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strongswan/src/libcharon/sa/ike_sa.c

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/*
* Copyright (C) 2006-2020 Tobias Brunner
* Copyright (C) 2006 Daniel Roethlisberger
* Copyright (C) 2005-2009 Martin Willi
* Copyright (C) 2005 Jan Hutter
* HSR Hochschule fuer Technik Rapperswil
*
* 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.
*/
/*
* Copyright (c) 2014 Volker Rümelin
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include <string.h>
#include <sys/stat.h>
#include <errno.h>
#include <time.h>
#include "ike_sa.h"
#include <library.h>
#include <daemon.h>
#include <collections/array.h>
#include <utils/lexparser.h>
#include <processing/jobs/retransmit_job.h>
#include <processing/jobs/delete_ike_sa_job.h>
#include <processing/jobs/send_dpd_job.h>
#include <processing/jobs/send_keepalive_job.h>
#include <processing/jobs/rekey_ike_sa_job.h>
#include <processing/jobs/retry_initiate_job.h>
#include <sa/ikev2/tasks/ike_auth_lifetime.h>
#include <sa/ikev2/tasks/ike_reauth_complete.h>
#include <sa/ikev2/tasks/ike_redirect.h>
#include <credentials/sets/auth_cfg_wrapper.h>
#ifdef ME
#include <sa/ikev2/tasks/ike_me.h>
#include <processing/jobs/initiate_mediation_job.h>
#endif
ENUM(ike_sa_state_names, IKE_CREATED, IKE_DESTROYING,
"CREATED",
"CONNECTING",
"ESTABLISHED",
"PASSIVE",
"REKEYING",
"REKEYED",
"DELETING",
"DESTROYING",
);
typedef struct private_ike_sa_t private_ike_sa_t;
typedef struct attribute_entry_t attribute_entry_t;
/**
* Private data of an ike_sa_t object.
*/
struct private_ike_sa_t {
/**
* Public members
*/
ike_sa_t public;
/**
* Identifier for the current IKE_SA.
*/
ike_sa_id_t *ike_sa_id;
/**
* IKE version of this SA.
*/
ike_version_t version;
/**
* unique numerical ID for this IKE_SA.
*/
uint32_t unique_id;
/**
* Current state of the IKE_SA
*/
ike_sa_state_t state;
/**
* IKE configuration used to set up this IKE_SA
*/
ike_cfg_t *ike_cfg;
/**
* Peer and authentication information to establish IKE_SA.
*/
peer_cfg_t *peer_cfg;
/**
* currently used authentication ruleset, local
*/
auth_cfg_t *my_auth;
/**
* currently used authentication constraints, remote
*/
auth_cfg_t *other_auth;
/**
* Array of completed local authentication rounds (as auth_cfg_t)
*/
array_t *my_auths;
/**
* Array of completed remote authentication rounds (as auth_cfg_t)
*/
array_t *other_auths;
/**
* Selected IKE proposal
*/
proposal_t *proposal;
/**
* Juggles tasks to process messages
*/
task_manager_t *task_manager;
/**
* Address of local host
*/
host_t *my_host;
/**
* Address of remote host
*/
host_t *other_host;
#ifdef ME
/**
* Are we mediation server
*/
bool is_mediation_server;
/**
* Server reflexive host
*/
host_t *server_reflexive_host;
/**
* Connect ID
*/
chunk_t connect_id;
#endif /* ME */
/**
* Identification used for us
*/
identification_t *my_id;
/**
* Identification used for other
*/
identification_t *other_id;
/**
* set of extensions the peer supports
*/
ike_extension_t extensions;
/**
* set of condition flags currently enabled for this IKE_SA
*/
ike_condition_t conditions;
/**
* Array containing the child sa's of the current IKE_SA.
*/
array_t *child_sas;
/**
* keymat of this IKE_SA
*/
keymat_t *keymat;
/**
* Virtual IPs on local host
*/
array_t *my_vips;
/**
* Virtual IPs on remote host
*/
array_t *other_vips;
/**
* List of configuration attributes (attribute_entry_t)
*/
array_t *attributes;
/**
* list of peer's addresses, additional ones transmitted via MOBIKE
*/
array_t *peer_addresses;
/**
* previously value of received DESTINATION_IP hash
*/
chunk_t nat_detection_dest;
/**
* NAT keep alive interval
*/
uint32_t keepalive_interval;
/**
* Time the NAT keep alive interval may be exceeded before triggering a DPD
* instead of a NAT keep alive
*/
uint32_t keepalive_dpd_margin;
/**
* The scheduled keep alive job, if any
*/
send_keepalive_job_t *keepalive_job;
/**
* interval for retries during initiation (e.g. if DNS resolution failed),
* 0 to disable (default)
*/
uint32_t retry_initiate_interval;
/**
* TRUE if a retry_initiate_job has been queued
*/
bool retry_initiate_queued;
/**
* Timestamps for this IKE_SA
*/
uint32_t stats[STAT_MAX];
/**
* how many times we have retried so far (keyingtries)
*/
uint32_t keyingtry;
/**
* local host address to be used for IKE, set via MIGRATE kernel message
*/
host_t *local_host;
/**
* remote host address to be used for IKE, set via MIGRATE kernel message
*/
host_t *remote_host;
/**
* Flush auth configs once established?
*/
bool flush_auth_cfg;
/**
* Maximum length of a single fragment, 0 for address-specific defaults
*/
size_t fragment_size;
/**
* Whether to follow IKEv2 redirects
*/
bool follow_redirects;
/**
* Original gateway address from which we got redirected
*/
host_t *redirected_from;
/**
* Timestamps of redirect attempts to handle loops
*/
array_t *redirected_at;
/**
* Inbound interface ID
*/
uint32_t if_id_in;
/**
* Outbound interface ID
*/
uint32_t if_id_out;
};
/**
* Entry to maintain install configuration attributes during IKE_SA lifetime
*/
struct attribute_entry_t {
/** handler used to install this attribute */
attribute_handler_t *handler;
/** attribute type */
configuration_attribute_type_t type;
/** attribute data */
chunk_t data;
};
/**
* get the time of the latest traffic processed by the kernel
*/
static time_t get_use_time(private_ike_sa_t* this, bool inbound)
{
enumerator_t *enumerator;
child_sa_t *child_sa;
time_t use_time, current;
if (inbound)
{
use_time = this->stats[STAT_INBOUND];
}
else
{
use_time = this->stats[STAT_OUTBOUND];
}
enumerator = array_create_enumerator(this->child_sas);
while (enumerator->enumerate(enumerator, &child_sa))
{
child_sa->get_usestats(child_sa, inbound, &current, NULL, NULL);
use_time = max(use_time, current);
}
enumerator->destroy(enumerator);
return use_time;
}
METHOD(ike_sa_t, get_unique_id, uint32_t,
private_ike_sa_t *this)
{
return this->unique_id;
}
METHOD(ike_sa_t, get_name, char*,
private_ike_sa_t *this)
{
if (this->peer_cfg)
{
return this->peer_cfg->get_name(this->peer_cfg);
}
return "(unnamed)";
}
METHOD(ike_sa_t, get_statistic, uint32_t,
private_ike_sa_t *this, statistic_t kind)
{
if (kind < STAT_MAX)
{
return this->stats[kind];
}
return 0;
}
METHOD(ike_sa_t, set_statistic, void,
private_ike_sa_t *this, statistic_t kind, uint32_t value)
{
if (kind < STAT_MAX)
{
this->stats[kind] = value;
}
}
METHOD(ike_sa_t, get_my_host, host_t*,
private_ike_sa_t *this)
{
return this->my_host;
}
METHOD(ike_sa_t, set_my_host, void,
private_ike_sa_t *this, host_t *me)
{
DESTROY_IF(this->my_host);
this->my_host = me;
}
METHOD(ike_sa_t, get_other_host, host_t*,
private_ike_sa_t *this)
{
return this->other_host;
}
METHOD(ike_sa_t, set_other_host, void,
private_ike_sa_t *this, host_t *other)
{
DESTROY_IF(this->other_host);
this->other_host = other;
}
METHOD(ike_sa_t, get_redirected_from, host_t*,
private_ike_sa_t *this)
{
return this->redirected_from;
}
METHOD(ike_sa_t, get_peer_cfg, peer_cfg_t*,
private_ike_sa_t *this)
{
return this->peer_cfg;
}
METHOD(ike_sa_t, set_peer_cfg, void,
private_ike_sa_t *this, peer_cfg_t *peer_cfg)
{
peer_cfg->get_ref(peer_cfg);
DESTROY_IF(this->peer_cfg);
this->peer_cfg = peer_cfg;
if (!this->ike_cfg)
{
this->ike_cfg = peer_cfg->get_ike_cfg(peer_cfg);
this->ike_cfg->get_ref(this->ike_cfg);
}
this->if_id_in = peer_cfg->get_if_id(peer_cfg, TRUE);
this->if_id_out = peer_cfg->get_if_id(peer_cfg, FALSE);
allocate_unique_if_ids(&this->if_id_in, &this->if_id_out);
}
METHOD(ike_sa_t, get_auth_cfg, auth_cfg_t*,
private_ike_sa_t *this, bool local)
{
if (local)
{
return this->my_auth;
}
return this->other_auth;
}
METHOD(ike_sa_t, add_auth_cfg, void,
private_ike_sa_t *this, bool local, auth_cfg_t *cfg)
{
if (local)
{
array_insert(this->my_auths, ARRAY_TAIL, cfg);
}
else
{
array_insert(this->other_auths, ARRAY_TAIL, cfg);
}
}
METHOD(ike_sa_t, create_auth_cfg_enumerator, enumerator_t*,
private_ike_sa_t *this, bool local)
{
if (local)
{
return array_create_enumerator(this->my_auths);
}
return array_create_enumerator(this->other_auths);
}
/**
* Flush the stored authentication round information
*/
static void flush_auth_cfgs(private_ike_sa_t *this)
{
auth_cfg_t *cfg;
this->my_auth->purge(this->my_auth, FALSE);
this->other_auth->purge(this->other_auth, FALSE);
while (array_remove(this->my_auths, ARRAY_TAIL, &cfg))
{
cfg->destroy(cfg);
}
while (array_remove(this->other_auths, ARRAY_TAIL, &cfg))
{
cfg->destroy(cfg);
}
}
METHOD(ike_sa_t, verify_peer_certificate, bool,
private_ike_sa_t *this)
{
enumerator_t *e1, *e2, *certs;
auth_cfg_t *cfg, *cfg_done;
certificate_t *peer, *cert;
public_key_t *key;
auth_cfg_t *auth;
auth_cfg_wrapper_t *wrapper;
time_t not_before, not_after;
bool valid = TRUE, found;
if (this->state != IKE_ESTABLISHED)
{
DBG1(DBG_IKE, "unable to verify peer certificate in state %N",
ike_sa_state_names, this->state);
return FALSE;
}
if (!this->flush_auth_cfg &&
lib->settings->get_bool(lib->settings,
"%s.flush_auth_cfg", FALSE, lib->ns))
{ /* we can do this check only once if auth configs are flushed */
DBG1(DBG_IKE, "unable to verify peer certificate as authentication "
"information has been flushed");
return FALSE;
}
this->public.set_condition(&this->public, COND_ONLINE_VALIDATION_SUSPENDED,
FALSE);
e1 = this->peer_cfg->create_auth_cfg_enumerator(this->peer_cfg, FALSE);
e2 = array_create_enumerator(this->other_auths);
while (e1->enumerate(e1, &cfg))
{
if (!e2->enumerate(e2, &cfg_done))
{ /* this should not happen as the authentication should never have
* succeeded */
valid = FALSE;
break;
}
if ((uintptr_t)cfg_done->get(cfg_done,
AUTH_RULE_AUTH_CLASS) != AUTH_CLASS_PUBKEY)
{
continue;
}
peer = cfg_done->get(cfg_done, AUTH_RULE_SUBJECT_CERT);
if (!peer)
{
DBG1(DBG_IKE, "no subject certificate found, skipping certificate "
"verification");
continue;
}
if (!peer->get_validity(peer, NULL, &not_before, &not_after))
{
DBG1(DBG_IKE, "peer certificate invalid (valid from %T to %T)",
&not_before, FALSE, &not_after, FALSE);
valid = FALSE;
break;
}
key = peer->get_public_key(peer);
if (!key)
{
DBG1(DBG_IKE, "unable to retrieve public key, skipping certificate "
"verification");
continue;
}
DBG1(DBG_IKE, "verifying peer certificate");
/* serve received certificates */
wrapper = auth_cfg_wrapper_create(cfg_done);
lib->credmgr->add_local_set(lib->credmgr, &wrapper->set, FALSE);
certs = lib->credmgr->create_trusted_enumerator(lib->credmgr,
key->get_type(key), peer->get_subject(peer), TRUE);
key->destroy(key);
found = FALSE;
while (certs->enumerate(certs, &cert, &auth))
{
if (peer->equals(peer, cert))
{
cfg_done->add(cfg_done, AUTH_RULE_CERT_VALIDATION_SUSPENDED,
FALSE);
cfg_done->merge(cfg_done, auth, FALSE);
valid = cfg_done->complies(cfg_done, cfg, TRUE);
found = TRUE;
break;
}
}
certs->destroy(certs);
lib->credmgr->remove_local_set(lib->credmgr, &wrapper->set);
wrapper->destroy(wrapper);
if (!found || !valid)
{
valid = FALSE;
break;
}
}
e1->destroy(e1);
e2->destroy(e2);
if (this->flush_auth_cfg)
{
this->flush_auth_cfg = FALSE;
flush_auth_cfgs(this);
}
return valid;
}
METHOD(ike_sa_t, get_proposal, proposal_t*,
private_ike_sa_t *this)
{
return this->proposal;
}
METHOD(ike_sa_t, set_proposal, void,
private_ike_sa_t *this, proposal_t *proposal)
{
DESTROY_IF(this->proposal);
this->proposal = proposal->clone(proposal, 0);
}
METHOD(ike_sa_t, set_message_id, void,
private_ike_sa_t *this, bool initiate, uint32_t mid)
{
if (initiate)
{
this->task_manager->reset(this->task_manager, mid, UINT_MAX);
}
else
{
this->task_manager->reset(this->task_manager, UINT_MAX, mid);
}
}
METHOD(ike_sa_t, get_message_id, uint32_t,
private_ike_sa_t *this, bool initiate)
{
return this->task_manager->get_mid(this->task_manager, initiate);
}
METHOD(ike_sa_t, send_keepalive, void,
private_ike_sa_t *this, bool scheduled)
{
time_t last_out, now, diff;
if (scheduled)
{
this->keepalive_job = NULL;
}
if (!this->keepalive_interval || this->state == IKE_PASSIVE)
{ /* keepalives disabled either by configuration or for passive IKE_SAs */
return;
}
if (!(this->conditions & COND_NAT_HERE) || (this->conditions & COND_STALE))
{ /* disable keepalives if we are not NATed anymore, or the SA is stale */
return;
}
last_out = get_use_time(this, FALSE);
now = time_monotonic(NULL);
diff = now - last_out;
if (this->keepalive_dpd_margin &&
diff > (this->keepalive_interval + this->keepalive_dpd_margin))
{
if (!this->task_manager->busy(this->task_manager))
{
DBG1(DBG_IKE, "sending DPD instead of keep alive %ds after last "
"outbound message", diff);
this->task_manager->queue_dpd(this->task_manager);
this->task_manager->initiate(this->task_manager);
}
diff = 0;
}
else if (diff >= this->keepalive_interval)
{
packet_t *packet;
chunk_t data;
packet = packet_create();
packet->set_source(packet, this->my_host->clone(this->my_host));
packet->set_destination(packet, this->other_host->clone(this->other_host));
data.ptr = malloc(1);
data.ptr[0] = 0xFF;
data.len = 1;
packet->set_data(packet, data);
DBG1(DBG_IKE, "sending keep alive to %#H", this->other_host);
charon->sender->send_no_marker(charon->sender, packet);
this->stats[STAT_OUTBOUND] = now;
diff = 0;
}
if (!this->keepalive_job)
{
this->keepalive_job = send_keepalive_job_create(this->ike_sa_id);
lib->scheduler->schedule_job(lib->scheduler, (job_t*)this->keepalive_job,
this->keepalive_interval - diff);
}
}
METHOD(ike_sa_t, get_ike_cfg, ike_cfg_t*,
private_ike_sa_t *this)
{
return this->ike_cfg;
}
METHOD(ike_sa_t, set_ike_cfg, void,
private_ike_sa_t *this, ike_cfg_t *ike_cfg)
{
DESTROY_IF(this->ike_cfg);
ike_cfg->get_ref(ike_cfg);
this->ike_cfg = ike_cfg;
}
METHOD(ike_sa_t, enable_extension, void,
private_ike_sa_t *this, ike_extension_t extension)
{
this->extensions |= extension;
}
METHOD(ike_sa_t, supports_extension, bool,
private_ike_sa_t *this, ike_extension_t extension)
{
return (this->extensions & extension) != FALSE;
}
METHOD(ike_sa_t, has_condition, bool,
private_ike_sa_t *this, ike_condition_t condition)
{
return (this->conditions & condition) != FALSE;
}
METHOD(ike_sa_t, set_condition, void,
private_ike_sa_t *this, ike_condition_t condition, bool enable)
{
if (has_condition(this, condition) != enable)
{
if (enable)
{
this->conditions |= condition;
switch (condition)
{
case COND_NAT_HERE:
DBG1(DBG_IKE, "local host is behind NAT, sending keep alives");
this->conditions |= COND_NAT_ANY;
send_keepalive(this, FALSE);
break;
case COND_NAT_THERE:
DBG1(DBG_IKE, "remote host is behind NAT");
this->conditions |= COND_NAT_ANY;
break;
case COND_NAT_FAKE:
DBG1(DBG_IKE, "faking NAT situation to enforce UDP encapsulation");
this->conditions |= COND_NAT_ANY;
break;
default:
break;
}
}
else
{
this->conditions &= ~condition;
switch (condition)
{
case COND_NAT_HERE:
case COND_NAT_THERE:
DBG1(DBG_IKE, "%s host is not behind NAT anymore",
condition == COND_NAT_HERE ? "local" : "remote");
/* fall-through */
case COND_NAT_FAKE:
set_condition(this, COND_NAT_ANY,
has_condition(this, COND_NAT_HERE) ||
has_condition(this, COND_NAT_THERE) ||
has_condition(this, COND_NAT_FAKE));
break;
case COND_STALE:
send_keepalive(this, FALSE);
break;
default:
break;
}
}
}
}
METHOD(ike_sa_t, send_dpd, status_t,
private_ike_sa_t *this)
{
job_t *job;
time_t diff, delay;
bool task_queued = FALSE;
if (this->state == IKE_PASSIVE)
{
return INVALID_STATE;
}
if (this->version == IKEV1 && this->state == IKE_REKEYING)
{ /* don't send DPDs for rekeyed IKEv1 SAs */
return SUCCESS;
}
delay = this->peer_cfg->get_dpd(this->peer_cfg);
if (this->task_manager->busy(this->task_manager))
{
/* an exchange is in the air, no need to start a DPD check */
diff = 0;
}
else
{
/* check if there was any inbound traffic */
time_t last_in, now;
last_in = get_use_time(this, TRUE);
now = time_monotonic(NULL);
diff = now - last_in;
if (!delay || diff >= delay)
{
/* too long ago, initiate dead peer detection */
DBG1(DBG_IKE, "sending DPD request");
this->task_manager->queue_dpd(this->task_manager);
task_queued = TRUE;
diff = 0;
}
}
/* recheck in "interval" seconds */
if (delay)
{
job = (job_t*)send_dpd_job_create(this->ike_sa_id);
lib->scheduler->schedule_job(lib->scheduler, job, delay - diff);
}
if (task_queued)
{
return this->task_manager->initiate(this->task_manager);
}
return SUCCESS;
}
METHOD(ike_sa_t, get_state, ike_sa_state_t,
private_ike_sa_t *this)
{
return this->state;
}
METHOD(ike_sa_t, set_state, void,
private_ike_sa_t *this, ike_sa_state_t state)
{
bool trigger_dpd = FALSE, keepalives = FALSE;
DBG2(DBG_IKE, "IKE_SA %s[%d] state change: %N => %N",
get_name(this), this->unique_id,
ike_sa_state_names, this->state,
ike_sa_state_names, state);
switch (state)
{
case IKE_ESTABLISHED:
{
if (this->state == IKE_CONNECTING ||
this->state == IKE_PASSIVE)
{
job_t *job;
uint32_t t;
/* calculate rekey, reauth and lifetime */
this->stats[STAT_ESTABLISHED] = time_monotonic(NULL);
/* schedule rekeying if we have a time which is smaller than
* an already scheduled rekeying */
t = this->peer_cfg->get_rekey_time(this->peer_cfg, TRUE);
if (t && (this->stats[STAT_REKEY] == 0 ||
(this->stats[STAT_REKEY] > t + this->stats[STAT_ESTABLISHED])))
{
this->stats[STAT_REKEY] = t + this->stats[STAT_ESTABLISHED];
job = (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, FALSE);
lib->scheduler->schedule_job(lib->scheduler, job, t);
DBG1(DBG_IKE, "scheduling rekeying in %ds", t);
}
t = this->peer_cfg->get_reauth_time(this->peer_cfg, TRUE);
if (t && (this->stats[STAT_REAUTH] == 0 ||
(this->stats[STAT_REAUTH] > t + this->stats[STAT_ESTABLISHED])))
{
this->stats[STAT_REAUTH] = t + this->stats[STAT_ESTABLISHED];
job = (job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE);
lib->scheduler->schedule_job(lib->scheduler, job, t);
DBG1(DBG_IKE, "scheduling reauthentication in %ds", t);
}
t = this->peer_cfg->get_over_time(this->peer_cfg);
if (this->stats[STAT_REKEY] || this->stats[STAT_REAUTH])
{
if (this->stats[STAT_REAUTH] == 0)
{
this->stats[STAT_DELETE] = this->stats[STAT_REKEY];
}
else if (this->stats[STAT_REKEY] == 0)
{
this->stats[STAT_DELETE] = this->stats[STAT_REAUTH];
}
else
{
this->stats[STAT_DELETE] = min(this->stats[STAT_REKEY],
this->stats[STAT_REAUTH]);
}
this->stats[STAT_DELETE] += t;
t = this->stats[STAT_DELETE] - this->stats[STAT_ESTABLISHED];
job = (job_t*)delete_ike_sa_job_create(this->ike_sa_id, TRUE);
lib->scheduler->schedule_job(lib->scheduler, job, t);
DBG1(DBG_IKE, "maximum IKE_SA lifetime %ds", t);
}
trigger_dpd = this->peer_cfg->get_dpd(this->peer_cfg);
if (trigger_dpd)
{
/* Some peers delay the DELETE after rekeying an IKE_SA.
* If this delay is longer than our DPD delay, we would
* send a DPD request here. The IKE_SA is not ready to do
* so yet, so prevent that. */
this->stats[STAT_INBOUND] = this->stats[STAT_ESTABLISHED];
}
if (this->state == IKE_PASSIVE)
{
keepalives = TRUE;
}
DESTROY_IF(this->redirected_from);
this->redirected_from = NULL;
}
break;
}
default:
break;
}
charon->bus->ike_state_change(charon->bus, &this->public, state);
this->state = state;
if (trigger_dpd)
{
if (supports_extension(this, EXT_DPD))
{
send_dpd(this);
}
else
{
DBG1(DBG_IKE, "DPD not supported by peer, disabled");
}
}
if (keepalives)
{
send_keepalive(this, FALSE);
}
}
METHOD(ike_sa_t, reset, void,
private_ike_sa_t *this, bool new_spi)
{
/* reset the initiator SPI if requested */
if (new_spi)
{
charon->ike_sa_manager->new_initiator_spi(charon->ike_sa_manager,
&this->public);
/* when starting from scratch, connect to the original peer again e.g.
* if we got redirected but weren't able to connect successfully */
if (this->redirected_from)
{
this->redirected_from->destroy(this->redirected_from);
this->redirected_from = NULL;
/* we can't restore the original value, if there was any */
DESTROY_IF(this->remote_host);
this->remote_host = NULL;
}
}
/* the responder ID is reset, as peer may choose another one */
if (this->ike_sa_id->is_initiator(this->ike_sa_id))
{
this->ike_sa_id->set_responder_spi(this->ike_sa_id, 0);
}
set_state(this, IKE_CREATED);
flush_auth_cfgs(this);
this->keymat->destroy(this->keymat);
this->keymat = keymat_create(this->version,
this->ike_sa_id->is_initiator(this->ike_sa_id));
this->task_manager->reset(this->task_manager, 0, 0);
this->task_manager->queue_ike(this->task_manager);
}
METHOD(ike_sa_t, get_keymat, keymat_t*,
private_ike_sa_t *this)
{
return this->keymat;
}
METHOD(ike_sa_t, add_virtual_ip, void,
private_ike_sa_t *this, bool local, host_t *ip)
{
if (local)
{
char *iface;
if (charon->kernel->get_interface(charon->kernel, this->my_host,
&iface))
{
DBG1(DBG_IKE, "installing new virtual IP %H", ip);
if (charon->kernel->add_ip(charon->kernel, ip, -1,
iface) == SUCCESS)
{
array_insert_create(&this->my_vips, ARRAY_TAIL, ip->clone(ip));
}
else
{
DBG1(DBG_IKE, "installing virtual IP %H failed", ip);
}
free(iface);
}
else
{
DBG1(DBG_IKE, "looking up interface for virtual IP %H failed", ip);
}
}
else
{
array_insert_create(&this->other_vips, ARRAY_TAIL, ip->clone(ip));
}
}
METHOD(ike_sa_t, clear_virtual_ips, void,
private_ike_sa_t *this, bool local)
{
array_t *vips;
host_t *vip;
vips = local ? this->my_vips : this->other_vips;
if (!local && array_count(vips))
{
charon->bus->assign_vips(charon->bus, &this->public, FALSE);
}
while (array_remove(vips, ARRAY_HEAD, &vip))
{
if (local)
{
charon->kernel->del_ip(charon->kernel, vip, -1, TRUE);
}
vip->destroy(vip);
}
}
METHOD(ike_sa_t, create_virtual_ip_enumerator, enumerator_t*,
private_ike_sa_t *this, bool local)
{
if (local)
{
return array_create_enumerator(this->my_vips);
}
return array_create_enumerator(this->other_vips);
}
METHOD(ike_sa_t, add_peer_address, void,
private_ike_sa_t *this, host_t *host)
{
array_insert_create(&this->peer_addresses, ARRAY_TAIL, host);
}
METHOD(ike_sa_t, create_peer_address_enumerator, enumerator_t*,
private_ike_sa_t *this)
{
if (this->peer_addresses)
{
return array_create_enumerator(this->peer_addresses);
}
/* in case we don't have MOBIKE */
return enumerator_create_single(this->other_host, NULL);
}
METHOD(ike_sa_t, clear_peer_addresses, void,
private_ike_sa_t *this)
{
array_destroy_offset(this->peer_addresses, offsetof(host_t, destroy));
this->peer_addresses = NULL;
}
METHOD(ike_sa_t, has_mapping_changed, bool,
private_ike_sa_t *this, chunk_t hash)
{
if (this->nat_detection_dest.ptr == NULL)
{
this->nat_detection_dest = chunk_clone(hash);
return FALSE;
}
if (chunk_equals(hash, this->nat_detection_dest))
{
return FALSE;
}
free(this->nat_detection_dest.ptr);
this->nat_detection_dest = chunk_clone(hash);
return TRUE;
}
METHOD(ike_sa_t, float_ports, void,
private_ike_sa_t *this)
{
/* even if the remote port is not 500 (e.g. because the response was natted)
* we switch the remote port if we used port 500 */
if (this->other_host->get_port(this->other_host) == IKEV2_UDP_PORT ||
this->my_host->get_port(this->my_host) == IKEV2_UDP_PORT)
{
this->other_host->set_port(this->other_host, IKEV2_NATT_PORT);
}
if (this->my_host->get_port(this->my_host) ==
charon->socket->get_port(charon->socket, FALSE))
{
this->my_host->set_port(this->my_host,
charon->socket->get_port(charon->socket, TRUE));
}
}
METHOD(ike_sa_t, update_hosts, void,
private_ike_sa_t *this, host_t *me, host_t *other, bool force)
{
host_t *new_me = NULL, *new_other = NULL;
bool silent = FALSE;
if (me == NULL)
{
me = this->my_host;
}
if (other == NULL)
{
other = this->other_host;
}
/* apply hosts on first received message */
if (this->my_host->is_anyaddr(this->my_host) ||
this->other_host->is_anyaddr(this->other_host))
{
new_me = me;
new_other = other;
silent = TRUE;
}
else
{
/* update our address in any case */
if (force && !me->equals(me, this->my_host))
{
new_me = me;
}
if (!other->equals(other, this->other_host) &&
(force || has_condition(this, COND_NAT_THERE)))
{
/* only update other's address if we are behind a static NAT,
* which we assume is the case if we are not initiator */
if (force ||
(!has_condition(this, COND_NAT_HERE) ||
!has_condition(this, COND_ORIGINAL_INITIATOR)))
{
new_other = other;
}
}
}
if (new_me || new_other)
{
enumerator_t *enumerator;
child_sa_t *child_sa;
linked_list_t *vips;
if (!silent)
{
charon->bus->ike_update(charon->bus, &this->public,
new_me ?: this->my_host,
new_other ?: this->other_host);
}
if (new_me)
{
set_my_host(this, new_me->clone(new_me));
}
if (new_other)
{
set_other_host(this, new_other->clone(new_other));
}
vips = linked_list_create_from_enumerator(
array_create_enumerator(this->my_vips));
enumerator = array_create_enumerator(this->child_sas);
while (enumerator->enumerate(enumerator, &child_sa))
{
charon->child_sa_manager->remove(charon->child_sa_manager, child_sa);
charon->child_sa_manager->add(charon->child_sa_manager,
child_sa, &this->public);
if (child_sa->update(child_sa, this->my_host, this->other_host,
vips, has_condition(this, COND_NAT_ANY)) == NOT_SUPPORTED)
{
this->public.rekey_child_sa(&this->public,
child_sa->get_protocol(child_sa),
child_sa->get_spi(child_sa, TRUE));
}
}
enumerator->destroy(enumerator);
vips->destroy(vips);
}
}
/**
* Set configured DSCP value on packet
*/
static void set_dscp(private_ike_sa_t *this, packet_t *packet)
{
ike_cfg_t *ike_cfg;
/* prefer IKE config on peer_cfg, as its selection is more accurate
* then the initial IKE config */
if (this->peer_cfg)
{
ike_cfg = this->peer_cfg->get_ike_cfg(this->peer_cfg);
}
else
{
ike_cfg = this->ike_cfg;
}
if (ike_cfg)
{
packet->set_dscp(packet, ike_cfg->get_dscp(ike_cfg));
}
}
METHOD(ike_sa_t, generate_message, status_t,
private_ike_sa_t *this, message_t *message, packet_t **packet)
{
status_t status;
if (message->is_encoded(message))
{ /* already encoded in task, but set DSCP value */
*packet = message->get_packet(message);
set_dscp(this, *packet);
return SUCCESS;
}
this->stats[STAT_OUTBOUND] = time_monotonic(NULL);
message->set_ike_sa_id(message, this->ike_sa_id);
charon->bus->message(charon->bus, message, FALSE, TRUE);
status = message->generate(message, this->keymat, packet);
if (status == SUCCESS)
{
set_dscp(this, *packet);
charon->bus->message(charon->bus, message, FALSE, FALSE);
}
return status;
}
CALLBACK(filter_fragments, bool,
private_ike_sa_t *this, enumerator_t *orig, va_list args)
{
packet_t *fragment, **packet;
VA_ARGS_VGET(args, packet);
if (orig->enumerate(orig, &fragment))
{
*packet = fragment->clone(fragment);
set_dscp(this, *packet);
return TRUE;
}
return FALSE;
}
METHOD(ike_sa_t, generate_message_fragmented, status_t,
private_ike_sa_t *this, message_t *message, enumerator_t **packets)
{
enumerator_t *fragments;
packet_t *packet;
status_t status;
bool use_frags = FALSE;
bool pre_generated = FALSE;
if (this->ike_cfg)
{
switch (this->ike_cfg->fragmentation(this->ike_cfg))
{
case FRAGMENTATION_FORCE:
use_frags = TRUE;
break;
case FRAGMENTATION_YES:
use_frags = supports_extension(this, EXT_IKE_FRAGMENTATION);
if (use_frags && this->version == IKEV1 &&
supports_extension(this, EXT_MS_WINDOWS))
{
/* It seems Windows 7 and 8 peers only accept proprietary
* fragmented messages if they expect certificates. */
use_frags = message->get_payload(message,
PLV1_CERTIFICATE) != NULL;
}
break;
default:
break;
}
}
if (!use_frags)
{
status = generate_message(this, message, &packet);
if (status != SUCCESS)
{
return status;
}
*packets = enumerator_create_single(packet, NULL);
return SUCCESS;
}
pre_generated = message->is_encoded(message);
this->stats[STAT_OUTBOUND] = time_monotonic(NULL);
message->set_ike_sa_id(message, this->ike_sa_id);
if (!pre_generated)
{
charon->bus->message(charon->bus, message, FALSE, TRUE);
}
status = message->fragment(message, this->keymat, this->fragment_size,
&fragments);
if (status == SUCCESS)
{
if (!pre_generated)
{
charon->bus->message(charon->bus, message, FALSE, FALSE);
}
*packets = enumerator_create_filter(fragments, filter_fragments,
this, NULL);
}
return status;
}
METHOD(ike_sa_t, set_kmaddress, void,
private_ike_sa_t *this, host_t *local, host_t *remote)
{
DESTROY_IF(this->local_host);
DESTROY_IF(this->remote_host);
this->local_host = local->clone(local);
this->remote_host = remote->clone(remote);
}
#ifdef ME
METHOD(ike_sa_t, act_as_mediation_server, void,
private_ike_sa_t *this)
{
charon->mediation_manager->update_sa_id(charon->mediation_manager,
this->other_id, this->ike_sa_id);
this->is_mediation_server = TRUE;
}
METHOD(ike_sa_t, get_server_reflexive_host, host_t*,
private_ike_sa_t *this)
{
return this->server_reflexive_host;
}
METHOD(ike_sa_t, set_server_reflexive_host, void,
private_ike_sa_t *this, host_t *host)
{
DESTROY_IF(this->server_reflexive_host);
this->server_reflexive_host = host;
}
METHOD(ike_sa_t, get_connect_id, chunk_t,
private_ike_sa_t *this)
{
return this->connect_id;
}
METHOD(ike_sa_t, respond, status_t,
private_ike_sa_t *this, identification_t *peer_id, chunk_t connect_id)
{
ike_me_t *task = ike_me_create(&this->public, TRUE);
task->respond(task, peer_id, connect_id);
this->task_manager->queue_task(this->task_manager, (task_t*)task);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, callback, status_t,
private_ike_sa_t *this, identification_t *peer_id)
{
ike_me_t *task = ike_me_create(&this->public, TRUE);
task->callback(task, peer_id);
this->task_manager->queue_task(this->task_manager, (task_t*)task);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, relay, status_t,
private_ike_sa_t *this, identification_t *requester, chunk_t connect_id,
chunk_t connect_key, linked_list_t *endpoints, bool response)
{
ike_me_t *task = ike_me_create(&this->public, TRUE);
task->relay(task, requester, connect_id, connect_key, endpoints, response);
this->task_manager->queue_task(this->task_manager, (task_t*)task);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, initiate_mediation, status_t,
private_ike_sa_t *this, peer_cfg_t *mediated_cfg)
{
ike_me_t *task = ike_me_create(&this->public, TRUE);
task->connect(task, mediated_cfg->get_peer_id(mediated_cfg));
this->task_manager->queue_task(this->task_manager, (task_t*)task);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, initiate_mediated, status_t,
private_ike_sa_t *this, host_t *me, host_t *other, chunk_t connect_id)
{
set_my_host(this, me->clone(me));
set_other_host(this, other->clone(other));
chunk_free(&this->connect_id);
this->connect_id = chunk_clone(connect_id);
return this->task_manager->initiate(this->task_manager);
}
#endif /* ME */
/**
* Resolve DNS host in configuration
*/
static void resolve_hosts(private_ike_sa_t *this)
{
host_t *host;
int family = AF_UNSPEC;
switch (charon->socket->supported_families(charon->socket))
{
case SOCKET_FAMILY_IPV4:
family = AF_INET;
break;
case SOCKET_FAMILY_IPV6:
family = AF_INET6;
break;
case SOCKET_FAMILY_BOTH:
case SOCKET_FAMILY_NONE:
break;
}
/* if an IP address is set locally, use the same family to resolve remote */
if (family == AF_UNSPEC && !this->remote_host)
{
if (this->local_host)
{
family = this->local_host->get_family(this->local_host);
}
else
{
family = ike_cfg_get_family(this->ike_cfg, TRUE);
}
}
if (this->remote_host)
{
host = this->remote_host->clone(this->remote_host);
host->set_port(host, IKEV2_UDP_PORT);
}
else
{
host = this->ike_cfg->resolve_other(this->ike_cfg, family);
}
if (host)
{
if (!host->is_anyaddr(host) ||
this->other_host->is_anyaddr(this->other_host))
{ /* don't set to %any if we currently have an address, but the
* address family might have changed */
set_other_host(this, host);
}
else
{ /* reuse the original port as some implementations might not like
* initial IKE messages on other ports */
this->other_host->set_port(this->other_host, host->get_port(host));
host->destroy(host);
}
}
if (this->local_host)
{
host = this->local_host->clone(this->local_host);
host->set_port(host, charon->socket->get_port(charon->socket, FALSE));
}
else
{
/* use same address family as for other */
if (!this->other_host->is_anyaddr(this->other_host))
{
family = this->other_host->get_family(this->other_host);
}
host = this->ike_cfg->resolve_me(this->ike_cfg, family);
if (host && host->is_anyaddr(host) &&
!this->other_host->is_anyaddr(this->other_host))
{
host->destroy(host);
host = charon->kernel->get_source_addr(charon->kernel,
this->other_host, NULL);
if (host)
{
host->set_port(host, this->ike_cfg->get_my_port(this->ike_cfg));
}
else
{ /* fallback to address family specific %any(6), if configured */
host = this->ike_cfg->resolve_me(this->ike_cfg, family);
}
}
}
if (host)
{
set_my_host(this, host);
}
}
METHOD(ike_sa_t, initiate, status_t,
private_ike_sa_t *this, child_cfg_t *child_cfg, uint32_t reqid,
traffic_selector_t *tsi, traffic_selector_t *tsr)
{
bool defer_initiate = FALSE;
if (this->state == IKE_CREATED)
{
if (this->my_host->is_anyaddr(this->my_host) ||
this->other_host->is_anyaddr(this->other_host))
{
resolve_hosts(this);
}
if (this->other_host->is_anyaddr(this->other_host)
#ifdef ME
&& !this->peer_cfg->get_mediated_by(this->peer_cfg)
#endif /* ME */
)
{
char *addr;
addr = this->ike_cfg->get_other_addr(this->ike_cfg);
if (!this->retry_initiate_interval)
{
DBG1(DBG_IKE, "unable to resolve %s, initiate aborted",
addr);
DESTROY_IF(child_cfg);
charon->bus->alert(charon->bus, ALERT_PEER_ADDR_FAILED);
return DESTROY_ME;
}
DBG1(DBG_IKE, "unable to resolve %s, retrying in %ds",
addr, this->retry_initiate_interval);
defer_initiate = TRUE;
}
set_condition(this, COND_ORIGINAL_INITIATOR, TRUE);
this->task_manager->queue_ike(this->task_manager);
}
#ifdef ME
if (this->peer_cfg->is_mediation(this->peer_cfg))
{
if (this->state == IKE_ESTABLISHED)
{
/* mediation connection is already established, retrigger state
* change to notify bus listeners */
DBG1(DBG_IKE, "mediation connection is already up");
set_state(this, IKE_ESTABLISHED);
}
DESTROY_IF(child_cfg);
}
else
#endif /* ME */
if (child_cfg)
{
/* normal IKE_SA with CHILD_SA */
this->task_manager->queue_child(this->task_manager, child_cfg, reqid,
tsi, tsr);
#ifdef ME
if (this->peer_cfg->get_mediated_by(this->peer_cfg))
{
/* mediated connection, initiate mediation process */
job_t *job = (job_t*)initiate_mediation_job_create(this->ike_sa_id);
lib->processor->queue_job(lib->processor, job);
return SUCCESS;
}
#endif /* ME */
}
if (defer_initiate)
{
if (!this->retry_initiate_queued)
{
job_t *job = (job_t*)retry_initiate_job_create(this->ike_sa_id);
lib->scheduler->schedule_job(lib->scheduler, (job_t*)job,
this->retry_initiate_interval);
this->retry_initiate_queued = TRUE;
}
return SUCCESS;
}
this->retry_initiate_queued = FALSE;
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, retry_initiate, status_t,
private_ike_sa_t *this)
{
if (this->retry_initiate_queued)
{
this->retry_initiate_queued = FALSE;
return initiate(this, NULL, 0, NULL, NULL);
}
return SUCCESS;
}
METHOD(ike_sa_t, process_message, status_t,
private_ike_sa_t *this, message_t *message)
{
status_t status;
if (this->state == IKE_PASSIVE)
{ /* do not handle messages in passive state */
return FAILED;
}
if (message->get_major_version(message) != this->version)
{
DBG1(DBG_IKE, "ignoring %N IKEv%u exchange on %N SA",
exchange_type_names, message->get_exchange_type(message),
message->get_major_version(message),
ike_version_names, this->version);
/* TODO-IKEv1: fall back to IKEv1 if we receive an IKEv1
* INVALID_MAJOR_VERSION on an IKEv2 SA. */
return FAILED;
}
status = this->task_manager->process_message(this->task_manager, message);
if (this->flush_auth_cfg && this->state == IKE_ESTABLISHED)
{
/* authentication completed but if the online validation is suspended we
* need the auth cfgs until we did the delayed verification, we flush
* them afterwards */
if (!has_condition(this, COND_ONLINE_VALIDATION_SUSPENDED))
{
this->flush_auth_cfg = FALSE;
flush_auth_cfgs(this);
}
}
return status;
}
METHOD(ike_sa_t, get_id, ike_sa_id_t*,
private_ike_sa_t *this)
{
return this->ike_sa_id;
}
METHOD(ike_sa_t, get_version, ike_version_t,
private_ike_sa_t *this)
{
return this->version;
}
METHOD(ike_sa_t, get_my_id, identification_t*,
private_ike_sa_t *this)
{
return this->my_id;
}
METHOD(ike_sa_t, set_my_id, void,
private_ike_sa_t *this, identification_t *me)
{
DESTROY_IF(this->my_id);
this->my_id = me;
}
METHOD(ike_sa_t, get_other_id, identification_t*,
private_ike_sa_t *this)
{
return this->other_id;
}
METHOD(ike_sa_t, get_other_eap_id, identification_t*,
private_ike_sa_t *this)
{
identification_t *id = NULL, *current;
enumerator_t *enumerator;
auth_cfg_t *cfg;
enumerator = array_create_enumerator(this->other_auths);
while (enumerator->enumerate(enumerator, &cfg))
{
/* prefer EAP-Identity of last round */
current = cfg->get(cfg, AUTH_RULE_EAP_IDENTITY);
if (!current || current->get_type(current) == ID_ANY)
{
current = cfg->get(cfg, AUTH_RULE_XAUTH_IDENTITY);
}
if (!current || current->get_type(current) == ID_ANY)
{
current = cfg->get(cfg, AUTH_RULE_IDENTITY);
}
if (current && current->get_type(current) != ID_ANY)
{
id = current;
continue;
}
}
enumerator->destroy(enumerator);
if (id)
{
return id;
}
return this->other_id;
}
METHOD(ike_sa_t, set_other_id, void,
private_ike_sa_t *this, identification_t *other)
{
DESTROY_IF(this->other_id);
this->other_id = other;
}
METHOD(ike_sa_t, get_if_id, uint32_t,
private_ike_sa_t *this, bool inbound)
{
return inbound ? this->if_id_in : this->if_id_out;
}
METHOD(ike_sa_t, add_child_sa, void,
private_ike_sa_t *this, child_sa_t *child_sa)
{
array_insert_create(&this->child_sas, ARRAY_TAIL, child_sa);
charon->child_sa_manager->add(charon->child_sa_manager,
child_sa, &this->public);
}
METHOD(ike_sa_t, get_child_sa, child_sa_t*,
private_ike_sa_t *this, protocol_id_t protocol, uint32_t spi, bool inbound)
{
enumerator_t *enumerator;
child_sa_t *current, *found = NULL;
enumerator = array_create_enumerator(this->child_sas);
while (enumerator->enumerate(enumerator, (void**)&current))
{
if (current->get_spi(current, inbound) == spi &&
current->get_protocol(current) == protocol)
{
found = current;
}
}
enumerator->destroy(enumerator);
return found;
}
METHOD(ike_sa_t, get_child_count, int,
private_ike_sa_t *this)
{
return array_count(this->child_sas);
}
/**
* Private data of a create_child_sa_enumerator()
*/
typedef struct {
/** implements enumerator */
enumerator_t public;
/** inner array enumerator */
enumerator_t *inner;
/** current item */
child_sa_t *current;
} child_enumerator_t;
METHOD(enumerator_t, child_enumerate, bool,
child_enumerator_t *this, va_list args)
{
child_sa_t **child_sa;
VA_ARGS_VGET(args, child_sa);
if (this->inner->enumerate(this->inner, &this->current))
{
*child_sa = this->current;
return TRUE;
}
return FALSE;
}
METHOD(enumerator_t, child_enumerator_destroy, void,
child_enumerator_t *this)
{
this->inner->destroy(this->inner);
free(this);
}
METHOD(ike_sa_t, create_child_sa_enumerator, enumerator_t*,
private_ike_sa_t *this)
{
child_enumerator_t *enumerator;
INIT(enumerator,
.public = {
.enumerate = enumerator_enumerate_default,
.venumerate = _child_enumerate,
.destroy = _child_enumerator_destroy,
},
.inner = array_create_enumerator(this->child_sas),
);
return &enumerator->public;
}
METHOD(ike_sa_t, remove_child_sa, void,
private_ike_sa_t *this, enumerator_t *enumerator)
{
child_enumerator_t *ce = (child_enumerator_t*)enumerator;
charon->child_sa_manager->remove(charon->child_sa_manager, ce->current);
array_remove_at(this->child_sas, ce->inner);
}
METHOD(ike_sa_t, rekey_child_sa, status_t,
private_ike_sa_t *this, protocol_id_t protocol, uint32_t spi)
{
if (this->state == IKE_PASSIVE)
{
return INVALID_STATE;
}
this->task_manager->queue_child_rekey(this->task_manager, protocol, spi);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, delete_child_sa, status_t,
private_ike_sa_t *this, protocol_id_t protocol, uint32_t spi, bool expired)
{
if (this->state == IKE_PASSIVE)
{
return INVALID_STATE;
}
this->task_manager->queue_child_delete(this->task_manager,
protocol, spi, expired);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, destroy_child_sa, status_t,
private_ike_sa_t *this, protocol_id_t protocol, uint32_t spi)
{
enumerator_t *enumerator;
child_sa_t *child_sa;
status_t status = NOT_FOUND;
enumerator = create_child_sa_enumerator(this);
while (enumerator->enumerate(enumerator, (void**)&child_sa))
{
if (child_sa->get_protocol(child_sa) == protocol &&
child_sa->get_spi(child_sa, TRUE) == spi)
{
remove_child_sa(this, enumerator);
child_sa->destroy(child_sa);
status = SUCCESS;
break;
}
}
enumerator->destroy(enumerator);
return status;
}
METHOD(ike_sa_t, delete_, status_t,
private_ike_sa_t *this, bool force)
{
status_t status = DESTROY_ME;
switch (this->state)
{
case IKE_ESTABLISHED:
case IKE_REKEYING:
if (time_monotonic(NULL) >= this->stats[STAT_DELETE] &&
!(this->version == IKEV1 && this->state == IKE_REKEYING))
{ /* IKE_SA hard lifetime hit, ignored for reauthenticated
* IKEv1 SAs */
charon->bus->alert(charon->bus, ALERT_IKE_SA_EXPIRED);
}
this->task_manager->queue_ike_delete(this->task_manager);
status = this->task_manager->initiate(this->task_manager);
break;
case IKE_CREATED:
DBG1(DBG_IKE, "deleting unestablished IKE_SA");
break;
case IKE_PASSIVE:
break;
default:
DBG1(DBG_IKE, "destroying IKE_SA in state %N without notification",
ike_sa_state_names, this->state);
force = TRUE;
break;
}
if (force)
{
status = DESTROY_ME;
if (this->version == IKEV2)
{ /* for IKEv1 we trigger this in the ISAKMP delete task */
switch (this->state)
{
case IKE_ESTABLISHED:
case IKE_REKEYING:
case IKE_DELETING:
charon->bus->ike_updown(charon->bus, &this->public, FALSE);
default:
break;
}
}
}
return status;
}
METHOD(ike_sa_t, rekey, status_t,
private_ike_sa_t *this)
{
if (this->state == IKE_PASSIVE)
{
return INVALID_STATE;
}
this->task_manager->queue_ike_rekey(this->task_manager);
return this->task_manager->initiate(this->task_manager);
}
METHOD(ike_sa_t, reauth, status_t,
private_ike_sa_t *this)
{
if (this->state == IKE_PASSIVE)
{
return INVALID_STATE;
}
if (this->state == IKE_CONNECTING)
{
DBG0(DBG_IKE, "reinitiating IKE_SA %s[%d]",
get_name(this), this->unique_id);
reset(this, TRUE);
return this->task_manager->initiate(this->task_manager);
}
/* we can't reauthenticate as responder when we use EAP or virtual IPs.
* If the peer does not support RFC4478, there is no way to keep the
* IKE_SA up. */
if (!has_condition(this, COND_ORIGINAL_INITIATOR))
{
DBG1(DBG_IKE, "initiator did not reauthenticate as requested");
if (array_count(this->other_vips) != 0 ||
has_condition(this, COND_XAUTH_AUTHENTICATED) ||
has_condition(this, COND_EAP_AUTHENTICATED)
#ifdef ME
/* as mediation server we too cannot reauth the IKE_SA */
|| this->is_mediation_server
#endif /* ME */
)
{
time_t del, now;
del = this->stats[STAT_DELETE];
now = time_monotonic(NULL);
DBG1(DBG_IKE, "IKE_SA %s[%d] will timeout in %V",
get_name(this), this->unique_id, &now, &del);
return FAILED;
}
else
{
DBG0(DBG_IKE, "reauthenticating IKE_SA %s[%d] actively",
get_name(this), this->unique_id);
}
}
else
{
DBG0(DBG_IKE, "reauthenticating IKE_SA %s[%d]",
get_name(this), this->unique_id);
}
set_condition(this, COND_REAUTHENTICATING, TRUE);
this->task_manager->queue_ike_reauth(this->task_manager);
return this->task_manager->initiate(this->task_manager);
}
/**
* Check if any tasks of a specific type are queued in the given queue.
*/
static bool is_task_queued(private_ike_sa_t *this, task_queue_t queue,
task_type_t type)
{
enumerator_t *enumerator;
task_t *task;
bool found = FALSE;
enumerator = this->task_manager->create_task_enumerator(this->task_manager,
queue);
while (enumerator->enumerate(enumerator, &task))
{
if (task->get_type(task) == type)
{
found = TRUE;
break;
}
}
enumerator->destroy(enumerator);
return found;
}
/**
* Check if any tasks to create CHILD_SAs are queued in the given queue.
*/
static bool is_child_queued(private_ike_sa_t *this, task_queue_t queue)
{
return is_task_queued(this, queue,
this->version == IKEV1 ? TASK_QUICK_MODE : TASK_CHILD_CREATE);
}
/**
* Check if any tasks to delete the IKE_SA are queued in the given queue.
*/
static bool is_delete_queued(private_ike_sa_t *this, task_queue_t queue)
{
return is_task_queued(this, queue,
this->version == IKEV1 ? TASK_ISAKMP_DELETE : TASK_IKE_DELETE);
}
/**
* Reestablish CHILD_SAs and migrate queued tasks.
*
* If force is true all SAs are restarted, otherwise their close/dpd_action
* is followed.
*/
static status_t reestablish_children(private_ike_sa_t *this, ike_sa_t *new,
bool force)
{
enumerator_t *enumerator;
child_sa_t *child_sa;
child_cfg_t *child_cfg;
action_t action;
status_t status = FAILED;
/* handle existing CHILD_SAs */
enumerator = create_child_sa_enumerator(this);
while (enumerator->enumerate(enumerator, (void**)&child_sa))
{
switch (child_sa->get_state(child_sa))
{
case CHILD_REKEYED:
case CHILD_DELETED:
/* ignore CHILD_SAs in these states */
continue;
default:
break;
}
if (force)
{
action = ACTION_RESTART;
}
else
{ /* only restart CHILD_SAs that are configured accordingly */
if (this->state == IKE_DELETING)
{
action = child_sa->get_close_action(child_sa);
}
else
{
action = child_sa->get_dpd_action(child_sa);
}
}
switch (action)
{
case ACTION_RESTART:
child_cfg = child_sa->get_config(child_sa);
DBG1(DBG_IKE, "restarting CHILD_SA %s",
child_cfg->get_name(child_cfg));
child_cfg->get_ref(child_cfg);
status = new->initiate(new, child_cfg,
child_sa->get_reqid(child_sa), NULL, NULL);
break;
default:
continue;
}
if (status == DESTROY_ME)
{
break;
}
}
enumerator->destroy(enumerator);
/* adopt any active or queued CHILD-creating tasks */
if (status != DESTROY_ME)
{
new->adopt_child_tasks(new, &this->public);
if (new->get_state(new) == IKE_CREATED)
{
status = new->initiate(new, NULL, 0, NULL, NULL);
}
}
return status;
}
METHOD(ike_sa_t, reestablish, status_t,
private_ike_sa_t *this)
{
ike_sa_t *new;
host_t *host;
action_t action;
enumerator_t *enumerator;
child_sa_t *child_sa;
bool restart = FALSE;
status_t status = FAILED;
if (is_delete_queued(this, TASK_QUEUE_QUEUED))
{ /* don't reestablish IKE_SAs that have explicitly been deleted in the
* mean time */
return FAILED;
}
if (has_condition(this, COND_REAUTHENTICATING))
{ /* only reauthenticate if we have children */
if (array_count(this->child_sas) == 0
#ifdef ME
/* allow reauth of mediation connections without CHILD_SAs */
&& !this->peer_cfg->is_mediation(this->peer_cfg)
#endif /* ME */
)
{
DBG1(DBG_IKE, "unable to reauthenticate IKE_SA, no CHILD_SA "
"to recreate");
}
else
{
restart = TRUE;
}
}
else
{ /* check if we have children to keep up at all */
enumerator = array_create_enumerator(this->child_sas);
while (enumerator->enumerate(enumerator, (void**)&child_sa))
{
switch (child_sa->get_state(child_sa))
{
case CHILD_REKEYED:
case CHILD_DELETED:
/* ignore CHILD_SAs in these states */
continue;
default:
break;
}
if (this->state == IKE_DELETING)
{
action = child_sa->get_close_action(child_sa);
}
else
{
action = child_sa->get_dpd_action(child_sa);
}
switch (action)
{
case ACTION_RESTART:
restart = TRUE;
break;
case ACTION_ROUTE:
charon->traps->install(charon->traps, this->peer_cfg,
child_sa->get_config(child_sa));
break;
default:
break;
}
}
enumerator->destroy(enumerator);
/* check if we have tasks that recreate children */
if (!restart)
{
restart = is_child_queued(this, TASK_QUEUE_ACTIVE) ||
is_child_queued(this, TASK_QUEUE_QUEUED);
}
#ifdef ME
/* mediation connections have no children, keep them up anyway */
if (this->peer_cfg->is_mediation(this->peer_cfg))
{
restart = TRUE;
}
#endif /* ME */
}
if (!restart)
{
return FAILED;
}
/* check if we are able to reestablish this IKE_SA */
if (!has_condition(this, COND_ORIGINAL_INITIATOR) &&
(array_count(this->other_vips) != 0 ||
has_condition(this, COND_EAP_AUTHENTICATED)
#ifdef ME
|| this->is_mediation_server
#endif /* ME */
))
{
DBG1(DBG_IKE, "unable to reestablish IKE_SA due to asymmetric setup");
return FAILED;
}
new = charon->ike_sa_manager->checkout_new(charon->ike_sa_manager,
this->version, TRUE);
if (!new)
{
return FAILED;
}
new->set_peer_cfg(new, this->peer_cfg);
host = this->other_host;
new->set_other_host(new, host->clone(host));
host = this->my_host;
new->set_my_host(new, host->clone(host));
charon->bus->ike_reestablish_pre(charon->bus, &this->public, new);
if (!has_condition(this, COND_REAUTHENTICATING))
{ /* reauthenticate to the same addresses, but resolve hosts if
* reestablishing (old addresses serve as fallback) */
resolve_hosts((private_ike_sa_t*)new);
}
/* if we already have a virtual IP, we reuse it */
enumerator = array_create_enumerator(this->my_vips);
while (enumerator->enumerate(enumerator, &host))
{
new->add_virtual_ip(new, TRUE, host);
}
enumerator->destroy(enumerator);
#ifdef ME
if (this->peer_cfg->is_mediation(this->peer_cfg))
{
status = new->initiate(new, NULL, 0, NULL, NULL);
}
else
#endif /* ME */
{
status = reestablish_children(this, new,
has_condition(this, COND_REAUTHENTICATING));
}
if (status == DESTROY_ME)
{
charon->bus->ike_reestablish_post(charon->bus, &this->public, new,
FALSE);
charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, new);
status = FAILED;
}
else
{
charon->bus->ike_reestablish_post(charon->bus, &this->public, new,
TRUE);
charon->ike_sa_manager->checkin(charon->ike_sa_manager, new);
status = SUCCESS;
}
charon->bus->set_sa(charon->bus, &this->public);
return status;
}
/**
* Resolve the given gateway ID
*/
static host_t *resolve_gateway_id(identification_t *gateway)
{
char gw[BUF_LEN];
host_t *addr;
snprintf(gw, sizeof(gw), "%Y", gateway);
gw[sizeof(gw)-1] = '\0';
addr = host_create_from_dns(gw, AF_UNSPEC, IKEV2_UDP_PORT);
if (!addr)
{
DBG1(DBG_IKE, "unable to resolve gateway ID '%Y', redirect failed",
gateway);
}
return addr;
}
/**
* Redirect the current SA to the given target host
*/
static bool redirect_established(private_ike_sa_t *this, identification_t *to)
{
private_ike_sa_t *new_priv;
ike_sa_t *new;
host_t *other;
time_t redirect;
new = charon->ike_sa_manager->checkout_new(charon->ike_sa_manager,
this->version, TRUE);
if (!new)
{
return FALSE;
}
new_priv = (private_ike_sa_t*)new;
new->set_peer_cfg(new, this->peer_cfg);
new_priv->redirected_from = this->other_host->clone(this->other_host);
charon->bus->ike_reestablish_pre(charon->bus, &this->public, new);
other = resolve_gateway_id(to);
if (other)
{
set_my_host(new_priv, this->my_host->clone(this->my_host));
/* this allows us to force the remote address while we still properly
* resolve the local address */
new_priv->remote_host = other;
resolve_hosts(new_priv);
new_priv->redirected_at = array_create(sizeof(time_t), MAX_REDIRECTS);
while (array_remove(this->redirected_at, ARRAY_HEAD, &redirect))
{
array_insert(new_priv->redirected_at, ARRAY_TAIL, &redirect);
}
if (reestablish_children(this, new, TRUE) != DESTROY_ME)
{
#ifdef USE_IKEV2
new->queue_task(new, (task_t*)ike_reauth_complete_create(new,
this->ike_sa_id));
#endif
charon->bus->ike_reestablish_post(charon->bus, &this->public, new,
TRUE);
charon->ike_sa_manager->checkin(charon->ike_sa_manager, new);
charon->bus->set_sa(charon->bus, &this->public);
return TRUE;
}
}
charon->bus->ike_reestablish_post(charon->bus, &this->public, new,
FALSE);
charon->ike_sa_manager->checkin_and_destroy(charon->ike_sa_manager, new);
charon->bus->set_sa(charon->bus, &this->public);
return FALSE;
}
/**
* Redirect the current connecting SA to the given target host
*/
static bool redirect_connecting(private_ike_sa_t *this, identification_t *to)
{
host_t *other;
other = resolve_gateway_id(to);
if (!other)
{
return FALSE;
}
reset(this, TRUE);
DESTROY_IF(this->redirected_from);
this->redirected_from = this->other_host->clone(this->other_host);
/* this allows us to force the remote address while we still properly
* resolve the local address */
DESTROY_IF(this->remote_host);
this->remote_host = other;
resolve_hosts(this);
return TRUE;
}
/**
* Check if the current redirect exceeds the limits for redirects
*/
static bool redirect_count_exceeded(private_ike_sa_t *this)
{
time_t now, redirect;
now = time_monotonic(NULL);
/* remove entries outside the defined period */
while (array_get(this->redirected_at, ARRAY_HEAD, &redirect) &&
now - redirect >= REDIRECT_LOOP_DETECT_PERIOD)
{
array_remove(this->redirected_at, ARRAY_HEAD, NULL);
}
if (array_count(this->redirected_at) < MAX_REDIRECTS)
{
if (!this->redirected_at)
{
this->redirected_at = array_create(sizeof(time_t), MAX_REDIRECTS);
}
array_insert(this->redirected_at, ARRAY_TAIL, &now);
return FALSE;
}
return TRUE;
}
METHOD(ike_sa_t, handle_redirect, bool,
private_ike_sa_t *this, identification_t *gateway)
{
DBG1(DBG_IKE, "redirected to %Y", gateway);
if (!this->follow_redirects)
{
DBG1(DBG_IKE, "server sent REDIRECT even though we disabled it");
return FALSE;
}
if (redirect_count_exceeded(this))
{
DBG1(DBG_IKE, "only %d redirects are allowed within %d seconds",
MAX_REDIRECTS, REDIRECT_LOOP_DETECT_PERIOD);
return FALSE;
}
switch (this->state)
{
case IKE_CONNECTING:
return redirect_connecting(this, gateway);
case IKE_ESTABLISHED:
return redirect_established(this, gateway);
default:
DBG1(DBG_IKE, "unable to handle redirect for IKE_SA in state %N",
ike_sa_state_names, this->state);
return FALSE;
}
}
METHOD(ike_sa_t, redirect, status_t,
private_ike_sa_t *this, identification_t *gateway)
{
switch (this->state)
{
case IKE_CONNECTING:
case IKE_ESTABLISHED:
case IKE_REKEYING:
if (has_condition(this, COND_REDIRECTED))
{ /* IKE_SA already got redirected */
return SUCCESS;
}
if (has_condition(this, COND_ORIGINAL_INITIATOR))
{
DBG1(DBG_IKE, "unable to redirect IKE_SA as initiator");
return FAILED;
}
if (this->version == IKEV1)
{
DBG1(DBG_IKE, "unable to redirect IKEv1 SA");
return FAILED;
}
if (!supports_extension(this, EXT_IKE_REDIRECTION))
{
DBG1(DBG_IKE, "client does not support IKE redirection");
return FAILED;
}
#ifdef USE_IKEV2
this->task_manager->queue_task(this->task_manager,
(task_t*)ike_redirect_create(&this->public, gateway));
#endif
return this->task_manager->initiate(this->task_manager);
default:
DBG1(DBG_IKE, "unable to redirect IKE_SA in state %N",
ike_sa_state_names, this->state);
return INVALID_STATE;
}
}
METHOD(ike_sa_t, retransmit, status_t,
private_ike_sa_t *this, uint32_t message_id)
{
if (this->state == IKE_PASSIVE)
{
return INVALID_STATE;
}
switch (this->task_manager->retransmit(this->task_manager, message_id))
{
case SUCCESS:
this->stats[STAT_OUTBOUND] = time_monotonic(NULL);
return SUCCESS;
case INVALID_STATE:
return INVALID_STATE;
default:
break;
}
/* send a proper signal to brief interested bus listeners */
switch (this->state)
{
case IKE_CONNECTING:
{
/* retry IKE_SA_INIT/Main Mode if we have multiple keyingtries */
uint32_t tries = this->peer_cfg->get_keyingtries(this->peer_cfg);
charon->bus->alert(charon->bus, ALERT_PEER_INIT_UNREACHABLE,
this->keyingtry);
this->keyingtry++;
if (tries == 0 || tries > this->keyingtry)
{
DBG1(DBG_IKE, "peer not responding, trying again (%d/%d)",
this->keyingtry + 1, tries);
reset(this, TRUE);
resolve_hosts(this);
return this->task_manager->initiate(this->task_manager);
}
DBG1(DBG_IKE, "establishing IKE_SA failed, peer not responding");
if (this->version == IKEV1 && array_count(this->child_sas))
{
enumerator_t *enumerator;
child_sa_t *child_sa;
/* if reauthenticating an IKEv1 SA failed (assumed for an SA
* in this state with CHILD_SAs), try again from scratch */
DBG1(DBG_IKE, "reauthentication failed, trying to "
"reestablish IKE_SA");
reestablish(this);
/* trigger down events for the CHILD_SAs, as no down event
* is triggered below for IKE SAs in this state */
enumerator = array_create_enumerator(this->child_sas);
while (enumerator->enumerate(enumerator, &child_sa))
{
if (child_sa->get_state(child_sa) != CHILD_REKEYED &&
child_sa->get_state(child_sa) != CHILD_DELETED)
{
charon->bus->child_updown(charon->bus, child_sa,
FALSE);
}
}
enumerator->destroy(enumerator);
}
break;
}
case IKE_DELETING:
DBG1(DBG_IKE, "proper IKE_SA delete failed, peer not responding");
if (has_condition(this, COND_REAUTHENTICATING) &&
!lib->settings->get_bool(lib->settings,
"%s.make_before_break", FALSE, lib->ns))
{
DBG1(DBG_IKE, "delete during reauthentication failed, "
"trying to reestablish IKE_SA anyway");
reestablish(this);
}
break;
case IKE_REKEYING:
DBG1(DBG_IKE, "rekeying IKE_SA failed, peer not responding");
/* FALL */
default:
reestablish(this);
break;
}
if (this->state != IKE_CONNECTING &&
this->state != IKE_REKEYED)
{
charon->bus->ike_updown(charon->bus, &this->public, FALSE);
}
return DESTROY_ME;
}
METHOD(ike_sa_t, set_auth_lifetime, status_t,
private_ike_sa_t *this, uint32_t lifetime)
{
uint32_t diff, hard, soft, now;
bool send_update;
diff = this->peer_cfg->get_over_time(this->peer_cfg);
now = time_monotonic(NULL);
hard = now + lifetime;
soft = hard - diff;
/* check if we have to send an AUTH_LIFETIME to enforce the new lifetime.
* We send the notify in IKE_AUTH if not yet ESTABLISHED. */
send_update = this->state == IKE_ESTABLISHED && this->version == IKEV2 &&
!has_condition(this, COND_ORIGINAL_INITIATOR) &&
(array_count(this->other_vips) != 0 ||
has_condition(this, COND_EAP_AUTHENTICATED));
if (lifetime < diff)
{
this->stats[STAT_REAUTH] = now;
if (!send_update)
{
DBG1(DBG_IKE, "received AUTH_LIFETIME of %ds, "
"starting reauthentication", lifetime);
lib->processor->queue_job(lib->processor,
(job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE));
}
}
else if (this->stats[STAT_REAUTH] == 0 ||
this->stats[STAT_REAUTH] > soft)
{
this->stats[STAT_REAUTH] = soft;
if (!send_update)
{
DBG1(DBG_IKE, "received AUTH_LIFETIME of %ds, scheduling "
"reauthentication in %ds", lifetime, lifetime - diff);
lib->scheduler->schedule_job(lib->scheduler,
(job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE),
lifetime - diff);
}
}
else
{
DBG1(DBG_IKE, "received AUTH_LIFETIME of %ds, "
"reauthentication already scheduled in %ds", lifetime,
this->stats[STAT_REAUTH] - time_monotonic(NULL));
send_update = FALSE;
}
/* give at least some seconds to reauthenticate */
this->stats[STAT_DELETE] = max(hard, now + 10);
#ifdef USE_IKEV2
if (send_update)
{
ike_auth_lifetime_t *task;
task = ike_auth_lifetime_create(&this->public, TRUE);
this->task_manager->queue_task(this->task_manager, &task->task);
return this->task_manager->initiate(this->task_manager);
}
#endif
return SUCCESS;
}
/**
* Check if the current combination of source and destination address is still
* valid.
*/
static bool is_current_path_valid(private_ike_sa_t *this)
{
bool valid = FALSE;
host_t *src;
if (supports_extension(this, EXT_MOBIKE) &&
lib->settings->get_bool(lib->settings,
"%s.prefer_best_path", FALSE, lib->ns))
{
/* check if the current path is the best path; migrate otherwise */
src = charon->kernel->get_source_addr(charon->kernel, this->other_host,
NULL);
if (src)
{
valid = src->ip_equals(src, this->my_host);
src->destroy(src);
}
if (!valid)
{
DBG1(DBG_IKE, "old path is not preferred anymore");
}
return valid;
}
src = charon->kernel->get_source_addr(charon->kernel, this->other_host,
this->my_host);
if (src)
{
if (src->ip_equals(src, this->my_host))
{
valid = TRUE;
}
src->destroy(src);
}
if (!valid)
{
DBG1(DBG_IKE, "old path is not available anymore, try to find another");
}
return valid;
}
/**
* Check if we have any path available for this IKE SA.
*/
static bool is_any_path_valid(private_ike_sa_t *this)
{
bool valid = FALSE;
enumerator_t *enumerator;
host_t *src = NULL, *addr;
int family = AF_UNSPEC;
switch (charon->socket->supported_families(charon->socket))
{
case SOCKET_FAMILY_IPV4:
family = AF_INET;
break;
case SOCKET_FAMILY_IPV6:
family = AF_INET6;
break;
case SOCKET_FAMILY_BOTH:
case SOCKET_FAMILY_NONE:
break;
}
enumerator = create_peer_address_enumerator(this);
while (enumerator->enumerate(enumerator, &addr))
{
if (family != AF_UNSPEC && addr->get_family(addr) != family)
{
continue;
}
DBG1(DBG_IKE, "looking for a route to %H ...", addr);
src = charon->kernel->get_source_addr(charon->kernel, addr, NULL);
if (src)
{
break;
}
}
enumerator->destroy(enumerator);
if (src)
{
valid = TRUE;
src->destroy(src);
}
return valid;
}
METHOD(ike_sa_t, roam, status_t,
private_ike_sa_t *this, bool address)
{
switch (this->state)
{
case IKE_CREATED:
case IKE_DELETING:
case IKE_DESTROYING:
case IKE_PASSIVE:
case IKE_REKEYED:
return SUCCESS;
default:
break;
}
if (!this->ike_cfg)
{ /* this is the case for new HA SAs not yet in state IKE_PASSIVE and
* without config assigned */
return SUCCESS;
}
if (this->version == IKEV1)
{ /* ignore roam events for IKEv1 where we don't have MOBIKE and would
* have to reestablish from scratch (reauth is not enough) */
return SUCCESS;
}
/* ignore roam events if MOBIKE is not supported/enabled and the local
* address is statically configured */
if (!supports_extension(this, EXT_MOBIKE) &&
ike_cfg_has_address(this->ike_cfg, this->my_host, TRUE))
{
DBG2(DBG_IKE, "keeping statically configured path %H - %H",
this->my_host, this->other_host);
return SUCCESS;
}
/* keep existing path if possible */
if (is_current_path_valid(this))
{
DBG2(DBG_IKE, "keeping connection path %H - %H",
this->my_host, this->other_host);
set_condition(this, COND_STALE, FALSE);
if (supports_extension(this, EXT_MOBIKE) && address)
{ /* if any addresses changed, send an updated list */
DBG1(DBG_IKE, "sending address list update using MOBIKE");
this->task_manager->queue_mobike(this->task_manager, FALSE, TRUE);
return this->task_manager->initiate(this->task_manager);
}
if (lib->settings->get_bool(lib->settings,
"%s.check_current_path", FALSE, lib->ns) &&
!this->task_manager->busy(this->task_manager))
{
DBG1(DBG_IKE, "checking if current path still works using DPD");
this->task_manager->queue_dpd(this->task_manager);
return this->task_manager->initiate(this->task_manager);
}
return SUCCESS;
}
if (!is_any_path_valid(this))
{
DBG1(DBG_IKE, "no route found to reach %H, MOBIKE update deferred",
this->other_host);
set_condition(this, COND_STALE, TRUE);
return SUCCESS;
}
set_condition(this, COND_STALE, FALSE);
/* update addresses with mobike, if supported ... */
if (supports_extension(this, EXT_MOBIKE))
{
if (!has_condition(this, COND_ORIGINAL_INITIATOR))
{ /* responder updates the peer about changed address config */
DBG1(DBG_IKE, "sending address list update using MOBIKE, "
"implicitly requesting an address change");
address = TRUE;
}
else
{
DBG1(DBG_IKE, "requesting address change using MOBIKE");
}
this->task_manager->queue_mobike(this->task_manager, TRUE, address);
return this->task_manager->initiate(this->task_manager);
}
/* ... reauth if not */
if (!has_condition(this, COND_ORIGINAL_INITIATOR))
{ /* responder does not reauthenticate */
set_condition(this, COND_STALE, TRUE);
return SUCCESS;
}
DBG1(DBG_IKE, "reauthenticating IKE_SA due to address change");
/* since our previous path is not valid anymore, try and find a new one */
resolve_hosts(this);
return reauth(this);
}
METHOD(ike_sa_t, add_configuration_attribute, void,
private_ike_sa_t *this, attribute_handler_t *handler,
configuration_attribute_type_t type, chunk_t data)
{
attribute_entry_t entry = {
.handler = handler,
.type = type,
.data = chunk_clone(data),
};
array_insert(this->attributes, ARRAY_TAIL, &entry);
}
CALLBACK(filter_attribute, bool,
void *null, enumerator_t *orig, va_list args)
{
attribute_entry_t *entry;
configuration_attribute_type_t *type;
chunk_t *data;
bool *handled;
VA_ARGS_VGET(args, type, data, handled);
if (orig->enumerate(orig, &entry))
{
*type = entry->type;
*data = entry->data;
*handled = entry->handler != NULL;
return TRUE;
}
return FALSE;
}
METHOD(ike_sa_t, create_attribute_enumerator, enumerator_t*,
private_ike_sa_t *this)
{
return enumerator_create_filter(array_create_enumerator(this->attributes),
filter_attribute, NULL, NULL);
}
METHOD(ike_sa_t, create_task_enumerator, enumerator_t*,
private_ike_sa_t *this, task_queue_t queue)
{
return this->task_manager->create_task_enumerator(this->task_manager, queue);
}
METHOD(ike_sa_t, remove_task, void,
private_ike_sa_t *this, enumerator_t *enumerator)
{
return this->task_manager->remove_task(this->task_manager, enumerator);
}
METHOD(ike_sa_t, flush_queue, void,
private_ike_sa_t *this, task_queue_t queue)
{
this->task_manager->flush_queue(this->task_manager, queue);
}
METHOD(ike_sa_t, queue_task, void,
private_ike_sa_t *this, task_t *task)
{
this->task_manager->queue_task(this->task_manager, task);
}
METHOD(ike_sa_t, queue_task_delayed, void,
private_ike_sa_t *this, task_t *task, uint32_t delay)
{
this->task_manager->queue_task_delayed(this->task_manager, task, delay);
}
/**
* Migrate and queue child-creating tasks from another IKE_SA
*/
static void migrate_child_tasks(private_ike_sa_t *this, ike_sa_t *other,
task_queue_t queue)
{
enumerator_t *enumerator;
task_t *task;
enumerator = other->create_task_enumerator(other, queue);
while (enumerator->enumerate(enumerator, &task))
{
if (task->get_type(task) == TASK_CHILD_CREATE ||
task->get_type(task) == TASK_QUICK_MODE)
{
other->remove_task(other, enumerator);
task->migrate(task, &this->public);
queue_task(this, task);
}
}
enumerator->destroy(enumerator);
}
METHOD(ike_sa_t, adopt_child_tasks, void,
private_ike_sa_t *this, ike_sa_t *other)
{
migrate_child_tasks(this, other, TASK_QUEUE_ACTIVE);
migrate_child_tasks(this, other, TASK_QUEUE_QUEUED);
}
METHOD(ike_sa_t, inherit_pre, void,
private_ike_sa_t *this, ike_sa_t *other_public)
{
private_ike_sa_t *other = (private_ike_sa_t*)other_public;
/* apply config and hosts */
set_peer_cfg(this, other->peer_cfg);
set_my_host(this, other->my_host->clone(other->my_host));
set_other_host(this, other->other_host->clone(other->other_host));
/* apply extensions and conditions with a few exceptions */
this->extensions = other->extensions;
this->conditions = other->conditions;
this->conditions &= ~COND_STALE;
this->conditions &= ~COND_REAUTHENTICATING;
}
METHOD(ike_sa_t, inherit_post, void,
private_ike_sa_t *this, ike_sa_t *other_public)
{
private_ike_sa_t *other = (private_ike_sa_t*)other_public;
child_sa_t *child_sa;
enumerator_t *enumerator;
attribute_entry_t entry;
auth_cfg_t *cfg;
host_t *vip;
/* apply hosts and ids */
this->my_host->destroy(this->my_host);
this->other_host->destroy(this->other_host);
this->my_id->destroy(this->my_id);
this->other_id->destroy(this->other_id);
this->my_host = other->my_host->clone(other->my_host);
this->other_host = other->other_host->clone(other->other_host);
this->my_id = other->my_id->clone(other->my_id);
this->other_id = other->other_id->clone(other->other_id);
this->if_id_in = other->if_id_in;
this->if_id_out = other->if_id_out;
/* apply assigned virtual IPs... */
while (array_remove(other->my_vips, ARRAY_HEAD, &vip))
{
array_insert_create(&this->my_vips, ARRAY_TAIL, vip);
}
while (array_remove(other->other_vips, ARRAY_HEAD, &vip))
{
array_insert_create(&this->other_vips, ARRAY_TAIL, vip);
}
/* MOBIKE additional addresses */
while (array_remove(other->peer_addresses, ARRAY_HEAD, &vip))
{
array_insert_create(&this->peer_addresses, ARRAY_TAIL, vip);
}
/* authentication information */
enumerator = array_create_enumerator(other->my_auths);
while (enumerator->enumerate(enumerator, &cfg))
{
array_insert(this->my_auths, ARRAY_TAIL, cfg->clone(cfg));
}
enumerator->destroy(enumerator);
enumerator = array_create_enumerator(other->other_auths);
while (enumerator->enumerate(enumerator, &cfg))
{
array_insert(this->other_auths, ARRAY_TAIL, cfg->clone(cfg));
}
enumerator->destroy(enumerator);
/* ... and configuration attributes */
while (array_remove(other->attributes, ARRAY_HEAD, &entry))
{
array_insert(this->attributes, ARRAY_TAIL, &entry);
}
/* inherit all conditions */
this->conditions = other->conditions;
if (this->conditions & COND_NAT_HERE)
{
send_keepalive(this, FALSE);
}
#ifdef ME
if (other->is_mediation_server)
{
act_as_mediation_server(this);
}
else if (other->server_reflexive_host)
{
this->server_reflexive_host = other->server_reflexive_host->clone(
other->server_reflexive_host);
}
#endif /* ME */
/* adopt all children */
while (array_remove(other->child_sas, ARRAY_HEAD, &child_sa))
{
charon->child_sa_manager->remove(charon->child_sa_manager, child_sa);
add_child_sa(this, child_sa);
}
/* move pending tasks to the new IKE_SA */
this->task_manager->adopt_tasks(this->task_manager, other->task_manager);
/* reauthentication timeout survives a rekeying */
if (other->stats[STAT_REAUTH])
{
time_t reauth, delete, now = time_monotonic(NULL);
this->stats[STAT_REAUTH] = other->stats[STAT_REAUTH];
reauth = this->stats[STAT_REAUTH] - now;
delete = reauth + this->peer_cfg->get_over_time(this->peer_cfg);
this->stats[STAT_DELETE] = this->stats[STAT_REAUTH] + delete;
DBG1(DBG_IKE, "rescheduling reauthentication in %ds after rekeying, "
"lifetime reduced to %ds", reauth, delete);
lib->scheduler->schedule_job(lib->scheduler,
(job_t*)rekey_ike_sa_job_create(this->ike_sa_id, TRUE), reauth);
lib->scheduler->schedule_job(lib->scheduler,
(job_t*)delete_ike_sa_job_create(this->ike_sa_id, TRUE), delete);
}
}
METHOD(ike_sa_t, destroy, void,
private_ike_sa_t *this)
{
attribute_entry_t entry;
child_sa_t *child_sa;
host_t *vip;
charon->bus->set_sa(charon->bus, &this->public);
set_state(this, IKE_DESTROYING);
if (this->task_manager)
{
this->task_manager->flush(this->task_manager);
}
/* remove attributes first, as we pass the IKE_SA to the handler */
charon->bus->handle_vips(charon->bus, &this->public, FALSE);
while (array_remove(this->attributes, ARRAY_TAIL, &entry))
{
if (entry.handler)
{
charon->attributes->release(charon->attributes, entry.handler,
&this->public, entry.type, entry.data);
}
free(entry.data.ptr);
}
/* uninstall CHILD_SAs before virtual IPs, otherwise we might kill
* routes that the CHILD_SA tries to uninstall. */
while (array_remove(this->child_sas, ARRAY_TAIL, &child_sa))
{
charon->child_sa_manager->remove(charon->child_sa_manager, child_sa);
child_sa->destroy(child_sa);
}
while (array_remove(this->my_vips, ARRAY_TAIL, &vip))
{
charon->kernel->del_ip(charon->kernel, vip, -1, TRUE);
vip->destroy(vip);
}
if (array_count(this->other_vips))
{
charon->bus->assign_vips(charon->bus, &this->public, FALSE);
}
while (array_remove(this->other_vips, ARRAY_TAIL, &vip))
{
if (this->peer_cfg)
{
linked_list_t *pools;
pools = linked_list_create_from_enumerator(
this->peer_cfg->create_pool_enumerator(this->peer_cfg));
charon->attributes->release_address(charon->attributes,
pools, vip, &this->public);
pools->destroy(pools);
}
vip->destroy(vip);
}
/* unset SA after here to avoid usage by the listeners */
charon->bus->set_sa(charon->bus, NULL);
array_destroy(this->child_sas);
DESTROY_IF(this->task_manager);
DESTROY_IF(this->keymat);
array_destroy(this->attributes);
array_destroy(this->my_vips);
array_destroy(this->other_vips);
array_destroy_offset(this->peer_addresses, offsetof(host_t, destroy));
#ifdef ME
if (this->is_mediation_server)
{
charon->mediation_manager->remove(charon->mediation_manager,
this->ike_sa_id);
}
DESTROY_IF(this->server_reflexive_host);
chunk_free(&this->connect_id);
#endif /* ME */
free(this->nat_detection_dest.ptr);
DESTROY_IF(this->my_host);
DESTROY_IF(this->other_host);
DESTROY_IF(this->my_id);
DESTROY_IF(this->other_id);
DESTROY_IF(this->local_host);
DESTROY_IF(this->remote_host);
DESTROY_IF(this->redirected_from);
array_destroy(this->redirected_at);
DESTROY_IF(this->ike_cfg);
DESTROY_IF(this->peer_cfg);
DESTROY_IF(this->proposal);
this->my_auth->destroy(this->my_auth);
this->other_auth->destroy(this->other_auth);
array_destroy_offset(this->my_auths, offsetof(auth_cfg_t, destroy));
array_destroy_offset(this->other_auths, offsetof(auth_cfg_t, destroy));
this->ike_sa_id->destroy(this->ike_sa_id);
free(this);
}
/*
* Described in header.
*/
ike_sa_t * ike_sa_create(ike_sa_id_t *ike_sa_id, bool initiator,
ike_version_t version)
{
private_ike_sa_t *this;
static refcount_t unique_id = 0;
if (version == IKE_ANY)
{ /* prefer IKEv2 if protocol not specified */
#ifdef USE_IKEV2
version = IKEV2;
#else
version = IKEV1;
#endif
}
INIT(this,
.public = {
.get_version = _get_version,
.get_state = _get_state,
.set_state = _set_state,
.get_name = _get_name,
.get_statistic = _get_statistic,
.set_statistic = _set_statistic,
.process_message = _process_message,
.initiate = _initiate,
.retry_initiate = _retry_initiate,
.get_ike_cfg = _get_ike_cfg,
.set_ike_cfg = _set_ike_cfg,
.get_peer_cfg = _get_peer_cfg,
.set_peer_cfg = _set_peer_cfg,
.get_auth_cfg = _get_auth_cfg,
.create_auth_cfg_enumerator = _create_auth_cfg_enumerator,
.verify_peer_certificate = _verify_peer_certificate,
.add_auth_cfg = _add_auth_cfg,
.get_proposal = _get_proposal,
.set_proposal = _set_proposal,
.get_id = _get_id,
.get_my_host = _get_my_host,
.set_my_host = _set_my_host,
.get_other_host = _get_other_host,
.set_other_host = _set_other_host,
.set_message_id = _set_message_id,
.get_message_id = _get_message_id,
.float_ports = _float_ports,
.update_hosts = _update_hosts,
.get_my_id = _get_my_id,
.set_my_id = _set_my_id,
.get_other_id = _get_other_id,
.set_other_id = _set_other_id,
.get_other_eap_id = _get_other_eap_id,
.enable_extension = _enable_extension,
.supports_extension = _supports_extension,
.set_condition = _set_condition,
.has_condition = _has_condition,
.create_peer_address_enumerator = _create_peer_address_enumerator,
.add_peer_address = _add_peer_address,
.clear_peer_addresses = _clear_peer_addresses,
.has_mapping_changed = _has_mapping_changed,
.retransmit = _retransmit,
.delete = _delete_,
.destroy = _destroy,
.send_dpd = _send_dpd,
.send_keepalive = _send_keepalive,
.redirect = _redirect,
.handle_redirect = _handle_redirect,
.get_redirected_from = _get_redirected_from,
.get_keymat = _get_keymat,
.add_child_sa = _add_child_sa,
.get_child_sa = _get_child_sa,
.get_child_count = _get_child_count,
.create_child_sa_enumerator = _create_child_sa_enumerator,
.remove_child_sa = _remove_child_sa,
.rekey_child_sa = _rekey_child_sa,
.delete_child_sa = _delete_child_sa,
.destroy_child_sa = _destroy_child_sa,
.rekey = _rekey,
.reauth = _reauth,
.reestablish = _reestablish,
.set_auth_lifetime = _set_auth_lifetime,
.roam = _roam,
.inherit_pre = _inherit_pre,
.inherit_post = _inherit_post,
.generate_message = _generate_message,
.generate_message_fragmented = _generate_message_fragmented,
.reset = _reset,
.get_unique_id = _get_unique_id,
.add_virtual_ip = _add_virtual_ip,
.clear_virtual_ips = _clear_virtual_ips,
.create_virtual_ip_enumerator = _create_virtual_ip_enumerator,
.add_configuration_attribute = _add_configuration_attribute,
.create_attribute_enumerator = _create_attribute_enumerator,
.get_if_id = _get_if_id,
.set_kmaddress = _set_kmaddress,
.create_task_enumerator = _create_task_enumerator,
.remove_task = _remove_task,
.flush_queue = _flush_queue,
.queue_task = _queue_task,
.queue_task_delayed = _queue_task_delayed,
.adopt_child_tasks = _adopt_child_tasks,
#ifdef ME
.act_as_mediation_server = _act_as_mediation_server,
.get_server_reflexive_host = _get_server_reflexive_host,
.set_server_reflexive_host = _set_server_reflexive_host,
.get_connect_id = _get_connect_id,
.initiate_mediation = _initiate_mediation,
.initiate_mediated = _initiate_mediated,
.relay = _relay,
.callback = _callback,
.respond = _respond,
#endif /* ME */
},
.ike_sa_id = ike_sa_id->clone(ike_sa_id),
.version = version,
.my_host = host_create_any(AF_INET),
.other_host = host_create_any(AF_INET),
.my_id = identification_create_from_encoding(ID_ANY, chunk_empty),
.other_id = identification_create_from_encoding(ID_ANY, chunk_empty),
.keymat = keymat_create(version, initiator),
.state = IKE_CREATED,
.stats[STAT_INBOUND] = time_monotonic(NULL),
.stats[STAT_OUTBOUND] = time_monotonic(NULL),
.my_auth = auth_cfg_create(),
.other_auth = auth_cfg_create(),
.my_auths = array_create(0, 0),
.other_auths = array_create(0, 0),
.attributes = array_create(sizeof(attribute_entry_t), 0),
.unique_id = ref_get(&unique_id),
.keepalive_interval = lib->settings->get_time(lib->settings,
"%s.keep_alive", KEEPALIVE_INTERVAL, lib->ns),
.keepalive_dpd_margin = lib->settings->get_time(lib->settings,
"%s.keep_alive_dpd_margin", 0, lib->ns),
.retry_initiate_interval = lib->settings->get_time(lib->settings,
"%s.retry_initiate_interval", 0, lib->ns),
.flush_auth_cfg = lib->settings->get_bool(lib->settings,
"%s.flush_auth_cfg", FALSE, lib->ns),
.fragment_size = lib->settings->get_int(lib->settings,
"%s.fragment_size", 1280, lib->ns),
.follow_redirects = lib->settings->get_bool(lib->settings,
"%s.follow_redirects", TRUE, lib->ns),
);
if (version == IKEV2)
{ /* always supported with IKEv2 */
enable_extension(this, EXT_DPD);
}
this->task_manager = task_manager_create(&this->public);
this->my_host->set_port(this->my_host,
charon->socket->get_port(charon->socket, FALSE));
if (!this->task_manager || !this->keymat)
{
DBG1(DBG_IKE, "IKE version %d not supported", this->version);
destroy(this);
return NULL;
}
return &this->public;
}
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