.\" $OpenBSD: vpn.8,v 1.68 2003/07/10 07:54:03 markus Exp $ .\" .\" Copyright 1998 Niels Provos .\" All rights reserved. .\" .\" Redistribution and use in source and binary forms, with or without .\" modification, are permitted provided that the following conditions .\" are met: .\" 1. Redistributions of source code must retain the above copyright .\" notice, this list of conditions and the following disclaimer. .\" 2. Redistributions in binary form must reproduce the above copyright .\" notice, this list of conditions and the following disclaimer in the .\" documentation and/or other materials provided with the distribution. .\" 3. All advertising materials mentioning features or use of this software .\" must display the following acknowledgement: .\" This product includes software developed by Niels Provos. .\" 4. The name of the author may not be used to endorse or promote products .\" derived from this software without specific prior written permission. .\" .\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR .\" IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES .\" OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. .\" IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, .\" INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT .\" NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, .\" DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY .\" THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT .\" (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF .\" THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. .\" .\" Manual page, using -mandoc macros .\" .Dd February 9, 1999 .Dt VPN 8 .Os .Sh NAME .Nm vpn .Nd configuring the system for virtual private networks .Sh DESCRIPTION A virtual private network is used to securely connect two or more subnets over the internet. For each subnet there is a security gateway which is linked via a cryptographically secured tunnel to the security gateway of the other subnet. .Xr ipsec 4 is used to provide the necessary network-layer cryptographic services. This document describes the configuration process for setting up a .Nm VPN . .Pp Briefly, creating a VPN consists of the following steps: .Pp .Bl -enum -compact .It Choose a key exchange method: manual keyed, or automated via .Xr isakmpd 8 . .It For manual keying, create the Security Associations (SA), one for each endpoint. .It For manual keying, create the appropriate IPsec flows. .It For automated keying, create a configuration file for the keying daemon. .It Configure your firewall rules appropriately. .El .Ss Choosing a key exchange method There are currently two key exchange methods available: .Pp .Bl -bullet -compact .It manual (symmetric shared secret) .It .Xr isakmpd 8 .El .Ss Enabling the Appropriate Kernel Operations Make sure that the following options and devices are enabled in the kernel: .Bd -literal option CRYPTO # Cryptographic Framework option IPSEC # IPSEC VPN pseudo-device enc 4 # Encapsulation device used by IPSEC .Ed .Pp To use IPsec, .Xr ipsec 4 operations must be enabled using .Xr sysctl 8 . Before doing either manual or automated keying, or performing encryption (ESP) or authentication (AH) operations, ensure the appropriate kernel operation has been enabled: .Bd -literal -offset indent # sysctl -w net.inet.esp.enable=1 # sysctl -w net.inet.ah.enable=1 .Ed .Pp The ESP and AH protocols default to 'on'. .Pp For security gateways, proper operation often also requires packet forwarding to be enabled: .Bd -literal -offset indent # sysctl -w net.inet.ip.forwarding=1 # sysctl -w net.inet6.ip6.forwarding=1 .Ed .Pp Packet forwarding defaults to 'off'. .Pp For more permanent operation, the appropriate option(s) should be enabled in your .Xr sysctl.conf 5 . .Ss Generating Manual Keys [manual keying] The shared secret symmetric keys used to create a VPN can be any hexadecimal value, so long as both sides of the connection use the same values. Since the security of the VPN is based on these keys being unguessable, it is very important that the keys be chosen using a strong random source. One practical method of generating them is by using the .Xr random 4 device. To produce 160 bits (20 bytes) of randomness, for example, do: .Bd -literal -offset indent # openssl rand 20 | hexdump -e '20/1 "%02x"' .Ed .Pp or: .Bd -literal -offset indent # openssl rand 20 | perl -pe 's/./unpack("H2",$&)/ges' .Ed .Pp Different cipher types may require different sized keys. .Pp .Bl -column "Cipher" "Key Length" -compact .It Em Cipher Key Length .It Li DES Ta "56 bits" .It Li 3DES Ta "168 bits" .It Li AES Ta "Variable (128 bits recommended)" .It Li BLF Ta "Variable (160 bits recommended)" .It Li CAST Ta "Variable (128 bits maximum and recommended)" .It Li SKIPJACK Ta "80 bits" .El .Pp Use of DES or SKIPJACK as an encryption algorithm is not recommended (except for backwards compatibility) due to their short key length. Furthermore, recent attacks on SKIPJACK have shown severe weaknesses in its structure. .Pp Note that DES requires 8 bytes to form a 56-bit key and 3DES requires 24 bytes to form its 168-bit key. This is because the most significant bit of each byte is ignored by both algorithms. .Ss Creating Security Associations [manual keying] Before the IPsec flows can be defined, two Security Associations (SAs) must be defined on each end of the VPN, e.g.: .Bd -literal -offset indent # ipsecadm new esp -spi $SPI_AB -src $GATEWAY_A \e -dst $GATEWAY_B -forcetunnel -enc 3des -auth sha1 \e -keyfile $ENCRYPTION_KEY_FILE \e -authkeyfile $AUTHENTICATION_KEY_FILE # ipsecadm new esp -spi $SPI_BA -src $GATEWAY_B \e -dst $GATEWAY_A -forcetunnel -enc 3des -auth sha1 \e -keyfile $ENCRYPTION_KEY_FILE \e -authkeyfile$ AUTHENTICATION_KEY_FILE .Ed .Pp Note that the .Fl key and .Fl authkey options may be used to specify the keys directly in the .Xr ipsecadm 8 command line. However, another user could view the keys by using the .Xr ps 1 command at the appropriate time (or use a program for doing so). .Ss Creating IPsec Flows [manual keying] Both IPsec gateways need to configure .Xr ipsec 4 routes with the .Xr ipsecadm 8 tool: .Pp On the security gateway of subnet A: .Bd -literal -offset indent # ipsecadm flow -out -require -proto esp \e -src $GATEWAY_A -dst $GATEWAY_B \e -addr $NETWORK_A $NETWORK_B \e # ipsecadm flow -in -require -proto esp \e -src $GATEWAY_A -dst $GATEWAY_B \e -addr $NETWORK_B $NETWORK_A \e .Ed .Pp and on the security gateway of subnet B: .Bd -literal -offset indent # ipsecadm flow -out -require -proto esp \e -src $GATEWAY_B -dst $GATEWAY_A \e -addr $NETWORK_B $NETWORK_A \e # ipsecadm flow -in -require -proto esp \e -src $GATEWAY_B -dst $GATEWAY_A \e -addr $NETWORK_A $NETWORK_B \e .Ed .Ss Configure and run the keying daemon [automated keying] Unless manual keying is used, both security gateways need to start the .Xr isakmpd 8 key management daemon. To make sure the daemon is properly configured to provide the required security services (typically, encryption and authentication) start the daemon with debugging or verbose output. .Pp .Xr isakmpd 8 implements security policy using the .Em KeyNote trust management system. .Ss Configuring Firewall Rules .Xr pf 4 needs to be configured such that all packets from the outside are blocked by default. Only successfully IPsec-processed packets (from the .Xr enc 4 interface), or key management packets (for .Xr isakmpd 8 , .Tn UDP packets with source and destination ports of 500) should be allowed to pass. .Pp The .Xr pf.conf 5 rules for a tunnel which uses encryption (the ESP IPsec protocol) and .Xr isakmpd 8 on security gateway A might look like this: .Bd -literal GATEWAY_A = "192.168.1.254/32" GATEWAY_B = "192.168.2.1/32" NETWORK_A = "10.0.50.0/24" NETWORK_B = "10.0.99.0/24" # default deny # ne0 is the only interface going to the outside. block in log on { enc0, ne0 } all block out log on { enc0, ne0 } all # Passing in encrypted traffic from security gateways pass in proto esp from $GATEWAY_B to $GATEWAY_A pass out proto esp from $GATEWAY_A to $GATEWAY_B # Passing in traffic from the designated subnets. pass in on enc0 from $NETWORK_B to $NETWORK_A pass out on enc0 from $NETWORK_A to $NETWORK_B # Passing in isakmpd(8) traffic from the security gateways pass in on ne0 proto udp from $GATEWAY_B port = 500 to $GATEWAY_A port = 500 pass out on ne0 proto udp from $GATEWAY_A port = 500 to $GATEWAY_B port = 500 .Ed .Pp If there are no other .Xr pf.conf 5 rules, the "quick" clause can be added to the last four rules. NAT rules can also be used on the .Xr enc 4 interface. Note that it is strongly encouraged that instead of detailed PF rules, the SPD (IPsec flow database) be utilized to specify security policy, if only to avoid filtering conflicts. .Sh FILES .Bl -tag -width /etc/isakmpd/isakmpd.conf -compact .It Pa /usr/share/ipsec/rc.vpn Sample VPN configuration file .It Pa /etc/isakmpd/isakmpd.conf .Xr isakmpd 8 configuration file .It Pa /etc/pf.conf Firewall configuration file .El .Sh EXAMPLES .Ss Manual keying To create a manual keyed VPN between two class C networks using 3DES encryption and the following IP addresses: .Bd -literal GATEWAY_A = 192.168.1.254 NETWORK_A = 10.0.50.0/24 GATEWAY_B = 192.168.2.1 NETWORK_B = 10.0.99.0/24 .Ed .Bl -enum .It Choose the shared secrets using a suitably random method. The 3DES encryption key needs 192 bits (3x64), or 24 bytes. The SHA-1 authentication key for needs 160 bits, or 20 bytes. .Bd -literal # openssl rand 24 | hexdump -e '24/1 "%02x"' > enc_key # openssl rand 20 | hexdump -e '20/1 "%02x"' > auth_key .Ed .It Create the Security Associations (on both endpoints): .Bd -literal # /sbin/ipsecadm new esp -src 192.168.2.1 -dst 192.168.1.254 \e -forcetunnel -spi 1000 -enc 3des -auth sha1 \e -keyfile enc_key -authkeyfile auth_key # /sbin/ipsecadm new esp -src 192.168.1.254 -dst 192.168.2.1 \e -forcetunnel -spi 1001 -enc 3des -auth sha1 \e -keyfile enc_key -authkeyfile auth_key .Ed .It Create the IPsec flows on machine A (the fist is for outbound flows, the latter is the ingress filter for the incoming security association): .Bd -literal # ipsecadm flow -out -require -proto esp \e -src 192.168.1.254 -dst 192.168.2.1 \e -addr 10.0.50.0/24 10.0.99.0/24 \e # ipsecadm flow -in -require -proto esp \e -src 192.168.1.254 -dst 192.168.2.1 \e -addr 10.0.99.0/24 10.0.50.0/24 \e .Ed .It Create the matching IPsec flows on machine B: .Bd -literal # ipsecadm flow -out -require -proto esp \e -src 192.168.1.254 -dst 192.168.2.1 \e -addr 10.0.50.0/24 10.0.99.0/24 \e # ipsecadm flow -in -require -proto esp \e -src 192.168.1.254 -dst 192.168.2.1 \e -addr 10.0.99.0/24 10.0.50.0/24 \e .Ed .It Configure the firewall rules on machine A using the previously defined ruleset: .Bd -literal GATEWAY_A = "192.168.1.254/32" GATEWAY_B = "192.168.2.1/32" NETWORK_A = "10.0.50.0/24" NETWORK_B = "10.0.99.0/24" (rest of ruleset) .Ed .It Configure the firewall rules on machine B, modifying the definitions as appropriate: .Bd -literal GATEWAY_B = "192.168.1.254/32" GATEWAY_A = "192.168.2.1/32" NETWORK_B = "10.0.50.0/24" NETWORK_A = "10.0.99.0/24" (rest of ruleset) .Ed .El .Ss Automated keying To create a VPN between the same two C class networks as the example above, using .Xr isakmpd 8 : .Bl -enum .It Create .Pa /etc/isakmpd/isakmpd.conf for machine A: .Bd -literal # Incoming phase 1 negotiations are multiplexed on the source IP # address. Phase 1 is used to set up a protected channel just # between the two gateway machines. This channel is then used for # the phase 2 negotiation traffic (i.e. encrypted & authenticated). [Phase 1] 192.168.2.1= peer-machineB # 'Phase 2' defines which connections the daemon should establish. # These connections contain the actual "IPsec VPN" information. [Phase 2] Connections= VPN-A-B # ISAKMP phase 1 peers (from [Phase 1]) [peer-machineB] Phase= 1 Transport= udp Address= 192.168.2.1 Configuration= Default-main-mode Authentication= yoursharedsecret # IPSEC phase 2 connections (from [Phase 2]) [VPN-A-B] Phase= 2 ISAKMP-peer= peer-machineB Configuration= Default-quick-mode Local-ID= machineA-internal-network Remote-ID= machineB-internal-network # ID sections (as used in [VPN-A-B]) [machineA-internal-network] ID-type= IPV4_ADDR_SUBNET Network= 10.0.50.0 Netmask= 255.255.255.0 [machineB-internal-network] ID-type= IPV4_ADDR_SUBNET Network= 10.0.99.0 Netmask= 255.255.255.0 # Main and Quick Mode descriptions (as used by peers and connections) [Default-main-mode] DOI= IPSEC EXCHANGE_TYPE= ID_PROT Transforms= 3DES-SHA,BLF-SHA [Default-quick-mode] DOI= IPSEC EXCHANGE_TYPE= QUICK_MODE Suites= QM-ESP-3DES-SHA-SUITE .Ed .Pp .It Create .Pa /etc/isakmpd/isakmpd.conf for machine B: .Bd -literal # Incoming phase 1 negotiations are multiplexed on the source IP # address. Phase 1 is used to set up a protected channel just # between the two gateway machines. This channel is then used for # the phase 2 negotiation traffic (i.e. encrypted & authenticated). [Phase 1] 192.168.1.254= peer-machineA # 'Phase 2' defines which connections the daemon should establish. # These connections contain the actual "IPsec VPN" information. [Phase 2] Connections= VPN-B-A # ISAKMP phase 1 peers (from [Phase 1]) [peer-machineA] Phase= 1 Transport= udp Address= 192.168.1.254 Configuration= Default-main-mode Authentication= yoursharedsecret # IPSEC phase 2 connections (from [Phase 2]) [VPN-B-A] Phase= 2 ISAKMP-peer= peer-machineA Configuration= Default-quick-mode Local-ID= machineB-internal-network Remote-ID= machineA-internal-network # ID sections (as used in [VPN-A-B]) [machineA-internal-network] ID-type= IPV4_ADDR_SUBNET Network= 10.0.50.0 Netmask= 255.255.255.0 [machineB-internal-network] ID-type= IPV4_ADDR_SUBNET Network= 10.0.99.0 Netmask= 255.255.255.0 # Main and Quick Mode descriptions (as used by peers and connections) [Default-main-mode] DOI= IPSEC EXCHANGE_TYPE= ID_PROT Transforms= 3DES-SHA,BLF-SHA [Default-quick-mode] DOI= IPSEC EXCHANGE_TYPE= QUICK_MODE Suites= QM-ESP-3DES-SHA-SUITE .Ed .It Read through the configuration one more time. The only real differences between the two files in this example are the IP-addresses, and ordering of Local- and Remote-ID for the VPN itself. Note that the shared secret (the .Em Authentication tag) must match between machineA and machineB. .Pp Due to the shared secret information in the configuration file, it must be installed without any permissions for "group" or "other". .Bd -literal # chmod og-rwx /etc/isakmpd/isakmpd.conf .Ed .Pp .It Create a simple .Pa /etc/isakmpd/isakmpd.policy file for machineA: .Bd -literal Keynote-version: 2 Authorizer: "POLICY" Conditions: app_domain == "IPsec policy" && esp_present == "yes" && esp_enc_alg != "null" -> "true"; .Ed .It Create a simple .Pa /etc/isakmpd/isakmpd.policy file for machineB: .Bd -literal Keynote-version: 2 Authorizer: "POLICY" Conditions: app_domain == "IPsec policy" && esp_present == "yes" && esp_enc_alg != "null" -> "true"; .Ed .It Configure the firewall rules on machines A and B: .Pp Use the same ruleset as the manual keying example, but add permission for the .Xr isakmpd 8 control traffic, on .Tn UDP port 500. .Pp For machineA, add: .Bd -literal # Permit ISAKMPD control traffic between A and B pass in proto udp from 192.168.2.1/32 to 193.127.1.254/32 port = 500 pass out proto udp from 192.168.1.254/32 to 193.127.2.1/32 port = 500 .Ed .Pp For machineB, add: .Bd -literal # Permit ISAKMPD control traffic between A and B pass in proto udp from 192.168.1.254/32 to 193.127.2.1/32 port = 500 pass out proto udp from 192.168.2.1/32 to 193.127.1.254/32 port = 500 .Ed .It Start .Xr isakmpd 8 .Pp On both machines, run: .Bd -literal # /sbin/isakmpd .Ed .Pp To run with verbose debugging enabled, instead start with: .Bd -literal # /sbin/isakmpd -d -DA=99 .Ed .El .Sh SEE ALSO .Xr openssl 1 , .Xr enc 4 , .Xr ipsec 4 , .Xr keynote 4 , .Xr options 4 , .Xr isakmpd.conf 5 , .Xr isakmpd.policy 5 , .Xr pf.conf 5 , .Xr ipsecadm 8 , .Xr isakmpd 8 , .Xr pfctl 8 , .Xr sysctl 8 .Sh BUGS In situations where the gateway IPs are outside the tunnelled network range, such as when tunnelling private (RFC 1918) networks over the Internet, .Xr isakmpd 8 or manual keying must be used.