
469 458
470 The fields indicate the DDP type, the local 459 The fields indicate the DDP type, the local address (in network:node format)
471 the remote address, the size of the transmi 460 the remote address, the size of the transmit pending queue, the size of the
472 received queue (bytes waiting for application 461 received queue (bytes waiting for applications to read) the state and the uid
473 owning the socket. 462 owning the socket.
474 463
475 /proc/net/atalk_iface lists all the interfa 464 /proc/net/atalk_iface lists all the interfaces configured for appletalk.It
476 shows the name of the interface, its Appleta 465 shows the name of the interface, its Appletalk address, the network range on
477 that address (or network number for phase 1 466 that address (or network number for phase 1 networks), and the status of the
478 interface. 467 interface.
479 468
480 /proc/net/atalk_route lists each known netw 469 /proc/net/atalk_route lists each known network route. It lists the target
481 (network) that the route leads to, the router 470 (network) that the route leads to, the router (may be directly connected), the
482 route flags, and the device the route is using 471 route flags, and the device the route is using.
483 472
484 5. TIPC 473 5. TIPC
485 ------- 474 -------
486 475
487 tipc_rmem 476 tipc_rmem
488 --------- 477 ---------
489 478
490 The TIPC protocol now has a tunable for the re 479 The TIPC protocol now has a tunable for the receive memory, similar to the
491 tcp_rmem - i.e. a vector of 3 INTEGERs: (min, 480 tcp_rmem - i.e. a vector of 3 INTEGERs: (min, default, max)
492 481
493 :: 482 ::
494 483
495 # cat /proc/sys/net/tipc/tipc_rmem 484 # cat /proc/sys/net/tipc/tipc_rmem
496 4252725 34021800 68043600 485 4252725 34021800 68043600
497 # 486 #
498 487
499 The max value is set to CONN_OVERLOAD_LIMIT, a 488 The max value is set to CONN_OVERLOAD_LIMIT, and the default and min values
500 are scaled (shifted) versions of that same val 489 are scaled (shifted) versions of that same value. Note that the min value
501 is not at this point in time used in any meani 490 is not at this point in time used in any meaningful way, but the triplet is
502 preserved in order to be consistent with thing 491 preserved in order to be consistent with things like tcp_rmem.
503 492
504 named_timeout 493 named_timeout
505 ------------- 494 -------------
506 495
507 TIPC name table updates are distributed asynch 496 TIPC name table updates are distributed asynchronously in a cluster, without
508 any form of transaction handling. This means t 497 any form of transaction handling. This means that different race scenarios are
509 possible. One such is that a name withdrawal s 498 possible. One such is that a name withdrawal sent out by one node and received
510 by another node may arrive after a second, ove 499 by another node may arrive after a second, overlapping name publication already
511 has been accepted from a third node, although 500 has been accepted from a third node, although the conflicting updates
512 originally may have been issued in the correct 501 originally may have been issued in the correct sequential order.
513 If named_timeout is nonzero, failed topology u 502 If named_timeout is nonzero, failed topology updates will be placed on a defer
514 queue until another event arrives that clears 503 queue until another event arrives that clears the error, or until the timeout
515 expires. Value is in milliseconds. 504 expires. Value is in milliseconds.
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