.\" $OpenBSD: iked.conf.5,v 1.53 2018/01/31 13:25:55 patrick Exp $ .\" .\" Copyright (c) 2010 - 2014 Reyk Floeter .\" Copyright (c) 2004 Mathieu Sauve-Frankel All rights reserved. .\" .\" Permission to use, copy, modify, and distribute this software for any .\" purpose with or without fee is hereby granted, provided that the above .\" copyright notice and this permission notice appear in all copies. .\" .\" THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES .\" WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF .\" MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR .\" ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES .\" WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN .\" ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF .\" OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. .\" .Dd $Mdocdate: January 31 2018 $ .Dt IKED.CONF 5 .Os .Sh NAME .Nm iked.conf .Nd IKEv2 configuration file .Sh DESCRIPTION .Nm is the configuration file for .Xr iked 8 , the Internet Key Exchange version 2 (IKEv2) daemon for IPsec. IPsec itself is a pair of protocols: Encapsulating Security Payload (ESP), which provides integrity and confidentiality; and Authentication Header (AH), which provides integrity. The IPsec protocol itself is described in .Xr ipsec 4 . .Pp In its most basic form, a flow is established between hosts and/or networks, and then Security Associations (SA) are established, which detail how the desired protection will be achieved. IPsec uses flows to determine whether to apply security services to an IP packet or not. .Xr iked 8 is used to set up flows and establish SAs automatically, by specifying .Sq ikev2 policies in .Nm (see .Sx AUTOMATIC KEYING POLICIES , below). .Pp Alternative methods of setting up flows and SAs are also possible using manual keying or automatic keying using the older ISAKMP/Oakley a.k.a. IKEv1 protocol. Manual keying is not recommended, but can be convenient for quick setups and testing. See .Xr ipsec.conf 5 and .Xr isakmpd 8 for more information about manual keying and ISAKMP support. .Sh IKED.CONF FILE FORMAT .Nm is divided into three main sections: .Bl -tag -width xxxx .It Sy Macros User-defined variables may be defined and used later, simplifying the configuration file. .It Sy Global Configuration Global settings for .Xr iked 8 . .It Sy Automatic Keying Policies Policies to set up IPsec flows and SAs automatically. .El .Pp Lines beginning with .Sq # and empty lines are regarded as comments, and ignored. Lines may be split using the .Sq \e character. .Pp Argument names not beginning with a letter, digit, or underscore must be quoted. .Pp Addresses can be specified in CIDR notation (matching netblocks), as symbolic host names, interface names, or interface group names. .Pp Additional configuration files can be included with the .Ic include keyword, for example: .Bd -literal -offset indent include "/etc/macros.conf" .Ed .Sh MACROS Macros can be defined that will later be expanded in context. Macro names must start with a letter, digit, or underscore, and may contain any of those characters. Macro names may not be reserved words (for example .Ic flow , .Ic from , .Ic esp ) . Macros are not expanded inside quotes. .Pp For example: .Bd -literal -offset indent remote_gw = "192.168.3.12" ikev2 esp from 192.168.7.0/24 to 192.168.8.0/24 peer $remote_gw .Ed .Sh GLOBAL CONFIGURATION Here are the settings that can be set globally: .Bl -tag -width xxxx .It Ic set active Set .Xr iked 8 to active mode. This is the default. .It Ic set passive Set .Xr iked 8 to passive mode. In passive mode no packets are sent to peers and no connections are initiated by .Xr iked 8 . This option is used for setups using .Xr sasyncd 8 and .Xr carp 4 to provide redundancy. iked will run in passive mode until sasyncd has determined that the host is the master and can switch to active mode. .It Ic set couple Load the negotiated security associations (SAs) and flows into the kernel. This is the default. .It Ic set decouple Don't load the negotiated SAs and flows from the kernel. This mode is only useful for testing and debugging. .It Ic set mobike Enable MOBIKE (RFC 4555) support. This is the default. MOBIKE allows the peer IP address to be changed for IKE and IPsec SAs. Currently .Xr iked 8 only supports MOBIKE when acting as a responder. .It Ic set nomobike Disables MOBIKE support. .It Ic set ocsp Ar URL Enable OCSP and set the URL of the OCSP responder. Please note that the matching responder and issuer certificates have to be placed in .Pa /etc/iked/ocsp/responder.crt and .Pa /etc/iked/ocsp/issuer.crt . .It Ic user Ar name Ar password .Xr iked 8 supports user-based authentication by tunneling the Extensible Authentication Protocol (EAP) over IKEv2. In its most basic form, the users will be authenticated against a local, integrated password database that is configured with the .Ic user lines in .Nm and the .Ar name and .Ar password arguments. Note that the password has to be specified in plain text which is required to support different challenge-based EAP methods like EAP-MD5 or EAP-MSCHAPv2. .El .Sh AUTOMATIC KEYING POLICIES This section is used to configure policies that will be used by .Xr iked 8 to set up flows and SAs automatically. Some examples of setting up automatic keying: .Bd -literal -offset 3n # Set up a VPN: # First between the gateway machines 192.168.3.1 and 192.168.3.2 # Second between the networks 10.1.1.0/24 and 10.1.2.0/24 ikev2 esp from 192.168.3.1 to 192.168.3.2 ikev2 esp from 10.1.1.0/24 to 10.1.2.0/24 peer 192.168.3.2 .Ed .Pp For incoming connections from remote peers, the policies are evaluated in sequential order, from first to last. The last matching policy decides what action is taken; if no policy matches the connection, the default action is to ignore the connection attempt or to use the .Ar default policy, if set. Please also see the .Sx EXAMPLES section for a detailed example of the policy evaluation. .Pp The first time an IKEv2 connection matches a policy, an IKE SA is created; for subsequent packets the connection is identified by the IKEv2 parameters that are stored in the SA without evaluating any policies. After the connection is closed or times out, the IKE SA is automatically removed. .Pp The commands are as follows: .Bl -tag -width xxxx .It Xo .Ic ikev2 .Op Ar name .Xc The mandatory .Ic ikev2 keyword will identify an IKEv2 automatic keying policy. .Ar name is an optional arbitrary string identifying the policy. The name should only occur once in .Nm or any included files. If omitted, a name will be generated automatically for the policy. .It Op Ar eval The .Ar eval option modifies the policy evaluation for this policy. It can be one of .Ar quick , .Ar skip or .Ar default . If a new incoming connection matches a policy with the .Ar quick option set, that policy is considered the last matching policy, and evaluation of subsequent policies is skipped. The .Ar skip option will disable evaluation of this policy for incoming connections. The .Ar default option sets the default policy and should only be specified once. .It Op Ar mode .Ar mode specifies the IKEv2 mode to use: one of .Ar passive or .Ar active . When .Ar passive is specified, .Xr iked 8 will not immediately start negotiation of this tunnel, but wait for an incoming request from the remote peer. When .Ar active is specified, negotiation will be started at once. If omitted, .Ar passive mode will be used. .It Op Ar ipcomp The keyword .Ar ipcomp specifies that .Xr ipcomp 4 , the IP Payload Compression protocol, is negotiated in addition to encapsulation. The optional compression is applied before packets are encapsulated. .It Op Ar encap .Ar encap specifies the encapsulation protocol to be used. Possible protocols are .Ar esp and .Ar ah ; the default is .Ar esp . .\" .It Op Ar tmode .\" .Ar tmode .\" describes the encapsulation mode to be used. .\" Possible modes are .\" .Ar tunnel .\" and .\" .Ar transport ; .\" the default is .\" .Ar tunnel . .It Op Ar af This policy only applies to endpoints of the specified address family which can be either .Ar inet or .Ar inet6 . Note that this only matters for IKEv2 endpoints and does not restrict the traffic selectors to negotiate flows with different address families, e.g. IPv6 flows negotiated by IPv4 endpoints. .It Ic proto Ar protocol The optional .Ic proto parameter restricts the flow to a specific IP protocol. Common protocols are .Xr icmp 4 , .Xr tcp 4 , and .Xr udp 4 . For a list of all the protocol name to number mappings used by .Xr iked 8 , see the file .Pa /etc/protocols . .It Xo .Ic from Ar src .Op Ic port Ar sport .Op Pq Ar srcnat .Ic to Ar dst .Op Ic port Ar dport .Xc Specify one or more traffic selectors for this policy which will be used to negotiate the IPsec flows between the IKEv2 peers. During the negotiation, the peers may decide to narrow a flow to a subset of the configured traffic selector networks to match the policies on each side. .Pp Each traffic selector will apply for packets with source address .Ar src and destination address .Ar dst . The keyword .Ar any will match any address (i.e. 0.0.0.0/0). If the .Ar src argument specifies a fictional source ID, the .Ar srcnat parameter can be used to specify the actual source address. This can be used in outgoing NAT/BINAT scenarios as described below. .Pp The optional .Ic port modifiers restrict the traffic selectors to the specified ports. They are only valid in conjunction with the .Xr tcp 4 and .Xr udp 4 protocols. Ports can be specified by number or by name. For a list of all port name to number mappings used by .Xr ipsecctl 8 , see the file .Pa /etc/services . .It Ic local Ar localip Ic peer Ar remote The .Ic local parameter specifies the address or FQDN of the local endpoint. Unless the gateway is multi-homed or uses address aliases, this option is generally not needed. .Pp The .Ic peer parameter specifies the address or FQDN of the remote endpoint. For host-to-host connections where .Ar dst is identical to .Ar remote , this option is generally not needed as it will be set to .Ar dst automatically. If it is not specified or if the keyword .Ar any is given, the default peer is used. .It Xo .Ic ikesa .Ic auth Ar algorithm .Ic enc Ar algorithm .Ic prf Ar algorithm .Ic group Ar group .Xc These parameters define the mode and cryptographic transforms to be used for the IKE SA negotiation, also known as phase 1. The IKE SA will be used to authenticate the machines and to set up an encrypted channel for the IKEv2 protocol. .Pp Possible values for .Ic auth , .Ic enc , .Ic prf , .Ic group , and the default proposals are described below in .Sx CRYPTO TRANSFORMS . If omitted, .Xr iked 8 will use the default proposals for the IKEv2 protocol. .Pp The keyword .Ic ikesa can be used multiple times as a delimiter between IKE SA proposals. The order of the proposals depend on the order in the configuration. The keywords .Ic auth , .Ic enc , .Ic prf and .Ic group can be used multiple times within a single proposal to configure multiple crypto transforms. .It Xo .Ic childsa .Ic auth Ar algorithm .Ic enc Ar algorithm .Ic group Ar group .Xc These parameters define the cryptographic transforms to be used for the Child SA negotiation, also known as phase 2. Each Child SA will be used to negotiate the actual IPsec SAs. The initial Child SA is always negotiated with the initial IKEv2 key exchange; additional Child SAs may be negotiated with additional Child SA key exchanges for an established IKE SA. .Pp Possible values for .Ic auth , .Ic enc , .Ic group , and the default proposals are described below in .Sx CRYPTO TRANSFORMS . If omitted, .Xr iked 8 will use the default proposals for the ESP or AH protocol. .Pp The .Ic group option will only be used to enable Perfect Forward Secrecy (PFS) for additional Child SAs exchanges that are not part of the initial key exchange. .Pp The keyword .Ic childsa can be used multiple times as a delimiter between Child SA proposals. The order of the proposals depend on the order in the configuration. The keywords .Ic auth , .Ic enc and .Ic group can be used multiple times within a single proposal to configure multiple crypto transforms. .It Ic srcid Ar string Ic dstid Ar string .Ic srcid defines an ID of type .Dq FQDN , .Dq ASN1_DN , .Dq IPV4 , .Dq IPV6 , or .Dq UFQDN that will be used by .Xr iked 8 as the identity of the local peer. If the argument is an email address (reyk@example.com), .Xr iked 8 will use UFQDN as the ID type. The ASN1_DN type will be used if the string starts with a slash .Sq / (/C=DE/../CN=10.0.0.1/emailAddress=reyk@example.com). If the argument is an IPv4 address or a compressed IPv6 address, the ID types IPV4 or IPV6 will be used. Anything else is considered to be an FQDN. .Pp If .Ic srcid is omitted, the default is to use the hostname of the local machine, see .Xr hostname 1 to set or print the hostname. .Pp .Ic dstid is similar to .Ic srcid , but instead specifies the ID to be used by the remote peer. .It Ic ikelifetime Ar time The optional .Ic ikelifetime parameter defines the IKE SA expiration timeout by the .Ar time SA was created. A zero value disables active IKE SA rekeying. This is the default. .Pp The accepted format of the .Ar time specification is described below. .It Ic lifetime Ar time Op Ic bytes Ar bytes The optional .Ic lifetime parameter defines the Child SA expiration timeout by the .Ar time SA was in use and by the number of .Ar bytes that were processed using the SA. Default values are 3 hours and 512 megabytes which means that SA will be rekeyed before reaching the time limit or 512 megabytes of data will pass through. Zero values disable rekeying. .Pp Several unit specifiers are recognized (ignoring case): .Ql m and .Ql h for minutes and hours, and .Ql K , .Ql M and .Ql G for kilo-, mega- and gigabytes accordingly. .Pp Please note that rekeying must happen at least several times a day as IPsec security heavily depends on frequent key renewals. .It Op Ar ikeauth Specify a method to be used to authenticate the remote peer. .Xr iked 8 will automatically determine a method based on public keys or certificates configured for the peer. .Ar ikeauth can be used to override this behaviour. Non-psk modes will require setting up certificates and RSA or ECDSA public keys; see .Xr iked 8 for more information. .Pp .Bl -tag -width $domain -compact -offset indent .It Ic eap Ar type Use EAP to authenticate the initiator. The only supported EAP .Ar type is currently .Ar MSCHAP-V2 . The responder will use RSA public key authentication. .It Ic ecdsa256 Use ECDSA with a 256-bit elliptic curve key and SHA2-256 for authentication. .It Ic ecdsa384 Use ECDSA with a 384-bit elliptic curve key and SHA2-384 for authentication. .It Ic ecdsa521 Use ECDSA with a 521-bit elliptic curve key and SHA2-512 for authentication. .It Ic psk Ar string Use a pre-shared key .Ar string or hex value (starting with 0x) for authentication. .It Ic rfc7427 Only use RFC 7427 signatures for authentication. RFC 7427 signatures currently only support SHA2-256 as the hash. .It Ic rsa Use RSA public key authentication with SHA1 as the hash. .El .Pp The default is to allow any signature authentication. .It Ic config Ar option address Send one or more optional configuration payloads (CP) to the peer. The configuration .Ar option can be one of the following with the expected address format: .Pp .Bl -tag -width Ds -compact -offset indent .It Ic address Ar address Assign a static address on the internal network. .It Ic address Ar address/prefix Assign a dynamic address on the internal network. The address will be assigned from an address pool with the size specified by .Ar prefix . .It Ic netmask Ar netmask The IPv4 netmask of the internal network. .It Ic name-server Ar address The DNS server address within the internal network. .It Ic netbios-server Ar address The NetBIOS name server (WINS) within the internal network. This option is provided for compatibility with legacy clients. .It Ic dhcp-server Ar address The address of an internal DHCP server for further configuration. .It Ic protected-subnet Ar address/prefix The address of the protected subnet within the internal network. .It Ic access-server Ar address The address of an internal remote access server. .El .It Ic tag Ar string Add a .Xr pf 4 tag to all packets of IPsec SAs created for this connection. This will allow matching packets for this connection by defining rules in .Xr pf.conf 5 using the .Cm tagged keyword. .Pp The following variables can be used in tags to include information from the remote peer on runtime: .Pp .Bl -tag -width $domain -compact -offset indent .It Ar $id The .Ic dstid that was proposed by the remote peer to identify itself. It will be expanded to .Ar id-value , e.g.\& .Ar FQDN/foo.example.com . To limit the size of the derived tag, .Xr iked 8 will extract the common name .Sq CN= from ASN1_DN IDs, for example .Ar ASN1_ID//C=DE/../CN=10.1.1.1/.. will be expanded to .Ar 10.1.1.1 . .It Ar $eapid For a connection using EAP, the identity (username) used by the remote peer. .It Ar $domain Extract the domain from IDs of type FQDN, UFQDN or ASN1_DN. .It Ar $name The name of the IKEv2 policy that was configured in .Nm or automatically generated by .Xr iked 8 . .El .Pp For example, if the ID is .Ar FQDN/foo.example.com or .Ar UFQDN/user@example.com , .Dq ipsec-$domain expands to .Dq ipsec-example.com . The variable expansion for the .Ar tag directive occurs only at runtime, not during configuration file parse time. .It Ic tap Ar interface Send the decapsulated IPsec traffic to the specified .Xr enc 4 .Ar interface instead of .Ar enc0 for filtering and monitoring. The traffic will be blocked if the specified .Ar interface does not exist. .El .Sh PACKET FILTERING IPsec traffic appears unencrypted on the .Xr enc 4 interface and can be filtered accordingly using the .Ox packet filter, .Xr pf 4 . The grammar for the packet filter is described in .Xr pf.conf 5 . .Pp The following components are relevant to filtering IPsec traffic: .Bl -ohang -offset indent .It external interface Interface for IKE traffic and encapsulated IPsec traffic. .It proto udp port 500 IKE traffic on the external interface. .It proto udp port 4500 IKE NAT-Traversal traffic on the external interface. .It proto ah | esp Encapsulated IPsec traffic on the external interface. .It enc0 Default interface for outgoing traffic before it's been encapsulated, and incoming traffic after it's been decapsulated. State on this interface should be interface bound; see .Xr enc 4 for further information. .It proto ipencap [tunnel mode only] IP-in-IP traffic flowing between gateways on the enc0 interface. .It tagged ipsec-example.org Match traffic of IPsec SAs using the .Ic tag keyword. .El .Pp If the filtering rules specify to block everything by default, the following rule would ensure that IPsec traffic never hits the packet filtering engine, and is therefore passed: .Bd -literal -offset indent set skip on enc0 .Ed .Pp In the following example, all traffic is blocked by default. IPsec-related traffic from gateways {192.168.3.1, 192.168.3.2} and networks {10.0.1.0/24, 10.0.2.0/24} is permitted. .Bd -literal -offset indent block on ix0 block on enc0 pass in on ix0 proto udp from 192.168.3.2 to 192.168.3.1 \e port {500, 4500} pass out on ix0 proto udp from 192.168.3.1 to 192.168.3.2 \e port {500, 4500} pass in on ix0 proto esp from 192.168.3.2 to 192.168.3.1 pass out on ix0 proto esp from 192.168.3.1 to 192.168.3.2 pass in on enc0 proto ipencap from 192.168.3.2 to 192.168.3.1 \e keep state (if-bound) pass out on enc0 proto ipencap from 192.168.3.1 to 192.168.3.2 \e keep state (if-bound) pass in on enc0 from 10.0.2.0/24 to 10.0.1.0/24 \e keep state (if-bound) pass out on enc0 from 10.0.1.0/24 to 10.0.2.0/24 \e keep state (if-bound) .Ed .Pp .Xr pf 4 has the ability to filter IPsec-related packets based on an arbitrary .Em tag specified within a ruleset. The tag is used as an internal marker which can be used to identify the packets later on. This could be helpful, for example, in scenarios where users are connecting in from differing IP addresses, or to support queue-based bandwidth control, since the enc0 interface does not support it. .Pp The following .Xr pf.conf 5 fragment uses queues for all IPsec traffic with special handling for developers and employees: .Bd -literal -offset indent queue std on ix0 bandwidth 100M queue deflt parent std bandwidth 10M default queue developers parent std bandwidth 75M queue employees parent std bandwidth 5M queue ipsec parent std bandwidth 10M pass out on ix0 proto esp set queue ipsec pass out on ix0 tagged ipsec-developers.example.com \e set queue developers pass out on ix0 tagged ipsec-employees.example.com \e set queue employees .Ed .Pp The following example assigns the tags in the .Nm configuration and also sets an alternative .Xr enc 4 device: .Bd -literal -offset indent ikev2 esp from 10.1.1.0/24 to 10.1.2.0/24 peer 192.168.3.2 \e tag ipsec-$domain tap "enc1" .Ed .Sh OUTGOING NETWORK ADDRESS TRANSLATION In some network topologies it is desirable to perform NAT on traffic leaving through the VPN tunnel. In order to achieve that, the .Ar src argument is used to negotiate the desired network ID with the peer and the .Ar srcnat parameter defines the true local subnet, so that a correct SA can be installed on the local side. .Pp For example, if the local subnet is 192.168.1.0/24 and all the traffic for a specific VPN peer should appear as coming from 10.10.10.1, the following configuration is used: .Bd -literal -offset indent ikev2 esp from 10.10.10.1 (192.168.1.0/24) to 192.168.2.0/24 \e peer 10.10.20.1 .Ed .Pp Naturally, a relevant NAT rule is required in .Xr pf.conf 5 . For the example above, this would be: .Bd -literal -offset indent match out on enc0 from 192.168.1.0/24 to 192.168.2.0/24 \e nat-to 10.10.10.1 .Ed .Pp From the peer's point of view, the local end of the VPN tunnel is declared to be 10.10.10.1 and all the traffic arrives with that source address. .Sh CRYPTO TRANSFORMS The following authentication types are permitted with the .Ic auth keyword: .Bl -column "Authentication" "Key Length" "Truncated Length" -offset indent .It Em "Authentication" Ta Em "Key Length" Ta Em "Truncated Length" .It Li hmac-md5 Ta "128 bits" Ta "96 bits" .It Li hmac-sha1 Ta "160 bits" Ta "96 bits" .It Li hmac-sha2-256 Ta "256 bits" Ta "128 bits" .It Li hmac-sha2-384 Ta "384 bits" Ta "192 bits" .It Li hmac-sha2-512 Ta "512 bits" Ta "256 bits" .El .Pp The following pseudo-random function types are permitted with the .Ic prf keyword: .Bl -column "hmac-sha2-512" "Key Length" "[IKE only]" -offset indent .It Em "PRF" Ta Em "Key Length" Ta "" .It Li hmac-md5 Ta "128 bits" Ta "[IKE only]" .It Li hmac-sha1 Ta "160 bits" Ta "[IKE only]" .It Li hmac-sha2-256 Ta "256 bits" Ta "[IKE only]" .It Li hmac-sha2-384 Ta "384 bits" Ta "[IKE only]" .It Li hmac-sha2-512 Ta "512 bits" Ta "[IKE only]" .El .Pp The following cipher types are permitted with the .Ic enc keyword: .Bl -column "chacha20-poly1305" "Key Length" "[ESP only]" -offset indent .It Em "Cipher" Ta Em "Key Length" Ta "" .It Li 3des Ta "168 bits" Ta "" .It Li aes-128 Ta "128 bits" Ta "" .It Li aes-192 Ta "192 bits" Ta "" .It Li aes-256 Ta "256 bits" Ta "" .It Li aes-128-ctr Ta "160 bits" Ta "[ESP only]" .It Li aes-192-ctr Ta "224 bits" Ta "[ESP only]" .It Li aes-256-ctr Ta "288 bits" Ta "[ESP only]" .It Li aes-128-gcm Ta "160 bits" Ta "[ESP only]" .It Li aes-192-gcm Ta "224 bits" Ta "[ESP only]" .It Li aes-256-gcm Ta "288 bits" Ta "[ESP only]" .It Li blowfish Ta "160 bits" Ta "[ESP only]" .It Li cast Ta "128 bits" Ta "[ESP only]" .It Li chacha20-poly1305 Ta "288 bits" Ta "[ESP only]" .El .Pp The following cipher types provide only authentication, not encryption: .Bl -column "chacha20-poly1305" "Key Length" "[ESP only]" -offset indent .It Li aes-128-gmac Ta "160 bits" Ta "[ESP only]" .It Li aes-192-gmac Ta "224 bits" Ta "[ESP only]" .It Li aes-256-gmac Ta "288 bits" Ta "[ESP only]" .It Li null Ta "" Ta "[ESP only]" .El .Pp 3DES requires 24 bytes to form its 168-bit key. This is because the most significant bit of each byte is used for parity. .Pp The keysize of AES-CTR is actually 128-bit. However as well as the key, a 32-bit nonce has to be supplied. Thus 160 bits of key material have to be supplied. The same applies to AES-GCM, AES-GMAC and Chacha20-Poly1305, however in the latter case the keysize is 256 bit. .Pp Using AES-GMAC or NULL with ESP will only provide authentication. This is useful in setups where AH cannot be used, e.g. when NAT is involved. .Pp The following group types are permitted with the .Ic group keyword: .Bl -column "modp1024-160" "Group" "Size" "Type" -offset indent .It Em Name Ta Em Group Ta Em Size Ta Em Type .It Li modp768 Ta grp1 Ta 768 Ta "MODP" .It Li modp1024 Ta grp2 Ta 1024 Ta "MODP" .It Li ec2n155 Ta grp3 Ta 155 Ta "EC2N [insecure]" .It Li ec2n185 Ta grp4 Ta 185 Ta "EC2N [insecure]" .It Li modp1536 Ta grp5 Ta 1536 Ta "MODP" .It Li modp2048 Ta grp14 Ta 2048 Ta "MODP" .It Li modp3072 Ta grp15 Ta 3072 Ta "MODP" .It Li modp4096 Ta grp16 Ta 4096 Ta "MODP" .It Li modp6144 Ta grp17 Ta 6144 Ta "MODP" .It Li modp8192 Ta grp18 Ta 8192 Ta "MODP" .It Li ecp256 Ta grp19 Ta 256 Ta "ECP" .It Li ecp384 Ta grp20 Ta 384 Ta "ECP" .It Li ecp521 Ta grp21 Ta 521 Ta "ECP" .It Li ecp192 Ta grp25 Ta 192 Ta "ECP" .It Li ecp224 Ta grp26 Ta 224 Ta "ECP" .It Li brainpool224 Ta grp27 Ta 224 Ta "ECP, brainpoolP224r1" .It Li brainpool256 Ta grp28 Ta 256 Ta "ECP, brainpoolP256r1" .It Li brainpool384 Ta grp29 Ta 384 Ta "ECP, brainpoolP384r1" .It Li brainpool512 Ta grp30 Ta 512 Ta "ECP, brainpoolP512r1" .It Li curve25519 Ta - Ta 256 Ta "Curve25519" .El .Pp The currently supported group types are either MODP (exponentiation groups modulo a prime), EC2N (elliptic curve groups over GF[2^N]), ECP (elliptic curve groups modulo a prime), or the non-standard Curve25519. Please note that the EC2N groups are considered as insecure and only provided for backwards compatibility. .Sh EXAMPLES The first example is intended for a server with clients connecting to .Xr iked 8 as an IPsec gateway, or IKEv2 responder, using mutual public key authentication and additional challenge-based EAP-MSCHAPv2 password authentication: .Bd -literal -offset indent user "test" "password123" ikev2 "win7" esp \e from 0.0.0.0/0 to 172.16.2.0/24 \e peer 10.0.0.0/8 local 192.168.56.0/24 \e eap "mschap-v2" \e config address 172.16.2.1 \e tag "$name-$id" .Ed .Pp The next example allows peers to authenticate using a pre-shared key .Sq foobar : .Bd -literal -offset indent ikev2 "big test" \e esp proto tcp \e from 10.0.0.0/8 port 23 to 20.0.0.0/8 port 40 \e from 192.168.1.1 to 192.168.2.2 \e peer any local any \e ikesa \e enc 3des auth hmac-sha2-256 \e group ecp256 group modp1024 \e ikesa \e enc 3des auth hmac-sha1 \e group ecp256 group modp1024 \e childsa enc aes-128 auth hmac-sha2-256 \e childsa enc aes-128 auth hmac-sha1 \e srcid host.example.com \e dstid 192.168.0.254 \e psk "foobar" .Ed .Pp The following example illustrates the last matching policy evaluation for incoming connections on an IKEv2 gateway. The peer 192.168.1.34 will always match the first policy because of the .Ar quick keyword; connections from the peers 192.168.1.3 and 192.168.1.2 will be matched by one of the last two policies; any other connections from 192.168.1.0/24 will be matched by the .Sq subnet policy; and any other connection will be matched by the .Sq catch all policy. .Bd -literal -offset indent ikev2 quick esp from 10.10.10.0/24 to 10.20.20.0/24 \e peer 192.168.1.34 ikev2 "catch all" esp from 10.0.1.0/24 to 10.0.2.0/24 \e peer any ikev2 "subnet" esp from 10.0.3.0/24 to 10.0.4.0/24 \e peer 192.168.1.0/24 ikev2 esp from 10.0.5.0/30 to 10.0.5.4/30 peer 192.168.1.2 ikev2 esp from 10.0.5.8/30 to 10.0.5.12/30 peer 192.168.1.3 .Ed .Sh SEE ALSO .Xr enc 4 , .Xr ipsec 4 , .Xr ipsec.conf 5 , .Xr pf.conf 5 , .Xr ikectl 8 , .Xr iked 8 .Sh HISTORY The .Nm file format first appeared in .Ox 4.8 . .Sh AUTHORS The .Xr iked 8 program was written by .An Reyk Floeter Aq Mt reyk@openbsd.org .