/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #define _SUN_TPI_VERSION 2 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ksslimpl.h" #include "ksslapi.h" #include "ksslproto.h" static ssl3CipherSuiteDef cipher_suite_defs[] = { /* 2 X 16 byte keys + 2 x 20 byte MAC secrets, no IVs */ {SSL_RSA_WITH_RC4_128_SHA, cipher_rc4, mac_sha, 72}, /* 2 X 16 byte keys + 2 x 16 byte MAC secrets, no IVs */ {SSL_RSA_WITH_RC4_128_MD5, cipher_rc4, mac_md5, 64}, /* 2 X 8 byte keys + 2 x 20 byte MAC secrets, 2 x 8 byte IVs */ {SSL_RSA_WITH_DES_CBC_SHA, cipher_des, mac_sha, 72}, /* 2 X 24 byte keys + 2 x 20 byte MAC secrets, 2 x 8 byte IVs */ {SSL_RSA_WITH_3DES_EDE_CBC_SHA, cipher_3des, mac_sha, 104}, /* 2 X 16 byte keys + 2 x 20 byte MAC secrets, 2 x 16 byte IVs */ {TLS_RSA_WITH_AES_128_CBC_SHA, cipher_aes128, mac_sha, 104}, /* 2 X 32 byte keys + 2 x 20 byte MAC secrets, 2 x 16 byte IVs */ {TLS_RSA_WITH_AES_256_CBC_SHA, cipher_aes256, mac_sha, 136}, {SSL_RSA_WITH_NULL_SHA, cipher_null, mac_sha, 40} }; static int cipher_suite_defs_nentries = sizeof (cipher_suite_defs) / sizeof (cipher_suite_defs[0]); static KSSLMACDef mac_defs[] = { /* indexed by SSL3MACAlgorithm */ /* macsz padsz HashInit HashUpdate HashFinal */ {MD5_HASH_LEN, SSL3_MD5_PAD_LEN, (hashinit_func_t)MD5Init, (hashupdate_func_t)MD5Update, (hashfinal_func_t)MD5Final}, {SHA1_HASH_LEN, SSL3_SHA1_PAD_LEN, (hashinit_func_t)SHA1Init, (hashupdate_func_t)SHA1Update, (hashfinal_func_t)SHA1Final}, }; static uchar_t kssl_pad_1[60] = { 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36, 0x36 }; static uchar_t kssl_pad_2[60] = { 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c, 0x5c }; int kssl_cache_count; static boolean_t kssl_synchronous = B_FALSE; static void kssl_update_handshake_hashes(ssl_t *, uchar_t *, uint_t); static int kssl_compute_handshake_hashes(ssl_t *, SSL3Hashes *, uint32_t); static int kssl_handle_client_hello(ssl_t *, mblk_t *, int); static int kssl_handle_client_key_exchange(ssl_t *, mblk_t *, int, kssl_callback_t, void *); static int kssl_send_server_hello(ssl_t *); static int kssl_send_certificate_and_server_hello_done(ssl_t *); static int kssl_send_change_cipher_specs(ssl_t *); static int kssl_send_finished(ssl_t *, int); static int kssl_handle_finished(ssl_t *, mblk_t *, int); static void kssl_get_hello_random(uchar_t *); static uchar_t *kssl_rsa_unwrap(uchar_t *, size_t *); static void kssl_cache_sid(sslSessionID *, kssl_entry_t *); static void kssl_lookup_sid(sslSessionID *, uchar_t *, in6_addr_t *, kssl_entry_t *); static int kssl_generate_tls_ms(ssl_t *, uchar_t *, size_t); static void kssl_generate_ssl_ms(ssl_t *, uchar_t *, size_t); static int kssl_generate_tls_keyblock(ssl_t *); static void kssl_generate_keyblock(ssl_t *); static void kssl_ssl3_key_material_derive_step(ssl_t *, uchar_t *, size_t, int, uchar_t *, int); static int kssl_tls_PRF(ssl_t *, uchar_t *, size_t, uchar_t *, size_t, uchar_t *, size_t, uchar_t *, size_t); static int kssl_tls_P_hash(crypto_mechanism_t *, crypto_key_t *, size_t, uchar_t *, size_t, uchar_t *, size_t, uchar_t *, size_t); static void kssl_cke_done(void *, int); #define HMAC_INIT(m, k, c) \ rv = crypto_mac_init(m, k, NULL, c, NULL); if (CRYPTO_ERR(rv)) goto end; #define HMAC_UPDATE(c, d, l) \ dd.cd_raw.iov_base = (char *)d; \ dd.cd_length = dd.cd_raw.iov_len = l; \ rv = crypto_mac_update(c, &dd, NULL); if (CRYPTO_ERR(rv)) goto end; #define HMAC_FINAL(c, d, l) \ mac.cd_raw.iov_base = (char *)d; \ mac.cd_length = mac.cd_raw.iov_len = l; \ rv = crypto_mac_final(c, &mac, NULL); if (CRYPTO_ERR(rv)) goto end; /* * This hack can go away once we have SSL3 MAC support by KCF * software providers (See 4873559). */ extern int kcf_md5_threshold; int kssl_compute_record_mac( ssl_t *ssl, int direction, uint64_t seq_num, SSL3ContentType ct, uchar_t *versionp, uchar_t *buf, int len, uchar_t *digest) { KSSL_HASHCTX mac_ctx; KSSL_HASHCTX *ctx = &mac_ctx; uchar_t temp[16], *p; KSSLCipherSpec *spec; boolean_t hash_use_ok = B_FALSE; int rv = 0; spec = &ssl->spec[direction]; if (spec->mac_hashsz == 0) { return (1); } p = temp; *p++ = (seq_num >> 56) & 0xff; *p++ = (seq_num >> 48) & 0xff; *p++ = (seq_num >> 40) & 0xff; *p++ = (seq_num >> 32) & 0xff; *p++ = (seq_num >> 24) & 0xff; *p++ = (seq_num >> 16) & 0xff; *p++ = (seq_num >> 8) & 0xff; *p++ = (seq_num) & 0xff; *p++ = (uchar_t)ct; if (IS_TLS(ssl)) { *p++ = versionp[0]; *p++ = versionp[1]; } *p++ = (len >> 8) & 0xff; *p++ = (len) & 0xff; if (IS_TLS(ssl) || (spec->hmac_mech.cm_type != CRYPTO_MECH_INVALID && len >= kcf_md5_threshold)) { crypto_data_t dd, mac; struct uio uio_pt; struct iovec iovarray_pt[2]; /* init the array of iovecs for use in the uio struct */ iovarray_pt[0].iov_base = (char *)temp; iovarray_pt[0].iov_len = (p - temp); iovarray_pt[1].iov_base = (char *)buf; iovarray_pt[1].iov_len = len; /* init the uio struct for use in the crypto_data_t struct */ bzero(&uio_pt, sizeof (uio_pt)); uio_pt.uio_iov = iovarray_pt; uio_pt.uio_iovcnt = 2; uio_pt.uio_segflg = UIO_SYSSPACE; dd.cd_format = CRYPTO_DATA_UIO; dd.cd_offset = 0; dd.cd_length = (p - temp) + len; dd.cd_miscdata = NULL; dd.cd_uio = &uio_pt; mac.cd_format = CRYPTO_DATA_RAW; mac.cd_offset = 0; mac.cd_raw.iov_base = (char *)digest; mac.cd_length = mac.cd_raw.iov_len = spec->mac_hashsz; /* * The calling context can tolerate a blocking call here. * For outgoing traffic, we are in user context * when called from strsock_kssl_output(). For incoming * traffic past the SSL handshake, we are in user * context when called from strsock_kssl_input(). During the * SSL handshake, we are called for client_finished message * handling from a squeue worker thread that gets scheduled * by an SQ_FILL call. This thread is not in interrupt * context and so can block. */ rv = crypto_mac(&spec->hmac_mech, &dd, &spec->hmac_key, NULL, &mac, NULL); if (CRYPTO_ERR(rv)) { hash_use_ok = (rv == CRYPTO_MECH_NOT_SUPPORTED && !IS_TLS(ssl)); if (!hash_use_ok) { DTRACE_PROBE1(kssl_err__crypto_mac_error, int, rv); KSSL_COUNTER(compute_mac_failure, 1); } } } else hash_use_ok = B_TRUE; if (hash_use_ok) { bcopy(&(ssl->mac_ctx[direction][0]), ctx, sizeof (KSSL_HASHCTX)); spec->MAC_HashUpdate((void *)ctx, temp, p - temp); spec->MAC_HashUpdate((void *)ctx, buf, len); spec->MAC_HashFinal(digest, (void *)ctx); bcopy(&(ssl->mac_ctx[direction][1]), ctx, sizeof (KSSL_HASHCTX)); spec->MAC_HashUpdate((void *)ctx, digest, spec->mac_hashsz); spec->MAC_HashFinal(digest, (void *)ctx); } return (rv); } /* * Handles handshake messages. * Messages to be replied are returned in handshake_sendbuf. */ int kssl_handle_handshake_message(ssl_t *ssl, mblk_t *mp, int *err, kssl_callback_t cbfn, void *arg) { uint32_t msglen; uchar_t msghdr[4]; ASSERT(ssl->msg.state == MSG_BODY); ASSERT(ssl->msg.msglen_bytes == 3); ASSERT(mp->b_wptr >= mp->b_rptr + ssl->msg.msglen); ssl->sslcnt++; msglen = ssl->msg.msglen; if (ssl->msg.type == client_hello) { MD5Init(&ssl->hs_md5); SHA1Init(&ssl->hs_sha1); } if (ssl->msg.type == finished && ssl->resumed == B_FALSE) { if (kssl_compute_handshake_hashes(ssl, &ssl->hs_hashes, sender_client) != 0) { *err = SSL_MISS; return (0); } } if (ssl->msg.type != finished || ssl->resumed == B_FALSE) { msghdr[0] = (uchar_t)ssl->msg.type; msghdr[1] = (uchar_t)(msglen >> 16); msghdr[2] = (uchar_t)(msglen >> 8); msghdr[3] = (uchar_t)(msglen); kssl_update_handshake_hashes(ssl, msghdr, 4); kssl_update_handshake_hashes(ssl, mp->b_rptr, msglen); } ssl->msg.state = MSG_INIT; ssl->msg.msglen = 0; ssl->msg.msglen_bytes = 0; switch (ssl->msg.type) { case client_hello: if (ssl->hs_waitstate != wait_client_hello) { kssl_send_alert(ssl, alert_fatal, unexpected_message); *err = EBADMSG; ssl->activeinput = B_FALSE; return (1); } *err = kssl_handle_client_hello(ssl, mp, msglen); if (*err == SSL_MISS) { ssl->activeinput = B_FALSE; return (0); } return (1); case client_key_exchange: if (ssl->hs_waitstate != wait_client_key) { kssl_send_alert(ssl, alert_fatal, unexpected_message); *err = EBADMSG; ssl->activeinput = B_FALSE; return (1); } *err = kssl_handle_client_key_exchange(ssl, mp, msglen, cbfn, arg); return (1); case finished: if (ssl->hs_waitstate != wait_finished) { kssl_send_alert(ssl, alert_fatal, unexpected_message); *err = EBADMSG; ssl->activeinput = B_FALSE; return (1); } *err = kssl_handle_finished(ssl, mp, msglen); return (1); default: kssl_send_alert(ssl, alert_fatal, unexpected_message); ssl->activeinput = B_FALSE; *err = EBADMSG; return (1); } } static void kssl_update_handshake_hashes(ssl_t *ssl, uchar_t *buf, uint_t len) { MD5Update(&ssl->hs_md5, buf, len); SHA1Update(&ssl->hs_sha1, buf, len); } static int kssl_compute_handshake_hashes( ssl_t *ssl, SSL3Hashes *hashes, uint32_t sender) { MD5_CTX md5 = ssl->hs_md5; /* clone md5 context */ SHA1_CTX sha1 = ssl->hs_sha1; /* clone sha1 context */ MD5_CTX *md5ctx = &md5; SHA1_CTX *sha1ctx = &sha1; if (IS_TLS(ssl)) { uchar_t seed[MD5_HASH_LEN + SHA1_HASH_LEN]; char *label; /* * Do not take another hash step here. * Just complete the operation. */ MD5Final(hashes->md5, md5ctx); SHA1Final(hashes->sha1, sha1ctx); bcopy(hashes->md5, seed, MD5_HASH_LEN); bcopy(hashes->sha1, seed + MD5_HASH_LEN, SHA1_HASH_LEN); if (sender == sender_client) label = TLS_CLIENT_FINISHED_LABEL; else label = TLS_SERVER_FINISHED_LABEL; return (kssl_tls_PRF(ssl, ssl->sid.master_secret, (size_t)SSL3_MASTER_SECRET_LEN, (uchar_t *)label, strlen(label), seed, (size_t)(MD5_HASH_LEN + SHA1_HASH_LEN), hashes->tlshash, (size_t)TLS_FINISHED_SIZE)); } else { uchar_t s[4]; s[0] = (sender >> 24) & 0xff; s[1] = (sender >> 16) & 0xff; s[2] = (sender >> 8) & 0xff; s[3] = (sender) & 0xff; MD5Update(md5ctx, s, 4); MD5Update(md5ctx, ssl->sid.master_secret, SSL3_MASTER_SECRET_LEN); MD5Update(md5ctx, kssl_pad_1, SSL3_MD5_PAD_LEN); MD5Final(hashes->md5, md5ctx); MD5Init(md5ctx); MD5Update(md5ctx, ssl->sid.master_secret, SSL3_MASTER_SECRET_LEN); MD5Update(md5ctx, kssl_pad_2, SSL3_MD5_PAD_LEN); MD5Update(md5ctx, hashes->md5, MD5_HASH_LEN); MD5Final(hashes->md5, md5ctx); SHA1Update(sha1ctx, s, 4); SHA1Update(sha1ctx, ssl->sid.master_secret, SSL3_MASTER_SECRET_LEN); SHA1Update(sha1ctx, kssl_pad_1, SSL3_SHA1_PAD_LEN); SHA1Final(hashes->sha1, sha1ctx); SHA1Init(sha1ctx); SHA1Update(sha1ctx, ssl->sid.master_secret, SSL3_MASTER_SECRET_LEN); SHA1Update(sha1ctx, kssl_pad_2, SSL3_SHA1_PAD_LEN); SHA1Update(sha1ctx, hashes->sha1, SHA1_HASH_LEN); SHA1Final(hashes->sha1, sha1ctx); return (0); } } /* * Minimum message length for a client hello = * 2-byte client_version + * 32-byte random + * 1-byte session_id length + * 2-byte cipher_suites length + * 1-byte compression_methods length + * 1-byte CompressionMethod.null */ #define KSSL_SSL3_CH_MIN_MSGLEN (39) static int kssl_handle_client_hello(ssl_t *ssl, mblk_t *mp, int msglen) { uchar_t *msgend; int err; SSL3AlertDescription desc = illegal_parameter; uint_t sidlen, cslen, cmlen; uchar_t *suitesp; uint_t i, j; uint16_t suite; int ch_msglen = KSSL_SSL3_CH_MIN_MSGLEN; ASSERT(mp->b_wptr >= mp->b_rptr + msglen); ASSERT(ssl->msg.type == client_hello); ASSERT(ssl->hs_waitstate == wait_client_hello); ASSERT(ssl->resumed == B_FALSE); if (msglen < ch_msglen) { goto falert; } msgend = mp->b_rptr + msglen; /* Support SSLv3 (version == 3.0) or TLS (version == 3.1) */ if (ssl->major_version != 3 || (ssl->major_version == 3 && ssl->minor_version != 0 && ssl->minor_version != 1)) { DTRACE_PROBE2(kssl_err__SSL_version_not_supported, uchar_t, ssl->major_version, uchar_t, ssl->minor_version); desc = handshake_failure; goto falert; } mp->b_rptr += 2; /* skip the version bytes */ bcopy(mp->b_rptr, ssl->client_random, SSL3_RANDOM_LENGTH); mp->b_rptr += SSL3_RANDOM_LENGTH; ASSERT(ssl->sid.cached == B_FALSE); sidlen = *mp->b_rptr++; ch_msglen += sidlen; if (msglen < ch_msglen) { goto falert; } if (sidlen != SSL3_SESSIONID_BYTES) { mp->b_rptr += sidlen; } else { kssl_lookup_sid(&ssl->sid, mp->b_rptr, &ssl->faddr, ssl->kssl_entry); mp->b_rptr += SSL3_SESSIONID_BYTES; } cslen = ((uint_t)mp->b_rptr[0] << 8) + (uint_t)mp->b_rptr[1]; mp->b_rptr += 2; ch_msglen += cslen; /* * This check can't be a "!=" since there can be * compression methods other than CompressionMethod.null. * Also, there can be extra data (TLS extensions) after the * compression methods field. We do not support any TLS * extensions and hence ignore them. */ if (msglen < ch_msglen) { goto falert; } /* The length has to be even since a cipher suite is 2-byte long */ if (cslen & 0x1) { goto falert; } suitesp = mp->b_rptr; if (ssl->sid.cached == B_TRUE) { suite = ssl->sid.cipher_suite; for (j = 0; j < cslen; j += 2) { if (suitesp[j] == ((suite >> 8) & 0xff) && suitesp[j + 1] == (suite & 0xff)) { break; } } if (j < cslen) { goto suite_found; } kssl_uncache_sid(&ssl->sid, ssl->kssl_entry); } /* Check if this server is capable of the cipher suite */ for (i = 0; i < ssl->kssl_entry->kssl_cipherSuites_nentries; i++) { suite = ssl->kssl_entry->kssl_cipherSuites[i]; for (j = 0; j < cslen; j += 2) { if (suitesp[j] == ((suite >> 8) & 0xff) && suitesp[j + 1] == (suite & 0xff)) { break; } } if (j < cslen) { break; } } if (i == ssl->kssl_entry->kssl_cipherSuites_nentries) { if (ssl->sslcnt == 1) { KSSL_COUNTER(no_suite_found, 1); return (SSL_MISS); } desc = handshake_failure; DTRACE_PROBE(kssl_err__no_cipher_suites_found); goto falert; } suite_found: mp->b_rptr += cslen; /* * Check for the mandatory CompressionMethod.null. We do not * support any other compression methods. */ cmlen = *mp->b_rptr++; ch_msglen += cmlen - 1; /* -1 accounts for the null method */ if (msglen < ch_msglen) { goto falert; } while (cmlen >= 1) { if (*mp->b_rptr++ == 0) break; cmlen--; } if (cmlen == 0) { desc = handshake_failure; DTRACE_PROBE(kssl_err__no_null_method_failure); goto falert; } mp->b_rptr = msgend; for (i = 0; i < cipher_suite_defs_nentries; i++) { if (suite == cipher_suite_defs[i].suite) { break; } } ASSERT(i < cipher_suite_defs_nentries); ssl->pending_cipher_suite = suite; ssl->pending_malg = cipher_suite_defs[i].malg; ssl->pending_calg = cipher_suite_defs[i].calg; ssl->pending_keyblksz = cipher_suite_defs[i].keyblksz; if (ssl->sid.cached == B_TRUE) { err = kssl_send_server_hello(ssl); if (err != 0) { return (err); } if (IS_TLS(ssl)) err = kssl_generate_tls_keyblock(ssl); else kssl_generate_keyblock(ssl); err = kssl_send_change_cipher_specs(ssl); if (err != 0) { return (err); } err = kssl_send_finished(ssl, 1); if (err != 0) return (err); err = kssl_compute_handshake_hashes(ssl, &ssl->hs_hashes, sender_client); if (err != 0) return (err); ssl->hs_waitstate = wait_change_cipher; ssl->resumed = B_TRUE; ssl->activeinput = B_FALSE; KSSL_COUNTER(resumed_sessions, 1); return (0); } (void) random_get_pseudo_bytes(ssl->sid.session_id, SSL3_SESSIONID_BYTES); ssl->sid.client_addr = ssl->faddr; ssl->sid.cipher_suite = suite; err = kssl_send_server_hello(ssl); if (err != 0) { return (err); } err = kssl_send_certificate_and_server_hello_done(ssl); if (err != 0) { return (err); } KSSL_COUNTER(full_handshakes, 1); ssl->hs_waitstate = wait_client_key; ssl->activeinput = B_FALSE; return (0); falert: kssl_send_alert(ssl, alert_fatal, desc); return (EBADMSG); } #define SET_HASH_INDEX(index, s, clnt_addr) { \ int addr; \ \ IN6_V4MAPPED_TO_IPADDR(clnt_addr, addr); \ index = addr ^ (((int)(s)[0] << 24) | ((int)(s)[1] << 16) | \ ((int)(s)[2] << 8) | (int)(s)[SSL3_SESSIONID_BYTES - 1]); \ } /* * Creates a cache entry. Sets the sid->cached flag * and sid->time fields. So, the caller should not set them. */ static void kssl_cache_sid(sslSessionID *sid, kssl_entry_t *kssl_entry) { uint_t index; uchar_t *s = sid->session_id; kmutex_t *lock; ASSERT(sid->cached == B_FALSE); /* set the values before creating the cache entry */ sid->cached = B_TRUE; sid->time = lbolt; SET_HASH_INDEX(index, s, &sid->client_addr); index %= kssl_entry->sid_cache_nentries; lock = &(kssl_entry->sid_cache[index].se_lock); mutex_enter(lock); kssl_entry->sid_cache[index].se_used++; bcopy(sid, &(kssl_entry->sid_cache[index].se_sid), sizeof (*sid)); mutex_exit(lock); KSSL_COUNTER(sid_cached, 1); } /* * Invalidates the cache entry, if any. Clears the sid->cached flag * as a side effect. */ void kssl_uncache_sid(sslSessionID *sid, kssl_entry_t *kssl_entry) { uint_t index; uchar_t *s = sid->session_id; sslSessionID *csid; kmutex_t *lock; ASSERT(sid->cached == B_TRUE); sid->cached = B_FALSE; SET_HASH_INDEX(index, s, &sid->client_addr); index %= kssl_entry->sid_cache_nentries; lock = &(kssl_entry->sid_cache[index].se_lock); mutex_enter(lock); csid = &(kssl_entry->sid_cache[index].se_sid); if (!(IN6_ARE_ADDR_EQUAL(&csid->client_addr, &sid->client_addr)) || bcmp(csid->session_id, s, SSL3_SESSIONID_BYTES)) { mutex_exit(lock); return; } csid->cached = B_FALSE; mutex_exit(lock); KSSL_COUNTER(sid_uncached, 1); } static void kssl_lookup_sid(sslSessionID *sid, uchar_t *s, in6_addr_t *faddr, kssl_entry_t *kssl_entry) { uint_t index; kmutex_t *lock; sslSessionID *csid; KSSL_COUNTER(sid_cache_lookups, 1); SET_HASH_INDEX(index, s, faddr); index %= kssl_entry->sid_cache_nentries; lock = &(kssl_entry->sid_cache[index].se_lock); mutex_enter(lock); csid = &(kssl_entry->sid_cache[index].se_sid); if (csid->cached == B_FALSE || !IN6_ARE_ADDR_EQUAL(&csid->client_addr, faddr) || bcmp(csid->session_id, s, SSL3_SESSIONID_BYTES)) { mutex_exit(lock); return; } if (TICK_TO_SEC(lbolt - csid->time) > kssl_entry->sid_cache_timeout) { csid->cached = B_FALSE; mutex_exit(lock); return; } bcopy(csid, sid, sizeof (*sid)); mutex_exit(lock); ASSERT(sid->cached == B_TRUE); KSSL_COUNTER(sid_cache_hits, 1); } static uchar_t * kssl_rsa_unwrap(uchar_t *buf, size_t *lenp) { size_t len = *lenp; int i = 2; if (buf[0] != 0 || buf[1] != 2) { return (NULL); } while (i < len) { if (buf[i++] == 0) { *lenp = len - i; break; } } if (i == len) { return (NULL); } return (buf + i); } #define KSSL_SSL3_SH_RECLEN (74) #define KSSL_SSL3_FIN_MSGLEN (36) #define KSSL_SSL3_MAX_CCP_FIN_MSGLEN (128) /* comfortable upper bound */ static int kssl_send_server_hello(ssl_t *ssl) { mblk_t *mp; uchar_t *buf; uchar_t *msgstart; mp = allocb(ssl->tcp_mss, BPRI_HI); if (mp == NULL) { KSSL_COUNTER(alloc_fails, 1); return (ENOMEM); } ssl->handshake_sendbuf = mp; buf = mp->b_wptr; /* 5 byte record header */ buf[0] = content_handshake; buf[1] = ssl->major_version; buf[2] = ssl->minor_version; buf[3] = KSSL_SSL3_SH_RECLEN >> 8; buf[4] = KSSL_SSL3_SH_RECLEN & 0xff; buf += SSL3_HDR_LEN; msgstart = buf; /* 6 byte message header */ buf[0] = (uchar_t)server_hello; /* message type */ buf[1] = 0; /* message len byte 0 */ buf[2] = ((KSSL_SSL3_SH_RECLEN - 4) >> 8) & 0xff; /* message len byte 1 */ buf[3] = (KSSL_SSL3_SH_RECLEN - 4) & 0xff; /* message len byte 2 */ buf[4] = ssl->major_version; /* version byte 0 */ buf[5] = ssl->minor_version; /* version byte 1 */ buf += 6; kssl_get_hello_random(ssl->server_random); bcopy(ssl->server_random, buf, SSL3_RANDOM_LENGTH); buf += SSL3_RANDOM_LENGTH; buf[0] = SSL3_SESSIONID_BYTES; bcopy(ssl->sid.session_id, buf + 1, SSL3_SESSIONID_BYTES); buf += SSL3_SESSIONID_BYTES + 1; buf[0] = (ssl->pending_cipher_suite >> 8) & 0xff; buf[1] = ssl->pending_cipher_suite & 0xff; buf[2] = 0; /* No compression */ mp->b_wptr = buf + 3; ASSERT(mp->b_wptr < mp->b_datap->db_lim); kssl_update_handshake_hashes(ssl, msgstart, KSSL_SSL3_SH_RECLEN); return (0); } static void kssl_get_hello_random(uchar_t *buf) { timestruc_t ts; time_t sec; gethrestime(&ts); sec = ts.tv_sec; buf[0] = (sec >> 24) & 0xff; buf[1] = (sec >> 16) & 0xff; buf[2] = (sec >> 8) & 0xff; buf[3] = (sec) & 0xff; (void) random_get_pseudo_bytes(&buf[4], SSL3_RANDOM_LENGTH - 4); /* Should this be caching? */ } static int kssl_tls_P_hash(crypto_mechanism_t *mech, crypto_key_t *key, size_t hashlen, uchar_t *label, size_t label_len, uchar_t *seed, size_t seedlen, uchar_t *data, size_t datalen) { int rv = 0; uchar_t A1[MAX_HASH_LEN], result[MAX_HASH_LEN]; int bytes_left = datalen; crypto_data_t dd, mac; crypto_context_t ctx; dd.cd_format = CRYPTO_DATA_RAW; dd.cd_offset = 0; mac.cd_format = CRYPTO_DATA_RAW; mac.cd_offset = 0; /* * A(i) = HMAC_hash(secret, seed + A(i-1)); * A(0) = seed; * * Compute A(1): * A(1) = HMAC_hash(secret, label + seed) * */ HMAC_INIT(mech, key, &ctx); HMAC_UPDATE(ctx, label, label_len); HMAC_UPDATE(ctx, seed, seedlen); HMAC_FINAL(ctx, A1, hashlen); /* Compute A(2) ... A(n) */ while (bytes_left > 0) { HMAC_INIT(mech, key, &ctx); HMAC_UPDATE(ctx, A1, hashlen); HMAC_UPDATE(ctx, label, label_len); HMAC_UPDATE(ctx, seed, seedlen); HMAC_FINAL(ctx, result, hashlen); /* * The A(i) value is stored in "result". * Save the results of the MAC so it can be input to next * iteration. */ if (bytes_left > hashlen) { /* Store the chunk result */ bcopy(result, data, hashlen); data += hashlen; bytes_left -= hashlen; /* Update A1 for next iteration */ HMAC_INIT(mech, key, &ctx); HMAC_UPDATE(ctx, A1, hashlen); HMAC_FINAL(ctx, A1, hashlen); } else { bcopy(result, data, bytes_left); data += bytes_left; bytes_left = 0; } } end: if (CRYPTO_ERR(rv)) { DTRACE_PROBE1(kssl_err__crypto_mac_error, int, rv); KSSL_COUNTER(compute_mac_failure, 1); } return (rv); } /* ARGSUSED */ static int kssl_tls_PRF(ssl_t *ssl, uchar_t *secret, size_t secret_len, uchar_t *label, size_t label_len, uchar_t *seed, size_t seed_len, uchar_t *prfresult, size_t prfresult_len) { /* * RFC 2246: * PRF(secret, label, seed) = P_MD5(S1, label + seed) XOR * P_SHA1(S2, label + seed); * S1 = 1st half of secret. * S1 = 2nd half of secret. * */ int rv, i; uchar_t psha1[MAX_KEYBLOCK_LENGTH]; crypto_key_t S1, S2; /* length of secret keys is ceil(length/2) */ size_t slen = roundup(secret_len, 2) / 2; if (prfresult_len > MAX_KEYBLOCK_LENGTH) { DTRACE_PROBE1(kssl_err__unexpected_keyblock_size, size_t, prfresult_len); return (CRYPTO_ARGUMENTS_BAD); } ASSERT(prfresult != NULL); ASSERT(label != NULL); ASSERT(seed != NULL); S1.ck_data = secret; S1.ck_length = slen * 8; /* bits */ S1.ck_format = CRYPTO_KEY_RAW; S2.ck_data = secret + slen; S2.ck_length = slen * 8; /* bits */ S2.ck_format = CRYPTO_KEY_RAW; rv = kssl_tls_P_hash(&hmac_md5_mech, &S1, MD5_HASH_LEN, label, label_len, seed, seed_len, prfresult, prfresult_len); if (CRYPTO_ERR(rv)) goto end; rv = kssl_tls_P_hash(&hmac_sha1_mech, &S2, SHA1_HASH_LEN, label, label_len, seed, seed_len, psha1, prfresult_len); if (CRYPTO_ERR(rv)) goto end; for (i = 0; i < prfresult_len; i++) prfresult[i] ^= psha1[i]; end: if (CRYPTO_ERR(rv)) bzero(prfresult, prfresult_len); return (rv); } #define IS_BAD_PRE_MASTER_SECRET(pms, pmslen, ssl) \ (pms == NULL || pmslen != SSL3_PRE_MASTER_SECRET_LEN || \ pms[0] != ssl->major_version || pms[1] != ssl->minor_version) #define FAKE_PRE_MASTER_SECRET(pms, pmslen, ssl, buf) { \ KSSL_COUNTER(bad_pre_master_secret, 1); \ pms = buf; \ pmslen = SSL3_PRE_MASTER_SECRET_LEN; \ pms[0] = ssl->major_version; \ pms[1] = ssl->minor_version; \ (void) random_get_pseudo_bytes(&buf[2], pmslen - 2); \ } static int kssl_generate_tls_ms(ssl_t *ssl, uchar_t *pms, size_t pmslen) { uchar_t buf[SSL3_PRE_MASTER_SECRET_LEN]; uchar_t seed[SSL3_RANDOM_LENGTH * 2]; /* * Computing the master secret: * ---------------------------- * master_secret = PRF (pms, "master secret", * ClientHello.random + ServerHello.random); */ bcopy(ssl->client_random, seed, SSL3_RANDOM_LENGTH); bcopy(ssl->server_random, seed + SSL3_RANDOM_LENGTH, SSL3_RANDOM_LENGTH); /* if pms is bad fake it to thwart Bleichenbacher attack */ if (IS_BAD_PRE_MASTER_SECRET(pms, pmslen, ssl)) { DTRACE_PROBE(kssl_err__under_Bleichenbacher_attack); FAKE_PRE_MASTER_SECRET(pms, pmslen, ssl, buf); } return (kssl_tls_PRF(ssl, pms, pmslen, (uchar_t *)TLS_MASTER_SECRET_LABEL, (size_t)strlen(TLS_MASTER_SECRET_LABEL), seed, sizeof (seed), ssl->sid.master_secret, (size_t)sizeof (ssl->sid.master_secret))); } static void kssl_generate_ssl_ms(ssl_t *ssl, uchar_t *pms, size_t pmslen) { uchar_t buf[SSL3_PRE_MASTER_SECRET_LEN]; uchar_t *ms; int hlen = MD5_HASH_LEN; ms = ssl->sid.master_secret; /* if pms is bad fake it to thwart Bleichenbacher attack */ if (IS_BAD_PRE_MASTER_SECRET(pms, pmslen, ssl)) { DTRACE_PROBE(kssl_err__under_Bleichenbacher_attack); FAKE_PRE_MASTER_SECRET(pms, pmslen, ssl, buf); } kssl_ssl3_key_material_derive_step(ssl, pms, pmslen, 1, ms, 0); kssl_ssl3_key_material_derive_step(ssl, pms, pmslen, 2, ms + hlen, 0); kssl_ssl3_key_material_derive_step(ssl, pms, pmslen, 3, ms + 2 * hlen, 0); } static int kssl_generate_tls_keyblock(ssl_t *ssl) { uchar_t seed[2 * SSL3_RANDOM_LENGTH]; bcopy(ssl->server_random, seed, SSL3_RANDOM_LENGTH); bcopy(ssl->client_random, seed + SSL3_RANDOM_LENGTH, SSL3_RANDOM_LENGTH); return (kssl_tls_PRF(ssl, ssl->sid.master_secret, (size_t)SSL3_MASTER_SECRET_LEN, (uchar_t *)TLS_KEY_EXPANSION_LABEL, (size_t)strlen(TLS_KEY_EXPANSION_LABEL), seed, (size_t)sizeof (seed), ssl->pending_keyblock, (size_t)ssl->pending_keyblksz)); } static void kssl_generate_keyblock(ssl_t *ssl) { uchar_t *ms; size_t mslen = SSL3_MASTER_SECRET_LEN; int hlen = MD5_HASH_LEN; uchar_t *keys = ssl->pending_keyblock; int steps = howmany(ssl->pending_keyblksz, hlen); int i; ms = ssl->sid.master_secret; ASSERT(hlen * steps <= MAX_KEYBLOCK_LENGTH); for (i = 1; i <= steps; i++) { kssl_ssl3_key_material_derive_step(ssl, ms, mslen, i, keys, 1); keys += hlen; } } static char *ssl3_key_derive_seeds[9] = {"A", "BB", "CCC", "DDDD", "EEEEE", "FFFFFF", "GGGGGGG", "HHHHHHHH", "IIIIIIIII"}; static void kssl_ssl3_key_material_derive_step( ssl_t *ssl, uchar_t *secret, size_t secretlen, int step, uchar_t *dst, int sr_first) { SHA1_CTX sha1, *sha1ctx; MD5_CTX md5, *md5ctx; uchar_t sha1_hash[SHA1_HASH_LEN]; sha1ctx = &sha1; md5ctx = &md5; ASSERT(step <= sizeof (ssl3_key_derive_seeds) / sizeof (ssl3_key_derive_seeds[0])); step--; SHA1Init(sha1ctx); SHA1Update(sha1ctx, (uchar_t *)ssl3_key_derive_seeds[step], step + 1); SHA1Update(sha1ctx, secret, secretlen); if (sr_first) { SHA1Update(sha1ctx, ssl->server_random, SSL3_RANDOM_LENGTH); SHA1Update(sha1ctx, ssl->client_random, SSL3_RANDOM_LENGTH); } else { SHA1Update(sha1ctx, ssl->client_random, SSL3_RANDOM_LENGTH); SHA1Update(sha1ctx, ssl->server_random, SSL3_RANDOM_LENGTH); } SHA1Final(sha1_hash, sha1ctx); MD5Init(md5ctx); MD5Update(md5ctx, secret, secretlen); MD5Update(md5ctx, sha1_hash, SHA1_HASH_LEN); MD5Final(dst, md5ctx); } static int kssl_send_certificate_and_server_hello_done(ssl_t *ssl) { int cur_reclen; int mss; int len, copylen; mblk_t *mp; uchar_t *cert_buf; int cert_len; uchar_t *msgbuf; Certificate_t *cert; cert = ssl->kssl_entry->ke_server_certificate; if (cert == NULL) { return (ENOENT); } cert_buf = cert->msg; cert_len = cert->len; mp = ssl->handshake_sendbuf; mss = ssl->tcp_mss; ASSERT(mp != NULL); cur_reclen = mp->b_wptr - mp->b_rptr - SSL3_HDR_LEN; ASSERT(cur_reclen == KSSL_SSL3_SH_RECLEN); /* Assume MSS is at least 80 bytes */ ASSERT(mss > cur_reclen + SSL3_HDR_LEN); ASSERT(cur_reclen < SSL3_MAX_RECORD_LENGTH); /* XXX */ copylen = mss - (cur_reclen + SSL3_HDR_LEN); len = cert_len; copylen = MIN(copylen, len); copylen = MIN(copylen, SSL3_MAX_RECORD_LENGTH - cur_reclen); /* new record always starts in a new mblk for simplicity */ msgbuf = cert_buf; for (;;) { ASSERT(mp->b_wptr + copylen <= mp->b_datap->db_lim); bcopy(msgbuf, mp->b_wptr, copylen); msgbuf += copylen; mp->b_wptr += copylen; cur_reclen += copylen; len -= copylen; if (len == 0) { break; } if (cur_reclen == SSL3_MAX_RECORD_LENGTH) { cur_reclen = 0; } copylen = MIN(len, mss); copylen = MIN(copylen, SSL3_MAX_RECORD_LENGTH - cur_reclen); mp->b_cont = allocb(copylen, BPRI_HI); if (mp->b_cont == NULL) { KSSL_COUNTER(alloc_fails, 1); freemsg(ssl->handshake_sendbuf); ssl->handshake_sendbuf = NULL; return (ENOMEM); } mp = mp->b_cont; if (cur_reclen == 0) { mp->b_wptr[0] = content_handshake; mp->b_wptr[1] = ssl->major_version; mp->b_wptr[2] = ssl->minor_version; cur_reclen = MIN(len, SSL3_MAX_RECORD_LENGTH); mp->b_wptr[3] = (cur_reclen >> 8) & 0xff; mp->b_wptr[4] = (cur_reclen) & 0xff; mp->b_wptr += SSL3_HDR_LEN; cur_reclen = 0; copylen = MIN(copylen, mss - SSL3_HDR_LEN); } } /* adjust the record length field for the first record */ mp = ssl->handshake_sendbuf; cur_reclen = MIN(KSSL_SSL3_SH_RECLEN + cert_len, SSL3_MAX_RECORD_LENGTH); mp->b_rptr[3] = (cur_reclen >> 8) & 0xff; mp->b_rptr[4] = (cur_reclen) & 0xff; kssl_update_handshake_hashes(ssl, cert_buf, cert_len); return (0); } static int kssl_send_change_cipher_specs(ssl_t *ssl) { mblk_t *mp, *newmp; uchar_t *buf; mp = ssl->handshake_sendbuf; /* We're most likely to hit the fast path for resumed sessions */ if ((mp != NULL) && (mp->b_datap->db_lim - mp->b_wptr > KSSL_SSL3_MAX_CCP_FIN_MSGLEN)) { buf = mp->b_wptr; } else { newmp = allocb(KSSL_SSL3_MAX_CCP_FIN_MSGLEN, BPRI_HI); if (newmp == NULL) return (ENOMEM); /* need to do better job! */ if (mp == NULL) { ssl->handshake_sendbuf = newmp; } else { linkb(ssl->handshake_sendbuf, newmp); } mp = newmp; buf = mp->b_rptr; } /* 5 byte record header */ buf[0] = content_change_cipher_spec; buf[1] = ssl->major_version; buf[2] = ssl->minor_version; buf[3] = 0; buf[4] = 1; buf += SSL3_HDR_LEN; buf[0] = 1; mp->b_wptr = buf + 1; ASSERT(mp->b_wptr < mp->b_datap->db_lim); ssl->seq_num[KSSL_WRITE] = 0; return (kssl_spec_init(ssl, KSSL_WRITE)); } int kssl_spec_init(ssl_t *ssl, int dir) { KSSL_HASHCTX *ctx; KSSLCipherSpec *spec = &ssl->spec[dir]; int ret = 0; spec->mac_hashsz = mac_defs[ssl->pending_malg].hashsz; spec->mac_padsz = mac_defs[ssl->pending_malg].padsz; spec->MAC_HashInit = mac_defs[ssl->pending_malg].HashInit; spec->MAC_HashUpdate = mac_defs[ssl->pending_malg].HashUpdate; spec->MAC_HashFinal = mac_defs[ssl->pending_malg].HashFinal; if (dir == KSSL_READ) { bcopy(ssl->pending_keyblock, ssl->mac_secret[dir], spec->mac_hashsz); } else { bcopy(&(ssl->pending_keyblock[spec->mac_hashsz]), ssl->mac_secret[dir], spec->mac_hashsz); } /* Pre-compute these here. will save cycles on each record later */ if (!IS_TLS(ssl)) { ctx = &ssl->mac_ctx[dir][0]; spec->MAC_HashInit((void *)ctx); spec->MAC_HashUpdate((void *)ctx, ssl->mac_secret[dir], spec->mac_hashsz); spec->MAC_HashUpdate((void *)ctx, kssl_pad_1, spec->mac_padsz); ctx = &ssl->mac_ctx[dir][1]; spec->MAC_HashInit((void *)ctx); spec->MAC_HashUpdate((void *)ctx, ssl->mac_secret[dir], spec->mac_hashsz); spec->MAC_HashUpdate((void *)ctx, kssl_pad_2, spec->mac_padsz); } spec->cipher_type = cipher_defs[ssl->pending_calg].type; spec->cipher_mech.cm_type = cipher_defs[ssl->pending_calg].mech_type; spec->cipher_bsize = cipher_defs[ssl->pending_calg].bsize; spec->cipher_keysz = cipher_defs[ssl->pending_calg].keysz; if (spec->cipher_ctx != NULL) { crypto_cancel_ctx(spec->cipher_ctx); spec->cipher_ctx = 0; } /* * Initialize HMAC keys for TLS and SSL3 HMAC keys * for SSL 3.0. */ if (IS_TLS(ssl)) { if (ssl->pending_malg == mac_md5) { spec->hmac_mech = hmac_md5_mech; } else if (ssl->pending_malg == mac_sha) { spec->hmac_mech = hmac_sha1_mech; } spec->hmac_key.ck_format = CRYPTO_KEY_RAW; spec->hmac_key.ck_data = ssl->mac_secret[dir]; spec->hmac_key.ck_length = spec->mac_hashsz * 8; } else { static uint32_t param; spec->hmac_mech.cm_type = CRYPTO_MECH_INVALID; spec->hmac_mech.cm_param = (caddr_t)¶m; spec->hmac_mech.cm_param_len = sizeof (param); if (ssl->pending_malg == mac_md5) { spec->hmac_mech.cm_type = crypto_mech2id("CKM_SSL3_MD5_MAC"); param = MD5_HASH_LEN; } else if (ssl->pending_malg == mac_sha) { spec->hmac_mech.cm_type = crypto_mech2id("CKM_SSL3_SHA1_MAC"); param = SHA1_HASH_LEN; } spec->hmac_key.ck_format = CRYPTO_KEY_RAW; spec->hmac_key.ck_data = ssl->mac_secret[dir]; spec->hmac_key.ck_length = spec->mac_hashsz * 8; } /* We're done if this is the nil cipher */ if (spec->cipher_keysz == 0) { return (0); } /* Initialize the key and the active context */ spec->cipher_key.ck_format = CRYPTO_KEY_RAW; spec->cipher_key.ck_length = 8 * spec->cipher_keysz; /* in bits */ if (cipher_defs[ssl->pending_calg].bsize > 0) { /* client_write_IV */ spec->cipher_mech.cm_param = (caddr_t)&(ssl->pending_keyblock[2 * spec->mac_hashsz + 2 * spec->cipher_keysz]); spec->cipher_mech.cm_param_len = spec->cipher_bsize; } spec->cipher_data.cd_format = CRYPTO_DATA_RAW; if (dir == KSSL_READ) { spec->cipher_mech.cm_param_len = cipher_defs[ssl->pending_calg].bsize; /* client_write_key */ spec->cipher_key.ck_data = &(ssl->pending_keyblock[2 * spec->mac_hashsz]); ret = crypto_decrypt_init(&(spec->cipher_mech), &(spec->cipher_key), NULL, &spec->cipher_ctx, NULL); if (CRYPTO_ERR(ret)) { DTRACE_PROBE1(kssl_err__crypto_decrypt_init_read, int, ret); } } else { if (cipher_defs[ssl->pending_calg].bsize > 0) { /* server_write_IV */ spec->cipher_mech.cm_param += spec->cipher_bsize; } /* server_write_key */ spec->cipher_key.ck_data = &(ssl->pending_keyblock[2 * spec->mac_hashsz + spec->cipher_keysz]); ret = crypto_encrypt_init(&(spec->cipher_mech), &(spec->cipher_key), NULL, &spec->cipher_ctx, NULL); if (CRYPTO_ERR(ret)) DTRACE_PROBE1(kssl_err__crypto_encrypt_init_non_read, int, ret); } return (ret); } static int kssl_send_finished(ssl_t *ssl, int update_hsh) { mblk_t *mp; uchar_t *buf; uchar_t *rstart; uchar_t *versionp; SSL3Hashes ssl3hashes; size_t finish_len; int ret; mp = ssl->handshake_sendbuf; ASSERT(mp != NULL); buf = mp->b_wptr; ASSERT(buf - mp->b_rptr == SSL3_HDR_LEN + KSSL_SSL3_SH_RECLEN + SSL3_HDR_LEN + 1 || buf - mp->b_rptr == SSL3_HDR_LEN + 1); rstart = buf; if (IS_TLS(ssl)) finish_len = TLS_FINISHED_SIZE; else finish_len = KSSL_SSL3_FIN_MSGLEN; /* 5 byte record header */ buf[0] = content_handshake; buf[1] = ssl->major_version; buf[2] = ssl->minor_version; buf[3] = 0; buf[4] = 4 + finish_len; versionp = &buf[1]; buf += SSL3_HDR_LEN; /* 4 byte message header */ buf[0] = (uchar_t)finished; /* message type */ buf[1] = 0; /* message len byte 0 */ buf[2] = 0; /* message len byte 1 */ buf[3] = finish_len; /* message len byte 2 */ buf += 4; if (IS_TLS(ssl)) { bcopy(ssl->hs_hashes.md5, ssl3hashes.md5, sizeof (ssl3hashes.md5)); bcopy(ssl->hs_hashes.sha1, ssl3hashes.sha1, sizeof (ssl3hashes.sha1)); } /* Compute hashes for the SENDER side */ ret = kssl_compute_handshake_hashes(ssl, &ssl3hashes, sender_server); if (ret != 0) return (ret); if (IS_TLS(ssl)) { bcopy(ssl3hashes.tlshash, buf, sizeof (ssl3hashes.tlshash)); } else { bcopy(ssl3hashes.md5, buf, MD5_HASH_LEN); bcopy(ssl3hashes.sha1, buf + MD5_HASH_LEN, SHA1_HASH_LEN); } if (update_hsh) { kssl_update_handshake_hashes(ssl, buf - 4, finish_len + 4); } mp->b_wptr = buf + finish_len; ret = kssl_mac_encrypt_record(ssl, content_handshake, versionp, rstart, mp); ASSERT(mp->b_wptr <= mp->b_datap->db_lim); return (ret); } int kssl_mac_encrypt_record(ssl_t *ssl, SSL3ContentType ct, uchar_t *versionp, uchar_t *rstart, mblk_t *mp) { KSSLCipherSpec *spec; int mac_sz; int ret = 0; uint16_t rec_sz; int pad_sz; int i; ASSERT(ssl != NULL); ASSERT(rstart >= mp->b_rptr); ASSERT(rstart < mp->b_wptr); spec = &ssl->spec[KSSL_WRITE]; mac_sz = spec->mac_hashsz; rec_sz = (mp->b_wptr - rstart) - SSL3_HDR_LEN; ASSERT(rec_sz > 0); if (mac_sz != 0) { ASSERT(mp->b_wptr + mac_sz <= mp->b_datap->db_lim); ret = kssl_compute_record_mac(ssl, KSSL_WRITE, ssl->seq_num[KSSL_WRITE], ct, versionp, rstart + SSL3_HDR_LEN, rec_sz, mp->b_wptr); if (ret == CRYPTO_SUCCESS) { ssl->seq_num[KSSL_WRITE]++; mp->b_wptr += mac_sz; rec_sz += mac_sz; } else { return (ret); } } if (spec->cipher_type == type_block) { pad_sz = spec->cipher_bsize - (rec_sz & (spec->cipher_bsize - 1)); ASSERT(mp->b_wptr + pad_sz <= mp->b_datap->db_lim); for (i = 0; i < pad_sz; i++) { mp->b_wptr[i] = pad_sz - 1; } mp->b_wptr += pad_sz; rec_sz += pad_sz; } ASSERT(rec_sz <= SSL3_MAX_RECORD_LENGTH); U16_TO_BE16(rec_sz, rstart + 3); if (spec->cipher_ctx == 0) return (ret); spec->cipher_data.cd_length = rec_sz; spec->cipher_data.cd_raw.iov_base = (char *)(rstart + SSL3_HDR_LEN); spec->cipher_data.cd_raw.iov_len = rec_sz; /* One record at a time. Otherwise, gotta allocate the crypt_data_t */ ret = crypto_encrypt_update(spec->cipher_ctx, &spec->cipher_data, NULL, NULL); if (CRYPTO_ERR(ret)) { DTRACE_PROBE1(kssl_err__crypto_encrypt_update, int, ret); } return (ret); } void kssl_send_alert(ssl_t *ssl, SSL3AlertLevel level, SSL3AlertDescription desc) { mblk_t *mp; uchar_t *buf; KSSLCipherSpec *spec; ASSERT(ssl != NULL); ssl->sendalert_level = level; ssl->sendalert_desc = desc; if (level == alert_fatal) { DTRACE_PROBE2(kssl_sending_alert, SSL3AlertLevel, level, SSL3AlertDescription, desc); if (ssl->sid.cached == B_TRUE) { kssl_uncache_sid(&ssl->sid, ssl->kssl_entry); } ssl->fatal_alert = B_TRUE; KSSL_COUNTER(fatal_alerts, 1); } else KSSL_COUNTER(warning_alerts, 1); spec = &ssl->spec[KSSL_WRITE]; ASSERT(ssl->alert_sendbuf == NULL); ssl->alert_sendbuf = mp = allocb(7 + spec->mac_hashsz + spec->cipher_bsize, BPRI_HI); if (mp == NULL) { KSSL_COUNTER(alloc_fails, 1); return; } buf = mp->b_wptr; /* 5 byte record header */ buf[0] = content_alert; buf[1] = ssl->major_version; buf[2] = ssl->minor_version; buf[3] = 0; buf[4] = 2; buf += SSL3_HDR_LEN; /* alert contents */ buf[0] = (uchar_t)level; buf[1] = (uchar_t)desc; mp->b_wptr = buf + 2; } /* Assumes RSA encryption */ static int kssl_handle_client_key_exchange(ssl_t *ssl, mblk_t *mp, int msglen, kssl_callback_t cbfn, void *arg) { char *buf; uchar_t *pms; size_t pmslen; int allocated; int err, rverr = ENOMEM; kssl_entry_t *ep; crypto_key_t *privkey; crypto_data_t *wrapped_pms_data, *pms_data; crypto_call_req_t creq, *creqp; ep = ssl->kssl_entry; privkey = ep->ke_private_key; if (privkey == NULL) { return (ENOENT); } ASSERT(ssl->msg.type == client_key_exchange); ASSERT(ssl->hs_waitstate == wait_client_key); /* * TLS adds an extra 2 byte length field before the data. */ if (IS_TLS(ssl)) { msglen = (mp->b_rptr[0] << 8) | mp->b_rptr[1]; mp->b_rptr += 2; } /* * Allocate all we need in one shot. about 300 bytes total, for * 1024 bit RSA modulus. * The buffer layout will be: pms_data, wrapped_pms_data, the * value of the wrapped pms from the client, then room for the * resulting decrypted premaster secret. */ allocated = 2 * (sizeof (crypto_data_t) + msglen); buf = kmem_alloc(allocated, KM_NOSLEEP); if (buf == NULL) { return (ENOMEM); } pms_data = (crypto_data_t *)buf; wrapped_pms_data = &(((crypto_data_t *)buf)[1]); wrapped_pms_data->cd_format = pms_data->cd_format = CRYPTO_DATA_RAW; wrapped_pms_data->cd_offset = pms_data->cd_offset = 0; wrapped_pms_data->cd_length = pms_data->cd_length = msglen; wrapped_pms_data->cd_miscdata = pms_data->cd_miscdata = NULL; wrapped_pms_data->cd_raw.iov_len = pms_data->cd_raw.iov_len = msglen; wrapped_pms_data->cd_raw.iov_base = buf + 2 * sizeof (crypto_data_t); pms_data->cd_raw.iov_base = wrapped_pms_data->cd_raw.iov_base + msglen; bcopy(mp->b_rptr, wrapped_pms_data->cd_raw.iov_base, msglen); mp->b_rptr += msglen; /* Proceed synchronously if out of interrupt and configured to do so */ if ((kssl_synchronous) && (!servicing_interrupt())) { creqp = NULL; } else { ssl->cke_callback_func = cbfn; ssl->cke_callback_arg = arg; creq.cr_flag = kssl_call_flag; creq.cr_callback_func = kssl_cke_done; creq.cr_callback_arg = ssl; /* The callback routine will release this one */ KSSL_SSL_REFHOLD(ssl); creqp = &creq; } if (ep->ke_is_nxkey) { kssl_session_info_t *s; s = ep->ke_sessinfo; err = CRYPTO_SUCCESS; if (!s->is_valid_handle) { /* Reauthenticate to the provider */ if (s->do_reauth) { err = kssl_get_obj_handle(ep); if (err == CRYPTO_SUCCESS) { s->is_valid_handle = B_TRUE; s->do_reauth = B_FALSE; } } else err = CRYPTO_FAILED; } if (err == CRYPTO_SUCCESS) { ASSERT(s->is_valid_handle); err = crypto_decrypt_prov(s->prov, s->sid, &rsa_x509_mech, wrapped_pms_data, &s->key, NULL, pms_data, creqp); } /* * Deal with session specific errors. We translate to * the closest errno. */ switch (err) { case CRYPTO_KEY_HANDLE_INVALID: case CRYPTO_SESSION_HANDLE_INVALID: s->is_valid_handle = B_FALSE; s->do_reauth = B_TRUE; rverr = EINVAL; break; case CRYPTO_PIN_EXPIRED: case CRYPTO_PIN_LOCKED: rverr = EACCES; break; case CRYPTO_UNKNOWN_PROVIDER: rverr = ENXIO; break; } } else { err = crypto_decrypt(&rsa_x509_mech, wrapped_pms_data, privkey, NULL, pms_data, creqp); } switch (err) { case CRYPTO_SUCCESS: break; case CRYPTO_QUEUED: /* * Finish the master secret then the rest of key material * derivation later. */ ssl->job.kjob = creq.cr_reqid; ssl->job.buf = buf; ssl->job.buflen = allocated; ssl->hs_waitstate = wait_client_key_done; return (0); default: DTRACE_PROBE1(kssl_err__crypto_decrypt, int, err); kmem_free(buf, allocated); return (rverr); } pmslen = pms_data->cd_length; pms = kssl_rsa_unwrap((uchar_t *)pms_data->cd_raw.iov_base, &pmslen); /* generate master key and save it in the ssl sid structure */ if (IS_TLS(ssl)) { err = kssl_generate_tls_ms(ssl, pms, pmslen); if (!CRYPTO_ERR(err)) err = kssl_generate_tls_keyblock(ssl); } else { kssl_generate_ssl_ms(ssl, pms, pmslen); kssl_generate_keyblock(ssl); } if (err == CRYPTO_SUCCESS) ssl->hs_waitstate = wait_change_cipher; ssl->activeinput = B_FALSE; kmem_free(buf, allocated); return (0); } static int kssl_handle_finished(ssl_t *ssl, mblk_t *mp, int msglen) { int err; size_t finish_len; int hashcompare; ASSERT(ssl->msg.type == finished); ASSERT(ssl->hs_waitstate == wait_finished); if (IS_TLS(ssl)) finish_len = TLS_FINISHED_SIZE; else finish_len = KSSL_SSL3_FIN_MSGLEN; if (msglen != finish_len) { kssl_send_alert(ssl, alert_fatal, illegal_parameter); return (EBADMSG); } if (IS_TLS(ssl)) { hashcompare = bcmp(mp->b_rptr, ssl->hs_hashes.tlshash, finish_len); } else { hashcompare = bcmp(mp->b_rptr, &ssl->hs_hashes, finish_len); } /* The handshake hashes should be computed by now */ if (hashcompare != 0) { kssl_send_alert(ssl, alert_fatal, handshake_failure); return (EBADMSG); } mp->b_rptr += msglen; ssl->hs_waitstate = idle_handshake; if (ssl->resumed == B_TRUE) { ssl->activeinput = B_FALSE; return (0); } err = kssl_send_change_cipher_specs(ssl); if (err != 0) { return (err); } err = kssl_send_finished(ssl, 0); if (err != 0) { return (err); } kssl_cache_sid(&ssl->sid, ssl->kssl_entry); ssl->activeinput = B_FALSE; return (0); } #define KSSL2_CH_MIN_RECSZ (9) /* * This method is needed to handle clients which send the * SSLv2/SSLv3 handshake for backwards compat with SSLv2 servers. * We are not really doing SSLv2 here, just handling the header * and then switching to SSLv3. */ int kssl_handle_v2client_hello(ssl_t *ssl, mblk_t *mp, int recsz) { uchar_t *recend; int err; SSL3AlertDescription desc = illegal_parameter; uint_t randlen; uint_t sidlen; uint_t cslen; uchar_t *suitesp; uchar_t *rand; uint_t i, j; uint16_t suite; int ch_recsz = KSSL2_CH_MIN_RECSZ; ASSERT(mp->b_wptr >= mp->b_rptr + recsz); ASSERT(ssl->hs_waitstate == wait_client_hello); ASSERT(ssl->resumed == B_FALSE); if (recsz < ch_recsz) { goto falert; } MD5Init(&ssl->hs_md5); SHA1Init(&ssl->hs_sha1); kssl_update_handshake_hashes(ssl, mp->b_rptr, recsz); recend = mp->b_rptr + recsz; if (*mp->b_rptr != 1) { goto falert; } mp->b_rptr += 3; cslen = ((uint_t)mp->b_rptr[0] << 8) + (uint_t)mp->b_rptr[1]; sidlen = ((uint_t)mp->b_rptr[2] << 8) + (uint_t)mp->b_rptr[3]; randlen = ((uint_t)mp->b_rptr[4] << 8) + (uint_t)mp->b_rptr[5]; if (cslen % 3 != 0) { DTRACE_PROBE1(kssl_err__cipher_suites_len_error, uint_t, cslen); goto falert; } if (randlen < SSL_MIN_CHALLENGE_BYTES || randlen > SSL_MAX_CHALLENGE_BYTES) { DTRACE_PROBE1(kssl_err__randlen_out_of_range, uint_t, randlen); goto falert; } mp->b_rptr += 6; ch_recsz += cslen + sidlen + randlen; if (recsz != ch_recsz) { goto falert; } suitesp = mp->b_rptr; rand = suitesp + cslen + sidlen; if (randlen < SSL3_RANDOM_LENGTH) { bzero(ssl->client_random, SSL3_RANDOM_LENGTH); } bcopy(rand, &ssl->client_random[SSL3_RANDOM_LENGTH - randlen], randlen); for (i = 0; i < ssl->kssl_entry->kssl_cipherSuites_nentries; i++) { suite = ssl->kssl_entry->kssl_cipherSuites[i]; for (j = 0; j < cslen; j += 3) { if (suitesp[j] != 0) { continue; } if (suitesp[j + 1] == ((suite >> 8) & 0xff) && suitesp[j + 2] == (suite & 0xff)) { break; } } if (j < cslen) { break; } } if (i == ssl->kssl_entry->kssl_cipherSuites_nentries) { DTRACE_PROBE(kssl_err__no_SSLv2_cipher_suite); ssl->activeinput = B_FALSE; return (SSL_MISS); } mp->b_rptr = recend; for (i = 0; i < cipher_suite_defs_nentries; i++) { if (suite == cipher_suite_defs[i].suite) { break; } } ASSERT(i < cipher_suite_defs_nentries); ssl->pending_cipher_suite = suite; ssl->pending_malg = cipher_suite_defs[i].malg; ssl->pending_calg = cipher_suite_defs[i].calg; ssl->pending_keyblksz = cipher_suite_defs[i].keyblksz; ASSERT(ssl->sid.cached == B_FALSE); (void) random_get_pseudo_bytes(ssl->sid.session_id, SSL3_SESSIONID_BYTES); ssl->sid.client_addr = ssl->faddr; ssl->sid.cipher_suite = suite; err = kssl_send_server_hello(ssl); if (err != 0) { return (err); } err = kssl_send_certificate_and_server_hello_done(ssl); if (err != 0) { return (err); } KSSL_COUNTER(full_handshakes, 1); ssl->hs_waitstate = wait_client_key; ssl->activeinput = B_FALSE; return (0); falert: kssl_send_alert(ssl, alert_fatal, desc); ssl->activeinput = B_FALSE; return (EBADMSG); } /* * Call back routine for asynchronously submitted RSA decryption jobs. * This routine retrieves the pre-master secret, and proceeds to generate * the remaining key materials. */ static void kssl_cke_done(void *arg, int status) { int ret = 0; uchar_t *pms; size_t pmslen; crypto_data_t *pms_data; kssl_cmd_t kssl_cmd = KSSL_CMD_NONE; ssl_t *ssl = (ssl_t *)arg; mblk_t *alertmp; kssl_callback_t cbfn; void *cbarg; mutex_enter(&ssl->kssl_lock); ASSERT(ssl->msg.type == client_key_exchange); ASSERT(ssl->hs_waitstate == wait_client_key_done); if (status != CRYPTO_SUCCESS) { kssl_send_alert(ssl, alert_fatal, decrypt_error); kssl_cmd = KSSL_CMD_SEND; goto out; } pms_data = (crypto_data_t *)(ssl->job.buf); ASSERT(pms_data != NULL); pmslen = pms_data->cd_length; pms = kssl_rsa_unwrap((uchar_t *)pms_data->cd_raw.iov_base, &pmslen); /* generate master key and save it in the ssl sid structure */ if (IS_TLS(ssl)) { ret = kssl_generate_tls_ms(ssl, pms, pmslen); if (!CRYPTO_ERR(ret)) ret = kssl_generate_tls_keyblock(ssl); } else { kssl_generate_ssl_ms(ssl, pms, pmslen); kssl_generate_keyblock(ssl); } if (ret == CRYPTO_SUCCESS) ssl->hs_waitstate = wait_change_cipher; out: kmem_free(ssl->job.buf, ssl->job.buflen); ssl->job.kjob = 0; ssl->job.buf = NULL; ssl->job.buflen = 0; ssl->activeinput = B_FALSE; /* If we're the only ones left, then we won't callback */ if (ssl->kssl_refcnt == 1) { mutex_exit(&ssl->kssl_lock); KSSL_SSL_REFRELE(ssl); return; } cbfn = ssl->cke_callback_func; cbarg = ssl->cke_callback_arg; alertmp = ssl->alert_sendbuf; ssl->alert_sendbuf = NULL; mutex_exit(&ssl->kssl_lock); KSSL_SSL_REFRELE(ssl); /* Now call the callback routine */ (*(cbfn))(cbarg, alertmp, kssl_cmd); } /* * Returns the first complete contiguous record out of rec_ass_head * The record is returned in a separate contiguous mblk, rec_ass_head is * left pointing to the next record in the queue. * * The output looks as follows: * * |--------|---------- .... -----|<---------->|<----------->|--- ... ---| * ^ ^ ^ mac_size pad_size ^ * | |___ b_rptr b_wptr __| | * | | * |___ db_base db_lim ___| */ mblk_t * kssl_get_next_record(ssl_t *ssl) { mblk_t *mp, *retmp; int rhsz = SSL3_HDR_LEN; uint16_t rec_sz; int mpsz, total_size; SSL3ContentType content_type; ASSERT(MUTEX_HELD(&ssl->kssl_lock)); mp = ssl->rec_ass_head; if (mp == NULL) return (NULL); /* Fast path: when mp has at least a complete record */ if (MBLKL(mp) < rhsz) { DTRACE_PROBE1(kssl_mblk__incomplete_header, mblk_t *, mp); /* Not even a complete header in there yet */ if (msgdsize(mp) < rhsz) { return (NULL); } if (!pullupmsg(mp, rhsz)) { kssl_send_alert(ssl, alert_fatal, internal_error); freemsg(mp); ssl->rec_ass_head = ssl->rec_ass_tail = NULL; return (NULL); } } content_type = (SSL3ContentType)mp->b_rptr[0]; if (content_type == content_handshake_v2) { DTRACE_PROBE1(kssl_mblk__ssl_v2, mblk_t *, mp); rec_sz = (uint16_t)mp->b_rptr[1]; rhsz = 2; } else { DTRACE_PROBE1(kssl_mblk__ssl_v3, mblk_t *, mp); uint8_t *rec_sz_p = (uint8_t *)mp->b_rptr + 3; rec_sz = BE16_TO_U16(rec_sz_p); } /* * same tests as above. Only rare very fragmented cases will * incur the cost of msgdsize() and msgpullup(). Well formed * packets will fall in the most frequent fast path. */ total_size = rhsz + rec_sz; /* * Missing: defensive against record fabricated with longer than * MAX record length. */ if (MBLKL(mp) < total_size) { DTRACE_PROBE2(kssl_mblk__smaller_than_total_size, mblk_t *, mp, int, total_size); /* Not a complete record yet. Keep accumulating */ if (msgdsize(mp) < total_size) { return (NULL); } if (!pullupmsg(mp, total_size)) { kssl_send_alert(ssl, alert_fatal, internal_error); freemsg(mp); ssl->rec_ass_head = ssl->rec_ass_tail = NULL; return (NULL); } } mpsz = MBLKL(mp); /* could've changed after the pullup */ if (mpsz > total_size) { DTRACE_PROBE2(kssl_mblk__bigger_than_total_size, mblk_t *, mp, int, total_size); /* gotta allocate a new block */ if ((retmp = dupb(mp)) == NULL) { kssl_send_alert(ssl, alert_fatal, internal_error); freemsg(mp); ssl->rec_ass_head = ssl->rec_ass_tail = NULL; return (NULL); } retmp->b_wptr = retmp->b_rptr + total_size; mp->b_rptr += total_size; ssl->rec_ass_head = mp; } else { DTRACE_PROBE2(kssl_mblk__equal_to_total_size, mblk_t *, mp, int, total_size); ASSERT(mpsz == total_size); ssl->rec_ass_head = mp->b_cont; mp->b_cont = NULL; retmp = mp; } /* Adjust the tail */ if ((mp = ssl->rec_ass_tail = ssl->rec_ass_head) != NULL) { for (; mp->b_cont != NULL; mp = mp->b_cont) { ssl->rec_ass_tail = mp->b_cont; } } return (retmp); } static void kssl_mblksfree(ssl_t *ssl) { ASSERT(ssl != NULL); if (ssl->rec_ass_head != NULL) { freemsg(ssl->rec_ass_head); } ssl->rec_ass_head = NULL; ssl->rec_ass_tail = NULL; if (ssl->msg.head != NULL) { freemsg(ssl->msg.head); } ssl->msg.head = NULL; ssl->msg.tail = NULL; if (ssl->handshake_sendbuf != NULL) { freemsg(ssl->handshake_sendbuf); ssl->handshake_sendbuf = NULL; } if (ssl->alert_sendbuf != NULL) { freemsg(ssl->alert_sendbuf); ssl->alert_sendbuf = NULL; } } static void kssl_specsfree(ssl_t *ssl) { KSSLCipherSpec *spec = &ssl->spec[KSSL_READ]; if (spec->cipher_ctx != NULL) { crypto_cancel_ctx(spec->cipher_ctx); spec->cipher_ctx = 0; } spec = &ssl->spec[KSSL_WRITE]; if (spec->cipher_ctx != NULL) { crypto_cancel_ctx(spec->cipher_ctx); spec->cipher_ctx = 0; } } /* * Frees the ssl structure (aka the context of an SSL session). * Any pending crypto jobs are cancelled. * Any initiated crypto contexts are freed as well. */ void kssl_free_context(ssl_t *ssl) { ASSERT(ssl != NULL); if (!(MUTEX_HELD(&ssl->kssl_lock))) { /* we're coming from an external API entry point */ mutex_enter(&ssl->kssl_lock); } if (ssl->job.kjob != NULL) { crypto_cancel_req(ssl->job.kjob); kmem_free(ssl->job.buf, ssl->job.buflen); ssl->job.kjob = 0; ssl->job.buf = NULL; ssl->job.buflen = 0; } kssl_mblksfree(ssl); kssl_specsfree(ssl); KSSL_ENTRY_REFRELE(ssl->kssl_entry); ssl->kssl_entry = NULL; mutex_exit(&ssl->kssl_lock); kmem_cache_free(kssl_cache, ssl); kssl_cache_count--; }