1# SPDX-License-Identifier: GPL-2.0-only
2#
3# IP Virtual Server configuration
4#
5menuconfig IP_VS
6	tristate "IP virtual server support"
7	depends on NET && INET && NETFILTER
8	depends on (NF_CONNTRACK || NF_CONNTRACK=n)
9	---help---
10	  IP Virtual Server support will let you build a high-performance
11	  virtual server based on cluster of two or more real servers. This
12	  option must be enabled for at least one of the clustered computers
13	  that will take care of intercepting incoming connections to a
14	  single IP address and scheduling them to real servers.
15
16	  Three request dispatching techniques are implemented, they are
17	  virtual server via NAT, virtual server via tunneling and virtual
18	  server via direct routing. The several scheduling algorithms can
19	  be used to choose which server the connection is directed to,
20	  thus load balancing can be achieved among the servers.  For more
21	  information and its administration program, please visit the
22	  following URL: <http://www.linuxvirtualserver.org/>.
23
24	  If you want to compile it in kernel, say Y. To compile it as a
25	  module, choose M here. If unsure, say N.
26
27if IP_VS
28
29config	IP_VS_IPV6
30	bool "IPv6 support for IPVS"
31	depends on IPV6 = y || IP_VS = IPV6
32	select IP6_NF_IPTABLES
33	select NF_DEFRAG_IPV6
34	---help---
35	  Add IPv6 support to IPVS.
36
37	  Say Y if unsure.
38
39config	IP_VS_DEBUG
40	bool "IP virtual server debugging"
41	---help---
42	  Say Y here if you want to get additional messages useful in
43	  debugging the IP virtual server code. You can change the debug
44	  level in /proc/sys/net/ipv4/vs/debug_level
45
46config	IP_VS_TAB_BITS
47	int "IPVS connection table size (the Nth power of 2)"
48	range 8 20
49	default 12
50	---help---
51	  The IPVS connection hash table uses the chaining scheme to handle
52	  hash collisions. Using a big IPVS connection hash table will greatly
53	  reduce conflicts when there are hundreds of thousands of connections
54	  in the hash table.
55
56	  Note the table size must be power of 2. The table size will be the
57	  value of 2 to the your input number power. The number to choose is
58	  from 8 to 20, the default number is 12, which means the table size
59	  is 4096. Don't input the number too small, otherwise you will lose
60	  performance on it. You can adapt the table size yourself, according
61	  to your virtual server application. It is good to set the table size
62	  not far less than the number of connections per second multiplying
63	  average lasting time of connection in the table.  For example, your
64	  virtual server gets 200 connections per second, the connection lasts
65	  for 200 seconds in average in the connection table, the table size
66	  should be not far less than 200x200, it is good to set the table
67	  size 32768 (2**15).
68
69	  Another note that each connection occupies 128 bytes effectively and
70	  each hash entry uses 8 bytes, so you can estimate how much memory is
71	  needed for your box.
72
73	  You can overwrite this number setting conn_tab_bits module parameter
74	  or by appending ip_vs.conn_tab_bits=? to the kernel command line
75	  if IP VS was compiled built-in.
76
77comment "IPVS transport protocol load balancing support"
78
79config	IP_VS_PROTO_TCP
80	bool "TCP load balancing support"
81	---help---
82	  This option enables support for load balancing TCP transport
83	  protocol. Say Y if unsure.
84
85config	IP_VS_PROTO_UDP
86	bool "UDP load balancing support"
87	---help---
88	  This option enables support for load balancing UDP transport
89	  protocol. Say Y if unsure.
90
91config	IP_VS_PROTO_AH_ESP
92	def_bool IP_VS_PROTO_ESP || IP_VS_PROTO_AH
93
94config	IP_VS_PROTO_ESP
95	bool "ESP load balancing support"
96	---help---
97	  This option enables support for load balancing ESP (Encapsulation
98	  Security Payload) transport protocol. Say Y if unsure.
99
100config	IP_VS_PROTO_AH
101	bool "AH load balancing support"
102	---help---
103	  This option enables support for load balancing AH (Authentication
104	  Header) transport protocol. Say Y if unsure.
105
106config  IP_VS_PROTO_SCTP
107	bool "SCTP load balancing support"
108	select LIBCRC32C
109	---help---
110	  This option enables support for load balancing SCTP transport
111	  protocol. Say Y if unsure.
112
113comment "IPVS scheduler"
114
115config	IP_VS_RR
116	tristate "round-robin scheduling"
117	---help---
118	  The robin-robin scheduling algorithm simply directs network
119	  connections to different real servers in a round-robin manner.
120
121	  If you want to compile it in kernel, say Y. To compile it as a
122	  module, choose M here. If unsure, say N.
123
124config	IP_VS_WRR
125	tristate "weighted round-robin scheduling"
126	---help---
127	  The weighted robin-robin scheduling algorithm directs network
128	  connections to different real servers based on server weights
129	  in a round-robin manner. Servers with higher weights receive
130	  new connections first than those with less weights, and servers
131	  with higher weights get more connections than those with less
132	  weights and servers with equal weights get equal connections.
133
134	  If you want to compile it in kernel, say Y. To compile it as a
135	  module, choose M here. If unsure, say N.
136
137config	IP_VS_LC
138	tristate "least-connection scheduling"
139	---help---
140	  The least-connection scheduling algorithm directs network
141	  connections to the server with the least number of active
142	  connections.
143
144	  If you want to compile it in kernel, say Y. To compile it as a
145	  module, choose M here. If unsure, say N.
146
147config	IP_VS_WLC
148	tristate "weighted least-connection scheduling"
149	---help---
150	  The weighted least-connection scheduling algorithm directs network
151	  connections to the server with the least active connections
152	  normalized by the server weight.
153
154	  If you want to compile it in kernel, say Y. To compile it as a
155	  module, choose M here. If unsure, say N.
156
157config  IP_VS_FO
158		tristate "weighted failover scheduling"
159	---help---
160	  The weighted failover scheduling algorithm directs network
161	  connections to the server with the highest weight that is
162	  currently available.
163
164	  If you want to compile it in kernel, say Y. To compile it as a
165	  module, choose M here. If unsure, say N.
166
167config  IP_VS_OVF
168	tristate "weighted overflow scheduling"
169	---help---
170	  The weighted overflow scheduling algorithm directs network
171	  connections to the server with the highest weight that is
172	  currently available and overflows to the next when active
173	  connections exceed the node's weight.
174
175	  If you want to compile it in kernel, say Y. To compile it as a
176	  module, choose M here. If unsure, say N.
177
178config	IP_VS_LBLC
179	tristate "locality-based least-connection scheduling"
180	---help---
181	  The locality-based least-connection scheduling algorithm is for
182	  destination IP load balancing. It is usually used in cache cluster.
183	  This algorithm usually directs packet destined for an IP address to
184	  its server if the server is alive and under load. If the server is
185	  overloaded (its active connection numbers is larger than its weight)
186	  and there is a server in its half load, then allocate the weighted
187	  least-connection server to this IP address.
188
189	  If you want to compile it in kernel, say Y. To compile it as a
190	  module, choose M here. If unsure, say N.
191
192config  IP_VS_LBLCR
193	tristate "locality-based least-connection with replication scheduling"
194	---help---
195	  The locality-based least-connection with replication scheduling
196	  algorithm is also for destination IP load balancing. It is
197	  usually used in cache cluster. It differs from the LBLC scheduling
198	  as follows: the load balancer maintains mappings from a target
199	  to a set of server nodes that can serve the target. Requests for
200	  a target are assigned to the least-connection node in the target's
201	  server set. If all the node in the server set are over loaded,
202	  it picks up a least-connection node in the cluster and adds it
203	  in the sever set for the target. If the server set has not been
204	  modified for the specified time, the most loaded node is removed
205	  from the server set, in order to avoid high degree of replication.
206
207	  If you want to compile it in kernel, say Y. To compile it as a
208	  module, choose M here. If unsure, say N.
209
210config	IP_VS_DH
211	tristate "destination hashing scheduling"
212	---help---
213	  The destination hashing scheduling algorithm assigns network
214	  connections to the servers through looking up a statically assigned
215	  hash table by their destination IP addresses.
216
217	  If you want to compile it in kernel, say Y. To compile it as a
218	  module, choose M here. If unsure, say N.
219
220config	IP_VS_SH
221	tristate "source hashing scheduling"
222	---help---
223	  The source hashing scheduling algorithm assigns network
224	  connections to the servers through looking up a statically assigned
225	  hash table by their source IP addresses.
226
227	  If you want to compile it in kernel, say Y. To compile it as a
228	  module, choose M here. If unsure, say N.
229
230config	IP_VS_MH
231	tristate "maglev hashing scheduling"
232	---help---
233	  The maglev consistent hashing scheduling algorithm provides the
234	  Google's Maglev hashing algorithm as a IPVS scheduler. It assigns
235	  network connections to the servers through looking up a statically
236	  assigned special hash table called the lookup table. Maglev hashing
237	  is to assign a preference list of all the lookup table positions
238	  to each destination.
239
240	  Through this operation, The maglev hashing gives an almost equal
241	  share of the lookup table to each of the destinations and provides
242	  minimal disruption by using the lookup table. When the set of
243	  destinations changes, a connection will likely be sent to the same
244	  destination as it was before.
245
246	  If you want to compile it in kernel, say Y. To compile it as a
247	  module, choose M here. If unsure, say N.
248
249config	IP_VS_SED
250	tristate "shortest expected delay scheduling"
251	---help---
252	  The shortest expected delay scheduling algorithm assigns network
253	  connections to the server with the shortest expected delay. The
254	  expected delay that the job will experience is (Ci + 1) / Ui if
255	  sent to the ith server, in which Ci is the number of connections
256	  on the ith server and Ui is the fixed service rate (weight)
257	  of the ith server.
258
259	  If you want to compile it in kernel, say Y. To compile it as a
260	  module, choose M here. If unsure, say N.
261
262config	IP_VS_NQ
263	tristate "never queue scheduling"
264	---help---
265	  The never queue scheduling algorithm adopts a two-speed model.
266	  When there is an idle server available, the job will be sent to
267	  the idle server, instead of waiting for a fast one. When there
268	  is no idle server available, the job will be sent to the server
269	  that minimize its expected delay (The Shortest Expected Delay
270	  scheduling algorithm).
271
272	  If you want to compile it in kernel, say Y. To compile it as a
273	  module, choose M here. If unsure, say N.
274
275comment 'IPVS SH scheduler'
276
277config IP_VS_SH_TAB_BITS
278	int "IPVS source hashing table size (the Nth power of 2)"
279	range 4 20
280	default 8
281	---help---
282	  The source hashing scheduler maps source IPs to destinations
283	  stored in a hash table. This table is tiled by each destination
284	  until all slots in the table are filled. When using weights to
285	  allow destinations to receive more connections, the table is
286	  tiled an amount proportional to the weights specified. The table
287	  needs to be large enough to effectively fit all the destinations
288	  multiplied by their respective weights.
289
290comment 'IPVS MH scheduler'
291
292config IP_VS_MH_TAB_INDEX
293	int "IPVS maglev hashing table index of size (the prime numbers)"
294	range 8 17
295	default 12
296	---help---
297	  The maglev hashing scheduler maps source IPs to destinations
298	  stored in a hash table. This table is assigned by a preference
299	  list of the positions to each destination until all slots in
300	  the table are filled. The index determines the prime for size of
301	  the table as 251, 509, 1021, 2039, 4093, 8191, 16381, 32749,
302	  65521 or 131071. When using weights to allow destinations to
303	  receive more connections, the table is assigned an amount
304	  proportional to the weights specified. The table needs to be large
305	  enough to effectively fit all the destinations multiplied by their
306	  respective weights.
307
308comment 'IPVS application helper'
309
310config	IP_VS_FTP
311  	tristate "FTP protocol helper"
312	depends on IP_VS_PROTO_TCP && NF_CONNTRACK && NF_NAT && \
313		NF_CONNTRACK_FTP
314	select IP_VS_NFCT
315	---help---
316	  FTP is a protocol that transfers IP address and/or port number in
317	  the payload. In the virtual server via Network Address Translation,
318	  the IP address and port number of real servers cannot be sent to
319	  clients in ftp connections directly, so FTP protocol helper is
320	  required for tracking the connection and mangling it back to that of
321	  virtual service.
322
323	  If you want to compile it in kernel, say Y. To compile it as a
324	  module, choose M here. If unsure, say N.
325
326config	IP_VS_NFCT
327	bool "Netfilter connection tracking"
328	depends on NF_CONNTRACK
329	---help---
330	  The Netfilter connection tracking support allows the IPVS
331	  connection state to be exported to the Netfilter framework
332	  for filtering purposes.
333
334config	IP_VS_PE_SIP
335	tristate "SIP persistence engine"
336	depends on IP_VS_PROTO_UDP
337	depends on NF_CONNTRACK_SIP
338	---help---
339	  Allow persistence based on the SIP Call-ID
340
341endif # IP_VS
342