diff --git a/daemons/based/based_remote.c b/daemons/based/based_remote.c index ad51698cf6..d07d31ecca 100644 --- a/daemons/based/based_remote.c +++ b/daemons/based/based_remote.c @@ -1,664 +1,663 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU General Public License version 2 * or later (GPLv2+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include // PRIx64 #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pacemaker-based.h" #include #include #include #if HAVE_SECURITY_PAM_APPL_H # include # define HAVE_PAM 1 #elif HAVE_PAM_PAM_APPL_H # include # define HAVE_PAM 1 #endif extern int remote_tls_fd; extern gboolean cib_shutdown_flag; int init_remote_listener(int port, gboolean encrypted); void cib_remote_connection_destroy(gpointer user_data); gnutls_dh_params_t dh_params; gnutls_anon_server_credentials_t anon_cred_s; // @TODO This is rather short for someone to type their password #define REMOTE_AUTH_TIMEOUT 10000 int num_clients; static bool authenticate_user(const char *user, const char *passwd); static int cib_remote_listen(gpointer data); static int cib_remote_msg(gpointer data); static void remote_connection_destroy(gpointer user_data) { crm_info("No longer listening for remote connections"); return; } int init_remote_listener(int port, gboolean encrypted) { int rc; int *ssock = NULL; struct sockaddr_in saddr; int optval; static struct mainloop_fd_callbacks remote_listen_fd_callbacks = { .dispatch = cib_remote_listen, .destroy = remote_connection_destroy, }; if (port <= 0) { /* don't start it */ return 0; } if (encrypted) { crm_notice("Starting TLS listener on port %d", port); crm_gnutls_global_init(); if (pcmk__init_tls_dh(&dh_params) != pcmk_rc_ok) { return -1; } gnutls_anon_allocate_server_credentials(&anon_cred_s); gnutls_anon_set_server_dh_params(anon_cred_s, dh_params); } else { crm_warn("Starting plain-text listener on port %d", port); } #ifndef HAVE_PAM crm_warn("This build does not support remote administrators " "because PAM support is not available"); #endif /* create server socket */ ssock = malloc(sizeof(int)); if(ssock == NULL) { crm_err("Listener socket allocation failed: %s", pcmk_rc_str(errno)); return -1; } *ssock = socket(AF_INET, SOCK_STREAM, 0); if (*ssock == -1) { crm_err("Listener socket creation failed: %s", pcmk_rc_str(errno)); free(ssock); return -1; } /* reuse address */ optval = 1; rc = setsockopt(*ssock, SOL_SOCKET, SO_REUSEADDR, &optval, sizeof(optval)); if (rc < 0) { crm_err("Local address reuse not allowed on listener socket: %s", pcmk_rc_str(errno)); } /* bind server socket */ memset(&saddr, '\0', sizeof(saddr)); saddr.sin_family = AF_INET; saddr.sin_addr.s_addr = INADDR_ANY; saddr.sin_port = htons(port); if (bind(*ssock, (struct sockaddr *)&saddr, sizeof(saddr)) == -1) { crm_err("Cannot bind to listener socket: %s", pcmk_rc_str(errno)); close(*ssock); free(ssock); return -2; } if (listen(*ssock, 10) == -1) { crm_err("Cannot listen on socket: %s", pcmk_rc_str(errno)); close(*ssock); free(ssock); return -3; } mainloop_add_fd("cib-remote", G_PRIORITY_DEFAULT, *ssock, ssock, &remote_listen_fd_callbacks); crm_debug("Started listener on port %d", port); return *ssock; } static int check_group_membership(const char *usr, const char *grp) { int index = 0; struct passwd *pwd = NULL; struct group *group = NULL; pwd = getpwnam(usr); if (pwd == NULL) { crm_notice("Rejecting remote client: '%s' is not a valid user", usr); return FALSE; } group = getgrgid(pwd->pw_gid); if (group != NULL && pcmk__str_eq(grp, group->gr_name, pcmk__str_none)) { return TRUE; } group = getgrnam(grp); if (group == NULL) { crm_err("Rejecting remote client: '%s' is not a valid group", grp); return FALSE; } while (TRUE) { char *member = group->gr_mem[index++]; if (member == NULL) { break; } else if (pcmk__str_eq(usr, member, pcmk__str_none)) { return TRUE; } } crm_notice("Rejecting remote client: User '%s' is not a member of " "group '%s'", usr, grp); return FALSE; } static gboolean cib_remote_auth(xmlNode * login) { const char *user = NULL; const char *pass = NULL; const char *tmp = NULL; if (login == NULL) { return FALSE; } if (!pcmk__xe_is(login, PCMK__XE_CIB_COMMAND)) { crm_warn("Rejecting remote client: Unrecognizable message " "(element '%s' not '" PCMK__XE_CIB_COMMAND "')", login->name); crm_log_xml_debug(login, "bad"); return FALSE; } tmp = crm_element_value(login, PCMK_XA_OP); if (!pcmk__str_eq(tmp, "authenticate", pcmk__str_casei)) { crm_warn("Rejecting remote client: Unrecognizable message " "(operation '%s' not 'authenticate')", tmp); crm_log_xml_debug(login, "bad"); return FALSE; } user = crm_element_value(login, PCMK_XA_USER); pass = crm_element_value(login, PCMK__XA_PASSWORD); if (!user || !pass) { crm_warn("Rejecting remote client: No %s given", ((user == NULL)? "username" : "password")); crm_log_xml_debug(login, "bad"); return FALSE; } crm_log_xml_debug(login, "auth"); return check_group_membership(user, CRM_DAEMON_GROUP) && authenticate_user(user, pass); } static gboolean remote_auth_timeout_cb(gpointer data) { pcmk__client_t *client = data; client->remote->auth_timeout = 0; if (pcmk_is_set(client->flags, pcmk__client_authenticated)) { return FALSE; } mainloop_del_fd(client->remote->source); crm_err("Remote client authentication timed out"); return FALSE; } static int cib_remote_listen(gpointer data) { int csock = 0; unsigned laddr; struct sockaddr_storage addr; char ipstr[INET6_ADDRSTRLEN]; int ssock = *(int *)data; int rc; pcmk__client_t *new_client = NULL; static struct mainloop_fd_callbacks remote_client_fd_callbacks = { .dispatch = cib_remote_msg, .destroy = cib_remote_connection_destroy, }; /* accept the connection */ laddr = sizeof(addr); memset(&addr, 0, sizeof(addr)); csock = accept(ssock, (struct sockaddr *)&addr, &laddr); if (csock == -1) { crm_warn("Could not accept remote connection: %s", pcmk_rc_str(errno)); return TRUE; } pcmk__sockaddr2str(&addr, ipstr); rc = pcmk__set_nonblocking(csock); if (rc != pcmk_rc_ok) { crm_warn("Dropping remote connection from %s because " "it could not be set to non-blocking: %s", ipstr, pcmk_rc_str(rc)); close(csock); return TRUE; } num_clients++; new_client = pcmk__new_unauth_client(NULL); new_client->remote = pcmk__assert_alloc(1, sizeof(pcmk__remote_t)); if (ssock == remote_tls_fd) { pcmk__set_client_flags(new_client, pcmk__client_tls); /* create gnutls session for the server socket */ new_client->remote->tls_session = pcmk__new_tls_session(csock, GNUTLS_SERVER, GNUTLS_CRD_ANON, anon_cred_s); if (new_client->remote->tls_session == NULL) { close(csock); return TRUE; } } else { pcmk__set_client_flags(new_client, pcmk__client_tcp); new_client->remote->tcp_socket = csock; } // Require the client to authenticate within this time new_client->remote->auth_timeout = pcmk__create_timer(REMOTE_AUTH_TIMEOUT, remote_auth_timeout_cb, new_client); crm_info("%s connection from %s pending authentication for client %s", ((ssock == remote_tls_fd)? "Encrypted" : "Clear-text"), ipstr, new_client->id); new_client->remote->source = mainloop_add_fd("cib-remote-client", G_PRIORITY_DEFAULT, csock, new_client, &remote_client_fd_callbacks); return TRUE; } void cib_remote_connection_destroy(gpointer user_data) { pcmk__client_t *client = user_data; int csock = 0; if (client == NULL) { return; } crm_trace("Cleaning up after client %s disconnect", pcmk__client_name(client)); num_clients--; crm_trace("Num unfree'd clients: %d", num_clients); switch (PCMK__CLIENT_TYPE(client)) { case pcmk__client_tcp: csock = client->remote->tcp_socket; break; case pcmk__client_tls: if (client->remote->tls_session) { - void *sock_ptr = gnutls_transport_get_ptr(*client->remote->tls_session); + void *sock_ptr = gnutls_transport_get_ptr(client->remote->tls_session); csock = GPOINTER_TO_INT(sock_ptr); if (pcmk_is_set(client->flags, pcmk__client_tls_handshake_complete)) { - gnutls_bye(*client->remote->tls_session, GNUTLS_SHUT_WR); + gnutls_bye(client->remote->tls_session, GNUTLS_SHUT_WR); } - gnutls_deinit(*client->remote->tls_session); - gnutls_free(client->remote->tls_session); + gnutls_deinit(client->remote->tls_session); client->remote->tls_session = NULL; } break; default: crm_warn("Unknown transport for client %s " QB_XS " flags=%#016" PRIx64, pcmk__client_name(client), client->flags); } if (csock > 0) { close(csock); } pcmk__free_client(client); crm_trace("Freed the cib client"); if (cib_shutdown_flag) { cib_shutdown(0); } return; } static void cib_handle_remote_msg(pcmk__client_t *client, xmlNode *command) { if (!pcmk__xe_is(command, PCMK__XE_CIB_COMMAND)) { crm_log_xml_trace(command, "bad"); return; } if (client->name == NULL) { client->name = pcmk__str_copy(client->id); } /* unset dangerous options */ pcmk__xe_remove_attr(command, PCMK__XA_SRC); pcmk__xe_remove_attr(command, PCMK__XA_CIB_HOST); pcmk__xe_remove_attr(command, PCMK__XA_CIB_UPDATE); crm_xml_add(command, PCMK__XA_T, PCMK__VALUE_CIB); crm_xml_add(command, PCMK__XA_CIB_CLIENTID, client->id); crm_xml_add(command, PCMK__XA_CIB_CLIENTNAME, client->name); crm_xml_add(command, PCMK__XA_CIB_USER, client->user); if (crm_element_value(command, PCMK__XA_CIB_CALLID) == NULL) { char *call_uuid = crm_generate_uuid(); /* fix the command */ crm_xml_add(command, PCMK__XA_CIB_CALLID, call_uuid); free(call_uuid); } if (crm_element_value(command, PCMK__XA_CIB_CALLOPT) == NULL) { crm_xml_add_int(command, PCMK__XA_CIB_CALLOPT, 0); } crm_log_xml_trace(command, "Remote command: "); cib_common_callback_worker(0, 0, command, client, TRUE); } static int cib_remote_msg(gpointer data) { xmlNode *command = NULL; pcmk__client_t *client = data; int rc; const char *client_name = pcmk__client_name(client); crm_trace("Remote %s message received for client %s", pcmk__client_type_str(PCMK__CLIENT_TYPE(client)), client_name); if ((PCMK__CLIENT_TYPE(client) == pcmk__client_tls) && !pcmk_is_set(client->flags, pcmk__client_tls_handshake_complete)) { int rc = pcmk__read_handshake_data(client); if (rc == EAGAIN) { /* No more data is available at the moment. Just return for now; * we'll get invoked again once the client sends more. */ return 0; } else if (rc != pcmk_rc_ok) { return -1; } crm_debug("Completed TLS handshake with remote client %s", client_name); pcmk__set_client_flags(client, pcmk__client_tls_handshake_complete); if (client->remote->auth_timeout) { g_source_remove(client->remote->auth_timeout); } // Require the client to authenticate within this time client->remote->auth_timeout = pcmk__create_timer(REMOTE_AUTH_TIMEOUT, remote_auth_timeout_cb, client); return 0; } rc = pcmk__read_available_remote_data(client->remote); switch (rc) { case pcmk_rc_ok: break; case EAGAIN: /* We haven't read the whole message yet */ return 0; default: /* Error */ crm_trace("Error reading from remote client: %s", pcmk_rc_str(rc)); return -1; } /* must pass auth before we will process anything else */ if (!pcmk_is_set(client->flags, pcmk__client_authenticated)) { xmlNode *reg; const char *user = NULL; command = pcmk__remote_message_xml(client->remote); if (cib_remote_auth(command) == FALSE) { pcmk__xml_free(command); return -1; } pcmk__set_client_flags(client, pcmk__client_authenticated); g_source_remove(client->remote->auth_timeout); client->remote->auth_timeout = 0; client->name = crm_element_value_copy(command, PCMK_XA_NAME); user = crm_element_value(command, PCMK_XA_USER); if (user) { client->user = pcmk__str_copy(user); } crm_notice("Remote connection accepted for authenticated user %s " QB_XS " client %s", pcmk__s(user, ""), client_name); /* send ACK */ reg = pcmk__xe_create(NULL, PCMK__XE_CIB_RESULT); crm_xml_add(reg, PCMK__XA_CIB_OP, CRM_OP_REGISTER); crm_xml_add(reg, PCMK__XA_CIB_CLIENTID, client->id); pcmk__remote_send_xml(client->remote, reg); pcmk__xml_free(reg); pcmk__xml_free(command); } command = pcmk__remote_message_xml(client->remote); if (command != NULL) { crm_trace("Remote message received from client %s", client_name); cib_handle_remote_msg(client, command); pcmk__xml_free(command); } return 0; } #ifdef HAVE_PAM /*! * \internal * \brief Pass remote user's password to PAM * * \param[in] num_msg Number of entries in \p msg * \param[in] msg Array of PAM messages * \param[out] response Where to set response to PAM * \param[in] data User data (the password string) * * \return PAM return code (PAM_BUF_ERR for memory errors, PAM_CONV_ERR for all * other errors, or PAM_SUCCESS on success) * \note See pam_conv(3) for more explanation */ static int construct_pam_passwd(int num_msg, const struct pam_message **msg, struct pam_response **response, void *data) { /* In theory, multiple messages are allowed, but due to OS compatibility * issues, PAM implementations are recommended to only send one message at a * time. We can require that here for simplicity. */ CRM_CHECK((num_msg == 1) && (msg != NULL) && (response != NULL) && (data != NULL), return PAM_CONV_ERR); switch (msg[0]->msg_style) { case PAM_PROMPT_ECHO_OFF: case PAM_PROMPT_ECHO_ON: // Password requested break; case PAM_TEXT_INFO: crm_info("PAM: %s", msg[0]->msg); data = NULL; break; case PAM_ERROR_MSG: /* In theory we should show msg[0]->msg, but that might * contain the password, which we don't want in the logs */ crm_err("PAM reported an error"); data = NULL; break; default: crm_warn("Ignoring PAM message of unrecognized type %d", msg[0]->msg_style); return PAM_CONV_ERR; } *response = calloc(1, sizeof(struct pam_response)); if (*response == NULL) { return PAM_BUF_ERR; } (*response)->resp_retcode = 0; (*response)->resp = pcmk__str_copy((const char *) data); // Caller will free return PAM_SUCCESS; } #endif /*! * \internal * \brief Verify the username and password passed for a remote CIB connection * * \param[in] user Username passed for remote CIB connection * \param[in] passwd Password passed for remote CIB connection * * \return \c true if the username and password are accepted, otherwise \c false * \note This function rejects all credentials when built without PAM support. */ static bool authenticate_user(const char *user, const char *passwd) { #ifdef HAVE_PAM int rc = 0; bool pass = false; const void *p_user = NULL; struct pam_conv p_conv; struct pam_handle *pam_h = NULL; static const char *pam_name = NULL; if (pam_name == NULL) { pam_name = getenv("CIB_pam_service"); if (pam_name == NULL) { pam_name = "login"; } } p_conv.conv = construct_pam_passwd; p_conv.appdata_ptr = (void *) passwd; rc = pam_start(pam_name, user, &p_conv, &pam_h); if (rc != PAM_SUCCESS) { crm_warn("Rejecting remote client for user %s " "because PAM initialization failed: %s", user, pam_strerror(pam_h, rc)); goto bail; } // Check user credentials rc = pam_authenticate(pam_h, PAM_SILENT); if (rc != PAM_SUCCESS) { crm_notice("Access for remote user %s denied: %s", user, pam_strerror(pam_h, rc)); goto bail; } /* Get the authenticated user name (PAM modules can map the original name to * something else). Since the CIB manager runs as the daemon user (not * root), that is the only user that can be successfully authenticated. */ rc = pam_get_item(pam_h, PAM_USER, &p_user); if (rc != PAM_SUCCESS) { crm_warn("Rejecting remote client for user %s " "because PAM failed to return final user name: %s", user, pam_strerror(pam_h, rc)); goto bail; } if (p_user == NULL) { crm_warn("Rejecting remote client for user %s " "because PAM returned no final user name", user); goto bail; } // @TODO Why do we require these to match? if (!pcmk__str_eq(p_user, user, pcmk__str_none)) { crm_warn("Rejecting remote client for user %s " "because PAM returned different final user name %s", user, p_user); goto bail; } // Check user account restrictions (expiration, etc.) rc = pam_acct_mgmt(pam_h, PAM_SILENT); if (rc != PAM_SUCCESS) { crm_notice("Access for remote user %s denied: %s", user, pam_strerror(pam_h, rc)); goto bail; } pass = true; bail: pam_end(pam_h, rc); return pass; #else // @TODO Implement for non-PAM environments crm_warn("Rejecting remote user %s because this build does not have " "PAM support", user); return false; #endif } diff --git a/daemons/execd/remoted_tls.c b/daemons/execd/remoted_tls.c index 37b6bfbe4d..1ab661f380 100644 --- a/daemons/execd/remoted_tls.c +++ b/daemons/execd/remoted_tls.c @@ -1,441 +1,440 @@ /* * Copyright 2012-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pacemaker-execd.h" #include #define LRMD_REMOTE_AUTH_TIMEOUT 10000 gnutls_psk_server_credentials_t psk_cred_s; gnutls_dh_params_t dh_params; static int ssock = -1; extern int lrmd_call_id; static void debug_log(int level, const char *str) { fputs(str, stderr); } /*! * \internal * \brief Read (more) TLS handshake data from client * * \param[in,out] client IPC client doing handshake * * \return 0 on success or more data needed, -1 on error */ static int remoted__read_handshake_data(pcmk__client_t *client) { int rc = pcmk__read_handshake_data(client); if (rc == EAGAIN) { /* No more data is available at the moment. Just return for now; * we'll get invoked again once the client sends more. */ return 0; } else if (rc != pcmk_rc_ok) { return -1; } if (client->remote->auth_timeout) { g_source_remove(client->remote->auth_timeout); } client->remote->auth_timeout = 0; pcmk__set_client_flags(client, pcmk__client_tls_handshake_complete); crm_notice("Remote client connection accepted"); /* Only a client with access to the TLS key can connect, so we can treat * it as privileged. */ pcmk__set_client_flags(client, pcmk__client_privileged); // Alert other clients of the new connection notify_of_new_client(client); return 0; } static int lrmd_remote_client_msg(gpointer data) { int id = 0; int rc = pcmk_rc_ok; xmlNode *request = NULL; pcmk__client_t *client = data; if (!pcmk_is_set(client->flags, pcmk__client_tls_handshake_complete)) { return remoted__read_handshake_data(client); } rc = pcmk__remote_ready(client->remote, 0); switch (rc) { case pcmk_rc_ok: break; case ETIME: /* No message available to read */ return 0; default: /* Error */ crm_info("Error polling remote client: %s", pcmk_rc_str(rc)); return -1; } rc = pcmk__read_available_remote_data(client->remote); switch (rc) { case pcmk_rc_ok: break; case EAGAIN: /* We haven't read the whole message yet */ return 0; default: /* Error */ crm_info("Error reading from remote client: %s", pcmk_rc_str(rc)); return -1; } request = pcmk__remote_message_xml(client->remote); if (request == NULL) { return 0; } crm_element_value_int(request, PCMK__XA_LRMD_REMOTE_MSG_ID, &id); crm_trace("Processing remote client request %d", id); if (!client->name) { client->name = crm_element_value_copy(request, PCMK__XA_LRMD_CLIENTNAME); } lrmd_call_id++; if (lrmd_call_id < 1) { lrmd_call_id = 1; } crm_xml_add(request, PCMK__XA_LRMD_CLIENTID, client->id); crm_xml_add(request, PCMK__XA_LRMD_CLIENTNAME, client->name); crm_xml_add_int(request, PCMK__XA_LRMD_CALLID, lrmd_call_id); process_lrmd_message(client, id, request); pcmk__xml_free(request); return 0; } static void lrmd_remote_client_destroy(gpointer user_data) { pcmk__client_t *client = user_data; if (client == NULL) { return; } crm_notice("Cleaning up after remote client %s disconnected", pcmk__client_name(client)); ipc_proxy_remove_provider(client); /* if this is the last remote connection, stop recurring * operations */ if (pcmk__ipc_client_count() == 1) { client_disconnect_cleanup(NULL); } if (client->remote->tls_session) { void *sock_ptr; int csock; - sock_ptr = gnutls_transport_get_ptr(*client->remote->tls_session); + sock_ptr = gnutls_transport_get_ptr(client->remote->tls_session); csock = GPOINTER_TO_INT(sock_ptr); - gnutls_bye(*client->remote->tls_session, GNUTLS_SHUT_RDWR); - gnutls_deinit(*client->remote->tls_session); - gnutls_free(client->remote->tls_session); + gnutls_bye(client->remote->tls_session, GNUTLS_SHUT_RDWR); + gnutls_deinit(client->remote->tls_session); client->remote->tls_session = NULL; close(csock); } lrmd_client_destroy(client); return; } static gboolean lrmd_auth_timeout_cb(gpointer data) { pcmk__client_t *client = data; client->remote->auth_timeout = 0; if (pcmk_is_set(client->flags, pcmk__client_tls_handshake_complete)) { return FALSE; } mainloop_del_fd(client->remote->source); client->remote->source = NULL; crm_err("Remote client authentication timed out"); return FALSE; } // Dispatch callback for remote server socket static int lrmd_remote_listen(gpointer data) { int csock = -1; - gnutls_session_t *session = NULL; + gnutls_session_t session = NULL; pcmk__client_t *new_client = NULL; // For client socket static struct mainloop_fd_callbacks lrmd_remote_fd_cb = { .dispatch = lrmd_remote_client_msg, .destroy = lrmd_remote_client_destroy, }; CRM_CHECK(ssock >= 0, return TRUE); if (pcmk__accept_remote_connection(ssock, &csock) != pcmk_rc_ok) { return TRUE; } session = pcmk__new_tls_session(csock, GNUTLS_SERVER, GNUTLS_CRD_PSK, psk_cred_s); if (session == NULL) { close(csock); return TRUE; } new_client = pcmk__new_unauth_client(NULL); new_client->remote = pcmk__assert_alloc(1, sizeof(pcmk__remote_t)); pcmk__set_client_flags(new_client, pcmk__client_tls); new_client->remote->tls_session = session; // Require the client to authenticate within this time new_client->remote->auth_timeout = pcmk__create_timer(LRMD_REMOTE_AUTH_TIMEOUT, lrmd_auth_timeout_cb, new_client); crm_info("Remote client pending authentication " QB_XS " %p id: %s", new_client, new_client->id); new_client->remote->source = mainloop_add_fd("pacemaker-remote-client", G_PRIORITY_DEFAULT, csock, new_client, &lrmd_remote_fd_cb); return TRUE; } static void tls_server_dropped(gpointer user_data) { crm_notice("TLS server session ended"); return; } // \return 0 on success, -1 on error (gnutls_psk_server_credentials_function) static int lrmd_tls_server_key_cb(gnutls_session_t session, const char *username, gnutls_datum_t * key) { return (lrmd__init_remote_key(key) == pcmk_rc_ok)? 0 : -1; } static int bind_and_listen(struct addrinfo *addr) { int optval; int fd; int rc; char buffer[INET6_ADDRSTRLEN] = { 0, }; pcmk__sockaddr2str(addr->ai_addr, buffer); crm_trace("Attempting to bind to address %s", buffer); fd = socket(addr->ai_family, addr->ai_socktype, addr->ai_protocol); if (fd < 0) { rc = errno; crm_err("Listener socket creation failed: %", pcmk_rc_str(rc)); return -rc; } /* reuse address */ optval = 1; rc = setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &optval, sizeof(optval)); if (rc < 0) { rc = errno; crm_err("Local address reuse not allowed on %s: %s", buffer, pcmk_rc_str(rc)); close(fd); return -rc; } if (addr->ai_family == AF_INET6) { optval = 0; rc = setsockopt(fd, IPPROTO_IPV6, IPV6_V6ONLY, &optval, sizeof(optval)); if (rc < 0) { rc = errno; crm_err("Couldn't disable IPV6-only on %s: %s", buffer, pcmk_rc_str(rc)); close(fd); return -rc; } } if (bind(fd, addr->ai_addr, addr->ai_addrlen) != 0) { rc = errno; crm_err("Cannot bind to %s: %s", buffer, pcmk_rc_str(rc)); close(fd); return -rc; } if (listen(fd, 10) == -1) { rc = errno; crm_err("Cannot listen on %s: %s", buffer, pcmk_rc_str(rc)); close(fd); return -rc; } return fd; } static int get_address_info(const char *bind_name, int port, struct addrinfo **res) { int rc; char port_str[6]; // at most "65535" struct addrinfo hints; memset(&hints, 0, sizeof(struct addrinfo)); hints.ai_flags = AI_PASSIVE; hints.ai_family = AF_UNSPEC; // IPv6 or IPv4 hints.ai_socktype = SOCK_STREAM; hints.ai_protocol = IPPROTO_TCP; snprintf(port_str, sizeof(port_str), "%d", port); rc = getaddrinfo(bind_name, port_str, &hints, res); rc = pcmk__gaierror2rc(rc); if (rc != pcmk_rc_ok) { crm_err("Unable to get IP address(es) for %s: %s", (bind_name? bind_name : "local node"), pcmk_rc_str(rc)); return rc; } return pcmk_rc_ok; } int lrmd_init_remote_tls_server(void) { int filter; int port = crm_default_remote_port(); struct addrinfo *res = NULL, *iter; gnutls_datum_t psk_key = { NULL, 0 }; const char *bind_name = pcmk__env_option(PCMK__ENV_REMOTE_ADDRESS); static struct mainloop_fd_callbacks remote_listen_fd_callbacks = { .dispatch = lrmd_remote_listen, .destroy = tls_server_dropped, }; CRM_CHECK(ssock == -1, return ssock); crm_debug("Starting TLS listener on %s port %d", (bind_name? bind_name : "all addresses on"), port); crm_gnutls_global_init(); gnutls_global_set_log_function(debug_log); if (pcmk__init_tls_dh(&dh_params) != pcmk_rc_ok) { return -1; } gnutls_psk_allocate_server_credentials(&psk_cred_s); gnutls_psk_set_server_credentials_function(psk_cred_s, lrmd_tls_server_key_cb); gnutls_psk_set_server_dh_params(psk_cred_s, dh_params); /* The key callback won't get called until the first client connection * attempt. Do it once here, so we can warn the user at start-up if we can't * read the key. We don't error out, though, because it's fine if the key is * going to be added later. */ if (lrmd__init_remote_key(&psk_key) != pcmk_rc_ok) { crm_warn("A cluster connection will not be possible until the key is available"); } gnutls_free(psk_key.data); if (get_address_info(bind_name, port, &res) != pcmk_rc_ok) { return -1; } /* Currently we listen on only one address from the resulting list (the * first IPv6 address we can bind to if possible, otherwise the first IPv4 * address we can bind to). When bind_name is NULL, this should be the * respective wildcard address. * * @TODO If there is demand for specifying more than one address, allow * bind_name to be a space-separated list, call getaddrinfo() for each, * and create a socket for each result (set IPV6_V6ONLY on IPv6 sockets * since IPv4 listeners will have their own sockets). */ iter = res; filter = AF_INET6; while (iter) { if (iter->ai_family == filter) { ssock = bind_and_listen(iter); } if (ssock >= 0) { break; } iter = iter->ai_next; if (iter == NULL && filter == AF_INET6) { iter = res; filter = AF_INET; } } if (ssock >= 0) { mainloop_add_fd("pacemaker-remote-server", G_PRIORITY_DEFAULT, ssock, NULL, &remote_listen_fd_callbacks); crm_debug("Started TLS listener on %s port %d", (bind_name? bind_name : "all addresses on"), port); } freeaddrinfo(res); return ssock; } void execd_stop_tls_server(void) { if (psk_cred_s) { gnutls_psk_free_server_credentials(psk_cred_s); psk_cred_s = 0; } if (ssock >= 0) { close(ssock); ssock = -1; } } diff --git a/include/crm/common/ipc_internal.h b/include/crm/common/ipc_internal.h index a405a5a142..9fe96609ef 100644 --- a/include/crm/common/ipc_internal.h +++ b/include/crm/common/ipc_internal.h @@ -1,284 +1,284 @@ /* * Copyright 2013-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #ifndef PCMK__CRM_COMMON_IPC_INTERNAL__H #define PCMK__CRM_COMMON_IPC_INTERNAL__H #include // bool #include // uint32_t, uint64_t, UINT64_C() #include // struct iovec #include // uid_t, gid_t, pid_t, size_t #include // gnutls_session_t #include // guint, gpointer, GQueue, ... #include // xmlNode #include // qb_ipcs_connection_t, ... #include // HAVE_GETPEEREID #include #include // pcmk_controld_api_reply #include // pcmk_pacemakerd_{api_reply,state} #include // mainloop_io_t #ifdef __cplusplus extern "C" { #endif /* denotes "non yieldable PID" on FreeBSD, or actual PID1 in scenarios that require a delicate handling anyway (socket-based activation with systemd); we can be reasonably sure that this PID is never possessed by the actual child daemon, as it gets taken either by the proper init, or by pacemakerd itself (i.e. this precludes anything else); note that value of zero is meant to carry "unset" meaning, and better not to bet on/conditionalize over signedness of pid_t */ #define PCMK__SPECIAL_PID 1 // Timeout (in seconds) to use for IPC client sends, reply waits, etc. #define PCMK__IPC_TIMEOUT 120 #if defined(HAVE_GETPEEREID) /* on FreeBSD, we don't want to expose "non-yieldable PID" (leading to "IPC liveness check only") as its nominal representation, which could cause confusion -- this is unambiguous as long as there's no socket-based activation like with systemd (very improbable) */ #define PCMK__SPECIAL_PID_AS_0(p) (((p) == PCMK__SPECIAL_PID) ? 0 : (p)) #else #define PCMK__SPECIAL_PID_AS_0(p) (p) #endif /*! * \internal * \brief Check the authenticity and liveness of the process via IPC end-point * * When IPC daemon under given IPC end-point (name) detected, its authenticity * is verified by the means of comparing against provided referential UID and * GID, and the result of this check can be deduced from the return value. * As an exception, referential UID of 0 (~ root) satisfies arbitrary * detected daemon's credentials. * * \param[in] name IPC name to base the search on * \param[in] refuid referential UID to check against * \param[in] refgid referential GID to check against * \param[out] gotpid to optionally store obtained PID of the found process * upon returning 1 or -2 * (not available on FreeBSD, special value of 1, * see PCMK__SPECIAL_PID, used instead, and the caller * is required to special case this value respectively) * * \return Standard Pacemaker return code * * \note Return codes of particular interest include pcmk_rc_ipc_unresponsive * indicating that no trace of IPC liveness was detected, and * pcmk_rc_ipc_unauthorized indicating that the IPC endpoint is blocked by * an unauthorized process. * \note This function emits a log message for return codes other than * pcmk_rc_ok and pcmk_rc_ipc_unresponsive, and when there isn't a perfect * match in respect to \p reguid and/or \p refgid, for a possible * least privilege principle violation. * * \see crm_ipc_is_authentic_process */ int pcmk__ipc_is_authentic_process_active(const char *name, uid_t refuid, gid_t refgid, pid_t *gotpid); int pcmk__connect_generic_ipc(crm_ipc_t *ipc); int pcmk__ipc_fd(crm_ipc_t *ipc, int *fd); int pcmk__connect_ipc(pcmk_ipc_api_t *api, enum pcmk_ipc_dispatch dispatch_type, int attempts); /* * Server-related */ typedef struct pcmk__client_s pcmk__client_t; struct pcmk__remote_s { /* Shared */ char *buffer; size_t buffer_size; size_t buffer_offset; int auth_timeout; int tcp_socket; mainloop_io_t *source; time_t uptime; char *start_state; /* CIB-only */ char *token; /* TLS only */ - gnutls_session_t *tls_session; + gnutls_session_t tls_session; }; enum pcmk__client_flags { // Lower 32 bits are reserved for server (not library) use // Next 8 bits are reserved for client type (sort of a cheap enum) //! Client uses plain IPC pcmk__client_ipc = (UINT64_C(1) << 32), //! Client uses TCP connection pcmk__client_tcp = (UINT64_C(1) << 33), //! Client uses TCP with TLS pcmk__client_tls = (UINT64_C(1) << 34), // The rest are client attributes //! Client IPC is proxied pcmk__client_proxied = (UINT64_C(1) << 40), //! Client is run by root or cluster user pcmk__client_privileged = (UINT64_C(1) << 41), //! Local client to be proxied pcmk__client_to_proxy = (UINT64_C(1) << 42), /*! * \brief Client IPC connection accepted * * Used only for remote CIB connections via \c PCMK_XA_REMOTE_TLS_PORT. */ pcmk__client_authenticated = (UINT64_C(1) << 43), //! Client TLS handshake is complete pcmk__client_tls_handshake_complete = (UINT64_C(1) << 44), }; #define PCMK__CLIENT_TYPE(client) ((client)->flags & UINT64_C(0xff00000000)) struct pcmk__client_s { unsigned int pid; char *id; char *name; char *user; uint64_t flags; // Group of pcmk__client_flags int request_id; void *userdata; int event_timer; GQueue *event_queue; /* Depending on the client type, only some of the following will be * populated/valid. @TODO Maybe convert to a union. */ qb_ipcs_connection_t *ipcs; /* IPC */ struct pcmk__remote_s *remote; /* TCP/TLS */ unsigned int queue_backlog; /* IPC queue length after last flush */ unsigned int queue_max; /* Evict client whose queue grows this big */ }; #define pcmk__set_client_flags(client, flags_to_set) do { \ (client)->flags = pcmk__set_flags_as(__func__, __LINE__, \ LOG_TRACE, \ "Client", pcmk__client_name(client), \ (client)->flags, (flags_to_set), #flags_to_set); \ } while (0) #define pcmk__clear_client_flags(client, flags_to_clear) do { \ (client)->flags = pcmk__clear_flags_as(__func__, __LINE__, \ LOG_TRACE, \ "Client", pcmk__client_name(client), \ (client)->flags, (flags_to_clear), #flags_to_clear); \ } while (0) #define pcmk__set_ipc_flags(ipc_flags, ipc_name, flags_to_set) do { \ ipc_flags = pcmk__set_flags_as(__func__, __LINE__, LOG_TRACE, \ "IPC", (ipc_name), \ (ipc_flags), (flags_to_set), \ #flags_to_set); \ } while (0) #define pcmk__clear_ipc_flags(ipc_flags, ipc_name, flags_to_clear) do { \ ipc_flags = pcmk__clear_flags_as(__func__, __LINE__, LOG_TRACE, \ "IPC", (ipc_name), \ (ipc_flags), (flags_to_clear), \ #flags_to_clear); \ } while (0) guint pcmk__ipc_client_count(void); void pcmk__foreach_ipc_client(GHFunc func, gpointer user_data); void pcmk__client_cleanup(void); pcmk__client_t *pcmk__find_client(const qb_ipcs_connection_t *c); pcmk__client_t *pcmk__find_client_by_id(const char *id); const char *pcmk__client_name(const pcmk__client_t *c); const char *pcmk__client_type_str(uint64_t client_type); pcmk__client_t *pcmk__new_unauth_client(void *key); pcmk__client_t *pcmk__new_client(qb_ipcs_connection_t *c, uid_t uid, gid_t gid); void pcmk__free_client(pcmk__client_t *c); void pcmk__drop_all_clients(qb_ipcs_service_t *s); void pcmk__set_client_queue_max(pcmk__client_t *client, const char *qmax); xmlNode *pcmk__ipc_create_ack_as(const char *function, int line, uint32_t flags, const char *tag, const char *ver, crm_exit_t status); #define pcmk__ipc_create_ack(flags, tag, ver, st) \ pcmk__ipc_create_ack_as(__func__, __LINE__, (flags), (tag), (ver), (st)) int pcmk__ipc_send_ack_as(const char *function, int line, pcmk__client_t *c, uint32_t request, uint32_t flags, const char *tag, const char *ver, crm_exit_t status); #define pcmk__ipc_send_ack(c, req, flags, tag, ver, st) \ pcmk__ipc_send_ack_as(__func__, __LINE__, (c), (req), (flags), (tag), (ver), (st)) int pcmk__ipc_prepare_iov(uint32_t request, const xmlNode *message, uint32_t max_send_size, struct iovec **result, ssize_t *bytes); int pcmk__ipc_send_xml(pcmk__client_t *c, uint32_t request, const xmlNode *message, uint32_t flags); int pcmk__ipc_send_iov(pcmk__client_t *c, struct iovec *iov, uint32_t flags); xmlNode *pcmk__client_data2xml(pcmk__client_t *c, void *data, uint32_t *id, uint32_t *flags); int pcmk__client_pid(qb_ipcs_connection_t *c); void pcmk__serve_attrd_ipc(qb_ipcs_service_t **ipcs, struct qb_ipcs_service_handlers *cb); void pcmk__serve_fenced_ipc(qb_ipcs_service_t **ipcs, struct qb_ipcs_service_handlers *cb); void pcmk__serve_pacemakerd_ipc(qb_ipcs_service_t **ipcs, struct qb_ipcs_service_handlers *cb); qb_ipcs_service_t *pcmk__serve_schedulerd_ipc(struct qb_ipcs_service_handlers *cb); qb_ipcs_service_t *pcmk__serve_controld_ipc(struct qb_ipcs_service_handlers *cb); void pcmk__serve_based_ipc(qb_ipcs_service_t **ipcs_ro, qb_ipcs_service_t **ipcs_rw, qb_ipcs_service_t **ipcs_shm, struct qb_ipcs_service_handlers *ro_cb, struct qb_ipcs_service_handlers *rw_cb); void pcmk__stop_based_ipc(qb_ipcs_service_t *ipcs_ro, qb_ipcs_service_t *ipcs_rw, qb_ipcs_service_t *ipcs_shm); static inline const char * pcmk__ipc_sys_name(const char *ipc_name, const char *fallback) { return ipc_name ? ipc_name : ((crm_system_name ? crm_system_name : fallback)); } const char *pcmk__pcmkd_state_enum2friendly(enum pcmk_pacemakerd_state state); const char *pcmk__controld_api_reply2str(enum pcmk_controld_api_reply reply); const char *pcmk__pcmkd_api_reply2str(enum pcmk_pacemakerd_api_reply reply); #ifdef __cplusplus } #endif #endif // PCMK__CRM_COMMON_IPC_INTERNAL__H diff --git a/include/crm/common/tls_internal.h b/include/crm/common/tls_internal.h index 88732e2d7b..c4eebc2caf 100644 --- a/include/crm/common/tls_internal.h +++ b/include/crm/common/tls_internal.h @@ -1,99 +1,99 @@ /* * Copyright 2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #ifndef PCMK__CRM_COMMON_TLS_INTERNAL__H #define PCMK__CRM_COMMON_TLS_INTERNAL__H #include // gnutls_session_t, gnutls_dh_params_t, etc. #include // pcmk__client_t #include // pcmk__remote_t #ifdef __cplusplus extern "C" { #endif /*! * \internal * \brief Initialize Diffie-Hellman parameters for a TLS server * * \param[out] dh_params Parameter object to initialize * * \return Standard Pacemaker return code * \todo The current best practice is to allow the client and server to * negotiate the Diffie-Hellman parameters via a TLS extension (RFC 7919). * However, we have to support both older versions of GnuTLS (<3.6) that * don't support the extension on our side, and older Pacemaker versions * that don't support the extension on the other side. The next best * practice would be to use a known good prime (see RFC 5114 section 2.2), * possibly stored in a file distributed with Pacemaker. */ int pcmk__init_tls_dh(gnutls_dh_params_t *dh_params); /*! * \internal * \brief Initialize a new TLS session * * \param[in] csock Connected socket for TLS session * \param[in] conn_type GNUTLS_SERVER or GNUTLS_CLIENT * \param[in] cred_type GNUTLS_CRD_ANON or GNUTLS_CRD_PSK * \param[in] credentials TLS session credentials * * \return Pointer to newly created session object, or NULL on error */ -gnutls_session_t *pcmk__new_tls_session(int csock, unsigned int conn_type, - gnutls_credentials_type_t cred_type, - void *credentials); +gnutls_session_t pcmk__new_tls_session(int csock, unsigned int conn_type, + gnutls_credentials_type_t cred_type, + void *credentials); /*! * \internal * \brief Process handshake data from TLS client * * Read as much TLS handshake data as is available. * * \param[in] client Client connection * * \return Standard Pacemaker return code (of particular interest, EAGAIN * if some data was successfully read but more data is needed) */ int pcmk__read_handshake_data(const pcmk__client_t *client); /*! * \internal * \brief Perform client TLS handshake after establishing TCP socket * * \param[in,out] remote Newly established remote connection * \param[in] timeout_sec Abort handshake if not completed within this time * \param[out] gnutls_rc If this is non-NULL, it will be set to the GnuTLS * rc (for logging) if this function returns EPROTO, * otherwise GNUTLS_E_SUCCESS * * \return Standard Pacemaker return code */ int pcmk__tls_client_handshake(pcmk__remote_t *remote, int timeout_sec, int *gnutls_rc); /*! * \internal * \brief Make a single attempt to perform the client TLS handshake * * \param[in,out] remote Newly established remote connection * \param[out] gnutls_rc If this is non-NULL, it will be set to the GnuTLS * rc (for logging) if this function returns EPROTO, * otherwise GNUTLS_E_SUCCESS * * \return Standard Pacemaker return code */ int pcmk__tls_client_try_handshake(pcmk__remote_t *remote, int *gnutls_rc); #ifdef __cplusplus } #endif #endif // PCMK__CRM_COMMON_TLS_INTERNAL__H diff --git a/lib/cib/cib_remote.c b/lib/cib/cib_remote.c index 4b1a1e2894..1a1a852073 100644 --- a/lib/cib/cib_remote.c +++ b/lib/cib/cib_remote.c @@ -1,676 +1,673 @@ /* * Copyright 2008-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // GnuTLS handshake timeout in seconds #define TLS_HANDSHAKE_TIMEOUT 5 static gnutls_anon_client_credentials_t anon_cred_c; static gboolean remote_gnutls_credentials_init = FALSE; #include typedef struct cib_remote_opaque_s { int port; char *server; char *user; char *passwd; gboolean encrypted; pcmk__remote_t command; pcmk__remote_t callback; pcmk__output_t *out; time_t start_time; int timeout_sec; } cib_remote_opaque_t; static int cib_remote_perform_op(cib_t *cib, const char *op, const char *host, const char *section, xmlNode *data, xmlNode **output_data, int call_options, const char *user_name) { int rc; int remaining_time = 0; time_t start_time; xmlNode *op_msg = NULL; xmlNode *op_reply = NULL; cib_remote_opaque_t *private = cib->variant_opaque; if (cib->state == cib_disconnected) { return -ENOTCONN; } if (output_data != NULL) { *output_data = NULL; } if (op == NULL) { crm_err("No operation specified"); return -EINVAL; } rc = cib__create_op(cib, op, host, section, data, call_options, user_name, NULL, &op_msg); if (rc != pcmk_ok) { return rc; } if (pcmk_is_set(call_options, cib_transaction)) { rc = cib__extend_transaction(cib, op_msg); pcmk__xml_free(op_msg); return rc; } crm_trace("Sending %s message to the CIB manager", op); if (!(call_options & cib_sync_call)) { pcmk__remote_send_xml(&private->callback, op_msg); } else { pcmk__remote_send_xml(&private->command, op_msg); } pcmk__xml_free(op_msg); if ((call_options & cib_discard_reply)) { crm_trace("Discarding reply"); return pcmk_ok; } else if (!(call_options & cib_sync_call)) { return cib->call_id; } crm_trace("Waiting for a synchronous reply"); start_time = time(NULL); remaining_time = cib->call_timeout ? cib->call_timeout : 60; rc = pcmk_rc_ok; while (remaining_time > 0 && (rc != ENOTCONN)) { int reply_id = -1; int msg_id = cib->call_id; rc = pcmk__read_remote_message(&private->command, remaining_time * 1000); op_reply = pcmk__remote_message_xml(&private->command); if (!op_reply) { break; } crm_element_value_int(op_reply, PCMK__XA_CIB_CALLID, &reply_id); if (reply_id == msg_id) { break; } else if (reply_id < msg_id) { crm_debug("Received old reply: %d (wanted %d)", reply_id, msg_id); crm_log_xml_trace(op_reply, "Old reply"); } else if ((reply_id - 10000) > msg_id) { /* wrap-around case */ crm_debug("Received old reply: %d (wanted %d)", reply_id, msg_id); crm_log_xml_trace(op_reply, "Old reply"); } else { crm_err("Received a __future__ reply:" " %d (wanted %d)", reply_id, msg_id); } pcmk__xml_free(op_reply); op_reply = NULL; /* wasn't the right reply, try and read some more */ remaining_time = time(NULL) - start_time; } if (rc == ENOTCONN) { crm_err("Disconnected while waiting for reply."); return -ENOTCONN; } else if (op_reply == NULL) { crm_err("No reply message - empty"); return -ENOMSG; } crm_trace("Synchronous reply received"); /* Start processing the reply... */ if (crm_element_value_int(op_reply, PCMK__XA_CIB_RC, &rc) != 0) { rc = -EPROTO; } if (rc == -pcmk_err_diff_resync) { /* This is an internal value that clients do not and should not care about */ rc = pcmk_ok; } if (rc == pcmk_ok || rc == -EPERM) { crm_log_xml_debug(op_reply, "passed"); } else { crm_err("Call failed: %s", pcmk_strerror(rc)); crm_log_xml_warn(op_reply, "failed"); } if (output_data == NULL) { /* do nothing more */ } else if (!(call_options & cib_discard_reply)) { xmlNode *wrapper = pcmk__xe_first_child(op_reply, PCMK__XE_CIB_CALLDATA, NULL, NULL); xmlNode *tmp = pcmk__xe_first_child(wrapper, NULL, NULL, NULL); if (tmp == NULL) { crm_trace("No output in reply to \"%s\" command %d", op, cib->call_id - 1); } else { *output_data = pcmk__xml_copy(NULL, tmp); } } pcmk__xml_free(op_reply); return rc; } static int cib_remote_callback_dispatch(gpointer user_data) { int rc; cib_t *cib = user_data; cib_remote_opaque_t *private = cib->variant_opaque; xmlNode *msg = NULL; const char *type = NULL; /* If start time is 0, we've previously handled a complete message and this * connection is being reused for a new message. Reset the start_time, * giving this new message timeout_sec from now to complete. */ if (private->start_time == 0) { private->start_time = time(NULL); } rc = pcmk__read_available_remote_data(&private->callback); switch (rc) { case pcmk_rc_ok: /* We have the whole message so process it */ break; case EAGAIN: /* Have we timed out? */ if (time(NULL) >= private->start_time + private->timeout_sec) { crm_info("Error reading from CIB manager connection: %s", pcmk_rc_str(ETIME)); return -1; } /* We haven't read the whole message yet */ return 0; default: /* Error */ crm_info("Error reading from CIB manager connection: %s", pcmk_rc_str(rc)); return -1; } msg = pcmk__remote_message_xml(&private->callback); if (msg == NULL) { private->start_time = 0; return 0; } type = crm_element_value(msg, PCMK__XA_T); crm_trace("Activating %s callbacks...", type); if (pcmk__str_eq(type, PCMK__VALUE_CIB, pcmk__str_none)) { cib_native_callback(cib, msg, 0, 0); } else if (pcmk__str_eq(type, PCMK__VALUE_CIB_NOTIFY, pcmk__str_none)) { g_list_foreach(cib->notify_list, cib_native_notify, msg); } else { crm_err("Unknown message type: %s", type); } pcmk__xml_free(msg); private->start_time = 0; return 0; } static int cib_remote_command_dispatch(gpointer user_data) { int rc; cib_t *cib = user_data; cib_remote_opaque_t *private = cib->variant_opaque; /* See cib_remote_callback_dispatch */ if (private->start_time == 0) { private->start_time = time(NULL); } rc = pcmk__read_available_remote_data(&private->command); if (rc == EAGAIN) { /* Have we timed out? */ if (time(NULL) >= private->start_time + private->timeout_sec) { crm_info("Error reading from CIB manager connection: %s", pcmk_rc_str(ETIME)); return -1; } /* We haven't read the whole message yet */ return 0; } free(private->command.buffer); private->command.buffer = NULL; crm_err("received late reply for remote cib connection, discarding"); if (rc != pcmk_rc_ok) { crm_info("Error reading from CIB manager connection: %s", pcmk_rc_str(rc)); return -1; } private->start_time = 0; return 0; } static int cib_tls_close(cib_t *cib) { cib_remote_opaque_t *private = cib->variant_opaque; if (private->encrypted) { if (private->command.tls_session) { - gnutls_bye(*(private->command.tls_session), GNUTLS_SHUT_RDWR); - gnutls_deinit(*(private->command.tls_session)); - gnutls_free(private->command.tls_session); + gnutls_bye(private->command.tls_session, GNUTLS_SHUT_RDWR); + gnutls_deinit(private->command.tls_session); } if (private->callback.tls_session) { - gnutls_bye(*(private->callback.tls_session), GNUTLS_SHUT_RDWR); - gnutls_deinit(*(private->callback.tls_session)); - gnutls_free(private->callback.tls_session); + gnutls_bye(private->callback.tls_session, GNUTLS_SHUT_RDWR); + gnutls_deinit(private->callback.tls_session); } private->command.tls_session = NULL; private->callback.tls_session = NULL; if (remote_gnutls_credentials_init) { gnutls_anon_free_client_credentials(anon_cred_c); gnutls_global_deinit(); remote_gnutls_credentials_init = FALSE; } } if (private->command.tcp_socket) { shutdown(private->command.tcp_socket, SHUT_RDWR); /* no more receptions */ close(private->command.tcp_socket); } if (private->callback.tcp_socket) { shutdown(private->callback.tcp_socket, SHUT_RDWR); /* no more receptions */ close(private->callback.tcp_socket); } private->command.tcp_socket = 0; private->callback.tcp_socket = 0; free(private->command.buffer); free(private->callback.buffer); private->command.buffer = NULL; private->callback.buffer = NULL; return 0; } static void cib_remote_connection_destroy(gpointer user_data) { crm_err("Connection destroyed"); cib_tls_close(user_data); } static int cib_tls_signon(cib_t *cib, pcmk__remote_t *connection, gboolean event_channel) { cib_remote_opaque_t *private = cib->variant_opaque; int rc; xmlNode *answer = NULL; xmlNode *login = NULL; static struct mainloop_fd_callbacks cib_fd_callbacks = { 0, }; cib_fd_callbacks.dispatch = event_channel ? cib_remote_callback_dispatch : cib_remote_command_dispatch; cib_fd_callbacks.destroy = cib_remote_connection_destroy; connection->tcp_socket = -1; connection->tls_session = NULL; rc = pcmk__connect_remote(private->server, private->port, 0, NULL, &(connection->tcp_socket), NULL, NULL); if (rc != pcmk_rc_ok) { crm_info("Remote connection to %s:%d failed: %s " QB_XS " rc=%d", private->server, private->port, pcmk_rc_str(rc), rc); return -ENOTCONN; } if (private->encrypted) { int tls_rc = GNUTLS_E_SUCCESS; /* initialize GnuTls lib */ if (remote_gnutls_credentials_init == FALSE) { crm_gnutls_global_init(); gnutls_anon_allocate_client_credentials(&anon_cred_c); remote_gnutls_credentials_init = TRUE; } /* bind the socket to GnuTls lib */ connection->tls_session = pcmk__new_tls_session(connection->tcp_socket, GNUTLS_CLIENT, GNUTLS_CRD_ANON, anon_cred_c); if (connection->tls_session == NULL) { cib_tls_close(cib); return -1; } rc = pcmk__tls_client_handshake(connection, TLS_HANDSHAKE_TIMEOUT, &tls_rc); if (rc != pcmk_rc_ok) { crm_err("Remote CIB session creation for %s:%d failed: %s", private->server, private->port, (rc == EPROTO)? gnutls_strerror(tls_rc) : pcmk_rc_str(rc)); - gnutls_deinit(*connection->tls_session); - gnutls_free(connection->tls_session); + gnutls_deinit(connection->tls_session); connection->tls_session = NULL; cib_tls_close(cib); return -1; } } /* login to server */ login = pcmk__xe_create(NULL, PCMK__XE_CIB_COMMAND); crm_xml_add(login, PCMK_XA_OP, "authenticate"); crm_xml_add(login, PCMK_XA_USER, private->user); crm_xml_add(login, PCMK__XA_PASSWORD, private->passwd); crm_xml_add(login, PCMK__XA_HIDDEN, PCMK__VALUE_PASSWORD); pcmk__remote_send_xml(connection, login); pcmk__xml_free(login); rc = pcmk_ok; if (pcmk__read_remote_message(connection, -1) == ENOTCONN) { rc = -ENOTCONN; } answer = pcmk__remote_message_xml(connection); crm_log_xml_trace(answer, "Reply"); if (answer == NULL) { rc = -EPROTO; } else { /* grab the token */ const char *msg_type = crm_element_value(answer, PCMK__XA_CIB_OP); const char *tmp_ticket = crm_element_value(answer, PCMK__XA_CIB_CLIENTID); if (!pcmk__str_eq(msg_type, CRM_OP_REGISTER, pcmk__str_casei)) { crm_err("Invalid registration message: %s", msg_type); rc = -EPROTO; } else if (tmp_ticket == NULL) { rc = -EPROTO; } else { connection->token = strdup(tmp_ticket); } } pcmk__xml_free(answer); answer = NULL; if (rc != 0) { cib_tls_close(cib); return rc; } crm_trace("remote client connection established"); private->timeout_sec = 60; connection->source = mainloop_add_fd("cib-remote", G_PRIORITY_HIGH, connection->tcp_socket, cib, &cib_fd_callbacks); return rc; } static int cib_remote_signon(cib_t *cib, const char *name, enum cib_conn_type type) { int rc = pcmk_ok; cib_remote_opaque_t *private = cib->variant_opaque; xmlNode *hello = NULL; if (name == NULL) { name = pcmk__s(crm_system_name, "client"); } if (private->passwd == NULL) { if (private->out == NULL) { /* If no pcmk__output_t is set, just assume that a text prompt * is good enough. */ pcmk__text_prompt("Password", false, &(private->passwd)); } else { private->out->prompt("Password", false, &(private->passwd)); } } if (private->server == NULL || private->user == NULL) { rc = -EINVAL; goto done; } rc = cib_tls_signon(cib, &(private->command), FALSE); if (rc != pcmk_ok) { goto done; } rc = cib_tls_signon(cib, &(private->callback), TRUE); if (rc != pcmk_ok) { goto done; } rc = cib__create_op(cib, CRM_OP_REGISTER, NULL, NULL, NULL, cib_none, NULL, name, &hello); if (rc != pcmk_ok) { goto done; } rc = pcmk__remote_send_xml(&private->command, hello); rc = pcmk_rc2legacy(rc); pcmk__xml_free(hello); done: if (rc == pcmk_ok) { crm_info("Opened connection to %s:%d for %s", private->server, private->port, name); cib->state = cib_connected_command; cib->type = cib_command; } else { crm_info("Connection to %s:%d for %s failed: %s\n", private->server, private->port, name, pcmk_strerror(rc)); } return rc; } static int cib_remote_signoff(cib_t *cib) { int rc = pcmk_ok; crm_debug("Disconnecting from the CIB manager"); cib_tls_close(cib); cib->cmds->end_transaction(cib, false, cib_none); cib->state = cib_disconnected; cib->type = cib_no_connection; return rc; } static int cib_remote_free(cib_t *cib) { int rc = pcmk_ok; crm_warn("Freeing CIB"); if (cib->state != cib_disconnected) { rc = cib_remote_signoff(cib); if (rc == pcmk_ok) { cib_remote_opaque_t *private = cib->variant_opaque; free(private->server); free(private->user); free(private->passwd); free(cib->cmds); free(cib->user); free(private); free(cib); } } return rc; } static int cib_remote_register_notification(cib_t * cib, const char *callback, int enabled) { xmlNode *notify_msg = pcmk__xe_create(NULL, PCMK__XE_CIB_COMMAND); cib_remote_opaque_t *private = cib->variant_opaque; crm_xml_add(notify_msg, PCMK__XA_CIB_OP, PCMK__VALUE_CIB_NOTIFY); crm_xml_add(notify_msg, PCMK__XA_CIB_NOTIFY_TYPE, callback); crm_xml_add_int(notify_msg, PCMK__XA_CIB_NOTIFY_ACTIVATE, enabled); pcmk__remote_send_xml(&private->callback, notify_msg); pcmk__xml_free(notify_msg); return pcmk_ok; } static int cib_remote_set_connection_dnotify(cib_t * cib, void (*dnotify) (gpointer user_data)) { return -EPROTONOSUPPORT; } /*! * \internal * \brief Get the given CIB connection's unique client identifiers * * These can be used to check whether this client requested the action that * triggered a CIB notification. * * \param[in] cib CIB connection * \param[out] async_id If not \p NULL, where to store asynchronous client ID * \param[out] sync_id If not \p NULL, where to store synchronous client ID * * \return Legacy Pacemaker return code (specifically, \p pcmk_ok) * * \note This is the \p cib_remote variant implementation of * \p cib_api_operations_t:client_id(). * \note The client IDs are assigned during CIB sign-on. */ static int cib_remote_client_id(const cib_t *cib, const char **async_id, const char **sync_id) { cib_remote_opaque_t *private = cib->variant_opaque; if (async_id != NULL) { // private->callback is the channel for async requests *async_id = private->callback.token; } if (sync_id != NULL) { // private->command is the channel for sync requests *sync_id = private->command.token; } return pcmk_ok; } cib_t * cib_remote_new(const char *server, const char *user, const char *passwd, int port, gboolean encrypted) { cib_remote_opaque_t *private = NULL; cib_t *cib = cib_new_variant(); if (cib == NULL) { return NULL; } private = calloc(1, sizeof(cib_remote_opaque_t)); if (private == NULL) { free(cib); return NULL; } cib->variant = cib_remote; cib->variant_opaque = private; private->server = pcmk__str_copy(server); private->user = pcmk__str_copy(user); private->passwd = pcmk__str_copy(passwd); private->port = port; private->encrypted = encrypted; /* assign variant specific ops */ cib->delegate_fn = cib_remote_perform_op; cib->cmds->signon = cib_remote_signon; cib->cmds->signoff = cib_remote_signoff; cib->cmds->free = cib_remote_free; cib->cmds->register_notification = cib_remote_register_notification; cib->cmds->set_connection_dnotify = cib_remote_set_connection_dnotify; cib->cmds->client_id = cib_remote_client_id; return cib; } void cib__set_output(cib_t *cib, pcmk__output_t *out) { cib_remote_opaque_t *private; if (cib->variant != cib_remote) { return; } private = cib->variant_opaque; private->out = out; } diff --git a/lib/common/ipc_server.c b/lib/common/ipc_server.c index bffd980f76..1912fadd93 100644 --- a/lib/common/ipc_server.c +++ b/lib/common/ipc_server.c @@ -1,1010 +1,1010 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include "crmcommon_private.h" /* Evict clients whose event queue grows this large (by default) */ #define PCMK_IPC_DEFAULT_QUEUE_MAX 500 static GHashTable *client_connections = NULL; /*! * \internal * \brief Count IPC clients * * \return Number of active IPC client connections */ guint pcmk__ipc_client_count(void) { return client_connections? g_hash_table_size(client_connections) : 0; } /*! * \internal * \brief Execute a function for each active IPC client connection * * \param[in] func Function to call * \param[in,out] user_data Pointer to pass to function * * \note The parameters are the same as for g_hash_table_foreach(). */ void pcmk__foreach_ipc_client(GHFunc func, gpointer user_data) { if ((func != NULL) && (client_connections != NULL)) { g_hash_table_foreach(client_connections, func, user_data); } } pcmk__client_t * pcmk__find_client(const qb_ipcs_connection_t *c) { if (client_connections) { return g_hash_table_lookup(client_connections, c); } crm_trace("No client found for %p", c); return NULL; } pcmk__client_t * pcmk__find_client_by_id(const char *id) { if ((client_connections != NULL) && (id != NULL)) { gpointer key; pcmk__client_t *client = NULL; GHashTableIter iter; g_hash_table_iter_init(&iter, client_connections); while (g_hash_table_iter_next(&iter, &key, (gpointer *) & client)) { if (strcmp(client->id, id) == 0) { return client; } } } crm_trace("No client found with id='%s'", pcmk__s(id, "")); return NULL; } /*! * \internal * \brief Get a client identifier for use in log messages * * \param[in] c Client * * \return Client's name, client's ID, or a string literal, as available * \note This is intended to be used in format strings like "client %s". */ const char * pcmk__client_name(const pcmk__client_t *c) { if (c == NULL) { return "(unspecified)"; } else if (c->name != NULL) { return c->name; } else if (c->id != NULL) { return c->id; } else { return "(unidentified)"; } } void pcmk__client_cleanup(void) { if (client_connections != NULL) { int active = g_hash_table_size(client_connections); if (active > 0) { crm_warn("Exiting with %d active IPC client%s", active, pcmk__plural_s(active)); } g_hash_table_destroy(client_connections); client_connections = NULL; } } void pcmk__drop_all_clients(qb_ipcs_service_t *service) { qb_ipcs_connection_t *c = NULL; if (service == NULL) { return; } c = qb_ipcs_connection_first_get(service); while (c != NULL) { qb_ipcs_connection_t *last = c; c = qb_ipcs_connection_next_get(service, last); /* There really shouldn't be anyone connected at this point */ crm_notice("Disconnecting client %p, pid=%d...", last, pcmk__client_pid(last)); qb_ipcs_disconnect(last); qb_ipcs_connection_unref(last); } } /*! * \internal * \brief Allocate a new pcmk__client_t object based on an IPC connection * * \param[in] c IPC connection (NULL to allocate generic client) * \param[in] key Connection table key (NULL to use sane default) * \param[in] uid_client UID corresponding to c (ignored if c is NULL) * * \return Pointer to new pcmk__client_t (guaranteed not to be \c NULL) */ static pcmk__client_t * client_from_connection(qb_ipcs_connection_t *c, void *key, uid_t uid_client) { pcmk__client_t *client = pcmk__assert_alloc(1, sizeof(pcmk__client_t)); if (c) { client->user = pcmk__uid2username(uid_client); if (client->user == NULL) { client->user = pcmk__str_copy("#unprivileged"); crm_err("Unable to enforce ACLs for user ID %d, assuming unprivileged", uid_client); } client->ipcs = c; pcmk__set_client_flags(client, pcmk__client_ipc); client->pid = pcmk__client_pid(c); if (key == NULL) { key = c; } } client->id = crm_generate_uuid(); if (key == NULL) { key = client->id; } if (client_connections == NULL) { crm_trace("Creating IPC client table"); client_connections = g_hash_table_new(g_direct_hash, g_direct_equal); } g_hash_table_insert(client_connections, key, client); return client; } /*! * \brief Allocate a new pcmk__client_t object and generate its ID * * \param[in] key What to use as connections hash table key (NULL to use ID) * * \return Pointer to new pcmk__client_t (asserts on failure) */ pcmk__client_t * pcmk__new_unauth_client(void *key) { return client_from_connection(NULL, key, 0); } pcmk__client_t * pcmk__new_client(qb_ipcs_connection_t *c, uid_t uid_client, gid_t gid_client) { gid_t uid_cluster = 0; gid_t gid_cluster = 0; pcmk__client_t *client = NULL; CRM_CHECK(c != NULL, return NULL); if (pcmk_daemon_user(&uid_cluster, &gid_cluster) < 0) { static bool need_log = TRUE; if (need_log) { crm_warn("Could not find user and group IDs for user %s", CRM_DAEMON_USER); need_log = FALSE; } } if (uid_client != 0) { crm_trace("Giving group %u access to new IPC connection", gid_cluster); /* Passing -1 to chown(2) means don't change */ qb_ipcs_connection_auth_set(c, -1, gid_cluster, S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP); } /* TODO: Do our own auth checking, return NULL if unauthorized */ client = client_from_connection(c, NULL, uid_client); if ((uid_client == 0) || (uid_client == uid_cluster)) { /* Remember when a connection came from root or hacluster */ pcmk__set_client_flags(client, pcmk__client_privileged); } crm_debug("New IPC client %s for PID %u with uid %d and gid %d", client->id, client->pid, uid_client, gid_client); return client; } static struct iovec * pcmk__new_ipc_event(void) { return (struct iovec *) pcmk__assert_alloc(2, sizeof(struct iovec)); } /*! * \brief Free an I/O vector created by pcmk__ipc_prepare_iov() * * \param[in,out] event I/O vector to free */ void pcmk_free_ipc_event(struct iovec *event) { if (event != NULL) { free(event[0].iov_base); free(event[1].iov_base); free(event); } } static void free_event(gpointer data) { pcmk_free_ipc_event((struct iovec *) data); } static void add_event(pcmk__client_t *c, struct iovec *iov) { if (c->event_queue == NULL) { c->event_queue = g_queue_new(); } g_queue_push_tail(c->event_queue, iov); } void pcmk__free_client(pcmk__client_t *c) { if (c == NULL) { return; } if (client_connections) { if (c->ipcs) { crm_trace("Destroying %p/%p (%d remaining)", c, c->ipcs, g_hash_table_size(client_connections) - 1); g_hash_table_remove(client_connections, c->ipcs); } else { crm_trace("Destroying remote connection %p (%d remaining)", c, g_hash_table_size(client_connections) - 1); g_hash_table_remove(client_connections, c->id); } } if (c->event_timer) { g_source_remove(c->event_timer); } if (c->event_queue) { crm_debug("Destroying %d events", g_queue_get_length(c->event_queue)); g_queue_free_full(c->event_queue, free_event); } free(c->id); free(c->name); free(c->user); if (c->remote) { if (c->remote->auth_timeout) { g_source_remove(c->remote->auth_timeout); } if (c->remote->tls_session != NULL) { /* @TODO Reduce duplication at callers. Put here everything * necessary to tear down and free tls_session. */ - gnutls_free(c->remote->tls_session); + gnutls_deinit(c->remote->tls_session); } free(c->remote->buffer); free(c->remote); } free(c); } /*! * \internal * \brief Raise IPC eviction threshold for a client, if allowed * * \param[in,out] client Client to modify * \param[in] qmax New threshold */ void pcmk__set_client_queue_max(pcmk__client_t *client, const char *qmax) { int rc = pcmk_rc_ok; long long qmax_ll = 0LL; unsigned int orig_value = 0U; CRM_CHECK(client != NULL, return); orig_value = client->queue_max; if (pcmk_is_set(client->flags, pcmk__client_privileged)) { rc = pcmk__scan_ll(qmax, &qmax_ll, 0LL); if (rc == pcmk_rc_ok) { if ((qmax_ll <= 0LL) || (qmax_ll > UINT_MAX)) { rc = ERANGE; } else { client->queue_max = (unsigned int) qmax_ll; } } } else { rc = EACCES; } if (rc != pcmk_rc_ok) { crm_info("Could not set IPC threshold for client %s[%u] to %s: %s", pcmk__client_name(client), client->pid, pcmk__s(qmax, "default"), pcmk_rc_str(rc)); } else if (client->queue_max != orig_value) { crm_debug("IPC threshold for client %s[%u] is now %u (was %u)", pcmk__client_name(client), client->pid, client->queue_max, orig_value); } } int pcmk__client_pid(qb_ipcs_connection_t *c) { struct qb_ipcs_connection_stats stats; stats.client_pid = 0; qb_ipcs_connection_stats_get(c, &stats, 0); return stats.client_pid; } /*! * \internal * \brief Retrieve message XML from data read from client IPC * * \param[in,out] c IPC client connection * \param[in] data Data read from client connection * \param[out] id Where to store message ID from libqb header * \param[out] flags Where to store flags from libqb header * * \return Message XML on success, NULL otherwise */ xmlNode * pcmk__client_data2xml(pcmk__client_t *c, void *data, uint32_t *id, uint32_t *flags) { xmlNode *xml = NULL; char *uncompressed = NULL; char *text = ((char *)data) + sizeof(pcmk__ipc_header_t); pcmk__ipc_header_t *header = data; if (!pcmk__valid_ipc_header(header)) { return NULL; } if (id) { *id = ((struct qb_ipc_response_header *)data)->id; } if (flags) { *flags = header->flags; } if (pcmk_is_set(header->flags, crm_ipc_proxied)) { /* Mark this client as being the endpoint of a proxy connection. * Proxy connections responses are sent on the event channel, to avoid * blocking the controller serving as proxy. */ pcmk__set_client_flags(c, pcmk__client_proxied); } if (header->size_compressed) { int rc = 0; unsigned int size_u = 1 + header->size_uncompressed; uncompressed = pcmk__assert_alloc(1, size_u); crm_trace("Decompressing message data %u bytes into %u bytes", header->size_compressed, size_u); rc = BZ2_bzBuffToBuffDecompress(uncompressed, &size_u, text, header->size_compressed, 1, 0); text = uncompressed; rc = pcmk__bzlib2rc(rc); if (rc != pcmk_rc_ok) { crm_err("Decompression failed: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); free(uncompressed); return NULL; } } pcmk__assert(text[header->size_uncompressed - 1] == 0); xml = pcmk__xml_parse(text); crm_log_xml_trace(xml, "[IPC received]"); free(uncompressed); return xml; } static int crm_ipcs_flush_events(pcmk__client_t *c); static gboolean crm_ipcs_flush_events_cb(gpointer data) { pcmk__client_t *c = data; c->event_timer = 0; crm_ipcs_flush_events(c); return FALSE; } /*! * \internal * \brief Add progressive delay before next event queue flush * * \param[in,out] c Client connection to add delay to * \param[in] queue_len Current event queue length */ static inline void delay_next_flush(pcmk__client_t *c, unsigned int queue_len) { /* Delay a maximum of 1.5 seconds */ guint delay = (queue_len < 5)? (1000 + 100 * queue_len) : 1500; c->event_timer = pcmk__create_timer(delay, crm_ipcs_flush_events_cb, c); } /*! * \internal * \brief Send client any messages in its queue * * \param[in,out] c Client to flush * * \return Standard Pacemaker return value */ static int crm_ipcs_flush_events(pcmk__client_t *c) { int rc = pcmk_rc_ok; ssize_t qb_rc = 0; unsigned int sent = 0; unsigned int queue_len = 0; if (c == NULL) { return rc; } else if (c->event_timer) { /* There is already a timer, wait until it goes off */ crm_trace("Timer active for %p - %d", c->ipcs, c->event_timer); return rc; } if (c->event_queue) { queue_len = g_queue_get_length(c->event_queue); } while (sent < 100) { pcmk__ipc_header_t *header = NULL; struct iovec *event = NULL; if (c->event_queue) { // We don't pop unless send is successful event = g_queue_peek_head(c->event_queue); } if (event == NULL) { // Queue is empty break; } qb_rc = qb_ipcs_event_sendv(c->ipcs, event, 2); if (qb_rc < 0) { rc = (int) -qb_rc; break; } event = g_queue_pop_head(c->event_queue); sent++; header = event[0].iov_base; if (header->size_compressed) { crm_trace("Event %d to %p[%d] (%lld compressed bytes) sent", header->qb.id, c->ipcs, c->pid, (long long) qb_rc); } else { crm_trace("Event %d to %p[%d] (%lld bytes) sent: %.120s", header->qb.id, c->ipcs, c->pid, (long long) qb_rc, (char *) (event[1].iov_base)); } pcmk_free_ipc_event(event); } queue_len -= sent; if (sent > 0 || queue_len) { crm_trace("Sent %d events (%d remaining) for %p[%d]: %s (%lld)", sent, queue_len, c->ipcs, c->pid, pcmk_rc_str(rc), (long long) qb_rc); } if (queue_len) { /* Allow clients to briefly fall behind on processing incoming messages, * but drop completely unresponsive clients so the connection doesn't * consume resources indefinitely. */ if (queue_len > QB_MAX(c->queue_max, PCMK_IPC_DEFAULT_QUEUE_MAX)) { if ((c->queue_backlog <= 1) || (queue_len < c->queue_backlog)) { /* Don't evict for a new or shrinking backlog */ crm_warn("Client with process ID %u has a backlog of %u messages " QB_XS " %p", c->pid, queue_len, c->ipcs); } else { crm_err("Evicting client with process ID %u due to backlog of %u messages " QB_XS " %p", c->pid, queue_len, c->ipcs); c->queue_backlog = 0; qb_ipcs_disconnect(c->ipcs); return rc; } } c->queue_backlog = queue_len; delay_next_flush(c, queue_len); } else { /* Event queue is empty, there is no backlog */ c->queue_backlog = 0; } return rc; } /*! * \internal * \brief Create an I/O vector for sending an IPC XML message * * \param[in] request Identifier for libqb response header * \param[in] message XML message to send * \param[in] max_send_size If 0, default IPC buffer size is used * \param[out] result Where to store prepared I/O vector * \param[out] bytes Size of prepared data in bytes * * \return Standard Pacemaker return code */ int pcmk__ipc_prepare_iov(uint32_t request, const xmlNode *message, uint32_t max_send_size, struct iovec **result, ssize_t *bytes) { struct iovec *iov; unsigned int total = 0; GString *buffer = NULL; pcmk__ipc_header_t *header = NULL; int rc = pcmk_rc_ok; if ((message == NULL) || (result == NULL)) { rc = EINVAL; goto done; } header = calloc(1, sizeof(pcmk__ipc_header_t)); if (header == NULL) { rc = ENOMEM; goto done; } buffer = g_string_sized_new(1024); pcmk__xml_string(message, 0, buffer, 0); if (max_send_size == 0) { max_send_size = crm_ipc_default_buffer_size(); } CRM_LOG_ASSERT(max_send_size != 0); *result = NULL; iov = pcmk__new_ipc_event(); iov[0].iov_len = sizeof(pcmk__ipc_header_t); iov[0].iov_base = header; header->version = PCMK__IPC_VERSION; header->size_uncompressed = 1 + buffer->len; total = iov[0].iov_len + header->size_uncompressed; if (total < max_send_size) { iov[1].iov_base = pcmk__str_copy(buffer->str); iov[1].iov_len = header->size_uncompressed; } else { static unsigned int biggest = 0; char *compressed = NULL; unsigned int new_size = 0; if (pcmk__compress(buffer->str, (unsigned int) header->size_uncompressed, (unsigned int) max_send_size, &compressed, &new_size) == pcmk_rc_ok) { pcmk__set_ipc_flags(header->flags, "send data", crm_ipc_compressed); header->size_compressed = new_size; iov[1].iov_len = header->size_compressed; iov[1].iov_base = compressed; biggest = QB_MAX(header->size_compressed, biggest); } else { crm_log_xml_trace(message, "EMSGSIZE"); biggest = QB_MAX(header->size_uncompressed, biggest); crm_err("Could not compress %u-byte message into less than IPC " "limit of %u bytes; set PCMK_ipc_buffer to higher value " "(%u bytes suggested)", header->size_uncompressed, max_send_size, 4 * biggest); free(compressed); pcmk_free_ipc_event(iov); rc = EMSGSIZE; goto done; } } header->qb.size = iov[0].iov_len + iov[1].iov_len; header->qb.id = (int32_t)request; /* Replying to a specific request */ *result = iov; pcmk__assert(header->qb.size > 0); if (bytes != NULL) { *bytes = header->qb.size; } done: if (buffer != NULL) { g_string_free(buffer, TRUE); } return rc; } int pcmk__ipc_send_iov(pcmk__client_t *c, struct iovec *iov, uint32_t flags) { int rc = pcmk_rc_ok; static uint32_t id = 1; pcmk__ipc_header_t *header = iov[0].iov_base; if (c->flags & pcmk__client_proxied) { /* _ALL_ replies to proxied connections need to be sent as events */ if (!pcmk_is_set(flags, crm_ipc_server_event)) { /* The proxied flag lets us know this was originally meant to be a * response, even though we're sending it over the event channel. */ pcmk__set_ipc_flags(flags, "server event", crm_ipc_server_event |crm_ipc_proxied_relay_response); } } pcmk__set_ipc_flags(header->flags, "server event", flags); if (flags & crm_ipc_server_event) { header->qb.id = id++; /* We don't really use it, but doesn't hurt to set one */ if (flags & crm_ipc_server_free) { crm_trace("Sending the original to %p[%d]", c->ipcs, c->pid); add_event(c, iov); } else { struct iovec *iov_copy = pcmk__new_ipc_event(); crm_trace("Sending a copy to %p[%d]", c->ipcs, c->pid); iov_copy[0].iov_len = iov[0].iov_len; iov_copy[0].iov_base = malloc(iov[0].iov_len); memcpy(iov_copy[0].iov_base, iov[0].iov_base, iov[0].iov_len); iov_copy[1].iov_len = iov[1].iov_len; iov_copy[1].iov_base = malloc(iov[1].iov_len); memcpy(iov_copy[1].iov_base, iov[1].iov_base, iov[1].iov_len); add_event(c, iov_copy); } } else { ssize_t qb_rc; CRM_LOG_ASSERT(header->qb.id != 0); /* Replying to a specific request */ qb_rc = qb_ipcs_response_sendv(c->ipcs, iov, 2); if (qb_rc < header->qb.size) { if (qb_rc < 0) { rc = (int) -qb_rc; } crm_notice("Response %d to pid %d failed: %s " QB_XS " bytes=%u rc=%lld ipcs=%p", header->qb.id, c->pid, pcmk_rc_str(rc), header->qb.size, (long long) qb_rc, c->ipcs); } else { crm_trace("Response %d sent, %lld bytes to %p[%d]", header->qb.id, (long long) qb_rc, c->ipcs, c->pid); } if (flags & crm_ipc_server_free) { pcmk_free_ipc_event(iov); } } if (flags & crm_ipc_server_event) { rc = crm_ipcs_flush_events(c); } else { crm_ipcs_flush_events(c); } if ((rc == EPIPE) || (rc == ENOTCONN)) { crm_trace("Client %p disconnected", c->ipcs); } return rc; } int pcmk__ipc_send_xml(pcmk__client_t *c, uint32_t request, const xmlNode *message, uint32_t flags) { struct iovec *iov = NULL; int rc = pcmk_rc_ok; if (c == NULL) { return EINVAL; } rc = pcmk__ipc_prepare_iov(request, message, crm_ipc_default_buffer_size(), &iov, NULL); if (rc == pcmk_rc_ok) { pcmk__set_ipc_flags(flags, "send data", crm_ipc_server_free); rc = pcmk__ipc_send_iov(c, iov, flags); } else { pcmk_free_ipc_event(iov); crm_notice("IPC message to pid %d failed: %s " QB_XS " rc=%d", c->pid, pcmk_rc_str(rc), rc); } return rc; } /*! * \internal * \brief Create an acknowledgement with a status code to send to a client * * \param[in] function Calling function * \param[in] line Source file line within calling function * \param[in] flags IPC flags to use when sending * \param[in] tag Element name to use for acknowledgement * \param[in] ver IPC protocol version (can be NULL) * \param[in] status Exit status code to add to ack * * \return Newly created XML for ack * * \note The caller is responsible for freeing the return value with * \c pcmk__xml_free(). */ xmlNode * pcmk__ipc_create_ack_as(const char *function, int line, uint32_t flags, const char *tag, const char *ver, crm_exit_t status) { xmlNode *ack = NULL; if (pcmk_is_set(flags, crm_ipc_client_response)) { ack = pcmk__xe_create(NULL, tag); crm_xml_add(ack, PCMK_XA_FUNCTION, function); crm_xml_add_int(ack, PCMK__XA_LINE, line); crm_xml_add_int(ack, PCMK_XA_STATUS, (int) status); crm_xml_add(ack, PCMK__XA_IPC_PROTO_VERSION, ver); } return ack; } /*! * \internal * \brief Send an acknowledgement with a status code to a client * * \param[in] function Calling function * \param[in] line Source file line within calling function * \param[in] c Client to send ack to * \param[in] request Request ID being replied to * \param[in] flags IPC flags to use when sending * \param[in] tag Element name to use for acknowledgement * \param[in] ver IPC protocol version (can be NULL) * \param[in] status Status code to send with acknowledgement * * \return Standard Pacemaker return code */ int pcmk__ipc_send_ack_as(const char *function, int line, pcmk__client_t *c, uint32_t request, uint32_t flags, const char *tag, const char *ver, crm_exit_t status) { int rc = pcmk_rc_ok; xmlNode *ack = pcmk__ipc_create_ack_as(function, line, flags, tag, ver, status); if (ack != NULL) { crm_trace("Ack'ing IPC message from client %s as <%s status=%d>", pcmk__client_name(c), tag, status); crm_log_xml_trace(ack, "sent-ack"); c->request_id = 0; rc = pcmk__ipc_send_xml(c, request, ack, flags); pcmk__xml_free(ack); } return rc; } /*! * \internal * \brief Add an IPC server to the main loop for the CIB manager API * * \param[out] ipcs_ro New IPC server for read-only CIB manager API * \param[out] ipcs_rw New IPC server for read/write CIB manager API * \param[out] ipcs_shm New IPC server for shared-memory CIB manager API * \param[in] ro_cb IPC callbacks for read-only API * \param[in] rw_cb IPC callbacks for read/write and shared-memory APIs * * \note This function exits fatally if unable to create the servers. * \note There is no actual difference between the three IPC endpoints other * than their names. */ void pcmk__serve_based_ipc(qb_ipcs_service_t **ipcs_ro, qb_ipcs_service_t **ipcs_rw, qb_ipcs_service_t **ipcs_shm, struct qb_ipcs_service_handlers *ro_cb, struct qb_ipcs_service_handlers *rw_cb) { *ipcs_ro = mainloop_add_ipc_server(PCMK__SERVER_BASED_RO, QB_IPC_NATIVE, ro_cb); *ipcs_rw = mainloop_add_ipc_server(PCMK__SERVER_BASED_RW, QB_IPC_NATIVE, rw_cb); *ipcs_shm = mainloop_add_ipc_server(PCMK__SERVER_BASED_SHM, QB_IPC_SHM, rw_cb); if (*ipcs_ro == NULL || *ipcs_rw == NULL || *ipcs_shm == NULL) { crm_err("Failed to create the CIB manager: exiting and inhibiting respawn"); crm_warn("Verify pacemaker and pacemaker_remote are not both enabled"); crm_exit(CRM_EX_FATAL); } } /*! * \internal * \brief Destroy IPC servers for the CIB manager API * * \param[out] ipcs_ro IPC server for read-only the CIB manager API * \param[out] ipcs_rw IPC server for read/write the CIB manager API * \param[out] ipcs_shm IPC server for shared-memory the CIB manager API * * \note This is a convenience function for calling qb_ipcs_destroy() for each * argument. */ void pcmk__stop_based_ipc(qb_ipcs_service_t *ipcs_ro, qb_ipcs_service_t *ipcs_rw, qb_ipcs_service_t *ipcs_shm) { qb_ipcs_destroy(ipcs_ro); qb_ipcs_destroy(ipcs_rw); qb_ipcs_destroy(ipcs_shm); } /*! * \internal * \brief Add an IPC server to the main loop for the controller API * * \param[in] cb IPC callbacks * * \return Newly created IPC server */ qb_ipcs_service_t * pcmk__serve_controld_ipc(struct qb_ipcs_service_handlers *cb) { return mainloop_add_ipc_server(CRM_SYSTEM_CRMD, QB_IPC_NATIVE, cb); } /*! * \internal * \brief Add an IPC server to the main loop for the attribute manager API * * \param[out] ipcs Where to store newly created IPC server * \param[in] cb IPC callbacks * * \note This function exits fatally if unable to create the servers. */ void pcmk__serve_attrd_ipc(qb_ipcs_service_t **ipcs, struct qb_ipcs_service_handlers *cb) { *ipcs = mainloop_add_ipc_server(PCMK__VALUE_ATTRD, QB_IPC_NATIVE, cb); if (*ipcs == NULL) { crm_crit("Exiting fatally because unable to serve " PCMK__SERVER_ATTRD " IPC (verify pacemaker and pacemaker_remote are not both " "enabled)"); crm_exit(CRM_EX_FATAL); } } /*! * \internal * \brief Add an IPC server to the main loop for the fencer API * * \param[out] ipcs Where to store newly created IPC server * \param[in] cb IPC callbacks * * \note This function exits fatally if unable to create the servers. */ void pcmk__serve_fenced_ipc(qb_ipcs_service_t **ipcs, struct qb_ipcs_service_handlers *cb) { *ipcs = mainloop_add_ipc_server_with_prio("stonith-ng", QB_IPC_NATIVE, cb, QB_LOOP_HIGH); if (*ipcs == NULL) { crm_err("Failed to create fencer: exiting and inhibiting respawn."); crm_warn("Verify pacemaker and pacemaker_remote are not both enabled."); crm_exit(CRM_EX_FATAL); } } /*! * \internal * \brief Add an IPC server to the main loop for the pacemakerd API * * \param[out] ipcs Where to store newly created IPC server * \param[in] cb IPC callbacks * * \note This function exits with CRM_EX_OSERR if unable to create the servers. */ void pcmk__serve_pacemakerd_ipc(qb_ipcs_service_t **ipcs, struct qb_ipcs_service_handlers *cb) { *ipcs = mainloop_add_ipc_server(CRM_SYSTEM_MCP, QB_IPC_NATIVE, cb); if (*ipcs == NULL) { crm_err("Couldn't start pacemakerd IPC server"); crm_warn("Verify pacemaker and pacemaker_remote are not both enabled."); /* sub-daemons are observed by pacemakerd. Thus we exit CRM_EX_FATAL * if we want to prevent pacemakerd from restarting them. * With pacemakerd we leave the exit-code shown to e.g. systemd * to what it was prior to moving the code here from pacemakerd.c */ crm_exit(CRM_EX_OSERR); } } /*! * \internal * \brief Add an IPC server to the main loop for the scheduler API * * \param[in] cb IPC callbacks * * \return Newly created IPC server * \note This function exits fatally if unable to create the servers. */ qb_ipcs_service_t * pcmk__serve_schedulerd_ipc(struct qb_ipcs_service_handlers *cb) { return mainloop_add_ipc_server(CRM_SYSTEM_PENGINE, QB_IPC_NATIVE, cb); } diff --git a/lib/common/remote.c b/lib/common/remote.c index 2bec831416..87146f226e 100644 --- a/lib/common/remote.c +++ b/lib/common/remote.c @@ -1,1029 +1,1029 @@ /* * Copyright 2008-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // PRIx32 #include #include #include #include #include #include #include #include /* Swab macros from linux/swab.h */ #ifdef HAVE_LINUX_SWAB_H # include #else /* * casts are necessary for constants, because we never know how for sure * how U/UL/ULL map to __u16, __u32, __u64. At least not in a portable way. */ #define __swab16(x) ((uint16_t)( \ (((uint16_t)(x) & (uint16_t)0x00ffU) << 8) | \ (((uint16_t)(x) & (uint16_t)0xff00U) >> 8))) #define __swab32(x) ((uint32_t)( \ (((uint32_t)(x) & (uint32_t)0x000000ffUL) << 24) | \ (((uint32_t)(x) & (uint32_t)0x0000ff00UL) << 8) | \ (((uint32_t)(x) & (uint32_t)0x00ff0000UL) >> 8) | \ (((uint32_t)(x) & (uint32_t)0xff000000UL) >> 24))) #define __swab64(x) ((uint64_t)( \ (((uint64_t)(x) & (uint64_t)0x00000000000000ffULL) << 56) | \ (((uint64_t)(x) & (uint64_t)0x000000000000ff00ULL) << 40) | \ (((uint64_t)(x) & (uint64_t)0x0000000000ff0000ULL) << 24) | \ (((uint64_t)(x) & (uint64_t)0x00000000ff000000ULL) << 8) | \ (((uint64_t)(x) & (uint64_t)0x000000ff00000000ULL) >> 8) | \ (((uint64_t)(x) & (uint64_t)0x0000ff0000000000ULL) >> 24) | \ (((uint64_t)(x) & (uint64_t)0x00ff000000000000ULL) >> 40) | \ (((uint64_t)(x) & (uint64_t)0xff00000000000000ULL) >> 56))) #endif #define REMOTE_MSG_VERSION 1 #define ENDIAN_LOCAL 0xBADADBBD struct remote_header_v0 { uint32_t endian; /* Detect messages from hosts with different endian-ness */ uint32_t version; uint64_t id; uint64_t flags; uint32_t size_total; uint32_t payload_offset; uint32_t payload_compressed; uint32_t payload_uncompressed; /* New fields get added here */ } __attribute__ ((packed)); /*! * \internal * \brief Retrieve remote message header, in local endianness * * Return a pointer to the header portion of a remote connection's message * buffer, converting the header to local endianness if needed. * * \param[in,out] remote Remote connection with new message * * \return Pointer to message header, localized if necessary */ static struct remote_header_v0 * localized_remote_header(pcmk__remote_t *remote) { struct remote_header_v0 *header = (struct remote_header_v0 *)remote->buffer; if(remote->buffer_offset < sizeof(struct remote_header_v0)) { return NULL; } else if(header->endian != ENDIAN_LOCAL) { uint32_t endian = __swab32(header->endian); CRM_LOG_ASSERT(endian == ENDIAN_LOCAL); if(endian != ENDIAN_LOCAL) { crm_err("Invalid message detected, endian mismatch: %" PRIx32 " is neither %" PRIx32 " nor the swab'd %" PRIx32, ENDIAN_LOCAL, header->endian, endian); return NULL; } header->id = __swab64(header->id); header->flags = __swab64(header->flags); header->endian = __swab32(header->endian); header->version = __swab32(header->version); header->size_total = __swab32(header->size_total); header->payload_offset = __swab32(header->payload_offset); header->payload_compressed = __swab32(header->payload_compressed); header->payload_uncompressed = __swab32(header->payload_uncompressed); } return header; } // \return Standard Pacemaker return code static int -send_tls(gnutls_session_t *session, struct iovec *iov) +send_tls(gnutls_session_t session, struct iovec *iov) { const char *unsent = iov->iov_base; size_t unsent_len = iov->iov_len; ssize_t gnutls_rc; if (unsent == NULL) { return EINVAL; } crm_trace("Sending TLS message of %llu bytes", (unsigned long long) unsent_len); while (true) { - gnutls_rc = gnutls_record_send(*session, unsent, unsent_len); + gnutls_rc = gnutls_record_send(session, unsent, unsent_len); if (gnutls_rc == GNUTLS_E_INTERRUPTED || gnutls_rc == GNUTLS_E_AGAIN) { crm_trace("Retrying to send %llu bytes remaining", (unsigned long long) unsent_len); } else if (gnutls_rc < 0) { // Caller can log as error if necessary crm_info("TLS connection terminated: %s " QB_XS " rc=%lld", gnutls_strerror((int) gnutls_rc), (long long) gnutls_rc); return ECONNABORTED; } else if (gnutls_rc < unsent_len) { crm_trace("Sent %lld of %llu bytes remaining", (long long) gnutls_rc, (unsigned long long) unsent_len); unsent_len -= gnutls_rc; unsent += gnutls_rc; } else { crm_trace("Sent all %lld bytes remaining", (long long) gnutls_rc); break; } } return pcmk_rc_ok; } // \return Standard Pacemaker return code static int send_plaintext(int sock, struct iovec *iov) { const char *unsent = iov->iov_base; size_t unsent_len = iov->iov_len; ssize_t write_rc; if (unsent == NULL) { return EINVAL; } crm_debug("Sending plaintext message of %llu bytes to socket %d", (unsigned long long) unsent_len, sock); while (true) { write_rc = write(sock, unsent, unsent_len); if (write_rc < 0) { int rc = errno; if ((errno == EINTR) || (errno == EAGAIN)) { crm_trace("Retrying to send %llu bytes remaining to socket %d", (unsigned long long) unsent_len, sock); continue; } // Caller can log as error if necessary crm_info("Could not send message: %s " QB_XS " rc=%d socket=%d", pcmk_rc_str(rc), rc, sock); return rc; } else if (write_rc < unsent_len) { crm_trace("Sent %lld of %llu bytes remaining", (long long) write_rc, (unsigned long long) unsent_len); unsent += write_rc; unsent_len -= write_rc; continue; } else { crm_trace("Sent all %lld bytes remaining: %.100s", (long long) write_rc, (char *) (iov->iov_base)); break; } } return pcmk_rc_ok; } // \return Standard Pacemaker return code static int remote_send_iovs(pcmk__remote_t *remote, struct iovec *iov, int iovs) { int rc = pcmk_rc_ok; for (int lpc = 0; (lpc < iovs) && (rc == pcmk_rc_ok); lpc++) { if (remote->tls_session) { rc = send_tls(remote->tls_session, &(iov[lpc])); continue; } if (remote->tcp_socket) { rc = send_plaintext(remote->tcp_socket, &(iov[lpc])); } else { rc = ESOCKTNOSUPPORT; } } return rc; } /*! * \internal * \brief Send an XML message over a Pacemaker Remote connection * * \param[in,out] remote Pacemaker Remote connection to use * \param[in] msg XML to send * * \return Standard Pacemaker return code */ int pcmk__remote_send_xml(pcmk__remote_t *remote, const xmlNode *msg) { int rc = pcmk_rc_ok; static uint64_t id = 0; GString *xml_text = NULL; struct iovec iov[2]; struct remote_header_v0 *header; CRM_CHECK((remote != NULL) && (msg != NULL), return EINVAL); xml_text = g_string_sized_new(1024); pcmk__xml_string(msg, 0, xml_text, 0); CRM_CHECK(xml_text->len > 0, g_string_free(xml_text, TRUE); return EINVAL); header = pcmk__assert_alloc(1, sizeof(struct remote_header_v0)); iov[0].iov_base = header; iov[0].iov_len = sizeof(struct remote_header_v0); iov[1].iov_len = 1 + xml_text->len; iov[1].iov_base = g_string_free(xml_text, FALSE); id++; header->id = id; header->endian = ENDIAN_LOCAL; header->version = REMOTE_MSG_VERSION; header->payload_offset = iov[0].iov_len; header->payload_uncompressed = iov[1].iov_len; header->size_total = iov[0].iov_len + iov[1].iov_len; rc = remote_send_iovs(remote, iov, 2); if (rc != pcmk_rc_ok) { crm_err("Could not send remote message: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); } free(iov[0].iov_base); g_free((gchar *) iov[1].iov_base); return rc; } /*! * \internal * \brief Obtain the XML from the currently buffered remote connection message * * \param[in,out] remote Remote connection possibly with message available * * \return Newly allocated XML object corresponding to message data, or NULL * \note This effectively removes the message from the connection buffer. */ xmlNode * pcmk__remote_message_xml(pcmk__remote_t *remote) { xmlNode *xml = NULL; struct remote_header_v0 *header = localized_remote_header(remote); if (header == NULL) { return NULL; } /* Support compression on the receiving end now, in case we ever want to add it later */ if (header->payload_compressed) { int rc = 0; unsigned int size_u = 1 + header->payload_uncompressed; char *uncompressed = pcmk__assert_alloc(1, header->payload_offset + size_u); crm_trace("Decompressing message data %d bytes into %d bytes", header->payload_compressed, size_u); rc = BZ2_bzBuffToBuffDecompress(uncompressed + header->payload_offset, &size_u, remote->buffer + header->payload_offset, header->payload_compressed, 1, 0); rc = pcmk__bzlib2rc(rc); if (rc != pcmk_rc_ok && header->version > REMOTE_MSG_VERSION) { crm_warn("Couldn't decompress v%d message, we only understand v%d", header->version, REMOTE_MSG_VERSION); free(uncompressed); return NULL; } else if (rc != pcmk_rc_ok) { crm_err("Decompression failed: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); free(uncompressed); return NULL; } pcmk__assert(size_u == header->payload_uncompressed); memcpy(uncompressed, remote->buffer, header->payload_offset); /* Preserve the header */ remote->buffer_size = header->payload_offset + size_u; free(remote->buffer); remote->buffer = uncompressed; header = localized_remote_header(remote); } /* take ownership of the buffer */ remote->buffer_offset = 0; CRM_LOG_ASSERT(remote->buffer[sizeof(struct remote_header_v0) + header->payload_uncompressed - 1] == 0); xml = pcmk__xml_parse(remote->buffer + header->payload_offset); if (xml == NULL && header->version > REMOTE_MSG_VERSION) { crm_warn("Couldn't parse v%d message, we only understand v%d", header->version, REMOTE_MSG_VERSION); } else if (xml == NULL) { crm_err("Couldn't parse: '%.120s'", remote->buffer + header->payload_offset); } crm_log_xml_trace(xml, "[remote msg]"); return xml; } static int get_remote_socket(const pcmk__remote_t *remote) { if (remote->tls_session) { - void *sock_ptr = gnutls_transport_get_ptr(*remote->tls_session); + void *sock_ptr = gnutls_transport_get_ptr(remote->tls_session); return GPOINTER_TO_INT(sock_ptr); } if (remote->tcp_socket) { return remote->tcp_socket; } crm_err("Remote connection type undetermined (bug?)"); return -1; } /*! * \internal * \brief Wait for a remote session to have data to read * * \param[in] remote Connection to check * \param[in] timeout_ms Maximum time (in ms) to wait * * \return Standard Pacemaker return code (of particular interest, pcmk_rc_ok if * there is data ready to be read, and ETIME if there is no data within * the specified timeout) */ int pcmk__remote_ready(const pcmk__remote_t *remote, int timeout_ms) { struct pollfd fds = { 0, }; int sock = 0; int rc = 0; time_t start; int timeout = timeout_ms; sock = get_remote_socket(remote); if (sock <= 0) { crm_trace("No longer connected"); return ENOTCONN; } start = time(NULL); errno = 0; do { fds.fd = sock; fds.events = POLLIN; /* If we got an EINTR while polling, and we have a * specific timeout we are trying to honor, attempt * to adjust the timeout to the closest second. */ if (errno == EINTR && (timeout > 0)) { timeout = timeout_ms - ((time(NULL) - start) * 1000); if (timeout < 1000) { timeout = 1000; } } rc = poll(&fds, 1, timeout); } while (rc < 0 && errno == EINTR); if (rc < 0) { return errno; } return (rc == 0)? ETIME : pcmk_rc_ok; } /*! * \internal * \brief Read bytes from non-blocking remote connection * * \param[in,out] remote Remote connection to read * * \return Standard Pacemaker return code (of particular interest, pcmk_rc_ok if * a full message has been received, or EAGAIN for a partial message) * \note Use only with non-blocking sockets after polling the socket. * \note This function will return when the socket read buffer is empty or an * error is encountered. */ int pcmk__read_available_remote_data(pcmk__remote_t *remote) { int rc = pcmk_rc_ok; size_t read_len = sizeof(struct remote_header_v0); struct remote_header_v0 *header = localized_remote_header(remote); ssize_t read_rc; if(header) { /* Stop at the end of the current message */ read_len = header->size_total; } /* automatically grow the buffer when needed */ if(remote->buffer_size < read_len) { remote->buffer_size = 2 * read_len; crm_trace("Expanding buffer to %llu bytes", (unsigned long long) remote->buffer_size); remote->buffer = pcmk__realloc(remote->buffer, remote->buffer_size + 1); } if (remote->tls_session) { - read_rc = gnutls_record_recv(*(remote->tls_session), + read_rc = gnutls_record_recv(remote->tls_session, remote->buffer + remote->buffer_offset, remote->buffer_size - remote->buffer_offset); if (read_rc == GNUTLS_E_INTERRUPTED) { rc = EINTR; } else if (read_rc == GNUTLS_E_AGAIN) { rc = EAGAIN; } else if (read_rc < 0) { crm_debug("TLS receive failed: %s (%lld)", gnutls_strerror(read_rc), (long long) read_rc); rc = EIO; } } else if (remote->tcp_socket) { read_rc = read(remote->tcp_socket, remote->buffer + remote->buffer_offset, remote->buffer_size - remote->buffer_offset); if (read_rc < 0) { rc = errno; } } else { crm_err("Remote connection type undetermined (bug?)"); return ESOCKTNOSUPPORT; } /* process any errors. */ if (read_rc > 0) { remote->buffer_offset += read_rc; /* always null terminate buffer, the +1 to alloc always allows for this. */ remote->buffer[remote->buffer_offset] = '\0'; crm_trace("Received %lld more bytes (%llu total)", (long long) read_rc, (unsigned long long) remote->buffer_offset); } else if ((rc == EINTR) || (rc == EAGAIN)) { crm_trace("No data available for non-blocking remote read: %s (%d)", pcmk_rc_str(rc), rc); } else if (read_rc == 0) { crm_debug("End of remote data encountered after %llu bytes", (unsigned long long) remote->buffer_offset); return ENOTCONN; } else { crm_debug("Error receiving remote data after %llu bytes: %s (%d)", (unsigned long long) remote->buffer_offset, pcmk_rc_str(rc), rc); return ENOTCONN; } header = localized_remote_header(remote); if(header) { if(remote->buffer_offset < header->size_total) { crm_trace("Read partial remote message (%llu of %u bytes)", (unsigned long long) remote->buffer_offset, header->size_total); } else { crm_trace("Read full remote message of %llu bytes", (unsigned long long) remote->buffer_offset); return pcmk_rc_ok; } } return EAGAIN; } /*! * \internal * \brief Read one message from a remote connection * * \param[in,out] remote Remote connection to read * \param[in] timeout_ms Fail if message not read in this many milliseconds * (10s will be used if 0, and 60s if negative) * * \return Standard Pacemaker return code */ int pcmk__read_remote_message(pcmk__remote_t *remote, int timeout_ms) { int rc = pcmk_rc_ok; time_t start = time(NULL); int remaining_timeout = 0; if (timeout_ms == 0) { timeout_ms = 10000; } else if (timeout_ms < 0) { timeout_ms = 60000; } remaining_timeout = timeout_ms; while (remaining_timeout > 0) { crm_trace("Waiting for remote data (%d ms of %d ms timeout remaining)", remaining_timeout, timeout_ms); rc = pcmk__remote_ready(remote, remaining_timeout); if (rc == ETIME) { crm_err("Timed out (%d ms) while waiting for remote data", remaining_timeout); return rc; } else if (rc != pcmk_rc_ok) { crm_debug("Wait for remote data aborted (will retry): %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); } else { rc = pcmk__read_available_remote_data(remote); if (rc == pcmk_rc_ok) { return rc; } else if (rc == EAGAIN) { crm_trace("Waiting for more remote data"); } else { crm_debug("Could not receive remote data: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); } } // Don't waste time retrying after fatal errors if ((rc == ENOTCONN) || (rc == ESOCKTNOSUPPORT)) { return rc; } remaining_timeout = timeout_ms - ((time(NULL) - start) * 1000); } return ETIME; } struct tcp_async_cb_data { int sock; int timeout_ms; time_t start; void *userdata; void (*callback) (void *userdata, int rc, int sock); }; // \return TRUE if timer should be rescheduled, FALSE otherwise static gboolean check_connect_finished(gpointer userdata) { struct tcp_async_cb_data *cb_data = userdata; int rc; fd_set rset, wset; struct timeval ts = { 0, }; if (cb_data->start == 0) { // Last connect() returned success immediately rc = pcmk_rc_ok; goto dispatch_done; } // If the socket is ready for reading or writing, the connect succeeded FD_ZERO(&rset); FD_SET(cb_data->sock, &rset); wset = rset; rc = select(cb_data->sock + 1, &rset, &wset, NULL, &ts); if (rc < 0) { // select() error rc = errno; if ((rc == EINPROGRESS) || (rc == EAGAIN)) { if ((time(NULL) - cb_data->start) < pcmk__timeout_ms2s(cb_data->timeout_ms)) { return TRUE; // There is time left, so reschedule timer } else { rc = ETIMEDOUT; } } crm_trace("Could not check socket %d for connection success: %s (%d)", cb_data->sock, pcmk_rc_str(rc), rc); } else if (rc == 0) { // select() timeout if ((time(NULL) - cb_data->start) < pcmk__timeout_ms2s(cb_data->timeout_ms)) { return TRUE; // There is time left, so reschedule timer } crm_debug("Timed out while waiting for socket %d connection success", cb_data->sock); rc = ETIMEDOUT; // select() returned number of file descriptors that are ready } else if (FD_ISSET(cb_data->sock, &rset) || FD_ISSET(cb_data->sock, &wset)) { // The socket is ready; check it for connection errors int error = 0; socklen_t len = sizeof(error); if (getsockopt(cb_data->sock, SOL_SOCKET, SO_ERROR, &error, &len) < 0) { rc = errno; crm_trace("Couldn't check socket %d for connection errors: %s (%d)", cb_data->sock, pcmk_rc_str(rc), rc); } else if (error != 0) { rc = error; crm_trace("Socket %d connected with error: %s (%d)", cb_data->sock, pcmk_rc_str(rc), rc); } else { rc = pcmk_rc_ok; } } else { // Should not be possible crm_trace("select() succeeded, but socket %d not in resulting " "read/write sets", cb_data->sock); rc = EAGAIN; } dispatch_done: if (rc == pcmk_rc_ok) { crm_trace("Socket %d is connected", cb_data->sock); } else { close(cb_data->sock); cb_data->sock = -1; } if (cb_data->callback) { cb_data->callback(cb_data->userdata, rc, cb_data->sock); } free(cb_data); return FALSE; // Do not reschedule timer } /*! * \internal * \brief Attempt to connect socket, calling callback when done * * Set a given socket non-blocking, then attempt to connect to it, * retrying periodically until success or a timeout is reached. * Call a caller-supplied callback function when completed. * * \param[in] sock Newly created socket * \param[in] addr Socket address information for connect * \param[in] addrlen Size of socket address information in bytes * \param[in] timeout_ms Fail if not connected within this much time * \param[out] timer_id If not NULL, store retry timer ID here * \param[in] userdata User data to pass to callback * \param[in] callback Function to call when connection attempt completes * * \return Standard Pacemaker return code */ static int connect_socket_retry(int sock, const struct sockaddr *addr, socklen_t addrlen, int timeout_ms, int *timer_id, void *userdata, void (*callback) (void *userdata, int rc, int sock)) { int rc = 0; int interval = 500; int timer; struct tcp_async_cb_data *cb_data = NULL; rc = pcmk__set_nonblocking(sock); if (rc != pcmk_rc_ok) { crm_warn("Could not set socket non-blocking: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); return rc; } rc = connect(sock, addr, addrlen); if (rc < 0 && (errno != EINPROGRESS) && (errno != EAGAIN)) { rc = errno; crm_warn("Could not connect socket: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); return rc; } cb_data = pcmk__assert_alloc(1, sizeof(struct tcp_async_cb_data)); cb_data->userdata = userdata; cb_data->callback = callback; cb_data->sock = sock; cb_data->timeout_ms = timeout_ms; if (rc == 0) { /* The connect was successful immediately, we still return to mainloop * and let this callback get called later. This avoids the user of this api * to have to account for the fact the callback could be invoked within this * function before returning. */ cb_data->start = 0; interval = 1; } else { cb_data->start = time(NULL); } /* This timer function does a non-blocking poll on the socket to see if we * can use it. Once we can, the connect has completed. This method allows us * to connect without blocking the mainloop. * * @TODO Use a mainloop fd callback for this instead of polling. Something * about the way mainloop is currently polling prevents this from * working at the moment though. (See connect(2) regarding EINPROGRESS * for possible new handling needed.) */ crm_trace("Scheduling check in %dms for whether connect to fd %d finished", interval, sock); timer = pcmk__create_timer(interval, check_connect_finished, cb_data); if (timer_id) { *timer_id = timer; } // timer callback should be taking care of cb_data // cppcheck-suppress memleak return pcmk_rc_ok; } /*! * \internal * \brief Attempt once to connect socket and set it non-blocking * * \param[in] sock Newly created socket * \param[in] addr Socket address information for connect * \param[in] addrlen Size of socket address information in bytes * * \return Standard Pacemaker return code */ static int connect_socket_once(int sock, const struct sockaddr *addr, socklen_t addrlen) { int rc = connect(sock, addr, addrlen); if (rc < 0) { rc = errno; crm_warn("Could not connect socket: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); return rc; } rc = pcmk__set_nonblocking(sock); if (rc != pcmk_rc_ok) { crm_warn("Could not set socket non-blocking: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); return rc; } return pcmk_ok; } /*! * \internal * \brief Connect to server at specified TCP port * * \param[in] host Name of server to connect to * \param[in] port Server port to connect to * \param[in] timeout_ms If asynchronous, fail if not connected in this time * \param[out] timer_id If asynchronous and this is non-NULL, retry timer ID * will be put here (for ease of cancelling by caller) * \param[out] sock_fd Where to store socket file descriptor * \param[in] userdata If asynchronous, data to pass to callback * \param[in] callback If NULL, attempt a single synchronous connection, * otherwise retry asynchronously then call this * * \return Standard Pacemaker return code */ int pcmk__connect_remote(const char *host, int port, int timeout, int *timer_id, int *sock_fd, void *userdata, void (*callback) (void *userdata, int rc, int sock)) { char buffer[INET6_ADDRSTRLEN]; struct addrinfo *res = NULL; struct addrinfo *rp = NULL; struct addrinfo hints; const char *server = host; int rc; int sock = -1; CRM_CHECK((host != NULL) && (sock_fd != NULL), return EINVAL); // Get host's IP address(es) memset(&hints, 0, sizeof(struct addrinfo)); hints.ai_family = AF_UNSPEC; /* Allow IPv4 or IPv6 */ hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_CANONNAME; rc = getaddrinfo(server, NULL, &hints, &res); rc = pcmk__gaierror2rc(rc); if (rc != pcmk_rc_ok) { crm_err("Unable to get IP address info for %s: %s", server, pcmk_rc_str(rc)); goto async_cleanup; } if (!res || !res->ai_addr) { crm_err("Unable to get IP address info for %s: no result", server); rc = ENOTCONN; goto async_cleanup; } // getaddrinfo() returns a list of host's addresses, try them in order for (rp = res; rp != NULL; rp = rp->ai_next) { struct sockaddr *addr = rp->ai_addr; if (!addr) { continue; } if (rp->ai_canonname) { server = res->ai_canonname; } crm_debug("Got canonical name %s for %s", server, host); sock = socket(rp->ai_family, SOCK_STREAM, IPPROTO_TCP); if (sock == -1) { rc = errno; crm_warn("Could not create socket for remote connection to %s:%d: " "%s " QB_XS " rc=%d", server, port, pcmk_rc_str(rc), rc); continue; } /* Set port appropriately for address family */ /* (void*) casts avoid false-positive compiler alignment warnings */ if (addr->sa_family == AF_INET6) { ((struct sockaddr_in6 *)(void*)addr)->sin6_port = htons(port); } else { ((struct sockaddr_in *)(void*)addr)->sin_port = htons(port); } memset(buffer, 0, PCMK__NELEM(buffer)); pcmk__sockaddr2str(addr, buffer); crm_info("Attempting remote connection to %s:%d", buffer, port); if (callback) { if (connect_socket_retry(sock, rp->ai_addr, rp->ai_addrlen, timeout, timer_id, userdata, callback) == pcmk_rc_ok) { goto async_cleanup; /* Success for now, we'll hear back later in the callback */ } } else if (connect_socket_once(sock, rp->ai_addr, rp->ai_addrlen) == pcmk_rc_ok) { break; /* Success */ } // Connect failed close(sock); sock = -1; rc = ENOTCONN; } async_cleanup: if (res) { freeaddrinfo(res); } *sock_fd = sock; return rc; } /*! * \internal * \brief Convert an IP address (IPv4 or IPv6) to a string for logging * * \param[in] sa Socket address for IP * \param[out] s Storage for at least INET6_ADDRSTRLEN bytes * * \note sa The socket address can be a pointer to struct sockaddr_in (IPv4), * struct sockaddr_in6 (IPv6) or struct sockaddr_storage (either), * as long as its sa_family member is set correctly. */ void pcmk__sockaddr2str(const void *sa, char *s) { switch (((const struct sockaddr *) sa)->sa_family) { case AF_INET: inet_ntop(AF_INET, &(((const struct sockaddr_in *) sa)->sin_addr), s, INET6_ADDRSTRLEN); break; case AF_INET6: inet_ntop(AF_INET6, &(((const struct sockaddr_in6 *) sa)->sin6_addr), s, INET6_ADDRSTRLEN); break; default: strcpy(s, ""); } } /*! * \internal * \brief Accept a client connection on a remote server socket * * \param[in] ssock Server socket file descriptor being listened on * \param[out] csock Where to put new client socket's file descriptor * * \return Standard Pacemaker return code */ int pcmk__accept_remote_connection(int ssock, int *csock) { int rc; struct sockaddr_storage addr; socklen_t laddr = sizeof(addr); char addr_str[INET6_ADDRSTRLEN]; #ifdef TCP_USER_TIMEOUT long sbd_timeout = 0; #endif /* accept the connection */ memset(&addr, 0, sizeof(addr)); *csock = accept(ssock, (struct sockaddr *)&addr, &laddr); if (*csock == -1) { rc = errno; crm_err("Could not accept remote client connection: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); return rc; } pcmk__sockaddr2str(&addr, addr_str); crm_info("Accepted new remote client connection from %s", addr_str); rc = pcmk__set_nonblocking(*csock); if (rc != pcmk_rc_ok) { crm_err("Could not set socket non-blocking: %s " QB_XS " rc=%d", pcmk_rc_str(rc), rc); close(*csock); *csock = -1; return rc; } #ifdef TCP_USER_TIMEOUT sbd_timeout = pcmk__get_sbd_watchdog_timeout(); if (sbd_timeout > 0) { // Time to fail and retry before watchdog long half = sbd_timeout / 2; unsigned int optval = (half <= UINT_MAX)? half : UINT_MAX; rc = setsockopt(*csock, SOL_TCP, TCP_USER_TIMEOUT, &optval, sizeof(optval)); if (rc < 0) { rc = errno; crm_err("Could not set TCP timeout to %d ms on remote connection: " "%s " QB_XS " rc=%d", optval, pcmk_rc_str(rc), rc); close(*csock); *csock = -1; return rc; } } #endif return rc; } /*! * \brief Get the default remote connection TCP port on this host * * \return Remote connection TCP port number */ int crm_default_remote_port(void) { static int port = 0; if (port == 0) { const char *env = pcmk__env_option(PCMK__ENV_REMOTE_PORT); if (env) { errno = 0; port = strtol(env, NULL, 10); if (errno || (port < 1) || (port > 65535)) { crm_warn("Environment variable PCMK_" PCMK__ENV_REMOTE_PORT " has invalid value '%s', using %d instead", env, DEFAULT_REMOTE_PORT); port = DEFAULT_REMOTE_PORT; } } else { port = DEFAULT_REMOTE_PORT; } } return port; } diff --git a/lib/common/tls.c b/lib/common/tls.c index 955e0e37b2..4d0399ff3f 100644 --- a/lib/common/tls.c +++ b/lib/common/tls.c @@ -1,202 +1,196 @@ /* * Copyright 2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include static char * get_gnutls_priorities(gnutls_credentials_type_t cred_type) { const char *prio_base = pcmk__env_option(PCMK__ENV_TLS_PRIORITIES); if (prio_base == NULL) { prio_base = PCMK__GNUTLS_PRIORITIES; } return crm_strdup_printf("%s:%s", prio_base, (cred_type == GNUTLS_CRD_ANON)? "+ANON-DH" : "+DHE-PSK:+PSK"); } int pcmk__init_tls_dh(gnutls_dh_params_t *dh_params) { int rc = GNUTLS_E_SUCCESS; unsigned int dh_bits = 0; int dh_max_bits = 0; rc = gnutls_dh_params_init(dh_params); if (rc != GNUTLS_E_SUCCESS) { goto error; } dh_bits = gnutls_sec_param_to_pk_bits(GNUTLS_PK_DH, GNUTLS_SEC_PARAM_NORMAL); if (dh_bits == 0) { rc = GNUTLS_E_DH_PRIME_UNACCEPTABLE; goto error; } pcmk__scan_min_int(pcmk__env_option(PCMK__ENV_DH_MAX_BITS), &dh_max_bits, 0); if ((dh_max_bits > 0) && (dh_bits > dh_max_bits)) { dh_bits = dh_max_bits; } crm_info("Generating Diffie-Hellman parameters with %u-bit prime for TLS", dh_bits); rc = gnutls_dh_params_generate2(*dh_params, dh_bits); if (rc != GNUTLS_E_SUCCESS) { goto error; } return pcmk_rc_ok; error: crm_err("Could not initialize Diffie-Hellman parameters for TLS: %s " QB_XS " rc=%d", gnutls_strerror(rc), rc); return EPROTO; } -gnutls_session_t * +gnutls_session_t pcmk__new_tls_session(int csock, unsigned int conn_type, gnutls_credentials_type_t cred_type, void *credentials) { int rc = GNUTLS_E_SUCCESS; char *prio = NULL; - gnutls_session_t *session = NULL; + gnutls_session_t session = NULL; - session = gnutls_malloc(sizeof(gnutls_session_t)); - if (session == NULL) { - rc = GNUTLS_E_MEMORY_ERROR; - goto error; - } - - rc = gnutls_init(session, conn_type); + rc = gnutls_init(&session, conn_type); if (rc != GNUTLS_E_SUCCESS) { goto error; } /* Determine list of acceptable ciphers, etc. Pacemaker always adds the * values required for its functionality. * * For an example of anonymous authentication, see: * http://www.manpagez.com/info/gnutls/gnutls-2.10.4/gnutls_81.php#Echo-Server-with-anonymous-authentication */ prio = get_gnutls_priorities(cred_type); /* @TODO On the server side, it would be more efficient to cache the * priority with gnutls_priority_init2() and set it with * gnutls_priority_set() for all sessions. */ - rc = gnutls_priority_set_direct(*session, prio, NULL); + rc = gnutls_priority_set_direct(session, prio, NULL); if (rc != GNUTLS_E_SUCCESS) { goto error; } - gnutls_transport_set_ptr(*session, + gnutls_transport_set_ptr(session, (gnutls_transport_ptr_t) GINT_TO_POINTER(csock)); - rc = gnutls_credentials_set(*session, cred_type, credentials); + rc = gnutls_credentials_set(session, cred_type, credentials); if (rc != GNUTLS_E_SUCCESS) { goto error; } free(prio); return session; error: crm_err("Could not initialize %s TLS %s session: %s " QB_XS " rc=%d priority='%s'", (cred_type == GNUTLS_CRD_ANON)? "anonymous" : "PSK", (conn_type == GNUTLS_SERVER)? "server" : "client", gnutls_strerror(rc), rc, prio); free(prio); if (session != NULL) { - gnutls_free(session); + gnutls_deinit(session); } return NULL; } int pcmk__read_handshake_data(const pcmk__client_t *client) { int rc = 0; pcmk__assert((client != NULL) && (client->remote != NULL) && (client->remote->tls_session != NULL)); do { - rc = gnutls_handshake(*client->remote->tls_session); + rc = gnutls_handshake(client->remote->tls_session); } while (rc == GNUTLS_E_INTERRUPTED); if (rc == GNUTLS_E_AGAIN) { /* No more data is available at the moment. This function should be * invoked again once the client sends more. */ return EAGAIN; } else if (rc != GNUTLS_E_SUCCESS) { crm_err("TLS handshake with remote client failed: %s " QB_XS " rc=%d", gnutls_strerror(rc), rc); return EPROTO; } return pcmk_rc_ok; } int pcmk__tls_client_try_handshake(pcmk__remote_t *remote, int *gnutls_rc) { int rc = pcmk_rc_ok; if (gnutls_rc != NULL) { *gnutls_rc = GNUTLS_E_SUCCESS; } - rc = gnutls_handshake(*remote->tls_session); + rc = gnutls_handshake(remote->tls_session); switch (rc) { case GNUTLS_E_SUCCESS: rc = pcmk_rc_ok; break; case GNUTLS_E_INTERRUPTED: case GNUTLS_E_AGAIN: rc = EAGAIN; break; default: if (gnutls_rc != NULL) { *gnutls_rc = rc; } rc = EPROTO; break; } return rc; } int pcmk__tls_client_handshake(pcmk__remote_t *remote, int timeout_sec, int *gnutls_rc) { const time_t time_limit = time(NULL) + timeout_sec; do { int rc = pcmk__tls_client_try_handshake(remote, gnutls_rc); if (rc != EAGAIN) { return rc; } } while (time(NULL) < time_limit); return ETIME; } diff --git a/lib/lrmd/lrmd_client.c b/lib/lrmd/lrmd_client.c index 4da419e8c1..c3a0e8f709 100644 --- a/lib/lrmd/lrmd_client.c +++ b/lib/lrmd/lrmd_client.c @@ -1,2675 +1,2672 @@ /* * Copyright 2012-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include #include #include #include #include // uint32_t, uint64_t #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // stonith__* #include #include #include #include #include #include #define MAX_TLS_RECV_WAIT 10000 CRM_TRACE_INIT_DATA(lrmd); static int lrmd_api_disconnect(lrmd_t * lrmd); static int lrmd_api_is_connected(lrmd_t * lrmd); /* IPC proxy functions */ int lrmd_internal_proxy_send(lrmd_t * lrmd, xmlNode *msg); static void lrmd_internal_proxy_dispatch(lrmd_t *lrmd, xmlNode *msg); void lrmd_internal_set_proxy_callback(lrmd_t * lrmd, void *userdata, void (*callback)(lrmd_t *lrmd, void *userdata, xmlNode *msg)); // GnuTLS client handshake timeout in seconds #define TLS_HANDSHAKE_TIMEOUT 5 gnutls_psk_client_credentials_t psk_cred_s; static void lrmd_tls_disconnect(lrmd_t * lrmd); static int global_remote_msg_id = 0; static void lrmd_tls_connection_destroy(gpointer userdata); static int add_tls_to_mainloop(lrmd_t *lrmd, bool do_api_handshake); typedef struct lrmd_private_s { uint64_t type; char *token; mainloop_io_t *source; /* IPC parameters */ crm_ipc_t *ipc; pcmk__remote_t *remote; /* Extra TLS parameters */ char *remote_nodename; char *server; int port; gnutls_psk_client_credentials_t psk_cred_c; /* while the async connection is occurring, this is the id * of the connection timeout timer. */ int async_timer; int sock; /* since tls requires a round trip across the network for a * request/reply, there are times where we just want to be able * to send a request from the client and not wait around (or even care * about) what the reply is. */ int expected_late_replies; GList *pending_notify; crm_trigger_t *process_notify; crm_trigger_t *handshake_trigger; lrmd_event_callback callback; /* Internal IPC proxy msg passing for remote guests */ void (*proxy_callback)(lrmd_t *lrmd, void *userdata, xmlNode *msg); void *proxy_callback_userdata; char *peer_version; } lrmd_private_t; static int process_lrmd_handshake_reply(xmlNode *reply, lrmd_private_t *native); static void report_async_connection_result(lrmd_t * lrmd, int rc); static lrmd_list_t * lrmd_list_add(lrmd_list_t * head, const char *value) { lrmd_list_t *p, *end; p = pcmk__assert_alloc(1, sizeof(lrmd_list_t)); p->val = strdup(value); end = head; while (end && end->next) { end = end->next; } if (end) { end->next = p; } else { head = p; } return head; } void lrmd_list_freeall(lrmd_list_t * head) { lrmd_list_t *p; while (head) { char *val = (char *)head->val; p = head->next; free(val); free(head); head = p; } } lrmd_key_value_t * lrmd_key_value_add(lrmd_key_value_t * head, const char *key, const char *value) { lrmd_key_value_t *p, *end; p = pcmk__assert_alloc(1, sizeof(lrmd_key_value_t)); p->key = strdup(key); p->value = strdup(value); end = head; while (end && end->next) { end = end->next; } if (end) { end->next = p; } else { head = p; } return head; } void lrmd_key_value_freeall(lrmd_key_value_t * head) { lrmd_key_value_t *p; while (head) { p = head->next; free(head->key); free(head->value); free(head); head = p; } } /*! * \brief Create a new lrmd_event_data_t object * * \param[in] rsc_id ID of resource involved in event * \param[in] task Action name * \param[in] interval_ms Action interval * * \return Newly allocated and initialized lrmd_event_data_t * \note This functions asserts on memory errors, so the return value is * guaranteed to be non-NULL. The caller is responsible for freeing the * result with lrmd_free_event(). */ lrmd_event_data_t * lrmd_new_event(const char *rsc_id, const char *task, guint interval_ms) { lrmd_event_data_t *event = pcmk__assert_alloc(1, sizeof(lrmd_event_data_t)); // lrmd_event_data_t has (const char *) members that lrmd_free_event() frees event->rsc_id = pcmk__str_copy(rsc_id); event->op_type = pcmk__str_copy(task); event->interval_ms = interval_ms; return event; } lrmd_event_data_t * lrmd_copy_event(lrmd_event_data_t * event) { lrmd_event_data_t *copy = NULL; copy = pcmk__assert_alloc(1, sizeof(lrmd_event_data_t)); copy->type = event->type; // lrmd_event_data_t has (const char *) members that lrmd_free_event() frees copy->rsc_id = pcmk__str_copy(event->rsc_id); copy->op_type = pcmk__str_copy(event->op_type); copy->user_data = pcmk__str_copy(event->user_data); copy->output = pcmk__str_copy(event->output); copy->remote_nodename = pcmk__str_copy(event->remote_nodename); copy->exit_reason = pcmk__str_copy(event->exit_reason); copy->call_id = event->call_id; copy->timeout = event->timeout; copy->interval_ms = event->interval_ms; copy->start_delay = event->start_delay; copy->rsc_deleted = event->rsc_deleted; copy->rc = event->rc; copy->op_status = event->op_status; copy->t_run = event->t_run; copy->t_rcchange = event->t_rcchange; copy->exec_time = event->exec_time; copy->queue_time = event->queue_time; copy->connection_rc = event->connection_rc; copy->params = pcmk__str_table_dup(event->params); return copy; } /*! * \brief Free an executor event * * \param[in,out] Executor event object to free */ void lrmd_free_event(lrmd_event_data_t *event) { if (event == NULL) { return; } // @TODO Why are these const char *? free((void *) event->rsc_id); free((void *) event->op_type); free((void *) event->user_data); free((void *) event->remote_nodename); lrmd__reset_result(event); if (event->params != NULL) { g_hash_table_destroy(event->params); } free(event); } static void lrmd_dispatch_internal(gpointer data, gpointer user_data) { xmlNode *msg = data; lrmd_t *lrmd = user_data; const char *type; const char *proxy_session = crm_element_value(msg, PCMK__XA_LRMD_IPC_SESSION); lrmd_private_t *native = lrmd->lrmd_private; lrmd_event_data_t event = { 0, }; if (proxy_session != NULL) { /* this is proxy business */ lrmd_internal_proxy_dispatch(lrmd, msg); return; } else if (!native->callback) { /* no callback set */ crm_trace("notify event received but client has not set callback"); return; } event.remote_nodename = native->remote_nodename; type = crm_element_value(msg, PCMK__XA_LRMD_OP); crm_element_value_int(msg, PCMK__XA_LRMD_CALLID, &event.call_id); event.rsc_id = crm_element_value(msg, PCMK__XA_LRMD_RSC_ID); if (pcmk__str_eq(type, LRMD_OP_RSC_REG, pcmk__str_none)) { event.type = lrmd_event_register; } else if (pcmk__str_eq(type, LRMD_OP_RSC_UNREG, pcmk__str_none)) { event.type = lrmd_event_unregister; } else if (pcmk__str_eq(type, LRMD_OP_RSC_EXEC, pcmk__str_none)) { int rc = 0; int exec_time = 0; int queue_time = 0; time_t epoch = 0; crm_element_value_int(msg, PCMK__XA_LRMD_TIMEOUT, &event.timeout); crm_element_value_ms(msg, PCMK__XA_LRMD_RSC_INTERVAL, &event.interval_ms); crm_element_value_int(msg, PCMK__XA_LRMD_RSC_START_DELAY, &event.start_delay); crm_element_value_int(msg, PCMK__XA_LRMD_EXEC_RC, &rc); event.rc = (enum ocf_exitcode) rc; crm_element_value_int(msg, PCMK__XA_LRMD_EXEC_OP_STATUS, &event.op_status); crm_element_value_int(msg, PCMK__XA_LRMD_RSC_DELETED, &event.rsc_deleted); crm_element_value_epoch(msg, PCMK__XA_LRMD_RUN_TIME, &epoch); event.t_run = epoch; crm_element_value_epoch(msg, PCMK__XA_LRMD_RCCHANGE_TIME, &epoch); event.t_rcchange = epoch; crm_element_value_int(msg, PCMK__XA_LRMD_EXEC_TIME, &exec_time); CRM_LOG_ASSERT(exec_time >= 0); event.exec_time = QB_MAX(0, exec_time); crm_element_value_int(msg, PCMK__XA_LRMD_QUEUE_TIME, &queue_time); CRM_LOG_ASSERT(queue_time >= 0); event.queue_time = QB_MAX(0, queue_time); event.op_type = crm_element_value(msg, PCMK__XA_LRMD_RSC_ACTION); event.user_data = crm_element_value(msg, PCMK__XA_LRMD_RSC_USERDATA_STR); event.type = lrmd_event_exec_complete; /* output and exit_reason may be freed by a callback */ event.output = crm_element_value_copy(msg, PCMK__XA_LRMD_RSC_OUTPUT); lrmd__set_result(&event, event.rc, event.op_status, crm_element_value(msg, PCMK__XA_LRMD_RSC_EXIT_REASON)); event.params = xml2list(msg); } else if (pcmk__str_eq(type, LRMD_OP_NEW_CLIENT, pcmk__str_none)) { event.type = lrmd_event_new_client; } else if (pcmk__str_eq(type, LRMD_OP_POKE, pcmk__str_none)) { event.type = lrmd_event_poke; } else { return; } crm_trace("op %s notify event received", type); native->callback(&event); if (event.params) { g_hash_table_destroy(event.params); } lrmd__reset_result(&event); } // \return Always 0, to indicate that IPC mainloop source should be kept static int lrmd_ipc_dispatch(const char *buffer, ssize_t length, gpointer userdata) { lrmd_t *lrmd = userdata; lrmd_private_t *native = lrmd->lrmd_private; if (native->callback != NULL) { xmlNode *msg = pcmk__xml_parse(buffer); lrmd_dispatch_internal(msg, lrmd); pcmk__xml_free(msg); } return 0; } static void lrmd_free_xml(gpointer userdata) { pcmk__xml_free((xmlNode *) userdata); } static bool remote_executor_connected(lrmd_t * lrmd) { lrmd_private_t *native = lrmd->lrmd_private; return (native->remote->tls_session != NULL); } static void handle_remote_msg(xmlNode *xml, lrmd_t *lrmd) { lrmd_private_t *native = lrmd->lrmd_private; const char *msg_type = NULL; msg_type = crm_element_value(xml, PCMK__XA_LRMD_REMOTE_MSG_TYPE); if (pcmk__str_eq(msg_type, "notify", pcmk__str_casei)) { lrmd_dispatch_internal(xml, lrmd); } else if (pcmk__str_eq(msg_type, "reply", pcmk__str_casei)) { const char *op = crm_element_value(xml, PCMK__XA_LRMD_OP); if (native->expected_late_replies > 0) { native->expected_late_replies--; /* The register op message we get as a response to lrmd_handshake_async * is a reply, so we have to handle that here. */ if (pcmk__str_eq(op, "register", pcmk__str_casei)) { int rc = process_lrmd_handshake_reply(xml, native); report_async_connection_result(lrmd, pcmk_rc2legacy(rc)); } } else { int reply_id = 0; crm_element_value_int(xml, PCMK__XA_LRMD_CALLID, &reply_id); /* if this happens, we want to know about it */ crm_err("Got outdated Pacemaker Remote reply %d", reply_id); } } } /*! * \internal * \brief Notify trigger handler * * \param[in,out] userdata API connection * * \return Always return G_SOURCE_CONTINUE to leave this trigger handler in the * mainloop */ static int process_pending_notifies(gpointer userdata) { lrmd_t *lrmd = userdata; lrmd_private_t *native = lrmd->lrmd_private; if (native->pending_notify == NULL) { return G_SOURCE_CONTINUE; } crm_trace("Processing pending notifies"); g_list_foreach(native->pending_notify, lrmd_dispatch_internal, lrmd); g_list_free_full(native->pending_notify, lrmd_free_xml); native->pending_notify = NULL; return G_SOURCE_CONTINUE; } /*! * \internal * \brief TLS dispatch function for file descriptor sources * * \param[in,out] userdata API connection * * \return -1 on error to remove the source from the mainloop, or 0 otherwise * to leave it in the mainloop */ static int lrmd_tls_dispatch(gpointer userdata) { lrmd_t *lrmd = userdata; lrmd_private_t *native = lrmd->lrmd_private; xmlNode *xml = NULL; int rc = pcmk_rc_ok; if (!remote_executor_connected(lrmd)) { crm_trace("TLS dispatch triggered after disconnect"); return -1; } crm_trace("TLS dispatch triggered"); rc = pcmk__remote_ready(native->remote, 0); if (rc == pcmk_rc_ok) { rc = pcmk__read_remote_message(native->remote, -1); } if (rc != pcmk_rc_ok && rc != ETIME) { crm_info("Lost %s executor connection while reading data", (native->remote_nodename? native->remote_nodename : "local")); lrmd_tls_disconnect(lrmd); return -1; } /* If rc is ETIME, there was nothing to read but we may already have a * full message in the buffer */ xml = pcmk__remote_message_xml(native->remote); if (xml == NULL) { return 0; } handle_remote_msg(xml, lrmd); pcmk__xml_free(xml); return 0; } /* Not used with mainloop */ int lrmd_poll(lrmd_t * lrmd, int timeout) { lrmd_private_t *native = lrmd->lrmd_private; switch (native->type) { case pcmk__client_ipc: return crm_ipc_ready(native->ipc); case pcmk__client_tls: if (native->pending_notify) { return 1; } else { int rc = pcmk__remote_ready(native->remote, 0); switch (rc) { case pcmk_rc_ok: return 1; case ETIME: return 0; default: return pcmk_rc2legacy(rc); } } default: crm_err("Unsupported executor connection type (bug?): %d", native->type); return -EPROTONOSUPPORT; } } /* Not used with mainloop */ bool lrmd_dispatch(lrmd_t * lrmd) { lrmd_private_t *private = NULL; pcmk__assert(lrmd != NULL); private = lrmd->lrmd_private; switch (private->type) { case pcmk__client_ipc: while (crm_ipc_ready(private->ipc)) { if (crm_ipc_read(private->ipc) > 0) { const char *msg = crm_ipc_buffer(private->ipc); lrmd_ipc_dispatch(msg, strlen(msg), lrmd); } } break; case pcmk__client_tls: lrmd_tls_dispatch(lrmd); break; default: crm_err("Unsupported executor connection type (bug?): %d", private->type); } if (lrmd_api_is_connected(lrmd) == FALSE) { crm_err("Connection closed"); return FALSE; } return TRUE; } static xmlNode * lrmd_create_op(const char *token, const char *op, xmlNode *data, int timeout, enum lrmd_call_options options) { xmlNode *op_msg = NULL; CRM_CHECK(token != NULL, return NULL); op_msg = pcmk__xe_create(NULL, PCMK__XE_LRMD_COMMAND); crm_xml_add(op_msg, PCMK__XA_T, PCMK__VALUE_LRMD); crm_xml_add(op_msg, PCMK__XA_LRMD_OP, op); crm_xml_add_int(op_msg, PCMK__XA_LRMD_TIMEOUT, timeout); crm_xml_add_int(op_msg, PCMK__XA_LRMD_CALLOPT, options); if (data != NULL) { xmlNode *wrapper = pcmk__xe_create(op_msg, PCMK__XE_LRMD_CALLDATA); pcmk__xml_copy(wrapper, data); } crm_trace("Created executor %s command with call options %.8lx (%d)", op, (long)options, options); return op_msg; } static void lrmd_ipc_connection_destroy(gpointer userdata) { lrmd_t *lrmd = userdata; lrmd_private_t *native = lrmd->lrmd_private; switch (native->type) { case pcmk__client_ipc: crm_info("Disconnected from local executor"); break; case pcmk__client_tls: crm_info("Disconnected from remote executor on %s", native->remote_nodename); break; default: crm_err("Unsupported executor connection type %d (bug?)", native->type); } /* Prevent these from being cleaned up in lrmd_api_disconnect() */ native->ipc = NULL; native->source = NULL; if (native->callback) { lrmd_event_data_t event = { 0, }; event.type = lrmd_event_disconnect; event.remote_nodename = native->remote_nodename; native->callback(&event); } } static void lrmd_tls_connection_destroy(gpointer userdata) { lrmd_t *lrmd = userdata; lrmd_private_t *native = lrmd->lrmd_private; crm_info("TLS connection destroyed"); if (native->remote->tls_session) { - gnutls_bye(*native->remote->tls_session, GNUTLS_SHUT_RDWR); - gnutls_deinit(*native->remote->tls_session); - gnutls_free(native->remote->tls_session); + gnutls_bye(native->remote->tls_session, GNUTLS_SHUT_RDWR); + gnutls_deinit(native->remote->tls_session); native->remote->tls_session = NULL; } if (native->psk_cred_c) { gnutls_psk_free_client_credentials(native->psk_cred_c); } if (native->sock) { close(native->sock); } if (native->process_notify) { mainloop_destroy_trigger(native->process_notify); native->process_notify = NULL; } if (native->pending_notify) { g_list_free_full(native->pending_notify, lrmd_free_xml); native->pending_notify = NULL; } if (native->handshake_trigger != NULL) { mainloop_destroy_trigger(native->handshake_trigger); native->handshake_trigger = NULL; } free(native->remote->buffer); free(native->remote->start_state); native->remote->buffer = NULL; native->remote->start_state = NULL; native->source = 0; native->sock = 0; native->psk_cred_c = NULL; native->sock = 0; if (native->callback) { lrmd_event_data_t event = { 0, }; event.remote_nodename = native->remote_nodename; event.type = lrmd_event_disconnect; native->callback(&event); } return; } // \return Standard Pacemaker return code int lrmd__remote_send_xml(pcmk__remote_t *session, xmlNode *msg, uint32_t id, const char *msg_type) { crm_xml_add_int(msg, PCMK__XA_LRMD_REMOTE_MSG_ID, id); crm_xml_add(msg, PCMK__XA_LRMD_REMOTE_MSG_TYPE, msg_type); return pcmk__remote_send_xml(session, msg); } // \return Standard Pacemaker return code static int read_remote_reply(lrmd_t *lrmd, int total_timeout, int expected_reply_id, xmlNode **reply) { lrmd_private_t *native = lrmd->lrmd_private; time_t start = time(NULL); const char *msg_type = NULL; int reply_id = 0; int remaining_timeout = 0; int rc = pcmk_rc_ok; /* A timeout of 0 here makes no sense. We have to wait a period of time * for the response to come back. If -1 or 0, default to 10 seconds. */ if (total_timeout <= 0 || total_timeout > MAX_TLS_RECV_WAIT) { total_timeout = MAX_TLS_RECV_WAIT; } for (*reply = NULL; *reply == NULL; ) { *reply = pcmk__remote_message_xml(native->remote); if (*reply == NULL) { /* read some more off the tls buffer if we still have time left. */ if (remaining_timeout) { remaining_timeout = total_timeout - ((time(NULL) - start) * 1000); } else { remaining_timeout = total_timeout; } if (remaining_timeout <= 0) { return ETIME; } rc = pcmk__read_remote_message(native->remote, remaining_timeout); if (rc != pcmk_rc_ok) { return rc; } *reply = pcmk__remote_message_xml(native->remote); if (*reply == NULL) { return ENOMSG; } } crm_element_value_int(*reply, PCMK__XA_LRMD_REMOTE_MSG_ID, &reply_id); msg_type = crm_element_value(*reply, PCMK__XA_LRMD_REMOTE_MSG_TYPE); if (!msg_type) { crm_err("Empty msg type received while waiting for reply"); pcmk__xml_free(*reply); *reply = NULL; } else if (pcmk__str_eq(msg_type, "notify", pcmk__str_casei)) { /* got a notify while waiting for reply, trigger the notify to be processed later */ crm_info("queueing notify"); native->pending_notify = g_list_append(native->pending_notify, *reply); if (native->process_notify) { crm_info("notify trigger set."); mainloop_set_trigger(native->process_notify); } *reply = NULL; } else if (!pcmk__str_eq(msg_type, "reply", pcmk__str_casei)) { /* msg isn't a reply, make some noise */ crm_err("Expected a reply, got %s", msg_type); pcmk__xml_free(*reply); *reply = NULL; } else if (reply_id != expected_reply_id) { if (native->expected_late_replies > 0) { native->expected_late_replies--; } else { crm_err("Got outdated reply, expected id %d got id %d", expected_reply_id, reply_id); } pcmk__xml_free(*reply); *reply = NULL; } } if (native->remote->buffer && native->process_notify) { mainloop_set_trigger(native->process_notify); } return rc; } // \return Standard Pacemaker return code static int send_remote_message(lrmd_t *lrmd, xmlNode *msg) { int rc = pcmk_rc_ok; lrmd_private_t *native = lrmd->lrmd_private; global_remote_msg_id++; if (global_remote_msg_id <= 0) { global_remote_msg_id = 1; } rc = lrmd__remote_send_xml(native->remote, msg, global_remote_msg_id, "request"); if (rc != pcmk_rc_ok) { crm_err("Disconnecting because TLS message could not be sent to " "Pacemaker Remote: %s", pcmk_rc_str(rc)); lrmd_tls_disconnect(lrmd); } return rc; } static int lrmd_tls_send_recv(lrmd_t * lrmd, xmlNode * msg, int timeout, xmlNode ** reply) { int rc = 0; xmlNode *xml = NULL; if (!remote_executor_connected(lrmd)) { return -ENOTCONN; } rc = send_remote_message(lrmd, msg); if (rc != pcmk_rc_ok) { return pcmk_rc2legacy(rc); } rc = read_remote_reply(lrmd, timeout, global_remote_msg_id, &xml); if (rc != pcmk_rc_ok) { crm_err("Disconnecting remote after request %d reply not received: %s " QB_XS " rc=%d timeout=%dms", global_remote_msg_id, pcmk_rc_str(rc), rc, timeout); lrmd_tls_disconnect(lrmd); } if (reply) { *reply = xml; } else { pcmk__xml_free(xml); } return pcmk_rc2legacy(rc); } static int lrmd_send_xml(lrmd_t * lrmd, xmlNode * msg, int timeout, xmlNode ** reply) { int rc = pcmk_ok; lrmd_private_t *native = lrmd->lrmd_private; switch (native->type) { case pcmk__client_ipc: rc = crm_ipc_send(native->ipc, msg, crm_ipc_client_response, timeout, reply); break; case pcmk__client_tls: rc = lrmd_tls_send_recv(lrmd, msg, timeout, reply); break; default: crm_err("Unsupported executor connection type (bug?): %d", native->type); rc = -EPROTONOSUPPORT; } return rc; } static int lrmd_send_xml_no_reply(lrmd_t * lrmd, xmlNode * msg) { int rc = pcmk_ok; lrmd_private_t *native = lrmd->lrmd_private; switch (native->type) { case pcmk__client_ipc: rc = crm_ipc_send(native->ipc, msg, crm_ipc_flags_none, 0, NULL); break; case pcmk__client_tls: rc = send_remote_message(lrmd, msg); if (rc == pcmk_rc_ok) { /* we don't want to wait around for the reply, but * since the request/reply protocol needs to behave the same * as libqb, a reply will eventually come later anyway. */ native->expected_late_replies++; } rc = pcmk_rc2legacy(rc); break; default: crm_err("Unsupported executor connection type (bug?): %d", native->type); rc = -EPROTONOSUPPORT; } return rc; } static int lrmd_api_is_connected(lrmd_t * lrmd) { lrmd_private_t *native = lrmd->lrmd_private; switch (native->type) { case pcmk__client_ipc: return crm_ipc_connected(native->ipc); case pcmk__client_tls: return remote_executor_connected(lrmd); default: crm_err("Unsupported executor connection type (bug?): %d", native->type); return 0; } } /*! * \internal * \brief Send a prepared API command to the executor * * \param[in,out] lrmd Existing connection to the executor * \param[in] op Name of API command to send * \param[in] data Command data XML to add to the sent command * \param[out] output_data If expecting a reply, it will be stored here * \param[in] timeout Timeout in milliseconds (if 0, defaults to * a sensible value per the type of connection, * standard vs. pacemaker remote); * also propagated to the command XML * \param[in] call_options Call options to pass to server when sending * \param[in] expect_reply If true, wait for a reply from the server; * must be true for IPC (as opposed to TLS) clients * * \return pcmk_ok on success, -errno on error */ static int lrmd_send_command(lrmd_t *lrmd, const char *op, xmlNode *data, xmlNode **output_data, int timeout, enum lrmd_call_options options, bool expect_reply) { int rc = pcmk_ok; lrmd_private_t *native = lrmd->lrmd_private; xmlNode *op_msg = NULL; xmlNode *op_reply = NULL; if (!lrmd_api_is_connected(lrmd)) { return -ENOTCONN; } if (op == NULL) { crm_err("No operation specified"); return -EINVAL; } CRM_LOG_ASSERT(native->token != NULL); crm_trace("Sending %s op to executor", op); op_msg = lrmd_create_op(native->token, op, data, timeout, options); if (op_msg == NULL) { return -EINVAL; } if (expect_reply) { rc = lrmd_send_xml(lrmd, op_msg, timeout, &op_reply); } else { rc = lrmd_send_xml_no_reply(lrmd, op_msg); goto done; } if (rc < 0) { crm_perror(LOG_ERR, "Couldn't perform %s operation (timeout=%d): %d", op, timeout, rc); goto done; } else if (op_reply == NULL) { rc = -ENOMSG; goto done; } rc = pcmk_ok; crm_trace("%s op reply received", op); if (crm_element_value_int(op_reply, PCMK__XA_LRMD_RC, &rc) != 0) { rc = -ENOMSG; goto done; } crm_log_xml_trace(op_reply, "Reply"); if (output_data) { *output_data = op_reply; op_reply = NULL; /* Prevent subsequent free */ } done: if (lrmd_api_is_connected(lrmd) == FALSE) { crm_err("Executor disconnected"); } pcmk__xml_free(op_msg); pcmk__xml_free(op_reply); return rc; } static int lrmd_api_poke_connection(lrmd_t * lrmd) { int rc; lrmd_private_t *native = lrmd->lrmd_private; xmlNode *data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); rc = lrmd_send_command(lrmd, LRMD_OP_POKE, data, NULL, 0, 0, (native->type == pcmk__client_ipc)); pcmk__xml_free(data); return rc < 0 ? rc : pcmk_ok; } // \return Standard Pacemaker return code int lrmd__validate_remote_settings(lrmd_t *lrmd, GHashTable *hash) { int rc = pcmk_rc_ok; const char *value; lrmd_private_t *native = lrmd->lrmd_private; xmlNode *data = pcmk__xe_create(NULL, PCMK__XA_LRMD_OP); crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); value = g_hash_table_lookup(hash, PCMK_OPT_STONITH_WATCHDOG_TIMEOUT); if ((value) && (stonith__watchdog_fencing_enabled_for_node(native->remote_nodename))) { crm_xml_add(data, PCMK__XA_LRMD_WATCHDOG, value); } rc = lrmd_send_command(lrmd, LRMD_OP_CHECK, data, NULL, 0, 0, (native->type == pcmk__client_ipc)); pcmk__xml_free(data); return (rc < 0)? pcmk_legacy2rc(rc) : pcmk_rc_ok; } static xmlNode * lrmd_handshake_hello_msg(const char *name, bool is_proxy) { xmlNode *hello = pcmk__xe_create(NULL, PCMK__XE_LRMD_COMMAND); crm_xml_add(hello, PCMK__XA_T, PCMK__VALUE_LRMD); crm_xml_add(hello, PCMK__XA_LRMD_OP, CRM_OP_REGISTER); crm_xml_add(hello, PCMK__XA_LRMD_CLIENTNAME, name); crm_xml_add(hello, PCMK__XA_LRMD_PROTOCOL_VERSION, LRMD_PROTOCOL_VERSION); /* advertise that we are a proxy provider */ if (is_proxy) { pcmk__xe_set_bool_attr(hello, PCMK__XA_LRMD_IS_IPC_PROVIDER, true); } return hello; } static int process_lrmd_handshake_reply(xmlNode *reply, lrmd_private_t *native) { int rc = pcmk_rc_ok; const char *version = crm_element_value(reply, PCMK__XA_LRMD_PROTOCOL_VERSION); const char *msg_type = crm_element_value(reply, PCMK__XA_LRMD_OP); const char *tmp_ticket = crm_element_value(reply, PCMK__XA_LRMD_CLIENTID); const char *start_state = crm_element_value(reply, PCMK__XA_NODE_START_STATE); long long uptime = -1; crm_element_value_int(reply, PCMK__XA_LRMD_RC, &rc); rc = pcmk_legacy2rc(rc); /* The remote executor may add its uptime to the XML reply, which is useful * in handling transient attributes when the connection to the remote node * unexpectedly drops. If no parameter is given, just default to -1. */ crm_element_value_ll(reply, PCMK__XA_UPTIME, &uptime); native->remote->uptime = uptime; if (start_state) { native->remote->start_state = strdup(start_state); } if (rc == EPROTO) { crm_err("Executor protocol version mismatch between client (%s) and server (%s)", LRMD_PROTOCOL_VERSION, version); crm_log_xml_err(reply, "Protocol Error"); } else if (!pcmk__str_eq(msg_type, CRM_OP_REGISTER, pcmk__str_casei)) { crm_err("Invalid registration message: %s", msg_type); crm_log_xml_err(reply, "Bad reply"); rc = EPROTO; } else if (tmp_ticket == NULL) { crm_err("No registration token provided"); crm_log_xml_err(reply, "Bad reply"); rc = EPROTO; } else { crm_trace("Obtained registration token: %s", tmp_ticket); native->token = strdup(tmp_ticket); native->peer_version = strdup(version?version:"1.0"); /* Included since 1.1 */ rc = pcmk_rc_ok; } return rc; } static int lrmd_handshake(lrmd_t * lrmd, const char *name) { int rc = pcmk_rc_ok; lrmd_private_t *native = lrmd->lrmd_private; xmlNode *reply = NULL; xmlNode *hello = lrmd_handshake_hello_msg(name, native->proxy_callback != NULL); rc = lrmd_send_xml(lrmd, hello, -1, &reply); if (rc < 0) { crm_perror(LOG_DEBUG, "Couldn't complete registration with the executor API: %d", rc); rc = ECOMM; } else if (reply == NULL) { crm_err("Did not receive registration reply"); rc = EPROTO; } else { rc = process_lrmd_handshake_reply(reply, native); } pcmk__xml_free(reply); pcmk__xml_free(hello); if (rc != pcmk_rc_ok) { lrmd_api_disconnect(lrmd); } return rc; } static int lrmd_handshake_async(lrmd_t * lrmd, const char *name) { int rc = pcmk_rc_ok; lrmd_private_t *native = lrmd->lrmd_private; xmlNode *hello = lrmd_handshake_hello_msg(name, native->proxy_callback != NULL); rc = send_remote_message(lrmd, hello); if (rc == pcmk_rc_ok) { native->expected_late_replies++; } else { lrmd_api_disconnect(lrmd); } pcmk__xml_free(hello); return rc; } static int lrmd_ipc_connect(lrmd_t * lrmd, int *fd) { int rc = pcmk_ok; lrmd_private_t *native = lrmd->lrmd_private; struct ipc_client_callbacks lrmd_callbacks = { .dispatch = lrmd_ipc_dispatch, .destroy = lrmd_ipc_connection_destroy }; crm_info("Connecting to executor"); if (fd) { /* No mainloop */ native->ipc = crm_ipc_new(CRM_SYSTEM_LRMD, 0); if (native->ipc != NULL) { rc = pcmk__connect_generic_ipc(native->ipc); if (rc == pcmk_rc_ok) { rc = pcmk__ipc_fd(native->ipc, fd); } if (rc != pcmk_rc_ok) { crm_err("Connection to executor failed: %s", pcmk_rc_str(rc)); rc = -ENOTCONN; } } } else { native->source = mainloop_add_ipc_client(CRM_SYSTEM_LRMD, G_PRIORITY_HIGH, 0, lrmd, &lrmd_callbacks); native->ipc = mainloop_get_ipc_client(native->source); } if (native->ipc == NULL) { crm_debug("Could not connect to the executor API"); rc = -ENOTCONN; } return rc; } static void copy_gnutls_datum(gnutls_datum_t *dest, gnutls_datum_t *source) { pcmk__assert((dest != NULL) && (source != NULL) && (source->data != NULL)); dest->data = gnutls_malloc(source->size); pcmk__mem_assert(dest->data); memcpy(dest->data, source->data, source->size); dest->size = source->size; } static void clear_gnutls_datum(gnutls_datum_t *datum) { gnutls_free(datum->data); datum->data = NULL; datum->size = 0; } #define KEY_READ_LEN 256 // Chunk size for reading key from file // \return Standard Pacemaker return code static int read_gnutls_key(const char *location, gnutls_datum_t *key) { FILE *stream = NULL; size_t buf_len = KEY_READ_LEN; if ((location == NULL) || (key == NULL)) { return EINVAL; } stream = fopen(location, "r"); if (stream == NULL) { return errno; } key->data = gnutls_malloc(buf_len); key->size = 0; while (!feof(stream)) { int next = fgetc(stream); if (next == EOF) { if (!feof(stream)) { crm_warn("Pacemaker Remote key read was partially successful " "(copy in memory may be corrupted)"); } break; } if (key->size == buf_len) { buf_len = key->size + KEY_READ_LEN; key->data = gnutls_realloc(key->data, buf_len); pcmk__assert(key->data); } key->data[key->size++] = (unsigned char) next; } fclose(stream); if (key->size == 0) { clear_gnutls_datum(key); return ENOKEY; } return pcmk_rc_ok; } // Cache the most recently used Pacemaker Remote authentication key struct key_cache_s { time_t updated; // When cached key was read (valid for 1 minute) const char *location; // Where cached key was read from gnutls_datum_t key; // Cached key }; static bool key_is_cached(struct key_cache_s *key_cache) { return key_cache->updated != 0; } static bool key_cache_expired(struct key_cache_s *key_cache) { return (time(NULL) - key_cache->updated) >= 60; } static void clear_key_cache(struct key_cache_s *key_cache) { clear_gnutls_datum(&(key_cache->key)); if ((key_cache->updated != 0) || (key_cache->location != NULL)) { key_cache->updated = 0; key_cache->location = NULL; crm_debug("Cleared Pacemaker Remote key cache"); } } static void get_cached_key(struct key_cache_s *key_cache, gnutls_datum_t *key) { copy_gnutls_datum(key, &(key_cache->key)); crm_debug("Using cached Pacemaker Remote key from %s", pcmk__s(key_cache->location, "unknown location")); } static void cache_key(struct key_cache_s *key_cache, gnutls_datum_t *key, const char *location) { key_cache->updated = time(NULL); key_cache->location = location; copy_gnutls_datum(&(key_cache->key), key); crm_debug("Using (and cacheing) Pacemaker Remote key from %s", pcmk__s(location, "unknown location")); } /*! * \internal * \brief Get Pacemaker Remote authentication key from file or cache * * \param[in] location Path to key file to try (this memory must * persist across all calls of this function) * \param[out] key Key from location or cache * * \return Standard Pacemaker return code */ static int get_remote_key(const char *location, gnutls_datum_t *key) { static struct key_cache_s key_cache = { 0, }; int rc = pcmk_rc_ok; if ((location == NULL) || (key == NULL)) { return EINVAL; } if (key_is_cached(&key_cache)) { if (key_cache_expired(&key_cache)) { clear_key_cache(&key_cache); } else { get_cached_key(&key_cache, key); return pcmk_rc_ok; } } rc = read_gnutls_key(location, key); if (rc != pcmk_rc_ok) { return rc; } cache_key(&key_cache, key, location); return pcmk_rc_ok; } /*! * \internal * \brief Initialize the Pacemaker Remote authentication key * * Try loading the Pacemaker Remote authentication key from cache if available, * otherwise from these locations, in order of preference: * * - The value of the PCMK_authkey_location environment variable, if set * - The Pacemaker default key file location * * \param[out] key Where to store key * * \return Standard Pacemaker return code */ int lrmd__init_remote_key(gnutls_datum_t *key) { static const char *env_location = NULL; static bool need_env = true; int rc = pcmk_rc_ok; if (need_env) { env_location = pcmk__env_option(PCMK__ENV_AUTHKEY_LOCATION); need_env = false; } // Try location in environment variable, if set if (env_location != NULL) { rc = get_remote_key(env_location, key); if (rc == pcmk_rc_ok) { return pcmk_rc_ok; } crm_warn("Could not read Pacemaker Remote key from %s: %s", env_location, pcmk_rc_str(rc)); return ENOKEY; } // Try default location, if environment wasn't explicitly set to it rc = get_remote_key(DEFAULT_REMOTE_KEY_LOCATION, key); if (rc == pcmk_rc_ok) { return pcmk_rc_ok; } crm_warn("Could not read Pacemaker Remote key from default location %s: %s", DEFAULT_REMOTE_KEY_LOCATION, pcmk_rc_str(rc)); return ENOKEY; } static void lrmd_gnutls_global_init(void) { static int gnutls_init = 0; if (!gnutls_init) { crm_gnutls_global_init(); } gnutls_init = 1; } static void report_async_connection_result(lrmd_t * lrmd, int rc) { lrmd_private_t *native = lrmd->lrmd_private; if (native->callback) { lrmd_event_data_t event = { 0, }; event.type = lrmd_event_connect; event.remote_nodename = native->remote_nodename; event.connection_rc = rc; native->callback(&event); } } static void tls_handshake_failed(lrmd_t *lrmd, int tls_rc, int rc) { lrmd_private_t *native = lrmd->lrmd_private; crm_warn("Disconnecting after TLS handshake with " "Pacemaker Remote server %s:%d failed: %s", native->server, native->port, (rc == EPROTO)? gnutls_strerror(tls_rc) : pcmk_rc_str(rc)); report_async_connection_result(lrmd, pcmk_rc2legacy(rc)); - gnutls_deinit(*native->remote->tls_session); - gnutls_free(native->remote->tls_session); + gnutls_deinit(native->remote->tls_session); native->remote->tls_session = NULL; lrmd_tls_connection_destroy(lrmd); } static void tls_handshake_succeeded(lrmd_t *lrmd) { int rc = pcmk_rc_ok; lrmd_private_t *native = lrmd->lrmd_private; crm_info("TLS connection to Pacemaker Remote server %s:%d succeeded", native->server, native->port); rc = add_tls_to_mainloop(lrmd, true); /* If add_tls_to_mainloop failed, report that right now. Otherwise, we have * to wait until we read the async reply to report anything. */ if (rc != pcmk_rc_ok) { report_async_connection_result(lrmd, pcmk_rc2legacy(rc)); } } /*! * \internal * \brief Perform a TLS client handshake with a Pacemaker Remote server * * \param[in] lrmd Newly established Pacemaker Remote executor connection * * \return Standard Pacemaker return code */ static int tls_client_handshake(lrmd_t *lrmd) { lrmd_private_t *native = lrmd->lrmd_private; int tls_rc = GNUTLS_E_SUCCESS; int rc = pcmk__tls_client_handshake(native->remote, TLS_HANDSHAKE_TIMEOUT, &tls_rc); if (rc != pcmk_rc_ok) { tls_handshake_failed(lrmd, tls_rc, rc); } return rc; } /*! * \internal * \brief Add trigger and file descriptor mainloop sources for TLS * * \param[in,out] lrmd API connection with established TLS session * \param[in] do_api_handshake Whether to perform executor handshake * * \return Standard Pacemaker return code */ static int add_tls_to_mainloop(lrmd_t *lrmd, bool do_api_handshake) { lrmd_private_t *native = lrmd->lrmd_private; int rc = pcmk_rc_ok; char *name = crm_strdup_printf("pacemaker-remote-%s:%d", native->server, native->port); struct mainloop_fd_callbacks tls_fd_callbacks = { .dispatch = lrmd_tls_dispatch, .destroy = lrmd_tls_connection_destroy, }; native->process_notify = mainloop_add_trigger(G_PRIORITY_HIGH, process_pending_notifies, lrmd); native->source = mainloop_add_fd(name, G_PRIORITY_HIGH, native->sock, lrmd, &tls_fd_callbacks); /* Async connections lose the client name provided by the API caller, so we * have to use our generated name here to perform the executor handshake. * * @TODO Keep track of the caller-provided name. Perhaps we should be using * that name in this function instead of generating one anyway. */ if (do_api_handshake) { rc = lrmd_handshake_async(lrmd, name); } free(name); return rc; } struct handshake_data_s { lrmd_t *lrmd; time_t start_time; int timeout_sec; }; static gboolean try_handshake_cb(gpointer user_data) { struct handshake_data_s *hs = user_data; lrmd_t *lrmd = hs->lrmd; lrmd_private_t *native = lrmd->lrmd_private; pcmk__remote_t *remote = native->remote; int rc = pcmk_rc_ok; int tls_rc = GNUTLS_E_SUCCESS; if (time(NULL) >= hs->start_time + hs->timeout_sec) { rc = ETIME; tls_handshake_failed(lrmd, GNUTLS_E_TIMEDOUT, rc); free(hs); return 0; } rc = pcmk__tls_client_try_handshake(remote, &tls_rc); if (rc == pcmk_rc_ok) { tls_handshake_succeeded(lrmd); free(hs); return 0; } else if (rc == EAGAIN) { mainloop_set_trigger(native->handshake_trigger); return 1; } else { rc = EKEYREJECTED; tls_handshake_failed(lrmd, tls_rc, rc); free(hs); return 0; } } static void lrmd_tcp_connect_cb(void *userdata, int rc, int sock) { lrmd_t *lrmd = userdata; lrmd_private_t *native = lrmd->lrmd_private; gnutls_datum_t psk_key = { NULL, 0 }; int tls_rc = GNUTLS_E_SUCCESS; native->async_timer = 0; if (rc != pcmk_rc_ok) { lrmd_tls_connection_destroy(lrmd); crm_info("Could not connect to Pacemaker Remote at %s:%d: %s " QB_XS " rc=%d", native->server, native->port, pcmk_rc_str(rc), rc); report_async_connection_result(lrmd, pcmk_rc2legacy(rc)); return; } /* The TCP connection was successful, so establish the TLS connection. */ native->sock = sock; rc = lrmd__init_remote_key(&psk_key); if (rc != pcmk_rc_ok) { crm_info("Could not connect to Pacemaker Remote at %s:%d: %s " QB_XS " rc=%d", native->server, native->port, pcmk_rc_str(rc), rc); lrmd_tls_connection_destroy(lrmd); report_async_connection_result(lrmd, pcmk_rc2legacy(rc)); return; } gnutls_psk_allocate_client_credentials(&native->psk_cred_c); gnutls_psk_set_client_credentials(native->psk_cred_c, DEFAULT_REMOTE_USERNAME, &psk_key, GNUTLS_PSK_KEY_RAW); gnutls_free(psk_key.data); native->remote->tls_session = pcmk__new_tls_session(sock, GNUTLS_CLIENT, GNUTLS_CRD_PSK, native->psk_cred_c); if (native->remote->tls_session == NULL) { lrmd_tls_connection_destroy(lrmd); report_async_connection_result(lrmd, -EPROTO); return; } /* If the TLS handshake immediately succeeds or fails, we can handle that * now without having to deal with mainloops and retries. Otherwise, add a * trigger to keep trying until we get a result (or it times out). */ rc = pcmk__tls_client_try_handshake(native->remote, &tls_rc); if (rc == EAGAIN) { struct handshake_data_s *hs = NULL; if (native->handshake_trigger != NULL) { return; } hs = pcmk__assert_alloc(1, sizeof(struct handshake_data_s)); hs->lrmd = lrmd; hs->start_time = time(NULL); hs->timeout_sec = TLS_HANDSHAKE_TIMEOUT; native->handshake_trigger = mainloop_add_trigger(G_PRIORITY_LOW, try_handshake_cb, hs); mainloop_set_trigger(native->handshake_trigger); } else if (rc == pcmk_rc_ok) { tls_handshake_succeeded(lrmd); } else { tls_handshake_failed(lrmd, tls_rc, rc); } } static int lrmd_tls_connect_async(lrmd_t * lrmd, int timeout /*ms */ ) { int rc = pcmk_rc_ok; int timer_id = 0; lrmd_private_t *native = lrmd->lrmd_private; lrmd_gnutls_global_init(); native->sock = -1; rc = pcmk__connect_remote(native->server, native->port, timeout, &timer_id, &(native->sock), lrmd, lrmd_tcp_connect_cb); if (rc != pcmk_rc_ok) { crm_warn("Pacemaker Remote connection to %s:%d failed: %s " QB_XS " rc=%d", native->server, native->port, pcmk_rc_str(rc), rc); return rc; } native->async_timer = timer_id; return rc; } static int lrmd_tls_connect(lrmd_t * lrmd, int *fd) { int rc = pcmk_rc_ok; lrmd_private_t *native = lrmd->lrmd_private; gnutls_datum_t psk_key = { NULL, 0 }; lrmd_gnutls_global_init(); native->sock = -1; rc = pcmk__connect_remote(native->server, native->port, 0, NULL, &(native->sock), NULL, NULL); if (rc != pcmk_rc_ok) { crm_warn("Pacemaker Remote connection to %s:%d failed: %s " QB_XS " rc=%d", native->server, native->port, pcmk_rc_str(rc), rc); lrmd_tls_connection_destroy(lrmd); return ENOTCONN; } rc = lrmd__init_remote_key(&psk_key); if (rc != pcmk_rc_ok) { lrmd_tls_connection_destroy(lrmd); return rc; } gnutls_psk_allocate_client_credentials(&native->psk_cred_c); gnutls_psk_set_client_credentials(native->psk_cred_c, DEFAULT_REMOTE_USERNAME, &psk_key, GNUTLS_PSK_KEY_RAW); gnutls_free(psk_key.data); native->remote->tls_session = pcmk__new_tls_session(native->sock, GNUTLS_CLIENT, GNUTLS_CRD_PSK, native->psk_cred_c); if (native->remote->tls_session == NULL) { lrmd_tls_connection_destroy(lrmd); return EPROTO; } if (tls_client_handshake(lrmd) != pcmk_rc_ok) { return EKEYREJECTED; } crm_info("Client TLS connection established with Pacemaker Remote server %s:%d", native->server, native->port); if (fd) { *fd = native->sock; } else { rc = add_tls_to_mainloop(lrmd, false); } return rc; } static int lrmd_api_connect(lrmd_t * lrmd, const char *name, int *fd) { int rc = -ENOTCONN; lrmd_private_t *native = lrmd->lrmd_private; switch (native->type) { case pcmk__client_ipc: rc = lrmd_ipc_connect(lrmd, fd); break; case pcmk__client_tls: rc = lrmd_tls_connect(lrmd, fd); rc = pcmk_rc2legacy(rc); break; default: crm_err("Unsupported executor connection type (bug?): %d", native->type); rc = -EPROTONOSUPPORT; } if (rc == pcmk_ok) { rc = lrmd_handshake(lrmd, name); rc = pcmk_rc2legacy(rc); } return rc; } static int lrmd_api_connect_async(lrmd_t * lrmd, const char *name, int timeout) { int rc = pcmk_ok; lrmd_private_t *native = lrmd->lrmd_private; CRM_CHECK(native && native->callback, return -EINVAL); switch (native->type) { case pcmk__client_ipc: /* fake async connection with ipc. it should be fast * enough that we gain very little from async */ rc = lrmd_api_connect(lrmd, name, NULL); if (!rc) { report_async_connection_result(lrmd, rc); } break; case pcmk__client_tls: rc = lrmd_tls_connect_async(lrmd, timeout); rc = pcmk_rc2legacy(rc); break; default: crm_err("Unsupported executor connection type (bug?): %d", native->type); rc = -EPROTONOSUPPORT; } return rc; } static void lrmd_ipc_disconnect(lrmd_t * lrmd) { lrmd_private_t *native = lrmd->lrmd_private; if (native->source != NULL) { /* Attached to mainloop */ mainloop_del_ipc_client(native->source); native->source = NULL; native->ipc = NULL; } else if (native->ipc) { /* Not attached to mainloop */ crm_ipc_t *ipc = native->ipc; native->ipc = NULL; crm_ipc_close(ipc); crm_ipc_destroy(ipc); } } static void lrmd_tls_disconnect(lrmd_t * lrmd) { lrmd_private_t *native = lrmd->lrmd_private; if (native->remote->tls_session) { - gnutls_bye(*native->remote->tls_session, GNUTLS_SHUT_RDWR); - gnutls_deinit(*native->remote->tls_session); - gnutls_free(native->remote->tls_session); + gnutls_bye(native->remote->tls_session, GNUTLS_SHUT_RDWR); + gnutls_deinit(native->remote->tls_session); native->remote->tls_session = NULL; } if (native->async_timer) { g_source_remove(native->async_timer); native->async_timer = 0; } if (native->source != NULL) { /* Attached to mainloop */ mainloop_del_ipc_client(native->source); native->source = NULL; } else if (native->sock) { close(native->sock); native->sock = 0; } if (native->pending_notify) { g_list_free_full(native->pending_notify, lrmd_free_xml); native->pending_notify = NULL; } } static int lrmd_api_disconnect(lrmd_t * lrmd) { lrmd_private_t *native = lrmd->lrmd_private; int rc = pcmk_ok; switch (native->type) { case pcmk__client_ipc: crm_debug("Disconnecting from local executor"); lrmd_ipc_disconnect(lrmd); break; case pcmk__client_tls: crm_debug("Disconnecting from remote executor on %s", native->remote_nodename); lrmd_tls_disconnect(lrmd); break; default: crm_err("Unsupported executor connection type (bug?): %d", native->type); rc = -EPROTONOSUPPORT; } free(native->token); native->token = NULL; free(native->peer_version); native->peer_version = NULL; return rc; } static int lrmd_api_register_rsc(lrmd_t * lrmd, const char *rsc_id, const char *class, const char *provider, const char *type, enum lrmd_call_options options) { int rc = pcmk_ok; xmlNode *data = NULL; if (!class || !type || !rsc_id) { return -EINVAL; } if (pcmk_is_set(pcmk_get_ra_caps(class), pcmk_ra_cap_provider) && (provider == NULL)) { return -EINVAL; } data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_RSC_ID, rsc_id); crm_xml_add(data, PCMK__XA_LRMD_CLASS, class); crm_xml_add(data, PCMK__XA_LRMD_PROVIDER, provider); crm_xml_add(data, PCMK__XA_LRMD_TYPE, type); rc = lrmd_send_command(lrmd, LRMD_OP_RSC_REG, data, NULL, 0, options, true); pcmk__xml_free(data); return rc; } static int lrmd_api_unregister_rsc(lrmd_t * lrmd, const char *rsc_id, enum lrmd_call_options options) { int rc = pcmk_ok; xmlNode *data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_RSC_ID, rsc_id); rc = lrmd_send_command(lrmd, LRMD_OP_RSC_UNREG, data, NULL, 0, options, true); pcmk__xml_free(data); return rc; } lrmd_rsc_info_t * lrmd_new_rsc_info(const char *rsc_id, const char *standard, const char *provider, const char *type) { lrmd_rsc_info_t *rsc_info = pcmk__assert_alloc(1, sizeof(lrmd_rsc_info_t)); rsc_info->id = pcmk__str_copy(rsc_id); rsc_info->standard = pcmk__str_copy(standard); rsc_info->provider = pcmk__str_copy(provider); rsc_info->type = pcmk__str_copy(type); return rsc_info; } lrmd_rsc_info_t * lrmd_copy_rsc_info(lrmd_rsc_info_t * rsc_info) { return lrmd_new_rsc_info(rsc_info->id, rsc_info->standard, rsc_info->provider, rsc_info->type); } void lrmd_free_rsc_info(lrmd_rsc_info_t * rsc_info) { if (!rsc_info) { return; } free(rsc_info->id); free(rsc_info->type); free(rsc_info->standard); free(rsc_info->provider); free(rsc_info); } static lrmd_rsc_info_t * lrmd_api_get_rsc_info(lrmd_t * lrmd, const char *rsc_id, enum lrmd_call_options options) { lrmd_rsc_info_t *rsc_info = NULL; xmlNode *data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); xmlNode *output = NULL; const char *class = NULL; const char *provider = NULL; const char *type = NULL; crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_RSC_ID, rsc_id); lrmd_send_command(lrmd, LRMD_OP_RSC_INFO, data, &output, 0, options, true); pcmk__xml_free(data); if (!output) { return NULL; } class = crm_element_value(output, PCMK__XA_LRMD_CLASS); provider = crm_element_value(output, PCMK__XA_LRMD_PROVIDER); type = crm_element_value(output, PCMK__XA_LRMD_TYPE); if (!class || !type) { pcmk__xml_free(output); return NULL; } else if (pcmk_is_set(pcmk_get_ra_caps(class), pcmk_ra_cap_provider) && !provider) { pcmk__xml_free(output); return NULL; } rsc_info = lrmd_new_rsc_info(rsc_id, class, provider, type); pcmk__xml_free(output); return rsc_info; } void lrmd_free_op_info(lrmd_op_info_t *op_info) { if (op_info) { free(op_info->rsc_id); free(op_info->action); free(op_info->interval_ms_s); free(op_info->timeout_ms_s); free(op_info); } } static int lrmd_api_get_recurring_ops(lrmd_t *lrmd, const char *rsc_id, int timeout_ms, enum lrmd_call_options options, GList **output) { xmlNode *data = NULL; xmlNode *output_xml = NULL; int rc = pcmk_ok; if (output == NULL) { return -EINVAL; } *output = NULL; // Send request if (rsc_id) { data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_RSC_ID, rsc_id); } rc = lrmd_send_command(lrmd, LRMD_OP_GET_RECURRING, data, &output_xml, timeout_ms, options, true); if (data) { pcmk__xml_free(data); } // Process reply if ((rc != pcmk_ok) || (output_xml == NULL)) { return rc; } for (const xmlNode *rsc_xml = pcmk__xe_first_child(output_xml, PCMK__XE_LRMD_RSC, NULL, NULL); (rsc_xml != NULL) && (rc == pcmk_ok); rsc_xml = pcmk__xe_next(rsc_xml, PCMK__XE_LRMD_RSC)) { rsc_id = crm_element_value(rsc_xml, PCMK__XA_LRMD_RSC_ID); if (rsc_id == NULL) { crm_err("Could not parse recurring operation information from executor"); continue; } for (const xmlNode *op_xml = pcmk__xe_first_child(rsc_xml, PCMK__XE_LRMD_RSC_OP, NULL, NULL); op_xml != NULL; op_xml = pcmk__xe_next(op_xml, PCMK__XE_LRMD_RSC_OP)) { lrmd_op_info_t *op_info = calloc(1, sizeof(lrmd_op_info_t)); if (op_info == NULL) { rc = -ENOMEM; break; } op_info->rsc_id = strdup(rsc_id); op_info->action = crm_element_value_copy(op_xml, PCMK__XA_LRMD_RSC_ACTION); op_info->interval_ms_s = crm_element_value_copy(op_xml, PCMK__XA_LRMD_RSC_INTERVAL); op_info->timeout_ms_s = crm_element_value_copy(op_xml, PCMK__XA_LRMD_TIMEOUT); *output = g_list_prepend(*output, op_info); } } pcmk__xml_free(output_xml); return rc; } static void lrmd_api_set_callback(lrmd_t * lrmd, lrmd_event_callback callback) { lrmd_private_t *native = lrmd->lrmd_private; native->callback = callback; } void lrmd_internal_set_proxy_callback(lrmd_t * lrmd, void *userdata, void (*callback)(lrmd_t *lrmd, void *userdata, xmlNode *msg)) { lrmd_private_t *native = lrmd->lrmd_private; native->proxy_callback = callback; native->proxy_callback_userdata = userdata; } void lrmd_internal_proxy_dispatch(lrmd_t *lrmd, xmlNode *msg) { lrmd_private_t *native = lrmd->lrmd_private; if (native->proxy_callback) { crm_log_xml_trace(msg, "PROXY_INBOUND"); native->proxy_callback(lrmd, native->proxy_callback_userdata, msg); } } int lrmd_internal_proxy_send(lrmd_t * lrmd, xmlNode *msg) { if (lrmd == NULL) { return -ENOTCONN; } crm_xml_add(msg, PCMK__XA_LRMD_OP, CRM_OP_IPC_FWD); crm_log_xml_trace(msg, "PROXY_OUTBOUND"); return lrmd_send_xml_no_reply(lrmd, msg); } static int stonith_get_metadata(const char *provider, const char *type, char **output) { int rc = pcmk_ok; stonith_t *stonith_api = stonith_api_new(); if (stonith_api == NULL) { crm_err("Could not get fence agent meta-data: API memory allocation failed"); return -ENOMEM; } rc = stonith_api->cmds->metadata(stonith_api, st_opt_sync_call, type, provider, output, 0); if ((rc == pcmk_ok) && (*output == NULL)) { rc = -EIO; } stonith_api->cmds->free(stonith_api); return rc; } static int lrmd_api_get_metadata(lrmd_t *lrmd, const char *standard, const char *provider, const char *type, char **output, enum lrmd_call_options options) { return lrmd->cmds->get_metadata_params(lrmd, standard, provider, type, output, options, NULL); } static int lrmd_api_get_metadata_params(lrmd_t *lrmd, const char *standard, const char *provider, const char *type, char **output, enum lrmd_call_options options, lrmd_key_value_t *params) { svc_action_t *action = NULL; GHashTable *params_table = NULL; if (!standard || !type) { lrmd_key_value_freeall(params); return -EINVAL; } if (pcmk__str_eq(standard, PCMK_RESOURCE_CLASS_STONITH, pcmk__str_casei)) { lrmd_key_value_freeall(params); return stonith_get_metadata(provider, type, output); } params_table = pcmk__strkey_table(free, free); for (const lrmd_key_value_t *param = params; param; param = param->next) { pcmk__insert_dup(params_table, param->key, param->value); } action = services__create_resource_action(type, standard, provider, type, PCMK_ACTION_META_DATA, 0, PCMK_DEFAULT_ACTION_TIMEOUT_MS, params_table, 0); lrmd_key_value_freeall(params); if (action == NULL) { return -ENOMEM; } if (action->rc != PCMK_OCF_UNKNOWN) { services_action_free(action); return -EINVAL; } if (!services_action_sync(action)) { crm_err("Failed to retrieve meta-data for %s:%s:%s", standard, provider, type); services_action_free(action); return -EIO; } if (!action->stdout_data) { crm_err("Failed to receive meta-data for %s:%s:%s", standard, provider, type); services_action_free(action); return -EIO; } *output = strdup(action->stdout_data); services_action_free(action); return pcmk_ok; } static int lrmd_api_exec(lrmd_t *lrmd, const char *rsc_id, const char *action, const char *userdata, guint interval_ms, int timeout, /* ms */ int start_delay, /* ms */ enum lrmd_call_options options, lrmd_key_value_t * params) { int rc = pcmk_ok; xmlNode *data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); xmlNode *args = pcmk__xe_create(data, PCMK__XE_ATTRIBUTES); lrmd_key_value_t *tmp = NULL; crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_RSC_ID, rsc_id); crm_xml_add(data, PCMK__XA_LRMD_RSC_ACTION, action); crm_xml_add(data, PCMK__XA_LRMD_RSC_USERDATA_STR, userdata); crm_xml_add_ms(data, PCMK__XA_LRMD_RSC_INTERVAL, interval_ms); crm_xml_add_int(data, PCMK__XA_LRMD_TIMEOUT, timeout); crm_xml_add_int(data, PCMK__XA_LRMD_RSC_START_DELAY, start_delay); for (tmp = params; tmp; tmp = tmp->next) { hash2smartfield((gpointer) tmp->key, (gpointer) tmp->value, args); } rc = lrmd_send_command(lrmd, LRMD_OP_RSC_EXEC, data, NULL, timeout, options, true); pcmk__xml_free(data); lrmd_key_value_freeall(params); return rc; } /* timeout is in ms */ static int lrmd_api_exec_alert(lrmd_t *lrmd, const char *alert_id, const char *alert_path, int timeout, lrmd_key_value_t *params) { int rc = pcmk_ok; xmlNode *data = pcmk__xe_create(NULL, PCMK__XE_LRMD_ALERT); xmlNode *args = pcmk__xe_create(data, PCMK__XE_ATTRIBUTES); lrmd_key_value_t *tmp = NULL; crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_ALERT_ID, alert_id); crm_xml_add(data, PCMK__XA_LRMD_ALERT_PATH, alert_path); crm_xml_add_int(data, PCMK__XA_LRMD_TIMEOUT, timeout); for (tmp = params; tmp; tmp = tmp->next) { hash2smartfield((gpointer) tmp->key, (gpointer) tmp->value, args); } rc = lrmd_send_command(lrmd, LRMD_OP_ALERT_EXEC, data, NULL, timeout, lrmd_opt_notify_orig_only, true); pcmk__xml_free(data); lrmd_key_value_freeall(params); return rc; } static int lrmd_api_cancel(lrmd_t *lrmd, const char *rsc_id, const char *action, guint interval_ms) { int rc = pcmk_ok; xmlNode *data = pcmk__xe_create(NULL, PCMK__XE_LRMD_RSC); crm_xml_add(data, PCMK__XA_LRMD_ORIGIN, __func__); crm_xml_add(data, PCMK__XA_LRMD_RSC_ACTION, action); crm_xml_add(data, PCMK__XA_LRMD_RSC_ID, rsc_id); crm_xml_add_ms(data, PCMK__XA_LRMD_RSC_INTERVAL, interval_ms); rc = lrmd_send_command(lrmd, LRMD_OP_RSC_CANCEL, data, NULL, 0, 0, true); pcmk__xml_free(data); return rc; } static int list_stonith_agents(lrmd_list_t ** resources) { int rc = 0; stonith_t *stonith_api = stonith_api_new(); stonith_key_value_t *stonith_resources = NULL; stonith_key_value_t *dIter = NULL; if (stonith_api == NULL) { crm_err("Could not list fence agents: API memory allocation failed"); return -ENOMEM; } stonith_api->cmds->list_agents(stonith_api, st_opt_sync_call, NULL, &stonith_resources, 0); stonith_api->cmds->free(stonith_api); for (dIter = stonith_resources; dIter; dIter = dIter->next) { rc++; if (resources) { *resources = lrmd_list_add(*resources, dIter->value); } } stonith_key_value_freeall(stonith_resources, 1, 0); return rc; } static int lrmd_api_list_agents(lrmd_t * lrmd, lrmd_list_t ** resources, const char *class, const char *provider) { int rc = 0; int stonith_count = 0; // Initially, whether to include stonith devices if (pcmk__str_eq(class, PCMK_RESOURCE_CLASS_STONITH, pcmk__str_casei)) { stonith_count = 1; } else { GList *gIter = NULL; GList *agents = resources_list_agents(class, provider); for (gIter = agents; gIter != NULL; gIter = gIter->next) { *resources = lrmd_list_add(*resources, (const char *)gIter->data); rc++; } g_list_free_full(agents, free); if (!class) { stonith_count = 1; } } if (stonith_count) { // Now, if stonith devices are included, how many there are stonith_count = list_stonith_agents(resources); if (stonith_count > 0) { rc += stonith_count; } } if (rc == 0) { crm_notice("No agents found for class %s", class); rc = -EPROTONOSUPPORT; } return rc; } static bool does_provider_have_agent(const char *agent, const char *provider, const char *class) { bool found = false; GList *agents = NULL; GList *gIter2 = NULL; agents = resources_list_agents(class, provider); for (gIter2 = agents; gIter2 != NULL; gIter2 = gIter2->next) { if (pcmk__str_eq(agent, gIter2->data, pcmk__str_casei)) { found = true; } } g_list_free_full(agents, free); return found; } static int lrmd_api_list_ocf_providers(lrmd_t * lrmd, const char *agent, lrmd_list_t ** providers) { int rc = pcmk_ok; char *provider = NULL; GList *ocf_providers = NULL; GList *gIter = NULL; ocf_providers = resources_list_providers(PCMK_RESOURCE_CLASS_OCF); for (gIter = ocf_providers; gIter != NULL; gIter = gIter->next) { provider = gIter->data; if (!agent || does_provider_have_agent(agent, provider, PCMK_RESOURCE_CLASS_OCF)) { *providers = lrmd_list_add(*providers, (const char *)gIter->data); rc++; } } g_list_free_full(ocf_providers, free); return rc; } static int lrmd_api_list_standards(lrmd_t * lrmd, lrmd_list_t ** supported) { int rc = 0; GList *standards = NULL; GList *gIter = NULL; standards = resources_list_standards(); for (gIter = standards; gIter != NULL; gIter = gIter->next) { *supported = lrmd_list_add(*supported, (const char *)gIter->data); rc++; } if (list_stonith_agents(NULL) > 0) { *supported = lrmd_list_add(*supported, PCMK_RESOURCE_CLASS_STONITH); rc++; } g_list_free_full(standards, free); return rc; } /*! * \internal * \brief Create an executor API object * * \param[out] api Will be set to newly created API object (it is the * caller's responsibility to free this value with * lrmd_api_delete() if this function succeeds) * \param[in] nodename If the object will be used for a remote connection, * the node name to use in cluster for remote executor * \param[in] server If the object will be used for a remote connection, * the resolvable host name to connect to * \param[in] port If the object will be used for a remote connection, * port number on \p server to connect to * * \return Standard Pacemaker return code * \note If the caller leaves one of \p nodename or \p server NULL, the other's * value will be used for both. If the caller leaves both NULL, an API * object will be created for a local executor connection. */ int lrmd__new(lrmd_t **api, const char *nodename, const char *server, int port) { lrmd_private_t *pvt = NULL; if (api == NULL) { return EINVAL; } *api = NULL; // Allocate all memory needed *api = calloc(1, sizeof(lrmd_t)); if (*api == NULL) { return ENOMEM; } pvt = calloc(1, sizeof(lrmd_private_t)); if (pvt == NULL) { lrmd_api_delete(*api); *api = NULL; return ENOMEM; } (*api)->lrmd_private = pvt; // @TODO Do we need to do this for local connections? pvt->remote = calloc(1, sizeof(pcmk__remote_t)); (*api)->cmds = calloc(1, sizeof(lrmd_api_operations_t)); if ((pvt->remote == NULL) || ((*api)->cmds == NULL)) { lrmd_api_delete(*api); *api = NULL; return ENOMEM; } // Set methods (*api)->cmds->connect = lrmd_api_connect; (*api)->cmds->connect_async = lrmd_api_connect_async; (*api)->cmds->is_connected = lrmd_api_is_connected; (*api)->cmds->poke_connection = lrmd_api_poke_connection; (*api)->cmds->disconnect = lrmd_api_disconnect; (*api)->cmds->register_rsc = lrmd_api_register_rsc; (*api)->cmds->unregister_rsc = lrmd_api_unregister_rsc; (*api)->cmds->get_rsc_info = lrmd_api_get_rsc_info; (*api)->cmds->get_recurring_ops = lrmd_api_get_recurring_ops; (*api)->cmds->set_callback = lrmd_api_set_callback; (*api)->cmds->get_metadata = lrmd_api_get_metadata; (*api)->cmds->exec = lrmd_api_exec; (*api)->cmds->cancel = lrmd_api_cancel; (*api)->cmds->list_agents = lrmd_api_list_agents; (*api)->cmds->list_ocf_providers = lrmd_api_list_ocf_providers; (*api)->cmds->list_standards = lrmd_api_list_standards; (*api)->cmds->exec_alert = lrmd_api_exec_alert; (*api)->cmds->get_metadata_params = lrmd_api_get_metadata_params; if ((nodename == NULL) && (server == NULL)) { pvt->type = pcmk__client_ipc; } else { if (nodename == NULL) { nodename = server; } else if (server == NULL) { server = nodename; } pvt->type = pcmk__client_tls; pvt->remote_nodename = strdup(nodename); pvt->server = strdup(server); if ((pvt->remote_nodename == NULL) || (pvt->server == NULL)) { lrmd_api_delete(*api); *api = NULL; return ENOMEM; } pvt->port = port; if (pvt->port == 0) { pvt->port = crm_default_remote_port(); } } return pcmk_rc_ok; } lrmd_t * lrmd_api_new(void) { lrmd_t *api = NULL; pcmk__assert(lrmd__new(&api, NULL, NULL, 0) == pcmk_rc_ok); return api; } lrmd_t * lrmd_remote_api_new(const char *nodename, const char *server, int port) { lrmd_t *api = NULL; pcmk__assert(lrmd__new(&api, nodename, server, port) == pcmk_rc_ok); return api; } void lrmd_api_delete(lrmd_t * lrmd) { if (lrmd == NULL) { return; } if (lrmd->cmds != NULL) { // Never NULL, but make static analysis happy if (lrmd->cmds->disconnect != NULL) { // Also never really NULL lrmd->cmds->disconnect(lrmd); // No-op if already disconnected } free(lrmd->cmds); } if (lrmd->lrmd_private != NULL) { lrmd_private_t *native = lrmd->lrmd_private; free(native->server); free(native->remote_nodename); free(native->remote); free(native->token); free(native->peer_version); free(lrmd->lrmd_private); } free(lrmd); } struct metadata_cb { void (*callback)(int pid, const pcmk__action_result_t *result, void *user_data); void *user_data; }; /*! * \internal * \brief Process asynchronous metadata completion * * \param[in,out] action Metadata action that completed */ static void metadata_complete(svc_action_t *action) { struct metadata_cb *metadata_cb = (struct metadata_cb *) action->cb_data; pcmk__action_result_t result = PCMK__UNKNOWN_RESULT; pcmk__set_result(&result, action->rc, action->status, services__exit_reason(action)); pcmk__set_result_output(&result, action->stdout_data, action->stderr_data); metadata_cb->callback(0, &result, metadata_cb->user_data); result.action_stdout = NULL; // Prevent free, because action owns it result.action_stderr = NULL; // Prevent free, because action owns it pcmk__reset_result(&result); free(metadata_cb); } /*! * \internal * \brief Retrieve agent metadata asynchronously * * \param[in] rsc Resource agent specification * \param[in] callback Function to call with result (this will always be * called, whether by this function directly or later * via the main loop, and on success the metadata will * be in its result argument's action_stdout) * \param[in,out] user_data User data to pass to callback * * \return Standard Pacemaker return code * \note This function is not a lrmd_api_operations_t method because it does not * need an lrmd_t object and does not go through the executor, but * executes the agent directly. */ int lrmd__metadata_async(const lrmd_rsc_info_t *rsc, void (*callback)(int pid, const pcmk__action_result_t *result, void *user_data), void *user_data) { svc_action_t *action = NULL; struct metadata_cb *metadata_cb = NULL; pcmk__action_result_t result = PCMK__UNKNOWN_RESULT; CRM_CHECK(callback != NULL, return EINVAL); if ((rsc == NULL) || (rsc->standard == NULL) || (rsc->type == NULL)) { pcmk__set_result(&result, PCMK_OCF_NOT_CONFIGURED, PCMK_EXEC_ERROR_FATAL, "Invalid resource specification"); callback(0, &result, user_data); pcmk__reset_result(&result); return EINVAL; } if (strcmp(rsc->standard, PCMK_RESOURCE_CLASS_STONITH) == 0) { return stonith__metadata_async(rsc->type, pcmk__timeout_ms2s(PCMK_DEFAULT_ACTION_TIMEOUT_MS), callback, user_data); } action = services__create_resource_action(pcmk__s(rsc->id, rsc->type), rsc->standard, rsc->provider, rsc->type, PCMK_ACTION_META_DATA, 0, PCMK_DEFAULT_ACTION_TIMEOUT_MS, NULL, 0); if (action == NULL) { pcmk__set_result(&result, PCMK_OCF_UNKNOWN_ERROR, PCMK_EXEC_ERROR, "Out of memory"); callback(0, &result, user_data); pcmk__reset_result(&result); return ENOMEM; } if (action->rc != PCMK_OCF_UNKNOWN) { pcmk__set_result(&result, action->rc, action->status, services__exit_reason(action)); callback(0, &result, user_data); pcmk__reset_result(&result); services_action_free(action); return EINVAL; } action->cb_data = calloc(1, sizeof(struct metadata_cb)); if (action->cb_data == NULL) { services_action_free(action); pcmk__set_result(&result, PCMK_OCF_UNKNOWN_ERROR, PCMK_EXEC_ERROR, "Out of memory"); callback(0, &result, user_data); pcmk__reset_result(&result); return ENOMEM; } metadata_cb = (struct metadata_cb *) action->cb_data; metadata_cb->callback = callback; metadata_cb->user_data = user_data; if (!services_action_async(action, metadata_complete)) { services_action_free(action); return pcmk_rc_error; // @TODO Derive from action->rc and ->status } // The services library has taken responsibility for action return pcmk_rc_ok; } /*! * \internal * \brief Set the result of an executor event * * \param[in,out] event Executor event to set * \param[in] rc OCF exit status of event * \param[in] op_status Executor status of event * \param[in] exit_reason Human-friendly description of event */ void lrmd__set_result(lrmd_event_data_t *event, enum ocf_exitcode rc, int op_status, const char *exit_reason) { if (event == NULL) { return; } event->rc = rc; event->op_status = op_status; // lrmd_event_data_t has (const char *) members that lrmd_free_event() frees pcmk__str_update((char **) &event->exit_reason, exit_reason); } /*! * \internal * \brief Clear an executor event's exit reason, output, and error output * * \param[in,out] event Executor event to reset */ void lrmd__reset_result(lrmd_event_data_t *event) { if (event == NULL) { return; } free((void *) event->exit_reason); event->exit_reason = NULL; free((void *) event->output); event->output = NULL; } /*! * \internal * \brief Get the uptime of a remote resource connection * * When the cluster connects to a remote resource, part of that resource's * handshake includes the uptime of the remote resource's connection. This * uptime is stored in the lrmd_t object. * * \return The connection's uptime, or -1 if unknown */ time_t lrmd__uptime(lrmd_t *lrmd) { lrmd_private_t *native = lrmd->lrmd_private; if (native->remote == NULL) { return -1; } else { return native->remote->uptime; } } const char * lrmd__node_start_state(lrmd_t *lrmd) { lrmd_private_t *native = lrmd->lrmd_private; if (native->remote == NULL) { return NULL; } else { return native->remote->start_state; } }