IPSEC_SET_POLICY(3) BSD Library Functions Manual IPSEC_SET_POLICY(3)NAME
ipsec_set_policy, ipsec_get_policylen, ipsec_dump_policy — manipulate
IPsec policy specification structure from human-readable policy string
LIBRARY
IPsec Policy Control Library (libipsec, -lipsec)
SYNOPSIS
#include <netipsec/ipsec.h>
char *
ipsec_set_policy(const char *policy, int len);
int
ipsec_get_policylen(char *buf);
char *
ipsec_dump_policy(char *buf, const char *delim);
DESCRIPTIONipsec_set_policy() generates an IPsec policy specification structure,
namely struct sadb_x_policy and/or struct sadb_x_ipsecrequest from a
human-readable policy specification. The policy specification must be
given as a C string policy and its length len. ipsec_set_policy() will
return a buffer with the corresponding IPsec policy specification struc‐
ture. The buffer is dynamically allocated, and must be free(3)'d by the
caller.
You can get the length of the generated buffer with ipsec_get_policylen()
(i.e. for calling setsockopt(2)).
ipsec_dump_policy() converts an IPsec policy structure into human-read‐
able form. Therefore, ipsec_dump_policy() can be regarded as the inverse
function to ipsec_set_policy(). buf points to an IPsec policy structure,
struct sadb_x_policy. delim is a delimiter string, which is usually a
blank character. If you set delim to NULL, a single whitespace is
assumed. ipsec_dump_policy() returns a pointer to a dynamically allo‐
cated string. It is the caller's responsibility to free(3) it.
policy is formatted as either of the following:
direction [priority specification] discard
direction must be in, out, or fwd. direction specifies in which
direction the policy needs to be applied. The non-standard
direction fwd is substituted with in on platforms which do not
support forward policies.
priority specification is used to control the placement of the
policy within the SPD. The policy position is determined by a
signed integer where higher priorities indicate the policy is
placed closer to the beginning of the list and lower priorities
indicate the policy is placed closer to the end of the list.
Policies with equal priorities are added at the end of the group
of such policies.
Priority can only be specified when libipsec has been compiled
against kernel headers that support policy priorities (Linux >=
2.6.6). It takes one of the following formats:
{priority,prio} offset
offset is an integer in the range
-2147483647..214783648.
{priority,prio} base {+,-} offset
base is either low (-1073741824), def (0), or high
(1073741824).
offset is an unsigned integer. It can be up to
1073741824 for positive offsets, and up to 1073741823
for negative offsets.
The interpretation of policy priority in these functions and the
kernel DOES differ. The relationship between the two can be
described as p(kernel) = 0x80000000 - p(func)
With discard policy, packets will be dropped if they match the
policy.
direction [priority specification] entrust
entrust means to consult the SPD defined by setkey(8).
direction [priority specification] bypass
bypass means to bypass the IPsec processing. (the packet will
be transmitted in clear). This is for privileged sockets.
direction [priority specification] ipsec request ...
ipsec means that the matching packets are subject to IPsec pro‐
cessing. ipsec can be followed by one or more request strings,
which are formatted as below:
protocol / mode / src - dst [/level]
protocol is either ah, esp, or ipcomp.
mode is either transport or tunnel.
src and dst specifies the IPsec endpoint. src always
means the “sending node” and dst always means the
“receiving node”. Therefore, when direction is in, dst
is this node and src is the other node (peer). If mode
is transport, Both src and dst can be omitted.
level must be set to one of the following: default,
use, require, or unique. default means that the kernel
should consult the system default policy defined by
sysctl(8), such as net.inet.ipsec.esp_trans_deflev.
See ipsec(4) regarding the system default. use means
that a relevant SA can be used when available, since
the kernel may perform IPsec operation against packets
when possible. In this case, packets can be transmit‐
ted in clear (when SA is not available), or encrypted
(when SA is available). require means that a relevant
SA is required, since the kernel must perform IPsec
operation against packets. unique is the same as
require, but adds the restriction that the SA for out‐
bound traffic is used only for this policy. You may
need the identifier in order to relate the policy and
the SA when you define the SA by manual keying. You
can put the decimal number as the identifier after
unique like unique: number. number must be between 1
and 32767 . If the request string is kept unambiguous,
level and slash prior to level can be omitted. How‐
ever, it is encouraged to specify them explicitly to
avoid unintended behavior. If level is omitted, it
will be interpreted as default.
Note that there are slight differences to the specification of
setkey(8). In the specification of setkey(8), both entrust and
bypass are not used. Refer to setkey(8) for details.
Here are several examples (long lines are wrapped for
readability):
in discard
out ipsec esp/transport//require
in ipsec ah/transport//require
out ipsec esp/tunnel/10.1.1.2-10.1.1.1/use
in ipsec ipcomp/transport//use
esp/transport//use
RETURN VALUESipsec_set_policy() returns a pointer to the allocated buffer with the
policy specification if successful; otherwise a NULL pointer is returned.
ipsec_get_policylen() returns a positive value (meaning the buffer size)
on success, and a negative value on errors. ipsec_dump_policy() returns
a pointer to a dynamically allocated region on success, and NULL on
errors.
SEE ALSOipsec_strerror(3), ipsec(4), setkey(8)HISTORY
The functions first appeared in the WIDE/KAME IPv6 protocol stack kit.
BSD January 4, 2012 BSD