/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1996, 1997, 1998 * Sleepycat Software. All rights reserved. */ #include "config.h" #ifndef lint static const char sccsid[] = "@(#)lock_deadlock.c 10.37 (Sleepycat) 10/4/98"; #endif /* not lint */ #ifndef NO_SYSTEM_INCLUDES #include #include #include #endif #include "db_int.h" #include "shqueue.h" #include "db_shash.h" #include "lock.h" #include "common_ext.h" #define ISSET_MAP(M, N) (M[(N) / 32] & (1 << (N) % 32)) #define CLEAR_MAP(M, N) { \ u_int32_t __i; \ for (__i = 0; __i < (N); __i++) \ M[__i] = 0; \ } #define SET_MAP(M, B) (M[(B) / 32] |= (1 << ((B) % 32))) #define CLR_MAP(M, B) (M[(B) / 32] &= ~(1 << ((B) % 32))) #define OR_MAP(D, S, N) { \ u_int32_t __i; \ for (__i = 0; __i < (N); __i++) \ D[__i] |= S[__i]; \ } #define BAD_KILLID 0xffffffff typedef struct { int valid; u_int32_t id; DB_LOCK last_lock; db_pgno_t pgno; } locker_info; static int __dd_abort __P((DB_ENV *, locker_info *)); static int __dd_build __P((DB_ENV *, u_int32_t **, u_int32_t *, locker_info **)); static u_int32_t *__dd_find __P((u_int32_t *, locker_info *, u_int32_t)); #ifdef DIAGNOSTIC static void __dd_debug __P((DB_ENV *, locker_info *, u_int32_t *, u_int32_t)); #endif int lock_detect(lt, flags, atype) DB_LOCKTAB *lt; u_int32_t flags, atype; { DB_ENV *dbenv; locker_info *idmap; u_int32_t *bitmap, *deadlock, i, killid, nentries, nlockers; int do_pass, ret; LOCK_PANIC_CHECK(lt); /* Validate arguments. */ if ((ret = __db_fchk(lt->dbenv, "lock_detect", flags, DB_LOCK_CONFLICT)) != 0) return (ret); /* Check if a detector run is necessary. */ dbenv = lt->dbenv; if (LF_ISSET(DB_LOCK_CONFLICT)) { /* Make a pass every time a lock waits. */ LOCK_LOCKREGION(lt); do_pass = dbenv->lk_info->region->need_dd != 0; UNLOCK_LOCKREGION(lt); if (!do_pass) return (0); } /* Build the waits-for bitmap. */ if ((ret = __dd_build(dbenv, &bitmap, &nlockers, &idmap)) != 0) return (ret); if (nlockers == 0) return (0); #ifdef DIAGNOSTIC if (dbenv->db_verbose != 0) __dd_debug(dbenv, idmap, bitmap, nlockers); #endif /* Find a deadlock. */ deadlock = __dd_find(bitmap, idmap, nlockers); nentries = ALIGN(nlockers, 32) / 32; killid = BAD_KILLID; if (deadlock != NULL) { /* Kill someone. */ switch (atype) { case DB_LOCK_OLDEST: /* * Find the first bit set in the current * array and then look for a lower tid in * the array. */ for (i = 0; i < nlockers; i++) if (ISSET_MAP(deadlock, i)) killid = i; if (killid == BAD_KILLID) { __db_err(dbenv, "warning: could not find locker to abort"); break; } /* * The oldest transaction has the lowest * transaction id. */ for (i = killid + 1; i < nlockers; i++) if (ISSET_MAP(deadlock, i) && idmap[i].id < idmap[killid].id) killid = i; break; case DB_LOCK_DEFAULT: case DB_LOCK_RANDOM: /* * We are trying to calculate the id of the * locker whose entry is indicated by deadlock. */ killid = (deadlock - bitmap) / nentries; break; case DB_LOCK_YOUNGEST: /* * Find the first bit set in the current * array and then look for a lower tid in * the array. */ for (i = 0; i < nlockers; i++) if (ISSET_MAP(deadlock, i)) killid = i; if (killid == BAD_KILLID) { __db_err(dbenv, "warning: could not find locker to abort"); break; } /* * The youngest transaction has the highest * transaction id. */ for (i = killid + 1; i < nlockers; i++) if (ISSET_MAP(deadlock, i) && idmap[i].id > idmap[killid].id) killid = i; break; default: killid = BAD_KILLID; ret = EINVAL; } /* Kill the locker with lockid idmap[killid]. */ if (dbenv->db_verbose != 0 && killid != BAD_KILLID) __db_err(dbenv, "Aborting locker %lx", (u_long)idmap[killid].id); if (killid != BAD_KILLID && (ret = __dd_abort(dbenv, &idmap[killid])) != 0) __db_err(dbenv, "warning: unable to abort locker %lx", (u_long)idmap[killid].id); } __os_free(bitmap, 0); __os_free(idmap, 0); return (ret); } /* * ======================================================================== * Utilities */ static int __dd_build(dbenv, bmp, nlockers, idmap) DB_ENV *dbenv; u_int32_t **bmp, *nlockers; locker_info **idmap; { struct __db_lock *lp; DB_LOCKTAB *lt; DB_LOCKOBJ *op, *lo, *lockerp; u_int8_t *pptr; locker_info *id_array; u_int32_t *bitmap, count, *entryp, i, id, nentries, *tmpmap; int is_first, ret; lt = dbenv->lk_info; /* * We'll check how many lockers there are, add a few more in for * good measure and then allocate all the structures. Then we'll * verify that we have enough room when we go back in and get the * mutex the second time. */ LOCK_LOCKREGION(lt); retry: count = lt->region->nlockers; lt->region->need_dd = 0; UNLOCK_LOCKREGION(lt); if (count == 0) { *nlockers = 0; return (0); } if (dbenv->db_verbose) __db_err(dbenv, "%lu lockers", (u_long)count); count += 10; nentries = ALIGN(count, 32) / 32; /* * Allocate enough space for a count by count bitmap matrix. * * XXX * We can probably save the malloc's between iterations just * reallocing if necessary because count grew by too much. */ if ((ret = __os_calloc((size_t)count, sizeof(u_int32_t) * nentries, &bitmap)) != 0) return (ret); if ((ret = __os_calloc(sizeof(u_int32_t), nentries, &tmpmap)) != 0) { __os_free(bitmap, sizeof(u_int32_t) * nentries); return (ret); } if ((ret = __os_calloc((size_t)count, sizeof(locker_info), &id_array)) != 0) { __os_free(bitmap, count * sizeof(u_int32_t) * nentries); __os_free(tmpmap, sizeof(u_int32_t) * nentries); return (ret); } /* * Now go back in and actually fill in the matrix. */ LOCK_LOCKREGION(lt); if (lt->region->nlockers > count) { __os_free(bitmap, count * sizeof(u_int32_t) * nentries); __os_free(tmpmap, sizeof(u_int32_t) * nentries); __os_free(id_array, count * sizeof(locker_info)); goto retry; } /* * First we go through and assign each locker a deadlock detector id. * Note that we fill in the idmap in the next loop since that's the * only place where we conveniently have both the deadlock id and the * actual locker. */ for (id = 0, i = 0; i < lt->region->table_size; i++) for (op = SH_TAILQ_FIRST(<->hashtab[i], __db_lockobj); op != NULL; op = SH_TAILQ_NEXT(op, links, __db_lockobj)) if (op->type == DB_LOCK_LOCKER) op->dd_id = id++; /* * We go through the hash table and find each object. For each object, * we traverse the waiters list and add an entry in the waitsfor matrix * for each waiter/holder combination. */ for (i = 0; i < lt->region->table_size; i++) { for (op = SH_TAILQ_FIRST(<->hashtab[i], __db_lockobj); op != NULL; op = SH_TAILQ_NEXT(op, links, __db_lockobj)) { if (op->type != DB_LOCK_OBJTYPE) continue; CLEAR_MAP(tmpmap, nentries); /* * First we go through and create a bit map that * represents all the holders of this object. */ for (lp = SH_TAILQ_FIRST(&op->holders, __db_lock); lp != NULL; lp = SH_TAILQ_NEXT(lp, links, __db_lock)) { if (__lock_getobj(lt, lp->holder, NULL, DB_LOCK_LOCKER, &lockerp) != 0) { __db_err(dbenv, "warning unable to find object"); continue; } id_array[lockerp->dd_id].id = lp->holder; id_array[lockerp->dd_id].valid = 1; /* * If the holder has already been aborted, then * we should ignore it for now. */ if (lp->status == DB_LSTAT_HELD) SET_MAP(tmpmap, lockerp->dd_id); } /* * Next, for each waiter, we set its row in the matrix * equal to the map of holders we set up above. */ for (is_first = 1, lp = SH_TAILQ_FIRST(&op->waiters, __db_lock); lp != NULL; is_first = 0, lp = SH_TAILQ_NEXT(lp, links, __db_lock)) { if (__lock_getobj(lt, lp->holder, NULL, DB_LOCK_LOCKER, &lockerp) != 0) { __db_err(dbenv, "warning unable to find object"); continue; } id_array[lockerp->dd_id].id = lp->holder; id_array[lockerp->dd_id].valid = 1; /* * If the transaction is pending abortion, then * ignore it on this iteration. */ if (lp->status != DB_LSTAT_WAITING) continue; entryp = bitmap + (nentries * lockerp->dd_id); OR_MAP(entryp, tmpmap, nentries); /* * If this is the first waiter on the queue, * then we remove the waitsfor relationship * with oneself. However, if it's anywhere * else on the queue, then we have to keep * it and we have an automatic deadlock. */ if (is_first) CLR_MAP(entryp, lockerp->dd_id); } } } /* Now for each locker; record its last lock. */ for (id = 0; id < count; id++) { if (!id_array[id].valid) continue; if (__lock_getobj(lt, id_array[id].id, NULL, DB_LOCK_LOCKER, &lockerp) != 0) { __db_err(dbenv, "No locks for locker %lu", (u_long)id_array[id].id); continue; } lp = SH_LIST_FIRST(&lockerp->heldby, __db_lock); if (lp != NULL) { id_array[id].last_lock = LOCK_TO_OFFSET(lt, lp); lo = (DB_LOCKOBJ *)((u_int8_t *)lp + lp->obj); pptr = SH_DBT_PTR(&lo->lockobj); if (lo->lockobj.size >= sizeof(db_pgno_t)) memcpy(&id_array[id].pgno, pptr, sizeof(db_pgno_t)); else id_array[id].pgno = 0; } } /* Pass complete, reset the deadlock detector bit. */ lt->region->need_dd = 0; UNLOCK_LOCKREGION(lt); /* * Now we can release everything except the bitmap matrix that we * created. */ *nlockers = id; *idmap = id_array; *bmp = bitmap; __os_free(tmpmap, sizeof(u_int32_t) * nentries); return (0); } static u_int32_t * __dd_find(bmp, idmap, nlockers) u_int32_t *bmp, nlockers; locker_info *idmap; { u_int32_t i, j, nentries, *mymap, *tmpmap; /* * For each locker, OR in the bits from the lockers on which that * locker is waiting. */ nentries = ALIGN(nlockers, 32) / 32; for (mymap = bmp, i = 0; i < nlockers; i++, mymap += nentries) { if (!idmap[i].valid) continue; for (j = 0; j < nlockers; j++) { if (ISSET_MAP(mymap, j)) { /* Find the map for this bit. */ tmpmap = bmp + (nentries * j); OR_MAP(mymap, tmpmap, nentries); if (ISSET_MAP(mymap, i)) return (mymap); } } } return (NULL); } static int __dd_abort(dbenv, info) DB_ENV *dbenv; locker_info *info; { struct __db_lock *lockp; DB_LOCKTAB *lt; DB_LOCKOBJ *lockerp, *sh_obj; int ret; lt = dbenv->lk_info; LOCK_LOCKREGION(lt); /* Find the locker's last lock. */ if ((ret = __lock_getobj(lt, info->id, NULL, DB_LOCK_LOCKER, &lockerp)) != 0) goto out; lockp = SH_LIST_FIRST(&lockerp->heldby, __db_lock); /* * It's possible that this locker was already aborted. * If that's the case, make sure that we remove its * locker from the hash table. */ if (lockp == NULL) { HASHREMOVE_EL(lt->hashtab, __db_lockobj, links, lockerp, lt->region->table_size, __lock_lhash); SH_TAILQ_INSERT_HEAD(<->region->free_objs, lockerp, links, __db_lockobj); lt->region->nlockers--; goto out; } else if (LOCK_TO_OFFSET(lt, lockp) != info->last_lock || lockp->status != DB_LSTAT_WAITING) goto out; /* Abort lock, take it off list, and wake up this lock. */ lockp->status = DB_LSTAT_ABORTED; lt->region->ndeadlocks++; SH_LIST_REMOVE(lockp, locker_links, __db_lock); sh_obj = (DB_LOCKOBJ *)((u_int8_t *)lockp + lockp->obj); SH_TAILQ_REMOVE(&sh_obj->waiters, lockp, links, __db_lock); (void)__db_mutex_unlock(&lockp->mutex, lt->reginfo.fd); ret = 0; out: UNLOCK_LOCKREGION(lt); return (ret); } #ifdef DIAGNOSTIC static void __dd_debug(dbenv, idmap, bitmap, nlockers) DB_ENV *dbenv; locker_info *idmap; u_int32_t *bitmap, nlockers; { u_int32_t i, j, *mymap, nentries; int ret; char *msgbuf; __db_err(dbenv, "Waitsfor array"); __db_err(dbenv, "waiter\twaiting on"); /* Allocate space to print 10 bytes per item waited on. */ #undef MSGBUF_LEN #define MSGBUF_LEN ((nlockers + 1) * 10 + 64) if ((ret = __os_malloc(MSGBUF_LEN, NULL, &msgbuf)) != 0) return; nentries = ALIGN(nlockers, 32) / 32; for (mymap = bitmap, i = 0; i < nlockers; i++, mymap += nentries) { if (!idmap[i].valid) continue; sprintf(msgbuf, /* Waiter. */ "%lx/%lu:\t", (u_long)idmap[i].id, (u_long)idmap[i].pgno); for (j = 0; j < nlockers; j++) if (ISSET_MAP(mymap, j)) sprintf(msgbuf, "%s %lx", msgbuf, (u_long)idmap[j].id); (void)sprintf(msgbuf, "%s %lu", msgbuf, (u_long)idmap[i].last_lock); __db_err(dbenv, msgbuf); } __os_free(msgbuf, MSGBUF_LEN); } #endif