/* * $LynxId: tidy_tls.c,v 1.35 2016/11/24 18:48:02 tom Exp $ * Copyright 2008-2015,2016 Thomas E. Dickey * with fix Copyright 2008 by Thomas Viehmann * * Required libraries: * libgnutls * libcrypt */ #include #include #include #ifdef HAVE_GNUTLS_RND #include #else #include #endif #include /* ASN1_SUCCESS,etc */ #include #define typeCalloc(type) (type *) calloc(1, sizeof(type)) static int last_error = 0; /* ugly, but hey, we could just use a more sane api, too */ #define GetDnByOID(target, oid, thewhat) \ len = sizeof(target); \ if (! thewhat) \ gnutls_x509_crt_get_dn_by_oid(xcert, oid, 0, 0, target, &len); \ else \ gnutls_x509_crt_get_issuer_dn_by_oid(xcert, oid, 0, 0, target, &len) /* thewhat: which DN to get 0 = subject, 1 = issuer */ static int ExtractCertificate(const gnutls_datum_t *cert, X509_NAME * result, int thewhat) { gnutls_x509_crt_t xcert; int rc; size_t len; if ((rc = gnutls_x509_crt_init(&xcert)) >= 0) { if ((rc = gnutls_x509_crt_import(xcert, cert, GNUTLS_X509_FMT_DER)) >= 0) { GetDnByOID(result->country, GNUTLS_OID_X520_COUNTRY_NAME, thewhat); GetDnByOID(result->organization, GNUTLS_OID_X520_ORGANIZATION_NAME, thewhat); GetDnByOID(result->organizational_unit_name, GNUTLS_OID_X520_ORGANIZATIONAL_UNIT_NAME, thewhat); GetDnByOID(result->common_name, GNUTLS_OID_X520_COMMON_NAME, thewhat); GetDnByOID(result->locality_name, GNUTLS_OID_X520_LOCALITY_NAME, thewhat); GetDnByOID(result->state_or_province_name, GNUTLS_OID_X520_STATE_OR_PROVINCE_NAME, thewhat); GetDnByOID(result->email, GNUTLS_OID_PKCS9_EMAIL, thewhat); rc = 0; } gnutls_x509_crt_deinit(xcert); } return rc; } /* * (stub) * ERR_error_string() generates a human-readable string representing the * error code 'e', and places it at 'buffer', which must be at least 120 bytes * long. If 'buffer' is NULL, the error string is placed in a static buffer. */ const char *ERR_error_string(unsigned long e, char *buffer) { (void) buffer; return gnutls_strerror((int) -e); } /* * (stub) * Return the earliest error code from the thread's error queue and remove the * entry. */ unsigned long ERR_get_error(void) { unsigned long rc; rc = (unsigned long) (-last_error); last_error = 0; return rc; } /* * Put 'num' cryptographically strong pseudo-random bytes into 'buffer'. */ int RAND_bytes(unsigned char *buffer, int num) { int rc; #ifdef HAVE_GNUTLS_RND rc = gnutls_rnd(GNUTLS_RND_KEY, buffer, (size_t) num); #else gcry_randomize(buffer, num, GCRY_VERY_STRONG_RANDOM); rc = 1; #endif return rc; } /* * (stub) * Generate a default path for the random seed file. 'buffer' points to a * buffer of size 'len' in which to store the filename. */ const char *RAND_file_name(char *buffer, size_t len) { (void) buffer; (void) len; return ""; } /* * (stub) * Read a number of bytes from file 'name' and adds them to the PRNG. If * 'maxbytes' is non-negative, up to to 'maxbytes' are read; if 'maxbytes' is * -1, the complete file is read. */ int RAND_load_file(const char *name, long maxbytes) { (void) name; return (int) maxbytes; } /* * (stub) * Mix the 'num' bytes at 'buffer' into the PRNG state. */ void RAND_seed(const void *buffer, int num) { (void) buffer; (void) num; } /* * (stub) * Return 1 if the PRNG has been seeded with enough data, 0 otherwise. */ int RAND_status(void) { return 1; } /* * (stub) * Write a number of random bytes (currently 1024) to file 'name' which can be * used to initialize the PRNG by calling RAND_load_file() in a later session. */ int RAND_write_file(const char *name) { (void) name; return 0; } /* * Return the number of secret bits used for cipher. If 'bits' is not NULL, it * contains the number of bits processed by the chosen algorithm. If cipher is * NULL, 0 is returned. */ int SSL_CIPHER_get_bits(SSL_CIPHER * cipher, int *bits) { int result = 0; if (cipher) { result = (8 * (int) gnutls_cipher_get_key_size(cipher->encrypts)); } if (bits) *bits = result; return result; } /* * Return a pointer to the name of 'cipher'. If 'cipher' is NULL the constant * value "NONE" is returned. */ const char *SSL_CIPHER_get_name(SSL_CIPHER * cipher) { const char *result = "NONE"; if (cipher) { result = gnutls_cipher_suite_get_name(cipher->key_xchg, cipher->encrypts, cipher->msg_code); } return result; } /* * Return the protocol version for cipher, currently "SSLv2", "SSLv3", or * "TLSv1". If cipher is NULL, "(NONE)" is returned. */ const char *SSL_CIPHER_get_version(SSL_CIPHER * cipher) { const char *result = "NONE"; if (cipher) { if ((result = gnutls_protocol_get_name(cipher->protocol)) == 0) result = "unknown"; } return result; } /* * Free an allocated SSL_CTX object. */ void SSL_CTX_free(SSL_CTX * ctx) { free(ctx->method); free(ctx); } /* * Create a new SSL_CTX object as framework for TLS/SSL enabled functions. */ SSL_CTX *SSL_CTX_new(SSL_METHOD * method) { SSL_CTX *ctx; if ((ctx = typeCalloc(SSL_CTX)) != 0) { ctx->method = method; } return ctx; } /* * See SSL_CTX_load_verify_locations() - this sets the paths for that and * SSL_CTX_set_verify() to their default values. GNU TLS does not have a * comparable feature (stub). */ int SSL_CTX_set_default_verify_paths(SSL_CTX * ctx) { (void) ctx; return 0; } /* * SSL_CTX_set_options() adds the options set via bitmask in options to * ctx. Options already set before are not cleared. */ unsigned long SSL_CTX_set_options(SSL_CTX * ctx, unsigned long options) { ctx->options |= options; return ctx->options; } /* * Set peer certificate verification parameters. */ void SSL_CTX_set_verify(SSL_CTX * ctx, int verify_mode, int (*verify_callback) (int, X509_STORE_CTX *)) { ctx->verify_mode = verify_mode; ctx->verify_callback = verify_callback; } #ifdef HAVE_GNUTLS_PROTOCOL_SET_PRIORITY static void RemoveProtocol(SSL * ssl, int protocol) { int j, k; int changed = 0; int *protocols = ssl->ctx->method->priority.protocol; for (j = k = 0; j < GNUTLS_MAX_ALGORITHM_NUM;) { if (protocols[k] == protocol) { if (++k >= GNUTLS_MAX_ALGORITHM_NUM) break; changed = 1; } else { protocols[j++] = protocols[k++]; } } if (changed) { gnutls_protocol_set_priority(ssl->gnutls_state, protocols); } } #endif /* * Initiate the TLS/SSL handshake with an TLS/SSL server. */ int SSL_connect(SSL * ssl) { X509_STORE_CTX *store; int rc; gnutls_alert_description_t alert; const char *aname; if (ssl->options & SSL_OP_NO_TLSv1) { #ifdef HAVE_GNUTLS_PROTOCOL_SET_PRIORITY RemoveProtocol(ssl, GNUTLS_TLS1); #else gnutls_priority_set_direct(ssl->gnutls_state, "NORMAL:-VERS-TLS1.0", NULL); #endif } while ((rc = gnutls_handshake(ssl->gnutls_state)) < 0 && !gnutls_error_is_fatal(rc)) { if (rc == GNUTLS_E_WARNING_ALERT_RECEIVED) { alert = gnutls_alert_get(ssl->gnutls_state); aname = gnutls_alert_get_name(alert); CTRACE((tfp, "SSL Alert: %s\n", NonNull(aname))); switch (gnutls_alert_get(ssl->gnutls_state)) { case GNUTLS_A_UNRECOGNIZED_NAME: continue; /* ignore */ default: break; } break; /* treat all other alerts as fatal */ } } ssl->last_error = rc; if (rc < 0) { last_error = rc; return 0; } store = typeCalloc(X509_STORE_CTX); if (store == 0) outofmem(__FILE__, "SSL_connect"); store->ssl = ssl; store->cert_list = SSL_get_peer_certificate(ssl); if (ssl->verify_callback) { ssl->verify_callback(1, store); } ssl->state = SSL_ST_OK; free(store); /* FIXME: deal with error from callback */ return 1; } /* * Free an allocated SSL structure. */ void SSL_free(SSL * ssl) { gnutls_certificate_free_credentials(ssl->gnutls_cred); gnutls_deinit(ssl->gnutls_state); free(ssl); } /* * Get SSL_CIPHER data of a connection. */ SSL_CIPHER *SSL_get_current_cipher(SSL * ssl) { SSL_CIPHER *result = 0; if (ssl) { result = &(ssl->ciphersuite); result->protocol = gnutls_protocol_get_version(ssl->gnutls_state); result->encrypts = gnutls_cipher_get(ssl->gnutls_state); result->key_xchg = gnutls_kx_get(ssl->gnutls_state); result->msg_code = gnutls_mac_get(ssl->gnutls_state); result->compress = gnutls_compression_get(ssl->gnutls_state); result->cert = gnutls_certificate_type_get(ssl->gnutls_state); } return result; } /* * Get the X509 certificate of the peer. */ const X509 *SSL_get_peer_certificate(SSL * ssl) { const gnutls_datum_t *result; unsigned list_size = 0; result = (const gnutls_datum_t *) gnutls_certificate_get_peers(ssl->gnutls_state, &list_size); return (const X509 *) result; } /* * Initialize SSL library by registering algorithms. */ int SSL_library_init(void) { gnutls_global_init(); return 1; } /* * (stub) * OpenSSL uses this to prepare for ERR_get_error() calls. */ void SSL_load_error_strings(void) { } /* * Create a new SSL structure for a connection. */ SSL *SSL_new(SSL_CTX * ctx) { SSL *ssl; int rc; if ((ssl = typeCalloc(SSL)) != 0) { rc = gnutls_certificate_allocate_credentials(&ssl->gnutls_cred); if (rc < 0) { last_error = rc; free(ssl); ssl = 0; } else { ssl->ctx = ctx; gnutls_init(&ssl->gnutls_state, ctx->method->connend); gnutls_set_default_priority(ssl->gnutls_state); gnutls_credentials_set(ssl->gnutls_state, GNUTLS_CRD_CERTIFICATE, ssl->gnutls_cred); if (ctx->certfile) gnutls_certificate_set_x509_trust_file(ssl->gnutls_cred, ctx->certfile, ctx->certfile_type); if (ctx->client_keyfile) gnutls_certificate_set_x509_key_file(ssl->gnutls_cred, ctx->client_certfile, ctx->client_keyfile, ctx->client_keyfile_type); ssl->verify_mode = ctx->verify_mode; ssl->verify_callback = ctx->verify_callback; ssl->options = ctx->options; ssl->rfd = (gnutls_transport_ptr_t) (-1); ssl->wfd = (gnutls_transport_ptr_t) (-1); ssl->bytes_sent = 0; ssl->sendbuffer = 0; } } return ssl; } /* * Read 'length' bytes into 'buffer' from the given SSL connection. * Returns the number of bytes read, or zero on error. */ int SSL_read(SSL * ssl, void *buffer, int length) { int rc; rc = (int) gnutls_record_recv(ssl->gnutls_state, buffer, (size_t) length); if (rc < 0 && gnutls_error_is_fatal(rc) == 0) { if (rc == GNUTLS_E_REHANDSHAKE) { (void) gnutls_handshake(ssl->gnutls_state); gnutls_record_send(ssl->gnutls_state, ssl->sendbuffer, (size_t) ssl->bytes_sent); rc = (int) gnutls_record_recv(ssl->gnutls_state, buffer, (size_t) length); } } ssl->last_error = rc; if (rc < 0) { last_error = rc; rc = 0; } return rc; } /* * Connect the SSL object with a file descriptor. * This always returns 1 (success) since GNU TLS does not check for errors. */ int SSL_set_fd(SSL * ssl, int fd) { gnutls_transport_set_ptr(ssl->gnutls_state, (gnutls_transport_ptr_t) (intptr_t) (fd)); return 1; } /* * Write 'length' bytes from 'buffer' to the given SSL connection. */ int SSL_write(SSL * ssl, const void *buffer, int length) { int rc; rc = (int) gnutls_record_send(ssl->gnutls_state, buffer, (size_t) length); ssl->last_error = rc; if (rc < 0) { last_error = rc; rc = 0; } else { size_t need = (size_t) rc; free(ssl->sendbuffer); ssl->sendbuffer = malloc(need); ssl->bytes_sent = need; } return rc; } /* * Return method-data for SSL verion 3, with the option of rollback to SSL * version 2. */ SSL_METHOD *SSLv23_client_method(void) { SSL_METHOD *m; if ((m = typeCalloc(SSL_METHOD)) != 0) { int n; /* * List the protocols in decreasing order of priority. */ n = 0; #if GNUTLS_VERSION_NUMBER >= 0x030000 m->priority.protocol[n++] = GNUTLS_SSL3; m->priority.protocol[n++] = GNUTLS_TLS1_2; #endif m->priority.protocol[n++] = GNUTLS_TLS1_1; m->priority.protocol[n++] = GNUTLS_TLS1_0; m->priority.protocol[n] = 0; /* * List the cipher algorithms in decreasing order of priority. */ n = 0; #if GNUTLS_VERSION_NUMBER >= 0x030000 m->priority.encrypts[n++] = GNUTLS_CIPHER_AES_256_GCM; m->priority.encrypts[n++] = GNUTLS_CIPHER_AES_128_GCM; #endif m->priority.encrypts[n++] = GNUTLS_CIPHER_AES_256_CBC; m->priority.encrypts[n++] = GNUTLS_CIPHER_AES_128_CBC; m->priority.encrypts[n++] = GNUTLS_CIPHER_CAMELLIA_256_CBC; m->priority.encrypts[n++] = GNUTLS_CIPHER_CAMELLIA_128_CBC; m->priority.encrypts[n++] = GNUTLS_CIPHER_3DES_CBC; m->priority.encrypts[n] = 0; /* * List the compression algorithms in decreasing order of priority. */ n = 0; m->priority.compress[n++] = GNUTLS_COMP_NULL; m->priority.compress[n] = 0; /* * List the key exchange algorithms in decreasing order of priority. */ n = 0; m->priority.key_xchg[n++] = GNUTLS_KX_DHE_RSA; m->priority.key_xchg[n++] = GNUTLS_KX_RSA; m->priority.key_xchg[n++] = GNUTLS_KX_DHE_DSS; m->priority.key_xchg[n] = 0; /* * List message authentication code (MAC) algorithms in decreasing * order of priority to specify via gnutls_mac_set_priority(). */ n = 0; m->priority.msg_code[n++] = GNUTLS_MAC_SHA1; m->priority.msg_code[n++] = GNUTLS_MAC_MD5; m->priority.msg_code[n] = 0; /* * For gnutls_init, says we're a client. */ m->connend = GNUTLS_CLIENT; } return m; } static int add_name(char *target, int len, const char *tag, const char *data) { if (*data != '\0') { int need = (int) strlen(tag) + 2; target += strlen(target); if (need < len) { strcat(target, "/"); strcat(target, tag); strcat(target, "="); len -= need; target += need; } need = (int) strlen(data); if (need >= len - 1) need = len - 1; strncat(target, data, (size_t) need)[need] = '\0'; } return len; } #define ADD_NAME(tag, data) len = add_name(target, len, tag, data); /* * Convert the X509 name 'source' to a string in the given buffer 'target', * whose length is 'len'. Return a pointer to the buffer. */ char *X509_NAME_oneline(X509_NAME * source, char *target, int len) { if (target && (len > 0)) { *target = '\0'; if (source) { ADD_NAME("C", source->country); ADD_NAME("ST", source->state_or_province_name); ADD_NAME("L", source->locality_name); ADD_NAME("O", source->organization); ADD_NAME("OU", source->organizational_unit_name); ADD_NAME("CN", source->common_name); ADD_NAME("Email", source->email); } } return target; } /* * Extract the certificate's issuer-name data. */ X509_NAME *X509_get_issuer_name(const X509 * cert) { static X509_NAME *result; free(result); if ((result = typeCalloc(X509_NAME)) != 0) { if (ExtractCertificate(cert, result, 1) < 0) { free(result); result = 0; } } return result; } /* * Extract the certificate's subject-name data. */ X509_NAME *X509_get_subject_name(const X509 * cert) { static X509_NAME *result; free(result); if ((result = typeCalloc(X509_NAME)) != 0) { if (ExtractCertificate(cert, result, 0) < 0) { free(result); result = 0; } } return result; }