Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/reiserfs/@/netinet/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/reiserfs/@/netinet/sctp_auth.c.orig |
/*- * Copyright (c) 2001-2008, by Cisco Systems, Inc. All rights reserved. * Copyright (c) 2008-2012, by Randall Stewart. All rights reserved. * Copyright (c) 2008-2012, by Michael Tuexen. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * a) Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * b) 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. * * c) Neither the name of Cisco Systems, Inc. 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 COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/netinet/sctp_auth.c 237896 2012-07-01 07:59:00Z tuexen $"); #include <netinet/sctp_os.h> #include <netinet/sctp.h> #include <netinet/sctp_header.h> #include <netinet/sctp_pcb.h> #include <netinet/sctp_var.h> #include <netinet/sctp_sysctl.h> #include <netinet/sctputil.h> #include <netinet/sctp_indata.h> #include <netinet/sctp_output.h> #include <netinet/sctp_auth.h> #ifdef SCTP_DEBUG #define SCTP_AUTH_DEBUG (SCTP_BASE_SYSCTL(sctp_debug_on) & SCTP_DEBUG_AUTH1) #define SCTP_AUTH_DEBUG2 (SCTP_BASE_SYSCTL(sctp_debug_on) & SCTP_DEBUG_AUTH2) #endif /* SCTP_DEBUG */ void sctp_clear_chunklist(sctp_auth_chklist_t * chklist) { bzero(chklist, sizeof(*chklist)); /* chklist->num_chunks = 0; */ } sctp_auth_chklist_t * sctp_alloc_chunklist(void) { sctp_auth_chklist_t *chklist; SCTP_MALLOC(chklist, sctp_auth_chklist_t *, sizeof(*chklist), SCTP_M_AUTH_CL); if (chklist == NULL) { SCTPDBG(SCTP_DEBUG_AUTH1, "sctp_alloc_chunklist: failed to get memory!\n"); } else { sctp_clear_chunklist(chklist); } return (chklist); } void sctp_free_chunklist(sctp_auth_chklist_t * list) { if (list != NULL) SCTP_FREE(list, SCTP_M_AUTH_CL); } sctp_auth_chklist_t * sctp_copy_chunklist(sctp_auth_chklist_t * list) { sctp_auth_chklist_t *new_list; if (list == NULL) return (NULL); /* get a new list */ new_list = sctp_alloc_chunklist(); if (new_list == NULL) return (NULL); /* copy it */ bcopy(list, new_list, sizeof(*new_list)); return (new_list); } /* * add a chunk to the required chunks list */ int sctp_auth_add_chunk(uint8_t chunk, sctp_auth_chklist_t * list) { if (list == NULL) return (-1); /* is chunk restricted? */ if ((chunk == SCTP_INITIATION) || (chunk == SCTP_INITIATION_ACK) || (chunk == SCTP_SHUTDOWN_COMPLETE) || (chunk == SCTP_AUTHENTICATION)) { return (-1); } if (list->chunks[chunk] == 0) { list->chunks[chunk] = 1; list->num_chunks++; SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: added chunk %u (0x%02x) to Auth list\n", chunk, chunk); } return (0); } /* * delete a chunk from the required chunks list */ int sctp_auth_delete_chunk(uint8_t chunk, sctp_auth_chklist_t * list) { if (list == NULL) return (-1); /* is chunk restricted? */ if ((chunk == SCTP_ASCONF) || (chunk == SCTP_ASCONF_ACK)) { return (-1); } if (list->chunks[chunk] == 1) { list->chunks[chunk] = 0; list->num_chunks--; SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: deleted chunk %u (0x%02x) from Auth list\n", chunk, chunk); } return (0); } size_t sctp_auth_get_chklist_size(const sctp_auth_chklist_t * list) { if (list == NULL) return (0); else return (list->num_chunks); } /* * set the default list of chunks requiring AUTH */ void sctp_auth_set_default_chunks(sctp_auth_chklist_t * list) { (void)sctp_auth_add_chunk(SCTP_ASCONF, list); (void)sctp_auth_add_chunk(SCTP_ASCONF_ACK, list); } /* * return the current number and list of required chunks caller must * guarantee ptr has space for up to 256 bytes */ int sctp_serialize_auth_chunks(const sctp_auth_chklist_t * list, uint8_t * ptr) { int i, count = 0; if (list == NULL) return (0); for (i = 0; i < 256; i++) { if (list->chunks[i] != 0) { *ptr++ = i; count++; } } return (count); } int sctp_pack_auth_chunks(const sctp_auth_chklist_t * list, uint8_t * ptr) { int i, size = 0; if (list == NULL) return (0); if (list->num_chunks <= 32) { /* just list them, one byte each */ for (i = 0; i < 256; i++) { if (list->chunks[i] != 0) { *ptr++ = i; size++; } } } else { int index, offset; /* pack into a 32 byte bitfield */ for (i = 0; i < 256; i++) { if (list->chunks[i] != 0) { index = i / 8; offset = i % 8; ptr[index] |= (1 << offset); } } size = 32; } return (size); } int sctp_unpack_auth_chunks(const uint8_t * ptr, uint8_t num_chunks, sctp_auth_chklist_t * list) { int i; int size; if (list == NULL) return (0); if (num_chunks <= 32) { /* just pull them, one byte each */ for (i = 0; i < num_chunks; i++) { (void)sctp_auth_add_chunk(*ptr++, list); } size = num_chunks; } else { int index, offset; /* unpack from a 32 byte bitfield */ for (index = 0; index < 32; index++) { for (offset = 0; offset < 8; offset++) { if (ptr[index] & (1 << offset)) { (void)sctp_auth_add_chunk((index * 8) + offset, list); } } } size = 32; } return (size); } /* * allocate structure space for a key of length keylen */ sctp_key_t * sctp_alloc_key(uint32_t keylen) { sctp_key_t *new_key; SCTP_MALLOC(new_key, sctp_key_t *, sizeof(*new_key) + keylen, SCTP_M_AUTH_KY); if (new_key == NULL) { /* out of memory */ return (NULL); } new_key->keylen = keylen; return (new_key); } void sctp_free_key(sctp_key_t * key) { if (key != NULL) SCTP_FREE(key, SCTP_M_AUTH_KY); } void sctp_print_key(sctp_key_t * key, const char *str) { uint32_t i; if (key == NULL) { SCTP_PRINTF("%s: [Null key]\n", str); return; } SCTP_PRINTF("%s: len %u, ", str, key->keylen); if (key->keylen) { for (i = 0; i < key->keylen; i++) SCTP_PRINTF("%02x", key->key[i]); SCTP_PRINTF("\n"); } else { SCTP_PRINTF("[Null key]\n"); } } void sctp_show_key(sctp_key_t * key, const char *str) { uint32_t i; if (key == NULL) { SCTP_PRINTF("%s: [Null key]\n", str); return; } SCTP_PRINTF("%s: len %u, ", str, key->keylen); if (key->keylen) { for (i = 0; i < key->keylen; i++) SCTP_PRINTF("%02x", key->key[i]); SCTP_PRINTF("\n"); } else { SCTP_PRINTF("[Null key]\n"); } } static uint32_t sctp_get_keylen(sctp_key_t * key) { if (key != NULL) return (key->keylen); else return (0); } /* * generate a new random key of length 'keylen' */ sctp_key_t * sctp_generate_random_key(uint32_t keylen) { sctp_key_t *new_key; /* validate keylen */ if (keylen > SCTP_AUTH_RANDOM_SIZE_MAX) keylen = SCTP_AUTH_RANDOM_SIZE_MAX; new_key = sctp_alloc_key(keylen); if (new_key == NULL) { /* out of memory */ return (NULL); } SCTP_READ_RANDOM(new_key->key, keylen); new_key->keylen = keylen; return (new_key); } sctp_key_t * sctp_set_key(uint8_t * key, uint32_t keylen) { sctp_key_t *new_key; new_key = sctp_alloc_key(keylen); if (new_key == NULL) { /* out of memory */ return (NULL); } bcopy(key, new_key->key, keylen); return (new_key); } /*- * given two keys of variable size, compute which key is "larger/smaller" * returns: 1 if key1 > key2 * -1 if key1 < key2 * 0 if key1 = key2 */ static int sctp_compare_key(sctp_key_t * key1, sctp_key_t * key2) { uint32_t maxlen; uint32_t i; uint32_t key1len, key2len; uint8_t *key_1, *key_2; uint8_t temp[SCTP_AUTH_RANDOM_SIZE_MAX]; /* sanity/length check */ key1len = sctp_get_keylen(key1); key2len = sctp_get_keylen(key2); if ((key1len == 0) && (key2len == 0)) return (0); else if (key1len == 0) return (-1); else if (key2len == 0) return (1); if (key1len != key2len) { if (key1len >= key2len) maxlen = key1len; else maxlen = key2len; bzero(temp, maxlen); if (key1len < maxlen) { /* prepend zeroes to key1 */ bcopy(key1->key, temp + (maxlen - key1len), key1len); key_1 = temp; key_2 = key2->key; } else { /* prepend zeroes to key2 */ bcopy(key2->key, temp + (maxlen - key2len), key2len); key_1 = key1->key; key_2 = temp; } } else { maxlen = key1len; key_1 = key1->key; key_2 = key2->key; } for (i = 0; i < maxlen; i++) { if (*key_1 > *key_2) return (1); else if (*key_1 < *key_2) return (-1); key_1++; key_2++; } /* keys are equal value, so check lengths */ if (key1len == key2len) return (0); else if (key1len < key2len) return (-1); else return (1); } /* * generate the concatenated keying material based on the two keys and the * shared key (if available). draft-ietf-tsvwg-auth specifies the specific * order for concatenation */ sctp_key_t * sctp_compute_hashkey(sctp_key_t * key1, sctp_key_t * key2, sctp_key_t * shared) { uint32_t keylen; sctp_key_t *new_key; uint8_t *key_ptr; keylen = sctp_get_keylen(key1) + sctp_get_keylen(key2) + sctp_get_keylen(shared); if (keylen > 0) { /* get space for the new key */ new_key = sctp_alloc_key(keylen); if (new_key == NULL) { /* out of memory */ return (NULL); } new_key->keylen = keylen; key_ptr = new_key->key; } else { /* all keys empty/null?! */ return (NULL); } /* concatenate the keys */ if (sctp_compare_key(key1, key2) <= 0) { /* key is shared + key1 + key2 */ if (sctp_get_keylen(shared)) { bcopy(shared->key, key_ptr, shared->keylen); key_ptr += shared->keylen; } if (sctp_get_keylen(key1)) { bcopy(key1->key, key_ptr, key1->keylen); key_ptr += key1->keylen; } if (sctp_get_keylen(key2)) { bcopy(key2->key, key_ptr, key2->keylen); } } else { /* key is shared + key2 + key1 */ if (sctp_get_keylen(shared)) { bcopy(shared->key, key_ptr, shared->keylen); key_ptr += shared->keylen; } if (sctp_get_keylen(key2)) { bcopy(key2->key, key_ptr, key2->keylen); key_ptr += key2->keylen; } if (sctp_get_keylen(key1)) { bcopy(key1->key, key_ptr, key1->keylen); } } return (new_key); } sctp_sharedkey_t * sctp_alloc_sharedkey(void) { sctp_sharedkey_t *new_key; SCTP_MALLOC(new_key, sctp_sharedkey_t *, sizeof(*new_key), SCTP_M_AUTH_KY); if (new_key == NULL) { /* out of memory */ return (NULL); } new_key->keyid = 0; new_key->key = NULL; new_key->refcount = 1; new_key->deactivated = 0; return (new_key); } void sctp_free_sharedkey(sctp_sharedkey_t * skey) { if (skey == NULL) return; if (SCTP_DECREMENT_AND_CHECK_REFCOUNT(&skey->refcount)) { if (skey->key != NULL) sctp_free_key(skey->key); SCTP_FREE(skey, SCTP_M_AUTH_KY); } } sctp_sharedkey_t * sctp_find_sharedkey(struct sctp_keyhead *shared_keys, uint16_t key_id) { sctp_sharedkey_t *skey; LIST_FOREACH(skey, shared_keys, next) { if (skey->keyid == key_id) return (skey); } return (NULL); } int sctp_insert_sharedkey(struct sctp_keyhead *shared_keys, sctp_sharedkey_t * new_skey) { sctp_sharedkey_t *skey; if ((shared_keys == NULL) || (new_skey == NULL)) return (EINVAL); /* insert into an empty list? */ if (LIST_EMPTY(shared_keys)) { LIST_INSERT_HEAD(shared_keys, new_skey, next); return (0); } /* insert into the existing list, ordered by key id */ LIST_FOREACH(skey, shared_keys, next) { if (new_skey->keyid < skey->keyid) { /* insert it before here */ LIST_INSERT_BEFORE(skey, new_skey, next); return (0); } else if (new_skey->keyid == skey->keyid) { /* replace the existing key */ /* verify this key *can* be replaced */ if ((skey->deactivated) && (skey->refcount > 1)) { SCTPDBG(SCTP_DEBUG_AUTH1, "can't replace shared key id %u\n", new_skey->keyid); return (EBUSY); } SCTPDBG(SCTP_DEBUG_AUTH1, "replacing shared key id %u\n", new_skey->keyid); LIST_INSERT_BEFORE(skey, new_skey, next); LIST_REMOVE(skey, next); sctp_free_sharedkey(skey); return (0); } if (LIST_NEXT(skey, next) == NULL) { /* belongs at the end of the list */ LIST_INSERT_AFTER(skey, new_skey, next); return (0); } } /* shouldn't reach here */ return (0); } void sctp_auth_key_acquire(struct sctp_tcb *stcb, uint16_t key_id) { sctp_sharedkey_t *skey; /* find the shared key */ skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, key_id); /* bump the ref count */ if (skey) { atomic_add_int(&skey->refcount, 1); SCTPDBG(SCTP_DEBUG_AUTH2, "%s: stcb %p key %u refcount acquire to %d\n", __FUNCTION__, stcb, key_id, skey->refcount); } } void sctp_auth_key_release(struct sctp_tcb *stcb, uint16_t key_id, int so_locked #if !defined(__APPLE__) && !defined(SCTP_SO_LOCK_TESTING) SCTP_UNUSED #endif ) { sctp_sharedkey_t *skey; /* find the shared key */ skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, key_id); /* decrement the ref count */ if (skey) { sctp_free_sharedkey(skey); SCTPDBG(SCTP_DEBUG_AUTH2, "%s: stcb %p key %u refcount release to %d\n", __FUNCTION__, stcb, key_id, skey->refcount); /* see if a notification should be generated */ if ((skey->refcount <= 1) && (skey->deactivated)) { /* notify ULP that key is no longer used */ sctp_ulp_notify(SCTP_NOTIFY_AUTH_FREE_KEY, stcb, key_id, 0, so_locked); SCTPDBG(SCTP_DEBUG_AUTH2, "%s: stcb %p key %u no longer used, %d\n", __FUNCTION__, stcb, key_id, skey->refcount); } } } static sctp_sharedkey_t * sctp_copy_sharedkey(const sctp_sharedkey_t * skey) { sctp_sharedkey_t *new_skey; if (skey == NULL) return (NULL); new_skey = sctp_alloc_sharedkey(); if (new_skey == NULL) return (NULL); if (skey->key != NULL) new_skey->key = sctp_set_key(skey->key->key, skey->key->keylen); else new_skey->key = NULL; new_skey->keyid = skey->keyid; return (new_skey); } int sctp_copy_skeylist(const struct sctp_keyhead *src, struct sctp_keyhead *dest) { sctp_sharedkey_t *skey, *new_skey; int count = 0; if ((src == NULL) || (dest == NULL)) return (0); LIST_FOREACH(skey, src, next) { new_skey = sctp_copy_sharedkey(skey); if (new_skey != NULL) { (void)sctp_insert_sharedkey(dest, new_skey); count++; } } return (count); } sctp_hmaclist_t * sctp_alloc_hmaclist(uint8_t num_hmacs) { sctp_hmaclist_t *new_list; int alloc_size; alloc_size = sizeof(*new_list) + num_hmacs * sizeof(new_list->hmac[0]); SCTP_MALLOC(new_list, sctp_hmaclist_t *, alloc_size, SCTP_M_AUTH_HL); if (new_list == NULL) { /* out of memory */ return (NULL); } new_list->max_algo = num_hmacs; new_list->num_algo = 0; return (new_list); } void sctp_free_hmaclist(sctp_hmaclist_t * list) { if (list != NULL) { SCTP_FREE(list, SCTP_M_AUTH_HL); list = NULL; } } int sctp_auth_add_hmacid(sctp_hmaclist_t * list, uint16_t hmac_id) { int i; if (list == NULL) return (-1); if (list->num_algo == list->max_algo) { SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: HMAC id list full, ignoring add %u\n", hmac_id); return (-1); } if ((hmac_id != SCTP_AUTH_HMAC_ID_SHA1) && #ifdef HAVE_SHA224 (hmac_id != SCTP_AUTH_HMAC_ID_SHA224) && #endif #ifdef HAVE_SHA2 (hmac_id != SCTP_AUTH_HMAC_ID_SHA256) && (hmac_id != SCTP_AUTH_HMAC_ID_SHA384) && (hmac_id != SCTP_AUTH_HMAC_ID_SHA512) && #endif 1) { return (-1); } /* Now is it already in the list */ for (i = 0; i < list->num_algo; i++) { if (list->hmac[i] == hmac_id) { /* already in list */ return (-1); } } SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: add HMAC id %u to list\n", hmac_id); list->hmac[list->num_algo++] = hmac_id; return (0); } sctp_hmaclist_t * sctp_copy_hmaclist(sctp_hmaclist_t * list) { sctp_hmaclist_t *new_list; int i; if (list == NULL) return (NULL); /* get a new list */ new_list = sctp_alloc_hmaclist(list->max_algo); if (new_list == NULL) return (NULL); /* copy it */ new_list->max_algo = list->max_algo; new_list->num_algo = list->num_algo; for (i = 0; i < list->num_algo; i++) new_list->hmac[i] = list->hmac[i]; return (new_list); } sctp_hmaclist_t * sctp_default_supported_hmaclist(void) { sctp_hmaclist_t *new_list; new_list = sctp_alloc_hmaclist(2); if (new_list == NULL) return (NULL); (void)sctp_auth_add_hmacid(new_list, SCTP_AUTH_HMAC_ID_SHA1); (void)sctp_auth_add_hmacid(new_list, SCTP_AUTH_HMAC_ID_SHA256); return (new_list); } /*- * HMAC algos are listed in priority/preference order * find the best HMAC id to use for the peer based on local support */ uint16_t sctp_negotiate_hmacid(sctp_hmaclist_t * peer, sctp_hmaclist_t * local) { int i, j; if ((local == NULL) || (peer == NULL)) return (SCTP_AUTH_HMAC_ID_RSVD); for (i = 0; i < peer->num_algo; i++) { for (j = 0; j < local->num_algo; j++) { if (peer->hmac[i] == local->hmac[j]) { /* found the "best" one */ SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: negotiated peer HMAC id %u\n", peer->hmac[i]); return (peer->hmac[i]); } } } /* didn't find one! */ return (SCTP_AUTH_HMAC_ID_RSVD); } /*- * serialize the HMAC algo list and return space used * caller must guarantee ptr has appropriate space */ int sctp_serialize_hmaclist(sctp_hmaclist_t * list, uint8_t * ptr) { int i; uint16_t hmac_id; if (list == NULL) return (0); for (i = 0; i < list->num_algo; i++) { hmac_id = htons(list->hmac[i]); bcopy(&hmac_id, ptr, sizeof(hmac_id)); ptr += sizeof(hmac_id); } return (list->num_algo * sizeof(hmac_id)); } int sctp_verify_hmac_param(struct sctp_auth_hmac_algo *hmacs, uint32_t num_hmacs) { uint32_t i; uint16_t hmac_id; uint32_t sha1_supported = 0; for (i = 0; i < num_hmacs; i++) { hmac_id = ntohs(hmacs->hmac_ids[i]); if (hmac_id == SCTP_AUTH_HMAC_ID_SHA1) sha1_supported = 1; } /* all HMAC id's are supported */ if (sha1_supported == 0) return (-1); else return (0); } sctp_authinfo_t * sctp_alloc_authinfo(void) { sctp_authinfo_t *new_authinfo; SCTP_MALLOC(new_authinfo, sctp_authinfo_t *, sizeof(*new_authinfo), SCTP_M_AUTH_IF); if (new_authinfo == NULL) { /* out of memory */ return (NULL); } bzero(new_authinfo, sizeof(*new_authinfo)); return (new_authinfo); } void sctp_free_authinfo(sctp_authinfo_t * authinfo) { if (authinfo == NULL) return; if (authinfo->random != NULL) sctp_free_key(authinfo->random); if (authinfo->peer_random != NULL) sctp_free_key(authinfo->peer_random); if (authinfo->assoc_key != NULL) sctp_free_key(authinfo->assoc_key); if (authinfo->recv_key != NULL) sctp_free_key(authinfo->recv_key); /* We are NOT dynamically allocating authinfo's right now... */ /* SCTP_FREE(authinfo, SCTP_M_AUTH_??); */ } uint32_t sctp_get_auth_chunk_len(uint16_t hmac_algo) { int size; size = sizeof(struct sctp_auth_chunk) + sctp_get_hmac_digest_len(hmac_algo); return (SCTP_SIZE32(size)); } uint32_t sctp_get_hmac_digest_len(uint16_t hmac_algo) { switch (hmac_algo) { case SCTP_AUTH_HMAC_ID_SHA1: return (SCTP_AUTH_DIGEST_LEN_SHA1); #ifdef HAVE_SHA224 case SCTP_AUTH_HMAC_ID_SHA224: return (SCTP_AUTH_DIGEST_LEN_SHA224); #endif #ifdef HAVE_SHA2 case SCTP_AUTH_HMAC_ID_SHA256: return (SCTP_AUTH_DIGEST_LEN_SHA256); case SCTP_AUTH_HMAC_ID_SHA384: return (SCTP_AUTH_DIGEST_LEN_SHA384); case SCTP_AUTH_HMAC_ID_SHA512: return (SCTP_AUTH_DIGEST_LEN_SHA512); #endif default: /* unknown HMAC algorithm: can't do anything */ return (0); } /* end switch */ } static inline int sctp_get_hmac_block_len(uint16_t hmac_algo) { switch (hmac_algo) { case SCTP_AUTH_HMAC_ID_SHA1: #ifdef HAVE_SHA224 case SCTP_AUTH_HMAC_ID_SHA224: #endif return (64); #ifdef HAVE_SHA2 case SCTP_AUTH_HMAC_ID_SHA256: return (64); case SCTP_AUTH_HMAC_ID_SHA384: case SCTP_AUTH_HMAC_ID_SHA512: return (128); #endif case SCTP_AUTH_HMAC_ID_RSVD: default: /* unknown HMAC algorithm: can't do anything */ return (0); } /* end switch */ } static void sctp_hmac_init(uint16_t hmac_algo, sctp_hash_context_t * ctx) { switch (hmac_algo) { case SCTP_AUTH_HMAC_ID_SHA1: SHA1_Init(&ctx->sha1); break; #ifdef HAVE_SHA224 case SCTP_AUTH_HMAC_ID_SHA224: break; #endif #ifdef HAVE_SHA2 case SCTP_AUTH_HMAC_ID_SHA256: SHA256_Init(&ctx->sha256); break; case SCTP_AUTH_HMAC_ID_SHA384: SHA384_Init(&ctx->sha384); break; case SCTP_AUTH_HMAC_ID_SHA512: SHA512_Init(&ctx->sha512); break; #endif case SCTP_AUTH_HMAC_ID_RSVD: default: /* unknown HMAC algorithm: can't do anything */ return; } /* end switch */ } static void sctp_hmac_update(uint16_t hmac_algo, sctp_hash_context_t * ctx, uint8_t * text, uint32_t textlen) { switch (hmac_algo) { case SCTP_AUTH_HMAC_ID_SHA1: SHA1_Update(&ctx->sha1, text, textlen); break; #ifdef HAVE_SHA224 case SCTP_AUTH_HMAC_ID_SHA224: break; #endif #ifdef HAVE_SHA2 case SCTP_AUTH_HMAC_ID_SHA256: SHA256_Update(&ctx->sha256, text, textlen); break; case SCTP_AUTH_HMAC_ID_SHA384: SHA384_Update(&ctx->sha384, text, textlen); break; case SCTP_AUTH_HMAC_ID_SHA512: SHA512_Update(&ctx->sha512, text, textlen); break; #endif case SCTP_AUTH_HMAC_ID_RSVD: default: /* unknown HMAC algorithm: can't do anything */ return; } /* end switch */ } static void sctp_hmac_final(uint16_t hmac_algo, sctp_hash_context_t * ctx, uint8_t * digest) { switch (hmac_algo) { case SCTP_AUTH_HMAC_ID_SHA1: SHA1_Final(digest, &ctx->sha1); break; #ifdef HAVE_SHA224 case SCTP_AUTH_HMAC_ID_SHA224: break; #endif #ifdef HAVE_SHA2 case SCTP_AUTH_HMAC_ID_SHA256: SHA256_Final(digest, &ctx->sha256); break; case SCTP_AUTH_HMAC_ID_SHA384: /* SHA384 is truncated SHA512 */ SHA384_Final(digest, &ctx->sha384); break; case SCTP_AUTH_HMAC_ID_SHA512: SHA512_Final(digest, &ctx->sha512); break; #endif case SCTP_AUTH_HMAC_ID_RSVD: default: /* unknown HMAC algorithm: can't do anything */ return; } /* end switch */ } /*- * Keyed-Hashing for Message Authentication: FIPS 198 (RFC 2104) * * Compute the HMAC digest using the desired hash key, text, and HMAC * algorithm. Resulting digest is placed in 'digest' and digest length * is returned, if the HMAC was performed. * * WARNING: it is up to the caller to supply sufficient space to hold the * resultant digest. */ uint32_t sctp_hmac(uint16_t hmac_algo, uint8_t * key, uint32_t keylen, uint8_t * text, uint32_t textlen, uint8_t * digest) { uint32_t digestlen; uint32_t blocklen; sctp_hash_context_t ctx; uint8_t ipad[128], opad[128]; /* keyed hash inner/outer pads */ uint8_t temp[SCTP_AUTH_DIGEST_LEN_MAX]; uint32_t i; /* sanity check the material and length */ if ((key == NULL) || (keylen == 0) || (text == NULL) || (textlen == 0) || (digest == NULL)) { /* can't do HMAC with empty key or text or digest store */ return (0); } /* validate the hmac algo and get the digest length */ digestlen = sctp_get_hmac_digest_len(hmac_algo); if (digestlen == 0) return (0); /* hash the key if it is longer than the hash block size */ blocklen = sctp_get_hmac_block_len(hmac_algo); if (keylen > blocklen) { sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, key, keylen); sctp_hmac_final(hmac_algo, &ctx, temp); /* set the hashed key as the key */ keylen = digestlen; key = temp; } /* initialize the inner/outer pads with the key and "append" zeroes */ bzero(ipad, blocklen); bzero(opad, blocklen); bcopy(key, ipad, keylen); bcopy(key, opad, keylen); /* XOR the key with ipad and opad values */ for (i = 0; i < blocklen; i++) { ipad[i] ^= 0x36; opad[i] ^= 0x5c; } /* perform inner hash */ sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, ipad, blocklen); sctp_hmac_update(hmac_algo, &ctx, text, textlen); sctp_hmac_final(hmac_algo, &ctx, temp); /* perform outer hash */ sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, opad, blocklen); sctp_hmac_update(hmac_algo, &ctx, temp, digestlen); sctp_hmac_final(hmac_algo, &ctx, digest); return (digestlen); } /* mbuf version */ uint32_t sctp_hmac_m(uint16_t hmac_algo, uint8_t * key, uint32_t keylen, struct mbuf *m, uint32_t m_offset, uint8_t * digest, uint32_t trailer) { uint32_t digestlen; uint32_t blocklen; sctp_hash_context_t ctx; uint8_t ipad[128], opad[128]; /* keyed hash inner/outer pads */ uint8_t temp[SCTP_AUTH_DIGEST_LEN_MAX]; uint32_t i; struct mbuf *m_tmp; /* sanity check the material and length */ if ((key == NULL) || (keylen == 0) || (m == NULL) || (digest == NULL)) { /* can't do HMAC with empty key or text or digest store */ return (0); } /* validate the hmac algo and get the digest length */ digestlen = sctp_get_hmac_digest_len(hmac_algo); if (digestlen == 0) return (0); /* hash the key if it is longer than the hash block size */ blocklen = sctp_get_hmac_block_len(hmac_algo); if (keylen > blocklen) { sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, key, keylen); sctp_hmac_final(hmac_algo, &ctx, temp); /* set the hashed key as the key */ keylen = digestlen; key = temp; } /* initialize the inner/outer pads with the key and "append" zeroes */ bzero(ipad, blocklen); bzero(opad, blocklen); bcopy(key, ipad, keylen); bcopy(key, opad, keylen); /* XOR the key with ipad and opad values */ for (i = 0; i < blocklen; i++) { ipad[i] ^= 0x36; opad[i] ^= 0x5c; } /* perform inner hash */ sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, ipad, blocklen); /* find the correct starting mbuf and offset (get start of text) */ m_tmp = m; while ((m_tmp != NULL) && (m_offset >= (uint32_t) SCTP_BUF_LEN(m_tmp))) { m_offset -= SCTP_BUF_LEN(m_tmp); m_tmp = SCTP_BUF_NEXT(m_tmp); } /* now use the rest of the mbuf chain for the text */ while (m_tmp != NULL) { if ((SCTP_BUF_NEXT(m_tmp) == NULL) && trailer) { sctp_hmac_update(hmac_algo, &ctx, mtod(m_tmp, uint8_t *) + m_offset, SCTP_BUF_LEN(m_tmp) - (trailer + m_offset)); } else { sctp_hmac_update(hmac_algo, &ctx, mtod(m_tmp, uint8_t *) + m_offset, SCTP_BUF_LEN(m_tmp) - m_offset); } /* clear the offset since it's only for the first mbuf */ m_offset = 0; m_tmp = SCTP_BUF_NEXT(m_tmp); } sctp_hmac_final(hmac_algo, &ctx, temp); /* perform outer hash */ sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, opad, blocklen); sctp_hmac_update(hmac_algo, &ctx, temp, digestlen); sctp_hmac_final(hmac_algo, &ctx, digest); return (digestlen); } /*- * verify the HMAC digest using the desired hash key, text, and HMAC * algorithm. * Returns -1 on error, 0 on success. */ int sctp_verify_hmac(uint16_t hmac_algo, uint8_t * key, uint32_t keylen, uint8_t * text, uint32_t textlen, uint8_t * digest, uint32_t digestlen) { uint32_t len; uint8_t temp[SCTP_AUTH_DIGEST_LEN_MAX]; /* sanity check the material and length */ if ((key == NULL) || (keylen == 0) || (text == NULL) || (textlen == 0) || (digest == NULL)) { /* can't do HMAC with empty key or text or digest */ return (-1); } len = sctp_get_hmac_digest_len(hmac_algo); if ((len == 0) || (digestlen != len)) return (-1); /* compute the expected hash */ if (sctp_hmac(hmac_algo, key, keylen, text, textlen, temp) != len) return (-1); if (memcmp(digest, temp, digestlen) != 0) return (-1); else return (0); } /* * computes the requested HMAC using a key struct (which may be modified if * the keylen exceeds the HMAC block len). */ uint32_t sctp_compute_hmac(uint16_t hmac_algo, sctp_key_t * key, uint8_t * text, uint32_t textlen, uint8_t * digest) { uint32_t digestlen; uint32_t blocklen; sctp_hash_context_t ctx; uint8_t temp[SCTP_AUTH_DIGEST_LEN_MAX]; /* sanity check */ if ((key == NULL) || (text == NULL) || (textlen == 0) || (digest == NULL)) { /* can't do HMAC with empty key or text or digest store */ return (0); } /* validate the hmac algo and get the digest length */ digestlen = sctp_get_hmac_digest_len(hmac_algo); if (digestlen == 0) return (0); /* hash the key if it is longer than the hash block size */ blocklen = sctp_get_hmac_block_len(hmac_algo); if (key->keylen > blocklen) { sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, key->key, key->keylen); sctp_hmac_final(hmac_algo, &ctx, temp); /* save the hashed key as the new key */ key->keylen = digestlen; bcopy(temp, key->key, key->keylen); } return (sctp_hmac(hmac_algo, key->key, key->keylen, text, textlen, digest)); } /* mbuf version */ uint32_t sctp_compute_hmac_m(uint16_t hmac_algo, sctp_key_t * key, struct mbuf *m, uint32_t m_offset, uint8_t * digest) { uint32_t digestlen; uint32_t blocklen; sctp_hash_context_t ctx; uint8_t temp[SCTP_AUTH_DIGEST_LEN_MAX]; /* sanity check */ if ((key == NULL) || (m == NULL) || (digest == NULL)) { /* can't do HMAC with empty key or text or digest store */ return (0); } /* validate the hmac algo and get the digest length */ digestlen = sctp_get_hmac_digest_len(hmac_algo); if (digestlen == 0) return (0); /* hash the key if it is longer than the hash block size */ blocklen = sctp_get_hmac_block_len(hmac_algo); if (key->keylen > blocklen) { sctp_hmac_init(hmac_algo, &ctx); sctp_hmac_update(hmac_algo, &ctx, key->key, key->keylen); sctp_hmac_final(hmac_algo, &ctx, temp); /* save the hashed key as the new key */ key->keylen = digestlen; bcopy(temp, key->key, key->keylen); } return (sctp_hmac_m(hmac_algo, key->key, key->keylen, m, m_offset, digest, 0)); } int sctp_auth_is_supported_hmac(sctp_hmaclist_t * list, uint16_t id) { int i; if ((list == NULL) || (id == SCTP_AUTH_HMAC_ID_RSVD)) return (0); for (i = 0; i < list->num_algo; i++) if (list->hmac[i] == id) return (1); /* not in the list */ return (0); } /*- * clear any cached key(s) if they match the given key id on an association. * the cached key(s) will be recomputed and re-cached at next use. * ASSUMES TCB_LOCK is already held */ void sctp_clear_cachedkeys(struct sctp_tcb *stcb, uint16_t keyid) { if (stcb == NULL) return; if (keyid == stcb->asoc.authinfo.assoc_keyid) { sctp_free_key(stcb->asoc.authinfo.assoc_key); stcb->asoc.authinfo.assoc_key = NULL; } if (keyid == stcb->asoc.authinfo.recv_keyid) { sctp_free_key(stcb->asoc.authinfo.recv_key); stcb->asoc.authinfo.recv_key = NULL; } } /*- * clear any cached key(s) if they match the given key id for all assocs on * an endpoint. * ASSUMES INP_WLOCK is already held */ void sctp_clear_cachedkeys_ep(struct sctp_inpcb *inp, uint16_t keyid) { struct sctp_tcb *stcb; if (inp == NULL) return; /* clear the cached keys on all assocs on this instance */ LIST_FOREACH(stcb, &inp->sctp_asoc_list, sctp_tcblist) { SCTP_TCB_LOCK(stcb); sctp_clear_cachedkeys(stcb, keyid); SCTP_TCB_UNLOCK(stcb); } } /*- * delete a shared key from an association * ASSUMES TCB_LOCK is already held */ int sctp_delete_sharedkey(struct sctp_tcb *stcb, uint16_t keyid) { sctp_sharedkey_t *skey; if (stcb == NULL) return (-1); /* is the keyid the assoc active sending key */ if (keyid == stcb->asoc.authinfo.active_keyid) return (-1); /* does the key exist? */ skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, keyid); if (skey == NULL) return (-1); /* are there other refcount holders on the key? */ if (skey->refcount > 1) return (-1); /* remove it */ LIST_REMOVE(skey, next); sctp_free_sharedkey(skey); /* frees skey->key as well */ /* clear any cached keys */ sctp_clear_cachedkeys(stcb, keyid); return (0); } /*- * deletes a shared key from the endpoint * ASSUMES INP_WLOCK is already held */ int sctp_delete_sharedkey_ep(struct sctp_inpcb *inp, uint16_t keyid) { sctp_sharedkey_t *skey; if (inp == NULL) return (-1); /* is the keyid the active sending key on the endpoint */ if (keyid == inp->sctp_ep.default_keyid) return (-1); /* does the key exist? */ skey = sctp_find_sharedkey(&inp->sctp_ep.shared_keys, keyid); if (skey == NULL) return (-1); /* endpoint keys are not refcounted */ /* remove it */ LIST_REMOVE(skey, next); sctp_free_sharedkey(skey); /* frees skey->key as well */ /* clear any cached keys */ sctp_clear_cachedkeys_ep(inp, keyid); return (0); } /*- * set the active key on an association * ASSUMES TCB_LOCK is already held */ int sctp_auth_setactivekey(struct sctp_tcb *stcb, uint16_t keyid) { sctp_sharedkey_t *skey = NULL; /* find the key on the assoc */ skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, keyid); if (skey == NULL) { /* that key doesn't exist */ return (-1); } if ((skey->deactivated) && (skey->refcount > 1)) { /* can't reactivate a deactivated key with other refcounts */ return (-1); } /* set the (new) active key */ stcb->asoc.authinfo.active_keyid = keyid; /* reset the deactivated flag */ skey->deactivated = 0; return (0); } /*- * set the active key on an endpoint * ASSUMES INP_WLOCK is already held */ int sctp_auth_setactivekey_ep(struct sctp_inpcb *inp, uint16_t keyid) { sctp_sharedkey_t *skey; /* find the key */ skey = sctp_find_sharedkey(&inp->sctp_ep.shared_keys, keyid); if (skey == NULL) { /* that key doesn't exist */ return (-1); } inp->sctp_ep.default_keyid = keyid; return (0); } /*- * deactivates a shared key from the association * ASSUMES INP_WLOCK is already held */ int sctp_deact_sharedkey(struct sctp_tcb *stcb, uint16_t keyid) { sctp_sharedkey_t *skey; if (stcb == NULL) return (-1); /* is the keyid the assoc active sending key */ if (keyid == stcb->asoc.authinfo.active_keyid) return (-1); /* does the key exist? */ skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, keyid); if (skey == NULL) return (-1); /* are there other refcount holders on the key? */ if (skey->refcount == 1) { /* no other users, send a notification for this key */ sctp_ulp_notify(SCTP_NOTIFY_AUTH_FREE_KEY, stcb, keyid, 0, SCTP_SO_LOCKED); } /* mark the key as deactivated */ skey->deactivated = 1; return (0); } /*- * deactivates a shared key from the endpoint * ASSUMES INP_WLOCK is already held */ int sctp_deact_sharedkey_ep(struct sctp_inpcb *inp, uint16_t keyid) { sctp_sharedkey_t *skey; if (inp == NULL) return (-1); /* is the keyid the active sending key on the endpoint */ if (keyid == inp->sctp_ep.default_keyid) return (-1); /* does the key exist? */ skey = sctp_find_sharedkey(&inp->sctp_ep.shared_keys, keyid); if (skey == NULL) return (-1); /* endpoint keys are not refcounted */ /* remove it */ LIST_REMOVE(skey, next); sctp_free_sharedkey(skey); /* frees skey->key as well */ return (0); } /* * get local authentication parameters from cookie (from INIT-ACK) */ void sctp_auth_get_cookie_params(struct sctp_tcb *stcb, struct mbuf *m, uint32_t offset, uint32_t length) { struct sctp_paramhdr *phdr, tmp_param; uint16_t plen, ptype; uint8_t random_store[SCTP_PARAM_BUFFER_SIZE]; struct sctp_auth_random *p_random = NULL; uint16_t random_len = 0; uint8_t hmacs_store[SCTP_PARAM_BUFFER_SIZE]; struct sctp_auth_hmac_algo *hmacs = NULL; uint16_t hmacs_len = 0; uint8_t chunks_store[SCTP_PARAM_BUFFER_SIZE]; struct sctp_auth_chunk_list *chunks = NULL; uint16_t num_chunks = 0; sctp_key_t *new_key; uint32_t keylen; /* convert to upper bound */ length += offset; phdr = (struct sctp_paramhdr *)sctp_m_getptr(m, offset, sizeof(struct sctp_paramhdr), (uint8_t *) & tmp_param); while (phdr != NULL) { ptype = ntohs(phdr->param_type); plen = ntohs(phdr->param_length); if ((plen == 0) || (offset + plen > length)) break; if (ptype == SCTP_RANDOM) { if (plen > sizeof(random_store)) break; phdr = sctp_get_next_param(m, offset, (struct sctp_paramhdr *)random_store, min(plen, sizeof(random_store))); if (phdr == NULL) return; /* save the random and length for the key */ p_random = (struct sctp_auth_random *)phdr; random_len = plen - sizeof(*p_random); } else if (ptype == SCTP_HMAC_LIST) { int num_hmacs; int i; if (plen > sizeof(hmacs_store)) break; phdr = sctp_get_next_param(m, offset, (struct sctp_paramhdr *)hmacs_store, min(plen, sizeof(hmacs_store))); if (phdr == NULL) return; /* save the hmacs list and num for the key */ hmacs = (struct sctp_auth_hmac_algo *)phdr; hmacs_len = plen - sizeof(*hmacs); num_hmacs = hmacs_len / sizeof(hmacs->hmac_ids[0]); if (stcb->asoc.local_hmacs != NULL) sctp_free_hmaclist(stcb->asoc.local_hmacs); stcb->asoc.local_hmacs = sctp_alloc_hmaclist(num_hmacs); if (stcb->asoc.local_hmacs != NULL) { for (i = 0; i < num_hmacs; i++) { (void)sctp_auth_add_hmacid(stcb->asoc.local_hmacs, ntohs(hmacs->hmac_ids[i])); } } } else if (ptype == SCTP_CHUNK_LIST) { int i; if (plen > sizeof(chunks_store)) break; phdr = sctp_get_next_param(m, offset, (struct sctp_paramhdr *)chunks_store, min(plen, sizeof(chunks_store))); if (phdr == NULL) return; chunks = (struct sctp_auth_chunk_list *)phdr; num_chunks = plen - sizeof(*chunks); /* save chunks list and num for the key */ if (stcb->asoc.local_auth_chunks != NULL) sctp_clear_chunklist(stcb->asoc.local_auth_chunks); else stcb->asoc.local_auth_chunks = sctp_alloc_chunklist(); for (i = 0; i < num_chunks; i++) { (void)sctp_auth_add_chunk(chunks->chunk_types[i], stcb->asoc.local_auth_chunks); } } /* get next parameter */ offset += SCTP_SIZE32(plen); if (offset + sizeof(struct sctp_paramhdr) > length) break; phdr = (struct sctp_paramhdr *)sctp_m_getptr(m, offset, sizeof(struct sctp_paramhdr), (uint8_t *) & tmp_param); } /* concatenate the full random key */ keylen = sizeof(*p_random) + random_len + sizeof(*hmacs) + hmacs_len; if (chunks != NULL) { keylen += sizeof(*chunks) + num_chunks; } new_key = sctp_alloc_key(keylen); if (new_key != NULL) { /* copy in the RANDOM */ if (p_random != NULL) { keylen = sizeof(*p_random) + random_len; bcopy(p_random, new_key->key, keylen); } /* append in the AUTH chunks */ if (chunks != NULL) { bcopy(chunks, new_key->key + keylen, sizeof(*chunks) + num_chunks); keylen += sizeof(*chunks) + num_chunks; } /* append in the HMACs */ if (hmacs != NULL) { bcopy(hmacs, new_key->key + keylen, sizeof(*hmacs) + hmacs_len); } } if (stcb->asoc.authinfo.random != NULL) sctp_free_key(stcb->asoc.authinfo.random); stcb->asoc.authinfo.random = new_key; stcb->asoc.authinfo.random_len = random_len; sctp_clear_cachedkeys(stcb, stcb->asoc.authinfo.assoc_keyid); sctp_clear_cachedkeys(stcb, stcb->asoc.authinfo.recv_keyid); /* negotiate what HMAC to use for the peer */ stcb->asoc.peer_hmac_id = sctp_negotiate_hmacid(stcb->asoc.peer_hmacs, stcb->asoc.local_hmacs); /* copy defaults from the endpoint */ /* FIX ME: put in cookie? */ stcb->asoc.authinfo.active_keyid = stcb->sctp_ep->sctp_ep.default_keyid; /* copy out the shared key list (by reference) from the endpoint */ (void)sctp_copy_skeylist(&stcb->sctp_ep->sctp_ep.shared_keys, &stcb->asoc.shared_keys); } /* * compute and fill in the HMAC digest for a packet */ void sctp_fill_hmac_digest_m(struct mbuf *m, uint32_t auth_offset, struct sctp_auth_chunk *auth, struct sctp_tcb *stcb, uint16_t keyid) { uint32_t digestlen; sctp_sharedkey_t *skey; sctp_key_t *key; if ((stcb == NULL) || (auth == NULL)) return; /* zero the digest + chunk padding */ digestlen = sctp_get_hmac_digest_len(stcb->asoc.peer_hmac_id); bzero(auth->hmac, SCTP_SIZE32(digestlen)); /* is the desired key cached? */ if ((keyid != stcb->asoc.authinfo.assoc_keyid) || (stcb->asoc.authinfo.assoc_key == NULL)) { if (stcb->asoc.authinfo.assoc_key != NULL) { /* free the old cached key */ sctp_free_key(stcb->asoc.authinfo.assoc_key); } skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, keyid); /* the only way skey is NULL is if null key id 0 is used */ if (skey != NULL) key = skey->key; else key = NULL; /* compute a new assoc key and cache it */ stcb->asoc.authinfo.assoc_key = sctp_compute_hashkey(stcb->asoc.authinfo.random, stcb->asoc.authinfo.peer_random, key); stcb->asoc.authinfo.assoc_keyid = keyid; SCTPDBG(SCTP_DEBUG_AUTH1, "caching key id %u\n", stcb->asoc.authinfo.assoc_keyid); #ifdef SCTP_DEBUG if (SCTP_AUTH_DEBUG) sctp_print_key(stcb->asoc.authinfo.assoc_key, "Assoc Key"); #endif } /* set in the active key id */ auth->shared_key_id = htons(keyid); /* compute and fill in the digest */ (void)sctp_compute_hmac_m(stcb->asoc.peer_hmac_id, stcb->asoc.authinfo.assoc_key, m, auth_offset, auth->hmac); } static void sctp_bzero_m(struct mbuf *m, uint32_t m_offset, uint32_t size) { struct mbuf *m_tmp; uint8_t *data; /* sanity check */ if (m == NULL) return; /* find the correct starting mbuf and offset (get start position) */ m_tmp = m; while ((m_tmp != NULL) && (m_offset >= (uint32_t) SCTP_BUF_LEN(m_tmp))) { m_offset -= SCTP_BUF_LEN(m_tmp); m_tmp = SCTP_BUF_NEXT(m_tmp); } /* now use the rest of the mbuf chain */ while ((m_tmp != NULL) && (size > 0)) { data = mtod(m_tmp, uint8_t *) + m_offset; if (size > (uint32_t) SCTP_BUF_LEN(m_tmp)) { bzero(data, SCTP_BUF_LEN(m_tmp)); size -= SCTP_BUF_LEN(m_tmp); } else { bzero(data, size); size = 0; } /* clear the offset since it's only for the first mbuf */ m_offset = 0; m_tmp = SCTP_BUF_NEXT(m_tmp); } } /*- * process the incoming Authentication chunk * return codes: * -1 on any authentication error * 0 on authentication verification */ int sctp_handle_auth(struct sctp_tcb *stcb, struct sctp_auth_chunk *auth, struct mbuf *m, uint32_t offset) { uint16_t chunklen; uint16_t shared_key_id; uint16_t hmac_id; sctp_sharedkey_t *skey; uint32_t digestlen; uint8_t digest[SCTP_AUTH_DIGEST_LEN_MAX]; uint8_t computed_digest[SCTP_AUTH_DIGEST_LEN_MAX]; /* auth is checked for NULL by caller */ chunklen = ntohs(auth->ch.chunk_length); if (chunklen < sizeof(*auth)) { SCTP_STAT_INCR(sctps_recvauthfailed); return (-1); } SCTP_STAT_INCR(sctps_recvauth); /* get the auth params */ shared_key_id = ntohs(auth->shared_key_id); hmac_id = ntohs(auth->hmac_id); SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP AUTH Chunk: shared key %u, HMAC id %u\n", shared_key_id, hmac_id); /* is the indicated HMAC supported? */ if (!sctp_auth_is_supported_hmac(stcb->asoc.local_hmacs, hmac_id)) { struct mbuf *m_err; struct sctp_auth_invalid_hmac *err; SCTP_STAT_INCR(sctps_recvivalhmacid); SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP Auth: unsupported HMAC id %u\n", hmac_id); /* * report this in an Error Chunk: Unsupported HMAC * Identifier */ m_err = sctp_get_mbuf_for_msg(sizeof(*err), 0, M_DONTWAIT, 1, MT_HEADER); if (m_err != NULL) { /* pre-reserve some space */ SCTP_BUF_RESV_UF(m_err, sizeof(struct sctp_chunkhdr)); /* fill in the error */ err = mtod(m_err, struct sctp_auth_invalid_hmac *); bzero(err, sizeof(*err)); err->ph.param_type = htons(SCTP_CAUSE_UNSUPPORTED_HMACID); err->ph.param_length = htons(sizeof(*err)); err->hmac_id = ntohs(hmac_id); SCTP_BUF_LEN(m_err) = sizeof(*err); /* queue it */ sctp_queue_op_err(stcb, m_err); } return (-1); } /* get the indicated shared key, if available */ if ((stcb->asoc.authinfo.recv_key == NULL) || (stcb->asoc.authinfo.recv_keyid != shared_key_id)) { /* find the shared key on the assoc first */ skey = sctp_find_sharedkey(&stcb->asoc.shared_keys, shared_key_id); /* if the shared key isn't found, discard the chunk */ if (skey == NULL) { SCTP_STAT_INCR(sctps_recvivalkeyid); SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP Auth: unknown key id %u\n", shared_key_id); return (-1); } /* generate a notification if this is a new key id */ if (stcb->asoc.authinfo.recv_keyid != shared_key_id) /* * sctp_ulp_notify(SCTP_NOTIFY_AUTH_NEW_KEY, stcb, * shared_key_id, (void * *)stcb->asoc.authinfo.recv_keyid); */ sctp_notify_authentication(stcb, SCTP_AUTH_NEW_KEY, shared_key_id, stcb->asoc.authinfo.recv_keyid, SCTP_SO_NOT_LOCKED); /* compute a new recv assoc key and cache it */ if (stcb->asoc.authinfo.recv_key != NULL) sctp_free_key(stcb->asoc.authinfo.recv_key); stcb->asoc.authinfo.recv_key = sctp_compute_hashkey(stcb->asoc.authinfo.random, stcb->asoc.authinfo.peer_random, skey->key); stcb->asoc.authinfo.recv_keyid = shared_key_id; #ifdef SCTP_DEBUG if (SCTP_AUTH_DEBUG) sctp_print_key(stcb->asoc.authinfo.recv_key, "Recv Key"); #endif } /* validate the digest length */ digestlen = sctp_get_hmac_digest_len(hmac_id); if (chunklen < (sizeof(*auth) + digestlen)) { /* invalid digest length */ SCTP_STAT_INCR(sctps_recvauthfailed); SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP Auth: chunk too short for HMAC\n"); return (-1); } /* save a copy of the digest, zero the pseudo header, and validate */ bcopy(auth->hmac, digest, digestlen); sctp_bzero_m(m, offset + sizeof(*auth), SCTP_SIZE32(digestlen)); (void)sctp_compute_hmac_m(hmac_id, stcb->asoc.authinfo.recv_key, m, offset, computed_digest); /* compare the computed digest with the one in the AUTH chunk */ if (memcmp(digest, computed_digest, digestlen) != 0) { SCTP_STAT_INCR(sctps_recvauthfailed); SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP Auth: HMAC digest check failed\n"); return (-1); } return (0); } /* * Generate NOTIFICATION */ void sctp_notify_authentication(struct sctp_tcb *stcb, uint32_t indication, uint16_t keyid, uint16_t alt_keyid, int so_locked #if !defined(__APPLE__) && !defined(SCTP_SO_LOCK_TESTING) SCTP_UNUSED #endif ) { struct mbuf *m_notify; struct sctp_authkey_event *auth; struct sctp_queued_to_read *control; if ((stcb == NULL) || (stcb->sctp_ep->sctp_flags & SCTP_PCB_FLAGS_SOCKET_GONE) || (stcb->sctp_ep->sctp_flags & SCTP_PCB_FLAGS_SOCKET_ALLGONE) || (stcb->asoc.state & SCTP_STATE_CLOSED_SOCKET) ) { /* If the socket is gone we are out of here */ return; } if (sctp_stcb_is_feature_off(stcb->sctp_ep, stcb, SCTP_PCB_FLAGS_AUTHEVNT)) /* event not enabled */ return; m_notify = sctp_get_mbuf_for_msg(sizeof(struct sctp_authkey_event), 0, M_DONTWAIT, 1, MT_HEADER); if (m_notify == NULL) /* no space left */ return; SCTP_BUF_LEN(m_notify) = 0; auth = mtod(m_notify, struct sctp_authkey_event *); auth->auth_type = SCTP_AUTHENTICATION_EVENT; auth->auth_flags = 0; auth->auth_length = sizeof(*auth); auth->auth_keynumber = keyid; auth->auth_altkeynumber = alt_keyid; auth->auth_indication = indication; auth->auth_assoc_id = sctp_get_associd(stcb); SCTP_BUF_LEN(m_notify) = sizeof(*auth); SCTP_BUF_NEXT(m_notify) = NULL; /* append to socket */ control = sctp_build_readq_entry(stcb, stcb->asoc.primary_destination, 0, 0, stcb->asoc.context, 0, 0, 0, m_notify); if (control == NULL) { /* no memory */ sctp_m_freem(m_notify); return; } control->spec_flags = M_NOTIFICATION; control->length = SCTP_BUF_LEN(m_notify); /* not that we need this */ control->tail_mbuf = m_notify; sctp_add_to_readq(stcb->sctp_ep, stcb, control, &stcb->sctp_socket->so_rcv, 1, SCTP_READ_LOCK_NOT_HELD, so_locked); } /*- * validates the AUTHentication related parameters in an INIT/INIT-ACK * Note: currently only used for INIT as INIT-ACK is handled inline * with sctp_load_addresses_from_init() */ int sctp_validate_init_auth_params(struct mbuf *m, int offset, int limit) { struct sctp_paramhdr *phdr, parm_buf; uint16_t ptype, plen; int peer_supports_asconf = 0; int peer_supports_auth = 0; int got_random = 0, got_hmacs = 0, got_chklist = 0; uint8_t saw_asconf = 0; uint8_t saw_asconf_ack = 0; /* go through each of the params. */ phdr = sctp_get_next_param(m, offset, &parm_buf, sizeof(parm_buf)); while (phdr) { ptype = ntohs(phdr->param_type); plen = ntohs(phdr->param_length); if (offset + plen > limit) { break; } if (plen < sizeof(struct sctp_paramhdr)) { break; } if (ptype == SCTP_SUPPORTED_CHUNK_EXT) { /* A supported extension chunk */ struct sctp_supported_chunk_types_param *pr_supported; uint8_t local_store[SCTP_PARAM_BUFFER_SIZE]; int num_ent, i; phdr = sctp_get_next_param(m, offset, (struct sctp_paramhdr *)&local_store, min(plen, sizeof(local_store))); if (phdr == NULL) { return (-1); } pr_supported = (struct sctp_supported_chunk_types_param *)phdr; num_ent = plen - sizeof(struct sctp_paramhdr); for (i = 0; i < num_ent; i++) { switch (pr_supported->chunk_types[i]) { case SCTP_ASCONF: case SCTP_ASCONF_ACK: peer_supports_asconf = 1; break; default: /* one we don't care about */ break; } } } else if (ptype == SCTP_RANDOM) { got_random = 1; /* enforce the random length */ if (plen != (sizeof(struct sctp_auth_random) + SCTP_AUTH_RANDOM_SIZE_REQUIRED)) { SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: invalid RANDOM len\n"); return (-1); } } else if (ptype == SCTP_HMAC_LIST) { uint8_t store[SCTP_PARAM_BUFFER_SIZE]; struct sctp_auth_hmac_algo *hmacs; int num_hmacs; if (plen > sizeof(store)) break; phdr = sctp_get_next_param(m, offset, (struct sctp_paramhdr *)store, min(plen, sizeof(store))); if (phdr == NULL) return (-1); hmacs = (struct sctp_auth_hmac_algo *)phdr; num_hmacs = (plen - sizeof(*hmacs)) / sizeof(hmacs->hmac_ids[0]); /* validate the hmac list */ if (sctp_verify_hmac_param(hmacs, num_hmacs)) { SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: invalid HMAC param\n"); return (-1); } got_hmacs = 1; } else if (ptype == SCTP_CHUNK_LIST) { int i, num_chunks; uint8_t chunks_store[SCTP_SMALL_CHUNK_STORE]; /* did the peer send a non-empty chunk list? */ struct sctp_auth_chunk_list *chunks = NULL; phdr = sctp_get_next_param(m, offset, (struct sctp_paramhdr *)chunks_store, min(plen, sizeof(chunks_store))); if (phdr == NULL) return (-1); /*- * Flip through the list and mark that the * peer supports asconf/asconf_ack. */ chunks = (struct sctp_auth_chunk_list *)phdr; num_chunks = plen - sizeof(*chunks); for (i = 0; i < num_chunks; i++) { /* record asconf/asconf-ack if listed */ if (chunks->chunk_types[i] == SCTP_ASCONF) saw_asconf = 1; if (chunks->chunk_types[i] == SCTP_ASCONF_ACK) saw_asconf_ack = 1; } if (num_chunks) got_chklist = 1; } offset += SCTP_SIZE32(plen); if (offset >= limit) { break; } phdr = sctp_get_next_param(m, offset, &parm_buf, sizeof(parm_buf)); } /* validate authentication required parameters */ if (got_random && got_hmacs) { peer_supports_auth = 1; } else { peer_supports_auth = 0; } if (!peer_supports_auth && got_chklist) { SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: peer sent chunk list w/o AUTH\n"); return (-1); } if (!SCTP_BASE_SYSCTL(sctp_asconf_auth_nochk) && peer_supports_asconf && !peer_supports_auth) { SCTPDBG(SCTP_DEBUG_AUTH1, "SCTP: peer supports ASCONF but not AUTH\n"); return (-1); } else if ((peer_supports_asconf) && (peer_supports_auth) && ((saw_asconf == 0) || (saw_asconf_ack == 0))) { return (-2); } return (0); } void sctp_initialize_auth_params(struct sctp_inpcb *inp, struct sctp_tcb *stcb) { uint16_t chunks_len = 0; uint16_t hmacs_len = 0; uint16_t random_len = SCTP_AUTH_RANDOM_SIZE_DEFAULT; sctp_key_t *new_key; uint16_t keylen; /* initialize hmac list from endpoint */ stcb->asoc.local_hmacs = sctp_copy_hmaclist(inp->sctp_ep.local_hmacs); if (stcb->asoc.local_hmacs != NULL) { hmacs_len = stcb->asoc.local_hmacs->num_algo * sizeof(stcb->asoc.local_hmacs->hmac[0]); } /* initialize auth chunks list from endpoint */ stcb->asoc.local_auth_chunks = sctp_copy_chunklist(inp->sctp_ep.local_auth_chunks); if (stcb->asoc.local_auth_chunks != NULL) { int i; for (i = 0; i < 256; i++) { if (stcb->asoc.local_auth_chunks->chunks[i]) chunks_len++; } } /* copy defaults from the endpoint */ stcb->asoc.authinfo.active_keyid = inp->sctp_ep.default_keyid; /* copy out the shared key list (by reference) from the endpoint */ (void)sctp_copy_skeylist(&inp->sctp_ep.shared_keys, &stcb->asoc.shared_keys); /* now set the concatenated key (random + chunks + hmacs) */ /* key includes parameter headers */ keylen = (3 * sizeof(struct sctp_paramhdr)) + random_len + chunks_len + hmacs_len; new_key = sctp_alloc_key(keylen); if (new_key != NULL) { struct sctp_paramhdr *ph; int plen; /* generate and copy in the RANDOM */ ph = (struct sctp_paramhdr *)new_key->key; ph->param_type = htons(SCTP_RANDOM); plen = sizeof(*ph) + random_len; ph->param_length = htons(plen); SCTP_READ_RANDOM(new_key->key + sizeof(*ph), random_len); keylen = plen; /* append in the AUTH chunks */ /* NOTE: currently we always have chunks to list */ ph = (struct sctp_paramhdr *)(new_key->key + keylen); ph->param_type = htons(SCTP_CHUNK_LIST); plen = sizeof(*ph) + chunks_len; ph->param_length = htons(plen); keylen += sizeof(*ph); if (stcb->asoc.local_auth_chunks) { int i; for (i = 0; i < 256; i++) { if (stcb->asoc.local_auth_chunks->chunks[i]) new_key->key[keylen++] = i; } } /* append in the HMACs */ ph = (struct sctp_paramhdr *)(new_key->key + keylen); ph->param_type = htons(SCTP_HMAC_LIST); plen = sizeof(*ph) + hmacs_len; ph->param_length = htons(plen); keylen += sizeof(*ph); (void)sctp_serialize_hmaclist(stcb->asoc.local_hmacs, new_key->key + keylen); } if (stcb->asoc.authinfo.random != NULL) sctp_free_key(stcb->asoc.authinfo.random); stcb->asoc.authinfo.random = new_key; stcb->asoc.authinfo.random_len = random_len; }