/* * Copyright (c) 1995 * Bill Paul . All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Bill Paul. * 4. Neither the name of the author nor the names of any co-contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL Bill Paul OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include "yp_extern.h" int ypdb_debug = 0; enum ypstat yp_errno = YP_TRUE; #define PERM_SECURE (S_IRUSR|S_IWUSR) HASHINFO openinfo = { 4096, /* bsize */ 32, /* ffactor */ 256, /* nelem */ 2048 * 512, /* cachesize */ NULL, /* hash */ 0, /* lorder */ }; #ifdef DB_CACHE #include #ifndef MAXDBS #define MAXDBS 20 #endif static int numdbs = 0; struct dbent { DB *dbp; char *name; char *key; int size; int flags; }; static TAILQ_HEAD(circlehead, circleq_entry) qhead; struct circleq_entry { struct dbent *dbptr; TAILQ_ENTRY(circleq_entry) links; }; /* * Initialize the circular queue. */ void yp_init_dbs(void) { TAILQ_INIT(&qhead); return; } /* * Dynamically allocate an entry for the circular queue. * Return a NULL pointer on failure. */ static struct circleq_entry * yp_malloc_qent(void) { register struct circleq_entry *q; q = (struct circleq_entry *)malloc(sizeof(struct circleq_entry)); if (q == NULL) { yp_error("failed to malloc() circleq entry"); return(NULL); } bzero((char *)q, sizeof(struct circleq_entry)); q->dbptr = (struct dbent *)malloc(sizeof(struct dbent)); if (q->dbptr == NULL) { yp_error("failed to malloc() circleq entry"); free(q); return(NULL); } bzero((char *)q->dbptr, sizeof(struct dbent)); return(q); } /* * Free a previously allocated circular queue * entry. */ static void yp_free_qent(struct circleq_entry *q) { /* * First, close the database. In theory, this is also * supposed to free the resources allocated by the DB * package, including the memory pointed to by q->dbptr->key. * This means we don't have to free q->dbptr->key here. */ if (q->dbptr->dbp) { (void)(q->dbptr->dbp->close)(q->dbptr->dbp); q->dbptr->dbp = NULL; } /* * Then free the database name, which was strdup()'ed. */ free(q->dbptr->name); /* * Free the rest of the dbent struct. */ free(q->dbptr); q->dbptr = NULL; /* * Free the circleq struct. */ free(q); q = NULL; return; } /* * Zorch a single entry in the dbent queue and release * all its resources. (This always removes the last entry * in the queue.) */ static void yp_flush(void) { register struct circleq_entry *qptr; qptr = TAILQ_LAST(&qhead, circlehead); TAILQ_REMOVE(&qhead, qptr, links); yp_free_qent(qptr); numdbs--; return; } /* * Close all databases, erase all database names and empty the queue. */ void yp_flush_all(void) { register struct circleq_entry *qptr; while (!TAILQ_EMPTY(&qhead)) { qptr = TAILQ_FIRST(&qhead); /* save this */ TAILQ_REMOVE(&qhead, qptr, links); yp_free_qent(qptr); } numdbs = 0; return; } static char *inter_string = "YP_INTERDOMAIN"; static char *secure_string = "YP_SECURE"; static int inter_sz = sizeof("YP_INTERDOMAIN") - 1; static int secure_sz = sizeof("YP_SECURE") - 1; static int yp_setflags(DB *dbp) { DBT key = { NULL, 0 }, data = { NULL, 0 }; int flags = 0; key.data = inter_string; key.size = inter_sz; if (!(dbp->get)(dbp, &key, &data, 0)) flags |= YP_INTERDOMAIN; key.data = secure_string; key.size = secure_sz; if (!(dbp->get)(dbp, &key, &data, 0)) flags |= YP_SECURE; return(flags); } int yp_testflag(char *map, char *domain, int flag) { char buf[MAXPATHLEN + 2]; register struct circleq_entry *qptr; if (map == NULL || domain == NULL) return(0); strcpy(buf, domain); strcat(buf, "/"); strcat(buf, map); TAILQ_FOREACH(qptr, &qhead, links) { if (!strcmp(qptr->dbptr->name, buf)) { if (qptr->dbptr->flags & flag) return(1); else return(0); } } if (yp_open_db_cache(domain, map, NULL, 0) == NULL) return(0); if (TAILQ_FIRST(&qhead)->dbptr->flags & flag) return(1); return(0); } /* * Add a DB handle and database name to the cache. We only maintain * fixed number of entries in the cache, so if we're asked to store * a new entry when all our slots are already filled, we have to kick * out the entry in the last slot to make room. */ static int yp_cache_db(DB *dbp, char *name, int size) { register struct circleq_entry *qptr; if (numdbs == MAXDBS) { if (ypdb_debug) yp_error("queue overflow -- releasing last slot"); yp_flush(); } /* * Allocate a new queue entry. */ if ((qptr = yp_malloc_qent()) == NULL) { yp_error("failed to allocate a new cache entry"); return(1); } qptr->dbptr->dbp = dbp; qptr->dbptr->name = strdup(name); qptr->dbptr->size = size; qptr->dbptr->key = NULL; qptr->dbptr->flags = yp_setflags(dbp); TAILQ_INSERT_HEAD(&qhead, qptr, links); numdbs++; return(0); } /* * Search the list for a database matching 'name.' If we find it, * move it to the head of the list and return its DB handle. If * not, just fail: yp_open_db_cache() will subsequently try to open * the database itself and call yp_cache_db() to add it to the * list. * * The search works like this: * * - The caller specifies the name of a database to locate. We try to * find an entry in our queue with a matching name. * * - If the caller doesn't specify a key or size, we assume that the * first entry that we encounter with a matching name is returned. * This will result in matches regardless of the key/size values * stored in the queue entry. * * - If the caller also specifies a key and length, we check to see * if the key and length saved in the queue entry also matches. * This lets us return a DB handle that's already positioned at the * correct location within a database. * * - Once we have a match, it gets migrated to the top of the queue * so that it will be easier to find if another request for * the same database comes in later. */ static DB * yp_find_db(const char *name, const char *key, int size) { register struct circleq_entry *qptr; TAILQ_FOREACH(qptr, &qhead, links) { if (!strcmp(qptr->dbptr->name, name)) { if (size) { if (size != qptr->dbptr->size || strncmp(qptr->dbptr->key, key, size)) continue; } else { if (qptr->dbptr->size) continue; } if (qptr != TAILQ_FIRST(&qhead)) { TAILQ_REMOVE(&qhead, qptr, links); TAILQ_INSERT_HEAD(&qhead, qptr, links); } return(qptr->dbptr->dbp); } } return(NULL); } /* * Open a DB database and cache the handle for later use. We first * check the cache to see if the required database is already open. * If so, we fetch the handle from the cache. If not, we try to open * the database and save the handle in the cache for later use. */ DB * yp_open_db_cache(const char *domain, const char *map, const char *key, const int size) { DB *dbp = NULL; char buf[MAXPATHLEN + 2]; /* snprintf(buf, sizeof(buf), "%s/%s", domain, map); */ yp_errno = YP_TRUE; strcpy(buf, domain); strcat(buf, "/"); strcat(buf, map); if ((dbp = yp_find_db(buf, key, size)) != NULL) { return(dbp); } else { if ((dbp = yp_open_db(domain, map)) != NULL) { if (yp_cache_db(dbp, buf, size)) { (void)(dbp->close)(dbp); yp_errno = YP_YPERR; return(NULL); } } } return (dbp); } #endif /* * Open a DB database. */ DB * yp_open_db(const char *domain, const char *map) { DB *dbp = NULL; char buf[MAXPATHLEN + 2]; yp_errno = YP_TRUE; if (map[0] == '.' || strchr(map, '/')) { yp_errno = YP_BADARGS; return (NULL); } #ifdef DB_CACHE if (yp_validdomain(domain)) { yp_errno = YP_NODOM; return(NULL); } #endif snprintf(buf, sizeof(buf), "%s/%s/%s", yp_dir, domain, map); #ifdef DB_CACHE again: #endif dbp = dbopen(buf,O_RDONLY, PERM_SECURE, DB_HASH, NULL); if (dbp == NULL) { switch (errno) { #ifdef DB_CACHE case ENFILE: /* * We ran out of file descriptors. Nuke an * open one and try again. */ yp_error("ran out of file descriptors"); yp_flush(); goto again; break; #endif case ENOENT: yp_errno = YP_NOMAP; break; case EFTYPE: yp_errno = YP_BADDB; break; default: yp_errno = YP_YPERR; break; } } return (dbp); } /* * Database access routines. * * - yp_get_record(): retrieve an arbitrary key/data pair given one key * to match against. * * - yp_first_record(): retrieve first key/data base in a database. * * - yp_next_record(): retrieve key/data pair that sequentially follows * the supplied key value in the database. */ #ifdef DB_CACHE int yp_get_record(DB *dbp, const DBT *key, DBT *data, int allow) #else int yp_get_record(const char *domain, const char *map, const DBT *key, DBT *data, int allow) #endif { #ifndef DB_CACHE DB *dbp; #endif int rval = 0; #ifndef DB_CACHE static unsigned char buf[YPMAXRECORD]; #endif if (ypdb_debug) yp_error("looking up key [%.*s]", (int)key->size, (char *)key->data); /* * Avoid passing back magic "YP_*" entries unless * the caller specifically requested them by setting * the 'allow' flag. */ if (!allow && !strncmp(key->data, "YP_", 3)) return(YP_NOKEY); #ifndef DB_CACHE if ((dbp = yp_open_db(domain, map)) == NULL) { return(yp_errno); } #endif if ((rval = (dbp->get)(dbp, key, data, 0)) != 0) { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->size = 0; #else (void)(dbp->close)(dbp); #endif if (rval == 1) return(YP_NOKEY); else return(YP_BADDB); } if (ypdb_debug) yp_error("result of lookup: key: [%.*s] data: [%.*s]", (int)key->size, (char *)key->data, (int)data->size, (char *)data->data); #ifdef DB_CACHE if (TAILQ_FIRST(&qhead)->dbptr->size) { TAILQ_FIRST(&qhead)->dbptr->key = ""; TAILQ_FIRST(&qhead)->dbptr->size = 0; } #else bcopy(data->data, &buf, data->size); data->data = &buf; (void)(dbp->close)(dbp); #endif return(YP_TRUE); } int yp_first_record(const DB *dbp, DBT *key, DBT *data, int allow) { int rval; #ifndef DB_CACHE static unsigned char buf[YPMAXRECORD]; #endif if (ypdb_debug) yp_error("retrieving first key in map"); if ((rval = (dbp->seq)(dbp,key,data,R_FIRST)) != 0) { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->size = 0; #endif if (rval == 1) return(YP_NOKEY); else return(YP_BADDB); } /* Avoid passing back magic "YP_*" records. */ while (!strncmp(key->data, "YP_", 3) && !allow) { if ((rval = (dbp->seq)(dbp,key,data,R_NEXT)) != 0) { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->size = 0; #endif if (rval == 1) return(YP_NOKEY); else return(YP_BADDB); } } if (ypdb_debug) yp_error("result of lookup: key: [%.*s] data: [%.*s]", (int)key->size, (char *)key->data, (int)data->size, (char *)data->data); #ifdef DB_CACHE if (TAILQ_FIRST(&qhead)->dbptr->size) { TAILQ_FIRST(&qhead)->dbptr->key = key->data; TAILQ_FIRST(&qhead)->dbptr->size = key->size; } #else bcopy(data->data, &buf, data->size); data->data = &buf; #endif return(YP_TRUE); } int yp_next_record(const DB *dbp, DBT *key, DBT *data, int all, int allow) { static DBT lkey = { NULL, 0 }; static DBT ldata = { NULL, 0 }; int rval; #ifndef DB_CACHE static unsigned char keybuf[YPMAXRECORD]; static unsigned char datbuf[YPMAXRECORD]; #endif if (key == NULL || !key->size || key->data == NULL) { rval = yp_first_record(dbp,key,data,allow); if (rval == YP_NOKEY) return(YP_NOMORE); else { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->key = key->data; TAILQ_FIRST(&qhead)->dbptr->size = key->size; #endif return(rval); } } if (ypdb_debug) yp_error("retrieving next key, previous was: [%.*s]", (int)key->size, (char *)key->data); if (!all) { #ifdef DB_CACHE if (TAILQ_FIRST(&qhead)->dbptr->key == NULL) { #endif (dbp->seq)(dbp,&lkey,&ldata,R_FIRST); while (key->size != lkey.size || strncmp(key->data, lkey.data, (int)key->size)) if ((dbp->seq)(dbp,&lkey,&ldata,R_NEXT)) { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->size = 0; #endif return(YP_NOKEY); } #ifdef DB_CACHE } #endif } if ((dbp->seq)(dbp,key,data,R_NEXT)) { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->size = 0; #endif return(YP_NOMORE); } /* Avoid passing back magic "YP_*" records. */ while (!strncmp(key->data, "YP_", 3) && !allow) if ((dbp->seq)(dbp,key,data,R_NEXT)) { #ifdef DB_CACHE TAILQ_FIRST(&qhead)->dbptr->size = 0; #endif return(YP_NOMORE); } if (ypdb_debug) yp_error("result of lookup: key: [%.*s] data: [%.*s]", (int)key->size, (char *)key->data, (int)data->size, (char *)data->data); #ifdef DB_CACHE if (TAILQ_FIRST(&qhead)->dbptr->size) { TAILQ_FIRST(&qhead)->dbptr->key = key->data; TAILQ_FIRST(&qhead)->dbptr->size = key->size; } #else bcopy(key->data, &keybuf, key->size); lkey.data = &keybuf; lkey.size = key->size; bcopy(data->data, &datbuf, data->size); data->data = &datbuf; #endif return(YP_TRUE); } #ifdef DB_CACHE /* * Database glue functions. */ static DB *yp_currmap_db = NULL; static int yp_allow_db = 0; ypstat yp_select_map(char *map, char *domain, keydat *key, int allow) { if (key == NULL) yp_currmap_db = yp_open_db_cache(domain, map, NULL, 0); else yp_currmap_db = yp_open_db_cache(domain, map, key->keydat_val, key->keydat_len); yp_allow_db = allow; return(yp_errno); } ypstat yp_getbykey(keydat *key, valdat *val) { DBT db_key = { NULL, 0 }, db_val = { NULL, 0 }; ypstat rval; db_key.data = key->keydat_val; db_key.size = key->keydat_len; rval = yp_get_record(yp_currmap_db, &db_key, &db_val, yp_allow_db); if (rval == YP_TRUE) { val->valdat_val = db_val.data; val->valdat_len = db_val.size; } return(rval); } ypstat yp_firstbykey(keydat *key, valdat *val) { DBT db_key = { NULL, 0 }, db_val = { NULL, 0 }; ypstat rval; rval = yp_first_record(yp_currmap_db, &db_key, &db_val, yp_allow_db); if (rval == YP_TRUE) { key->keydat_val = db_key.data; key->keydat_len = db_key.size; val->valdat_val = db_val.data; val->valdat_len = db_val.size; } return(rval); } ypstat yp_nextbykey(keydat *key, valdat *val) { DBT db_key = { NULL, 0 }, db_val = { NULL, 0 }; ypstat rval; db_key.data = key->keydat_val; db_key.size = key->keydat_len; rval = yp_next_record(yp_currmap_db, &db_key, &db_val, 0, yp_allow_db); if (rval == YP_TRUE) { key->keydat_val = db_key.data; key->keydat_len = db_key.size; val->valdat_val = db_val.data; val->valdat_len = db_val.size; } return(rval); } #endif