.TH STRONGSWAN.CONF 5 "2013-01-25" "@IPSEC_VERSION@" "strongSwan" .SH NAME strongswan.conf \- strongSwan configuration file .SH DESCRIPTION While the .IR ipsec.conf (5) configuration file is well suited to define IPsec related configuration parameters, it is not useful for other strongSwan applications to read options from this file. The file is hard to parse and only .I ipsec starter is capable of doing so. As the number of components of the strongSwan project is continually growing, a more flexible configuration file was needed, one that is easy to extend and can be used by all components. With strongSwan 4.2.1 .IR strongswan.conf (5) was introduced which meets these requirements. .SH SYNTAX The format of the strongswan.conf file consists of hierarchical .B sections and a list of .B key/value pairs in each section. Each section has a name, followed by C-Style curly brackets defining the section body. Each section body contains a set of subsections and key/value pairs: .PP .EX settings := (section|keyvalue)* section := name { settings } keyvalue := key = value\\n .EE .PP Values must be terminated by a newline. .PP Comments are possible using the \fB#\fP-character, but be careful: The parser implementation is currently limited and does not like brackets in comments. .PP Section names and keys may contain any printable character except: .PP .EX . { } # \\n \\t space .EE .PP An example file in this format might look like this: .PP .EX a = b section-one { somevalue = asdf subsection { othervalue = xxx } # yei, a comment yetanother = zz } section-two { x = 12 } .EE .PP Indentation is optional, you may use tabs or spaces. .SH INCLUDING FILES Using the .B include statement it is possible to include other files into strongswan.conf, e.g. .PP .EX include /some/path/*.conf .EE .PP If the file name is not an absolute path, it is considered to be relative to the directory of the file containing the include statement. The file name may include shell wildcards (see .IR sh (1)). Also, such inclusions can be nested. .PP Sections loaded from included files .I extend previously loaded sections; already existing values are .IR replaced . It is important to note that settings are added relative to the section the include statement is in. .PP As an example, the following three files result in the same final config as the one given above: .PP .EX a = b section-one { somevalue = before include include include.conf } include other.conf include.conf: # settings loaded from this file are added to section-one # the following replaces the previous value somevalue = asdf subsection { othervalue = yyy } yetanother = zz other.conf: # this extends section-one and subsection section-one { subsection { # this replaces the previous value othervalue = xxx } } section-two { x = 12 } .EE .SH READING VALUES Values are accessed using a dot-separated section list and a key. With reference to the example above, accessing .B section-one.subsection.othervalue will return .BR xxx . .SH DEFINED KEYS The following keys are currently defined (using dot notation). The default value (if any) is listed in brackets after the key. .SS attest section .TP .BR attest.database Path to database with file measurement information .TP .BR attest.load Plugins to load in ipsec attest tool .SS charon section .TP .BR charon.block_threshold " [5]" Maximum number of half-open IKE_SAs for a single peer IP .TP .BR charon.cisco_unity " [no] Send Cisco Unity vendor ID payload (IKEv1 only) .TP .BR charon.close_ike_on_child_failure " [no]" Close the IKE_SA if setup of the CHILD_SA along with IKE_AUTH failed .TP .BR charon.cookie_threshold " [10]" Number of half-open IKE_SAs that activate the cookie mechanism .TP .BR charon.dns1 .TQ .BR charon.dns2 DNS servers assigned to peer via configuration payload (CP) .TP .BR charon.dos_protection " [yes]" Enable Denial of Service protection using cookies and aggressiveness checks .TP .BR charon.filelog Section to define file loggers, see LOGGER CONFIGURATION .TP .BR charon.flush_auth_cfg " [no]" If enabled objects used during authentication (certificates, identities etc.) are released to free memory once an IKE_SA is established. Enabling this might conflict with plugins that later need access to e.g. the used certificates. .TP .BR charon.fragment_size " [512]" Maximum size (in bytes) of a sent fragment when using the proprietary IKEv1 fragmentation extension. .TP .BR charon.half_open_timeout " [30]" Timeout in seconds for connecting IKE_SAs (also see IKE_SA_INIT DROPPING). .TP .BR charon.hash_and_url " [no]" Enable hash and URL support .TP .BR charon.i_dont_care_about_security_and_use_aggressive_mode_psk " [no]" If enabled responders are allowed to use IKEv1 Aggressive Mode with pre-shared keys, which is discouraged due to security concerns (offline attacks on the openly transmitted hash of the PSK) .TP .BR charon.ignore_routing_tables A space-separated list of routing tables to be excluded from route lookups .TP .BR charon.ikesa_limit " [0]" Maximum number of IKE_SAs that can be established at the same time before new connection attempts are blocked .TP .BR charon.ikesa_table_segments " [1]" Number of exclusively locked segments in the hash table .TP .BR charon.ikesa_table_size " [1]" Size of the IKE_SA hash table .TP .BR charon.inactivity_close_ike " [no]" Whether to close IKE_SA if the only CHILD_SA closed due to inactivity .TP .BR charon.init_limit_half_open " [0]" Limit new connections based on the current number of half open IKE_SAs (see IKE_SA_INIT DROPPING). .TP .BR charon.init_limit_job_load " [0]" Limit new connections based on the number of jobs currently queued for processing (see IKE_SA_INIT DROPPING). .TP .BR charon.install_routes " [yes]" Install routes into a separate routing table for established IPsec tunnels .TP .BR charon.install_virtual_ip " [yes]" Install virtual IP addresses .TP .BR charon.install_virtual_ip_on The name of the interface on which virtual IP addresses should be installed. If not specified the addresses will be installed on the outbound interface. .TP .BR charon.interfaces_ignore A comma-separated list of network interfaces that should be ignored, if .B charon.interfaces_use is specified this option has no effect. .TP .BR charon.interfaces_use A comma-separated list of network interfaces that should be used by charon. All other interfaces are ignored. .TP .BR charon.keep_alive " [20s]" NAT keep alive interval .TP .BR charon.load Plugins to load in the IKEv2 daemon charon .TP .BR charon.max_packet " [10000]" Maximum packet size accepted by charon .TP .BR charon.multiple_authentication " [yes]" Enable multiple authentication exchanges (RFC 4739) .TP .BR charon.nbns1 .TQ .BR charon.nbns2 WINS servers assigned to peer via configuration payload (CP) .TP .BR charon.port " [500]" UDP port used locally. If set to 0 a random port will be allocated. .TP .BR charon.port_nat_t " [4500]" UDP port used locally in case of NAT-T. If set to 0 a random port will be allocated. Has to be different from .BR charon.port , otherwise a random port will be allocated. .TP .BR charon.process_route " [yes]" Process RTM_NEWROUTE and RTM_DELROUTE events .TP .BR charon.receive_delay " [0]" Delay in ms for receiving packets, to simulate larger RTT .TP .BR charon.receive_delay_response " [yes]" Delay response messages .TP .BR charon.receive_delay_request " [yes]" Delay request messages .TP .BR charon.receive_delay_type " [0]" Specific IKEv2 message type to delay, 0 for any .TP .BR charon.replay_window " [32]" Size of the AH/ESP replay window, in packets. .TP .BR charon.retransmit_base " [1.8]" Base to use for calculating exponential back off, see IKEv2 RETRANSMISSION .TP .BR charon.retransmit_timeout " [4.0] Timeout in seconds before sending first retransmit .TP .BR charon.retransmit_tries " [5]" Number of times to retransmit a packet before giving up .TP .BR charon.retry_initiate_interval " [0]" Interval to use when retrying to initiate an IKE_SA (e.g. if DNS resolution failed), 0 to disable retries. .TP .BR charon.reuse_ikesa " [yes] Initiate CHILD_SA within existing IKE_SAs .TP .BR charon.routing_table Numerical routing table to install routes to .TP .BR charon.routing_table_prio Priority of the routing table .TP .BR charon.send_delay " [0]" Delay in ms for sending packets, to simulate larger RTT .TP .BR charon.send_delay_response " [yes]" Delay response messages .TP .BR charon.send_delay_request " [yes]" Delay request messages .TP .BR charon.send_delay_type " [0]" Specific IKEv2 message type to delay, 0 for any .TP .BR charon.send_vendor_id " [no] Send strongSwan vendor ID payload .TP .BR charon.syslog Section to define syslog loggers, see LOGGER CONFIGURATION .TP .BR charon.threads " [16]" Number of worker threads in charon .SS charon.plugins subsection .TP .BR charon.plugins.android_log.loglevel " [1]" Loglevel for logging to Android specific logger .TP .BR charon.plugins.attr Section to specify arbitrary attributes that are assigned to a peer via configuration payload (CP) .TP .BR charon.plugins.certexpire.csv.cron Cron style string specifying CSV export times .TP .BR charon.plugins.certexpire.csv.local strftime(3) format string for the CSV file name to export local certificates to .TP .BR charon.plugins.certexpire.csv.remote strftime(3) format string for the CSV file name to export remote certificates to .TP .BR charon.plugins.certexpire.csv.separator " [,]" CSV field separator .TP .BR charon.plugins.certexpire.csv.empty_string String to use in empty intermediate CA fields .TP .BR charon.plugins.certexpire.csv.format " [%d:%m:%Y]" strftime(3) format string to export expiration dates as .TP .BR charon.plugins.certexpire.csv.fixed_fields " [yes]" Use a fixed intermediate CA field count .TP .BR charon.plugins.coupling.file File to store coupling list to .TP .BR charon.plugins.coupling.hash " [sha1]" Hashing algorithm to fingerprint coupled certificates .TP .BR charon.plugins.coupling.max " [1]" Maximum number of coupling entries to create .TP .BR charon.plugins.dhcp.force_server_address " [no]" Always use the configured server address. This might be helpful if the DHCP server runs on the same host as strongSwan, and the DHCP daemon does not listen on the loopback interface. In that case the server cannot be reached via unicast (or even 255.255.255.255) as that would be routed via loopback. Setting this option to yes and configuring the local broadcast address (e.g. 192.168.0.255) as server address might work. .TP .BR charon.plugins.dhcp.identity_lease " [no]" Derive user-defined MAC address from hash of IKEv2 identity .TP .BR charon.plugins.dhcp.server " [255.255.255.255]" DHCP server unicast or broadcast IP address .TP .BR charon.plugins.duplicheck.enable " [yes]" Enable duplicheck plugin (if loaded) .TP .BR charon.plugins.eap-aka.request_identity " [yes]" .TP .BR charon.plugins.eap-aka-3ggp2.seq_check .TP .BR charon.plugins.eap-dynamic.preferred The preferred EAP method(s) to be used. If it is not given the first registered method will be used initially. If a comma separated list is given the methods are tried in the given order before trying the rest of the registered methods. .TP .BR charon.plugins.eap-dynamic.prefer_user " [no]" If enabled the EAP methods proposed in an EAP-Nak message sent by the peer are preferred over the methods registered locally. .TP .BR charon.plugins.eap-gtc.backend " [pam]" XAuth backend to be used for credential verification .TP .BR charon.plugins.eap-peap.fragment_size " [1024]" Maximum size of an EAP-PEAP packet .TP .BR charon.plugins.eap-peap.max_message_count " [32]" Maximum number of processed EAP-PEAP packets (0 = no limit) .TP .BR charon.plugins.eap-peap.include_length " [no]" Include length in non-fragmented EAP-PEAP packets .TP .BR charon.plugins.eap-peap.phase2_method " [mschapv2]" Phase2 EAP client authentication method .TP .BR charon.plugins.eap-peap.phase2_piggyback " [no]" Phase2 EAP Identity request piggybacked by server onto TLS Finished message .TP .BR charon.plugins.eap-peap.phase2_tnc " [no]" Start phase2 EAP TNC protocol after successful client authentication .TP .BR charon.plugins.eap-peap.request_peer_auth " [no]" Request peer authentication based on a client certificate .TP .BR charon.plugins.eap-radius.accounting " [no]" Send RADIUS accounting information to RADIUS servers. .TP .BR charon.plugins.eap-radius.class_group " [no]" Use the .I class attribute sent in the RADIUS-Accept message as group membership information that is compared to the groups specified in the .B rightgroups option in .B ipsec.conf (5). .TP .BR charon.plugins.eap-radius.dae.enable " [no]" Enables support for the Dynamic Authorization Extension (RFC 5176) .TP .BR charon.plugins.eap-radius.dae.listen " [0.0.0.0]" Address to listen for DAE messages from the RADIUS server .TP .BR charon.plugins.eap-radius.dae.port " [3799]" Port to listen for DAE requests .TP .BR charon.plugins.eap-radius.dae.secret Shared secret used to verify/sign DAE messages .TP .BR charon.plugins.eap-radius.eap_start " [no]" Send EAP-Start instead of EAP-Identity to start RADIUS conversation .TP .BR charon.plugins.eap-radius.filter_id " [no]" If the RADIUS .I tunnel_type attribute with value .B ESP is received, use the .I filter_id attribute sent in the RADIUS-Accept message as group membership information that is compared to the groups specified in the .B rightgroups option in .B ipsec.conf (5). .TP .BR charon.plugins.eap-radius.forward.ike_to_radius RADIUS attributes to be forwarded from IKEv2 to RADIUS (can be defined by name or attribute number, a colon can be used to specify vendor-specific attributes, e.g. Reply-Message, or 11, or 36906:12). .TP .BR charon.plugins.eap-radius.forward.radius_to_ike Same as .B charon.plugins.eap-radius.forward.ike_to_radius but from RADIUS to IKEv2, a strongSwan specific private notify (40969) is used to transmit the attributes. .TP .BR charon.plugins.eap-radius.id_prefix Prefix to EAP-Identity, some AAA servers use a IMSI prefix to select the EAP method .TP .BR charon.plugins.eap-radius.nas_identifier " [strongSwan]" NAS-Identifier to include in RADIUS messages .TP .BR charon.plugins.eap-radius.port " [1812]" Port of RADIUS server (authentication) .TP .BR charon.plugins.eap-radius.secret Shared secret between RADIUS and NAS .TP .BR charon.plugins.eap-radius.server IP/Hostname of RADIUS server .TP .BR charon.plugins.eap-radius.servers Section to specify multiple RADIUS servers. The .BR nas_identifier , .BR secret , .B sockets and .B port (or .BR auth_port ) options can be specified for each server. A server's IP/Hostname can be configured using the .B address option. The .BR acct_port " [1813]" option can be used to specify the port used for RADIUS accounting. For each RADIUS server a priority can be specified using the .BR preference " [0]" option. .TP .BR charon.plugins.eap-radius.sockets " [1]" Number of sockets (ports) to use, increase for high load .TP .BR charon.plugins.eap-sim.request_identity " [yes]" .TP .BR charon.plugins.eap-simaka-sql.database .TP .BR charon.plugins.eap-simaka-sql.remove_used " [no]" .TP .BR charon.plugins.eap-tls.fragment_size " [1024]" Maximum size of an EAP-TLS packet .TP .BR charon.plugins.eap-tls.max_message_count " [32]" Maximum number of processed EAP-TLS packets (0 = no limit) .TP .BR charon.plugins.eap-tls.include_length " [yes]" Include length in non-fragmented EAP-TLS packets .TP .BR charon.plugins.eap-tnc.max_message_count " [10]" Maximum number of processed EAP-TNC packets (0 = no limit) .TP .BR charon.plugins.eap-tnc.protocol " [tnccs-1.1]" IF-TNCCS protocol version to be used (tnccs-1.1, tnccs-2.0, tnccs-dynamic) .TP .BR charon.plugins.eap-ttls.fragment_size " [1024]" Maximum size of an EAP-TTLS packet .TP .BR charon.plugins.eap-ttls.max_message_count " [32]" Maximum number of processed EAP-TTLS packets (0 = no limit) .TP .BR charon.plugins.eap-ttls.include_length " [yes]" Include length in non-fragmented EAP-TTLS packets .TP .BR charon.plugins.eap-ttls.phase2_method " [md5]" Phase2 EAP client authentication method .TP .BR charon.plugins.eap-ttls.phase2_piggyback " [no]" Phase2 EAP Identity request piggybacked by server onto TLS Finished message .TP .BR charon.plugins.eap-ttls.phase2_tnc " [no]" Start phase2 EAP TNC protocol after successful client authentication .TP .BR charon.plugins.eap-ttls.request_peer_auth " [no]" Request peer authentication based on a client certificate .TP .BR charon.plugins.ha.fifo_interface " [yes]" .TP .BR charon.plugins.ha.heartbeat_delay " [1000]" .TP .BR charon.plugins.ha.heartbeat_timeout " [2100]" .TP .BR charon.plugins.ha.local .TP .BR charon.plugins.ha.monitor " [yes]" .TP .BR charon.plugins.ha.pools .TP .BR charon.plugins.ha.remote .TP .BR charon.plugins.ha.resync " [yes]" .TP .BR charon.plugins.ha.secret .TP .BR charon.plugins.ha.segment_count " [1]" .TP .BR charon.plugins.led.activity_led .TP .BR charon.plugins.led.blink_time " [50]" .TP .BR charon.plugins.kernel-klips.ipsec_dev_count " [4]" Number of ipsecN devices .TP .BR charon.plugins.kernel-klips.ipsec_dev_mtu " [0]" Set MTU of ipsecN device .TP .BR charon.plugins.load-tester Section to configure the load-tester plugin, see LOAD TESTS .TP .BR charon.plugins.radattr.dir Directory where RADIUS attributes are stored in client-ID specific files. .TP .BR charon.plugins.radattr.message_id " [-1]" Attributes are added to all IKE_AUTH messages by default (-1), or only to the IKE_AUTH message with the given IKEv2 message ID. .TP .BR charon.plugins.resolve.file " [/etc/resolv.conf]" File where to add DNS server entries .TP .BR charon.plugins.resolve.resolvconf.iface_prefix " [lo.inet.ipsec.]" Prefix used for interface names sent to resolvconf(8). The nameserver address is appended to this prefix to make it unique. The result has to be a valid interface name according to the rules defined by resolvconf. Also, it should have a high priority according to the order defined in interface-order(5). .TP .BR charon.plugins.socket-default.set_source " [yes]" Set source address on outbound packets, if possible. .TP .BR charon.plugins.sql.database Database URI for charons SQL plugin .TP .BR charon.plugins.sql.loglevel " [-1]" Loglevel for logging to SQL database .TP .BR charon.plugins.stroke.ignore_missing_ca_basic_constraint " [no]" Treat certificates in ipsec.d/cacerts and ipsec.conf ca sections as CA certificates even if they don't contain a CA basic constraint. .TP .BR charon.plugins.stroke.max_concurrent " [4]" Maximum number of stroke messages handled concurrently .TP .BR charon.plugins.tnccs-11.max_message_size " [45000]" Maximum size of a PA-TNC message (XML & Base64 encoding) .TP .BR charon.plugins.tnccs-20.max_batch_size " [65522]" Maximum size of a PB-TNC batch (upper limit via PT-EAP = 65529) .TP .BR charon.plugins.tnccs-20.max_message_size " [65490]" Maximum size of a PA-TNC message (upper limit via PT-EAP = 65497) .TP .BR charon.plugins.tnc-ifmap.device_name Unique name of strongSwan as a PEP and/or PDP device .TP .BR charon.plugins.tnc-ifmap.key_file Concatenated client certificate and private key .TP .BR charon.plugins.tnc-ifmap.password Authentication password of strongSwan MAP client .TP .BR charon.plugins.tnc-ifmap.server_cert Certificate of MAP server .TP .BR charon.plugins.tnc-ifmap.ssl_passphrase Passphrase protecting the private key .TP .BR charon.plugins.tnc-ifmap.username Authentication username of strongSwan MAP client .TP .BR charon.plugins.tnc-imc.dlclose " [yes]" Unload IMC after use .TP .BR charon.plugins.tnc-imc.preferred_language " [en]" Preferred language for TNC recommendations .TP .BR charon.plugins.tnc-imv.dlclose " [yes]" Unload IMV after use .TP .BR charon.plugins.tnc-pdp.method " [ttls]" EAP tunnel method to be used .TP .BR charon.plugins.tnc-pdp.port " [1812]" RADIUS server port the strongSwan PDP is listening on .TP .BR charon.plugins.tnc-pdp.secret Shared RADIUS secret between strongSwan PDP and NAS .TP .BR charon.plugins.tnc-pdp.server Name of the strongSwan PDP as contained in the AAA certificate .TP .BR charon.plugins.updown.dns_handler " [no]" Whether the updown script should handle DNS serves assigned via IKEv1 Mode Config or IKEv2 Config Payloads (if enabled they can't be handled by other plugins, like resolve) .TP .BR charon.plugins.whitelist.enable " [yes]" Enable loaded whitelist plugin .TP .BR charon.plugins.xauth-eap.backend " [radius]" EAP plugin to be used as backend for XAuth credential verification .TP .BR charon.plugins.xauth-pam.pam_service " [login]" PAM service to be used for authentication .SS libstrongswan section .TP .BR libstrongswan.cert_cache " [yes]" Whether relations in validated certificate chains should be cached in memory .TP .BR libstrongswan.crypto_test.bench " [no]" .TP .BR libstrongswan.crypto_test.bench_size " [1024]" .TP .BR libstrongswan.crypto_test.bench_time " [50]" .TP .BR libstrongswan.crypto_test.on_add " [no]" Test crypto algorithms during registration .TP .BR libstrongswan.crypto_test.on_create " [no]" Test crypto algorithms on each crypto primitive instantiation .TP .BR libstrongswan.crypto_test.required " [no]" Strictly require at least one test vector to enable an algorithm .TP .BR libstrongswan.crypto_test.rng_true " [no]" Whether to test RNG with TRUE quality; requires a lot of entropy .TP .BR libstrongswan.dh_exponent_ansi_x9_42 " [yes]" Use ANSI X9.42 DH exponent size or optimum size matched to cryptographical strength .TP .BR libstrongswan.ecp_x_coordinate_only " [yes]" Compliance with the errata for RFC 4753 .TP .BR libstrongswan.host_resolver.max_threads " [3]" Maximum number of concurrent resolver threads (they are terminated if unused) .TP .BR libstrongswan.host_resolver.min_threads " [0]" Minimum number of resolver threads to keep around .TP .BR libstrongswan.integrity_test " [no]" Check daemon, libstrongswan and plugin integrity at startup .TP .BR libstrongswan.leak_detective.detailed " [yes]" Includes source file names and line numbers in leak detective output .TP .BR libstrongswan.leak_detective.usage_threshold " [10240]" Threshold in bytes for leaks to be reported (0 to report all) .TP .BR libstrongswan.processor.priority_threads Subsection to configure the number of reserved threads per priority class see JOB PRIORITY MANAGEMENT .TP .BR libstrongswan.x509.enforce_critical " [yes]" Discard certificates with unsupported or unknown critical extensions .SS libstrongswan.plugins subsection .TP .BR libstrongswan.plugins.attr-sql.database Database URI for attr-sql plugin used by charon .TP .BR libstrongswan.plugins.attr-sql.lease_history " [yes]" Enable logging of SQL IP pool leases .TP .BR libstrongswan.plugins.gcrypt.quick_random " [no]" Use faster random numbers in gcrypt; for testing only, produces weak keys! .TP .BR libstrongswan.plugins.openssl.engine_id " [pkcs11]" ENGINE ID to use in the OpenSSL plugin .TP .BR libstrongswan.plugins.pkcs11.modules List of available PKCS#11 modules .TP .BR libstrongswan.plugins.pkcs11.load_certs " [yes]" Whether to load certificates from tokens .TP .BR libstrongswan.plugins.pkcs11.reload_certs " [no]" Reload certificates from all tokens if charon receives a SIGHUP .TP .BR libstrongswan.plugins.pkcs11.use_dh " [no]" Whether the PKCS#11 modules should be used for DH and ECDH (see use_ecc option) .TP .BR libstrongswan.plugins.pkcs11.use_ecc " [no]" Whether the PKCS#11 modules should be used for ECDH and ECDSA public key operations. ECDSA private keys can be used regardless of this option .TP .BR libstrongswan.plugins.pkcs11.use_hasher " [no]" Whether the PKCS#11 modules should be used to hash data .TP .BR libstrongswan.plugins.pkcs11.use_pubkey " [no]" Whether the PKCS#11 modules should be used for public key operations, even for keys not stored on tokens .TP .BR libstrongswan.plugins.pkcs11.use_rng " [no]" Whether the PKCS#11 modules should be used as RNG .TP .BR libstrongswan.plugins.random.random " [@DEV_RANDOM@]" File to read random bytes from, instead of @DEV_RANDOM@ .TP .BR libstrongswan.plugins.random.urandom " [@DEV_URANDOM@]" File to read pseudo random bytes from, instead of @DEV_URANDOM@ .SS libtnccs section .TP .BR libtnccs.tnc_config " [/etc/tnc_config]" TNC IMC/IMV configuration directory .SS libimcv section .TP .BR libimcv.assessment_result " [yes]" Whether IMVs send a standard IETF Assessment Result attribute .TP .BR libimcv.debug_level " [1]" Debug level for a stand-alone libimcv library .TP .BR libimcv.stderr_quiet " [no]" Disable output to stderr with a stand-alone libimcv library .TP .BR libimcv.os_info.name Manually set the name of the client OS (e.g. Ubuntu) .TP .BR libimcv.os_info.version Manually set the version of the client OS (e.g. 12.04 i686) .SS libimcv plugins section .TP .BR libimcv.plugins.imc-attestation.aik_blob AIK encrypted private key blob file .TP .BR libimcv.plugins.imc-attestation.aik_cert AIK certificate file .TP .BR libimcv.plugins.imc-attestation.aik_key AIK public key file .TP .BR libimcv.plugins.imv-attestation.nonce_len " [20]" DH nonce length .TP .BR libimcv.plugins.imv-attestation.use_quote2 " [yes]" Use Quote2 AIK signature instead of Quote signature .TP .BR libimcv.plugins.imv-attestation.cadir Path to directory with AIK cacerts .TP .BR libimcv.plugins.imv-attestation.database Path to database with file measurement information .TP .BR libimcv.plugins.imv-attestation.dh_group " [ecp256]" Preferred Diffie-Hellman group .TP .BR libimcv.plugins.imv-attestation.hash_algorithm " [sha256]" Preferred measurement hash algorithm .TP .BR libimcv.plugins.imv-attestation.min_nonce_len " [0]" DH minimum nonce length .TP .BR libimcv.plugins.imv-attestation.remediation_uri URI pointing to attestation remediation instructions .TP .BR libimcv.plugins.imc-os.push_info " [yes]" Send operating system info without being prompted .TP .BR libimcv.plugins.imv-os.database Database URI for the database that stores operating system information .TP .BR libimcv.plugins.imv-os.remediation_uri URI pointing to operating system remediation instructions .TP .BR libimcv.plugins.imc-scanner.push_info " [yes]" Send open listening ports without being prompted .TP .BR libimcv.plugins.imv-scanner.closed_port_policy " [yes]" By default all ports must be closed (yes) or can be open (no) .TP .BR libimcv.plugins.imv-scanner.remediation_uri URI pointing to scanner remediation instructions .TP .BR libimcv.plugins.imv-scanner.tcp_ports List of TCP ports that can be open or must be closed .TP .BR libimcv.plugins.imv-scanner.udp_ports List of UDP ports that can be open or must be closed .TP .BR libimcv.plugins.imc-test.additional_ids " [0]" Number of additional IMC IDs .TP .BR libimcv.plugins.imc-test.command " [none]" Command to be sent to the Test IMV .TP .BR libimcv.plugins.imc-test.dummy_size " [0]" Size of dummy attribute to be sent to the Test IMV (0 = disabled) .TP .BR libimcv.plugins.imc-test.retry " [no]" Do a handshake retry .TP .BR libimcv.plugins.imc-test.retry_command Command to be sent to the Test IMV in the handshake retry .TP .BR libimcv.plugins.imv-test.remediation_uri URI pointing to test remediation instructions .TP .BR libimcv.plugins.imv-test.rounds " [0]" Number of IMC-IMV retry rounds .SS libtls section .TP .BR libtls.cipher List of TLS encryption ciphers .TP .BR libtls.key_exchange List of TLS key exchange methods .TP .BR libtls.mac List of TLS MAC algorithms .TP .BR libtls.suites List of TLS cipher suites .SS manager section .TP .BR manager.database Credential database URI for manager .TP .BR manager.debug " [no]" Enable debugging in manager .TP .BR manager.load Plugins to load in manager .TP .BR manager.socket FastCGI socket of manager, to run it statically .TP .BR manager.threads " [10]" Threads to use for request handling .TP .BR manager.timeout " [15m]" Session timeout for manager .SS mediation client section .TP .BR medcli.database Mediation client database URI .TP .BR medcli.dpd " [5m]" DPD timeout to use in mediation client plugin .TP .BR medcli.rekey " [20m]" Rekeying time on mediation connections in mediation client plugin .SS mediation server section .TP .BR medsrv.database Mediation server database URI .TP .BR medsrv.debug " [no]" Debugging in mediation server web application .TP .BR medsrv.dpd " [5m]" DPD timeout to use in mediation server plugin .TP .BR medsrv.load Plugins to load in mediation server plugin .TP .BR medsrv.password_length " [6]" Minimum password length required for mediation server user accounts .TP .BR medsrv.rekey " [20m]" Rekeying time on mediation connections in mediation server plugin .TP .BR medsrv.socket Run Mediation server web application statically on socket .TP .BR medsrv.threads " [5]" Number of thread for mediation service web application .TP .BR medsrv.timeout " [15m]" Session timeout for mediation service .SS openac section .TP .BR openac.load Plugins to load in ipsec openac tool .SS pacman section .TP .BR pacman.database Database URI for the database that stores the package information .SS pki section .TP .BR pki.load Plugins to load in ipsec pki tool .SS pool section .TP .BR pool.load Plugins to load in ipsec pool tool .SS scepclient section .TP .BR scepclient.load Plugins to load in ipsec scepclient tool .SS starter section .TP .BR starter.load Plugins to load in starter .TP .BR starter.load_warning " [yes]" Disable charon plugin load option warning .SH LOGGER CONFIGURATION The options described below provide a much more flexible way to configure loggers for the IKEv2 daemon charon than using the .B charondebug option in .BR ipsec.conf (5). .PP .B Please note that if any loggers are specified in strongswan.conf, .B charondebug does not have any effect. .PP There are currently two types of loggers defined: .TP .B File loggers Log directly to a file and are defined by specifying the full path to the file as subsection in the .B charon.filelog section. To log to the console the two special filenames .BR stdout " and " stderr can be used. .TP .B Syslog loggers Log into a syslog facility and are defined by specifying the facility to log to as the name of a subsection in the .B charon.syslog section. The following facilities are currently supported: .BR daemon " and " auth . .PP Multiple loggers can be defined for each type with different log verbosity for the different subsystems of the daemon. .SS Options .TP .BR charon.filelog..default " [1]" .TQ .BR charon.syslog..default Specifies the default loglevel to be used for subsystems for which no specific loglevel is defined. .TP .BR charon.filelog.. " []" .TQ .BR charon.syslog.. Specifies the loglevel for the given subsystem. .TP .BR charon.filelog..append " [yes]" If this option is enabled log entries are appended to the existing file. .TP .BR charon.filelog..flush_line " [no]" Enabling this option disables block buffering and enables line buffering. .TP .BR charon.filelog..ike_name " [no]" .TQ .BR charon.syslog..ike_name Prefix each log entry with the connection name and a unique numerical identifier for each IKE_SA. .TP .BR charon.filelog..time_format Prefix each log entry with a timestamp. The option accepts a format string as passed to .BR strftime (3). .TP .BR charon.syslog.identifier Global identifier used for an .BR openlog (3) call, prepended to each log message by syslog. If not configured, .BR openlog (3) is not called, so the value will depend on system defaults (often the program name). .SS Subsystems .TP .B dmn Main daemon setup/cleanup/signal handling .TP .B mgr IKE_SA manager, handling synchronization for IKE_SA access .TP .B ike IKE_SA .TP .B chd CHILD_SA .TP .B job Jobs queueing/processing and thread pool management .TP .B cfg Configuration management and plugins .TP .B knl IPsec/Networking kernel interface .TP .B net IKE network communication .TP .B asn Low-level encoding/decoding (ASN.1, X.509 etc.) .TP .B enc Packet encoding/decoding encryption/decryption operations .TP .B tls libtls library messages .TP .B esp libipsec library messages .TP .B lib libstrongwan library messages .TP .B tnc Trusted Network Connect .TP .B imc Integrity Measurement Collector .TP .B imv Integrity Measurement Verifier .TP .B pts Platform Trust Service .SS Loglevels .TP .B -1 Absolutely silent .TP .B 0 Very basic auditing logs, (e.g. SA up/SA down) .TP .B 1 Generic control flow with errors, a good default to see whats going on .TP .B 2 More detailed debugging control flow .TP .B 3 Including RAW data dumps in Hex .TP .B 4 Also include sensitive material in dumps, e.g. keys .SS Example .PP .EX charon { filelog { /var/log/charon.log { time_format = %b %e %T append = no default = 1 } stderr { ike = 2 knl = 3 ike_name = yes } } syslog { # enable logging to LOG_DAEMON, use defaults daemon { } # minimalistic IKE auditing logging to LOG_AUTHPRIV auth { default = -1 ike = 0 } } } .EE .SH JOB PRIORITY MANAGEMENT Some operations in the IKEv2 daemon charon are currently implemented synchronously and blocking. Two examples for such operations are communication with a RADIUS server via EAP-RADIUS, or fetching CRL/OCSP information during certificate chain verification. Under high load conditions, the thread pool may run out of available threads, and some more important jobs, such as liveness checking, may not get executed in time. .PP To prevent thread starvation in such situations job priorities were introduced. The job processor will reserve some threads for higher priority jobs, these threads are not available for lower priority, locking jobs. .SS Implementation Currently 4 priorities have been defined, and they are used in charon as follows: .TP .B CRITICAL Priority for long-running dispatcher jobs. .TP .B HIGH INFORMATIONAL exchanges, as used by liveness checking (DPD). .TP .B MEDIUM Everything not HIGH/LOW, including IKE_SA_INIT processing. .TP .B LOW IKE_AUTH message processing. RADIUS and CRL fetching block here .PP Although IKE_SA_INIT processing is computationally expensive, it is explicitly assigned to the MEDIUM class. This allows charon to do the DH exchange while other threads are blocked in IKE_AUTH. To prevent the daemon from accepting more IKE_SA_INIT requests than it can handle, use IKE_SA_INIT DROPPING. .PP The thread pool processes jobs strictly by priority, meaning it will consume all higher priority jobs before looking for ones with lower priority. Further, it reserves threads for certain priorities. A priority class having reserved .I n threads will always have .I n threads available for this class (either currently processing a job, or waiting for one). .SS Configuration To ensure that there are always enough threads available for higher priority tasks, threads must be reserved for each priority class. .TP .BR libstrongswan.processor.priority_threads.critical " [0]" Threads reserved for CRITICAL priority class jobs .TP .BR libstrongswan.processor.priority_threads.high " [0]" Threads reserved for HIGH priority class jobs .TP .BR libstrongswan.processor.priority_threads.medium " [0]" Threads reserved for MEDIUM priority class jobs .TP .BR libstrongswan.processor.priority_threads.low " [0]" Threads reserved for LOW priority class jobs .PP Let's consider the following configuration: .PP .EX libstrongswan { processor { priority_threads { high = 1 medium = 4 } } } .EE .PP With this configuration, one thread is reserved for HIGH priority tasks. As currently only liveness checking and stroke message processing is done with high priority, one or two threads should be sufficient. .PP The MEDIUM class mostly processes non-blocking jobs. Unless your setup is experiencing many blocks in locks while accessing shared resources, threads for one or two times the number of CPU cores is fine. .PP It is usually not required to reserve threads for CRITICAL jobs. Jobs in this class rarely return and do not release their thread to the pool. .PP The remaining threads are available for LOW priority jobs. Reserving threads does not make sense (until we have an even lower priority). .SS Monitoring To see what the threads are actually doing, invoke .IR "ipsec statusall" . Under high load, something like this will show up: .PP .EX worker threads: 2 or 32 idle, 5/1/2/22 working, job queue: 0/0/1/149, scheduled: 198 .EE .PP From 32 worker threads, .IP 2 are currently idle. .IP 5 are running CRITICAL priority jobs (dispatching from sockets, etc.). .IP 1 is currently handling a HIGH priority job. This is actually the thread currently providing this information via stroke. .IP 2 are handling MEDIUM priority jobs, likely IKE_SA_INIT or CREATE_CHILD_SA messages. .IP 22 are handling LOW priority jobs, probably waiting for an EAP-RADIUS response while processing IKE_AUTH messages. .PP The job queue load shows how many jobs are queued for each priority, ready for execution. The single MEDIUM priority job will get executed immediately, as we have two spare threads reserved for MEDIUM class jobs. .SH IKE_SA_INIT DROPPING If a responder receives more connection requests per seconds than it can handle, it does not make sense to accept more IKE_SA_INIT messages. And if they are queued but can't get processed in time, an answer might be sent after the client has already given up and restarted its connection setup. This additionally increases the load on the responder. .PP To limit the responder load resulting from new connection attempts, the daemon can drop IKE_SA_INIT messages just after reception. There are two mechanisms to decide if this should happen, configured with the following options: .TP .BR charon.init_limit_half_open " [0]" Limit based on the number of half open IKE_SAs. Half open IKE_SAs are SAs in connecting state, but not yet established. .TP .BR charon.init_limit_job_load " [0]" Limit based on the number of jobs currently queued for processing (sum over all job priorities). .PP The second limit includes load from other jobs, such as rekeying. Choosing a good value is difficult and depends on the hardware and expected load. .PP The first limit is simpler to calculate, but includes the load from new connections only. If your responder is capable of negotiating 100 tunnels/s, you might set this limit to 1000. The daemon will then drop new connection attempts if generating a response would require more than 10 seconds. If you are allowing for a maximum response time of more than 30 seconds, consider adjusting the timeout for connecting IKE_SAs .RB ( charon.half_open_timeout ). A responder, by default, deletes an IKE_SA if the initiator does not establish it within 30 seconds. Under high load, a higher value might be required. .SH LOAD TESTS To do stability testing and performance optimizations, the IKEv2 daemon charon provides the load-tester plugin. This plugin allows one to setup thousands of tunnels concurrently against the daemon itself or a remote host. .PP .B WARNING: Never enable the load-testing plugin on productive systems. It provides preconfigured credentials and allows an attacker to authenticate as any user. .SS Options .TP .BR charon.plugins.load-tester.addrs Subsection that contains key/value pairs with address pools (in CIDR notation) to use for a specific network interface e.g. eth0 = 10.10.0.0/16 .TP .BR charon.plugins.load-tester.addrs_prefix " [16]" Network prefix length to use when installing dynamic addresses. If set to -1 the full address is used (i.e. 32 or 128) .TP .BR charon.plugins.load-tester.ca_dir Directory to load (intermediate) CA certificates from .TP .BR charon.plugins.load-tester.child_rekey " [600]" Seconds to start CHILD_SA rekeying after setup .TP .BR charon.plugins.load-tester.delay " [0]" Delay between initiatons for each thread .TP .BR charon.plugins.load-tester.delete_after_established " [no]" Delete an IKE_SA as soon as it has been established .TP .BR charon.plugins.load-tester.digest " [sha1]" Digest algorithm used when issuing certificates .TP .BR charon.plugins.load-tester.dpd_delay " [0]" DPD delay to use in load test .TP .BR charon.plugins.load-tester.dynamic_port " [0]" Base port to be used for requests (each client uses a different port) .TP .BR charon.plugins.load-tester.eap_password " [default-pwd]" EAP secret to use in load test .TP .BR charon.plugins.load-tester.enable " [no]" Enable the load testing plugin .TP .BR charon.plugins.load-tester.fake_kernel " [no]" Fake the kernel interface to allow load-testing against self .TP .BR charon.plugins.load-tester.ike_rekey " [0]" Seconds to start IKE_SA rekeying after setup .TP .BR charon.plugins.load-tester.init_limit " [0]" Global limit of concurrently established SAs during load test .TP .BR charon.plugins.load-tester.initiator " [0.0.0.0]" Address to initiate from .TP .BR charon.plugins.load-tester.initiators " [0]" Number of concurrent initiator threads to use in load test .TP .BR charon.plugins.load-tester.initiator_auth " [pubkey]" Authentication method(s) the intiator uses .TP .BR charon.plugins.load-tester.initiator_id Initiator ID used in load test .TP .BR charon.plugins.load-tester.initiator_match Initiator ID to to match against as responder .TP .BR charon.plugins.load-tester.initiator_tsi Traffic selector on initiator side, as proposed by initiator .TP .BR charon.plugins.load-tester.initiator_tsr Traffic selector on responder side, as proposed by initiator .TP .BR charon.plugins.load-tester.iterations " [1]" Number of IKE_SAs to initiate by each initiator in load test .TP .BR charon.plugins.load-tester.issuer_cert Path to the issuer certificate (if not configured a hard-coded value is used) .TP .BR charon.plugins.load-tester.issuer_key Path to private key that is used to issue certificates (if not configured a hard-coded value is used) .TP .BR charon.plugins.load-tester.pool Provide INTERNAL_IPV4_ADDRs from a named pool .TP .BR charon.plugins.load-tester.preshared_key " [default-psk]" Preshared key to use in load test .TP .BR charon.plugins.load-tester.proposal " [aes128-sha1-modp768]" IKE proposal to use in load test .TP .BR charon.plugins.load-tester.responder " [127.0.0.1]" Address to initiation connections to .TP .BR charon.plugins.load-tester.responder_auth " [pubkey]" Authentication method(s) the responder uses .TP .BR charon.plugins.load-tester.responder_id Responder ID used in load test .TP .BR charon.plugins.load-tester.responder_tsi " [initiator_tsi]" Traffic selector on initiator side, as narrowed by responder .TP .BR charon.plugins.load-tester.responder_tsr " [initiator_tsr]" Traffic selector on responder side, as narrowed by responder .TP .BR charon.plugins.load-tester.request_virtual_ip " [no]" Request an INTERNAL_IPV4_ADDR from the server .TP .BR charon.plugins.load-tester.shutdown_when_complete " [no]" Shutdown the daemon after all IKE_SAs have been established .TP .BR charon.plugins.load-tester.version " [0]" IKE version to use (0 means use IKEv2 as initiator and accept any version as responder) .SS Configuration details For public key authentication, the responder uses the .B \(dqCN=srv, OU=load-test, O=strongSwan\(dq identity. For the initiator, each connection attempt uses a different identity in the form .BR "\(dqCN=c1-r1, OU=load-test, O=strongSwan\(dq" , where the first number inidicates the client number, the second the authentication round (if multiple authentication is used). .PP For PSK authentication, FQDN identities are used. The server uses .BR srv.strongswan.org , the client uses an identity in the form .BR c1-r1.strongswan.org . .PP For EAP authentication, the client uses a NAI in the form .BR 100000000010001@strongswan.org . .PP To configure multiple authentication, concatenate multiple methods using, e.g. .EX initiator_auth = pubkey|psk|eap-md5|eap-aka .EE .PP The responder uses a hardcoded certificate based on a 1024-bit RSA key. This certificate additionally serves as CA certificate. A peer uses the same private key, but generates client certificates on demand signed by the CA certificate. Install the Responder/CA certificate on the remote host to authenticate all clients. .PP To speed up testing, the load tester plugin implements a special Diffie-Hellman implementation called modpnull. By setting .EX proposal = aes128-sha1-modpnull .EE this wicked fast DH implementation is used. It does not provide any security at all, but allows one to run tests without DH calculation overhead. .SS Examples .PP In the simplest case, the daemon initiates IKE_SAs against itself using the loopback interface. This will actually establish double the number of IKE_SAs, as the daemon is initiator and responder for each IKE_SA at the same time. Installation of IPsec SAs would fails, as each SA gets installed twice. To simulate the correct behavior, a fake kernel interface can be enabled which does not install the IPsec SAs at the kernel level. .PP A simple loopback configuration might look like this: .PP .EX charon { # create new IKE_SAs for each CHILD_SA to simulate # different clients reuse_ikesa = no # turn off denial of service protection dos_protection = no plugins { load-tester { # enable the plugin enable = yes # use 4 threads to initiate connections # simultaneously initiators = 4 # each thread initiates 1000 connections iterations = 1000 # delay each initiation in each thread by 20ms delay = 20 # enable the fake kernel interface to # avoid SA conflicts fake_kernel = yes } } } .EE .PP This will initiate 4000 IKE_SAs within 20 seconds. You may increase the delay value if your box can not handle that much load, or decrease it to put more load on it. If the daemon starts retransmitting messages your box probably can not handle all connection attempts. .PP The plugin also allows one to test against a remote host. This might help to test against a real world configuration. A connection setup to do stress testing of a gateway might look like this: .PP .EX charon { reuse_ikesa = no threads = 32 plugins { load-tester { enable = yes # 10000 connections, ten in parallel initiators = 10 iterations = 1000 # use a delay of 100ms, overall time is: # iterations * delay = 100s delay = 100 # address of the gateway remote = 1.2.3.4 # IKE-proposal to use proposal = aes128-sha1-modp1024 # use faster PSK authentication instead # of 1024bit RSA initiator_auth = psk responder_auth = psk # request a virtual IP using configuration # payloads request_virtual_ip = yes # enable CHILD_SA every 60s child_rekey = 60 } } } .EE .SH IKEv2 RETRANSMISSION Retransmission timeouts in the IKEv2 daemon charon can be configured globally using the three keys listed below: .PP .RS .nf .BR charon.retransmit_base " [1.8]" .BR charon.retransmit_timeout " [4.0]" .BR charon.retransmit_tries " [5]" .fi .RE .PP The following algorithm is used to calculate the timeout: .PP .EX relative timeout = retransmit_timeout * retransmit_base ^ (n-1) .EE .PP Where .I n is the current retransmission count. .PP Using the default values, packets are retransmitted in: .TS l r r --- lB r r. Retransmission Relative Timeout Absolute Timeout 1 4s 4s 2 7s 11s 3 13s 24s 4 23s 47s 5 42s 89s giving up 76s 165s .TE .SH FILES /etc/strongswan.conf .SH SEE ALSO ipsec.conf(5), ipsec.secrets(5), ipsec(8) .SH HISTORY Written for the .UR http://www.strongswan.org strongSwan project .UE by Tobias Brunner, Andreas Steffen and Martin Willi.