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IP-XFRM(8) Linux IP-XFRM(8)
ip-xfrm - transform configuration
ip [ OPTIONS ] xfrm { COMMAND | help } ip xfrm XFRM-OBJECT { COMMAND | help } XFRM-OBJECT := state | policy | monitor ip xfrm state { add | update } ID [ ALGO-LIST ] [ mode MODE ] [ mark MARK [ mask MASK ] ] [ reqid REQID ] [ seq SEQ ] [ replay-window SIZE ] [ replay-seq SEQ ] [ replay-oseq SEQ ] [ replay-seq-hi SEQ ] [ replay-oseq-hi SEQ ] [ flag FLAG-LIST ] [ sel SELECTOR ] [ LIMIT-LIST ] [ encap ENCAP ] [ coa ADDR[/PLEN] ] [ ctx CTX ] [ extra-flag EXTRA- FLAG-LIST ] [ output-mark OUTPUT-MARK [ mask MASK ] ] [ if_id IF-ID ] [ offload [ crypto|packet ] dev DEV dir DIR ] [ tfcpad LENGTH ] ip xfrm state allocspi ID [ mode MODE ] [ mark MARK [ mask MASK ] ] [ reqid REQID ] [ seq SEQ ] [ min SPI max SPI ] ip xfrm state { delete | get } ID [ mark MARK [ mask MASK ] ] ip [ -4 | -6 ] xfrm state deleteall [ ID ] [ mode MODE ] [ reqid REQID ] [ flag FLAG-LIST ] ip [ -4 | -6 ] xfrm state list [ ID ] [ nokeys ] [ mode MODE ] [ reqid REQID ] [ flag FLAG-LIST ] ip xfrm state flush [ proto XFRM-PROTO ] ip xfrm state count ID := [ src ADDR ] [ dst ADDR ] [ proto XFRM-PROTO ] [ spi SPI ] XFRM-PROTO := esp | ah | comp | route2 | hao ALGO-LIST := [ ALGO-LIST ] ALGO ALGO := { enc | auth } ALGO-NAME ALGO-KEYMAT | auth-trunc ALGO-NAME ALGO-KEYMAT ALGO-TRUNC-LEN | aead ALGO-NAME ALGO-KEYMAT ALGO-ICV-LEN | comp ALGO-NAME MODE := transport | tunnel | beet | ro | in_trigger FLAG-LIST := [ FLAG-LIST ] FLAG FLAG := noecn | decap-dscp | nopmtudisc | wildrecv | icmp | af- unspec | align4 | esn SELECTOR := [ src ADDR[/PLEN] ] [ dst ADDR[/PLEN] ] [ dev DEV ] [ UPSPEC ] UPSPEC := proto { PROTO | { tcp | udp | sctp | dccp } [ sport PORT ] [ dport PORT ] | { icmp | ipv6-icmp | mobility-header } [ type NUMBER ] [ code NUMBER ] | gre [ key { DOTTED-QUAD | NUMBER } ] } LIMIT-LIST := [ LIMIT-LIST ] limit LIMIT LIMIT := { time-soft | time-hard | time-use-soft | time-use-hard } SECONDS | { byte-soft | byte-hard } SIZE | { packet-soft | packet-hard } COUNT ENCAP := { espinudp | espinudp-nonike | espintcp } SPORT DPORT OADDR EXTRA-FLAG-LIST := [ EXTRA-FLAG-LIST ] EXTRA-FLAG EXTRA-FLAG := dont-encap-dscp | oseq-may-wrap ip xfrm policy { add | update } SELECTOR dir DIR [ ctx CTX ] [ mark MARK [ mask MASK ] ] [ index INDEX ] [ ptype PTYPE ] [ action ACTION ] [ priority PRIORITY ] [ flag FLAG-LIST ] [ if_id IF-ID ] [ offload packet dev DEV ] [ LIMIT-LIST ] [ TMPL-LIST ] ip xfrm policy { delete | get } { SELECTOR | index INDEX } dir DIR [ ctx CTX ] [ mark MARK [ mask MASK ] ] [ ptype PTYPE ] [ if_id IF-ID ] ip [ -4 | -6 ] xfrm policy { deleteall | list } [ nosock ] [ SELECTOR ] [ dir DIR ] [ index INDEX ] [ ptype PTYPE ] [ action ACTION ] [ priority PRIORITY ] [ flag FLAG-LIST] ip xfrm policy flush [ ptype PTYPE ] ip xfrm policy count ip xfrm policy set [ hthresh4 LBITS RBITS ] [ hthresh6 LBITS RBITS ] ip xfrm policy setdefault DIR ACTION [ DIR ACTION ] [ DIR ACTION ] ip xfrm policy getdefault SELECTOR := [ src ADDR[/PLEN] ] [ dst ADDR[/PLEN] ] [ dev DEV ] [ UPSPEC ] UPSPEC := proto { PROTO | { tcp | udp | sctp | dccp } [ sport PORT ] [ dport PORT ] | { icmp | ipv6-icmp | mobility-header } [ type NUMBER ] [ code NUMBER ] | gre [ key { DOTTED-QUAD | NUMBER } ] } DIR := in | out | fwd PTYPE := main | sub ACTION := allow | block FLAG-LIST := [ FLAG-LIST ] FLAG FLAG := localok | icmp LIMIT-LIST := [ LIMIT-LIST ] limit LIMIT LIMIT := { time-soft | time-hard | time-use-soft | time-use-hard } SECONDS | { byte-soft | byte-hard } SIZE | { packet-soft | packet-hard } COUNT TMPL-LIST := [ TMPL-LIST ] tmpl TMPL TMPL := ID [ mode MODE ] [ reqid REQID ] [ level LEVEL ] ID := [ src ADDR ] [ dst ADDR ] [ proto XFRM-PROTO ] [ spi SPI ] XFRM-PROTO := esp | ah | comp | route2 | hao MODE := transport | tunnel | beet | ro | in_trigger LEVEL := required | use ip xfrm monitor [ all-nsid ] [ nokeys ] [ all | LISTofXFRM-OBJECTS ] LISTofXFRM-OBJECTS := [ LISTofXFRM-OBJECTS ] XFRM-OBJECT XFRM-OBJECT := acquire | expire | SA | policy | aevent | report
xfrm is an IP framework for transforming packets (such as encrypting their payloads). This framework is used to implement the IPsec protocol suite (with the state object operating on the Security Association Database, and the policy object operating on the Security Policy Database). It is also used for the IP Payload Compression Protocol and features of Mobile IPv6. ip xfrm state add add new state into xfrm ip xfrm state update update existing state in xfrm ip xfrm state allocspi allocate an SPI value ip xfrm state delete delete existing state in xfrm ip xfrm state get get existing state in xfrm ip xfrm state deleteall delete all existing state in xfrm ip xfrm state list print out the list of existing state in xfrm ip xfrm state flush flush all state in xfrm ip xfrm state count count all existing state in xfrm ID is specified by a source address, destination address, transform protocol XFRM-PROTO, and/or Security Parameter Index SPI. (For IP Payload Compression, the Compression Parameter Index or CPI is used for SPI.) XFRM-PROTO specifies a transform protocol: IPsec Encapsulating Security Payload (esp), IPsec Authentication Header (ah), IP Payload Compression (comp), Mobile IPv6 Type 2 Routing Header (route2), or Mobile IPv6 Home Address Option (hao). ALGO-LIST contains one or more algorithms to use. Each algorithm ALGO is specified by: • the algorithm type: encryption (enc), authentication (auth or auth-trunc), authenticated encryption with associated data (aead), or compression (comp) • the algorithm name ALGO-NAME (see below) • (for all except comp) the keying material ALGO- KEYMAT, which may include both a key and a salt or nonce value; refer to the corresponding RFC • (for auth-trunc only) the truncation length ALGO- TRUNC-LEN in bits • (for aead only) the Integrity Check Value length ALGO-ICV-LEN in bits Encryption algorithms include ecb(cipher_null), cbc(des), cbc(des3_ede), cbc(cast5), cbc(blowfish), cbc(aes), cbc(serpent), cbc(camellia), cbc(twofish), and rfc3686(ctr(aes)). Authentication algorithms include digest_null, hmac(md5), hmac(sha1), hmac(sha256), hmac(sha384), hmac(sha512), hmac(rmd160), and xcbc(aes). Authenticated encryption with associated data (AEAD) algorithms include rfc4106(gcm(aes)), rfc4309(ccm(aes)), and rfc4543(gcm(aes)). Compression algorithms include deflate, lzs, and lzjh. MODE specifies a mode of operation for the transform protocol. IPsec and IP Payload Compression modes are transport, tun‐ nel, and (for IPsec ESP only) Bound End-to-End Tunnel (beet). Mobile IPv6 modes are route optimization (ro) and inbound trigger (in_trigger). FLAG-LIST contains one or more of the following optional flags: noecn, decap-dscp, nopmtudisc, wildrecv, icmp, af-unspec, align4, or esn. SELECTOR selects the traffic that will be controlled by the policy, based on the source address, the destination address, the network device, and/or UPSPEC. UPSPEC selects traffic by protocol. For the tcp, udp, sctp, or dccp protocols, the source and destination port can op‐ tionally be specified. For the icmp, ipv6-icmp, or mobil‐ ity-header protocols, the type and code numbers can op‐ tionally be specified. For the gre protocol, the key can optionally be specified as a dotted-quad or number. Other protocols can be selected by name or number PROTO. LIMIT-LIST sets limits in seconds, bytes, or numbers of packets. ENCAP encapsulates packets with protocol espinudp, espinudp-non‐ ike, or espintcp, using source port SPORT, destination port DPORT , and original address OADDR. MARK used to match xfrm policies and states OUTPUT-MARK used to set the output mark to influence the routing of the packets emitted by the state IF-ID xfrm interface identifier used to in both xfrm policies and states DEV Network interface name used to offload policies and states ip xfrm policy add add a new policy ip xfrm policy update update an existing policy ip xfrm policy delete delete an existing policy ip xfrm policy get get an existing policy ip xfrm policy deleteall delete all existing xfrm policies ip xfrm policy list print out the list of xfrm policies ip xfrm policy flush flush policies nosock filter (remove) all socket policies from the output. SELECTOR selects the traffic that will be controlled by the policy, based on the source address, the destination address, the network device, and/or UPSPEC. UPSPEC selects traffic by protocol. For the tcp, udp, sctp, or dccp protocols, the source and destination port can op‐ tionally be specified. For the icmp, ipv6-icmp, or mobil‐ ity-header protocols, the type and code numbers can op‐ tionally be specified. For the gre protocol, the key can optionally be specified as a dotted-quad or number. Other protocols can be selected by name or number PROTO. DIR selects the policy direction as in, out, or fwd. CTX sets the security context. PTYPE can be main (default) or sub. ACTION can be allow (default) or block. PRIORITY is a number that defaults to zero. FLAG-LIST contains one or both of the following optional flags: lo‐ cal or icmp. LIMIT-LIST sets limits in seconds, bytes, or numbers of packets. TMPL-LIST is a template list specified using ID, MODE, REQID, and/or LEVEL. ID is specified by a source address, destination address, transform protocol XFRM-PROTO, and/or Security Parameter Index SPI. (For IP Payload Compression, the Compression Parameter Index or CPI is used for SPI.) XFRM-PROTO specifies a transform protocol: IPsec Encapsulating Secu‐ rity Payload (esp), IPsec Authentication Header (ah), IP Payload Compression (comp), Mobile IPv6 Type 2 Routing Header (route2), or Mobile IPv6 Home Address Option (hao). MODE specifies a mode of operation for the transform protocol. IPsec and IP Payload Compression modes are transport, tun‐ nel, and (for IPsec ESP only) Bound End-to-End Tunnel (beet). Mobile IPv6 modes are route optimization (ro) and inbound trigger (in_trigger). LEVEL can be required (default) or use. ip xfrm policy count count existing policies Use one or more -s options to display more details, including policy hash table information. ip xfrm policy set configure the policy hash table Security policies whose address prefix lengths are greater than or equal policy hash table thresholds are hashed. Others are stored in the policy_inexact chained list. LBITS specifies the minimum local address prefix length of poli‐ cies that are stored in the Security Policy Database hash table. RBITS specifies the minimum remote address prefix length of policies that are stored in the Security Policy Database hash table. ip xfrm monitor state monitoring for xfrm objects The xfrm objects to monitor can be optionally specified. If the all-nsid option is set, the program listens to all network namespaces that have a nsid assigned into the network namespace were the program is running. A prefix is displayed to show the network namespace where the message originates. Example: [nsid 1]Flushed state proto 0
Manpage revised by David Ward <david.ward@ll.mit.edu> Manpage revised by Christophe Gouault <christophe.gouault@6wind.com> Manpage revised by Nicolas Dichtel <nicolas.dichtel@6wind.com>
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iproute2 20 Dec 2011 IP-XFRM(8)
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