/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * This is the main file for the Domain Configuration Server (DCS). * * The DCS is a server that runs on a domain and communicates with * a Domain Configuration Agent (DCA) running on a remote host. The * DCA initiates DR requests that the DCS performs by calling the * appropriate libcfgadm(3LIB) function. * * This file contains functions that receive and process the messages * received from the DCA. It also handles the initialization of the * server and is responsible for starting a concurrent session to * handle each DR request. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "dcs.h" #include "remote_cfg.h" #include "rdr_param_types.h" #include "rdr_messages.h" #include "rsrc_info.h" typedef struct { ushort_t major; ushort_t minor; } dcs_ver_t; /* initialization functions */ static int init_server(struct pollfd *pfd, uint8_t ah_auth_alg, uint8_t esp_encr_alg, uint8_t esp_auth_alg); static void init_signals(void); /* message processing functions */ static int invalid_msg(rdr_msg_hdr_t *hdr); /* message handling functions */ static int dcs_ses_req(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_ses_estbl(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_ses_end(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_change_state(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_private_func(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_test(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_list_ext(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_help(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_ap_id_cmp(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_abort_cmd(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_rsrc_info(rdr_msg_hdr_t *hdr, cfga_params_t *param); static int dcs_unknown_op(rdr_msg_hdr_t *hdr, cfga_params_t *param); /* local callback functions */ static int dcs_confirm_callback(void *appdata_ptr, const char *message); static int dcs_message_callback(void *appdata_ptr, const char *message); /* utility functions */ static dcs_ver_t resolve_version(ushort_t req_major, ushort_t req_minor); static void filter_list_data(int perm, int *nlistp, cfga_list_data_t *linfo); static rdr_list_t *generate_sort_order(cfga_list_data_t *listp, int nlist); static int ldata_compare(const void *ap1, const void *ap2); static int invalid_msg(rdr_msg_hdr_t *hdr); static char *basename(char *path); static boolean_t is_socket(int fd); static uint8_t dcs_get_alg(dcs_alg_t *algs, char *arg, dcs_err_code *error); static void dcs_log_bad_alg(char optopt, char *optarg); /* * Lookup table for handling different message types. This * assumes the ordering of rdr_msg_opcode_t in remote_cfg.h. * If this enum changes, the lookup table must be updated. * * The lookup table handles all _known_ opcodes >= 0. Unsupported * opcodes, or opcodes that should not be received by the * dispatcher are handled by the dcs_unknown_op() function. */ int (*dcs_cmd[])(rdr_msg_hdr_t *, cfga_params_t *) = { dcs_unknown_op, /* 0 is an invalid opcode */ dcs_ses_req, /* RDR_SES_REQ */ dcs_ses_estbl, /* RDR_SES_ESTBL */ dcs_ses_end, /* RDR_SES_END */ dcs_change_state, /* RDR_CONF_CHANGE_STATE */ dcs_private_func, /* RDR_CONF_PRIVATE_FUNC */ dcs_test, /* RDR_CONF_TEST */ dcs_list_ext, /* RDR_CONF_LIST_EXT */ dcs_help, /* RDR_CONF_HELP */ dcs_ap_id_cmp, /* RDR_CONF_AP_ID_CMP */ dcs_abort_cmd, /* RDR_CONF_ABORT_CMD */ dcs_unknown_op, /* RDR_CONF_CONFIRM_CALLBACK */ dcs_unknown_op, /* RDR_CONF_MSG_CALLBACK */ dcs_rsrc_info /* RDR_RSRC_INFO */ }; /* * ver_supp[] is an array of the supported versions for the network * transport protocol used by the DCA and DCS. Each item in the array * is a pair: { major_version, minor_version }. * * The order of the array is significant. The first element should be * the highest supported version and all successive elements should be * strictly decreasing. */ dcs_ver_t ver_supp[] = { { 1, 0 } }; #define DCS_CURR_VER ver_supp[0] /* * Global Data */ char *cmdname = NULL; /* the name of the executable */ ulong_t dcs_debug = 0; /* control the amount of debugging */ int standalone = 0; /* control standalone mode */ boolean_t inetd = B_FALSE; /* control daemon mode */ ulong_t max_sessions = DCS_MAX_SESSIONS; /* control maximum active sessions */ int dcsfd = STDIN_FILENO; /* fd for the DCS reserved port */ /* * Array of acceptable -a, -e and -u arguments. */ static dcs_alg_t auth_algs_array[] = { { "none", SADB_AALG_NONE }, /* -a none or -u none */ { "md5", SADB_AALG_MD5HMAC }, /* -a md5 or -u md5 */ { "sha1", SADB_AALG_SHA1HMAC }, /* -a sha1 or -u sha1 */ { NULL, 0x0 } }, esp_algs_array[] = { { "none", SADB_EALG_NONE }, /* -e none */ { "des", SADB_EALG_DESCBC }, /* -e des */ { "3des", SADB_EALG_3DESCBC }, /* -e 3des */ { NULL, 0x0 } }; /* * main: * * Initialize the DCS and then enter an infinite loop. This loop waits * for connection requests to come and then establishes a connection. * It dispatches the connection to be handled in a concurrent session. */ int main(int argc, char **argv) { int opt; struct timeval tv; struct pollfd dcs_rcv; int newfd; uint8_t ah_auth_alg = SADB_AALG_NONE; uint8_t esp_encr_alg = SADB_EALG_NONE; uint8_t esp_auth_alg = SADB_AALG_NONE; dcs_err_code alg_ec = DCS_NO_ERR; /* initialize globals */ dcs_debug = DBG_NONE; cmdname = basename(argv[0]); /* open log file with unique prefix */ openlog(cmdname, LOG_CONS | LOG_NDELAY, LOG_DAEMON); /* * Process command line args */ opterr = 0; /* disable getopt error messages */ while ((opt = getopt(argc, argv, OPT_STR)) != EOF) { switch (opt) { case 'd': { int usr_debug; char *err_str; usr_debug = strtol(optarg, &err_str, 0); /* * The err_str parameter will be an * empty string if successful. */ if (*err_str != '\0') { dcs_log_msg(LOG_ERR, DCS_BAD_OPT_ARG, optopt, optarg, "exiting"); (void) rdr_reject(dcsfd); exit(1); } dcs_debug = usr_debug; break; } case 'S': standalone++; break; case 's': { int usr_ses; char *err_str; usr_ses = strtol(optarg, &err_str, 0); if (usr_ses >= 1) { max_sessions = usr_ses; } else { char behavior_str[MAX_MSG_LEN]; snprintf(behavior_str, MAX_MSG_LEN, "using default value (%d)", max_sessions); dcs_log_msg(LOG_NOTICE, DCS_BAD_OPT_ARG, optopt, optarg, behavior_str); } break; } case 'a': case 'u': if (opt == 'a') ah_auth_alg = dcs_get_alg(auth_algs_array, optarg, &alg_ec); else /* opt == 'u' */ esp_auth_alg = dcs_get_alg(auth_algs_array, optarg, &alg_ec); if (alg_ec == DCS_BAD_OPT_ARG) { dcs_log_bad_alg(optopt, optarg); (void) rdr_reject(dcsfd); exit(1); } break; case 'e': esp_encr_alg = dcs_get_alg(esp_algs_array, optarg, &alg_ec); if (alg_ec == DCS_BAD_OPT_ARG) { dcs_log_bad_alg(optopt, optarg); (void) rdr_reject(dcsfd); exit(1); } break; default: if (optopt == 'a' || optopt == 'e' || optopt == 'u') dcs_log_bad_alg(optopt, optarg); else dcs_log_msg(LOG_ERR, DCS_BAD_OPT, optopt); (void) rdr_reject(dcsfd); exit(1); /* NOTREACHED */ break; } } /* * In the future if inetd supports per-socket IPsec dcs can be run * under inetd. * Daemonize if we were not started by inetd unless running standalone. */ inetd = is_socket(STDIN_FILENO); if (inetd == B_FALSE && standalone == 0) { closefrom(0); (void) chdir("/"); (void) umask(0); if (fork() != 0) exit(0); (void) setsid(); /* open log again after all files were closed */ openlog(cmdname, LOG_CONS | LOG_NDELAY, LOG_DAEMON); } DCS_DBG(DBG_ALL, "initializing %s...", cmdname); init_signals(); /* must be root */ if (geteuid() != 0) { dcs_log_msg(LOG_ERR, DCS_NO_PRIV); (void) rdr_reject(dcsfd); exit(1); } /* * Seed the random number generator for * generating random session identifiers. */ gettimeofday(&tv, NULL); srand48(tv.tv_usec); /* initialize our transport endpoint */ if (init_server(&dcs_rcv, ah_auth_alg, esp_encr_alg, esp_auth_alg) == -1) { dcs_log_msg(LOG_ERR, DCS_INIT_ERR); (void) rdr_reject(dcsfd); exit(1); } DCS_DBG(DBG_ALL, "%s initialized, debug level = 0x%X, " "max sessions = %d", cmdname, dcs_debug, max_sessions); /* * Main service loop */ for (;;) { /* wait for a connection request */ if (ses_poll(&dcs_rcv, 1, BLOCKFOREVER) == -1) { if (errno != EINTR) { dcs_log_msg(LOG_ERR, DCS_INT_ERR, "poll", strerror(errno)); } continue; } /* attempt to connect */ newfd = rdr_connect_srv(dcs_rcv.fd); if ((newfd == RDR_ERROR) || (newfd == RDR_NET_ERR)) { dcs_log_msg(LOG_ERR, DCS_CONNECT_ERR); continue; } /* process the session concurrently */ if (ses_start(newfd) == -1) { dcs_log_msg(LOG_ERR, DCS_SES_HAND_ERR); (void) rdr_close(newfd); break; } } close(dcs_rcv.fd); return (1); } /* * dcs_get_alg: * * Returns the ID of the first algorithm found in the 'algs' array * with a name matching 'arg'. If there is no matching algorithm, * 'error' is set to DCS_BAD_OPT_ARG, otherwise it is set to DCS_NO_ERR. * The 'algs' array must be terminated by an entry containing a NULL * 'arg_name' field. The 'error' argument must be a valid pointer. */ static uint8_t dcs_get_alg(dcs_alg_t *algs, char *arg, dcs_err_code *error) { dcs_alg_t *alg; *error = DCS_NO_ERR; for (alg = algs; alg->arg_name != NULL && arg != NULL; alg++) { if (strncmp(alg->arg_name, arg, strlen(alg->arg_name) + 1) == 0) { return (alg->alg_id); } } *error = DCS_BAD_OPT_ARG; return (0); } /* * dcs_log_bad_alg: * * Logs an appropriate message when an invalid command line argument * was provided. 'optarg' is the invalid argument string for the * command line option 'optopt', where 'optopt' = 'a' for the '-a' * option. A NULL 'optarg' indicates the required option was not * provided. */ static void dcs_log_bad_alg(char optopt, char *optarg) { if (optarg == NULL) { dcs_log_msg(LOG_ERR, DCS_BAD_OPT_ARG, optopt, "empty string", "an argument is required, exiting"); } else { dcs_log_msg(LOG_ERR, DCS_BAD_OPT_ARG, optopt, optarg, "exiting"); } } /* * init_server: * * Perform all the operations that are required to initialize the * transport endpoint used by the DCS. After this routine succeeds, * the DCS is ready to accept session requests on its well known * port. */ static int init_server(struct pollfd *pfd, uint8_t ah_auth_alg, uint8_t esp_encr_alg, uint8_t esp_auth_alg) { struct servent *se; struct sockaddr_storage ss; struct sockaddr_in *sin; struct sockaddr_in6 *sin6; ipsec_req_t ipsec_req; int req_port; int act_port; int init_status; int num_sock_opts; int sock_opts[] = { SO_REUSEADDR }; assert(pfd); pfd->fd = dcsfd; pfd->events = POLLIN | POLLPRI; pfd->revents = 0; /* * In standalone mode, we have to initialize the transport * endpoint for our reserved port. In daemon mode, inetd * starts the DCS and hands off STDIN_FILENO connected to * our reserved port. */ if (inetd == B_FALSE || standalone) { /* in standalone mode, init fd for reserved port */ if ((dcsfd = rdr_open(AF_INET6)) == -1) { DCS_DBG(DBG_ALL, "rdr_open failed"); return (-1); } pfd->fd = dcsfd; /* * Enable per-socket IPsec if the user specified an * AH or ESP algorithm to use. */ if (ah_auth_alg != SADB_AALG_NONE || esp_encr_alg != SADB_EALG_NONE || esp_auth_alg != SADB_AALG_NONE) { int err; bzero(&ipsec_req, sizeof (ipsec_req)); /* Hardcoded values */ ipsec_req.ipsr_self_encap_req = SELF_ENCAP_REQ; /* User defined */ ipsec_req.ipsr_auth_alg = ah_auth_alg; ipsec_req.ipsr_esp_alg = esp_encr_alg; if (ah_auth_alg != SADB_AALG_NONE) ipsec_req.ipsr_ah_req = AH_REQ; if (esp_encr_alg != SADB_EALG_NONE || esp_auth_alg != SADB_AALG_NONE) { ipsec_req.ipsr_esp_req = ESP_REQ; ipsec_req.ipsr_esp_auth_alg = esp_auth_alg; } err = rdr_setsockopt(pfd->fd, IPPROTO_IPV6, IPV6_SEC_OPT, (void *)&ipsec_req, sizeof (ipsec_req)); if (err != RDR_OK) { DCS_DBG(DBG_ALL, "rdr_setsockopt failed"); return (-1); } } } /* * Look up our service to get the reserved port number */ if ((se = getservbyname(DCS_SERVICE, "tcp")) == NULL) { dcs_log_msg(LOG_NOTICE, DCS_NO_SERV, DCS_SERVICE); /* use the known port if service wasn't found */ req_port = SUN_DR_PORT; } else { req_port = se->s_port; } /* initialize our local address */ sin6 = (struct sockaddr_in6 *)&ss; (void) memset(sin6, 0, sizeof (*sin6)); sin6->sin6_family = AF_INET6; sin6->sin6_port = htons(req_port); sin6->sin6_addr = in6addr_any; num_sock_opts = sizeof (sock_opts) / sizeof (*sock_opts); init_status = rdr_init(pfd->fd, (struct sockaddr *)sin6, sock_opts, num_sock_opts, DCS_BACKLOG); if (init_status != RDR_OK) { return (-1); } switch (ss.ss_family) { case AF_INET: DCS_DBG(DBG_ALL, "using AF_INET socket"); sin = (struct sockaddr_in *)&ss; act_port = ntohs(sin->sin_port); break; case AF_INET6: DCS_DBG(DBG_ALL, "using AF_INET6 socket"); /* sin6 already set correctly */ act_port = ntohs(sin6->sin6_port); break; default: DCS_DBG(DBG_ALL, "unknown socket type"); return (-1); } /* check that we got the requested port */ if (req_port != act_port) { dcs_log_msg(LOG_ERR, DCS_NO_PORT, req_port); return (-1); } return (0); } /* * init_signals: * * Initialize signals for the current session. All signals will be * blocked with two possible exceptions. SIGINT is not blocked in * standalone mode, and ses_init_signals() is called to selectively * unblock any signals required to handle concurrent sessions. */ static void init_signals(void) { sigset_t mask; /* block all signals */ sigfillset(&mask); /* in standalone, allow user to abort */ if (standalone) { sigdelset(&mask, SIGINT); } ses_init_signals(&mask); (void) sigprocmask(SIG_BLOCK, &mask, NULL); } /* * dcs_dispatch_message: * * This function dispatches a message to the correct function. The * correct handler is determined by the opcode field of the message * header. */ int dcs_dispatch_message(rdr_msg_hdr_t *hdr, cfga_params_t *params) { session_t *sp; assert(hdr); assert(params); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } /* check the message */ if (invalid_msg(hdr)) { dcs_log_msg(LOG_ERR, DCS_MSG_INVAL); ses_close(DCS_MSG_INVAL); return (-1); } /* save the current message */ sp->curr_msg.hdr = hdr; sp->curr_msg.params = params; /* * hdr->message_opcode is unsigned so don't need * to check for values less than zero */ if (hdr->message_opcode >= RDR_NUM_OPS) { dcs_unknown_op(hdr, params); ses_close(DCS_MSG_INVAL); return (-1); } PRINT_MSG_DBG(DCS_RECEIVE, hdr); /* dispatch the message */ if ((*dcs_cmd[hdr->message_opcode])(hdr, params) == -1) { dcs_log_msg(LOG_ERR, DCS_OP_FAILED); ses_close(DCS_ERROR); return (-1); } return (0); } /* * init_msg: * * Initialize the message header with information from the current * session. Fields not set directly are initialized to zero. */ void init_msg(rdr_msg_hdr_t *hdr) { session_t *sp; assert(hdr); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return; } (void) memset(hdr, 0, sizeof (rdr_msg_hdr_t)); /* set the session information */ hdr->random_req = sp->random_req; hdr->random_resp = sp->random_resp; /* set the version being used */ hdr->major_version = sp->major_version; hdr->minor_version = sp->minor_version; } /* * invalid_msg: * * Check if the message is valid for the current session. This * is accomplished by checking various information in the header * against the information for the current session. */ static int invalid_msg(rdr_msg_hdr_t *hdr) { session_t *sp; assert(hdr); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } /* * Only perform the following checks if the message * is not a session request. The information to check * will not be set at the time a session request is * received. */ if (hdr->message_opcode != RDR_SES_REQ) { /* check major and minor version */ if ((sp->major_version != hdr->major_version) || (sp->minor_version != hdr->minor_version)) { DCS_DBG(DBG_MSG, "unsupported version %d.%d", hdr->major_version, hdr->minor_version); return (-1); } /* check session identifiers */ if ((sp->random_req != hdr->random_req) || (sp->random_resp != hdr->random_resp)) { DCS_DBG(DBG_MSG, "invalid session identifiers: " "<%d, %d>", hdr->random_req, hdr->random_resp); return (-1); } } return (0); } /* * dcs_ses_req: * * Handle a session request message (RDR_SES_REQ). */ static int dcs_ses_req(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; cfga_params_t reply_param; dcs_ver_t act_ver; int snd_status; static char *op_name = "session request"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } /* make sure that a session hasn't been requested yet */ if (sp->state != DCS_CONNECTED) { dcs_log_msg(LOG_ERR, DCS_SES_SEQ_INVAL); ses_close(DCS_SES_SEQ_INVAL); return (-1); } ses_setlocale(param->req.locale_str); /* get the best matching version supported */ act_ver = resolve_version(hdr->major_version, hdr->minor_version); /* initialize session information */ sp->random_req = hdr->random_req; sp->major_version = act_ver.major; sp->minor_version = act_ver.minor; /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_SES_REQ; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = DCS_OK; /* prepare session request specific data */ (void) memset(&reply_param, 0, sizeof (cfga_params_t)); reply_param.req.session_id = sp->id; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, &reply_param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); return (-1); } sp->state = DCS_SES_REQ; return (0); } /* * dcs_ses_estbl: * * Handle a session establishment message (RDR_SES_ESTBL). */ /* ARGSUSED */ static int dcs_ses_estbl(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; dcs_ver_t act_ver; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } /* * Make sure that a session has not been * established yet, and that a session * request has already been processed. */ if (sp->state != DCS_SES_REQ) { dcs_log_msg(LOG_ERR, DCS_SES_SEQ_INVAL); ses_close(DCS_SES_SEQ_INVAL); return (-1); } /* get the best matching version supported */ act_ver = resolve_version(hdr->major_version, hdr->minor_version); if ((act_ver.major != hdr->major_version) || (act_ver.minor != hdr->minor_version)) { /* end the session because protocol not supported */ dcs_log_msg(LOG_ERR, DCS_VER_INVAL, hdr->major_version, hdr->minor_version); ses_close(DCS_VER_INVAL); return (-1); } DCS_DBG(DBG_SES, "Session Established"); sp->state = DCS_SES_ESTBL; return (0); } /* * dcs_ses_end: * * Handle a session end message (RDR_SES_END). */ static int dcs_ses_end(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; cfga_params_t reply_param; int snd_status; static char *op_name = "session end"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } /* * Session end is valid from any state. However, only * send back a reply if the error code is zero. A non-zero * error code indicates that the session is being terminated * under an error condition, and no acknowledgement is * required. */ if (param->end.error_code == 0) { /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_SES_END; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = DCS_OK; /* return empty data - no information needed in reply */ (void) memset(&reply_param, 0, sizeof (cfga_params_t)); PRINT_MSG_DBG(DCS_SEND, &reply_hdr); snd_status = rdr_snd_msg(sp->fd, &reply_hdr, &reply_param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } } sp->state = DCS_SES_END; return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_change_state: * * Handle a change state request message (RDR_CONF_CHANGE_STATE). */ static int dcs_change_state(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; change_state_params_t *op_data; struct cfga_confirm local_conf_cb; struct cfga_msg local_msg_cb; int cfga_status = 0; int snd_status; char *err_str; unsigned int curr_attempt; unsigned int num_attempts; char retry_msg[MAX_MSG_LEN]; static char *op_name = "config_change_state"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = ¶m->change; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } /* initialize local confirm callback */ local_conf_cb.confirm = dcs_confirm_callback; local_conf_cb.appdata_ptr = (void *)op_data->confp; /* initialize local message callback */ local_msg_cb.message_routine = dcs_message_callback; local_msg_cb.appdata_ptr = (void *)op_data->msgp; /* verify retry value */ if (op_data->retries < 0) { dcs_log_msg(LOG_NOTICE, DCS_BAD_RETRY_VAL, op_data->retries); op_data->retries = 0; } /* verify timeout value */ if (op_data->timeval < 0) { dcs_log_msg(LOG_NOTICE, DCS_BAD_TIME_VAL, op_data->timeval); op_data->timeval = 0; } num_attempts = 1 + op_data->retries; curr_attempt = 0; while (curr_attempt < num_attempts) { /* don't sleep the first time around */ if (curr_attempt != 0) { /* log the error message and alert the user */ err_str = dcs_cfga_str(op_data->errstring, cfga_status); if (err_str) { dcs_log_msg(LOG_ERR, DCS_CFGA_ERR, op_name, err_str); dcs_message_callback((void *)op_data->msgp, err_str); free((void *)err_str); } else { dcs_log_msg(LOG_ERR, DCS_CFGA_UNKNOWN); dcs_message_callback((void *)op_data->msgp, dcs_strerror(DCS_CFGA_UNKNOWN)); } if (op_data->errstring && *op_data->errstring) { free((void *)*op_data->errstring); *op_data->errstring = NULL; } /* sleep with abort enabled */ ses_sleep(op_data->timeval); /* log the retry attempt and alert the user */ dcs_log_msg(LOG_INFO, DCS_RETRY, curr_attempt); snprintf(retry_msg, MAX_MSG_LEN, dcs_strerror(DCS_RETRY), curr_attempt); dcs_message_callback((void *)op_data->msgp, retry_msg); } sp->state = DCS_CONF_PENDING; /* * Call into libcfgadm */ ses_abort_enable(); cfga_status = config_change_state(op_data->state_change, op_data->num_ap_ids, op_data->ap_ids, op_data->options, &local_conf_cb, &local_msg_cb, op_data->errstring, op_data->flags); ses_abort_disable(); /* * Retry only the operations that have a chance to * succeed if retried. All libcfgadm errors not * included below will always fail, regardless of * a retry. */ if ((cfga_status != CFGA_BUSY) && (cfga_status != CFGA_SYSTEM_BUSY) && (cfga_status != CFGA_ERROR)) { break; } /* prepare for another attempt */ ++curr_attempt; } sp->state = DCS_CONF_DONE; /* log any libcfgadm errors */ if (cfga_status != CFGA_OK) { err_str = dcs_cfga_str(op_data->errstring, cfga_status); if (err_str) { dcs_log_msg(LOG_ERR, DCS_CFGA_ERR, op_name, err_str); free((void *)err_str); } } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_CHANGE_STATE; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = cfga_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } /* clean up */ if (op_data->errstring && *op_data->errstring) { free((void *)*op_data->errstring); *op_data->errstring = NULL; } return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_private_func: * * Handle a private function request message (RDR_CONF_PRIVATE_FUNC). */ static int dcs_private_func(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; private_func_params_t *op_data; struct cfga_confirm local_conf_cb; struct cfga_msg local_msg_cb; int cfga_status; int snd_status; char *err_str; static char *op_name = "config_private_func"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = ¶m->priv; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } /* initialize local confirm callback */ local_conf_cb.confirm = dcs_confirm_callback; local_conf_cb.appdata_ptr = (void *)op_data->confp; /* initialize local message callback */ local_msg_cb.message_routine = dcs_message_callback; local_msg_cb.appdata_ptr = (void *)op_data->msgp; sp->state = DCS_CONF_PENDING; /* * Call into libcfgadm */ ses_abort_enable(); cfga_status = config_private_func(op_data->function, op_data->num_ap_ids, op_data->ap_ids, op_data->options, &local_conf_cb, &local_msg_cb, op_data->errstring, op_data->flags); ses_abort_disable(); sp->state = DCS_CONF_DONE; /* log any libcfgadm errors */ if (cfga_status != CFGA_OK) { err_str = dcs_cfga_str(op_data->errstring, cfga_status); if (err_str) { dcs_log_msg(LOG_ERR, DCS_CFGA_ERR, op_name, err_str); free((void *)err_str); } } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_PRIVATE_FUNC; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = cfga_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } if (op_data->errstring && *op_data->errstring) { free((void *)*op_data->errstring); *op_data->errstring = NULL; } return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_test: * * Handle a test request message (RDR_CONF_TEST). */ static int dcs_test(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; test_params_t *op_data; struct cfga_msg local_msg_cb; int cfga_status; int snd_status; char *err_str; static char *op_name = "config_test"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = ¶m->test; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } /* initialize local message callback */ local_msg_cb.message_routine = dcs_message_callback; local_msg_cb.appdata_ptr = op_data->msgp; sp->state = DCS_CONF_PENDING; /* * Call into libcfgadm */ ses_abort_enable(); cfga_status = config_test(op_data->num_ap_ids, op_data->ap_ids, op_data->options, &local_msg_cb, op_data->errstring, op_data->flags); ses_abort_disable(); sp->state = DCS_CONF_DONE; /* log any libcfgadm errors */ if (cfga_status != CFGA_OK) { err_str = dcs_cfga_str(op_data->errstring, cfga_status); if (err_str) { dcs_log_msg(LOG_ERR, DCS_CFGA_ERR, op_name, err_str); free((void *)err_str); } } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_TEST; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = cfga_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } if (op_data->errstring && *op_data->errstring) { free((void *)*op_data->errstring); *op_data->errstring = NULL; } return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_list_ext: * * Handle a list request message (RDR_CONF_LIST_EXT). */ static int dcs_list_ext(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; list_ext_params_t *op_data; int cfga_status; int snd_status; char *err_str; static char *op_name = "config_list_ext"; cfga_list_data_t *ap_ids; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = ¶m->list_ext; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } /* * Make sure that we can retrieve the data * from libcfgadm. If not, report the error. */ if (op_data->ap_id_list == NULL) { dcs_log_msg(LOG_ERR, DCS_MSG_INVAL); ses_close(DCS_MSG_INVAL); return (-1); } sp->state = DCS_CONF_PENDING; /* * Call into libcfgadm */ ses_abort_enable(); cfga_status = config_list_ext(op_data->num_ap_ids, op_data->ap_ids, &ap_ids, op_data->nlist, op_data->options, op_data->listopts, op_data->errstring, op_data->flags); ses_abort_disable(); sp->state = DCS_CONF_DONE; /* * Log any libcfgadm errors at a low priority level. * Since a status request does not modify the system * in any way, we do not need to worry about these * errors here on the host. */ if (cfga_status != CFGA_OK) { err_str = dcs_cfga_str(op_data->errstring, cfga_status); if (err_str) { dcs_log_msg(LOG_INFO, DCS_CFGA_ERR, op_name, err_str); free((void *)err_str); } } /* * Filter ap ids to return only appropriate information */ filter_list_data(op_data->permissions, op_data->nlist, ap_ids); /* if all aps were filtered out, return an error */ if ((cfga_status == CFGA_OK) && (*op_data->nlist == 0)) { cfga_status = CFGA_APID_NOEXIST; } /* calculate the sort order */ if (cfga_status == CFGA_OK) { *op_data->ap_id_list = generate_sort_order(ap_ids, *op_data->nlist); if (*op_data->ap_id_list == NULL) { cfga_status = CFGA_LIB_ERROR; } } /* ensure that nlist is 0 for errors */ if (cfga_status != CFGA_OK) { *op_data->nlist = 0; } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_LIST_EXT; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = cfga_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } if (op_data->errstring && *op_data->errstring) { free((void *)*op_data->errstring); *op_data->errstring = NULL; } if (ap_ids != NULL) { free((void *)ap_ids); } return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_help: * * Handle a help request message (RDR_CONF_HELP). */ static int dcs_help(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; help_params_t *op_data; struct cfga_msg local_msg_cb; int cfga_status; int snd_status; char *err_str; static char *op_name = "config_help"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = ¶m->help; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } /* initialize local message callback */ local_msg_cb.message_routine = dcs_message_callback; local_msg_cb.appdata_ptr = op_data->msgp; sp->state = DCS_CONF_PENDING; /* * Call into libcfgadm */ ses_abort_enable(); cfga_status = config_help(op_data->num_ap_ids, op_data->ap_ids, &local_msg_cb, op_data->options, op_data->flags); ses_abort_disable(); sp->state = DCS_CONF_DONE; /* * Log any libcfgadm errors at a low priority level. * Since a help request does not modify the system * in any way, we do not need to worry about these * errors here on the host. */ if (cfga_status != CFGA_OK) { err_str = dcs_cfga_str(NULL, cfga_status); if (err_str) { dcs_log_msg(LOG_INFO, DCS_CFGA_ERR, op_name, err_str); free((void *)err_str); } } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_HELP; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = cfga_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_ap_id_cmp: * * Handle an attachment point comparison request message (RDR_AP_ID_CMP). */ static int dcs_ap_id_cmp(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; ap_id_cmp_params_t *op_data; int snd_status; int cmp_result; static char *op_name = "config_ap_id_cmp"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = ¶m->cmp; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } sp->state = DCS_CONF_PENDING; /* * Call into libcfgadm */ ses_abort_enable(); cmp_result = config_ap_id_cmp(op_data->ap_log_id1, op_data->ap_log_id2); ses_abort_disable(); sp->state = DCS_CONF_DONE; /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_AP_ID_CMP; reply_hdr.data_type = RDR_REPLY; /* * Return result of comparison as error code. * Since all values are valid, it is impossible * to report an error. */ reply_hdr.status = cmp_result; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_abort_cmd: * * Handle an abort request message (RDR_CONF_ABORT_CMD). */ /* ARGSUSED */ static int dcs_abort_cmd(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; abort_cmd_params_t *op_data; int op_status = RDR_SUCCESS; int snd_status; static char *op_name = "abort command"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = (abort_cmd_params_t *)param; op_status = ses_abort(op_data->session_id); if (op_status == -1) { dcs_log_msg(LOG_ERR, DCS_ABORT_ERR, op_data->session_id); } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_CONF_ABORT_CMD; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = op_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } sp->state = DCS_CONF_DONE; return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_rsrc_info: * * Handle a resource info request message (RDR_RSRC_INFO). */ static int dcs_rsrc_info(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; rdr_msg_hdr_t reply_hdr; rsrc_info_params_t *op_data; int rsrc_status; int snd_status; static char *op_name = "resource info init"; assert(hdr); assert(param); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } op_data = (rsrc_info_params_t *)¶m->rsrc_info; /* make sure we have a session established */ if (sp->state != DCS_SES_ESTBL) { dcs_log_msg(LOG_ERR, DCS_NO_SES_ESTBL, op_name); ses_close(DCS_NO_SES_ERR); return (-1); } sp->state = DCS_CONF_PENDING; /* * Request resource info data. */ ses_abort_enable(); rsrc_status = ri_init(op_data->num_ap_ids, op_data->ap_ids, op_data->flags, &op_data->hdl); ses_abort_disable(); sp->state = DCS_CONF_DONE; /* log errors */ if (rsrc_status != RI_SUCCESS) { dcs_log_msg(LOG_ERR, DCS_RSRC_ERR, rsrc_status); } /* prepare header information */ init_msg(&reply_hdr); reply_hdr.message_opcode = RDR_RSRC_INFO; reply_hdr.data_type = RDR_REPLY; reply_hdr.status = rsrc_status; PRINT_MSG_DBG(DCS_SEND, &reply_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &reply_hdr, param, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); } ri_fini(op_data->hdl); return ((snd_status != RDR_OK) ? -1 : 0); } /* * dcs_unknown_op: * * Handle all unknown requests. */ /* ARGSUSED */ static int dcs_unknown_op(rdr_msg_hdr_t *hdr, cfga_params_t *param) { session_t *sp; assert(hdr); assert(param); assert(hdr); /* get the current session information */ if ((sp = curr_ses()) == NULL) { ses_close(DCS_ERROR); return (-1); } dcs_log_msg(LOG_ERR, DCS_UNKNOWN_OP, hdr->message_opcode); sp->state = DCS_CONF_DONE; return (-1); } /* * dcs_confirm_callback: * * Perform a confirm callback and wait for the reply. As defined * in the config_admin(3CFGADM) man page, 1 is returned if the * operation should be allowed to continue and 0 otherwise. */ static int dcs_confirm_callback(void *appdata_ptr, const char *message) { session_t *sp; rdr_msg_hdr_t req_hdr; cfga_params_t req_data; struct cfga_confirm *cb_data; rdr_msg_hdr_t reply_hdr; cfga_params_t reply_data; int snd_status; int rcv_status; static char *op_name = "confirm callback"; /* sanity check */ if (appdata_ptr == NULL) { dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } /* get the current session information */ if ((sp = curr_ses()) == NULL) { dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } cb_data = (struct cfga_confirm *)appdata_ptr; /* prepare header information */ init_msg(&req_hdr); req_hdr.message_opcode = RDR_CONF_CONFIRM_CALLBACK; req_hdr.data_type = RDR_REQUEST; /* prepare confirm callback specific data */ (void) memset(&req_data, 0, sizeof (req_data)); req_data.conf_cb.confp = cb_data; req_data.conf_cb.message = (char *)message; PRINT_MSG_DBG(DCS_SEND, &req_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &req_hdr, &req_data, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } /* * Wait for response */ rcv_status = rdr_rcv_msg(sp->fd, &reply_hdr, &reply_data, DCS_RCV_CB_TIMEOUT); if (rcv_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } /* * Perform several checks to see if we have a * valid response to the confirm callback. */ if (invalid_msg(&reply_hdr)) { dcs_log_msg(LOG_ERR, DCS_MSG_INVAL); dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } /* check the opcode and type */ if ((reply_hdr.message_opcode != RDR_CONF_CONFIRM_CALLBACK) || (reply_hdr.data_type != RDR_REPLY)) { DCS_DBG(DBG_MSG, "bad opcode or message type"); dcs_log_msg(LOG_ERR, DCS_MSG_INVAL); dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } PRINT_MSG_DBG(DCS_RECEIVE, &reply_hdr); /* check for incorrect callback id */ if (reply_data.conf_cb.confp->confirm != cb_data->confirm) { dcs_log_msg(LOG_ERR, DCS_MSG_INVAL); dcs_log_msg(LOG_NOTICE, DCS_CONF_CB_ERR); return (0); } /* * Got back valid response: return the user's answer */ return (reply_data.conf_cb.response); } /* * dcs_message_callback: * * Perform a message callback to display a string to the user. * * Note: There is no documentation about possible return values * for the message callback. It is assumed that the value returned * is ignored, so 0 is returned for all cases. */ static int dcs_message_callback(void *appdata_ptr, const char *message) { session_t *sp; rdr_msg_hdr_t req_hdr; cfga_params_t req_data; struct cfga_msg *cb_data; int snd_status; static char *op_name = "message callback"; /* sanity check */ if (appdata_ptr == NULL) { dcs_log_msg(LOG_NOTICE, DCS_MSG_CB_ERR); return (0); } /* get the current session information */ if ((sp = curr_ses()) == NULL) { dcs_log_msg(LOG_NOTICE, DCS_MSG_CB_ERR); return (0); } cb_data = (struct cfga_msg *)appdata_ptr; /* prepare header information */ init_msg(&req_hdr); req_hdr.message_opcode = RDR_CONF_MSG_CALLBACK; req_hdr.data_type = RDR_REQUEST; /* prepare message callback specific data */ (void) memset(&req_data, 0, sizeof (req_data)); req_data.msg_cb.msgp = cb_data; req_data.msg_cb.message = (char *)message; PRINT_MSG_DBG(DCS_SEND, &req_hdr); /* send the message */ snd_status = rdr_snd_msg(sp->fd, &req_hdr, (cfga_params_t *)&req_data, DCS_SND_TIMEOUT); if (snd_status == RDR_ABORTED) { abort_handler(); } if (snd_status != RDR_OK) { dcs_log_msg(LOG_ERR, DCS_OP_REPLY_ERR, op_name); dcs_log_msg(LOG_NOTICE, DCS_MSG_CB_ERR); } return (0); } /* * resolve_version: * * Consult the list of supported versions and find the highest supported * version that is less than or equal to the version requested in the * parameters. This assumes that the list of supported versions is ordered * so that the highest supported version is the first element, and that * the versions are strictly decreasing. */ static dcs_ver_t resolve_version(ushort_t req_major, ushort_t req_minor) { int i; dcs_ver_t act_ver; int num_vers; num_vers = sizeof (ver_supp) / sizeof (*ver_supp); /* default to the lowest version */ act_ver = ver_supp[num_vers - 1]; for (i = 0; i < num_vers; i++) { if (req_major == ver_supp[i].major) { if (req_minor >= ver_supp[i].minor) { /* * The major version matches and the * minor version either matches, or * is the best match that we have. */ act_ver = ver_supp[i]; break; } } else if (req_major > ver_supp[i].major) { /* * The requested major version is larger than * the current version we are checking. There * is not going to be a better match. */ act_ver = ver_supp[i]; break; } } DCS_DBG(DBG_SES, "requested ver: %d.%d, closest match: %d.%d", req_major, req_minor, act_ver.major, act_ver.minor); return (act_ver); } /* * filter_list_data: * * Check a list of cfga_list_data_t structures to filter out the ones * that don't have other-read permissions. All valid entries are placed * at the beginning of the array and the count of entries is updated. */ static void filter_list_data(int perm, int *nlistp, cfga_list_data_t *linfo) { int num_aps; int num_aps_ret; int curr_ap; int next_aval; int end_block; int block_size; struct stat ap_info; DCS_DBG(DBG_MSG, "list access = %s", (perm == RDR_PRIVILEGED) ? "RDR_PRIVILEGED" : "RDR_NOT_PRIVILEGED"); /* * Check if the user has priviledged access * to view all attachment points */ if (perm == RDR_PRIVILEGED) { return; } if (*nlistp < 0) { *nlistp = 0; } /* * No priviledged access, check each attachment point to * see if the user has access (other:read) to view it. */ num_aps = *nlistp; next_aval = 0; num_aps_ret = 0; curr_ap = 0; /* * Use a simple algorithm to compact the array so that * all attachment points that can be viewed are at the * beginning of the array. Adjust the count of the * attachment points accordingly. */ while (curr_ap < num_aps) { stat(linfo[curr_ap].ap_phys_id, &ap_info); /* check for unrestricted read permission */ if (ap_info.st_mode & S_IROTH) { end_block = curr_ap + 1; /* * Check if this is the beginning of a * block of consecutive ap ids that can * be returned. */ while (end_block < num_aps) { stat(linfo[end_block].ap_phys_id, &ap_info); /* search until the end of the block */ if (ap_info.st_mode & S_IROTH) { end_block++; } else { break; } } block_size = end_block - curr_ap; /* make sure a copy is necessary */ if (curr_ap != next_aval) { /* copy the block of ap ids all at once */ (void) memmove(&linfo[next_aval], &linfo[curr_ap], block_size * sizeof (cfga_list_data_t)); } /* move past the copied block */ next_aval += block_size; curr_ap = end_block; num_aps_ret += block_size; } else { curr_ap++; } } DCS_DBG(DBG_ALL, "filtered %d of %d ap ids", (*nlistp - num_aps_ret), *nlistp); /* * return the number of aps that have the correct * access permissions. */ *nlistp = num_aps_ret; } /* * generate_sort_order: * * Determine the sort order of an array of cfga_list_data_t structures * and create an array of rdr_list_t structures that contain the original * elements tagged with the sort order. * * This function is used to eliminate unnecessary network traffic that * might occur if the client needs the output of config_list_ext(3CFGADM) * sorted. Since a comparison is performed in a platform specific manner * using config_ap_id_cmp(3CFGADM), a client must establish a new session * for each comparison. For a long lists of attachment points, this can * slow down a simple list_ext operation significantly. With the sort * information included in the array of rdr_list_t structures, the client * can perform the sort operation locally, thus eliminating a great deal * of network traffic. */ static rdr_list_t * generate_sort_order(cfga_list_data_t *listp, int nlist) { int curr_ap; rdr_list_t *datalp; cfga_list_data_t *sortlp; cfga_list_data_t *match; assert(listp); if (nlist <= 0) { return (NULL); } /* create our new array */ datalp = (rdr_list_t *)malloc(nlist * sizeof (rdr_list_t)); if (datalp == NULL) { return (NULL); } /* copy over the elements, preserving the original order */ for (curr_ap = 0; curr_ap < nlist; curr_ap++) { datalp[curr_ap].ap_id_info = listp[curr_ap]; } /* handle a one element list */ if (nlist == 1) { datalp[0].sort_order = 0; return (datalp); } /* sort the cfga_list_data_t array */ qsort(listp, nlist, sizeof (listp[0]), ldata_compare); sortlp = listp; /* process each item in the original list */ for (curr_ap = 0; curr_ap < nlist; curr_ap++) { /* look up the sort order in the sorted list */ match = bsearch(&datalp[curr_ap].ap_id_info, sortlp, nlist, sizeof (cfga_list_data_t), ldata_compare); /* found a match */ if (match != NULL) { datalp[curr_ap].sort_order = match - sortlp; } else { /* * Should never get here. Since we did a * direct copy of the array, we should always * be able to find the ap id that we were * looking for. */ DCS_DBG(DBG_ALL, "could not find a matching " "ap id in the sorted list"); datalp[curr_ap].sort_order = 0; } } return (datalp); } /* * ldata_compare: * * Compare the two inputs to produce a strcmp(3C) style result. It uses * config_ap_id_cmp(3CFGADM) to perform the comparison. * * This function is passed to qsort(3C) in generate_sort_order() to sort a * list of attachment points. */ static int ldata_compare(const void *ap1, const void *ap2) { cfga_list_data_t *ap_id1; cfga_list_data_t *ap_id2; ap_id1 = (cfga_list_data_t *)ap1; ap_id2 = (cfga_list_data_t *)ap2; return (config_ap_id_cmp(ap_id1->ap_log_id, ap_id2->ap_log_id)); } /* * basename: * * Find short path name of a full path name. If a short path name * is passed in, the original pointer is returned. */ static char * basename(char *cp) { char *sp; if ((sp = strrchr(cp, '/')) != NULL) { return (sp + 1); } return (cp); } /* * is_socket: * * determine if fd represents a socket file type. */ static boolean_t is_socket(int fd) { struct stat statb; if (fstat(fd, &statb) < 0) { return (B_FALSE); } return (S_ISSOCK(statb.st_mode)); }