NAME
ipsec
—
IP security protocol
SYNOPSIS
options IPSEC
options IPSEC_DEBUG
DESCRIPTION
This manual pages describes the IPsec protocol. For the network device driver please see ipsecif(4).ipsec
is a security protocol in the
Internet Protocol (IP) layer. ipsec
is defined for
both IPv4 and IPv6
(inet(4) and
inet6(4)). ipsec
consists of three
sub-protocols:
- Encapsulated Security Payload (ESP)
- protects IP payloads from wire-tapping (interception) by encrypting them with secret key cryptography algorithms.
- Authentication Header (AH)
- guarantees the integrity of IP packets and protects them from intermediate alteration or impersonation, by attaching cryptographic checksums computed by one-way hash functions.
- IP Payload Compression Protocol (IPComp)
- increases the communication performance by compressing the datagrams.
ipsec
has two operation modes:
- Transport mode
- is for protecting peer-to-peer communication between end nodes.
- Tunnel mode
- includes IP-in-IP encapsulation operation and is designed for security gateways, as in Virtual Private Network (VPN) configurations.
Kernel interface
ipsec
is controlled by two engines in the
kernel: one for key management and one for policy.
The key management engine can be accessed from userland by using
PF_KEY
sockets. The PF_KEY
socket API is defined in RFC2367.
The policy engine can be controlled through the
PF_KEY
API,
setsockopt(2) operations, and the
sysctl(3) interface. The kernel implements an extended version of the
PF_KEY
interface and allows you to define IPsec
policy like per-packet filters.
setsockopt(2) is used to define per-socket behavior, and
sysctl(3) is used to define host-wide default behavior.
The kernel does not implement dynamic encryption key exchange protocols like IKE (Internet Key Exchange). That should be done in userland (usually as a daemon), using the APIs described above.
Policy management
The kernel implements experimental policy management code. You can
manage the IPsec policy in two ways. One is to configure per-socket policy
using setsockopt(2). The other is to configure kernel packet
filter-based policy using the PF_KEY
interface, via
setkey(8). In both cases, IPsec policy must be specified with syntax
described in
ipsec_set_policy(3).
With setsockopt(2), you can define IPsec policy on a per-socket basis. You can enforce particular IPsec policy on packets that go through a particular socket.
With setkey(8) you can define IPsec policy for packets using a form of packet filtering rules. See setkey(8) for details.
In the latter case,
“default
” policy is allowed for use
with setkey(8). By configuring policy to default
,
you can refer to system-wide
sysctl(8) variables for default settings. The following variables are
available. 1
means
“use
”, and 2
means “require
” in the syntax.
Name | Type | Changeable |
net.inet.ipsec.esp_trans_deflev | integer | yes |
net.inet.ipsec.esp_net_deflev | integer | yes |
net.inet.ipsec.ah_trans_deflev | integer | yes |
net.inet.ipsec.ah_net_deflev | integer | yes |
net.inet6.ipsec6.esp_trans_deflev | integer | yes |
net.inet6.ipsec6.esp_net_deflev | integer | yes |
net.inet6.ipsec6.ah_trans_deflev | integer | yes |
net.inet6.ipsec6.ah_net_deflev | integer | yes |
If the kernel finds no matching policy, the system-wide default
value is applied. System-wide defaults are specified by the following
sysctl(8) variables. 0
means
“discard
” which asks the kernel to
drop the packet. 1
means
“none
”.
Name | Type | Changeable |
net.inet.ipsec.def_policy | integer | yes |
net.inet6.ipsec6.def_policy | integer | yes |
Miscellaneous sysctl variables
The following variables are accessible via sysctl(8), for tweaking kernel IPsec behavior:
Name | Type | Changeable |
net.inet.ipsec.ah_cleartos | integer | yes |
net.inet.ipsec.ah_offsetmask | integer | yes |
net.inet.ipsec.crypto_support | integer | yes |
net.inet.ipsec.dfbit | integer | yes |
net.inet.ipsec.ecn | integer | yes |
net.inet.ipsec.debug | integer | yes |
net.inet6.ipsec6.ecn | integer | yes |
net.inet6.ipsec6.debug | integer | yes |
The variables are interpreted as follows:
ipsec.ah_cleartos
- If set to non-zero, the kernel clears the type-of-service field in the IPv4 header during AH authentication data computation. The variable is for tweaking AH behavior to interoperate with devices that implement RFC1826 AH. It should be set to non-zero (clear the type-of-service field) for RFC2402 conformance.
ipsec.ah_offsetmask
- During AH authentication data computation, the kernel will include a 16 bit fragment offset field (including flag bits) in the IPv4 header, after computing logical AND with the variable. The variable is for tweaking AH behavior to interoperate with devices that implement RFC1826 AH. It should be set to zero (clear the fragment offset field during computation) for RFC2402 conformance.
ipsec.crypto_support
- This variable configures the kernel behavior for selecting encryption drivers. If set to > 0, the kernel will select a hardware encryption driver first. If set to < 0, the kernel will select a software encryption driver first. If set to 0, the kernel will select either a hardware or software driver.
ipsec.dfbit
- This variable configures the kernel behavior on IPv4 IPsec tunnel encapsulation. If set to 0, the DF bit on the outer IPv4 header will be cleared. 1 means that the outer DF bit is set from the inner DF bit. 2 means that the DF bit is copied from the inner header to the outer. The variable is supplied to conform to RFC2401 chapter 6.1.
ipsec.ecn
- If set to non-zero, IPv4 IPsec tunnel encapsulation/decapsulation behavior
will be friendly to ECN (explicit congestion notification), as documented
in
draft-ietf-ipsec-ecn-02.txt
. gif(4) talks more about the behavior. ipsec.debug
- If set to non-zero, debug messages will be generated via syslog(3).
Variables under the net.inet6.ipsec6
tree
have similar meanings to their net.inet.ipsec
counterparts.
Cryptographic operations
The current IPsec implementation, formerly called Fast IPsec, uses the opencrypto(9) subsystem to carry out cryptographic operations. This means, in particular, that cryptographic hardware devices are employed whenever possible to optimize the performance of sub-protocols.
System configuration requires the opencrypto(9) subsystem. When the Fast IPsec protocols are configured for use, all protocols are included in the system. To selectively enable/disable protocols, use sysctl(8).
PROTOCOLS
The ipsec
protocol works like a plug-in to
inet(4) and
inet6(4) protocols. Therefore, ipsec
supports
most of the protocols defined upon those IP-layer protocols. Some of the
protocols, like icmp(4) or
icmp6(4), may behave differently with ipsec
.
This is because ipsec
can prevent
icmp(4) or
icmp6(4) routines from looking into IP payload.
SEE ALSO
ioctl(2), socket(2), ipsec_set_policy(3), icmp6(4), intro(4), ip6(4), ipsecif(4), racoon(8), setkey(8), sysctl(8)
STANDARDS
Daniel L. McDonald, Craig Metz, and Bao G. Phan, PF_KEY Key Management API, Version 2, RFC, 2367.
HISTORY
The protocols draw heavily on the OpenBSD implementation of the IPsec protocols. The policy management code is derived from the KAME implementation found in their IPsec protocols. The Fast IPsec protocols are based on code which appeared in FreeBSD 4.7. The NetBSD version is a close copy of the FreeBSD original, and first appeared in NetBSD 2.0.
Support for IPv6 and IPcomp protocols has been added in NetBSD 4.0.
Support for Network Address Translator Traversal as described in RFCs 3947 and 3948 has been added in NetBSD 5.0.
Since NetBSD 6.0, the IPsec implementation formerly known as Fast IPsec is used.
BUGS
IPsec support is subject to change as the IPsec protocols develop.
There is no single standard for policy engine API, so the policy engine API described herein is just for the version introduced by KAME.
AH and tunnel mode encapsulation may not work as you might expect.
If you configure inbound “require” policy against AH tunnel or
any IPsec encapsulating policy with AH (like
“esp/tunnel/A-B/use
ah/transport/A-B/require
”), tunneled packets will be rejected.
This is because we enforce policy check on inner packet on reception, and AH
authenticates encapsulating (outer) packet, not the encapsulated (inner)
packet (so for the receiving kernel there's no sign of authenticity). The
issue will be solved when we revamp our policy engine to keep all the packet
decapsulation history.
Under certain condition, truncated result may be raised from the
kernel against SADB_DUMP
and
SADB_SPDDUMP
operation on
PF_KEY
socket. This occurs if there are too many
database entries in the kernel and socket buffer for the
PF_KEY
socket is insufficient. If you manipulate
many IPsec key/policy database entries, increase the size of socket buffer
or use sysctl(8) interface.
Certain legacy authentication algorithms are not supported because of issues with the opencrypto(9) subsystem.