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IPSEC(4)	       FreeBSD Kernel Interfaces Manual		      IPSEC(4)

NAME
     ipsec -- IP Security Protocol

DESCRIPTION
     IPsec is a	pair of	protocols, Encapsulating Security Payload (ESP)	and
     Authentication Header (AH), which provide security	services for IP	data-
     grams.

     Both protocols may	be enabled or disabled using the following sysctl(2)
     variables in /etc/sysctl.conf.  By	default, both protocols	are enabled:

	   net.inet.esp.enable	  Enable the ESP IPsec protocol
	   net.inet.ah.enable	  Enable the AH	IPsec protocol

     There are four main security properties provided by IPsec:

	   Confidentiality - Ensure it is hard for anyone but the receiver to
	   understand what data	has been communicated.	For example, ensuring
	   the secrecy of passwords when logging into a	remote machine over
	   the Internet.

	   Integrity - Guarantee that the data does not	get changed in tran-
	   sit.	 If you	are on a line carrying invoicing data you probably
	   want	to know	that the amounts and account numbers are correct and
	   have	not been modified by a third party.

	   Authenticity	- Sign your data so that others	can see	that it	is re-
	   ally	you that sent it.  It is clearly nice to know that documents
	   are not forged.

	   Replay protection - We need ways to ensure a	datagram is processed
	   only	once, regardless of how	many times it is received.  That is,
	   it should not be possible for an attacker to	record a transaction
	   (such as a bank account withdrawal),	and then by replaying it ver-
	   batim cause the peer	to think a new message (withdrawal request)
	   had been received.  WARNING:	as per the standard's specification,
	   replay protection is	not performed when using manual-keyed IPsec
	   (e.g. when using ipsecctl(8)).

   IPsec Protocols
     IPsec provides these services using two new protocols: Authentication
     Header (AH), and Encapsulating Security Payload (ESP).

     ESP can provide the properties authentication, integrity, replay protec-
     tion, and confidentiality of the data (it secures everything in the
     packet that follows the IP	header).  Replay protection requires authenti-
     cation and	integrity (these two always go together).  Confidentiality
     (encryption) can be used with or without authentication/integrity.	 Simi-
     larly, one	could use authentication/integrity with	or without confiden-
     tiality.

     AH	provides authentication, integrity, and	replay protection (but not
     confidentiality).	The main difference between the	authentication fea-
     tures of AH and ESP is that AH also authenticates portions	of the IP
     header of the packet (such	as the source/destination addresses).  ESP au-
     thenticates only the packet payload.

   Authentication Header (AH)
     AH	works by computing a value that	depends	on all of the payload data,
     some of the IP header data, and a certain secret value (the authentica-
     tion key).	 This value is then sent with the rest of each packet.	The
     receiver performs the same	computation, and if the	value matches, he
     knows no one tampered with	the data (integrity), the address information
     (authenticity) or a sequence number (replay protection).  He knows	this
     because the secret	authentication key makes sure no active	attacker (man-
     in-the-middle) can	recompute the correct value after altering the packet.
     The algorithms used to compute these values are called hash algorithms
     and are parameters	in the SA, just	like the authentication	key.

   Encapsulating Security Payload (ESP)
     ESP optionally does almost	everything that	AH does	except that it does
     not protect the outer IP header but furthermore it	encrypts the payload
     data with an encryption algorithm using a secret encryption key.  Only
     the ones knowing this key can decrypt the data, thus providing confiden-
     tiality.  Both the	algorithm and the encryption key are parameters	of the
     SA.

   Security Associations (SAs)
     These protocols require certain parameters	for each connection, describ-
     ing exactly how the desired protection will be achieved.  These parame-
     ters are collected	in an entity called a security association, or SA for
     short.  Typical SA	parameters include encryption algorithm, hash algo-
     rithm, encryption key, and	authentication key, to name a few.  When two
     peers have	established matching SAs (one at each end), packets protected
     with one end's SA may be verified and/or decrypted	using the information
     in	the other end's	SA.  The only issue remaining is to ensure that	both
     ends have matching	SAs.  This may be done manually, or automatically us-
     ing a key management daemon.

     Further information on manual SA establishment is described in
     ipsec.conf(5).  Information on automated key management for IKEv1 can be
     found in isakmpd(8) and for IKEv2 in iked.conf(5).

   Security Parameter Indexes (SPIs)
     In	order to identify an SA	we need	to have	a unique name for it.  This
     name is a triplet,	consisting of the destination address, security	param-
     eter index	(aka SPI) and the security protocol (ESP or AH).  Since	the
     destination address is part of the	name, an SA is necessarily a unidirec-
     tional construct.	For a bidirectional communication channel, two SAs are
     required, one outgoing and	one incoming, where the	destination address is
     our local IP address.  The	SPI is just a number that helps	us make	the
     name unique; it can be arbitrarily	chosen in the range 0x100 -
     0xffffffff.  The security protocol	number should be 50 for	ESP and	51 for
     AH, as these are the protocol numbers assigned by IANA.

   Modes of Operation
     IPsec can operate in two modes, either tunnel or transport	mode.  In
     transport mode the	ordinary IP header is used to deliver the packets to
     their endpoint; in	tunnel mode the	ordinary IP header just	tells us the
     address of	a security gateway which knows how to verify/decrypt the pay-
     load and forward the packet to a destination given	by another IP header
     contained in the protected	payload.  Tunnel mode can be used for estab-
     lishing virtual private networks (VPNs), where parts of the networks can
     be	spread out over	an unsafe public network, but security gateways	at
     each subnet are responsible for encrypting	and decrypting the data	pass-
     ing over the public net.  An SA will contain information specifying
     whether it	is a tunnel or transport mode SA, and for tunnels it will con-
     tain values to fill in into the outer IP header.

   Lifetimes
     The SA also holds a couple	of other parameters, especially	useful for au-
     tomatic keying, called lifetimes, which puts a limit on how much we can
     use an SA for protecting our data.	 These limits can be in	wall-clock
     time or in	volume of our data.

   IPsec Examples
     To	better illustrate how IPsec works, consider a typical TCP packet:

	   [IP header] [TCP header] [data...]

     If	we apply ESP in	transport mode to the above packet, we will get:

	   [IP header] [ESP header] [TCP header] [data...]

     Everything	after the ESP header is	protected by whatever services of ESP
     we	are using (authentication/integrity, replay protection,	confidential-
     ity).  This means the IP header itself is not protected.

     If	we apply ESP in	tunnel mode to the original packet, we would get:

	   [IP header] [ESP header] [IP	header]	[TCP header] [data...]

     Again, everything after the ESP header is cryptographically protected.
     Notice the	insertion of an	IP header between the ESP and TCP header.
     This mode of operation allows us to hide who the true source and destina-
     tion addresses of a packet	are (since the protected and the unprotected
     IP	headers	don't have to be exactly the same).  A typical application of
     this is in	Virtual	Private	Networks (or VPNs), where two firewalls	use
     IPsec to secure the traffic of all	the hosts behind them.	For example:

	   Net A <---->	Firewall 1 <---	Internet ---> Firewall 2 <---->	Net B

     Firewall 1	and Firewall 2 can protect all communications between Net A
     and Net B by using	IPsec in tunnel	mode, as illustrated above.

     This implementation makes use of a	virtual	interface, enc0, which can be
     used in packet filters to specify those packets that have been or will be
     processed by IPsec.

     NAT can also be applied to	enc# interfaces, but special care should be
     taken because of the interactions between NAT and the IPsec flow match-
     ing, especially on	the packet output path.	 Inside	the TCP/IP stack,
     packets go	through	the following stages:

	   UL/R	-> [X] -> PF/NAT(enc0) -> IPsec	-> PF/NAT(IF) -> IF
	   UL/R	<-------- PF/NAT(enc0) <- IPsec	<- PF/NAT(IF) <- IF

     With IF being the real interface and UL/R the Upper Layer or Routing
     code.  The	[X] stage on the output	path represents	the point where	the
     packet is matched against the IPsec flow database (SPD) to	determine if
     and how the packet	has to be IPsec-processed.  If,	at this	point, it is
     determined	that the packet	should be IPsec-processed, it is processed by
     the PF/NAT	code.  Unless PF drops the packet, it will then	be IPsec-pro-
     cessed, even if the packet	has been modified by NAT.

     Security Associations can be set up manually with ipsecctl(8) or automat-
     ically with the isakmpd(8)	or iked(8) key management daemons.

   Additional Variables
     A number of sysctl(8) variables are relevant to ipsec.  These are gener-
     ally net.inet.ah.*, net.inet.esp.*, net.inet.ip.forwarding,
     net.inet6.ip6.forwarding, and net.inet.ip.ipsec-*.	 Full explanations can
     be	found in sysctl(2), and	variables can be set using the sysctl(8) in-
     terface.

     A number of kernel	options	are also relevant to ipsec.  See options(4)
     for further information.

   API Details
     The following IP-level setsockopt(2) and getsockopt(2) options are	spe-
     cific to ipsec.  A	socket can specify security levels for three different
     categories:

       IP_AUTH_LEVEL	     Specifies the use of authentication for packets
			     sent or received by the socket.

       IP_ESP_TRANS_LEVEL    Specifies the use of encryption in	transport mode
			     for packets sent or received by the socket.

       IP_ESP_NETWORK_LEVEL  Specifies the use of encryption in	tunnel mode.

     For each of the categories	there are five possible	levels which specify
     the security policy to use	in that	category:

       IPSEC_LEVEL_BYPASS   Bypass the default system security policy.	This
			    option can only be used by privileged processes.
			    This level is necessary for	the key	management
			    daemon, isakmpd(8).

       IPSEC_LEVEL_AVAIL    If a Security Association is available it will be
			    used for sending packets by	that socket.

       IPSEC_LEVEL_USE	    Use	IP Security for	sending	packets	but still ac-
			    cept packets which are not secured.

       IPSEC_LEVEL_REQUIRE  Use	IP Security for	sending	packets	and also re-
			    quire IP Security for received data.

       IPSEC_LEVEL_UNIQUE   The	outbound Security Association will only	be
			    used by this socket.

     When a new	socket is created, it is assigned the default system security
     level in each category.  These levels can be queried with getsockopt(2).
     Only a privileged process can lower the security level with a
     setsockopt(2) call.

     For example, a server process might want to accept	only authenticated
     connections to prevent session hijacking.	It would issue the following
     setsockopt(2) call:

	 int level = IPSEC_LEVEL_REQUIRE;
	 error = setsockopt(s, IPPROTO_IP, IP_AUTH_LEVEL, &level, sizeof(int));

     The system	does guarantee that it will succeed at establishing the	re-
     quired security associations.  In any case	a properly configured key man-
     agement daemon is required	which listens to messages from the kernel.

     A list of all security associations in the	kernel tables can be obtained
     using the ipsecctl(8) command.

DIAGNOSTICS
     A socket operation	may fail with one of the following errors returned:

     [EACCES]  An attempt was made to lower the	security level below the sys-
	       tem default by a	non-privileged process.

     [EINVAL]  The length of option field did not match	or an unknown security
	       level was given.

     netstat(1)	can be used to obtain some statistics about AH and ESP usage,
     using the -p flag.	 Using the -r flag, netstat(1) displays	information
     about IPsec flows.

     vmstat(8) displays	information about memory use by	IPsec with the -m flag
     (look for "tdb" and "xform" allocations).

SEE ALSO
     enc(4), options(4), ipsec.conf(5),	iked(8), ipsecctl(8), isakmpd(8),
     sysctl(8)

HISTORY
     IPsec was originally designed to provide security services	for Internet
     Protocol IPv6.  It	has since been engineered to provide those services
     for the original Internet Protocol, IPv4.

     The IPsec protocol	design process was started in 1992 by John Ioannidis,
     Phil Karn,	and William Allen Simpson.  In 1995, the former	wrote an im-
     plementation for BSD/OS.  Angelos D. Keromytis ported it to OpenBSD and
     NetBSD.  The latest transforms and	new features were implemented by Ange-
     los D. Keromytis and Niels	Provos.

AUTHORS
     The authors of the	IPsec code proper are John Ioannidis, Angelos D.
     Keromytis,	and Niels Provos.

     Niklas Hallqvist and Niels	Provos are the authors of isakmpd(8).

     Eric Young's libdeslite was used in this implementation for the DES algo-
     rithm.

     Steve Reid's SHA-1	code was also used.

     The setsockopt(2)/getsockopt(2) interface follows somewhat	loosely	the
     draft-mcdonald-simple-ipsec-api (since expired, but still available from
     ftp://ftp.kame.net/pub/internet-drafts/)

BUGS
     There's a lot more	to be said on this subject.  This is just a beginning.
     At	the moment the socket options are not fully implemented.

FreeBSD	13.0		       January 12, 2018			  FreeBSD 13.0

NAME | DESCRIPTION | DIAGNOSTICS | SEE ALSO | HISTORY | AUTHORS | BUGS

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