/* * Copyright (C) 2006-2011 Tobias Brunner * Copyright (C) 2005-2008 Martin Willi * Copyright (C) 2006 Daniel Roethlisberger * Copyright (C) 2005 Jan Hutter * 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 . * * 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. */ #define _GNU_SOURCE #include "child_sa.h" #include #include #include #include #include ENUM(child_sa_state_names, CHILD_CREATED, CHILD_DESTROYING, "CREATED", "ROUTED", "INSTALLING", "INSTALLED", "UPDATING", "REKEYING", "DELETING", "DESTROYING", ); typedef struct private_child_sa_t private_child_sa_t; /** * Private data of a child_sa_t object. */ struct private_child_sa_t { /** * Public interface of child_sa_t. */ child_sa_t public; /** * address of us */ host_t *my_addr; /** * address of remote */ host_t *other_addr; /** * our actually used SPI, 0 if unused */ u_int32_t my_spi; /** * others used SPI, 0 if unused */ u_int32_t other_spi; /** * our Compression Parameter Index (CPI) used, 0 if unused */ u_int16_t my_cpi; /** * others Compression Parameter Index (CPI) used, 0 if unused */ u_int16_t other_cpi; /** * List for local traffic selectors */ linked_list_t *my_ts; /** * List for remote traffic selectors */ linked_list_t *other_ts; /** * Protocol used to protect this SA, ESP|AH */ protocol_id_t protocol; /** * reqid used for this child_sa */ u_int32_t reqid; /** * inbound mark used for this child_sa */ mark_t mark_in; /** * outbound mark used for this child_sa */ mark_t mark_out; /** * absolute time when rekeying is scheduled */ time_t rekey_time; /** * absolute time when the SA expires */ time_t expire_time; /** * state of the CHILD_SA */ child_sa_state_t state; /** * TRUE if this CHILD_SA is used to install trap policies */ bool trap; /** * Specifies if UDP encapsulation is enabled (NAT traversal) */ bool encap; /** * Specifies the IPComp transform used (IPCOMP_NONE if disabled) */ ipcomp_transform_t ipcomp; /** * mode this SA uses, tunnel/transport */ ipsec_mode_t mode; /** * Action to enforce if peer closes the CHILD_SA */ action_t close_action; /** * Action to enforce if peer is considered dead */ action_t dpd_action; /** * selected proposal */ proposal_t *proposal; /** * config used to create this child */ child_cfg_t *config; /** * time of last use in seconds (inbound) */ u_int32_t my_usetime; /** * time of last use in seconds (outbound) */ u_int32_t other_usetime; /** * last number of inbound bytes */ u_int64_t my_usebytes; /** * last number of outbound bytes */ u_int64_t other_usebytes; }; /** * convert an IKEv2 specific protocol identifier to the IP protocol identifier. */ static inline u_int8_t proto_ike2ip(protocol_id_t protocol) { switch (protocol) { case PROTO_ESP: return IPPROTO_ESP; case PROTO_AH: return IPPROTO_AH; default: return protocol; } } METHOD(child_sa_t, get_name, char*, private_child_sa_t *this) { return this->config->get_name(this->config); } METHOD(child_sa_t, get_reqid, u_int32_t, private_child_sa_t *this) { return this->reqid; } METHOD(child_sa_t, get_config, child_cfg_t*, private_child_sa_t *this) { return this->config; } METHOD(child_sa_t, set_state, void, private_child_sa_t *this, child_sa_state_t state) { charon->bus->child_state_change(charon->bus, &this->public, state); this->state = state; } METHOD(child_sa_t, get_state, child_sa_state_t, private_child_sa_t *this) { return this->state; } METHOD(child_sa_t, get_spi, u_int32_t, private_child_sa_t *this, bool inbound) { return inbound ? this->my_spi : this->other_spi; } METHOD(child_sa_t, get_cpi, u_int16_t, private_child_sa_t *this, bool inbound) { return inbound ? this->my_cpi : this->other_cpi; } METHOD(child_sa_t, get_protocol, protocol_id_t, private_child_sa_t *this) { return this->protocol; } METHOD(child_sa_t, set_protocol, void, private_child_sa_t *this, protocol_id_t protocol) { this->protocol = protocol; } METHOD(child_sa_t, get_mode, ipsec_mode_t, private_child_sa_t *this) { return this->mode; } METHOD(child_sa_t, set_mode, void, private_child_sa_t *this, ipsec_mode_t mode) { this->mode = mode; } METHOD(child_sa_t, has_encap, bool, private_child_sa_t *this) { return this->encap; } METHOD(child_sa_t, get_ipcomp, ipcomp_transform_t, private_child_sa_t *this) { return this->ipcomp; } METHOD(child_sa_t, set_ipcomp, void, private_child_sa_t *this, ipcomp_transform_t ipcomp) { this->ipcomp = ipcomp; } METHOD(child_sa_t, set_close_action, void, private_child_sa_t *this, action_t action) { this->close_action = action; } METHOD(child_sa_t, get_close_action, action_t, private_child_sa_t *this) { return this->close_action; } METHOD(child_sa_t, set_dpd_action, void, private_child_sa_t *this, action_t action) { this->dpd_action = action; } METHOD(child_sa_t, get_dpd_action, action_t, private_child_sa_t *this) { return this->dpd_action; } METHOD(child_sa_t, get_proposal, proposal_t*, private_child_sa_t *this) { return this->proposal; } METHOD(child_sa_t, set_proposal, void, private_child_sa_t *this, proposal_t *proposal) { this->proposal = proposal->clone(proposal); } METHOD(child_sa_t, get_traffic_selectors, linked_list_t*, private_child_sa_t *this, bool local) { return local ? this->my_ts : this->other_ts; } typedef struct policy_enumerator_t policy_enumerator_t; /** * Private policy enumerator */ struct policy_enumerator_t { /** implements enumerator_t */ enumerator_t public; /** enumerator over own TS */ enumerator_t *mine; /** enumerator over others TS */ enumerator_t *other; /** list of others TS, to recreate enumerator */ linked_list_t *list; /** currently enumerating TS for "me" side */ traffic_selector_t *ts; }; METHOD(enumerator_t, policy_enumerate, bool, policy_enumerator_t *this, traffic_selector_t **my_out, traffic_selector_t **other_out) { traffic_selector_t *other_ts; while (this->ts || this->mine->enumerate(this->mine, &this->ts)) { if (!this->other->enumerate(this->other, &other_ts)) { /* end of others list, restart with new of mine */ this->other->destroy(this->other); this->other = this->list->create_enumerator(this->list); this->ts = NULL; continue; } if (this->ts->get_type(this->ts) != other_ts->get_type(other_ts)) { /* family mismatch */ continue; } if (this->ts->get_protocol(this->ts) && other_ts->get_protocol(other_ts) && this->ts->get_protocol(this->ts) != other_ts->get_protocol(other_ts)) { /* protocol mismatch */ continue; } *my_out = this->ts; *other_out = other_ts; return TRUE; } return FALSE; } METHOD(enumerator_t, policy_destroy, void, policy_enumerator_t *this) { this->mine->destroy(this->mine); this->other->destroy(this->other); free(this); } METHOD(child_sa_t, create_policy_enumerator, enumerator_t*, private_child_sa_t *this) { policy_enumerator_t *e; INIT(e, .public = { .enumerate = (void*)_policy_enumerate, .destroy = _policy_destroy, }, .mine = this->my_ts->create_enumerator(this->my_ts), .other = this->other_ts->create_enumerator(this->other_ts), .list = this->other_ts, .ts = NULL, ); return &e->public; } /** * update the cached usebytes * returns SUCCESS if the usebytes have changed, FAILED if not or no SPIs * are available, and NOT_SUPPORTED if the kernel interface does not support * querying the usebytes. */ static status_t update_usebytes(private_child_sa_t *this, bool inbound) { status_t status = FAILED; u_int64_t bytes; if (inbound) { if (this->my_spi) { status = hydra->kernel_interface->query_sa(hydra->kernel_interface, this->other_addr, this->my_addr, this->my_spi, proto_ike2ip(this->protocol), this->mark_in, &bytes); if (status == SUCCESS) { if (bytes > this->my_usebytes) { this->my_usebytes = bytes; return SUCCESS; } return FAILED; } } } else { if (this->other_spi) { status = hydra->kernel_interface->query_sa(hydra->kernel_interface, this->my_addr, this->other_addr, this->other_spi, proto_ike2ip(this->protocol), this->mark_out, &bytes); if (status == SUCCESS) { if (bytes > this->other_usebytes) { this->other_usebytes = bytes; return SUCCESS; } return FAILED; } } } return status; } /** * updates the cached usetime */ static void update_usetime(private_child_sa_t *this, bool inbound) { enumerator_t *enumerator; traffic_selector_t *my_ts, *other_ts; u_int32_t last_use = 0; enumerator = create_policy_enumerator(this); while (enumerator->enumerate(enumerator, &my_ts, &other_ts)) { u_int32_t in, out, fwd; if (inbound) { if (hydra->kernel_interface->query_policy(hydra->kernel_interface, other_ts, my_ts, POLICY_IN, this->mark_in, &in) == SUCCESS) { last_use = max(last_use, in); } if (this->mode != MODE_TRANSPORT) { if (hydra->kernel_interface->query_policy(hydra->kernel_interface, other_ts, my_ts, POLICY_FWD, this->mark_in, &fwd) == SUCCESS) { last_use = max(last_use, fwd); } } } else { if (hydra->kernel_interface->query_policy(hydra->kernel_interface, my_ts, other_ts, POLICY_OUT, this->mark_out, &out) == SUCCESS) { last_use = max(last_use, out); } } } enumerator->destroy(enumerator); if (last_use == 0) { return; } if (inbound) { this->my_usetime = last_use; } else { this->other_usetime = last_use; } } METHOD(child_sa_t, get_usestats, void, private_child_sa_t *this, bool inbound, time_t *time, u_int64_t *bytes) { if (update_usebytes(this, inbound) != FAILED) { /* there was traffic since last update or the kernel interface * does not support querying the number of usebytes. */ update_usetime(this, inbound); } if (time) { *time = inbound ? this->my_usetime : this->other_usetime; } if (bytes) { *bytes = inbound ? this->my_usebytes : this->other_usebytes; } } METHOD(child_sa_t, get_mark, mark_t, private_child_sa_t *this, bool inbound) { if (inbound) { return this->mark_in; } return this->mark_out; } METHOD(child_sa_t, get_lifetime, time_t, private_child_sa_t *this, bool hard) { return hard ? this->expire_time : this->rekey_time; } METHOD(child_sa_t, alloc_spi, u_int32_t, private_child_sa_t *this, protocol_id_t protocol) { if (hydra->kernel_interface->get_spi(hydra->kernel_interface, this->other_addr, this->my_addr, proto_ike2ip(protocol), this->reqid, &this->my_spi) == SUCCESS) { return this->my_spi; } return 0; } METHOD(child_sa_t, alloc_cpi, u_int16_t, private_child_sa_t *this) { if (hydra->kernel_interface->get_cpi(hydra->kernel_interface, this->other_addr, this->my_addr, this->reqid, &this->my_cpi) == SUCCESS) { return this->my_cpi; } return 0; } METHOD(child_sa_t, install, status_t, private_child_sa_t *this, chunk_t encr, chunk_t integ, u_int32_t spi, u_int16_t cpi, bool inbound, bool tfcv3, linked_list_t *my_ts, linked_list_t *other_ts) { u_int16_t enc_alg = ENCR_UNDEFINED, int_alg = AUTH_UNDEFINED, size; u_int16_t esn = NO_EXT_SEQ_NUMBERS; traffic_selector_t *src_ts = NULL, *dst_ts = NULL; time_t now; lifetime_cfg_t *lifetime; u_int32_t tfc = 0; host_t *src, *dst; status_t status; bool update = FALSE; /* now we have to decide which spi to use. Use self allocated, if "in", * or the one in the proposal, if not "in" (others). Additionally, * source and dest host switch depending on the role */ if (inbound) { dst = this->my_addr; src = this->other_addr; if (this->my_spi == spi) { /* alloc_spi has been called, do an SA update */ update = TRUE; } this->my_spi = spi; this->my_cpi = cpi; } else { src = this->my_addr; dst = this->other_addr; this->other_spi = spi; this->other_cpi = cpi; if (tfcv3) { tfc = this->config->get_tfc(this->config); } } DBG2(DBG_CHD, "adding %s %N SA", inbound ? "inbound" : "outbound", protocol_id_names, this->protocol); /* send SA down to the kernel */ DBG2(DBG_CHD, " SPI 0x%.8x, src %H dst %H", ntohl(spi), src, dst); this->proposal->get_algorithm(this->proposal, ENCRYPTION_ALGORITHM, &enc_alg, &size); this->proposal->get_algorithm(this->proposal, INTEGRITY_ALGORITHM, &int_alg, &size); this->proposal->get_algorithm(this->proposal, EXTENDED_SEQUENCE_NUMBERS, &esn, NULL); lifetime = this->config->get_lifetime(this->config); now = time_monotonic(NULL); if (lifetime->time.rekey) { if (this->rekey_time) { this->rekey_time = min(this->rekey_time, now + lifetime->time.rekey); } else { this->rekey_time = now + lifetime->time.rekey; } } if (lifetime->time.life) { this->expire_time = now + lifetime->time.life; } if (!lifetime->time.jitter && !inbound) { /* avoid triggering multiple rekey events */ lifetime->time.rekey = 0; } if (this->mode == MODE_BEET || this->mode == MODE_TRANSPORT) { /* BEET requires the bound address from the traffic selectors. * TODO: We add just the first traffic selector for now, as the * kernel accepts a single TS per SA only */ if (inbound) { my_ts->get_first(my_ts, (void**)&dst_ts); other_ts->get_first(other_ts, (void**)&src_ts); } else { my_ts->get_first(my_ts, (void**)&src_ts); other_ts->get_first(other_ts, (void**)&dst_ts); } } status = hydra->kernel_interface->add_sa(hydra->kernel_interface, src, dst, spi, proto_ike2ip(this->protocol), this->reqid, inbound ? this->mark_in : this->mark_out, tfc, lifetime, enc_alg, encr, int_alg, integ, this->mode, this->ipcomp, cpi, this->encap, esn, update, src_ts, dst_ts); free(lifetime); return status; } /** * Install 3 policies: out, in and forward */ static status_t install_policies_internal(private_child_sa_t *this, host_t *my_addr, host_t *other_addr, traffic_selector_t *my_ts, traffic_selector_t *other_ts, ipsec_sa_cfg_t *my_sa, ipsec_sa_cfg_t *other_sa, policy_type_t type, policy_priority_t priority) { status_t status = SUCCESS; status |= hydra->kernel_interface->add_policy(hydra->kernel_interface, my_addr, other_addr, my_ts, other_ts, POLICY_OUT, type, other_sa, this->mark_out, priority); status |= hydra->kernel_interface->add_policy(hydra->kernel_interface, other_addr, my_addr, other_ts, my_ts, POLICY_IN, type, my_sa, this->mark_in, priority); if (this->mode != MODE_TRANSPORT) { status |= hydra->kernel_interface->add_policy(hydra->kernel_interface, other_addr, my_addr, other_ts, my_ts, POLICY_FWD, type, my_sa, this->mark_in, priority); } return status; } /** * Delete 3 policies: out, in and forward */ static void del_policies_internal(private_child_sa_t *this, traffic_selector_t *my_ts, traffic_selector_t *other_ts, policy_priority_t priority) { hydra->kernel_interface->del_policy(hydra->kernel_interface, my_ts, other_ts, POLICY_OUT, this->reqid, this->mark_out, priority); hydra->kernel_interface->del_policy(hydra->kernel_interface, other_ts, my_ts, POLICY_IN, this->reqid, this->mark_in, priority); if (this->mode != MODE_TRANSPORT) { hydra->kernel_interface->del_policy(hydra->kernel_interface, other_ts, my_ts, POLICY_FWD, this->reqid, this->mark_in, priority); } } METHOD(child_sa_t, add_policies, status_t, private_child_sa_t *this, linked_list_t *my_ts_list, linked_list_t *other_ts_list) { enumerator_t *enumerator; traffic_selector_t *my_ts, *other_ts; status_t status = SUCCESS; /* apply traffic selectors */ enumerator = my_ts_list->create_enumerator(my_ts_list); while (enumerator->enumerate(enumerator, &my_ts)) { this->my_ts->insert_last(this->my_ts, my_ts->clone(my_ts)); } enumerator->destroy(enumerator); enumerator = other_ts_list->create_enumerator(other_ts_list); while (enumerator->enumerate(enumerator, &other_ts)) { this->other_ts->insert_last(this->other_ts, other_ts->clone(other_ts)); } enumerator->destroy(enumerator); if (this->config->install_policy(this->config)) { policy_priority_t priority; ipsec_sa_cfg_t my_sa = { .mode = this->mode, .reqid = this->reqid, .ipcomp = { .transform = this->ipcomp, }, }, other_sa = my_sa; my_sa.ipcomp.cpi = this->my_cpi; other_sa.ipcomp.cpi = this->other_cpi; if (this->protocol == PROTO_ESP) { my_sa.esp.use = TRUE; my_sa.esp.spi = this->my_spi; other_sa.esp.use = TRUE; other_sa.esp.spi = this->other_spi; } else { my_sa.ah.use = TRUE; my_sa.ah.spi = this->my_spi; other_sa.ah.use = TRUE; other_sa.ah.spi = this->other_spi; } /* if we're not in state CHILD_INSTALLING (i.e. if there is no SAD * entry) we install a trap policy */ this->trap = this->state == CHILD_CREATED; priority = this->trap ? POLICY_PRIORITY_ROUTED : POLICY_PRIORITY_DEFAULT; /* enumerate pairs of traffic selectors */ enumerator = create_policy_enumerator(this); while (enumerator->enumerate(enumerator, &my_ts, &other_ts)) { /* install outbound drop policy to avoid packets leaving unencrypted * when updating policies */ if (priority == POLICY_PRIORITY_DEFAULT) { status |= install_policies_internal(this, this->my_addr, this->other_addr, my_ts, other_ts, &my_sa, &other_sa, POLICY_DROP, POLICY_PRIORITY_FALLBACK); } /* install policies */ status |= install_policies_internal(this, this->my_addr, this->other_addr, my_ts, other_ts, &my_sa, &other_sa, POLICY_IPSEC, priority); if (status != SUCCESS) { break; } } enumerator->destroy(enumerator); } if (status == SUCCESS && this->trap) { set_state(this, CHILD_ROUTED); } return status; } /** * Callback to reinstall a virtual IP */ static void reinstall_vip(host_t *vip, host_t *me) { char *iface; if (hydra->kernel_interface->get_interface(hydra->kernel_interface, me, &iface)) { hydra->kernel_interface->del_ip(hydra->kernel_interface, vip, -1, TRUE); hydra->kernel_interface->add_ip(hydra->kernel_interface, vip, -1, iface); free(iface); } } METHOD(child_sa_t, update, status_t, private_child_sa_t *this, host_t *me, host_t *other, linked_list_t *vips, bool encap) { child_sa_state_t old; bool transport_proxy_mode; /* anything changed at all? */ if (me->equals(me, this->my_addr) && other->equals(other, this->other_addr) && this->encap == encap) { return SUCCESS; } old = this->state; set_state(this, CHILD_UPDATING); transport_proxy_mode = this->config->use_proxy_mode(this->config) && this->mode == MODE_TRANSPORT; if (!transport_proxy_mode) { /* update our (initiator) SA */ if (this->my_spi) { if (hydra->kernel_interface->update_sa(hydra->kernel_interface, this->my_spi, proto_ike2ip(this->protocol), this->ipcomp != IPCOMP_NONE ? this->my_cpi : 0, this->other_addr, this->my_addr, other, me, this->encap, encap, this->mark_in) == NOT_SUPPORTED) { return NOT_SUPPORTED; } } /* update his (responder) SA */ if (this->other_spi) { if (hydra->kernel_interface->update_sa(hydra->kernel_interface, this->other_spi, proto_ike2ip(this->protocol), this->ipcomp != IPCOMP_NONE ? this->other_cpi : 0, this->my_addr, this->other_addr, me, other, this->encap, encap, this->mark_out) == NOT_SUPPORTED) { return NOT_SUPPORTED; } } } if (this->config->install_policy(this->config)) { ipsec_sa_cfg_t my_sa = { .mode = this->mode, .reqid = this->reqid, .ipcomp = { .transform = this->ipcomp, }, }, other_sa = my_sa; my_sa.ipcomp.cpi = this->my_cpi; other_sa.ipcomp.cpi = this->other_cpi; if (this->protocol == PROTO_ESP) { my_sa.esp.use = TRUE; my_sa.esp.spi = this->my_spi; other_sa.esp.use = TRUE; other_sa.esp.spi = this->other_spi; } else { my_sa.ah.use = TRUE; my_sa.ah.spi = this->my_spi; other_sa.ah.use = TRUE; other_sa.ah.spi = this->other_spi; } /* update policies */ if (!me->ip_equals(me, this->my_addr) || !other->ip_equals(other, this->other_addr)) { enumerator_t *enumerator; traffic_selector_t *my_ts, *other_ts; /* always use high priorities, as hosts getting updated are INSTALLED */ enumerator = create_policy_enumerator(this); while (enumerator->enumerate(enumerator, &my_ts, &other_ts)) { traffic_selector_t *old_my_ts = NULL, *old_other_ts = NULL; /* remove old policies first */ del_policies_internal(this, my_ts, other_ts, POLICY_PRIORITY_DEFAULT); /* check if we have to update a "dynamic" traffic selector */ if (!me->ip_equals(me, this->my_addr) && my_ts->is_host(my_ts, this->my_addr)) { old_my_ts = my_ts->clone(my_ts); my_ts->set_address(my_ts, me); } if (!other->ip_equals(other, this->other_addr) && other_ts->is_host(other_ts, this->other_addr)) { old_other_ts = other_ts->clone(other_ts); other_ts->set_address(other_ts, other); } /* we reinstall the virtual IP to handle interface roaming * correctly */ vips->invoke_function(vips, (void*)reinstall_vip, me); /* reinstall updated policies */ install_policies_internal(this, me, other, my_ts, other_ts, &my_sa, &other_sa, POLICY_IPSEC, POLICY_PRIORITY_DEFAULT); /* update fallback policies after the new policy is in place */ if (old_my_ts || old_other_ts) { del_policies_internal(this, old_my_ts ?: my_ts, old_other_ts ?: other_ts, POLICY_PRIORITY_FALLBACK); install_policies_internal(this, me, other, my_ts, other_ts, &my_sa, &other_sa, POLICY_DROP, POLICY_PRIORITY_FALLBACK); DESTROY_IF(old_my_ts); DESTROY_IF(old_other_ts); } } enumerator->destroy(enumerator); } } if (!transport_proxy_mode) { /* apply hosts */ if (!me->equals(me, this->my_addr)) { this->my_addr->destroy(this->my_addr); this->my_addr = me->clone(me); } if (!other->equals(other, this->other_addr)) { this->other_addr->destroy(this->other_addr); this->other_addr = other->clone(other); } } this->encap = encap; set_state(this, old); return SUCCESS; } METHOD(child_sa_t, destroy, void, private_child_sa_t *this) { enumerator_t *enumerator; traffic_selector_t *my_ts, *other_ts; policy_priority_t priority; priority = this->trap ? POLICY_PRIORITY_ROUTED : POLICY_PRIORITY_DEFAULT; set_state(this, CHILD_DESTROYING); /* delete SAs in the kernel, if they are set up */ if (this->my_spi) { /* if CHILD was not established, use PROTO_ESP used during alloc_spi(). * TODO: For AH support, we have to store protocol specific SPI.s */ if (this->protocol == PROTO_NONE) { this->protocol = PROTO_ESP; } hydra->kernel_interface->del_sa(hydra->kernel_interface, this->other_addr, this->my_addr, this->my_spi, proto_ike2ip(this->protocol), this->my_cpi, this->mark_in); } if (this->other_spi) { hydra->kernel_interface->del_sa(hydra->kernel_interface, this->my_addr, this->other_addr, this->other_spi, proto_ike2ip(this->protocol), this->other_cpi, this->mark_out); } if (this->config->install_policy(this->config)) { /* delete all policies in the kernel */ enumerator = create_policy_enumerator(this); while (enumerator->enumerate(enumerator, &my_ts, &other_ts)) { del_policies_internal(this, my_ts, other_ts, priority); if (priority == POLICY_PRIORITY_DEFAULT) { del_policies_internal(this, my_ts, other_ts, POLICY_PRIORITY_FALLBACK); } } enumerator->destroy(enumerator); } this->my_ts->destroy_offset(this->my_ts, offsetof(traffic_selector_t, destroy)); this->other_ts->destroy_offset(this->other_ts, offsetof(traffic_selector_t, destroy)); this->my_addr->destroy(this->my_addr); this->other_addr->destroy(this->other_addr); DESTROY_IF(this->proposal); this->config->destroy(this->config); free(this); } /** * Described in header. */ child_sa_t * child_sa_create(host_t *me, host_t* other, child_cfg_t *config, u_int32_t rekey, bool encap) { static u_int32_t reqid = 0; private_child_sa_t *this; INIT(this, .public = { .get_name = _get_name, .get_reqid = _get_reqid, .get_config = _get_config, .get_state = _get_state, .set_state = _set_state, .get_spi = _get_spi, .get_cpi = _get_cpi, .get_protocol = _get_protocol, .set_protocol = _set_protocol, .get_mode = _get_mode, .set_mode = _set_mode, .get_proposal = _get_proposal, .set_proposal = _set_proposal, .get_lifetime = _get_lifetime, .get_usestats = _get_usestats, .get_mark = _get_mark, .has_encap = _has_encap, .get_ipcomp = _get_ipcomp, .set_ipcomp = _set_ipcomp, .get_close_action = _get_close_action, .set_close_action = _set_close_action, .get_dpd_action = _get_dpd_action, .set_dpd_action = _set_dpd_action, .alloc_spi = _alloc_spi, .alloc_cpi = _alloc_cpi, .install = _install, .update = _update, .add_policies = _add_policies, .get_traffic_selectors = _get_traffic_selectors, .create_policy_enumerator = _create_policy_enumerator, .destroy = _destroy, }, .my_addr = me->clone(me), .other_addr = other->clone(other), .encap = encap, .ipcomp = IPCOMP_NONE, .state = CHILD_CREATED, .my_ts = linked_list_create(), .other_ts = linked_list_create(), .protocol = PROTO_NONE, .mode = MODE_TUNNEL, .close_action = config->get_close_action(config), .dpd_action = config->get_dpd_action(config), .reqid = config->get_reqid(config), .mark_in = config->get_mark(config, TRUE), .mark_out = config->get_mark(config, FALSE), ); this->config = config; config->get_ref(config); if (!this->reqid) { /* reuse old reqid if we are rekeying an existing CHILD_SA */ this->reqid = rekey ? rekey : ++reqid; } if (this->mark_in.value == MARK_REQID) { this->mark_in.value = this->reqid; } if (this->mark_out.value == MARK_REQID) { this->mark_out.value = this->reqid; } /* MIPv6 proxy transport mode sets SA endpoints to TS hosts */ if (config->get_mode(config) == MODE_TRANSPORT && config->use_proxy_mode(config)) { ts_type_t type; int family; chunk_t addr; host_t *host; enumerator_t *enumerator; linked_list_t *my_ts_list, *other_ts_list, *list; traffic_selector_t *my_ts, *other_ts; this->mode = MODE_TRANSPORT; list = linked_list_create_with_items(me, NULL); my_ts_list = config->get_traffic_selectors(config, TRUE, NULL, list); list->destroy(list); enumerator = my_ts_list->create_enumerator(my_ts_list); if (enumerator->enumerate(enumerator, &my_ts)) { if (my_ts->is_host(my_ts, NULL) && !my_ts->is_host(my_ts, this->my_addr)) { type = my_ts->get_type(my_ts); family = (type == TS_IPV4_ADDR_RANGE) ? AF_INET : AF_INET6; addr = my_ts->get_from_address(my_ts); host = host_create_from_chunk(family, addr, 0); free(addr.ptr); DBG1(DBG_CHD, "my address: %H is a transport mode proxy for %H", this->my_addr, host); this->my_addr->destroy(this->my_addr); this->my_addr = host; } } enumerator->destroy(enumerator); my_ts_list->destroy_offset(my_ts_list, offsetof(traffic_selector_t, destroy)); list = linked_list_create_with_items(other, NULL); other_ts_list = config->get_traffic_selectors(config, FALSE, NULL, list); list->destroy(list); enumerator = other_ts_list->create_enumerator(other_ts_list); if (enumerator->enumerate(enumerator, &other_ts)) { if (other_ts->is_host(other_ts, NULL) && !other_ts->is_host(other_ts, this->other_addr)) { type = other_ts->get_type(other_ts); family = (type == TS_IPV4_ADDR_RANGE) ? AF_INET : AF_INET6; addr = other_ts->get_from_address(other_ts); host = host_create_from_chunk(family, addr, 0); free(addr.ptr); DBG1(DBG_CHD, "other address: %H is a transport mode proxy for %H", this->other_addr, host); this->other_addr->destroy(this->other_addr); this->other_addr = host; } } enumerator->destroy(enumerator); other_ts_list->destroy_offset(other_ts_list, offsetof(traffic_selector_t, destroy)); } return &this->public; }