/* $NetBSD: handler.h,v 1.26 2017/01/24 19:23:56 christos Exp $ */ /* Id: handler.h,v 1.19 2006/02/25 08:25:12 manubsd Exp */ /* * Copyright (C) 1995, 1996, 1997, and 1998 WIDE Project. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the project nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE PROJECT AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE PROJECT OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifndef _HANDLER_H #define _HANDLER_H #include #include #include #include "isakmp_var.h" #include "oakley.h" #include "schedule.h" #include "evt.h" /* Phase 1 handler */ /* * main mode: * initiator responder * 0 (---) (---) * 1 start start (1st msg received) * 2 (---) 1st valid msg received * 3 1st msg sent 1st msg sent * 4 1st valid msg received 2st valid msg received * 5 2nd msg sent 2nd msg sent * 6 2nd valid msg received 3rd valid msg received * 7 3rd msg sent 3rd msg sent * 8 3rd valid msg received (---) * 9 SA established SA established * * aggressive mode: * initiator responder * 0 (---) (---) * 1 start start (1st msg received) * 2 (---) 1st valid msg received * 3 1st msg sent 1st msg sent * 4 1st valid msg received 2st valid msg received * 5 (---) (---) * 6 (---) (---) * 7 (---) (---) * 8 (---) (---) * 9 SA established SA established * * base mode: * initiator responder * 0 (---) (---) * 1 start start (1st msg received) * 2 (---) 1st valid msg received * 3 1st msg sent 1st msg sent * 4 1st valid msg received 2st valid msg received * 5 2nd msg sent (---) * 6 (---) (---) * 7 (---) (---) * 8 (---) (---) * 9 SA established SA established */ #define PHASE1ST_SPAWN 0 #define PHASE1ST_START 1 #define PHASE1ST_MSG1RECEIVED 2 #define PHASE1ST_MSG1SENT 3 #define PHASE1ST_MSG2RECEIVED 4 #define PHASE1ST_MSG2SENT 5 #define PHASE1ST_MSG3RECEIVED 6 #define PHASE1ST_MSG3SENT 7 #define PHASE1ST_MSG4RECEIVED 8 #define PHASE1ST_ESTABLISHED 9 #define PHASE1ST_DYING 10 #define PHASE1ST_EXPIRED 11 #define PHASE1ST_MAX 12 /* About address semantics in each case. * initiator(addr=I) responder(addr=R) * src dst src dst * (local) (remote) (local) (remote) * phase 1 handler I R R I * phase 2 handler I R R I * getspi msg R I I R * acquire msg I R * ID payload I R I R */ #ifdef ENABLE_HYBRID struct isakmp_cfg_state; #endif struct ph1handle { isakmp_index index; int status; /* status of this SA */ int side; /* INITIATOR or RESPONDER */ struct sockaddr *remote; /* remote address to negosiate ph1 */ struct sockaddr *local; /* local address to negosiate ph1 */ /* XXX copy from rmconf due to anonymous configuration. * If anonymous will be forbidden, we do delete them. */ struct remoteconf *rmconf; /* pointer to remote configuration */ struct isakmpsa *approval; /* pointer to SA(s) approved. */ vchar_t *authstr; /* place holder of string for auth. */ /* for example pre-shared key */ u_int8_t version; /* ISAKMP version */ u_int8_t etype; /* Exchange type actually for use */ u_int8_t flags; /* Flags */ u_int32_t msgid; /* message id */ u_int32_t vendorid_mask; /* bitmask of received supported vendor ids*/ #ifdef ENABLE_NATT struct ph1natt_options *natt_options; /* Selected NAT-T IKE version */ u_int32_t natt_flags; /* NAT-T related flags */ #endif #ifdef ENABLE_FRAG int frag; /* IKE phase 1 fragmentation */ int frag_last_index; struct isakmp_frag_item *frag_chain; /* Received fragments */ #endif struct sched sce; /* schedule for expire */ struct sched scr; /* schedule for resend */ int retry_counter; /* for resend. */ vchar_t *sendbuf; /* buffer for re-sending */ vchar_t *dhpriv; /* DH; private value */ vchar_t *dhpub; /* DH; public value */ vchar_t *dhpub_p; /* DH; partner's public value */ vchar_t *dhgxy; /* DH; shared secret */ vchar_t *nonce; /* nonce value */ vchar_t *nonce_p; /* partner's nonce value */ vchar_t *skeyid; /* SKEYID */ vchar_t *skeyid_d; /* SKEYID_d */ vchar_t *skeyid_a; /* SKEYID_a, i.e. hash */ vchar_t *skeyid_e; /* SKEYID_e, i.e. encryption */ vchar_t *key; /* cipher key */ vchar_t *hash; /* HASH minus general header */ vchar_t *sig; /* SIG minus general header */ vchar_t *sig_p; /* peer's SIG minus general header */ vchar_t *cert; /* CERT minus general header */ vchar_t *cert_p; /* peer's CERT minus general header */ vchar_t *crl_p; /* peer's CRL minus general header */ vchar_t *cr_p; /* peer's CR not including general */ RSA *rsa; /* my RSA key */ RSA *rsa_p; /* peer's RSA key */ struct genlist *rsa_candidates; /* possible candidates for peer's RSA key */ vchar_t *id; /* ID minus gen header */ vchar_t *id_p; /* partner's ID minus general header */ /* i.e. struct ipsecdoi_id_b*. */ struct isakmp_ivm *ivm; /* IVs */ vchar_t *sa; /* whole SA payload to send/to be sent*/ /* to calculate HASH */ /* NOT INCLUDING general header. */ vchar_t *sa_ret; /* SA payload to reply/to be replyed */ /* NOT INCLUDING general header. */ /* NOTE: Should be release after use. */ #ifdef HAVE_GSSAPI void *gssapi_state; /* GSS-API specific state. */ /* Allocated when needed */ vchar_t *gi_i; /* optional initiator GSS id */ vchar_t *gi_r; /* optional responder GSS id */ #endif struct isakmp_pl_hash *pl_hash; /* pointer to hash payload */ time_t created; /* timestamp for establish */ int initial_contact_received; /* set if initial contact received */ #ifdef ENABLE_STATS struct timeval start; struct timeval end; #endif #ifdef ENABLE_DPD int dpd_support; /* Does remote supports DPD ? */ u_int32_t dpd_last_ack; u_int32_t dpd_seq; /* DPD seq number to receive */ u_int8_t dpd_fails; /* number of failures */ struct sched dpd_r_u; #endif u_int32_t msgid2; /* msgid counter for Phase 2 */ int ph2cnt; /* the number which is negotiated by this phase 1 */ LIST_HEAD(_ph2ofph1_, ph2handle) ph2tree; LIST_ENTRY(ph1handle) chain; #ifdef ENABLE_HYBRID struct isakmp_cfg_state *mode_cfg; /* ISAKMP mode config state */ #endif EVT_LISTENER_LIST(evt_listeners); }; /* For limiting enumeration of ph1 tree */ struct ph1selector { struct sockaddr *local; struct sockaddr *remote; }; /* Phase 2 handler */ /* allocated per a SA or SA bundles of a pair of peer's IP addresses. */ /* * initiator responder * 0 (---) (---) * 1 start start (1st msg received) * 2 acquire msg get 1st valid msg received * 3 getspi request sent getspi request sent * 4 getspi done getspi done * 5 1st msg sent 1st msg sent * 6 1st valid msg received 2nd valid msg received * 7 (commit bit) (commit bit) * 8 SAs added SAs added * 9 SAs established SAs established * 10 SAs expired SAs expired */ #define PHASE2ST_SPAWN 0 #define PHASE2ST_START 1 #define PHASE2ST_STATUS2 2 #define PHASE2ST_GETSPISENT 3 #define PHASE2ST_GETSPIDONE 4 #define PHASE2ST_MSG1SENT 5 #define PHASE2ST_STATUS6 6 #define PHASE2ST_COMMIT 7 #define PHASE2ST_ADDSA 8 #define PHASE2ST_ESTABLISHED 9 #define PHASE2ST_EXPIRED 10 #define PHASE2ST_MAX 11 struct ph2handle { /* source and destination addresses used for IKE exchange. Might * differ from source and destination of SA. On the initiator, * they are tweaked if a hint is available in the SPD (set by * MIGRATE for instance). Otherwise they are the source and * destination of SA for transport mode and the tunnel endpoints * for tunnel mode */ struct sockaddr *src; struct sockaddr *dst; /* source and destination addresses of the SA in the case addresses * used for IKE exchanges (src and dst) do differ. On the initiator, * they are set (if needed) in pk_recvacquire(). On the responder, * they are _derived_ from the local and remote parameters of the * SP, if available. */ struct sockaddr *sa_src; struct sockaddr *sa_dst; /* Store our Phase 2 ID and the peer ID (ID minus general header). * On the initiator, they are set during ACQUIRE processing. * On the responder, they are set from the content of ID payload * in quick_r1recv(). Then, if they are of type address or * tunnel, they are compared to sainfo selectors. */ vchar_t *id; /* ID minus gen header */ vchar_t *id_p; /* peer's ID minus general header */ #ifdef ENABLE_NATT struct sockaddr *natoa_src; /* peer's view of my address */ struct sockaddr *natoa_dst; /* peer's view of his address */ #endif u_int32_t spid; /* policy id by kernel */ int status; /* ipsec sa status */ u_int8_t side; /* INITIATOR or RESPONDER */ struct sched sce; /* schedule for expire */ struct sched scr; /* schedule for resend */ int retry_counter; /* for resend. */ vchar_t *sendbuf; /* buffer for re-sending */ vchar_t *msg1; /* buffer for re-sending */ /* used for responder's first message */ int retry_checkph1; /* counter to wait phase 1 finished. */ /* NOTE: actually it's timer. */ u_int32_t seq; /* sequence number used by PF_KEY */ /* * NOTE: In responder side, we can't identify each SAs * with same destination address for example, when * socket based SA is required. So we set a identifier * number to "seq", and sent kernel by pfkey. */ u_int8_t satype; /* satype in PF_KEY */ /* * saved satype in the original PF_KEY request from * the kernel in order to reply a error. */ u_int8_t flags; /* Flags for phase 2 */ u_int32_t msgid; /* msgid for phase 2 */ struct sainfo *sainfo; /* place holder of sainfo */ struct saprop *proposal; /* SA(s) proposal. */ struct saprop *approval; /* SA(s) approved. */ u_int32_t lifetime_secs; /* responder lifetime (seconds) */ u_int32_t lifetime_kb; /* responder lifetime (kbytes) */ caddr_t spidx_gen; /* policy from peer's proposal */ struct dhgroup *pfsgrp; /* DH; prime number */ vchar_t *dhpriv; /* DH; private value */ vchar_t *dhpub; /* DH; public value */ vchar_t *dhpub_p; /* DH; partner's public value */ vchar_t *dhgxy; /* DH; shared secret */ vchar_t *nonce; /* nonce value in phase 2 */ vchar_t *nonce_p; /* partner's nonce value in phase 2 */ vchar_t *sa; /* whole SA payload to send/to be sent*/ /* to calculate HASH */ /* NOT INCLUDING general header. */ vchar_t *sa_ret; /* SA payload to reply/to be replyed */ /* NOT INCLUDING general header. */ /* NOTE: Should be release after use. */ struct isakmp_ivm *ivm; /* IVs */ int generated_spidx; /* mark handlers whith generated policy */ #ifdef ENABLE_STATS struct timeval start; struct timeval end; #endif struct ph1handle *ph1; /* back pointer to isakmp status */ LIST_ENTRY(ph2handle) chain; LIST_ENTRY(ph2handle) ph1bind; /* chain to ph1handle */ EVT_LISTENER_LIST(evt_listeners); }; /* For limiting enumeration of ph2 tree */ struct ph2selector { u_int32_t spid; struct sockaddr *src; struct sockaddr *dst; }; /* * for handling initial contact. */ struct contacted { struct sockaddr *remote; /* remote address to negosiate ph1 */ LIST_ENTRY(contacted) chain; }; /* * for checking a packet retransmited. */ struct recvdpkt { struct sockaddr *remote; /* the remote address */ struct sockaddr *local; /* the local address */ vchar_t *hash; /* hash of the received packet */ vchar_t *sendbuf; /* buffer for the response */ int retry_counter; /* how many times to send */ struct timeval time_send; /* timestamp of previous send */ LIST_ENTRY(recvdpkt) chain; }; /* for parsing ISAKMP header. */ struct isakmp_parse_t { u_char type; /* payload type of mine */ int len; /* ntohs(ptr->len) */ struct isakmp_gen *ptr; }; /* * for IV management. * * - normal case * initiator responder * ------------------------- -------------------------- * initialize iv(A), ive(A). initialize iv(A), ive(A). * encode by ive(A). * save to iv(B). ---[packet(B)]--> save to ive(B). * decode by iv(A). * packet consistency. * sync iv(B) with ive(B). * check auth, integrity. * encode by ive(B). * save to ive(C). <--[packet(C)]--- save to iv(C). * decoded by iv(B). * : * * - In the case that a error is found while cipher processing, * initiator responder * ------------------------- -------------------------- * initialize iv(A), ive(A). initialize iv(A), ive(A). * encode by ive(A). * save to iv(B). ---[packet(B)]--> save to ive(B). * decode by iv(A). * packet consistency. * sync iv(B) with ive(B). * check auth, integrity. * error found. * create notify. * get ive2(X) from iv(B). * encode by ive2(X). * get iv2(X) from iv(B). <--[packet(Y)]--- save to iv2(Y). * save to ive2(Y). * decoded by iv2(X). * : * * The reason why the responder synchronizes iv with ive after checking the * packet consistency is that it is required to leave the IV for decoding * packet. Because there is a potential of error while checking the packet * consistency. Also the reason why that is before authentication and * integirty check is that the IV for informational exchange has to be made * by the IV which is after packet decoded and checking the packet consistency. * Otherwise IV mismatched happens between the intitiator and the responder. */ struct isakmp_ivm { vchar_t *iv; /* for decoding packet */ /* if phase 1, it's for computing phase2 iv */ vchar_t *ive; /* for encoding packet */ }; /* for dumping */ struct ph1dump { isakmp_index index; int status; int side; struct sockaddr_storage remote; struct sockaddr_storage local; u_int8_t version; u_int8_t etype; time_t created; int ph2cnt; }; struct sockaddr; struct ph1handle; struct ph2handle; struct policyindex; extern struct ph1handle *getph1byindex __P((isakmp_index *)); extern struct ph1handle *getph1byindex0 __P((isakmp_index *)); extern int enumph1 __P((struct ph1selector *ph1sel, int (* enum_func)(struct ph1handle *iph1, void *arg), void *enum_arg)); #define GETPH1_F_ESTABLISHED 0x0001 extern struct ph1handle *getph1 __P((struct ph1handle *ph1hint, struct sockaddr *local, struct sockaddr *remote, int flags)); #define getph1byaddr(local, remote, est) \ getph1(NULL, local, remote, est ? GETPH1_F_ESTABLISHED : 0) #define getph1bydstaddr(remote) \ getph1(NULL, NULL, remote, 0) #ifdef ENABLE_HYBRID struct ph1handle *getph1bylogin __P((char *)); int purgeph1bylogin __P((char *)); #endif extern void migrate_ph12 __P((struct ph1handle *old_iph1, struct ph1handle *new_iph1)); extern void migrate_dying_ph12 __P((struct ph1handle *iph1)); extern vchar_t *dumpph1 __P((void)); extern struct ph1handle *newph1 __P((void)); extern void delph1 __P((struct ph1handle *)); extern int insph1 __P((struct ph1handle *)); extern void remph1 __P((struct ph1handle *)); extern int resolveph1rmconf __P((struct ph1handle *)); extern void flushph1 __P((void)); extern void initph1tree __P((void)); extern int ph1_rekey_enabled __P((struct ph1handle *)); extern int enumph2 __P((struct ph2selector *ph2sel, int (* enum_func)(struct ph2handle *iph2, void *arg), void *enum_arg)); extern struct ph2handle *getph2byseq __P((u_int32_t)); extern struct ph2handle *getph2bysaddr __P((struct sockaddr *, struct sockaddr *)); extern struct ph2handle *getph2bymsgid __P((struct ph1handle *, u_int32_t)); extern struct ph2handle *getph2byid __P((struct sockaddr *, struct sockaddr *, u_int32_t)); extern struct ph2handle *getph2bysaidx __P((struct sockaddr *, struct sockaddr *, u_int, u_int32_t)); extern struct ph2handle *newph2 __P((void)); extern void initph2 __P((struct ph2handle *)); extern void delph2 __P((struct ph2handle *)); extern int insph2 __P((struct ph2handle *)); extern void remph2 __P((struct ph2handle *)); extern void flushph2 __P((void)); extern void deleteallph2 __P((struct sockaddr *, struct sockaddr *, u_int)); extern void initph2tree __P((void)); extern void bindph12 __P((struct ph1handle *, struct ph2handle *)); extern void unbindph12 __P((struct ph2handle *)); extern struct contacted *getcontacted __P((struct sockaddr *)); extern int inscontacted __P((struct sockaddr *)); extern void remcontacted __P((struct sockaddr *)); extern void initctdtree __P((void)); extern int check_recvdpkt __P((struct sockaddr *, struct sockaddr *, vchar_t *)); extern int add_recvdpkt __P((struct sockaddr *, struct sockaddr *, vchar_t *, vchar_t *)); extern void init_recvdpkt __P((void)); #ifdef ENABLE_HYBRID extern int exclude_cfg_addr __P((const struct sockaddr *)); #endif extern int revalidate_ph12(void); #endif /* _HANDLER_H */