---------------------------- strongSwan - Configuration ---------------------------- Contents -------- 1. Overview 2. Quickstart 2.1 Site-to-Site case 2.2 Host-to-Host case 2.3 Four Tunnel case 2.4 Four Tunnel case the elegant way with source routing 2.5 Roadwarrior case 2.6 Roadwarrior case with virtual IP 3. Generating X.509 certificates and CRLs with OpenSSL 3.1 Generating a CA certificate 3.2 Generating a host or user certificate 3.3 Generating a CRL 3.4 Revoking a certificate 4. Configuring the connections - ipsec.conf 4.1 Configuring my side 4.2 Multiple certificates 4.3 Configuring the peer side using CA certificates 4.4 Handling Virtual IPs and wildcard subnets 4.5 Protocol and port selectors 4.6 IPsec policies based on wildcards 4.7 IPsec policies based on CA certificates 4.8 Sending certificate requests 4.9 IPsec policies based on group attributes 5. Configuring certificates and CRLs 5.1 Installing CA certificates 5.2 Installing optional Certificate Revocation Lists (CRLs) 5.3 Dynamic update of certificates and CRLs 5.4 Local caching of CRLs 5.5 Online Certificate Status Protocol (OCSP) 5.6 CRL policy 5.7 Configuring the peer side using locally stored certificates 6. Configuring the private keys - ipsec.secrets 6.1 Loading private key files in PKCS#1 format 6.2 Entering passphrases interactively 6.3 Multiple private keys 7. Configuring CA properties - ipsec.conf 8. Smartcard support 8.1 Configuring a smartcard-based connection 8.2 Entering the PIN code 8.3 PIN-pad equipped smartcard readers 8.4 Configuring a smartcard using pkcs15-init 8.5 PKCS#1 proxy functions 9. Configuring the clients 9.1 strongSwan 9.2 PGPnet 9.3 Safenet/Soft-Remote 9.4 SSH Sentinel 9.5 Windows 2000/XP 10. Monitoring functions 11. Firewall support functions 11.1 Environment variables in the updown script 11.2 Sample Linux 2.4 updown script for iptables 11.3 Sample Linux 2.6 updown script for iptables < 1.3.5 11.4 Sample Linux 2.6 updown script for iptables-1.3.5 (NEW) 12. Authentication with raw RSA public keys 13. Authentication with OpenPGP certificates 13.1 OpenPGP certificates 13.2 OpenPGP private keys 13.3 Monitoring functions 13.4 Suppression of certificate request messages 14. Additional features 14.1 Authentication and encryption algorithms 14.2 NAT traversal 14.3 Dead peer detection 14.4 IKE Mode Config 15. Copyright statement and acknowledgements 1. Overview -------- strongSwan is an OpenSource IPsec solution for the Linux operating system and currently supports the following features: * runs both on Linux 2.4 (KLIPS) and Linux 2.6 (native IPsec) kernels. * strong 3DES, AES, Serpent, Twofish, or Blowfish encryption. * Authentication based on X.509 certificates or preshared secrets. * IPsec policies based on wildcards or intermediate CAs. * Powerful and flexible IPsec policies based on group attributes. * Retrieval of Certificate Revocation Lists (CRLs) via HTTP or LDAP. * Local caching of fetched CRLs * Full support of the Online Certificate Status Protocol (OCSP, RFC 2560). * CA management functions including OCSP and CRL URIs and default LDAP server. * Optional storage of RSA private keys on smartcards or USB crypto tokens * Standardized PKCS#11 interface with optional proxy functions serving external applications (disc encryption, etc.). * NAT-Traversal (RFC 3947) * Support of Virtual IPs via static configuratin and IKE Mode Config * Support of Delete SA and informational Notification messages. * Dead Peer Detection (DPD, RFC 3706) Compatibility has successfully been tested with peers running the following IPsec clients: FreeS/WAN, Openswan, SafeNet/SoftRemote, NCP Secure Entry Client, SonicWALL Global VPN Client, The GreenBow, Microsoft Windows 2000/XP, etc. Furthermore, interoperability with the following VPN gateways has been demonstrated during the IPsec 2001 Conference in Paris: Cisco IOS Routers, Cisco PIX firewall, Cisco VPN3000, Nortel Contivity VPN Switch, NetScreen (FreeS/WAN as responder only), OpenBSD with isakmpd, Netasq, Netcelo, and 6WIND. Potentially any IPsec implementation with X.509 certificate support can be made to cooperate with strongSwan. The latest addition has been the successful interoperability with the Check Point VPN-1 NG gateway. 2. Quickstart ---------- In the following examples we assume for reasons of clarity that left designates the local host and that right is the remote host. Certificates for users, hosts and gateways are issued by a ficticious strongSwan CA. How to generate private keys and certificates using OpenSSL will be explained in section 3. The CA certificate "strongswanCert.pem" must be present on all VPN end points in order to be able to authenticate the peers. 2.1 Site-to-site case ----------------- In this scenario two security gateways moon and sun will connect the two subnets moon-net and sun-net with each other through a VPN tunnel set up between the two gateways: 10.1.0.0/16 -- | 192.168.0.1 | === | 192.168.0.2 | -- 10.2.0.0/16 moon-net moon sun sun-net Configuration on gateway moon: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/moonCert.pem /etc/ipsec.secrets: : RSA moonKey.pem "" /etc/ipsec.conf: conn net-net left=%defaultroute leftsubnet=10.1.0.0/16 leftcert=moonCert.pem right=192.168.0.2 rightsubnet=10.2.0.0/16 rightid="C=CH, O=Linux strongSwan, CN=sun.strongswan.org" auto=start Configuration on gateway sun: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/sunCert.pem /etc/ipsec.secrets: : RSA sunKey.pem "" /etc/ipsec.conf: conn net-net left=%defaultroute leftsubnet=10.2.0.0/16 leftcert=sunCert.pem right=192.168.0.1 rightsubnet=10.1.0.0/16 rightid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" auto=start 2.2 Host-to-host case ----------------- This is a setup between two single hosts which don't have a subnet behind them. Although IPsec transport mode would be sufficient for host-to-host connections we will use the default IPsec tunnel mode. | 192.168.0.1 | === | 192.168.0.2 | moon sun Configuration on host moon: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/moonCert.pem /etc/ipsec.secrets: : RSA moonKey.pem "" /etc/ipsec.conf: conn host-host left=%defaultroute leftcert=moonCert.pem right=192.168.0.2 rightid="C=CH, O=Linux strongSwan, CN=sun.strongswan.org" auto=start Configuration on host sun: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/sunCert.pem /etc/ipsec.secrets: : RSA sunKey.pem "" /etc/ipsec.conf: conn host-host left=%defaultroute leftcert=sunCert.pem right=192.168.0.1 rightid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" auto=start 2.3 Four Tunnel case ---------------- In a site-to-site setup a system administrator logged into the local gateway often would like to access the peer gateway or a server in the subnet behind the peer gateway over a secure IPsec tunnel.Since IP packets leaving a gateway via the outer network interface carry the IP address of this NIC, four IPsec Security Associations (SAs) must be set up to achieve full connectivity. The example below shows how this can be done without much additional typing work , using the "also" macro which includes connection definitions defined farther down in the ipsec.conf file. 10.1.0.0/16 -- | 192.168.0.1 | === | 192.168.0.2 | -- 10.2.0.0/16 moon-net moon sun sun-net Configuration on gateway moon: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/moonCert.pem /etc/ipsec.secrets: : RSA moonKey.pem "" /etc/ipsec.conf: conn net-net leftsubnet=10.1.0.0/16 rightsubnet=10.2.0.0/16 also host-host conn net-host leftsubnet=10.1.0.0/16 also host-host conn host-net rightsubnet=10.2.0.0/16 also host-host conn host-host left=%defaultroute leftcert=moonCert.pem right=192.168.0.2 rightid="C=CH, O=Linux strongSwan, CN=sun.strongswan.org" auto=start Configuration on gateway sun: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/sunCert.pem /etc/ipsec.secrets: : RSA sunKey.pem "" /etc/ipsec.conf: conn net-net leftsubnet=10.2.0.0/16 rightsubnet=10.1.0.0/16 also=host-host conn net-host leftsubnet=10.2.0.0/16 also=host-host conn host-net rightsubnet=10.1.0.0/16 also=host-host conn host-host left=%defaultroute leftcert=sunCert.pem right=192.168.0.1 rightid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" auto=start 2.4 The four tunnel case the elegant way with source routing -------------------------------------------------------- As you certainly agree, the full four tunnel case described in the previous section becomes quite complex. If we could force the source address of the IP packets leaving the gateway through the outer interface to take on the IP address of the inner interface then we could use the single subnet-to-subnet tunnel from section 2.1. Such a setup becomes possible if we use the source routing capabilites of the ip route command that is already used by strongSwan's updown scripts. 10.1.0.0/16 -- | 192.168.0.1 | === | 192.168.0.2 | -- 10.2.0.0/16 moon-net moon sun sun-net If we assume that the inner IP address of gateway moon is 10.1.0.1 and the inner IP address of gateway sun is 10.2.0.1 then the insertion of the parameter leftsourceip=10.1.0.1 in the connection definition of moon and leftsourceip=10.2.0.1 on sun, respectively, will install source routing on both gateways. As a result the command ping 10.2.0.1 executed on moon will leave the gateway with a source address of 10.1.0.1 and will therefore take the net-net IPsec tunnel. Configuration on gateway moon: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/moonCert.pem /etc/ipsec.secrets: : RSA moonKey.pem "" /etc/ipsec.conf: conn net-net left=%defaultroute leftsourceip=10.1.0.1 leftsubnet=10.1.0.0/16 leftcert=moonCert.pem right=192.168.0.2 rightsubnet=10.2.0.0/16 rightid="C=CH, O=Linux strongSwan, CN=sun.strongswan.org" auto=start Configuration on gateway sun: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/sunCert.pem /etc/ipsec.secrets: : RSA sunKey.pem "" /etc/ipsec.conf: conn net-net left=%defaultroute leftsubnet=10.2.0.0/16 leftsourceip=10.2.0.1 leftcert=sunCert.pem right=192.168.0.1 rightsubnet=10.1.0.0/16 rightid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" auto=start 2.5 Roadwarrior case ---------------- This is a very common case where a strongSwan gateway serves an arbitrary number of remote VPN clients usually having dynamic IP addresses. 10.1.0.0/16 -- | 192.168.0.1 | === | x.x.x.x | moon-net moon carol Configuration on gateway moon: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/moonCert.pem /etc/ipsec.secrets: : RSA moonKey.pem "" /etc/ipsec.conf: conn rw left=%defaultroute leftsubnet=10.1.0.0/16 leftcert=moonCert.pem right=%any auto=add Configuration on roadwarrior carol: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/carolCert.pem /etc/ipsec.secrets: : RSA carolKey.pem "" /etc/ipsec.conf: conn home left=%defaultroute leftcert=carolCert.pem right=192.168.0.1 rightsubnet=10.1.0.0/16 rightid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" auto=start 2.6 Roadwarrior case with virtual IP -------------------------------- Roadwarriors usually have dynamic IP addresses assigned by the ISP they are currently attached to. In order to simplify the routing from moon-net back to the remote access client carol it would be desirable if the roadwarrior had an inner IP address chosen from a pre-assigned pool. 10.1.0.0/16 -- | 192.168.0.1 | === | x.x.x.x | -- 10.3.0.1 moon-net moon carol virtual IP This virtual IP address can be assigned to a strongSwan roadwarrior by adding the parameter leftsourceip=10.3.0.1 to the roadwarrior's ipsec.conf. Of course the virtual IP of each roadwarrior must be distinct. In our example it is chosen from the address pool rightsubnetwithin=10.3.0.0/16 which can be added to the gateway's ipsec.conf so that a single connection definition can handle multiple roadwarriors. Configuration on gateway moon: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/moonCert.pem /etc/ipsec.secrets: : RSA moonKey.pem "" /etc/ipsec.conf: conn rw left=%defaultroute leftsubnet=10.1.0.0/16 leftcert=moonCert.pem right=%any rightsubnetwithin=10.3.0.0/16 auto=add Configuration on roadwarrior carol: /etc/ipsec.d/cacerts/strongswanCert.pem /etc/ipsec.d/certs/carolCert.pem /etc/ipsec.secrets: : RSA carolKey.pem "" /etc/ipsec.conf: conn home left=%defaultroute leftsourceip=10.3.0.1 leftcert=carolCert.pem right=192.168.0.1 rightsubnet=10.1.0.0/16 rightid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" auto=start 3. Generating certificates and CRLs with OpenSSL --------------------------------------------- This section is not a full-blown tutorial on how to use OpenSSL. It just lists a few points that are relevant if you want to generate your own certificates and CRLs for use with strongSwan. 3.1 Generating a CA certificate --------------------------- The OpenSSL statement openssl req -x509 -days 1460 -newkey rsa:2048 \ -keyout strongswanKey.pem -out strongswanCert.pem creates a 2048 bit RSA private key strongswanKey.pem and a self-signed CA certificate strongswanCert.pem with a validity of 4 years (1460 days). openssl x509 -in cert.pem -noout -text lists the properties of a X.509 certificate cert.pem. It allows you to verify whether the configuration defaults in openssl.cnf have been inserted correctly. If you prefer the CA certificate to be in binary DER format then the following command achieves this transformation: openssl x509 -in strongswanCert.pem -outform DER -out strongswanCert.der The directory /etc/ipsec.d/cacerts contains all required CA certificates either in binary DER or in base64 PEM format. Irrespective of the file suffix, Pluto "automagically" determines the correct format. 3.2 Generating a host or user certificate ------------------------------------- The OpenSSL statement openssl req -newkey rsa:1024 -keyout hostKey.pem \ -out hostReq.pem generates a 1024 bit RSA private key hostKey.pem and a certificate request hostReq.pem which has to be signed by the CA. If you want to add a subjectAltName field to the host certificate you must edit the OpenSSL configuration file openssl.cnf and add the following line in the [ usr_cert ] section: subjectAltName=DNS:moon.strongswan.org if you want to identify the host by its Fully Qualified Domain Name (FQDN ), or subjectAltName=IP:192.168.0.1 if you want the ID to be of type IPV4_ADDR. Of course you could include both ID types with subjectAltName=DNS:moon.strongswan.org,IP:192.168.0.1 but the use of an IP address for the identification of a host should be discouraged anyway. For user certificates the appropriate ID type is USER_FQDN which can be specified as subjectAltName=email:carol@strongswan.org or if the user's e-mail address is part of the subject's distinguished name subjectAltName=email:copy Now the certificate request can be signed by the CA with the command openssl ca -in hostReq.pem -days 730 -out hostCert.pem -notext If you omit the -days option then the default_days value (365 days) specified in openssl.cnf is used. The -notext option avoids that a human readable listing of the certificate is prepended to the base64 encoded certificate body. If you want to use the dynamic CRL fetching feature described in section 4.7 then you may include one or several crlDistributionPoints in your end certificates. This can be done in the [ usr_cert ] section of the openssl.cnf configuration file: crlDistributionPoints= @crl_dp [ crl_dp ] URI.1="http://crl.strongswan.org/strongswan.crl" URI.2="ldap://ldap.strongswan.org/cn=strongSwan Root CA, o=Linux strongSwan , c=CH?certificateRevocationList" If you have only a single http distribution point then the short form crlDistributionPoints="URI:http://crl.strongswan.org/strongswan.crl" also works. Due to a known bug in OpenSSL this notation fails with ldap URIs. Usually a Windows-based VPN client needs its private key, its host or user certificate, and the CA certificate. The most convenient way to load this information is to put everything into a PKCS#12 file: openssl pkcs12 -export -inkey carolKey.pem \ -in carolCert.pem -name "carol" \ -certfile strongswanCert.pem -caname "strongSwan Root CA" \ -out carolCert.p12 3.3 Generating a CRL ---------------- An empty CRL that is signed by the CA can be generated with the command openssl ca -gencrl -crldays 15 -out crl.pem If you omit the -crldays option then the default_crl_days value (30 days) specified in openssl.cnf is used. If you prefer the CRL to be in binary DER format then this conversion can be achieved with openssl crl -in crl.pem -outform DER -out cert.crl The directory /etc/ipsec.d/crls contains all CRLs either in binary DER or in base64 PEM format. Irrespective of the file suffix, Pluto "automagically" determines the correct format. 3.4 Revoking a certificate ---------------------- A specific host certificate stored in the file host.pem is revoked with the command openssl ca -revoke host.pem Next the CRL file must be updated openssl ca -gencrl -crldays 60 -out crl.pem The content of the CRL file can be listed with the command openssl crl -in crl.pem -noout -text in the case of a base64 CRL, or alternatively for a CRL in DER format openssl crl -inform DER -in cert.crl -noout -text 4. Configuring the connections - ipsec.conf ---------------------------------------- 4.1 Configuring my side ------------------- Usually the local side is the same for all connections. Therefore it makes sense to put the definitions characterizing the strongSwan security gateway into the conn %default section of the configuration file /etc/ipsec.conf. If we assume throughout this document that the strongSwan security gateway is left and the peer is right then we can write conn %default # my side is left - the freeswan security gateway left=%defaultroute leftcert=moonCert.pem # load connection definitions automatically auto=add The X.509 certificate by which the strongSwan security gateway will authenticate itself by sending it in binary form to its peers as part of the Internet Key Exchange (IKE) is specified in the line leftcert=moonCert.pem The certificate can either be stored in base64 PEM-format or in the binary DER-format. Irrespective of the file suffix, Pluto "automagically" determines the correct format. Therefore leftcert=moonCert.der or leftcert=moonCert.cer would also be valid alternatives. When using relative pathnames as in the examples above, the certificate files must be stored in in the directory /etc/ipsec.d/certs. In order to distinguish strongSwan's own certificates from locally stored trusted peer certificates (see section 5.5 for details), they could also be stored in a subdirectory below /etc/ipsec.d/certs as e.g. in leftcert=mycerts/moonCert.pem Absolute pathnames are also possible as in leftcert=/usr/ssl/certs/moonCert.pem As an ID for the VPN gateway we recommend the use of a Fully Qualified Domain Name (FQDN) of the form conn rw right=%any leftid=@moon.strongswan.org Important: When an FQDN identifier is used it must be explicitly included as a so called subjectAltName of type dnsName (DNS:) in the certificate indicated by leftcert. For details on how to generate certificates with subjectAltNames, please refer to section 7.2. If you don't want to mess with subjectAltNames, you can use the certificate's Distinguished Name (DN) instead, which is an identifier of type DER_ASN1_DN and which can be written e.g. in the LDAP-type format conn rw right=%any leftid="C=CH, O=Linux strongSwan, CN=moon.strongswan.org" Since the subject's DN is part of the certificate, the leftid does not have to be declared explicitly. Thus the entry conn rw right=%any automatically assumes the subject DN of leftcert to be the host ID. 4.2 Multiple certificates --------------------- strongSwan supports multiple local host certificates and corresponding RSA private keys: conn rw1 right=%any rightid=@peer1.domain1 leftcert=myCert1.pem # leftid is DN of myCert1 conn rw2 right=%any rightid=@peer2.domain2 leftcert=myCert2.pem # leftid is DN of myCert2 When peer1 initiates a connection then strongSwan will send myCert1 and will sign with myKey1 defined in /etc/ipsec.secrets (see section 6.2) whereas myCert2 and myKey2 will be used in a connection setup started from peer2. 4.3 Configuring the peer side using CA certificates ----------------------------------------------- Now we can proceed to define our connections. In many applications we might have dozens of mostly Windows-based road warriors connecting to a central strongSwan security gateway. The following most simple statement: conn rw right=%any defines the general roadwarrior case. The line right=%any literally means that any IPSec peer is accepted, regardless of its current IP source address and its ID, as long as the peer presents a valid X.509 certificate signed by a CA the strongSwan security gateway puts explicit trust in. Additionally the signature during IKE main mode gives proof that the peer is in possession of the private RSA key matching the public key contained in the transmitted certificate. The ID by which a peer is identifying itself during IKE main mode can by any of the ID types IPV4_ADDR, FQDN, USER_FQDN or DER_ASN1_DN. If one of the first three ID types is used, then the accompanying X.509 certificate of the peer must contain a matching subjectAltName field of the type ipAddress (IP:), dnsName (DNS:) or rfc822Name (email:), respectively. With the fourth type DER_ASN1_DN the identifier must completely match the subject field of the peer's certificate. One of the two possible representations of a Distinguished Name (DN) is the LDAP-type format rightid="C=CH, O=Linux strongSwan, CN=sun.strongswan.org" Additional whitespace can be added everywhere as desired since it will be automatically eliminated by the X.509 parser. An exception is the single whitespace between individual words , like e.g. in Linux strongSwan, which is preserved by the parser. The Relative Distinguished Names (RDNs) can alternatively be separated by a slash '/' instead of a comma ',' rightid="/C=CH/O=Linux strongSwan/CN=sun.strongswan.org" This is the representation extracted from the certificate by the OpenSSL command line option openssl x509 -in sunCert.pem -noout -subject The following RDNs are supported by strongSwan +---------------------------------------------------+ | DC Domain Component | |---------------------------------------------------| | C Country | |---------------------------------------------------| | ST State or province | |---------------------------------------------------| | L Locality or town | |---------------------------------------------------| | O Organisation | |---------------------------------------------------| | OU Organisational Unit | |---------------------------------------------------| | CN Common Name | |---------------------------------------------------| | ND NameDistinguisher, used with CN | |---------------------------------------------------| | N Name | |---------------------------------------------------| | G Given name | |---------------------------------------------------| | S Surname | |---------------------------------------------------| | I Initials | |---------------------------------------------------| | T Personal title | |---------------------------------------------------| | E E-mail | |---------------------------------------------------| | Email E-mail | |---------------------------------------------------| | emailAddress E-mail | |---------------------------------------------------| | SN Serial number | |---------------------------------------------------| | serialNumber Serial number | |---------------------------------------------------| | D Description | |---------------------------------------------------| | ID X.500 Unique Identifier | |---------------------------------------------------| | UID User ID | |---------------------------------------------------| | TCGID [Siemens] Trust Center Global ID | |---------------------------------------------------| | unstructuredName Unstructured Name | |---------------------------------------------------| | UN Unstructured Name | |---------------------------------------------------| | employeeNumber Employee Number | |---------------------------------------------------| | EN Employee Number | +---------------------------------------------------+ With the roadwarrior connection definition listed above, an IPsec SA for the strongSwan security gateway moon.strongswan.org itself can be established. If any roadwarrior should be able to reach e.g. the two subnets 10.1.0.0/24 and 10.1.3.0/24 behind the security gateway then the following connection definitions will make this possible conn rw1 right=%any leftsubnet=10.1.0.0/24 conn rw3 right=%any leftsubnet=10.1.3.0/24 If not all peers in possession of a X.509 certificate signed by a specific certificate authority shall be given access to the Linux security gateway, then either a subset of them can be barred by listing the serial numbers of their certificates in a certificate revocation list (CRL) as specified in section 5.2 or as an alternative, access can be controlled by explicitly putting a roadwarrior entry for each eligible peer into ipsec.conf: conn sun right=%any rightid=@sun.strongswan.org conn carol right=%any rightid=carol@strongswan.org conn dave right=%any rightid="C=CH, O=Linux strongSwan, CN=dave@strongswan.org" When the IP address of a peer is known to be stable, it can be specified as well. This entry is mandatory when the strongSwan host wants to act as the initiator of an IPSec connection. conn sun right=192.168.0.2 rightid=@sun.strongswan.org conn carol right=192.168.0.100 rightid=carol@strongswan.org conn dave right=192.168.0.200 rightid="C=CH, O=Linux strongSwan, CN=dave@strongswan.org" conn venus right=192.168.0.50 In the last example the ID types FQDN, USER_FQDN, DER_ASN1_DN and IPV4_ADDR, respectively, were used. Of course all connection definitions presented so far have included the lines in the conn %defaults section, comprising among other a left and leftcert entry. 4.4 Handling Virtual IPs and wildcard subnets ----------------------------------------- Often roadwarriors are behind NAT-boxes with IPsec passthrough, which causes the inner IP source address of an IPsec tunnel to be different from the outer IP source address usually assigned dynamically by the ISP. Whereas the varying outer IP address can be handled by the right=%any construct, the inner IP address or subnet must always be declared in a connection definition. Therefore for the three roadwarriors rw1 to rw3 connecting to a strongSwan security gateway the following entries are required in /etc/ipsec.conf: conn rw1 right=%any righsubnet=10.4.0.5/32 conn rw2 right=%any rightsubnet=10.4.0.47/32 conn rw3 right=%any rightsubnet=10.4.0.128/28 With the wildcard parameter rightsubnetwithin these three entries can be reduced to the single connection definition conn rw right=%any rightsubnetwithin=10.4.0.0/24 Any host will be accepted (of course after successful authentication based on the peer's X.509 certificate only) if it declares a client subnet lying totally within the brackets defined by the wildcard subnet definition (in our example 10.4.0.0/24). For each roadwarrior a connection instance tailored to the subnet of the particular client will be created,based on the generic rightsubnetwithin template. This strongSwan feature can also be helpful with VPN clients getting a dynamically assigned inner IP from a DHCP server located on the NAT router box. 4.5 Protocol and Port Selectors --------------------------- strongSwan offer the possibility to restrict the protocol and optionally the ports in an IPsec SA using the rightprotoport and leftprotoport parameters. Some examples: conn icmp right=%any rightprotoport=icmp left=%defaultroute leftid=@moon.strongswan.org leftprotoport=icmp conn http right=%any rightprotoport=6 left=%defaultroute leftid=@moon.strongswan.org leftprotoport=6/80 conn l2tp # with port wildcard for Mac OS X Panther interoperability right=%any rightprotoport=17/%any left=%defaultroute leftid=@moon.strongswan.org leftprotoport=17/1701 conn dhcp right=%any rightprotoport=udp/bootpc left=%defaultroute leftid=@moon.strongswan.org leftsubnet=0.0.0.0/0 #allows DHCP discovery broadcast leftprotoport=udp/bootps rekey=no keylife=20s rekeymargin=10s auto=add Protocols and ports can be designated either by their numerical values or by their acronyms defined in /etc/services. ipsec status shows the following connection definitions: "icmp": 192.168.0.1[@moon.strongswan.org]:1/0...%any:1/0 "http": 192.168.0.1[@moon.strongswan.org]:6/80...%any:6/0 "l2tp": 192.168.0.1[@moon.strongswan.org]:17/1701...%any:17/%any "dhcp": 0.0.0.0/0===192.168.0.1[@moon.strongswan.org]:17/67...%any:17/68 Based on the protocol and port selectors appropriate eroutes will be set up, so that only the specified payload types will pass through the IPsec tunnel. 4.6 IPsec policies based on wildcards --------------------------------- In large VPN-based remote access networks there is often a requirement that access to the various parts of an internal network must be granted selectively, e.g. depending on the group membership of the remote access user. strongSwan makes this possible by applying wildcard filtering on the VPN user's distinguished name (ID_DER_ASN1_DN). Let's make a practical example: An organization has a sales department (OU=Sales) and a research group (OU=Research). In the company intranet there are separate subnets for Sales (10.0.0.0/24) and Research (10.0.1.0/24) but both groups share a common web server (10.0.2.100). The VPN clients use Virtual IP addresses that are either assigned statically or via DHCP-over-IPsec. The sales and research departments use IP addresses from separate DHCP address pools (10.1.0.0/24) and (10.1.1.0/24), respectively. An X.509 certificate is issued to each employee, containing in its subject distinguished name the country (C=CH), the company (O=ACME), the group membership(OU=Sales or OU=Research) and the common name (e.g. CN=Bart Simpson). The IPsec policy defined above can now be enforced with the following three IPsec security associations: conn sales right=%any rightid="C=CH, O=ACME, OU=Sales, CN=*" rightsubnetwithin=10.1.0.0/24 # Sales DHCP range leftsubnet=10.0.0.0/24 # Sales subnet conn research right=%any rightid="C=CH, O=ACME, OU=Research, CN=*" rightsubnetwithin=10.1.1.0/24 # Research DHCP range leftsubnet=10.0.1.0/24 # Research subnet conn web right=%any rightid="C=CH, O=ACME, OU=*, CN=*" rightsubnetwithin=10.1.0.0/23 # Remote access DHCP range leftsubnet=10.0.2.100/32 # Web server rightprotoport=tcp # TCP protocol only leftprotoport=tcp/http # TCP port 80 only Of course group specific tunneling could be implemented on the basis of the Virtual IP range specified by the rightsubnetwithin parameter alone, but the wildcard matching mechanism guarantees that only authorized user can access the corresponding subnets. The '*' character is used as a wildcard in relative distinguished names (RDNs). In order to match a wildcard template, the ID_DER_ASN1_DN of a peer must contain the same number of RDNs (selected from the list in section 4.3) appearing in the exact order defined by the template. "C=CH, O=ACME, OU=Research, OU=Special Effects, CN=Bart Simpson" matches the templates "C=CH, O=ACME, OU=Research, OU=*, CN=*" "C=CH, O=ACME, OU=*, OU=Special Effects, CN=*" "C=CH, O=ACME, OU=*, OU=*, CN=*" but not the template "C=CH, O=ACME, OU=*, CN=*" which doesn't have the same number of RDNs. 4.7 IPsec policies based on CA certificates --------------------------------------- As an alternative to the wildcard based IPsec policies described in section 4.6, access to specific client host and subnets can abe controlled on the basis of the CA that issued the peer certificate conn sales right=%any rightca="C=CH, O=ACME, OU=Sales, CN=Sales CA" rightsubnetwithin=10.1.0.0/24 # Sales DHCP range leftsubnet=10.0.0.0/24 # Sales subnet conn research right=%any rightca="C=CH, O=ACME, OU=Research, CN=Research CA" rightsubnetwithin=10.1.1.0/24 # Research DHCP range leftsubnet=10.0.1.0/24 # Research subnet conn web right=%any rightca="C=CH, O=ACME, CN=ACME Root CA" rightsubnetwithin=10.1.0.0/23 # Remote access DHCP range leftsubnet=10.0.2.100/32 # Web server rightprotoport=tcp # TCP protocol only leftprotoport=tcp/http # TCP port 80 only In the example above, the connection "sales" can be used by peers presenting certificates issued by the Sales CA, only. In the same way, the use of the connection "research" is restricted to owners of certificates issued by the Research CA. The connection "web" is open to both "Sales" and "Research" peers because the required "ACME Root CA" is the issuer of the Research and Sales intermediate CAs. If no rightca parameter is present then any valid certificate issued by one of the trusted CAs in /etc/ipsec.d/cacerts can be used by the peer. The leftca parameter usually doesn't have to be set explicitly because by default it is set to the issuer field of the certificate loaded via leftcert. The statement rightca=%same sets the CA requested from the peer to the CA used by the left side itself as e.g. in conn sales right=%any rightca=%same leftcert=mySalesCert.pem 4.8 Sending certificate requests ---------------------------- The presence of a rightca parameter also causes the CA to be sent as part of the certificate request message when strongSwan is the initiator. A special case occurs when strongSwan responds to a roadwarrior. If several roadwarrior connections based on different CAs are defined then all eligible CAs will be listed in Pluto’s certificate request message. 4.9 IPsec policies based on group attributes ---------------------------------------- X.509 attribute certificates are the most powerful mechanism for implementing IPsec security policies. The rightgroups parameter in a connection definition restricts the access to members of the listed groups only. An IPsec peer must have a valid attribute certificate issued by a trusted Authorization Authority and listing one of the requirede group attributes in order to get admitted. conn sales right=%any rightgroups="Sales" rightsubnetwithin=10.1.0.0/24 # Sales DHCP range leftsubnet=10.0.0.0/24 # Sales subnet conn research right=%any rightgroups="Research" rightsubnetwithin=10.1.1.0/24 # Research DHCP range leftsubnet=10.0.1.0/24 # Research subnet conn web right=%any rightgroups="Sales, Research" rightsubnetwithin=10.1.0.0/23 # Remote access DHCP range leftsubnet=10.0.2.100/32 # Web server rightprotoport=tcp # TCP protocol only leftprotoport=tcp/http # TCP port 80 only In the examples above membership of the group "Sales" is required for connection sales and membership of "Research" for connection research whereas connection web is accessible for both groups. Currently the attribute certificates of the peers must be loaded statically via the /etc/ipsec.d/acerts/ directory. In future releases of strongSwan it will be possible to fetch them from an LDAP directory server. 5. Configuring certificates and CRLs --------------------------------- 5.1 Installing the CA certificates ------------------------------ X.509 certificates received by strongSwan during the IKE protocol are automatically authenticated by going up the trust chain until a self-signed root CA certificate is reached. Usually host certificates are directly signed by a root CA, but strongSwan also supports multi-level hierarchies with intermediate CAs in between. All CA certificates belonging to a trust chain must be copied in either binary DER or base64 PEM format into the directory /etc/ipsec.d/cacerts/ 5.2 Installing optional certificate revocation lists (CRLs) ------------------------------------------------------- By copying a CA certificate into /etc/ipsec.d/cacerts/, automatically all user or host certificates issued by this CA are declared valid. Unfortunately private keys might get compromised inadvertently or intentionally, personal certificates of users leaving a company have to be blocked immediately, etc. To this purpose certificate revocation lists (CRLs) have been created. CRLs contain the serial numbers of all user or host certificates that have been revoked due to various reasons. After successful verification of the X.509 trust chain, Pluto searches its list of CRLs either obtained by loading them from the /etc/ipsec.d/crls/ directory or fetching them dynamically from a HTTP or LDAP server for the presence of a CRL issued by the CA that has signed the certificate. If the serial number of the certificate is found in the CRL then the public key contained in the certificate is declared invalid and the IPSec SA will not be established. If no CRL is found or if the deadline defined in the nextUpdate field of the CRL has been reached, a warning is issued but the public key will nevertheless be accepted. CRLs must be stored either in binary DER or base64 PEM format in the crls directory. Section 7.3 will explain in detail how CRLs can be created using OpenSSL. 5.3 Dynamic update of certificates and CRLs --------------------------------------- Pluto reads certificates and CRLs from their respective files during system startup and keeps them in memory in the form of chained lists. X.509 certificates have a finite life span defined by their validity field. Therefore it must be possible to replace CA or OCSP certificates kept in system memory without disturbing established ISAKMP SAs. Certificate revocation lists should also be updated in the regular intervals indicated by the nextUpdate field in the CRL body. The following interactive commands allow the manual replacement of the various files: +---------------------------------------------------------------------------+ | ipsec rereadsecrets reload file /etc/ipsec.secrets | |---------------------------------------------------------------------------| | ipsec rereadcacerts reload all files in /etc/ipsec.d/cacerts/ | |---------------------------------------------------------------------------| | ipsec rereadaacerts reload all files in /etc/ipsec.d/aacerts/ | |---------------------------------------------------------------------------| | ipsec rereadocspcerts reload all files in /etc/ipsec.d/ocspcerts/ | |---------------------------------------------------------------------------| | ipsec rereadacerts reload all files in /etc/ipsec.d/acerts/ | |---------------------------------------------------------------------------| | ipsec rereadcrls reload all files in /etc/ipsec.d/crls/ | |---------------------------------------------------------------------------| | ipsec rereadall ipsec rereadsecrets | | rereadcacerts | | rereadaacerts | | rereadocspcerts | | rereadacerts | | rereadcrls | |---------------------------------------------------------------------------| | ipsec purgeocsp purge the OCSP cache and fetching requests | +---------------------------------------------------------------------------+ CRLs can also be automatically fetched from an HTTP or LDAP server by using the CRL distribution points contained in X.509 certificates. The command ipsec listcrls shows any pending fetch requests: Oct 31 00:29:53 2002, trials: 2 issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' distPts: 'http://crl.strongswan.org/strongswan.crl' 'ldap://ldap.strongswan.org/o=Linux strongSwan, c=CH ?certificateRevocationList?base ?(objectClass=certificationAuthority)' In the example above, an http and an ldap URL were extracted from a received end certificate. An independent thread then tries to fetch a CRL from the designated distribution points. The same thread also periodically checks if any loaded CRLs are about to expire. The check interval can be defined in the "config setup" section of the ipsec.conf file: config setup crlcheckinterval=600 In our example the thread wakes up every 600 seconds or 10 minutes in order to check the validity of the CRLs or to retry any pending fetch requests: List of X.509 CRLs: Dec 19 09:35:31 2002, revoked certs: 40 issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' distPts: 'http://crl.strongswan.org/strongswan.crl' updates: this Dec 19 09:35:00 2002 next Dec 19 10:35:00 2002 warning (expires in 19 minutes) List of fetch requests: Dec 19 10:15:31 2002, trials: 1 issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' distPts: 'http://crl.strongwan.org/strongswan.crl' The first trial to update a CRL is started 2*crlcheckinterval before the nextUpdate time, i.e. when less than 20 minutes are left in our practical example. When crlcheckinterval is set to 0 (this is also the default value when the parameter is not set in ipsec.conf) then the CRL checking and updating thread is not started and dynamic CRL fetching is disabled. 5.4 Local caching of CRLs --------------------- The the ipsec.conf option config setup cachecrls=yes activates the local caching of CRLs that were dynamically fetched from an HTTP or LDAP server. Cached copies are stored in /etc/ipsec.d/crls under a unique filename formed from the issuer's SubjectKeyIdentifier and the suffix .crl. With the cached copy the CRL is immediately available after pluto's startup. When the local copy is about to expire it is automatically replaced with an updated CRL fetched from one of the defined CRL distribution points. 5.5 Online Certificate Status Protocol (OCSP) ----------------------------------------- The Online Certificate Status Protocol is defined by RFC 2560. It can be used to query an OCSP server about the current status of an X.509 certificate and is often used as a more dynamic alternative to a static Certificate Revocation List (CRL). Both the OCSP request sent by the client and the OCSP response messages returned by the server are transported via a standard TCP/HTTP connection. Therefore cURL support must be enabled in pluto/Makefile: # Uncomment this line to enable OCSP fetching using HTTP LIBCURL=1 In the simplest OCSP setup, a default URI under which the OCSP server for a given CA can be accessed is defined in ipsec.conf: config setup crlcheckinterval=600 ca strongswan cacert=strongswanCert.pem ocspuri=http://ocsp.strongswan.org:8880 auto=add The HTTP port can be freely chosen. In our example we have assumed TCP port 8880. The crlcheckinterval must be set to a value different from zero. Otherwise the OCSP fetching thread will not be started. The well-known openssl-0.9.7 package from http://www.openssl.org implements an OCSP server that can be used in conjunction with an openssl-based Public Key Infrastructure. The OCSP client integrated into Pluto does not contain any OpenSSL code though, but is based on the existing ASN.1 functionality of strongSwan. The OpenSSL-based OCSP server is started with the following command: openssl ocsp -index index.txt -CA strongswanCert.pem -port 8880 \ -rkey ocspKey.pem -rsigner ocspCert.pem \ -resp_no_certs -nmin 60 -text The command consists of the parameters -index index.txt is a copy of the OpenSSL index file containing the list of all issued certificates. The certificate status in indext.txt is designated either by V for valid or R for revoked. If a new certificate is added or if a certificate is revoked using the openssl ca command, the OCSP server must be restarted in order for the changes in index.txt to take effect. -CA the CA certificate -port the HTTP port the OCSP server is listening on. -rkey the private key used to sign the OCSP response. The use of the sensitive CA private key is not recommended since this could jeopardize the security of your production PKI if the OCSP server is hacked. It is much better to generate a special RSA private key just for OCSP signing use instead. -rsigner the certificate of the OCSP server containing a public key which matches the private key defined by -rkey and which can be used by the client to check the trustworthiness of the signed OCSP response. -resp_no_certs With this option the OCSP signer certificate defined by -rsigner is not included in the OCSP response. -nmin the validity interval of an OCSP response given in minutes. 2*crlcheckinterval before the expiration of the OCSP responses, a new query will by pro-actively started by the Pluto fetching thread. If nmin is missing or set to zero then the default validity interval compiled into Pluto will be 2 minutes, leading to a quasi one-time use of the OCSP status response which will not be periodically refreshed by the fetching thread. In conjunction with the parameter setting "strictcrlpolicy=yes" a real-time certificate status query can be implemented in this way. -text This option activates a verbose logging output, showing the contents of both the received OCSP request and sent OCSP response. How does Pluto get hold of the OCSP signer certificate? There are two possibilities: Either you put the OCSP certificate into the default directory /etc/ipsec.d/ocspcerts or alternatively Pluto can receive it as part of the OCSP response from the remote OCSP server. In the latter case, how can Pluto make sure that the server has indeed been authorized by the CA to deal out certificate status information? In order to ascertain the OCSP signer capability, an extended key usage attribute can be included in the OCSP server certificate. Just insert the parameter extendedKeyUsage=OCSPSigner in the [ usr_cert ] section of your openssl.cnf configuration file before the CA signs the OCSP server certificate. For a given CA the corresponding ca section in ipsec.conf (see section 7) allows to define the URI of a single OCSP server. As an alternative an OCSP URI can be embedded into each host and user certificate by putting the line authorityInfoAccess = OCSP;URI:http://ocsp.strongswan.org:8880 into the [ usr_cert ] section of your openssl.cnf configuration file. If an OCSP authorityInfoAccess extension is present in a certificate then this record overrides the default URI defined by the ca section. 5.6 CRL Policy ---------- By default Pluto is quite tolerant concerning the handling of CRLs. It is not mandatory for a CRL to be present in /etc/ipsec.d/crls and if the expiration date defined by the nextUpdate field of a CRL has been reached just a warning is issued but a peer certificate will always be accepted if it has not been revoked. If you want to enforce a stricter CRL policy then you can do this by setting the "strictcrlpolicy" option. This is done in the "config setup" section of the ipsec.conf file: config setup strictcrlpolicy=yes ... A certificate received from a peer will not be accepted if no corresponding CRL or OCSP response is available. And if an ISAKMP SA re-negotiation takes place after the nextUpdate deadline has been reached, the peer certificate will be declared invalid and the cached RSA public key will be deleted, causing the connection in question to fail. Therefore if you are going to use the "strictcrlpolicy=yes" option, make sure that the CRLs will always be updated in time. Otherwise a total standstill would ensue. As mentioned earlier the default setting is "strictcrlpolicy=no" 5.7 Configuring the peer side using locally stored certificates ----------------------------------------------------------- If you don't want to use trust chains based on CA certificates as proposed in section 4.3 you can alternatively import trusted peer certificates directly into Pluto. Thus you do not have to rely on the certificate to be transmitted by the peer as part of the IKE protocol. With the conn %default section defined in section 4.1 and the use of the rightcert keyword for the peer side, the connection definitions in section 4.3 can alternatively be written as conn sun right=%any rightid=@sun.strongswan.org rightcert=sunCert.cer conn carol right=192.168.0.100 rightcert=carolCert.der If the peer certificates are loaded locally then there is no sense in sending any certificates to the other end via the IKE Main Mode protocol. Especially if self-signed certificates are used which wouldn't be accepted any way by the other side. In these cases it is recommended to add leftsendcert=never to the connection definition[s] in order to avoid the sending of the host's own certificate. The default value is leftsendcert=always. If a peer certificate contains a subjectAltName extension, then an alternative rightid type can be used, as the example "conn sun" shows. If no rightid entry is present then the subject distinguished name contained in the certificate is taken as the ID. Using the same rules concerning pathnames that apply to strongSwan's own certificates, the following two definitions are also valid for trusted peer certificates: rightcert=peercerts/carolCert.der or rightcert=/usr/ssl/certs/carolCert.der 6. Installing the private key - ipsec.secrets ------------------------------------------ 6.1 Loading private key files in PKCS#1 format ------------------------------------------ Besides strongSwan's raw private key format strongSwan has been enabled to load RSA private keys in the PKCS#1 file format. The key files can be optionally secured with a passphrase. RSA private key files are declared in /etc/ipsec.secrets using the syntax : RSA "" The key file can be either in base64 PEM-format or binary DER-format. The actual coding is detected "automagically" by Pluto. The example : RSA moonKey.pem uses a relative pathname. In this case Pluto will look for the key file in the directory /etc/ipsec.d/private As an alternative an absolute pathname can be given as in : RSA /usr/ssl/private/moonKey.pem In both cases make sure that the key files are root readable only. Often a private key must be transported from the Certification Authority where it was generated to the target security gateway where it is going to be used. In order to protect the key it can be encrypted with 3DES using a symmetric transport key derived from a cryptographically strong passphrase. openssl genrsa -des3 -out moonKey.pem 1024 Because of the weak security, key files protected by single DES will not be accepted by Pluto!!! Once on the security gateway the private key can either be permanently unlocked so that it can be used by Pluto without having to know a passphrase openssl rsa -in moonKey.pem -out moonKey.pem or as an option the key file can remain secured. In this case the passphrase unlocking the private key must be added after the pathname in /etc/ipsec.secrets : RSA moonKey.pem "This is my passphrase" Some CAs distribute private keys embedded in a PKCS#12 file. Since Pluto is not able yet to read this format directly, the private key part must first be extracted using the command openssl pkcs12 -nocerts -in moonCert.p12 -out moonKey.pem if the key file moonKey.pem is to be secured again by a passphrase, or openssl pkcs12 -nocerts -nodes -in moonCert.p12 -out moonKey.pem if the private key is to be stored unlocked. 6.2 Entering passphrases interactively ---------------------------------- On a VPN gateway you would want to put the passphrase protecting the private key file right into /etc/ipsec.secrets as described in the previous paragraph, so that the gateway can be booted in unattended mode. The risk of keeping unencrypted secrets on a server can be minimized by putting the box into a locked room. As long as no one can get root access on the machine the private keys are safe. On a mobile laptop computer the situation is quite different. The computer can be stolen or the user is leaving it unattended so that unauthorized persons can get access to it. In theses cases it would be preferable not to keep any passphrases openly in /etc/ipsec.secrets but to prompt for them interactively instead. This is easily done by defining : RSA moonKey.pem %prompt Since strongSwan is usually started during the boot process, usually no interactive console windows is available which can be used by Pluto to prompt for the passphrase. This must be initiated by the user by typing ipsec secrets which actually is an alias for the existing command ipsec rereadsecrets and which causes the prompt need passphrase for '/etc/ipsec.d/private/moonKey.pem' Enter: to appear. If the passphrase was correct and the private key file could be successfully decrypted then valid passphrase results. Otherwise the prompt invalid passphrase, please try again Enter: will give you another try. Entering a carriage return will abort the the passphrase prompting. 6.3 Multiple private keys --------------------- strongSwan supports multiple private keys. Since the connections defined in ipsec.conf can find the correct private key based on the public key contained in the certificate assigned by leftcert, default private key definitions without specific IDs can be used : RSA myKey1.pem "" : RSA myKey2.pem "" 7. Configuring CA properties - ipsec.conf -------------------------------------- Besides the definition of IPsec connections the ipsec.conf file can also be used to configure a few properties of the certification authorities needed to establish the X.509 trust chains. The following example shows the parameters that are currently available: ca strongswan cacert=strongswanCert.pem ocspuri=http://ocsp.strongswan.org:8880 crluri=http://crl.strongswan.org/strongswan.crl' crluri2="ldap:///O=Linux strongSwan, C=CH?certificateRevocationList" ldaphost=ldap.strongswan.org auto=add In a similar way as conn sections are used for connection definitions, an arbitrary number of optional ca sections define the basic properties of CAs. Each ca section is named with a unique label ca strongswan The only mandatory parameter is cacert=strongswanCert.pem which points to the CA certificate which usually resides in the default directory /etc/ipsec.d/cacerts/ but could also be retrieved via an absolute path name. If the CA certificate is stored on a smartcard then the notation cacert=%smartcard# or alternatively cacert=%smartcard: can be used. The selection of smartcard slots is described in more detail in section 8.1. From the certificate the CA's distinguished name and the serial number is extracted. If an optional subjectKeyAuthentifier is present then it can be used to uniquely identify consecutive generations of CA certificates carrying the same distinguished name. The OCSP URI ocspuri=http://ocsp.strongswan.org:8880 allows to define an individual OCSP server per CA. Also up to two additional CRL distribution points (CDPs) can be defined crluri=http://crl.strongswan.org/strongswan.crl' crluri2="ldap:///O=Linux strongSwan, C=CH?certificateRevocationList" which are added to any CDPs already present in the received certificates themselves. The last parameter ldaphost=ldap.strongswan.org can be used to fill in the actual server name in LDAP CDPs where the host is missing as e.g. in the crluri2 above. In future releases this ldaphost parameter might be used to retrieve user, host and attribute certificates. With the auto=add statement the ca definition is automatically loaded into Pluto during system startup. Setting auto=ignore will ignore the ca section. Additional ca definitions can be loaded from ipsec.conf during runtime with the command ipsec auto --type ca --add strongswan-sales and ipsec auto --type ca --delete strongswan-sales deletes the labeled ca entry. And finally the command ipsec auto --type ca --replace strongswan first deletes the old definition in Pluto's memory and then loads the updated version from ipsec.conf. Any parameters which appear in several ca definitions can be put in a common ca %default section ca %default ldaphost=ldap.strongswan.org 8. Smartcard support ----------------- 8.1 Configuring a smartcard-based connection ---------------------------------------- Defining a smartcard-based connection in ipsec.conf is easy: conn sun right=192.168.0.2 rightid=@sun.strongswan.org left=%defaultroute leftcert=%smartcard auto=add In most cases there is a single smartcard reader or cryptotoken and only one RSA private key safely stored on the crypto device. Thus usually the entry leftcert=%smartcard which stands for the full notation leftcert=%smartcard#1 is sufficient where the first certificate/private key object enumerated by the PKCS#11 module is used. If several certificate/private key objects are present then the nth object can be selected using leftcert=%smartcard# The command ipsec listcards gives an overview over all certificate objects made available by the PKCS#11 module.CA certificates are automatically available as trust anchors. As an alternative the certificate ID and/or the slot number defined by the PKCS#11 standard can be specified using the notation leftcert=%smartcard: Thus leftcert=%smartcard:50 will look in all available slots for ID 0x50 starting with the first slot (usually slot 0) whereas leftcert=%smartcard4:50 will directly check slot 4 (which is usually the first slot on the second reader/token when using the OpenSC library) for a key with ID 0x50. 8.2 Entering the PIN code --------------------- Since the smartcard signing operation needed to sign the hash with the RSA private key during IKE Main Mode is protected by a PIN code, the secret PIN must be made available to Pluto. For gateways that must be able to start IPsec tunnels automatically in unattended mode after a reboot, the secret PIN can be stored statically in ipsec.secrets : PIN %smartcard "12345678" or with the general notation : PIN %smartcard# "" or alternatively : PIN %smartcard: "" On personal notebooks that could get stolen, you wouldn't want to store your PIN in ipsec.secrets. Thus the alternative form : PIN %smartcard %prompt will prompt you for the PIN when you start up the first IPsec connection using the command ipsec up sun The auto command calls the whack function which in turn communicates with Pluto over a socket. Since the whack function call is executed from a command window, Pluto can prompt you for the PIN over this socket connection. Unfortunately roadwarrior connections which just wait passively for peers cannot be initiated via the command window: conn rw right=%any left=%defaultroute leftcert=%smartcard4:50 auto=add But if there is a corresponding entry : PIN %smartcard4:50 %prompt in ipsec.secrets, then the standard command ipsec rereadsecrets or the alias ipsec secrets can be used to enter the PIN code for this connection interactively. The command ipsec listcards can be executed at any time to check the current status of the PIN code[s]. 8.3 PIN-pad equipped smartcard readers ---------------------------------- Smartcard readers with an integrated PIN-pad offer an increased security level because the PIN entry cannot be sniffed on the host computer e.g. by a surrepticiously installed key logger. In order to tell pluto not to prompt for the PIN on the host itself, the entry : PIN %smartcard:50 %pinpad can be used in ipsec.secrets. Because the key pad does not cache the PIN in the smartcard reader, it must be entered for every PKCS #11 session login. By default pluto does a session logout after every RSA signature. In order to avoid the repeated entry of the PIN code during the periodic IKE main mode rekeyings, the following parameter can be set in the config setup section of ipsec.conf: config setup pkcs11keepstate=yes The default setting is pkcs11keepstate=no. 8.4 Configuring a smartcard with pkcsc15-init ----------------------------------------- strongSwan's smartcard solution is based on the PKCS#15 "Cryptographic Token Information Format Standard" fully supported by OpenSC library functions. Using the command pkcs15-init --erase-card --create-pkcs15 a fresh PKCS#15 file structure is created on a smartcard or cryptotoken. With the next command pkcs15-init --auth-id 1 --store-pin --pin "12345678" --puk "87654321" --label "my PIN" a secret PIN code with auth-id 1 is stored in an unretrievable location on the smart card. The PIN will protect the RSA signing operation. If the PIN is entered incorrectly more than three times the smartcard will be locked and the PUK code can be used to unlock the card again. Next the RSA private key is transferred to the smartcard pkcs15-init --auth-id 1 --store-private-key myKey.pem [--id 45] By default the PKCS#15 smartcard record will be assigned the id 45. Using the --id option multiple key records can be stored on a smartcard. At last we load the matching X.509 certificate onto the smartcard pkcs15-init --auth-id 1 --store-certificate myCert.pem [--id 45] The pkcs15-tool can now be used to verify the contents of the smartcard. pkcs15-tool --list-pins --list-keys --list-certificates If everything is ok then you are ready to use the generated PKCS#15 structure with strongSwan. 8.5 PKCS#11 proxy functions ----------------------- With the setting pkcs11keepstate=yes some PKCS#11 implementations (e.g. OpenSC) will lock the access to the smartcard as soon as pluto has opened a session and will thus prevent other application from sharing the smartcard resource. In order to solve this locking problem, strongSwan offers a PKCS#11 proxy service making use of the whack socket communication channel. The setting config setup pkcs11proxy=yes will enable the proxy mode that is disabled by default. Currently two smartcard operations are supported: RSA encryption and RSA decryption. The notation is as follows: ipsec scdecrypt [--inbase 16|hex|64|base64|256|text|ascii] [--outbase 16|hex|64|base64|256|text|ascii] [--keyid ] The default settings for inbase and outbase is hexadecimal. Thus the simplest call has the form ipsec scdecrypt bb952b71920094ce0696ef9b8b26...12e6 and the returned result might be a decrypted 128 bit AES key 000 8836362e030e6707c32ffaa0bdad5540 The leading three characters represent the return code of the whack channel with 000 signifying that no error has occured. Here is another example showing the use of the inbase and outbase attributes ipsec scdecrypt m/ewDnTs0k...woE= --inbase base64 --outbase text where the result has the form 000 This is a secret By default the first RSA private key found by the PKCS#11 enumeration is used. If a different key should be selected then the notation introduced in sections 8.1 and 8.2 can be used: --keyid %smartcard:50 --keyid %smartcard4:50 --keyid %smartcard#3 with --keyid %smartcard#1 being the default. If supported by the smartcard and PKCS#11 library RSA encryption can be used with the notation ipsec scencrypt [--inbase 16|hex|64|base64|256|text|ascii] [--outbase 16|hex|64|base64|256|text|ascii] [--keyid <id>] with the example ipsec scencrypt "This is a secret" --inbase ascii --outbase 64 returning the expected output 000 m/ewDnTs0k...woE= 9. Configuring the clients ----------------------- 9.1 strongSwan ---------- A strongSwan to strongSwan connection is symmetrical. Any of the four defined ID types can be used, even different types on either end of the connection, although this wouldn't make much sense. +--------------------------------------------------------------+ | Connection Definition ID type subjectAltName | |--------------------------------------------------------------| | rightid (strongSwan) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | |--------------------------------------------------------------| | leftid (strongSwan) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | +--------------------------------------------------------------+ 9.2 PGPnet ------ Use the file peerCert.p12 to import PGPnet's X.509 certificate, the CA certificate, plus the encrypted private key in binary PKCS#12 format into the PGPkey tool. You will be prompted for the passphrase securing the private key. Use the file myCert.pem to import the X.509 certificate of the strongSwan security gateway into the PGPkey tool. The PGPkeyTool does not accept X.509 certificates in binary DER format, so it must be imported in base64 format: -----BEGIN CERTIFICATE----- M... ... -----END CERTIFICATE----- Make sure that there is no human-readable listing of the X.509 certificate in front of the line -----BEGIN CERTIFICATE----- otherwise PGPnet will refuse to load the *.PEM file. Any surplus lines can either be deleted by loading the certificate into a text editor or you can apply the command openssl x509 -in myCert.pem -out myCert.pem to achieve the same effect. With authentication based on X.509 certificates, PGPnet always sends the ID type DER_ASN1_DN, therefore rightid in the connection definition of the strongSwan security gateway must be an ASN.1 distinguished name. In the receiving direction PGPnet accepts all four ID types from strongSwan. +--------------------------------------------------------------+ | Connection Definition ID type subjectAltName | |--------------------------------------------------------------| | rightid (PGPnet) DER_ASN1_DN - | |--------------------------------------------------------------| | leftid (strongSwan) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | +--------------------------------------------------------------+ 9.3 SafeNet/Soft-PK/Soft-Remote --------------------------- SafeNet/Soft-PK and SafeNet/Soft-Remote can be configured to send their identity either as DER_ASN1_DN, IPV4_ADDR, FQDN, or USER_FQDN. In the receiving direction SafeNet/Soft-PK and SafeNet/Soft-Remote accept all four ID types coming from strongSwan. +--------------------------------------------------------------+ | Connection Definition ID type subjectAltName | |--------------------------------------------------------------| | rightid (SafeNet/Soft-PK) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | |--------------------------------------------------------------| | leftid (strongSwan) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | +--------------------------------------------------------------+ 9.4 SSH Sentinel ------------ SSH Sentinel sends its identity as DER_ASN1_DN if the subjectAltName field of its certificate is empty. If a subjectAltName field is present, then the corresponding type IPV4_ADDR, FQDN, or USER_FQDN is automatically chosen. With several subjectAltName entries, the precedence of the different ID types is not quite clear. In the receiving direction SSH Sentinel accepts all four ID types from strongSwan. +--------------------------------------------------------------+ | Connection Definition ID type subjectAltName | |--------------------------------------------------------------| | rightid (SSH Sentinel) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | |--------------------------------------------------------------| | leftid (strongSwan) DER_ASN1_DN - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | +--------------------------------------------------------------+ 9.5 Windows 2000/XP --------------- Windows 2000 and Windows XP always send the ID type DER_ASN1_DN, therefore rightid in the connection definition of the strongSwan security gateway must be an ASN.1 distinguished name.In the receiving direction Windows 2000/XP accepts all four ID types from strongSwan. +--------------------------------------------------------------+ | Connection Definition ID type subjectAltName | |--------------------------------------------------------------| | rightid (Windows 2000/XP) DER_ASN1_DN - | |--------------------------------------------------------------| | leftid (strongSwan) DER_ASN1_D - | | FQDN DNS: | | USER_FQDN email: | | IPV4_ADDR IP: | +--------------------------------------------------------------+ 10. Monitoring functions -------------------- strongSwan offers the following monitoring functions: ipsec listalgs lists all IKE and ESP cryptographic algorithms that are currently registered with strongSwan. The a listing has the following form: List of registered IKE Encryption Algorithms: #3 OAKLEY_BLOWFISH_CBC, blocksize: 64, keylen: 128-128-256 #5 OAKLEY_3DES_CBC, blocksize: 64, keylen: 192-192-192 #7 OAKLEY_AES_CBC, blocksize: 128, keylen: 128-128-256 #65004 OAKLEY_SERPENT_CBC, blocksize: 128, keylen: 128-128-256 #65005 OAKLEY_TWOFISH_CBC, blocksize: 128, keylen: 128-128-256 #65289 OAKLEY_TWOFISH_CBC_SSH, blocksize: 128, keylen: 128-128-256 List of registered IKE Hash Algorithms: #1 OAKLEY_MD5, hashsize: 128 #2 OAKLEY_SHA, hashsize: 160 #4 OAKLEY_SHA2_256, hashsize: 256 #6 OAKLEY_SHA2_512, hashsize: 512 List of registered IKE DH Groups: #2 OAKLEY_GROUP_MODP1024, groupsize: 1024 #5 OAKLEY_GROUP_MODP1536, groupsize: 1536 #14 OAKLEY_GROUP_MODP2048, groupsize: 2048 #15 OAKLEY_GROUP_MODP3072, groupsize: 3072 #16 OAKLEY_GROUP_MODP4096, groupsize: 4096 #17 OAKLEY_GROUP_MODP6144, groupsize: 6144 #18 OAKLEY_GROUP_MODP8192, groupsize: 8192 List of registered ESP Encryption Algorithms: #3 ESP_3DES, blocksize: 64, keylen: 168-168 #7 ESP_BLOWFISH, blocksize: 64, keylen: 96-128 #12 ESP_AES, blocksize: 128, keylen: 128-256 #252 ESP_SERPENT, blocksize: 128, keylen: 128-256 #253 ESP_TWOFISH, blocksize: 128, keylen: 128-256 List of registered ESP Authentication Algorithms: #1 AUTH_ALGORITHM_HMAC_MD5, keylen: 128-128 #2 AUTH_ALGORITHM_HMAC_SHA1, keylen: 160-160 #5 AUTH_ALGORITHM_HMAC_SHA2_256, keylen: 256-256 #7 AUTH_ALGORITHM_HMAC_SHA2_512, keylen: 512-512 The command ipsec listpubkeys [--utc] lists all public keys currently installed in the chained list of public keys. These keys were statically loaded from ipsec.conf or aquired either from received certificates or retrieved from secure DNS servers using opportunistic mode. The public key listing has the following form: Feb 11 14:40:18 2005, 2048 RSA Key AwEAAa+uL, until Sep 09 13:17:25 2009 ok ID_FQDN '@moon.strongswan.org' issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' serial: '03' Feb 11 14:40:18 2005, 2048 RSA Key AwEAAa+uL, until Sep 09 13:17:25 2009 ok ID_DER_ASN1_DN 'C=CH, O=Linux strongSwan, CN=moon.strongswan.org' issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' serial: '03' Feb 11 13:36:53 2005, 2048 RSA Key AwEAAbgbh, until Dec 31 22:43:18 2009 ok ID_USER_FQDN 'carol@strongswan.org' issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' serial: '0a' It consists of - the date the public key was installed either in local time or UTC (--utc) - the modulus size of the RSA key in bits - a keyID consisting of 9 base64 symbols representing the public exponent and the most significant bits of the modulus - the expiration date of the public key (extracted from the certificate) - the type and value of the ID associated with the public key. - the issuer of the certificate the public key was extracted from. - the serial number of the certificate the public key was extracted from. A public key can be associated with several IDs, e.g. using subjectAltNames in certificates and an ID can possess several public keys, e.g. retrieved from a secure DNS server. The command ipsec listcerts [--utc] lists all local certificates, both strongSwan's own and those of trusted peer loaded via leftcert and rightcert, respectively. The output has the form Feb 11 13:36:47 2005, count: 4 subject: 'C=CH, O=Linux strongSwan, CN=moon.strongswan.org' issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' serial: 03 pubkey: 2048 RSA Key AwEAAa+uL, has private key validity: not before Sep 10 13:17:25 2004 ok not after Sep 09 13:17:25 2009 ok subjkey: e5:e4:10:87:6c:2a:c4:be:ad:85:49:42:a6:de:76:58:30:3a:9f:c1 authkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef aserial: 00 and shows - the date the certificate was installed either in local time or UTC (--utc) - the count shows how many connections refer to this certificate - the subject of the certificate - the issuer of the certificate - the serial number of the certificate - the size and keyid of the RSA public key contained in the certificate. the label "has private key" indicates that a matching RSA private key has been found, defined or loaded in ipsec.secrets. - the label "on smartcard" indicates that the certificate was loaded from a smartcard or cryptotoken and that most probably a matching RSA private key also resides on-card. - the validity of the CA certificate expressed either in local time or UTC (--utc). The validity is checked automatically resulting either in an "ok" message or a "fatal" error message. - the optional subjectKeyIdentifier extension which is a 20 byte SHA-1 hash over the certificate's public key. - the optional authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the issuer who signed the certificate. - the serial number of the issuer's certificate. The command ipsec listcacerts [--utc] lists all CA certificates that have been either been loaded from the directory /etc/ipsec.d/cacerts/ or received via the IKE protocol. The output has the form Feb 11 13:36:52 2005, count: 1 subject: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' serial: 00 pubkey: 2048 RSA Key AwEAAb/yX validity: not before Sep 10 13:01:45 2004 ok not after Sep 08 13:01:45 2014 ok subjkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef authkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef aserial: 00 and shows - the date the CA certificate was installed either in local time or UTC (--utc) - the count is always set to 1 - the subject of the CA certificate - the issuer of the CA certificate - the serial number of the CA certificate - the size and keyid of the RSA public key contained in the certificate. - the validity of the CA certificate expressed either in local time or UTC (--utc). The validity is checked automatically resulting either in an "ok" message or a "fatal" error message. - the optional subjectKeyIdentifier extension which is a 20 byte SHA-1 hash over the CA certificate's public key. - the optional authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the issuer who signed the CA certificate. For Root CA certificates the authorityKeyIdentifier and subjectKeyIdentifier fields must be equal. - the serial number of the issuer's certificate. The command ipsec listaacerts [--utc] lists all Authorization Authority certificates that have been loaded from the directory /etc/ipsec.d/aacerts/. The output has the form Dec 20 13:29:55 2004, count: 1 subject: 'C=CH, O=strongSec GmbH, CN=strongSec Authorization Authority' issuer: 'C=CH, O=strongSec GmbH, CN=strongSec Root CA' serial: 0f pubkey: 2048 RSA Key AwEAAfazH validity: not before Aug 24 13:41:56 2003 ok not after Aug 23 13:41:56 2005 ok subjkey: 56:89:b9:28:c9:1b:a0:00:7f:50:9d:ec:28:75:23:c1:1e:d1:dd:90 authkey: af:80:d5:c6:02:1c:96:78:b3:85:a5:65:a2:23:fd:ad:cf:e2:55:b2 aserial: 00 and shows - the date the AA certificate was installed either in local time or UTC (--utc) - the count is always set to 1 - the subject of the AA certificate - the issuer of the AA certificate - the serial number of the AA certificate - the size and keyid of the RSA public key contained in the certificate. - the validity of the AA certificate expressed either in local time or UTC (--utc). The validity is checked automatically resulting either in an "ok" message or a "fatal" error message. - the optional subjectKeyIdentifier extension which is a 20 byte SHA-1 hash over the AA certificate's public key. - the optional authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the issuer who signed the AA certificate. - the serial number of the issuer's certificate. The command ipsec listocspcerts [--utc] lists all OCSO signer certificates that have been either loaded from /etc/ipsec.d/ocspcerts/ or have been received included in the OCSP server response. The output has the form Feb 09 22:56:17 2005, count: 1 subject: 'C=CH, O=Linux strongSwan, OU=OCSP, CN=ocsp.strongswan.org' issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' serial: 09 pubkey: 2048 RSA Key AwEAAaonT validity: not before Nov 19 17:29:28 2004 ok not after Nov 18 17:29:28 2009 ok subjkey: 88:07:0a:b8:ae:c7:c1:07:5c:be:68:6a:c4:a5:7f:81:1f:37:b5:56 authkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef aserial: 00 and shows - the date the OCSP signer certificate was installed either in local time or UTC (--utc) - the count is always set to 1 - the subject of the OCSP signer certificate - the issuer of the OCSP signer certificate - the serial number of the OCSP signer certificate - the size and keyid of the RSA public key contained in the certificate. - the validity of the OCSP signer certificate expressed either in local time or UTC (--utc). The validity is checked automatically resulting either in an "ok" message or a "fatal" error message. - the optional subjectKeyIdentifier extension which is a 20 byte SHA-1 hash over the OCSP signer certificate's public key. - the optional authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the issuer who signed the OCSP certificate. - the serial number of the issuer's certificate. The command ipsec listacerts [--utc] lists all X.509 attribute certificates that have been loaded from the directory /etc/ipsec.d/acerts/. The output has the form Dec 20 13:29:56 2004 holder: 'C=CH, O=strongSec GmbH, CN=Andreas Steffen' hissuer: 'C=CH, O=strongSec GmbH, CN=strongSec Root CA' hserial: 1e groups: Research, Sales issuer: 'C=CH, O=strongSec GmbH, CN=strongSec Authorization Authority' serial: 2c validity: not before Dec 19 14:51:38 2004 ok not after Dec 20 14:51:38 2004 fatal (expired) authkey: 56:89:b9:28:c9:1b:a0:00:7f:50:9d:ec:28:75:23:c1:1e:d1:dd:90 aserial: 0f and shows - the date the attribute certificate was installed either in local time or UTC (--utc) - the holder of the attribute certificate - the issuer of holder's certificate - the serial number of the holder's certificate - the group attributes - the issuing Authorization Authority of the attribute certificate - the serial number of the attribute certificate - the validity of the attribute certificate expressed either in local time or UTC (--utc). The validity is checked automatically resulting either in an "ok" message or a "fatal" error message. - an authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the issuing Authorization Authority - the serial number of the AA certificate. The command ipsec listgroups [--utc] lists all group attributes either defined in right|leftgroups statements in ipsec.conf or contained in loaded X.509 attribute certificates. The output has the form Dec 20 13:29:55 2004, count: 4 Research Dec 20 13:30:04 2004, count: 1 Research New York Dec 20 13:29:55 2004, count: 3 Sales and shows - the date the group attribute was first installed either in local time or UTC (--utc) - the count shows how many times the attribute is used - the group name The command ipsec listcainfos [--utc] lists the properties defined by the ca definition sections in ipsec.conf. The output has the form Jun 08 22:31:37 2004, "strongswan" authname: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' ldaphost: 'ldap.strongswan.org' ocspuri: 'http://ocsp.strongswan.org:8880' distPts: 'http://crl.strongswan.org/strongswan.crl' 'ldap:///O=Linux strongSwan, C=CH?certificateRevocationList' authkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef aserial: 00 and shows - the date the CA definition was loaded either in local time or UTC (--utc) - the name of the ca section - the distinguished name of the CA - an optional default ldap host for the CA - an optional OCSP URI - a maximum of two optional CRL distribution points - the optional authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the CA. - the serial number of the CA. The command ipsec listcrls [--utc] lists all CRLs that have been loaded from /etc/ipsec.d/crls/. The output has the form Feb 11 13:37:00 2005, revoked certs: 1 issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' distPts: 'http://crl.strongswan.org/strongswan.crl' updates: this Feb 08 07:46:29 2005 next Mar 10 07:46:29 2005 ok authkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef aserial: 00 and shows - the date the CRL was installed either in local time or UTC (--utc) - the number revoked certificates - the issuer of the CRL - the URLs of the distribution points where the CRL can be fetched from. - the dates when the CRL was issued and when the next update is expected, respectively, expressed either in local time or UTC (--utc). It is automatically checked if the next update deadline has passed, resulting either in an "ok" message, a a "warning" message when strictcrlpolicy=no or a "fatal" message when strictcrlpolicy=yes. - the optional authorityKeyIdentifier extension which is a 20 byte SHA-1 hash over the public key of the issuer who signed the CRL. This extension is present in version 2 CRLs, only. - the serial number of the issuer's certificate. The command ipsec listocsp [--utc] lists the contents of the OCSP response cache. The output has the form issuer: 'C=CH, O=Linux strongSwan, CN=strongSwan Root CA' uri: 'http://ocsp.strongswan.org:8880' authname: 13:9d:a0:9e:f4:32:ab:8f:e2:89:56:67:fa:d0:d4:e3:35:86:71:b9 authkey: 5d:a7:dd:70:06:51:32:7e:e7:b6:6d:b3:b5:e5:e0:60:ea:2e:4d:ef aserial: 00 Feb 09 22:56:17 2005, until Feb 09 23:01:17 2005 warning (expires in 4 minutes) serial: 0a, good and shows - the distinguished name of the CA handled by the OCSP server - the http URI of the OCSP server. - the 20 byte SHA-1 hash of the CA's distinguished name - the 20 byte SHA-1 hash of the CA's public key - the serial number of the CA's certificate - a certificate status list showing - the time the OCSP status was received - an optional nextUpdate deadline (if missing the OCSP status will be onetime with a lifetime of 2 minutes only). - the serial number of the certificate - the status of the certificate (good, revoked, unknown) The command ipsec listcards [--utc] lists all smartcard records that are currently in use by Pluto. The output has the form Aug 17 16:47:59 2005, #1, count: 6 slot: 0, session closed, logged out, has valid pin id: 45 label: 'strongSwan' subject: 'C=CH, O=Linux strongSwan, CN=carol@strongswan.org' with pkcs11keepstate=no and Aug 17 16:47:59 2005, #1, count: 6 slot: 0, session opened, logged in, has pin pad id: 45 label: 'strongSwan' subject: 'C=CH, O=Linux strongSwan, CN=carol@strongswan.org' with pkcs11keepstate=yes and shows - the date the certificate was read from the smartcard record - the certificate objects are numbered starting from #1 - the count shows how many connections and secret pin entries point to the smartcard record - the PKCS #11 slot number - the PKCS #11 session state: closed | opened - the PKCS #11 session login state: logged out | logged in - the status of the PIN: no pin | valid pin | invalid pin | pin pad - the ID of the certificate object - the label of the certificate object - the subject distinguished name of the certificate The command ipsec auto --listall [--utc] is equivalent to ipsec listalgs ipsec listpubkeys [--utc] ipsec listcerts [--utc] ipsec listcacerts [--utc] ipsec listaacerts [--utc] ipsec listocspcerts [--utc] ipsec listacerts [--utc] ipsec listgroups [--utc] ipsec listcainfos [--utc] ipsec listcrls [--utc] ipsec listocsp [--utc] ipsec listcards [--utc] 11. Firewall support functions -------------------------- 11.1 Environment variables in the updown script ------------------------------------------ strongSwan makes the following environment variables available in the updown script indicated by the leftupdown option: +------------------------------------------------------------------+ | Variable Example Comment | |------------------------------------------------------------------| | $PLUTO_PEER_ID carol@strongswan.org USER_FQDN (1) | |------------------------------------------------------------------| | $PLUTO_PEER_PROTOCOL 17 udp (2) | |------------------------------------------------------------------| | $PLUTO_PEER_PORT 68 bootpc (3) | |------------------------------------------------------------------| | $PLUTO_PEER_CA C=CH, O=ACME, CN=Sales CA (4) | |------------------------------------------------------------------| | $PLUTO_MY_ID @moon.strongswan.org FQDN (1) | |------------------------------------------------------------------| | $PLUTO_MY_PROTOCOL 17 udp (2) | |------------------------------------------------------------------| | $PLUTO_MY_PORT 67 bootps (3) | +------------------------------------------------------------------+ (1) $PLUTO_PEER_ID/$PLUTO_MY_ID contain the IDs of the two ends of an established connection. In our examples these correspond to the strings defined by rightid and leftid, respectively. (2) $PLUTO_PEER_PROTOCOL/$PLUTO_MY_PROTOCOL contain the protocol defined by the rightprotoport and leftprotoport options, respectively. Both variables contain the same protocol value. The variables take on the value '0' if no protocol has been defined. (3) $PLUTO_PEER_PORT/$PLUTO_MY_PORT contain the ports defined by the rightprotoport and leftprotoport options, respectively. The variables take on the value '0' if no port has been defined. (4) $PLUTO_PEER_CA contains the distinguished name of the CA that issued the peer's certificate. 11.2 Sample Linux 2.4 updown script for iptables ------------------------------------------- The template "_updown.x509" located in the programs/_updown_x509 directory of the strongSwan distribution can be used as an updown script to dynamically insert and delete iptables firewall rules. The script also features a logging facility which will register the creation (+) and the expiration (-) of each successfully established VPN connection in a special syslog file in the following concise and easily readable format: Jul 19 18:58:38 moon vpn: + @carol.strongswan.org 192.168.0.100 -- 192.168.0.1 == 10.1.0.0/16 Jul 19 22:15:17 moon vpn: - @carol.strongswan.org 192.168.0.100 -- 192.168.0.1 == 10.1.0.0/16 11.3 Sample Linux 2.6 updown script for iptables < 1.3.5 --------------------------------------------------- Because the native IPsec stack of the Linux 2.6 kernel does not implement any virtual ipsecN interfaces ipsec0, ipsec1, ... but uses the physical interfaces eth0, eth1, ..., instead, both for the incoming ESP packets and the decapsulated IP packets, dynamic firewall rules on eth0, etc. will applied to both tunneled packets and packets appearing directly at the firewall input. In order to make sure that only tunneled packets are accepted, a mark can be set on incoming ESP packets. This "ESP" mark will be retained on the decapsulated packet so that iptables rules inserted by the updown script can check on the presence of this mark. For this purpose the template located in programs/_updown_espmark can be used. In addition for the dynamic updown script to work the following static iptables rules must be applied: iptables -t mangle -A INPUT -p 50 -j MARK --set-mark 50 11.4 Sample Linux 2.6 updown script for iptables-1.3.5 ------------------------------------------------- iptables-1.3.5 introduces ipsec policy matching rules in conjunction with the linux 2.6.16 kernel. The new template located in programs/_updown_policy does not require the setting of ESP marks anymore. Tunnel traffic is recognized on the basis of the requid which is conferred via the new PLUTO_REQID environment variable to the firewall updown script. 12. Authentication with raw RSA public keys --------------------------------------- FreeS/WAN, as it is available from www.freeswan.org does public key authentication with raw RSA public keys that are directly defined in /etc/ipsec.conf rightrsasigkey=0sAq4c.... When version 1.x of standard FreeS/WAN receives a certificate request (CR), it immediately drops the negotiation because it does not know how to answer the request. As a workaround strongSwan does not send a CR if the RSA key has been statically loaded using [right/left]rsasigkey. A problem remains with roadwarriors initiating a connection. Since strongSwan does not know the identity of the initiating peer in advance, it will always send a CR, causing the rupture of the IKE negotiation if the peer is a version 1.x FreeS/WAN host. To circumvent this problem the configuration parameter 'nocrsend' can be set in the config setup section of /etc/ipsec.conf: config setup: nocrsend=yes With this entry no certificate request is sent in any connection. The default setting is nocrsend=no. 13. Authentication with OpenPGP certificates ---------------------------------------- strongSwan also supports RSA based authentication using OpenPGP certificates and OpenPGP V3 fingerprints used as an KEY_ID identifier. 13.1 OpenPGP certificates -------------------- OpenPGP certificates containing RSA public keys can now directly be loaded in ASCII armored PGP format using the leftcert and rightcert parameters in /etc/ipsec.conf: conn pgp right=%any righcert=peerCert.asc left=%defaultroute leftcert=gatewayCert.asc The peer certificate must be stored locally (the default directory is /etc/ipsec.d/certs) since currently no trust can be established for PGP certificates received from a peer via the IKE protocol. 13.2 OpenPGP private keys -------------------- PGP private keys in unencrypted form can now directly be loaded in ASCII armored PGP format via an entry in /etc/ipsec.secrets: : RSA gatewayKey.asc Existing IDEA-encrypted RSA private keys can be unlocked with GnuPG and the IDEA extension (see http://www.gnupg.org/gph/en/pgp2x.html) using the commands gpg --import gatewayCert.asc gpg --allow-secret-key-import --import gatewayKey.asc gpg --edit-key <gateway ID> > passwd #change to empty password > save gpg -a --export-secret-key <gateway ID> gatewayKey.asc 13.3 Monitoring functions -------------------- The command ipsec listcerts shows all loaded PGP certificates in the following format: Aug 28 09:51:55 2002, count: 1 fingerprint: 0x1ccfca12d93467ffa9d5093d87a465dc pubkey: 1024 RSA Key ARHso6uKQ created: Aug 27 08:51:39 2002 until: --- -- --:--:-- ---- ok (expires never) The entries are - the date the certificate was loaded either in local time or UTC (--utc) - the V3 fingerprint consisting of the 16 byte MD5 hash of the public key which is used as an ID of type KEY_ID - the modulus size of the RSA key in bits - a keyID consisting of 9 base64 symbols representing the public exponent and the most significant bits of the modulus - the creation date of the public key (extracted from the certificate) - the optional expiration date of the public key (extracted from the certificate) 13.4 Suppression of certificate request messages ------------------------------------------- PGPnet configured to work with OpenPGP certificates aborts the IKE negotiation when it receives a X.509 certificate. Therefore it is recommended (mandatory for roadwarrior connections) to set config setup: nocrsend=yes in /etc/ipsec.conf. 14. Additional Features ------------------- 14.1 Authentication and encryption algorithms ---------------------------------------- strongSwan supports the following suite of encryption and authentication algorithms for both IKE and ESP payloads. +------------------------------------------------------------------+ | IKE algorithms (negotiated in Phase 1 Main Mode) | +------------------------------------------------------------------+ | Encryption algorithms: 3des, aes, serpent, twofish, blowfish | |------------------------------------------------------------------| | Hash algorithms: md5, sha, sha2 | |------------------------------------------------------------------| | DH groups: 1024, 1536, 2048, 3072, 4096, 6144, 8192 | +------------------------------------------------------------------+ NOTE: For IKE the SHA-1 algorithm is denoted by "sha" The cryptographic IKE algorithms listed above are a fixed part of the strongSwan distribution. Particular algorithms can be added or removed in the "programs/pluto/alg" directory. +------------------------------------------------------------------+ | ESP algorithms (negotiated in Phase 2 Quick Mode) | +------------------------------------------------------------------+ | Encryption algorithms: 3des, aes, serpent, twofish, blowfish | |------------------------------------------------------------------| | Hash algorithms: md5, sha1, sha2 | |------------------------------------------------------------------| | PFS groups: 1024, 1536, 2048, 3072, 4096, 6144, 8192 | +------------------------------------------------------------------+ The cryptographic ESP algorithms listed above are a fixed part of the strongSwan distribution. If your Linux 2.4 or 2.6 kernel includes the CryptoAPI then additional ESP algorithms can be added or deleted as kernel modules. The IKE and ESP cryptographic algorithms to be proposed to the peer as an initiator can be specified on a per connection basis in the form conn normal ... ike=aes128-sha-modp1536,3des-sha-modp1536 esp=aes128-sha1,3des-sha1 ... or if you are more paranoid conn paranoid ... ike=aes256-sha2_512-modp2048 esp=aes256-sha2_512 ... If the the "ike" and "esp" configuration parameters are missing in ipsec.conf, then the default settings ike=3des-md5-modp1536,3des-sha-modp1536,\ 3des-md5-modp1024,3des-sha-modp1024 esp=3des-md5,3des-sha1 arre implicitly assumed. The 3DES encryption algorithm and the MD5 and SHA-1 hash algorithms are hardcoded into strongSwan and cannot be removed. If Perfect Forward Secrecy (PFS is desired), then a PFS group can be optionally specified: conn make_sure ... pfs=yes pfsgroup=modp2048,modp1536 ... If the "pfs" parameter is missing then "pfs=yes" is assumed by default. This means that PFS must be disabled explicitly by setting "pfs=no". If the "pfsgroup" parameter is missing then the default is pfsgroup=<Phase1 DH group> The "ike" and "esp" parameters are used to formulate one or several transform proposals to the peer if the strongSwan VPN host is the initiator. Attention! As a responder the first proposal from the peer is accepted that is supported the by one of the registered algorithms listed by the command ipsec listalgs If the responder wants to restrict the allowed cipher suites the '!' flag can be used to do so. The configuration conn normal_but_strict ... ike=aes128-sha-modp1536,3des-sha-modp1536! esp=aes128-sha1,3des-sha1! ... will only permit the listed algorithms defined above but no other methods even if they might be supported by the responder. 14.2 NAT traversal ------------- Currently please refer to README.NAT-Traversal document in the strongSwan distribution. 14.3 Dead peer detection -------------------- strongSwan implements the RFC 3706 Dead Peer Detection (DPD) keep-alive scheme. If an established IPsec SA has been idle (i.e. without any traffic) for N seconds (dpddelay=N) then strongSwan side sends a "hello" message (R_U_THERE) and the peer replies with an acknowledge message (R_U_THERE_ACK). If no response is received, the R_U_THERE messages are repeated until a DPD timeout of M seconds (dpdtimeout=M) has elapsed. If still no traffic or R_U_THERE_ACK packets were received, the peer is declared to be dead and all SAs belonging to a common Phase 1 SA are deleted. DPD support is tuneable on a per connection basis by using the dpdaction, dpddelay and dpdtimeout directives: conn roadwarrior right=%any left=%defaultroute leftsubnet=10.1.0.0/16 dpdaction=clear conn net-to-net right=192.168.0.2 rightsubnet=10.2.0.0/16 left=%defaultroute leftsubnet=10.1.0.0/16 dpdaction=hold dpddelay=60 dpdtimeout=500 In the first example dpdaction=clear activates the DPD mechanism under the condition that the peer supports RFC 3706. The values dpddelay=30s and dpdtimeout=120s are assumed by default in the absence of these parameters, so that during idle periods an R_U_THERE packet is sent every 30 seconds. If no traffic or a no R_U_THERE_ACK packet is received from the peer within a 120 second time span, the peer will be declared dead and all SAs and associated eroutes will be cleared. In the second example R_U_THERE packets are sent every 60 seconds and the parameter setting dpdaction=hold will put the eroute of the ruptured connection into a %trap state, so that when new outgoing traffic will occur, the correspondig connection will be automatically renegotiated as soon as the peer is up again. It is recommended to use dpdaction=hold for statically defined connections and dpdaction=clear for dynamic roadwarrior connections. The default value is dpdaction=none, which disables DPD. 14.4 IKE Mode Config --------------- The IKE Mode Config protocol <draft-ietf-ipsec-isakmp-mode-cfg-04.txt> allows the dynamic assignment of virtual IP addresses and optional DNS and WINS server information to IPsec clients. Currently only "Mode Config Pull Mode" is implemented where the client actively sends a Mode Config request to the server in order to obtain a virtual IP. Client side configuration (carol): conn home right=192.168.0.1 rightsubnet=10.1.0.0/16 rightid=@moon.strongswan.org left=%defaultroute leftsourceip=%modeconfig leftcert=carolCert.pem leftid=carol@strongswan.org auto=start Server side configuration (moon): conn roadwarrior right=%any rightid=carol@strongswan.org rightsourceip=10.3.0.1 left=%defaultroute leftsubnet=10.1.0.0/16 leftcert=moonCert.pem leftid=@moon.strongswan.org auto=add The wildcard %modeconfig or %modecfg used in the leftsourceip parameter of the client will trigger a Mode Config request. Currently the server will return the virtual IP address defined by the rightsourceip parameter. In the future an LDAP-based lookup mechanism will be supported. 15. Copyright statement and acknowledgements ---------------------------------------- FreeS/WAN version base system: Copyright (c) 1999-2004 Henry Spencer, Richard Guy Briggs, D. Hugh Redelmeier, Sandy Harris, Claudia Schmeing, Michael Richardson, Angelos D. Keromytis, John Ioannidis, NAT-Traversal, ipsec starter, Delete SA and Notification messages: Copyright (c) 2002-2003, Mathieu Lafon Additional cryptoalgorithms (AES, etc): Copyright (c) 2002-2003, JuanJo Ciarlante Dead Peer Detection: Copyright (c) 2002-2004 Ken Bantoft, JuanJo Ciarlante, Philip Craig, Pawel Krawczyk, Srinvasan Venkataraman Porting to Linux 2.6 kernel: Copyright (c) 2003, Herbert Xu Dynamic CRL fetching: Copyright (c) 2002, Stephane Laroche IKE Mode Config protocol: Copyright (c) 2001-2002, Colubris Networks Virtual IP and source routing: Copyright (c) 2003, Tuomo Soini Port and protocol selectors for outbound traffic: Copyright (c) 2002, Stephen J. Bevan PGPnet-RSA parts of patch: Copyright (c) 2000, Kai Martius X.509, OCSP and smartcard functionality: Copyright (c) 2000, Andreas Hess, Patric Lichtsteiner, Roger Wegmann Copyright (c) 2001, Marco Bertossa, Andreas Schleiss Copyright (c) 2002, Uli Galizzi, Ariane Seiler, Mario Strasser Copyright (c) 2002, Martin Berner, Lukas Suter Copyright (c) 2003, Christoph Gysin, Simon Zwahlen Copyright (c) 2004, David Buechi, Michael Meier Copyright (c) 2000-2005, Andreas Steffen Zurich University of Applied Sciences in Winterthur, Switzerland scepclient: Copyright (c) 2005, Jan Hutter, Martin Willi, Andreas Steffen University of Applied Sciences in Rapperswil, Switzerland This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. See http://www.fsf.org/copyleft/gpl.txt. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. ----------------------------------------------------------------------------- This file is RCSID $Id: README,v 1.32 2006/04/12 06:02:01 as Exp $