/* $OpenBSD: ssl.c,v 1.2 2010/05/31 18:29:04 martinh Exp $ */ /* * Copyright (c) 2008 Pierre-Yves Ritschard * Copyright (c) 2008 Reyk Floeter * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ldapd.h" #define SSL_CIPHERS "HIGH" void ssl_error(const char *); char *ssl_load_file(const char *, off_t *); SSL_CTX *ssl_ctx_create(void); void ssl_session_accept(int, short, void *); void ssl_read(int, short, void *); void ssl_write(int, short, void *); int ssl_bufferevent_add(struct event *, int); void ssl_connect(int, short, void *); SSL *ssl_client_init(int, char *, size_t, char *, size_t); int ssl_buf_read(SSL *, struct ibuf_read *); int ssl_buf_write(SSL *, struct msgbuf *); DH *get_dh512(void); void ssl_set_ephemeral_key_exchange(SSL_CTX *); extern void bufferevent_read_pressure_cb(struct evbuffer *, size_t, size_t, void *); /* From OpenSSL's documentation: * * If "strong" primes were used to generate the DH parameters, it is * not strictly necessary to generate a new key for each handshake * but it does improve forward secrecy. * * These are the parameters used by both sendmail and openssl's * s_server. * * -- gilles@ */ unsigned char dh512_p[] = { 0xDA,0x58,0x3C,0x16,0xD9,0x85,0x22,0x89,0xD0,0xE4,0xAF,0x75, 0x6F,0x4C,0xCA,0x92,0xDD,0x4B,0xE5,0x33,0xB8,0x04,0xFB,0x0F, 0xED,0x94,0xEF,0x9C,0x8A,0x44,0x03,0xED,0x57,0x46,0x50,0xD3, 0x69,0x99,0xDB,0x29,0xD7,0x76,0x27,0x6B,0xA2,0xD3,0xD4,0x12, 0xE2,0x18,0xF4,0xDD,0x1E,0x08,0x4C,0xF6,0xD8,0x00,0x3E,0x7C, 0x47,0x74,0xE8,0x33, }; unsigned char dh512_g[] = { 0x02, }; #if 0 void ssl_connect(int fd, short event, void *p) { struct conn *s = p; int ret; int retry_flag; int ssl_err; if (event == EV_TIMEOUT) { log_debug("ssl_connect: session timed out"); conn_close(s); return; } ret = SSL_connect(s->s_ssl); if (ret <= 0) { ssl_err = SSL_get_error(s->s_ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: retry_flag = EV_READ; goto retry; case SSL_ERROR_WANT_WRITE: retry_flag = EV_WRITE; goto retry; case SSL_ERROR_ZERO_RETURN: case SSL_ERROR_SYSCALL: if (ret == 0) { log_debug("session destroy in MTA #1"); conn_close(s); return; } /* FALLTHROUGH */ default: ssl_error("ssl_session_connect"); conn_close(s); return; } } event_set(&s->bev->ev_read, s->fd, EV_READ, ssl_read, s->bev); event_set(&s->bev->ev_write, s->fd, EV_WRITE, ssl_write, s->bev); log_info("ssl_connect: connected to remote ssl server"); bufferevent_enable(s->bev, EV_READ|EV_WRITE); s->s_flags |= F_SECURE; if (s->s_flags & F_PEERHASTLS) { session_respond(s, "EHLO %s", s->s_env->sc_hostname); } return; retry: event_add(&s->s_ev, &s->s_tv); } #endif void ssl_read(int fd, short event, void *p) { struct bufferevent *bufev = p; struct conn *s = bufev->cbarg; int ret; int ssl_err; short what; size_t len; char rbuf[IBUF_READ_SIZE]; int howmuch = IBUF_READ_SIZE; what = EVBUFFER_READ; ret = ssl_err = 0; if (event == EV_TIMEOUT) { what |= EVBUFFER_TIMEOUT; goto err; } if (bufev->wm_read.high != 0) howmuch = MIN(sizeof(rbuf), bufev->wm_read.high); ret = SSL_read(s->s_ssl, rbuf, howmuch); if (ret <= 0) { ssl_err = SSL_get_error(s->s_ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: goto retry; case SSL_ERROR_WANT_WRITE: goto retry; default: if (ret == 0) what |= EVBUFFER_EOF; else { ssl_error("ssl_read"); what |= EVBUFFER_ERROR; } goto err; } } if (evbuffer_add(bufev->input, rbuf, ret) == -1) { what |= EVBUFFER_ERROR; goto err; } ssl_bufferevent_add(&bufev->ev_read, bufev->timeout_read); len = EVBUFFER_LENGTH(bufev->input); if (bufev->wm_read.low != 0 && len < bufev->wm_read.low) return; if (bufev->wm_read.high != 0 && len > bufev->wm_read.high) { struct evbuffer *buf = bufev->input; event_del(&bufev->ev_read); evbuffer_setcb(buf, bufferevent_read_pressure_cb, bufev); return; } if (bufev->readcb != NULL) (*bufev->readcb)(bufev, bufev->cbarg); return; retry: ssl_bufferevent_add(&bufev->ev_read, bufev->timeout_read); return; err: (*bufev->errorcb)(bufev, what, bufev->cbarg); } void ssl_write(int fd, short event, void *p) { struct bufferevent *bufev = p; struct conn *s = bufev->cbarg; int ret; int ssl_err; short what; ret = 0; what = EVBUFFER_WRITE; if (event == EV_TIMEOUT) { what |= EV_TIMEOUT; goto err; } if (EVBUFFER_LENGTH(bufev->output)) { if (s->s_buf == NULL) { s->s_buflen = EVBUFFER_LENGTH(bufev->output); if ((s->s_buf = malloc(s->s_buflen)) == NULL) { what |= EVBUFFER_ERROR; goto err; } memcpy(s->s_buf, EVBUFFER_DATA(bufev->output), s->s_buflen); } ret = SSL_write(s->s_ssl, s->s_buf, s->s_buflen); if (ret <= 0) { ssl_err = SSL_get_error(s->s_ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: goto retry; case SSL_ERROR_WANT_WRITE: goto retry; default: if (ret == 0) what |= EVBUFFER_EOF; else { ssl_error("ssl_write"); what |= EVBUFFER_ERROR; } goto err; } } evbuffer_drain(bufev->output, ret); } if (s->s_buf != NULL) { free(s->s_buf); s->s_buf = NULL; s->s_buflen = 0; } if (EVBUFFER_LENGTH(bufev->output) != 0) ssl_bufferevent_add(&bufev->ev_write, bufev->timeout_write); if (bufev->writecb != NULL && EVBUFFER_LENGTH(bufev->output) <= bufev->wm_write.low) (*bufev->writecb)(bufev, bufev->cbarg); return; retry: if (s->s_buflen != 0) ssl_bufferevent_add(&bufev->ev_write, bufev->timeout_write); return; err: if (s->s_buf != NULL) { free(s->s_buf); s->s_buf = NULL; s->s_buflen = 0; } (*bufev->errorcb)(bufev, what, bufev->cbarg); } int ssl_bufferevent_add(struct event *ev, int timeout) { struct timeval tv; struct timeval *ptv = NULL; if (timeout) { timerclear(&tv); tv.tv_sec = timeout; ptv = &tv; } return (event_add(ev, ptv)); } int ssl_cmp(struct ssl *s1, struct ssl *s2) { return (strcmp(s1->ssl_name, s2->ssl_name)); } SPLAY_GENERATE(ssltree, ssl, ssl_nodes, ssl_cmp); char * ssl_load_file(const char *name, off_t *len) { struct stat st; off_t size; char *buf = NULL; int fd; if ((fd = open(name, O_RDONLY)) == -1) return (NULL); if (fstat(fd, &st) != 0) goto fail; size = st.st_size; if ((buf = calloc(1, size + 1)) == NULL) goto fail; if (read(fd, buf, size) != size) goto fail; close(fd); *len = size + 1; return (buf); fail: if (buf != NULL) free(buf); close(fd); return (NULL); } SSL_CTX * ssl_ctx_create(void) { SSL_CTX *ctx; ctx = SSL_CTX_new(SSLv23_method()); if (ctx == NULL) { ssl_error("ssl_ctx_create"); fatal("ssl_ctx_create: could not create SSL context"); } SSL_CTX_set_session_cache_mode(ctx, SSL_SESS_CACHE_OFF); SSL_CTX_set_timeout(ctx, LDAPD_SESSION_TIMEOUT); SSL_CTX_set_options(ctx, SSL_OP_ALL); SSL_CTX_set_options(ctx, SSL_OP_NO_SESSION_RESUMPTION_ON_RENEGOTIATION); if (!SSL_CTX_set_cipher_list(ctx, SSL_CIPHERS)) { ssl_error("ssl_ctx_create"); fatal("ssl_ctx_create: could not set cipher list"); } return (ctx); } int ssl_load_certfile(struct ldapd_config *env, const char *name, u_int8_t flags) { struct ssl *s; struct ssl key; char certfile[PATH_MAX]; if (strlcpy(key.ssl_name, name, sizeof(key.ssl_name)) >= sizeof(key.ssl_name)) { log_warn("ssl_load_certfile: certificate name truncated"); return -1; } s = SPLAY_FIND(ssltree, env->sc_ssl, &key); if (s != NULL) { s->flags |= flags; return 0; } if ((s = calloc(1, sizeof(*s))) == NULL) fatal(NULL); s->flags = flags; (void)strlcpy(s->ssl_name, key.ssl_name, sizeof(s->ssl_name)); if ((name[0] == '/' && !bsnprintf(certfile, sizeof(certfile), "%s.crt", name)) || !bsnprintf(certfile, sizeof(certfile), "/etc/ldap/certs/%s.crt", name)) { log_warn("ssl_load_certfile: path truncated"); free(s); return -1; } log_debug("loading certificate file %s", certfile); if ((s->ssl_cert = ssl_load_file(certfile, &s->ssl_cert_len)) == NULL) { free(s); return (-1); } if ((name[0] == '/' && !bsnprintf(certfile, sizeof(certfile), "%s.key", name)) || !bsnprintf(certfile, sizeof(certfile), "/etc/ldap/certs/%s.key", name)) { log_warn("ssl_load_certfile: path truncated"); free(s->ssl_cert); free(s); return -1; } log_debug("loading key file %s", certfile); if ((s->ssl_key = ssl_load_file(certfile, &s->ssl_key_len)) == NULL) { free(s->ssl_cert); free(s); return (-1); } SPLAY_INSERT(ssltree, env->sc_ssl, s); return (0); } void ssl_init(void) { SSL_library_init(); SSL_load_error_strings(); OpenSSL_add_all_algorithms(); /* Init hardware crypto engines. */ ENGINE_load_builtin_engines(); ENGINE_register_all_complete(); } void ssl_setup(struct ldapd_config *env, struct listener *l) { struct ssl key; if (!(l->flags & F_SSL)) return; if (strlcpy(key.ssl_name, l->ssl_cert_name, sizeof(key.ssl_name)) >= sizeof(key.ssl_name)) fatal("ssl_setup: certificate name truncated"); if ((l->ssl = SPLAY_FIND(ssltree, env->sc_ssl, &key)) == NULL) fatal("ssl_setup: certificate tree corrupted"); l->ssl_ctx = ssl_ctx_create(); if (!ssl_ctx_use_certificate_chain(l->ssl_ctx, l->ssl->ssl_cert, l->ssl->ssl_cert_len)) goto err; if (!ssl_ctx_use_private_key(l->ssl_ctx, l->ssl->ssl_key, l->ssl->ssl_key_len)) goto err; if (!SSL_CTX_check_private_key(l->ssl_ctx)) goto err; if (!SSL_CTX_set_session_id_context(l->ssl_ctx, (const unsigned char *)l->ssl_cert_name, strlen(l->ssl_cert_name) + 1)) goto err; ssl_set_ephemeral_key_exchange(l->ssl_ctx); log_debug("ssl_setup: ssl setup finished for listener: %p", l); return; err: if (l->ssl_ctx != NULL) SSL_CTX_free(l->ssl_ctx); ssl_error("ssl_setup"); fatal("ssl_setup: cannot set SSL up"); return; } void ssl_error(const char *where) { unsigned long code; char errbuf[128]; extern int debug; if (!debug) return; for (; (code = ERR_get_error()) != 0 ;) { ERR_error_string_n(code, errbuf, sizeof(errbuf)); log_debug("SSL library error: %s: %s", where, errbuf); } } void ssl_session_accept(int fd, short event, void *p) { struct conn *s = p; int ret; int retry_flag; int ssl_err; if (event == EV_TIMEOUT) { log_debug("ssl_session_accept: session timed out"); conn_close(s); return; } retry_flag = ssl_err = 0; log_debug("ssl_session_accept: accepting client"); ret = SSL_accept(s->s_ssl); if (ret <= 0) { ssl_err = SSL_get_error(s->s_ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: retry_flag = EV_READ; goto retry; case SSL_ERROR_WANT_WRITE: retry_flag = EV_WRITE; goto retry; case SSL_ERROR_ZERO_RETURN: case SSL_ERROR_SYSCALL: if (ret == 0) { conn_close(s); return; } /* FALLTHROUGH */ default: ssl_error("ssl_session_accept"); conn_close(s); return; } } log_debug("ssl_session_accept: accepted ssl client"); s->s_flags |= F_SECURE; s->bev = bufferevent_new(s->fd, conn_read, conn_write, conn_err, s); if (s->bev == NULL) { log_warn("ssl_session_accept: bufferevent_new"); conn_close(s); return; } bufferevent_settimeout(s->bev, 0, 60); event_set(&s->bev->ev_read, s->fd, EV_READ, ssl_read, s->bev); event_set(&s->bev->ev_write, s->fd, EV_WRITE, ssl_write, s->bev); bufferevent_enable(s->bev, EV_READ); return; retry: event_add(&s->s_ev, &s->s_tv); } void ssl_session_init(struct conn *s) { struct listener *l; SSL *ssl; l = s->s_l; if (!(l->flags & F_SSL)) return; log_debug("ssl_session_init: switching to SSL"); ssl = SSL_new(l->ssl_ctx); if (ssl == NULL) goto err; if (!SSL_set_ssl_method(ssl, SSLv23_server_method())) goto err; if (!SSL_set_fd(ssl, s->fd)) goto err; SSL_set_accept_state(ssl); s->s_ssl = ssl; s->s_tv.tv_sec = LDAPD_SESSION_TIMEOUT; s->s_tv.tv_usec = 0; event_set(&s->s_ev, s->fd, EV_READ|EV_TIMEOUT, ssl_session_accept, s); event_add(&s->s_ev, &s->s_tv); return; err: if (ssl != NULL) SSL_free(ssl); ssl_error("ssl_session_init"); } SSL * ssl_client_init(int fd, char *cert, size_t certsz, char *key, size_t keysz) { SSL_CTX *ctx; SSL *ssl = NULL; int rv = -1; ctx = ssl_ctx_create(); if (cert && key) { if (!ssl_ctx_use_certificate_chain(ctx, cert, certsz)) goto done; else if (!ssl_ctx_use_private_key(ctx, key, keysz)) goto done; else if (!SSL_CTX_check_private_key(ctx)) goto done; } if ((ssl = SSL_new(ctx)) == NULL) goto done; if (!SSL_set_ssl_method(ssl, SSLv23_client_method())) goto done; if (!SSL_set_fd(ssl, fd)) goto done; SSL_set_connect_state(ssl); rv = 0; done: if (rv) { if (ssl) SSL_free(ssl); else if (ctx) SSL_CTX_free(ctx); ssl = NULL; } return (ssl); } void ssl_session_destroy(struct conn *s) { SSL_free(s->s_ssl); } int ssl_buf_read(SSL *s, struct ibuf_read *r) { char *buf = r->buf + r->wpos; ssize_t bufsz = sizeof(r->buf) - r->wpos; int ret; if (bufsz == 0) { errno = EMSGSIZE; return (SSL_ERROR_SYSCALL); } if ((ret = SSL_read(s, buf, bufsz)) > 0) r->wpos += ret; return SSL_get_error(s, ret); } int ssl_buf_write(SSL *s, struct msgbuf *msgbuf) { struct ibuf *buf; int ret; buf = TAILQ_FIRST(&msgbuf->bufs); if (buf == NULL) return (SSL_ERROR_NONE); ret = SSL_write(s, buf->buf + buf->rpos, buf->wpos - buf->rpos); if (ret > 0) msgbuf_drain(msgbuf, ret); return SSL_get_error(s, ret); } DH * get_dh512(void) { DH *dh; if ((dh = DH_new()) == NULL) return NULL; dh->p = BN_bin2bn(dh512_p, sizeof(dh512_p), NULL); dh->g = BN_bin2bn(dh512_g, sizeof(dh512_g), NULL); if (dh->p == NULL || dh->g == NULL) return NULL; return dh; } void ssl_set_ephemeral_key_exchange(SSL_CTX *ctx) { DH *dh; dh = get_dh512(); if (dh != NULL) SSL_CTX_set_tmp_dh(ctx, dh); }