/** * @file ike_sa.h * * @brief Interface of ike_sa_t. * */ /* * Copyright (C) 2006 Tobias Brunner, Daniel Roethlisberger * Copyright (C) 2005-2006 Martin Willi * 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. */ #ifndef IKE_SA_H_ #define IKE_SA_H_ typedef enum ike_sa_state_t ike_sa_state_t; typedef struct ike_sa_t ike_sa_t; #include #include #include #include #include #include #include #include #include #include #include #include #include /** * @brief State of an IKE_SA. * * An IKE_SA passes various states in its lifetime. A newly created * SA is in the state CREATED. * @verbatim +----------------+ ¦ SA_CREATED ¦ +----------------+ ¦ on initiate()---> ¦ <----- on IKE_SA_INIT received V +----------------+ ¦ SA_CONNECTING ¦ +----------------+ ¦ ¦ <----- on IKE_AUTH successfully completed V +----------------+ ¦ SA_ESTABLISHED ¦-------------------------+ <-- on rekeying +----------------+ ¦ ¦ V on delete()---> ¦ <----- on IKE_SA +-------------+ ¦ delete request ¦ SA_REKEYING ¦ ¦ received +-------------+ V ¦ +----------------+ ¦ ¦ SA_DELETING ¦<------------------------+ <-- after rekeying +----------------+ ¦ ¦ <----- after delete() acknowledged ¦ \V/ X / \ @endverbatim * * @ingroup sa */ enum ike_sa_state_t { /** * IKE_SA just got created, but is not initiating nor responding yet. */ IKE_CREATED, /** * IKE_SA gets initiated actively or passively */ IKE_CONNECTING, /** * IKE_SA is fully established */ IKE_ESTABLISHED, /** * IKE_SA rekeying in progress */ IKE_REKEYING, /** * IKE_SA is in progress of deletion */ IKE_DELETING, }; /** * enum names for ike_sa_state_t. */ extern enum_name_t *ike_sa_state_names; /** * @brief Class ike_sa_t representing an IKE_SA. * * An IKE_SA contains crypto information related to a connection * with a peer. It contains multiple IPsec CHILD_SA, for which * it is responsible. All traffic is handled by an IKE_SA, using * the task manager and its tasks. * * @b Constructors: * - ike_sa_create() * * @ingroup sa */ struct ike_sa_t { /** * @brief Get the id of the SA. * * Returned ike_sa_id_t object is not getting cloned! * * @param this calling object * @return ike_sa's ike_sa_id_t */ ike_sa_id_t* (*get_id) (ike_sa_t *this); /** * @brief Get the numerical ID uniquely defining this IKE_SA. * * @param this calling object * @return unique ID */ u_int32_t (*get_unique_id) (ike_sa_t *this); /** * @brief Get the state of the IKE_SA. * * @param this calling object * @return state of the IKE_SA */ ike_sa_state_t (*get_state) (ike_sa_t *this); /** * @brief Set the state of the IKE_SA. * * @param this calling object * @param state state to set for the IKE_SA */ void (*set_state) (ike_sa_t *this, ike_sa_state_t ike_sa); /** * @brief Get the name of the connection this IKE_SA uses. * * @param this calling object * @return name */ char* (*get_name) (ike_sa_t *this); /** * @brief Get the own host address. * * @param this calling object * @return host address */ host_t* (*get_my_host) (ike_sa_t *this); /** * @brief Set the own host address. * * @param this calling object * @param me host address */ void (*set_my_host) (ike_sa_t *this, host_t *me); /** * @brief Get the other peers host address. * * @param this calling object * @return host address */ host_t* (*get_other_host) (ike_sa_t *this); /** * @brief Set the others host address. * * @param this calling object * @param other host address */ void (*set_other_host) (ike_sa_t *this, host_t *other); /** * @brief Get the own identification. * * @param this calling object * @return identification */ identification_t* (*get_my_id) (ike_sa_t *this); /** * @brief Set the own identification. * * @param this calling object * @param me identification */ void (*set_my_id) (ike_sa_t *this, identification_t *me); /** * @brief Get the other peers identification. * * @param this calling object * @return identification */ identification_t* (*get_other_id) (ike_sa_t *this); /** * @brief Set the other peers identification. * * @param this calling object * @param other identification */ void (*set_other_id) (ike_sa_t *this, identification_t *other); /** * @brief Get the config used to setup this IKE_SA. * * @param this calling object * @return ike_config */ ike_cfg_t* (*get_ike_cfg) (ike_sa_t *this); /** * @brief Set the config to setup this IKE_SA. * * @param this calling object * @param config ike_config to use */ void (*set_ike_cfg) (ike_sa_t *this, ike_cfg_t* config); /** * @brief Get the peer config used by this IKE_SA. * * @param this calling object * @return peer_config */ peer_cfg_t* (*get_peer_cfg) (ike_sa_t *this); /** * @brief Set the peer config to use with this IKE_SA. * * @param this calling object * @param config peer_config to use */ void (*set_peer_cfg) (ike_sa_t *this, peer_cfg_t *config); /** * @brief Initiate a new connection. * * The configs are owned by the IKE_SA after the call. * * @param this calling object * @param child_cfg child config to create CHILD from * @return * - SUCCESS if initialization started * - DESTROY_ME if initialization failed */ status_t (*initiate) (ike_sa_t *this, child_cfg_t *child_cfg); /** * @brief Route a policy in the kernel. * * Installs the policies in the kernel. If traffic matches, * the kernel requests connection setup from the IKE_SA via acquire(). * * @param this calling object * @param child_cfg child config to route * @return * - SUCCESS if routed successfully * - FAILED if routing failed */ status_t (*route) (ike_sa_t *this, child_cfg_t *child_cfg); /** * @brief Unroute a policy in the kernel previously routed. * * @param this calling object * @param child_cfg child config to unroute * @return * - SUCCESS if route removed * - DESTROY_ME if last CHILD_SA was unrouted */ status_t (*unroute) (ike_sa_t *this, child_cfg_t *child_cfg); /** * @brief Acquire connection setup for an installed kernel policy. * * If an installed policy raises an acquire, the kernel calls * this function to establish the CHILD_SA (and maybe the IKE_SA). * * @param this calling object * @param reqid reqid of the CHILD_SA the policy belongs to. * @return * - SUCCESS if initialization started * - DESTROY_ME if initialization failed */ status_t (*acquire) (ike_sa_t *this, u_int32_t reqid); /** * @brief Initiates the deletion of an IKE_SA. * * Sends a delete message to the remote peer and waits for * its response. If the response comes in, or a timeout occurs, * the IKE SA gets deleted. * * @param this calling object * @return * - SUCCESS if deletion is initialized * - INVALID_STATE, if the IKE_SA is not in * an established state and can not be * delete (but destroyed). */ status_t (*delete) (ike_sa_t *this); /** * @brief Processes a incoming IKEv2-Message. * * Message processing may fail. If a critical failure occurs, * process_message() return DESTROY_ME. Then the caller must * destroy the IKE_SA immediatly, as it is unusable. * * @param this calling object * @param message message to process * @return * - SUCCESS * - FAILED * - DESTROY_ME if this IKE_SA MUST be deleted */ status_t (*process_message) (ike_sa_t *this, message_t *message); /** * @brief Generate a IKE message to send it to the peer. * * This method generates all payloads in the message and encrypts/signs * the packet. * * @param this calling object * @param message message to generate * @param packet generated output packet * @return * - SUCCESS * - FAILED * - DESTROY_ME if this IKE_SA MUST be deleted */ status_t (*generate_message) (ike_sa_t *this, message_t *message, packet_t **packet); /** * @brief Retransmits a request. * * @param this calling object * @param message_id ID of the request to retransmit * @return * - SUCCESS * - NOT_FOUND if request doesn't have to be retransmited */ status_t (*retransmit) (ike_sa_t *this, u_int32_t message_id); /** * @brief Sends a DPD request to the peer. * * To check if a peer is still alive, periodic * empty INFORMATIONAL messages are sent if no * other traffic was received. * * @param this calling object * @return * - SUCCESS * - DESTROY_ME, if peer did not respond */ status_t (*send_dpd) (ike_sa_t *this); /** * @brief Sends a keep alive packet. * * To refresh NAT tables in a NAT router * between the peers, periodic empty * UDP packets are sent if no other traffic * was sent. * * @param this calling object */ void (*send_keepalive) (ike_sa_t *this); /** * @brief Check if NAT traversal is enabled for this IKE_SA. * * @param this calling object * @return TRUE if NAT traversal enabled */ bool (*is_natt_enabled) (ike_sa_t *this); /** * @brief Enable NAT detection for this IKE_SA. * * If a Network address translation is detected with * NAT_DETECTION notifys, a SA must switch to ports * 4500. To enable this behavior, call enable_natt(). * It is relevant which peer is NATted, this is specified * with the "local" parameter. Call it twice when both * are NATted. * * @param this calling object * @param local TRUE, if we are NATted, FALSE if other */ void (*enable_natt) (ike_sa_t *this, bool local); /** * @brief Derive all keys and create the transforms for IKE communication. * * Keys are derived using the diffie hellman secret, nonces and internal * stored SPIs. * Key derivation differs when an IKE_SA is set up to replace an * existing IKE_SA (rekeying). The SK_d key from the old IKE_SA * is included in the derivation process. * * @param this calling object * @param proposal proposal which contains algorithms to use * @param secret secret derived from DH exchange, gets freed * @param nonce_i initiators nonce * @param nonce_r responders nonce * @param initiator TRUE if initiator, FALSE otherwise * @param child_prf PRF with SK_d key when rekeying, NULL otherwise * @param old_prf general purpose PRF of old SA when rekeying */ status_t (*derive_keys)(ike_sa_t *this, proposal_t* proposal, chunk_t secret, chunk_t nonce_i, chunk_t nonce_r, bool initiator, prf_t *child_prf, prf_t *old_prf); /** * @brief Get the multi purpose prf. * * @param this calling object * @return pointer to prf_t object */ prf_t *(*get_prf) (ike_sa_t *this); /** * @brief Get the prf-object, which is used to derive keys for child SAs. * * @param this calling object * @return pointer to prf_t object */ prf_t *(*get_child_prf) (ike_sa_t *this); /** * @brief Get the prf to build outgoing authentication data. * * @param this calling object * @return pointer to prf_t object */ prf_t *(*get_auth_build) (ike_sa_t *this); /** * @brief Get the prf to verify incoming authentication data. * * @param this calling object * @return pointer to prf_t object */ prf_t *(*get_auth_verify) (ike_sa_t *this); /** * @brief Associates a child SA to this IKE SA * * @param this calling object * @param child_sa child_sa to add */ void (*add_child_sa) (ike_sa_t *this, child_sa_t *child_sa); /** * @brief Get a CHILD_SA identified by protocol and SPI. * * @param this calling object * @param protocol protocol of the SA * @param spi SPI of the CHILD_SA * @param inbound TRUE if SPI is inbound, FALSE if outbound * @return child_sa, or NULL if none found */ child_sa_t* (*get_child_sa) (ike_sa_t *this, protocol_id_t protocol, u_int32_t spi, bool inbound); /** * @brief Create an iterator over all CHILD_SAs. * * @param this calling object * @return iterator */ iterator_t* (*create_child_sa_iterator) (ike_sa_t *this); /** * @brief Rekey the CHILD SA with the specified reqid. * * Looks for a CHILD SA owned by this IKE_SA, and start the rekeing. * * @param this calling object * @param protocol protocol of the SA * @param spi inbound SPI of the CHILD_SA * @return * - NOT_FOUND, if IKE_SA has no such CHILD_SA * - SUCCESS, if rekeying initiated */ status_t (*rekey_child_sa) (ike_sa_t *this, protocol_id_t protocol, u_int32_t spi); /** * @brief Close the CHILD SA with the specified protocol/SPI. * * Looks for a CHILD SA owned by this IKE_SA, deletes it and * notify's the remote peer about the delete. The associated * states and policies in the kernel get deleted, if they exist. * * @param this calling object * @param protocol protocol of the SA * @param spi inbound SPI of the CHILD_SA * @return * - NOT_FOUND, if IKE_SA has no such CHILD_SA * - SUCCESS, if delete message sent */ status_t (*delete_child_sa) (ike_sa_t *this, protocol_id_t protocol, u_int32_t spi); /** * @brief Destroy a CHILD SA with the specified protocol/SPI. * * Looks for a CHILD SA owned by this IKE_SA and destroys it. * * @param this calling object * @param protocol protocol of the SA * @param spi inbound SPI of the CHILD_SA * @return * - NOT_FOUND, if IKE_SA has no such CHILD_SA * - SUCCESS */ status_t (*destroy_child_sa) (ike_sa_t *this, protocol_id_t protocol, u_int32_t spi); /** * @brief Rekey the IKE_SA. * * Sets up a new IKE_SA, moves all CHILDs to it and deletes this IKE_SA. * * @param this calling object * @return - SUCCESS, if IKE_SA rekeying initiated */ status_t (*rekey) (ike_sa_t *this); /** * @brief Restablish the IKE_SA. * * Create a completely new IKE_SA with authentication, recreates all children * within the IKE_SA, but lets the old IKE_SA untouched. * * @param this calling object */ void (*reestablish) (ike_sa_t *this); /** * @brief Set the virtual IP to use for this IKE_SA and its children. * * The virtual IP is assigned per IKE_SA, not per CHILD_SA. It has the same * lifetime as the IKE_SA. * * @param this calling object */ void (*set_virtual_ip) (ike_sa_t *this, bool local, host_t *ip); /** * @brief Get the virtual IP configured. * * @param this calling object * @param local TRUE to get local virtual IP, FALSE for remote */ host_t* (*get_virtual_ip) (ike_sa_t *this, bool local); /** * @brief Add a DNS server to the system. * * An IRAS may send a DNS server. To use it, it is installed on the * system. The DNS entry has a lifetime until the IKE_SA gets closed. * * @param this calling object * @param dns DNS server to install on the system */ void (*add_dns_server) (ike_sa_t *this, host_t *dns); /** * @brief Inherit all attributes of other to this after rekeying. * * When rekeying is completed, all CHILD_SAs, the virtual IP and all * outstanding tasks are moved from other to this. * As this call may initiate inherited tasks, a status is returned. * * @param this calling object * @param other other task to inherit from * @return DESTROY_ME if initiation of inherited task failed */ status_t (*inherit) (ike_sa_t *this, ike_sa_t *other); /** * @brief Reset the IKE_SA, useable when initiating fails * * @param this calling object */ void (*reset) (ike_sa_t *this); /** * @brief Destroys a ike_sa_t object. * * @param this calling object */ void (*destroy) (ike_sa_t *this); }; /** * @brief Creates an ike_sa_t object with a specific ID. * * @param ike_sa_id ike_sa_id_t object to associate with new IKE_SA * @return ike_sa_t object * * @ingroup sa */ ike_sa_t *ike_sa_create(ike_sa_id_t *ike_sa_id); #endif /* IKE_SA_H_ */