/* Copyright (c) 2007-2017 Contributors as noted in the AUTHORS file This file is part of libzmq, the ZeroMQ core engine in C++. libzmq is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License (LGPL) as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. As a special exception, the Contributors give you permission to link this library with independent modules to produce an executable, regardless of the license terms of these independent modules, and to copy and distribute the resulting executable under terms of your choice, provided that you also meet, for each linked independent module, the terms and conditions of the license of that module. An independent module is a module which is not derived from or based on this library. If you modify this library, you must extend this exception to your version of the library. libzmq is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program. If not, see . */ #include "testutil.hpp" #if defined (ZMQ_HAVE_WINDOWS) # include # include # include # define close closesocket #else # include # include # include # include #endif // We'll generate random test keys at startup static char valid_client_public [41]; static char valid_client_secret [41]; static char valid_server_public [41]; static char valid_server_secret [41]; void *zap_requests_handled; #ifdef ZMQ_BUILD_DRAFT_API // Read one event off the monitor socket; return value and address // by reference, if not null, and event number by value. Returns -1 // in case of error. static int get_monitor_event (void *monitor, int *value, char **address, int recv_flag) { // First frame in message contains event number and value zmq_msg_t msg; zmq_msg_init (&msg); if (zmq_msg_recv (&msg, monitor, recv_flag) == -1) { assert (errno == EAGAIN); return -1; // timed out or no message available } assert (zmq_msg_more (&msg)); uint8_t *data = (uint8_t *) zmq_msg_data (&msg); uint16_t event = *(uint16_t *) (data); if (value) *value = *(uint32_t *) (data + 2); // Second frame in message contains event address zmq_msg_init (&msg); int res = zmq_msg_recv (&msg, monitor, recv_flag) == -1; assert (res != -1); assert (!zmq_msg_more (&msg)); if (address) { uint8_t *data = (uint8_t *) zmq_msg_data (&msg); size_t size = zmq_msg_size (&msg); *address = (char *) malloc (size + 1); memcpy (*address, data, size); *address [size] = 0; } return event; } int get_monitor_event_with_timeout (void *monitor, int *value, char **address, int timeout) { zmq_setsockopt (monitor, ZMQ_RCVTIMEO, &timeout, sizeof (timeout)); int res = get_monitor_event (monitor, value, address, 0); int timeout_infinite = -1; zmq_setsockopt (monitor, ZMQ_RCVTIMEO, &timeout_infinite, sizeof (timeout_infinite)); return res; } // assert_* are macros rather than functions, to allow assertion failures be // attributed to the causing source code line #define assert_no_more_monitor_events_with_timeout(monitor, timeout) \ { \ int event_count = 0; \ int event, err; \ while ((event = get_monitor_event_with_timeout ((monitor), &err, NULL, \ (timeout))) \ != -1) { \ ++event_count; \ fprintf (stderr, "Unexpected event: %x (err = %i)\n", event, err); \ } \ assert (event_count == 0); \ } #define assert_monitor_event(monitor, expected_events) \ { \ int err; \ int event = get_monitor_event (monitor, &err, NULL, 0); \ assert (event != -1); \ if ((event & (expected_events)) == 0) { \ fprintf (stderr, "Unexpected event: %x (err = %i)\n", event, err); \ while ( \ (event = get_monitor_event (monitor, NULL, NULL, (timeout))) \ != -1) { \ fprintf (stderr, "Further event: %x\n", event); \ } \ assert (false); \ } \ } #endif // -------------------------------------------------------------------------- // This methods receives and validates ZAP requests (allowing or denying // each client connection). enum zap_protocol_t { zap_ok, // ZAP-compliant non-standard cases zap_status_internal_error, // ZAP protocol errors zap_wrong_version, zap_wrong_request_id, zap_status_invalid, zap_too_many_parts }; static void zap_handler_generic (void *ctx, zap_protocol_t zap_protocol) { void *control = zmq_socket (ctx, ZMQ_REQ); assert (control); int rc = zmq_connect (control, "inproc://handler-control"); assert (rc == 0); void *handler = zmq_socket (ctx, ZMQ_REP); assert (handler); rc = zmq_bind (handler, "inproc://zeromq.zap.01"); assert (rc == 0); // Signal main thread that we are ready rc = s_send (control, "GO"); assert (rc == 2); zmq_pollitem_t items [] = { { control, 0, ZMQ_POLLIN, 0 }, { handler, 0, ZMQ_POLLIN, 0 }, }; // Process ZAP requests forever while (zmq_poll (items, 2, -1) >= 0) { if (items [0].revents & ZMQ_POLLIN) { char *buf = s_recv (control); assert (buf); assert (streq (buf, "STOP")); free (buf); break; // Terminating - main thread signal } if (!(items [1].revents & ZMQ_POLLIN)) continue; char *version = s_recv (handler); if (!version) break; // Terminating - peer's socket closed char *sequence = s_recv (handler); char *domain = s_recv (handler); char *address = s_recv (handler); char *identity = s_recv (handler); char *mechanism = s_recv (handler); uint8_t client_key [32]; int size = zmq_recv (handler, client_key, 32, 0); assert (size == 32); char client_key_text [41]; zmq_z85_encode (client_key_text, client_key, 32); assert (streq (version, "1.0")); assert (streq (mechanism, "CURVE")); assert (streq (identity, "IDENT")); s_sendmore (handler, zap_protocol == zap_wrong_version ? "invalid_version" : version); s_sendmore (handler, zap_protocol == zap_wrong_request_id ? "invalid_request_id" : sequence); if (streq (client_key_text, valid_client_public)) { s_sendmore (handler, zap_protocol == zap_status_internal_error ? "500" : (zap_protocol == zap_status_invalid ? "invalid_status" : "200")); s_sendmore (handler, "OK"); s_sendmore (handler, "anonymous"); if (zap_protocol == zap_too_many_parts) { s_sendmore (handler, ""); } s_send (handler, ""); } else { s_sendmore (handler, "400"); s_sendmore (handler, "Invalid client public key"); s_sendmore (handler, ""); s_send (handler, ""); } free (version); free (sequence); free (domain); free (address); free (identity); free (mechanism); zmq_atomic_counter_inc (zap_requests_handled); } rc = zmq_unbind (handler, "inproc://zeromq.zap.01"); assert (rc == 0); close_zero_linger (handler); rc = s_send (control, "STOPPED"); assert (rc == 7); close_zero_linger (control); } static void zap_handler (void *ctx) { zap_handler_generic (ctx, zap_ok); } static void zap_handler_wrong_version (void *ctx) { zap_handler_generic (ctx, zap_wrong_version); } static void zap_handler_wrong_request_id (void *ctx) { zap_handler_generic (ctx, zap_wrong_request_id); } static void zap_handler_wrong_status_invalid (void *ctx) { zap_handler_generic (ctx, zap_status_invalid); } static void zap_handler_wrong_status_internal_error (void *ctx) { zap_handler_generic (ctx, zap_status_internal_error); } static void zap_handler_too_many_parts (void *ctx) { zap_handler_generic (ctx, zap_too_many_parts); } void *create_and_connect_curve_client (void *ctx, char *server_public, char *client_public, char *client_secret, char *my_endpoint) { void *client = zmq_socket (ctx, ZMQ_DEALER); assert (client); int rc = zmq_setsockopt (client, ZMQ_CURVE_SERVERKEY, server_public, 41); assert (rc == 0); rc = zmq_setsockopt (client, ZMQ_CURVE_PUBLICKEY, client_public, 41); assert (rc == 0); rc = zmq_setsockopt (client, ZMQ_CURVE_SECRETKEY, client_secret, 41); assert (rc == 0); rc = zmq_connect (client, my_endpoint); assert (rc == 0); return client; } void expect_new_client_curve_bounce_fail (void *ctx, char *server_public, char *client_public, char *client_secret, char *my_endpoint, void *server) { void *client = create_and_connect_curve_client ( ctx, server_public, client_public, client_secret, my_endpoint); expect_bounce_fail (server, client); close_zero_linger (client); } #ifdef ZMQ_BUILD_DRAFT_API // expects that one or more occurrences of the expected event are received // via the specified socket monitor // returns the number of occurrences of the expected event // interrupts, if a ZMQ_EVENT_HANDSHAKE_FAILED_NO_DETAIL with EPIPE, ECONNRESET // or ECONNABORTED occurs; in this case, 0 is returned // this should be investigated further, see // https://github.com/zeromq/libzmq/issues/2644 int expect_monitor_event_multiple (void *server_mon, int expected_event, int expected_err = -1) { int count_of_expected_events = 0; int client_closed_connection = 0; int timeout = -1; int event; int err; while ( (event = get_monitor_event_with_timeout (server_mon, &err, NULL, timeout)) != -1) { timeout = 250; // ignore errors with EPIPE/ECONNRESET/ECONNABORTED, which can happen // ECONNRESET can happen on very slow machines, when the engine writes // to the peer and then tries to read the socket before the peer reads // ECONNABORTED happens when a client aborts a connection via RST/timeout if (event == ZMQ_EVENT_HANDSHAKE_FAILED_NO_DETAIL && (err == EPIPE || err == ECONNRESET || err == ECONNABORTED)) { fprintf (stderr, "Ignored event: %x (err = %i)\n", event, err); client_closed_connection = 1; break; } if (event != expected_event || (-1 != expected_err && err != expected_err)) { fprintf (stderr, "Unexpected event: %x (err = %i)\n", event, err); assert (false); } ++count_of_expected_events; } assert (count_of_expected_events > 0 || client_closed_connection); return count_of_expected_events; } #endif void test_garbage_key(void *ctx, void *server, void *server_mon, char *my_endpoint, char *server_public, char *client_public, char *client_secret) { expect_new_client_curve_bounce_fail (ctx, server_public, client_public, client_secret, my_endpoint, server); #ifdef ZMQ_BUILD_DRAFT_API int handshake_failed_encryption_event_count = expect_monitor_event_multiple (server_mon, ZMQ_EVENT_HANDSHAKE_FAILED_ENCRYPTION); // handshake_failed_encryption_event_count should be at least two because // expect_bounce_fail involves two exchanges // however, with valgrind we see only one event (maybe the next one takes // very long, or does not happen at all because something else takes very // long) fprintf (stderr, "count of ZMQ_EVENT_HANDSHAKE_FAILED_ENCRYPTION events: %i\n", handshake_failed_encryption_event_count); #endif } void setup_context_and_server_side (void **ctx, void **handler, void **zap_thread, void **server, void **server_mon, char *my_endpoint, zmq_thread_fn zap_handler_ = &zap_handler) { *ctx = zmq_ctx_new (); assert (*ctx); // Spawn ZAP handler zap_requests_handled = zmq_atomic_counter_new (); assert (zap_requests_handled != NULL); *handler = zmq_socket (*ctx, ZMQ_REP); assert (*handler); int rc = zmq_bind (*handler, "inproc://handler-control"); assert (rc == 0); *zap_thread = zmq_threadstart (zap_handler_, *ctx); char *buf = s_recv (*handler); assert (buf); assert (streq (buf, "GO")); free (buf); // Server socket will accept connections *server = zmq_socket (*ctx, ZMQ_DEALER); assert (*server); int as_server = 1; rc = zmq_setsockopt (*server, ZMQ_CURVE_SERVER, &as_server, sizeof (int)); assert (rc == 0); rc = zmq_setsockopt (*server, ZMQ_CURVE_SECRETKEY, valid_server_secret, 41); assert (rc == 0); rc = zmq_setsockopt (*server, ZMQ_IDENTITY, "IDENT", 6); assert (rc == 0); rc = zmq_bind (*server, "tcp://127.0.0.1:*"); assert (rc == 0); size_t len = MAX_SOCKET_STRING; rc = zmq_getsockopt (*server, ZMQ_LAST_ENDPOINT, my_endpoint, &len); assert (rc == 0); #ifdef ZMQ_BUILD_DRAFT_API char monitor_endpoint [] = "inproc://monitor-server"; // Monitor handshake events on the server rc = zmq_socket_monitor ( *server, monitor_endpoint, ZMQ_EVENT_HANDSHAKE_SUCCEEDED | ZMQ_EVENT_HANDSHAKE_FAILED_NO_DETAIL | ZMQ_EVENT_HANDSHAKE_FAILED_ZAP | ZMQ_EVENT_HANDSHAKE_FAILED_ZMTP | ZMQ_EVENT_HANDSHAKE_FAILED_ENCRYPTION); assert (rc == 0); // Create socket for collecting monitor events *server_mon = zmq_socket (*ctx, ZMQ_PAIR); assert (*server_mon); // Connect it to the inproc endpoints so they'll get events rc = zmq_connect (*server_mon, monitor_endpoint); assert (rc == 0); #endif } void shutdown_context_and_server_side (void *ctx, void *zap_thread, void *server, void *server_mon, void *handler) { int rc = s_send (handler, "STOP"); assert (rc == 4); char *buf = s_recv (handler); assert (buf); assert (streq (buf, "STOPPED")); free (buf); rc = zmq_unbind (handler, "inproc://handler-control"); assert (rc == 0); close_zero_linger (handler); #ifdef ZMQ_BUILD_DRAFT_API close_zero_linger (server_mon); #endif close_zero_linger (server); // Wait until ZAP handler terminates zmq_threadclose (zap_thread); rc = zmq_ctx_term (ctx); assert (rc == 0); zmq_atomic_counter_destroy (&zap_requests_handled); } void test_curve_security_with_valid_credentials ( void *ctx, char *my_endpoint, void *server, void *server_mon, int timeout) { void *client = create_and_connect_curve_client ( ctx, valid_server_public, valid_client_public, valid_client_secret, my_endpoint); bounce (server, client); int rc = zmq_close (client); assert (rc == 0); #ifdef ZMQ_BUILD_DRAFT_API int event = get_monitor_event (server_mon, NULL, NULL, 0); assert (event == ZMQ_EVENT_HANDSHAKE_SUCCEEDED); assert_no_more_monitor_events_with_timeout (server_mon, timeout); #endif } void test_curve_security_with_bogus_client_credentials ( void *ctx, char *my_endpoint, void *server, void *server_mon, int timeout) { // This must be caught by the ZAP handler char bogus_public [41]; char bogus_secret [41]; zmq_curve_keypair (bogus_public, bogus_secret); expect_new_client_curve_bounce_fail (ctx, valid_server_public, bogus_public, bogus_secret, my_endpoint, server); #ifdef ZMQ_BUILD_DRAFT_API int event = get_monitor_event (server_mon, NULL, NULL, 0); // TODO add another event type ZMQ_EVENT_HANDSHAKE_FAILED_AUTH for this case? assert ( event == ZMQ_EVENT_HANDSHAKE_FAILED_NO_DETAIL); // ZAP handle the error, not curve_server assert_no_more_monitor_events_with_timeout (server_mon, timeout); #endif // there may be more than one ZAP request due to repeated attempts by the client assert (1 <= zmq_atomic_counter_value (zap_requests_handled)); } void expect_zmtp_failure (void *client, char *my_endpoint, void *server, void *server_mon) { // This must be caught by the curve_server class, not passed to ZAP int rc = zmq_connect (client, my_endpoint); assert (rc == 0); expect_bounce_fail (server, client); close_zero_linger (client); #ifdef ZMQ_BUILD_DRAFT_API int err; int event = get_monitor_event (server_mon, &err, NULL, 0); assert (event == ZMQ_EVENT_HANDSHAKE_FAILED_ZMTP || (event == ZMQ_EVENT_HANDSHAKE_FAILED_NO_DETAIL && err == EPIPE)); #endif assert (0 == zmq_atomic_counter_value (zap_requests_handled)); } void test_curve_security_with_null_client_credentials (void *ctx, char *my_endpoint, void *server, void *server_mon) { void *client = zmq_socket (ctx, ZMQ_DEALER); assert (client); expect_zmtp_failure (client, my_endpoint, server, server_mon); } void test_curve_security_with_plain_client_credentials (void *ctx, char *my_endpoint, void *server, void *server_mon) { void *client = zmq_socket (ctx, ZMQ_DEALER); assert (client); int rc = zmq_setsockopt (client, ZMQ_PLAIN_USERNAME, "admin", 5); assert (rc == 0); rc = zmq_setsockopt (client, ZMQ_PLAIN_PASSWORD, "password", 8); assert (rc == 0); expect_zmtp_failure (client, my_endpoint, server, server_mon); } void test_curve_security_unauthenticated_message (char *my_endpoint, void *server, int timeout) { // Unauthenticated messages from a vanilla socket shouldn't be received struct sockaddr_in ip4addr; int s; unsigned short int port; int rc = sscanf (my_endpoint, "tcp://127.0.0.1:%hu", &port); assert (rc == 1); ip4addr.sin_family = AF_INET; ip4addr.sin_port = htons (port); #if defined(ZMQ_HAVE_WINDOWS) && (_WIN32_WINNT < 0x0600) ip4addr.sin_addr.s_addr = inet_addr ("127.0.0.1"); #else inet_pton (AF_INET, "127.0.0.1", &ip4addr.sin_addr); #endif s = socket (AF_INET, SOCK_STREAM, IPPROTO_TCP); rc = connect (s, (struct sockaddr *) &ip4addr, sizeof (ip4addr)); assert (rc > -1); // send anonymous ZMTP/1.0 greeting send (s, "\x01\x00", 2, 0); // send sneaky message that shouldn't be received send (s, "\x08\x00sneaky\0", 9, 0); zmq_setsockopt (server, ZMQ_RCVTIMEO, &timeout, sizeof (timeout)); char *buf = s_recv (server); if (buf != NULL) { printf ("Received unauthenticated message: %s\n", buf); assert (buf == NULL); } close (s); } void test_curve_security_zap_unsuccessful (void *ctx, char *my_endpoint, void *server, void *server_mon, int expected_event, int expected_err) { expect_new_client_curve_bounce_fail ( ctx, valid_server_public, valid_client_public, valid_client_secret, my_endpoint, server); #ifdef ZMQ_BUILD_DRAFT_API expect_monitor_event_multiple (server_mon, expected_event, expected_err); #endif // there may be more than one ZAP request due to repeated attempts by the client assert (1 <= zmq_atomic_counter_value (zap_requests_handled)); } void test_curve_security_zap_protocol_error (void *ctx, char *my_endpoint, void *server, void *server_mon) { test_curve_security_zap_unsuccessful (ctx, my_endpoint, server, server_mon, #ifdef ZMQ_BUILD_DRAFT_API ZMQ_EVENT_HANDSHAKE_FAILED_ZAP, EPROTO #else 0, 0 #endif ); } void test_curve_security_invalid_keysize (void *ctx) { // Check return codes for invalid buffer sizes void *client = zmq_socket (ctx, ZMQ_DEALER); assert (client); errno = 0; int rc = zmq_setsockopt (client, ZMQ_CURVE_SERVERKEY, valid_server_public, 123); assert (rc == -1 && errno == EINVAL); errno = 0; rc = zmq_setsockopt (client, ZMQ_CURVE_PUBLICKEY, valid_client_public, 123); assert (rc == -1 && errno == EINVAL); errno = 0; rc = zmq_setsockopt (client, ZMQ_CURVE_SECRETKEY, valid_client_secret, 123); assert (rc == -1 && errno == EINVAL); rc = zmq_close (client); assert (rc == 0); } int main (void) { if (!zmq_has ("curve")) { printf ("CURVE encryption not installed, skipping test\n"); return 0; } // Generate new keypairs for these tests int rc = zmq_curve_keypair (valid_client_public, valid_client_secret); assert (rc == 0); rc = zmq_curve_keypair (valid_server_public, valid_server_secret); assert (rc == 0); int timeout = 250; setup_test_environment (); void *ctx; void *handler; void *zap_thread; void *server; void *server_mon; char my_endpoint [MAX_SOCKET_STRING]; setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_curve_security_with_valid_credentials (ctx, my_endpoint, server, server_mon, timeout); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); char garbage_key [] = "0000000000000000000000000000000000000000"; // Check CURVE security with a garbage server key // This will be caught by the curve_server class, not passed to ZAP fprintf (stderr, "test_garbage_server_key\n"); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_garbage_key (ctx, server, server_mon, my_endpoint, garbage_key, valid_client_public, valid_client_secret); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // Check CURVE security with a garbage client public key // This will be caught by the curve_server class, not passed to ZAP fprintf (stderr, "test_garbage_client_public_key\n"); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_garbage_key (ctx, server, server_mon, my_endpoint, valid_server_public, garbage_key, valid_client_secret); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // Check CURVE security with a garbage client secret key // This will be caught by the curve_server class, not passed to ZAP fprintf (stderr, "test_garbage_client_secret_key\n"); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_garbage_key (ctx, server, server_mon, my_endpoint, valid_server_public, valid_client_public, garbage_key); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_curve_security_with_bogus_client_credentials (ctx, my_endpoint, server, server_mon, timeout); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_curve_security_with_null_client_credentials (ctx, my_endpoint, server, server_mon); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_curve_security_with_plain_client_credentials (ctx, my_endpoint, server, server_mon); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint); test_curve_security_unauthenticated_message (my_endpoint, server, timeout); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // Invalid ZAP protocol tests // wrong version setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint, &zap_handler_wrong_version); test_curve_security_zap_protocol_error (ctx, my_endpoint, server, server_mon); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // wrong request id setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint, &zap_handler_wrong_request_id); test_curve_security_zap_protocol_error (ctx, my_endpoint, server, server_mon); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // status invalid (not a 3-digit number) setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint, &zap_handler_wrong_status_invalid); test_curve_security_zap_protocol_error (ctx, my_endpoint, server, server_mon); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // too many parts setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint, &zap_handler_too_many_parts); test_curve_security_zap_protocol_error (ctx, my_endpoint, server, server_mon); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); // ZAP non-standard cases // status 500 internal error setup_context_and_server_side (&ctx, &handler, &zap_thread, &server, &server_mon, my_endpoint, &zap_handler_wrong_status_internal_error); // TODO is this usable? EAGAIN does not appear to be an appropriate error // code, and the status text is completely lost test_curve_security_zap_unsuccessful (ctx, my_endpoint, server, server_mon, #ifdef ZMQ_BUILD_DRAFT_API ZMQ_EVENT_HANDSHAKE_FAILED_NO_DETAIL, EAGAIN #else 0, 0 #endif ); shutdown_context_and_server_side (ctx, zap_thread, server, server_mon, handler); ctx = zmq_ctx_new (); test_curve_security_invalid_keysize (ctx); rc = zmq_ctx_term (ctx); assert (rc == 0); return 0; }