# User authentication method. Could be set multiple times and in # that case all should succeed. To enable multiple methods use # multiple auth directives. Available options: certificate, # plain, pam, radius, gssapi. # # Note that authentication methods cannot be changed with reload. # certificate: # This indicates that all connecting users must present a certificate. # # pam[gid-min=1000]: # This enabled PAM authentication of the user. The gid-min option is used # by auto-select-group option, in order to select the minimum valid group ID. # # plain[passwd=/etc/ocserv/ocpasswd] # The plain option requires specifying a password file which contains # entries of the following format. # "username:groupname1,groupname2:encoded-password" # One entry must be listed per line, and 'ocpasswd' should be used # to generate password entries. # # radius[config=/etc/radiusclient/radiusclient.conf,groupconfig=true,nas-identifier=name]: # The radius option requires specifying freeradius-client configuration # file. If the groupconfig option is set, then config-per-user will be overriden, # and all configuration will be read from radius. The supported atributes for # radius configuration are: # Group-Name, Framed-IPv6-Address, Framed-IPv6-Prefix, DNS-Server-IPv6-Address, # Framed-IP-Address, Framed-IP-Netmask, MS-Primary-DNS-Server, MS-Secondary-DNS-Server # # gssapi[keytab=/etc/key.tab,require-local-user-map=false] # The gssapi option allows to use authentication methods supported by GSSAPI, # such as Kerberos tickets with ocserv. It should be best used as an alternative # to PAM (i.e., have pam in auth and gssapi in enable-auth), to allow users with # tickets and without tickets to login. The default value for require-local-user-map # is true. auth = "pam" #auth = "pam[gid-min=1000]" #auth = "plain[passwd=./sample.passwd]" #auth = "certificate" #auth = "radius[config=/etc/radiusclient/radiusclient.conf,groupconfig=true]" # Specify alternative authentication methods that are sufficient # for authentication. That is, if set, any of the methods enabled # will be sufficient to login. #enable-auth = certificate #enable-auth = gssapi #enable-auth = "gssapi[keytab=/etc/key.tab,require-local-user-map=true]" # Accounting methods available: # pam: can only be combined with PAM authentication method, it provides # a session opened using PAM. # # radius: can be combined with any authentication method, it provides # radius accounting to available users (see also stats-report-time). # # Only one accounting method can be specified. #acct = "pam" #acct = "radius[config=/etc/radiusclient/radiusclient.conf]" # Use listen-host to limit to specific IPs or to the IPs of a provided # hostname. #listen-host = [IP|HOSTNAME] # When the server has a dynamic DNS address (that may change), # should set that to true to ask the client to resolve again on # reconnects. #listen-host-is-dyndns = true # TCP and UDP port number tcp-port = 443 udp-port = 443 # Accept connections using a socket file. It accepts HTTP # connections (i.e., without SSL/TLS unlike its TCP counterpart), # and uses it as the primary channel. That option cannot be # combined with certificate authentication. #listen-clear-file = /var/run/ocserv-conn.socket # The user the worker processes will be run as. It should be # unique (no other services run as this user). run-as-user = ocserv run-as-group = ocserv # socket file used for IPC with occtl. You only need to set that, # if you use more than a single servers. #occtl-socket-file = /var/run/occtl.socket # socket file used for server IPC (worker-main), will be appended with .PID # It must be accessible within the chroot environment (if any), so it is best # specified relatively to the chroot directory. socket-file = ocserv.sock # The default server directory. Does not require any devices present. chroot-dir = /var/lib/ocserv ### All configuration options below this line are reloaded on a SIGHUP. ### The options above, will remain unchanged. # Whether to enable seccomp/Linux namespaces worker isolation. That restricts the number of # system calls allowed to a worker process, in order to reduce damage from a # bug in the worker process. It is available on Linux systems at a performance cost. # The performance cost is roughly 2% overhead at transfer time (tested on a Linux 3.17.8). isolate-workers = true # A banner to be displayed on clients #banner = "Welcome" # Limit the number of clients. Unset or set to zero for unlimited. #max-clients = 1024 max-clients = 16 # Limit the number of identical clients (i.e., users connecting # multiple times). Unset or set to zero for unlimited. max-same-clients = 2 # When the server has a dynamic DNS address (that may change), # should set that to true to ask the client to resolve again on # reconnects. #listen-host-is-dyndns = true # Limit the number of client connections to one every X milliseconds # (X is the provided value). Set to zero for no limit. #rate-limit-ms = 100 # Stats report time. The number of seconds after which each # worker process will report its usage statistics (number of # bytes transferred etc). This is useful when accounting like # radius is in use. #stats-report-time = 360 # Keepalive in seconds keepalive = 32400 # Dead peer detection in seconds. # Note that when the client is behind a NAT this value # needs to be short enough to prevent the NAT disassociating # his UDP session from the port number. Otherwise the client # could have his UDP connection stalled, for several minutes. dpd = 90 # Dead peer detection for mobile clients. That needs to # be higher to prevent such clients being awaken too # often by the DPD messages, and save battery. # The mobile clients are distinguished from the header # 'X-AnyConnect-Identifier-DeviceType'. mobile-dpd = 1800 # MTU discovery (DPD must be enabled) try-mtu-discovery = false # The key and the certificates of the server # The key may be a file, or any URL supported by GnuTLS (e.g., # tpmkey:uuid=xxxxxxx-xxxx-xxxx-xxxx-xxxxxxxx;storage=user # or pkcs11:object=my-vpn-key;object-type=private) # # The server-cert file may contain a single certificate, or # a sorted certificate chain. # # There may be multiple server-cert and server-key directives, # but each key should correspond to the preceding certificate. server-cert = /etc/pki/ocserv/public/server.crt server-key = /etc/pki/ocserv/private/server.key # Diffie-Hellman parameters. Only needed if you require support # for the DHE ciphersuites (by default this server supports ECDHE). # Can be generated using: # certtool --generate-dh-params --outfile /path/to/dh.pem #dh-params = /path/to/dh.pem # If you have a certificate from a CA that provides an OCSP # service you may provide a fresh OCSP status response within # the TLS handshake. That will prevent the client from connecting # independently on the OCSP server. # You can update this response periodically using: # ocsptool --ask --load-cert=your_cert --load-issuer=your_ca --outfile response # Make sure that you replace the following file in an atomic way. #ocsp-response = /path/to/ocsp.der # In case PKCS #11 or TPM keys are used the PINs should be available # in files. The srk-pin-file is applicable to TPM keys only, and is the # storage root key. #pin-file = /path/to/pin.txt #srk-pin-file = /path/to/srkpin.txt # The Certificate Authority that will be used to verify # client certificates (public keys) if certificate authentication # is set. ca-cert = /etc/pki/ocserv/cacerts/ca.crt # The object identifier that will be used to read the user ID in the client # certificate. The object identifier should be part of the certificate's DN # Useful OIDs are: # CN = 2.5.4.3, UID = 0.9.2342.19200300.100.1.1 cert-user-oid = 0.9.2342.19200300.100.1.1 # The object identifier that will be used to read the user group in the # client certificate. The object identifier should be part of the certificate's # DN. Useful OIDs are: # OU (organizational unit) = 2.5.4.11 #cert-group-oid = 2.5.4.11 # The revocation list of the certificates issued by the 'ca-cert' above. # See the manual to generate an empty CRL initially. #crl = /path/to/crl.pem # Uncomment this to enable compression negotiation (LZS, LZ4). #compression = true # Set the minimum size under which a packet will not be compressed. # That is to allow low-latency for VoIP packets. The default size # is 256 bytes. Modify it if the clients typically use compression # as well of VoIP with codecs that exceed the default value. #no-compress-limit = 256 # GnuTLS priority string; note that SSL 3.0 is disabled by default # as there are no openconnect (and possibly anyconnect clients) using # that protocol. The string below does not enforce perfect forward # secrecy, in order to be compatible with legacy clients. # # Note that the most performant ciphersuites are the moment are the ones # involving AES-GCM. These are very fast in x86 and x86-64 hardware, and # in addition require no padding, thus taking full advantage of the MTU. # For that to be taken advantage of, the openconnect client must be # used, and the server must be compiled against GnuTLS 3.2.7 or later. # Use "gnutls-cli --benchmark-tls-ciphers", to see the performance # difference with AES_128_CBC_SHA1 (the default for anyconnect clients) # in your system. #tls-priorities = "NORMAL:%SERVER_PRECEDENCE:%COMPAT:-VERS-SSL3.0" tls-priorities = "@SYSTEM" # More combinations in priority strings are available, check # http://gnutls.org/manual/html_node/Priority-Strings.html # E.g., the string below enforces perfect forward secrecy (PFS) # on the main channel. #tls-priorities = "NORMAL:%SERVER_PRECEDENCE:%COMPAT:-RSA:-VERS-SSL3.0:-ARCFOUR-128" # The time (in seconds) that a client is allowed to stay connected prior # to authentication auth-timeout = 40 # The time (in seconds) that a client is allowed to stay idle (no traffic) # before being disconnected. Unset to disable. #idle-timeout = 1200 # The time (in seconds) that a mobile client is allowed to stay idle (no # traffic) before being disconnected. Unset to disable. #mobile-idle-timeout = 2400 # The time (in seconds) that a client is not allowed to reconnect after # a failed authentication attempt. min-reauth-time = 300 # Banning clients in ocserv works with a point system. IP addresses # that get a score over that configured number are banned for # min-reauth-time seconds. By default a wrong password attempt is 10 points, # a KKDCP POST is 1 point, and a connection is 1 point. Note that # due to difference processes being involved the count of points # will not be real-time precise. # # Score banning cannot be reliably used when receiving proxied connections # locally from an HTTP server (i.e., when listen-clear-file is used). # # Set to zero to disable. max-ban-score = 50 # The time (in seconds) that all score kept for a client is reset. ban-reset-time = 300 # In case you'd like to change the default points. #ban-points-wrong-password = 10 #ban-points-connection = 1 #ban-points-kkdcp = 1 # Cookie timeout (in seconds) # Once a client is authenticated he's provided a cookie with # which he can reconnect. That cookie will be invalided if not # used within this timeout value. On a user disconnection, that # cookie will also be active for this time amount prior to be # invalid. That should allow a reasonable amount of time for roaming # between different networks. cookie-timeout = 300 # Whether roaming is allowed, i.e., if true a cookie is # restricted to a single IP address and cannot be re-used # from a different IP. deny-roaming = false # ReKey time (in seconds) # ocserv will ask the client to refresh keys periodically once # this amount of seconds is elapsed. Set to zero to disable. rekey-time = 172800 # ReKey method # Valid options: ssl, new-tunnel # ssl: Will perform an efficient rehandshake on the channel allowing # a seamless connection during rekey. # new-tunnel: Will instruct the client to discard and re-establish the channel. # Use this option only if the connecting clients have issues with the ssl # option. rekey-method = ssl # Script to call when a client connects and obtains an IP. # The following parameters are passed on the environment. # REASON, USERNAME, GROUPNAME, HOSTNAME (the hostname selected by client), # DEVICE, IP_REAL (the real IP of the client), IP_LOCAL (the local IP # in the P-t-P connection), IP_REMOTE (the VPN IP of the client), # IPV6_LOCAL (the IPv6 local address if there are both IPv4 and IPv6 # assigned), IPV6_REMOVE (the IPv6 remote address), and # ID (a unique numeric ID); REASON may be "connect" or "disconnect". # The disconnect script will receive the additional values: STATS_BYTES_IN, # STATS_BYTES_OUT, STATS_DURATION that contain a 64-bit counter of the bytes # output from the tun device, and the duration of the session in seconds. #connect-script = /usr/bin/ocserv-script #disconnect-script = /usr/bin/ocserv-script # UTMP # Register the connected clients to utmp. This will allow viewing # the connected clients using the command 'who'. #use-utmp = true # Whether to enable support for the occtl tool (i.e., either through D-BUS, # or via a unix socket). use-occtl = true # PID file. It can be overriden in the command line. pid-file = /var/run/ocserv.pid # Set the protocol-defined priority (SO_PRIORITY) for packets to # be sent. That is a number from 0 to 6 with 0 being the lowest # priority. Alternatively this can be used to set the IP Type- # Of-Service, by setting it to a hexadecimal number (e.g., 0x20). # This can be set per user/group or globally. #net-priority = 3 # Set the VPN worker process into a specific cgroup. This is Linux # specific and can be set per user/group or globally. #cgroup = "cpuset,cpu:test" # # Network settings # # The name to use for the tun device device = vpns # Whether the generated IPs will be predictable, i.e., IP stays the # same for the same user when possible. predictable-ips = true # The default domain to be advertised default-domain = example.com # The pool of addresses that leases will be given from. If the leases # are given via Radius, or via the explicit-ip? per-user config option then # these network values should contain a network with at least a single # address that will remain under the full control of ocserv (that is # to be able to assign the local part of the tun device address). #ipv4-network = 192.168.1.0 #ipv4-netmask = 255.255.255.0 # An alternative way of specifying the network: #ipv4-network = 192.168.1.0/24 # The IPv6 subnet that leases will be given from. #ipv6-network = fda9:4efe:7e3b:03ea::/64 # The advertized DNS server. Use multiple lines for # multiple servers. # dns = fc00::4be0 #dns = 192.168.1.2 # The NBNS server (if any) #nbns = 192.168.1.3 # The domains over which the provided DNS should be used. Use # multiple lines for multiple domains. #split-dns = example.com # Prior to leasing any IP from the pool ping it to verify that # it is not in use by another (unrelated to this server) host. # Only set to true, if there can be occupied addresses in the # IP range for leases. ping-leases = false # Use this option to enforce an MTU value to the incoming # connections. Unset to use the default MTU of the TUN device. #mtu = 1420 # Unset to enable bandwidth restrictions (in bytes/sec). The # setting here is global, but can also be set per user or per group. #rx-data-per-sec = 40000 #tx-data-per-sec = 40000 # The number of packets (of MTU size) that are available in # the output buffer. The default is low to improve latency. # Setting it higher will improve throughput. #output-buffer = 10 # Routes to be forwarded to the client. If you need the # client to forward routes to the server, you may use the # config-per-user/group or even connect and disconnect scripts. # # To set the server as the default gateway for the client just # comment out all routes from the server, or use the special keyword # 'default'. #route = 10.10.10.0/255.255.255.0 #route = 192.168.0.0/255.255.0.0 #route = fef4:db8:1000:1001::/64 # Subsets of the routes above that will not be routed by # the server. #no-route = 192.168.5.0/255.255.255.0 # Groups that a client is allowed to select from. # A client may belong in multiple groups, and in certain use-cases # it is needed to switch between them. For these cases the client can # select prior to authentication. Add multiple entries for multiple groups. # The group may be followed by a user-friendly name in brackets. #select-group = group1 #select-group = group2[My special group] # The name of the (virtual) group that if selected it would assign the user # to its default group. #default-select-group = DEFAULT # Instead of specifying manually all the allowed groups, you may instruct # ocserv to scan all available groups and include the full list. #auto-select-group = true # Configuration files that will be applied per user connection or # per group. Each file name on these directories must match the username # or the groupname. # The options allowed in the configuration files are dns, nbns, # ipv?-network, ipv4-netmask, rx/tx-per-sec, iroute, route, # net-priority, deny-roaming, no-udp, user-profile, and cgroup. # # Note that the 'iroute' option allows to add routes on the server # based on a user or group. The syntax depends on the input accepted # by the commands route-add-cmd and route-del-cmd (see below). The no-udp # is a boolean option (e.g., no-udp = true), and will prevent a UDP session # for that specific user or group. #config-per-user = /etc/ocserv/config-per-user/ #config-per-group = /etc/ocserv/config-per-group/ # When config-per-xxx is specified and there is no group or user that # matches, then utilize the following configuration. #default-user-config = /etc/ocserv/defaults/user.conf #default-group-config = /etc/ocserv/defaults/group.conf # The system command to use to setup a route. %{R} will be replaced with the # route/mask and %{D} with the (tun) device. # # The following example is from linux systems. %R should be something # like 192.168.2.0/24 (the argument of iroute). #route-add-cmd = "ip route add %{R} dev %{D}" #route-del-cmd = "ip route delete %{R} dev %{D}" # This option allows to forward a proxy. The special keywords '%{U}' # and '%{G}', if present will be replaced by the username and group name. #proxy-url = http://example.com/ #proxy-url = http://example.com/%{U}/ # This option allows you to specify a URL location where a client can # post using MS-KKDCP, and the message will be forwarded to the provided # KDC server. That is a translation URL between HTTP and Kerberos. # In MIT kerberos you'll need to add in realms: # EXAMPLE.COM = { # kdc = https://ocserv.example.com/kerberos # http_anchors = FILE:/etc/ocserv-ca.pem # } # This option is available if ocserv is compiled with GSSAPI support. #kkdcp = SERVER-PATH KERBEROS-REALM PROTOCOL@SERVER:PORT #kkdcp = /kerberos EXAMPLE.COM udp@127.0.0.1:88 #kkdcp = /kerberos-tcp EXAMPLE.COM tcp@127.0.0.1:88 # # The following options are for (experimental) AnyConnect client # compatibility. # This option must be set to true to support legacy CISCO clients. # A side effect of this option is that it will no longer be required # for clients to present their certificate on every connection. # That is they may resume a cookie without presenting a certificate # (when certificate authentication is used). cisco-client-compat = true # Client profile xml. A sample file exists in doc/profile.xml. # It is required by some of the CISCO clients. # This file must be accessible from inside the worker's chroot. user-profile = profile.xml # Binary files that may be downloaded by the CISCO client. Must # be within any chroot environment. Normally you don't need # to use this option. #binary-files = /path/to/binaries #Advanced options # Option to allow sending arbitrary custom headers to the client after # authentication and prior to VPN tunnel establishment. You shouldn't # need to use this option normally; if you do and you think that # this may help others, please send your settings and reason to # the openconnect mailing list. The special keywords '%{U}' # and '%{G}', if present will be replaced by the username and group name. #custom-header = "X-My-Header: hi there"