/* Unix SMB/CIFS implementation. tdb utility functions Copyright (C) Andrew Tridgell 1992-1998 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "includes.h" #include "lib/tdb/include/tdbutil.h" #include "system/glob.h" #include "system/wait.h" #include "system/filesys.h" #include "dlinklist.h" #include "pstring.h" /* these are little tdb utility functions that are meant to make dealing with a tdb database a little less cumbersome in Samba */ static sig_atomic_t gotalarm; /*************************************************************** Signal function to tell us we timed out. ****************************************************************/ static void gotalarm_sig(void) { gotalarm = 1; } /******************************************************************* THIS is a copy of the function CatchSignal found in lib/signal.c I need to copy it there to avoid sucking all of the samba source into tdb. Catch a signal. This should implement the following semantics: 1) The handler remains installed after being called. 2) The signal should be blocked during handler execution. ********************************************************************/ static void (*TdbCatchSignal(int signum,void (*handler)(int )))(int) { #ifdef HAVE_SIGACTION struct sigaction act; struct sigaction oldact; ZERO_STRUCT(act); act.sa_handler = handler; #ifdef SA_RESTART /* * We *want* SIGALRM to interrupt a system call. */ if(signum != SIGALRM) act.sa_flags = SA_RESTART; #endif sigemptyset(&act.sa_mask); sigaddset(&act.sa_mask,signum); sigaction(signum,&act,&oldact); return oldact.sa_handler; #else /* !HAVE_SIGACTION */ /* FIXME: need to handle sigvec and systems with broken signal() */ return signal(signum, handler); #endif } /*************************************************************** Make a TDB_DATA and keep the const warning in one place ****************************************************************/ static TDB_DATA make_tdb_data(const char *dptr, size_t dsize) { TDB_DATA ret; ret.dptr = discard_const_p(char, dptr); ret.dsize = dsize; return ret; } /**************************************************************************** Lock a chain with timeout (in seconds). ****************************************************************************/ static int tdb_chainlock_with_timeout_internal(TDB_CONTEXT *tdb, TDB_DATA key, uint_t timeout, int rw_type) { /* Allow tdb_chainlock to be interrupted by an alarm. */ int ret; gotalarm = 0; tdb_set_lock_alarm(&gotalarm); if (timeout) { TdbCatchSignal(SIGALRM, SIGNAL_CAST gotalarm_sig); alarm(timeout); } if (rw_type == F_RDLCK) ret = tdb_chainlock_read(tdb, key); else ret = tdb_chainlock(tdb, key); if (timeout) { alarm(0); TdbCatchSignal(SIGALRM, SIGNAL_CAST SIG_IGN); if (gotalarm) { tdb->log_fn(tdb, 0, "tdb_chainlock_with_timeout_internal: alarm (%u) timed out for key %s in tdb %s\n", timeout, key.dptr, tdb->name); /* TODO: If we time out waiting for a lock, it might * be nice to use F_GETLK to get the pid of the * process currently holding the lock and print that * as part of the debugging message. -- mbp */ return -1; } } return ret; } /**************************************************************************** Write lock a chain. Return -1 if timeout or lock failed. ****************************************************************************/ int tdb_chainlock_with_timeout(TDB_CONTEXT *tdb, TDB_DATA key, uint_t timeout) { return tdb_chainlock_with_timeout_internal(tdb, key, timeout, F_WRLCK); } /**************************************************************************** Lock a chain by string. Return -1 if timeout or lock failed. ****************************************************************************/ int tdb_lock_bystring(TDB_CONTEXT *tdb, const char *keyval, uint_t timeout) { TDB_DATA key = make_tdb_data(keyval, strlen(keyval)+1); return tdb_chainlock_with_timeout_internal(tdb, key, timeout, F_WRLCK); } /**************************************************************************** Unlock a chain by string. ****************************************************************************/ void tdb_unlock_bystring(TDB_CONTEXT *tdb, const char *keyval) { TDB_DATA key = make_tdb_data(keyval, strlen(keyval)+1); tdb_chainunlock(tdb, key); } /**************************************************************************** Read lock a chain by string. Return -1 if timeout or lock failed. ****************************************************************************/ int tdb_read_lock_bystring(TDB_CONTEXT *tdb, const char *keyval, uint_t timeout) { TDB_DATA key = make_tdb_data(keyval, strlen(keyval)+1); return tdb_chainlock_with_timeout_internal(tdb, key, timeout, F_RDLCK); } /**************************************************************************** Read unlock a chain by string. ****************************************************************************/ void tdb_read_unlock_bystring(TDB_CONTEXT *tdb, const char *keyval) { TDB_DATA key = make_tdb_data(keyval, strlen(keyval)+1); tdb_chainunlock_read(tdb, key); } /**************************************************************************** Fetch a int32_t value by a arbitrary blob key, return -1 if not found. Output is int32_t in native byte order. ****************************************************************************/ int32_t tdb_fetch_int32_byblob(TDB_CONTEXT *tdb, const char *keyval, size_t len) { TDB_DATA key = make_tdb_data(keyval, len); TDB_DATA data; int32_t ret; data = tdb_fetch(tdb, key); if (!data.dptr || data.dsize != sizeof(int32_t)) { SAFE_FREE(data.dptr); return -1; } ret = IVAL(data.dptr,0); SAFE_FREE(data.dptr); return ret; } /**************************************************************************** Fetch a int32_t value by string key, return -1 if not found. Output is int32_t in native byte order. ****************************************************************************/ int32_t tdb_fetch_int32(TDB_CONTEXT *tdb, const char *keystr) { return tdb_fetch_int32_byblob(tdb, keystr, strlen(keystr) + 1); } /**************************************************************************** Store a int32_t value by an arbitary blob key, return 0 on success, -1 on failure. Input is int32_t in native byte order. Output in tdb is in little-endian. ****************************************************************************/ int tdb_store_int32_byblob(TDB_CONTEXT *tdb, const char *keystr, size_t len, int32_t v) { TDB_DATA key = make_tdb_data(keystr, len); TDB_DATA data; int32_t v_store; SIVAL(&v_store,0,v); data.dptr = (void *)&v_store; data.dsize = sizeof(int32_t); return tdb_store(tdb, key, data, TDB_REPLACE); } /**************************************************************************** Store a int32_t value by string key, return 0 on success, -1 on failure. Input is int32_t in native byte order. Output in tdb is in little-endian. ****************************************************************************/ int tdb_store_int32(TDB_CONTEXT *tdb, const char *keystr, int32_t v) { return tdb_store_int32_byblob(tdb, keystr, strlen(keystr) + 1, v); } /**************************************************************************** Fetch a uint32_t value by a arbitrary blob key, return -1 if not found. Output is uint32_t in native byte order. ****************************************************************************/ BOOL tdb_fetch_uint32_byblob(TDB_CONTEXT *tdb, const char *keyval, size_t len, uint32_t *value) { TDB_DATA key = make_tdb_data(keyval, len); TDB_DATA data; data = tdb_fetch(tdb, key); if (!data.dptr || data.dsize != sizeof(uint32_t)) { SAFE_FREE(data.dptr); return False; } *value = IVAL(data.dptr,0); SAFE_FREE(data.dptr); return True; } /**************************************************************************** Fetch a uint32_t value by string key, return -1 if not found. Output is uint32_t in native byte order. ****************************************************************************/ BOOL tdb_fetch_uint32(TDB_CONTEXT *tdb, const char *keystr, uint32_t *value) { return tdb_fetch_uint32_byblob(tdb, keystr, strlen(keystr) + 1, value); } /**************************************************************************** Store a uint32_t value by an arbitary blob key, return 0 on success, -1 on failure. Input is uint32_t in native byte order. Output in tdb is in little-endian. ****************************************************************************/ BOOL tdb_store_uint32_byblob(TDB_CONTEXT *tdb, const char *keystr, size_t len, uint32_t value) { TDB_DATA key = make_tdb_data(keystr, len); TDB_DATA data; uint32_t v_store; BOOL ret = True; SIVAL(&v_store, 0, value); data.dptr = (void *)&v_store; data.dsize = sizeof(uint32_t); if (tdb_store(tdb, key, data, TDB_REPLACE) == -1) ret = False; return ret; } /**************************************************************************** Store a uint32_t value by string key, return 0 on success, -1 on failure. Input is uint32_t in native byte order. Output in tdb is in little-endian. ****************************************************************************/ BOOL tdb_store_uint32(TDB_CONTEXT *tdb, const char *keystr, uint32_t value) { return tdb_store_uint32_byblob(tdb, keystr, strlen(keystr) + 1, value); } /**************************************************************************** Store a buffer by a null terminated string key. Return 0 on success, -1 on failure. ****************************************************************************/ int tdb_store_bystring(TDB_CONTEXT *tdb, const char *keystr, TDB_DATA data, int flags) { TDB_DATA key = make_tdb_data(keystr, strlen(keystr)+1); return tdb_store(tdb, key, data, flags); } /**************************************************************************** Fetch a buffer using a null terminated string key. Don't forget to call free() on the result dptr. ****************************************************************************/ TDB_DATA tdb_fetch_bystring(TDB_CONTEXT *tdb, const char *keystr) { TDB_DATA key = make_tdb_data(keystr, strlen(keystr)+1); return tdb_fetch(tdb, key); } /**************************************************************************** Delete an entry using a null terminated string key. ****************************************************************************/ int tdb_delete_bystring(TDB_CONTEXT *tdb, const char *keystr) { TDB_DATA key = make_tdb_data(keystr, strlen(keystr)+1); return tdb_delete(tdb, key); } /**************************************************************************** Atomic integer change. Returns old value. To create, set initial value in *oldval. ****************************************************************************/ int32_t tdb_change_int32_atomic(TDB_CONTEXT *tdb, const char *keystr, int32_t *oldval, int32_t change_val) { int32_t val; int32_t ret = -1; if (tdb_lock_bystring(tdb, keystr,0) == -1) return -1; if ((val = tdb_fetch_int32(tdb, keystr)) == -1) { /* The lookup failed */ if (tdb_error(tdb) != TDB_ERR_NOEXIST) { /* but not because it didn't exist */ goto err_out; } /* Start with 'old' value */ val = *oldval; } else { /* It worked, set return value (oldval) to tdb data */ *oldval = val; } /* Increment value for storage and return next time */ val += change_val; if (tdb_store_int32(tdb, keystr, val) == -1) goto err_out; ret = 0; err_out: tdb_unlock_bystring(tdb, keystr); return ret; } /**************************************************************************** Atomic unsigned integer change. Returns old value. To create, set initial value in *oldval. ****************************************************************************/ BOOL tdb_change_uint32_atomic(TDB_CONTEXT *tdb, const char *keystr, uint32_t *oldval, uint32_t change_val) { uint32_t val; BOOL ret = False; if (tdb_lock_bystring(tdb, keystr,0) == -1) return False; if (!tdb_fetch_uint32(tdb, keystr, &val)) { /* It failed */ if (tdb_error(tdb) != TDB_ERR_NOEXIST) { /* and not because it didn't exist */ goto err_out; } /* Start with 'old' value */ val = *oldval; } else { /* it worked, set return value (oldval) to tdb data */ *oldval = val; } /* get a new value to store */ val += change_val; if (!tdb_store_uint32(tdb, keystr, val)) goto err_out; ret = True; err_out: tdb_unlock_bystring(tdb, keystr); return ret; } /**************************************************************************** Useful pair of routines for packing/unpacking data consisting of integers and strings. ****************************************************************************/ size_t tdb_pack(TDB_CONTEXT *tdb, char *buf, int bufsize, const char *fmt, ...) { va_list ap; uint8_t bt; uint16_t w; uint32_t d; int i; void *p; int len; char *s; char c; char *buf0 = buf; const char *fmt0 = fmt; int bufsize0 = bufsize; va_start(ap, fmt); while (*fmt) { switch ((c = *fmt++)) { case 'b': /* unsigned 8-bit integer */ len = 1; bt = (uint8_t)va_arg(ap, int); if (bufsize && bufsize >= len) SSVAL(buf, 0, bt); break; case 'w': /* unsigned 16-bit integer */ len = 2; w = (uint16_t)va_arg(ap, int); if (bufsize && bufsize >= len) SSVAL(buf, 0, w); break; case 'd': /* signed 32-bit integer (standard int in most systems) */ len = 4; d = va_arg(ap, uint32_t); if (bufsize && bufsize >= len) SIVAL(buf, 0, d); break; case 'p': /* pointer */ len = 4; p = va_arg(ap, void *); d = p?1:0; if (bufsize && bufsize >= len) SIVAL(buf, 0, d); break; case 'P': /* null-terminated string */ s = va_arg(ap,char *); w = strlen(s); len = w + 1; if (bufsize && bufsize >= len) memcpy(buf, s, len); break; case 'f': /* null-terminated string */ s = va_arg(ap,char *); w = strlen(s); len = w + 1; if (bufsize && bufsize >= len) memcpy(buf, s, len); break; case 'B': /* fixed-length string */ i = va_arg(ap, int); s = va_arg(ap, char *); len = 4+i; if (bufsize && bufsize >= len) { SIVAL(buf, 0, i); memcpy(buf+4, s, i); } break; default: tdb->log_fn(tdb, 0,"Unknown tdb_pack format %c in %s\n", c, fmt); len = 0; break; } buf += len; if (bufsize) bufsize -= len; if (bufsize < 0) bufsize = 0; } va_end(ap); tdb->log_fn(tdb, 18,"tdb_pack(%s, %d) -> %d\n", fmt0, bufsize0, (int)PTR_DIFF(buf, buf0)); return PTR_DIFF(buf, buf0); } /**************************************************************************** Useful pair of routines for packing/unpacking data consisting of integers and strings. ****************************************************************************/ int tdb_unpack(TDB_CONTEXT *tdb, char *buf, int bufsize, const char *fmt, ...) { va_list ap; uint8_t *bt; uint16_t *w; uint32_t *d; int len; int *i; void **p; char *s, **b; char c; char *buf0 = buf; const char *fmt0 = fmt; int bufsize0 = bufsize; va_start(ap, fmt); while (*fmt) { switch ((c=*fmt++)) { case 'b': len = 1; bt = va_arg(ap, uint8_t *); if (bufsize < len) goto no_space; *bt = SVAL(buf, 0); break; case 'w': len = 2; w = va_arg(ap, uint16_t *); if (bufsize < len) goto no_space; *w = SVAL(buf, 0); break; case 'd': len = 4; d = va_arg(ap, uint32_t *); if (bufsize < len) goto no_space; *d = IVAL(buf, 0); break; case 'p': len = 4; p = va_arg(ap, void **); if (bufsize < len) goto no_space; *p = (void *)IVAL(buf, 0); break; case 'P': s = va_arg(ap,char *); len = strlen(buf) + 1; if (bufsize < len || len > sizeof(pstring)) goto no_space; memcpy(s, buf, len); break; case 'f': s = va_arg(ap,char *); len = strlen(buf) + 1; if (bufsize < len || len > sizeof(fstring)) goto no_space; memcpy(s, buf, len); break; case 'B': i = va_arg(ap, int *); b = va_arg(ap, char **); len = 4; if (bufsize < len) goto no_space; *i = IVAL(buf, 0); if (! *i) { *b = NULL; break; } len += *i; if (bufsize < len) goto no_space; *b = (char *)malloc(*i); if (! *b) goto no_space; memcpy(*b, buf+4, *i); break; default: tdb->log_fn(tdb, 0, "Unknown tdb_unpack format %c in %s\n", c, fmt); len = 0; break; } buf += len; bufsize -= len; } va_end(ap); tdb->log_fn(tdb, 18, "tdb_unpack(%s, %d) -> %d\n", fmt0, bufsize0, (int)PTR_DIFF(buf, buf0)); return PTR_DIFF(buf, buf0); no_space: return -1; } /**************************************************************************** Allow tdb_delete to be used as a tdb_traversal_fn. ****************************************************************************/ int tdb_traverse_delete_fn(TDB_CONTEXT *the_tdb, TDB_DATA key, TDB_DATA dbuf, void *state) { return tdb_delete(the_tdb, key); } /** * Search across the whole tdb for keys that match the given pattern * return the result as a list of keys * * @param tdb pointer to opened tdb file context * @param pattern searching pattern used by fnmatch(3) functions * * @return list of keys found by looking up with given pattern **/ TDB_LIST_NODE *tdb_search_keys(TDB_CONTEXT *tdb, const char* pattern) { TDB_DATA key, next; TDB_LIST_NODE *list = NULL; TDB_LIST_NODE *rec = NULL; for (key = tdb_firstkey(tdb); key.dptr; key = next) { /* duplicate key string to ensure null-termination */ char *key_str = (char*) strndup(key.dptr, key.dsize); #if 0 if (!key_str) { tdb->log_fn(tdb, 0, "tdb_search_keys: strndup() failed!\n"); smb_panic("strndup failed!\n"); } #endif tdb->log_fn(tdb, 18, "checking %s for match to pattern %s\n", key_str, pattern); next = tdb_nextkey(tdb, key); /* do the pattern checking */ if (fnmatch(pattern, key_str, 0) == 0) { rec = (TDB_LIST_NODE*) malloc(sizeof(*rec)); ZERO_STRUCTP(rec); rec->node_key = key; DLIST_ADD_END(list, rec, TDB_LIST_NODE *); tdb->log_fn(tdb, 18, "checking %s matched pattern %s\n", key_str, pattern); } else { free(key.dptr); } /* free duplicated key string */ free(key_str); } return list; } /** * Free the list returned by tdb_search_keys * * @param node list of results found by tdb_search_keys **/ void tdb_search_list_free(TDB_LIST_NODE* node) { TDB_LIST_NODE *next_node; while (node) { next_node = node->next; SAFE_FREE(node->node_key.dptr); SAFE_FREE(node); node = next_node; } }