/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1996,2008 Oracle. All rights reserved. */ /* * Copyright (c) 1995, 1996 * The President and Fellows of Harvard University. All rights reserved. * * This code is derived from software contributed to Berkeley by * Margo Seltzer. * * 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. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 THE REGENTS 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. * * $Id: txn.c,v 12.89 2008/04/19 15:47:42 mjc Exp $ */ #include "db_config.h" #include "db_int.h" #include "dbinc/crypto.h" #include "dbinc/hmac.h" #include "dbinc/db_page.h" #include "dbinc/hash.h" #include "dbinc/lock.h" #include "dbinc/log.h" #include "dbinc/mp.h" #include "dbinc/txn.h" #define LOG_FLAGS(txn) \ (DB_LOG_COMMIT | (F_ISSET(txn, TXN_SYNC) ? \ DB_FLUSH : (F_ISSET(txn, TXN_WRITE_NOSYNC) ? \ DB_LOG_WRNOSYNC : 0))) /* * __txn_isvalid enumerated types. We cannot simply use the transaction * statuses, because different statuses need to be handled differently * depending on the caller. */ typedef enum { TXN_OP_ABORT, TXN_OP_COMMIT, TXN_OP_DISCARD, TXN_OP_PREPARE } txnop_t; static int __txn_abort_pp __P((DB_TXN *)); static int __txn_begin_int __P((DB_TXN *)); static int __txn_commit_pp __P((DB_TXN *, u_int32_t)); static int __txn_discard __P((DB_TXN *, u_int32_t)); static int __txn_dispatch_undo __P((ENV *, DB_TXN *, DBT *, DB_LSN *, DB_TXNHEAD *)); static int __txn_end __P((DB_TXN *, int)); static int __txn_isvalid __P((const DB_TXN *, txnop_t)); static int __txn_undo __P((DB_TXN *)); static void __txn_set_txn_lsnp __P((DB_TXN *, DB_LSN **, DB_LSN **)); /* * __txn_begin_pp -- * ENV->txn_begin pre/post processing. * * PUBLIC: int __txn_begin_pp __P((DB_ENV *, DB_TXN *, DB_TXN **, u_int32_t)); */ int __txn_begin_pp(dbenv, parent, txnpp, flags) DB_ENV *dbenv; DB_TXN *parent, **txnpp; u_int32_t flags; { DB_THREAD_INFO *ip; ENV *env; int rep_check, ret; env = dbenv->env; ENV_REQUIRES_CONFIG(env, env->tx_handle, "txn_begin", DB_INIT_TXN); if ((ret = __db_fchk(env, "txn_begin", flags, DB_READ_COMMITTED | DB_READ_UNCOMMITTED | DB_TXN_NOSYNC | DB_TXN_SNAPSHOT | DB_TXN_SYNC | DB_TXN_WAIT | DB_TXN_WRITE_NOSYNC | DB_TXN_NOWAIT)) != 0) return (ret); if ((ret = __db_fcchk(env, "txn_begin", flags, DB_TXN_WRITE_NOSYNC | DB_TXN_NOSYNC, DB_TXN_SYNC)) != 0) return (ret); if ((ret = __db_fcchk(env, "txn_begin", flags, DB_TXN_WRITE_NOSYNC, DB_TXN_NOSYNC)) != 0) return (ret); if (parent != NULL && !F_ISSET(parent, TXN_SNAPSHOT) && LF_ISSET(DB_TXN_SNAPSHOT)) { __db_errx(env, "Child transaction snapshot setting must match parent"); return (EINVAL); } ENV_ENTER(env, ip); if (parent == NULL) { rep_check = IS_ENV_REPLICATED(env) ? 1 : 0; if (rep_check && (ret = __op_rep_enter(env)) != 0) goto err; } else rep_check = 0; ret = __txn_begin(env, ip, parent, txnpp, flags); /* * We only decrement the count if the operation fails. * Otherwise the count will be decremented when the * txn is resolved by txn_commit, txn_abort, etc. */ if (ret != 0 && rep_check) (void)__op_rep_exit(env); err: ENV_LEAVE(env, ip); return (ret); } /* * __txn_begin -- * ENV->txn_begin. * * This is a wrapper to the actual begin process. Normal transaction begin * allocates a DB_TXN structure for the caller, while XA transaction begin * does not. Other than that, both call into common __txn_begin_int code. * * Internally, we use TXN_DETAIL structures, but the DB_TXN structure * provides access to the transaction ID and the offset in the transaction * region of the TXN_DETAIL structure. * * PUBLIC: int __txn_begin __P((ENV *, * PUBLIC: DB_THREAD_INFO *, DB_TXN *, DB_TXN **, u_int32_t)); */ int __txn_begin(env, ip, parent, txnpp, flags) ENV *env; DB_THREAD_INFO *ip; DB_TXN *parent, **txnpp; u_int32_t flags; { DB_ENV *dbenv; DB_LOCKREGION *region; DB_TXN *txn; TXN_DETAIL *ptd, *td; int ret; *txnpp = NULL; if ((ret = __os_calloc(env, 1, sizeof(DB_TXN), &txn)) != 0) return (ret); dbenv = env->dbenv; txn->mgrp = env->tx_handle; txn->parent = parent; TAILQ_INIT(&txn->kids); TAILQ_INIT(&txn->events); STAILQ_INIT(&txn->logs); txn->flags = TXN_MALLOC; txn->thread_info = ip != NULL ? ip : (parent != NULL ? parent->thread_info : NULL); /* * Set the sync mode for commit. Any local bits override those * in the environment. SYNC is the default. */ if (LF_ISSET(DB_TXN_SYNC)) F_SET(txn, TXN_SYNC); else if (LF_ISSET(DB_TXN_NOSYNC)) F_SET(txn, TXN_NOSYNC); else if (LF_ISSET(DB_TXN_WRITE_NOSYNC)) F_SET(txn, TXN_WRITE_NOSYNC); else if (F_ISSET(dbenv, DB_ENV_TXN_NOSYNC)) F_SET(txn, TXN_NOSYNC); else if (F_ISSET(dbenv, DB_ENV_TXN_WRITE_NOSYNC)) F_SET(txn, TXN_WRITE_NOSYNC); else F_SET(txn, TXN_SYNC); if (LF_ISSET(DB_TXN_NOWAIT) || (F_ISSET(dbenv, DB_ENV_TXN_NOWAIT) && !LF_ISSET(DB_TXN_WAIT))) F_SET(txn, TXN_NOWAIT); if (LF_ISSET(DB_READ_COMMITTED)) F_SET(txn, TXN_READ_COMMITTED); if (LF_ISSET(DB_READ_UNCOMMITTED)) F_SET(txn, TXN_READ_UNCOMMITTED); if (LF_ISSET(DB_TXN_SNAPSHOT) || F_ISSET(dbenv, DB_ENV_TXN_SNAPSHOT) || (parent != NULL && F_ISSET(parent, TXN_SNAPSHOT))) F_SET(txn, TXN_SNAPSHOT); if ((ret = __txn_begin_int(txn)) != 0) goto err; td = txn->td; if (parent != NULL) { ptd = parent->td; TAILQ_INSERT_HEAD(&parent->kids, txn, klinks); SH_TAILQ_INSERT_HEAD(&ptd->kids, td, klinks, __txn_detail); } if (LOCKING_ON(env)) { region = env->lk_handle->reginfo.primary; if (parent != NULL) { ret = __lock_inherit_timeout(env, parent->locker, txn->locker); /* No parent locker set yet. */ if (ret == EINVAL) { parent = NULL; ret = 0; } if (ret != 0) goto err; } /* * Parent is NULL if we have no parent * or it has no timeouts set. */ if (parent == NULL && region->tx_timeout != 0) if ((ret = __lock_set_timeout(env, txn->locker, region->tx_timeout, DB_SET_TXN_TIMEOUT)) != 0) goto err; } *txnpp = txn; return (0); err: __os_free(env, txn); return (ret); } /* * __txn_xa_begin -- * XA version of txn_begin. * * PUBLIC: int __txn_xa_begin __P((ENV *, DB_TXN *)); */ int __txn_xa_begin(env, txn) ENV *env; DB_TXN *txn; { /* * We need to initialize the transaction structure, but must be careful * not to smash the links. We manually initialize the structure. */ txn->mgrp = env->tx_handle; TAILQ_INIT(&txn->kids); TAILQ_INIT(&txn->events); STAILQ_INIT(&txn->logs); txn->parent = NULL; txn->txnid = TXN_INVALID; txn->cursors = 0; memset(&txn->lock_timeout, 0, sizeof(db_timeout_t)); memset(&txn->expire, 0, sizeof(db_timeout_t)); return (__txn_begin_int(txn)); } /* * __txn_recycle_id -- * Find a range of useable transaction ids. * * PUBLIC: int __txn_recycle_id __P((ENV *)); */ int __txn_recycle_id(env) ENV *env; { DB_LSN null_lsn; DB_TXNMGR *mgr; DB_TXNREGION *region; TXN_DETAIL *td; u_int32_t *ids; int nids, ret; mgr = env->tx_handle; region = mgr->reginfo.primary; if ((ret = __os_malloc(env, sizeof(u_int32_t) * region->maxtxns, &ids)) != 0) return (ret); nids = 0; SH_TAILQ_FOREACH(td, ®ion->active_txn, links, __txn_detail) ids[nids++] = td->txnid; region->last_txnid = TXN_MINIMUM - 1; region->cur_maxid = TXN_MAXIMUM; if (nids != 0) __db_idspace(ids, nids, ®ion->last_txnid, ®ion->cur_maxid); __os_free(env, ids); /* * Check LOGGING_ON rather than DBENV_LOGGING as we want to emit this * record at the end of recovery. */ if (LOGGING_ON(env)) ret = __txn_recycle_log(env, NULL, &null_lsn, 0, region->last_txnid + 1, region->cur_maxid); return (ret); } /* * __txn_compensate_begin * Begin an compensation transaction. This is a special interface * that is used only for transactions that must be started to compensate * for actions during an abort. Currently only used for allocations. * * PUBLIC: int __txn_compensate_begin __P((ENV *, DB_TXN **)); */ int __txn_compensate_begin(env, txnpp) ENV *env; DB_TXN **txnpp; { DB_TXN *txn; int ret; if ((ret = __os_calloc(env, 1, sizeof(DB_TXN), &txn)) != 0) return (ret); txn->mgrp = env->tx_handle; TAILQ_INIT(&txn->kids); TAILQ_INIT(&txn->events); STAILQ_INIT(&txn->logs); txn->flags = TXN_COMPENSATE | TXN_MALLOC; *txnpp = txn; return (__txn_begin_int(txn)); } /* * __txn_begin_int -- * Normal DB version of txn_begin. */ static int __txn_begin_int(txn) DB_TXN *txn; { DB_ENV *dbenv; DB_TXNMGR *mgr; DB_TXNREGION *region; ENV *env; TXN_DETAIL *td; u_int32_t id; int ret; mgr = txn->mgrp; env = mgr->env; dbenv = env->dbenv; region = mgr->reginfo.primary; TXN_SYSTEM_LOCK(env); if (!F_ISSET(txn, TXN_COMPENSATE) && F_ISSET(region, TXN_IN_RECOVERY)) { __db_errx(env, "operation not permitted during recovery"); ret = EINVAL; goto err; } /* * Allocate a new transaction id. Our current valid range can span * the maximum valid value, so check for it and wrap manually. */ if (region->last_txnid == TXN_MAXIMUM && region->cur_maxid != TXN_MAXIMUM) region->last_txnid = TXN_MINIMUM - 1; if (region->last_txnid == region->cur_maxid && (ret = __txn_recycle_id(env)) != 0) goto err; /* Allocate a new transaction detail structure. */ if ((ret = __env_alloc(&mgr->reginfo, sizeof(TXN_DETAIL), &td)) != 0) { __db_errx(env, "Unable to allocate memory for transaction detail"); goto err; } /* Place transaction on active transaction list. */ SH_TAILQ_INSERT_HEAD(®ion->active_txn, td, links, __txn_detail); id = ++region->last_txnid; #ifdef HAVE_STATISTICS ++region->stat.st_nbegins; if (++region->stat.st_nactive > region->stat.st_maxnactive) region->stat.st_maxnactive = region->stat.st_nactive; #endif td->txnid = id; dbenv->thread_id(dbenv, &td->pid, &td->tid); /* allocate a locker for this txn */ if (LOCKING_ON(env) && (ret = __lock_getlocker(env->lk_handle, id, 1, &txn->locker)) != 0) goto err; ZERO_LSN(td->last_lsn); ZERO_LSN(td->begin_lsn); SH_TAILQ_INIT(&td->kids); if (txn->parent != NULL) td->parent = R_OFFSET(&mgr->reginfo, txn->parent->td); else td->parent = INVALID_ROFF; td->name = INVALID_ROFF; MAX_LSN(td->read_lsn); MAX_LSN(td->visible_lsn); td->mvcc_ref = 0; td->mvcc_mtx = MUTEX_INVALID; td->status = TXN_RUNNING; td->flags = 0; td->xa_status = 0; td->nlog_dbs = 0; td->nlog_slots = TXN_NSLOTS; td->log_dbs = R_OFFSET(&mgr->reginfo, td->slots); TXN_SYSTEM_UNLOCK(env); txn->txnid = id; txn->td = td; txn->abort = __txn_abort_pp; txn->commit = __txn_commit_pp; txn->discard = __txn_discard; txn->get_name = __txn_get_name; txn->id = __txn_id; txn->prepare = __txn_prepare; txn->set_txn_lsnp = __txn_set_txn_lsnp; txn->set_name = __txn_set_name; txn->set_timeout = __txn_set_timeout; /* * If this is a transaction family, we must link the child to the * maximal grandparent in the lock table for deadlock detection. */ if (txn->parent != NULL && LOCKING_ON(env)) if ((ret = __lock_addfamilylocker(env, txn->parent->txnid, txn->txnid)) != 0) return (ret); if (F_ISSET(txn, TXN_MALLOC)) { MUTEX_LOCK(env, mgr->mutex); TAILQ_INSERT_TAIL(&mgr->txn_chain, txn, links); MUTEX_UNLOCK(env, mgr->mutex); } return (0); err: TXN_SYSTEM_UNLOCK(env); return (ret); } /* * __txn_continue * Fill in the fields of the local transaction structure given * the detail transaction structure. * * PUBLIC: int __txn_continue __P((ENV *, DB_TXN *, TXN_DETAIL *)); */ int __txn_continue(env, txn, td) ENV *env; DB_TXN *txn; TXN_DETAIL *td; { int ret; ret = 0; txn->mgrp = env->tx_handle; txn->parent = NULL; txn->txnid = td->txnid; txn->td = td; txn->abort = __txn_abort_pp; txn->commit = __txn_commit_pp; txn->discard = __txn_discard; txn->get_name = __txn_get_name; txn->id = __txn_id; txn->prepare = __txn_prepare; txn->set_name = __txn_set_name; txn->flags = 0; /* * If this is a restored transaction, we need to propagate that fact * to the process-local structure. However, if it's not a restored * transaction, then we're running in XA and we need to make sure * that we have a locker associated with this transaction. */ if (F_ISSET(td, TXN_DTL_RESTORED)) F_SET(txn, TXN_RESTORED); else ret = __lock_getlocker(env->lk_handle, txn->txnid, 0, &txn->locker); return (ret); } /* * __txn_commit_pp -- * Interface routine to TXN->commit. */ static int __txn_commit_pp(txn, flags) DB_TXN *txn; u_int32_t flags; { DB_THREAD_INFO *ip; ENV *env; int not_child, ret, t_ret; env = txn->mgrp->env; not_child = txn->parent == NULL; ENV_ENTER(env, ip); ret = __txn_commit(txn, flags); if (not_child && IS_ENV_REPLICATED(env) && (t_ret = __op_rep_exit(env)) != 0 && ret == 0) ret = t_ret; ENV_LEAVE(env, ip); return (ret); } /* * __txn_commit -- * Commit a transaction. * * PUBLIC: int __txn_commit __P((DB_TXN *, u_int32_t)); */ int __txn_commit(txn, flags) DB_TXN *txn; u_int32_t flags; { DBT list_dbt; DB_LOCKREQ request; DB_TXN *kid; ENV *env; REGENV *renv; REGINFO *infop; TXN_DETAIL *td; u_int32_t id; int ret, t_ret; env = txn->mgrp->env; td = txn->td; /* * A common mistake in Berkeley DB programs is to mis-handle deadlock * return. If the transaction deadlocked, they want abort, not commit. */ if (F_ISSET(txn, TXN_DEADLOCK)) { ret = __db_txn_deadlock_err(env, txn); goto err; } if ((ret = __txn_isvalid(txn, TXN_OP_COMMIT)) != 0) return (ret); /* * Check for master leases at the beginning. If we are a * master and cannot have valid leases now, we error and * abort this txn. Leases are granted on PERM records, * and since this is the beginning of txn_commit, there * might not be *any* in the log yet. If that is the case, * then __rep_lease_check (from __rep_lease_refresh and * lower, log_c_get) will return DB_NOTFOUND. If we get * that here, allow the operation to continue because leases * will be checked after the commit completes again anyway. */ if (txn->parent == NULL && IS_REP_MASTER(env) && IS_USING_LEASES(env) && (ret = __rep_lease_check(env, 1)) != 0) { if (ret == DB_NOTFOUND) { ret = 0; } else goto err; } infop = env->reginfo; renv = infop->primary; /* * No mutex is needed as envid is read-only once it is set. */ id = renv->envid; /* * We clear flags that are incorrect, ignoring any flag errors, and * default to synchronous operations. By definition, transaction * handles are dead when we return, and this error should never * happen, but we don't want to fail in the field 'cause the app is * specifying the wrong flag for some reason. */ if (__db_fchk(env, "DB_TXN->commit", flags, DB_TXN_NOSYNC | DB_TXN_SYNC | DB_TXN_WRITE_NOSYNC) != 0) flags = DB_TXN_SYNC; if (__db_fcchk(env, "DB_TXN->commit", flags, DB_TXN_SYNC, DB_TXN_NOSYNC | DB_TXN_WRITE_NOSYNC) != 0) flags = DB_TXN_SYNC; if (LF_ISSET(DB_TXN_WRITE_NOSYNC)) { F_CLR(txn, TXN_SYNC_FLAGS); F_SET(txn, TXN_WRITE_NOSYNC); } if (LF_ISSET(DB_TXN_NOSYNC)) { F_CLR(txn, TXN_SYNC_FLAGS); F_SET(txn, TXN_NOSYNC); } if (LF_ISSET(DB_TXN_SYNC)) { F_CLR(txn, TXN_SYNC_FLAGS); F_SET(txn, TXN_SYNC); } DB_ASSERT(env, F_ISSET(txn, TXN_SYNC_FLAGS)); /* * Commit any unresolved children. If anyone fails to commit, * then try to abort the rest of the kids and then abort the parent. * Abort should never fail; if it does, we bail out immediately. */ while ((kid = TAILQ_FIRST(&txn->kids)) != NULL) if ((ret = __txn_commit(kid, flags)) != 0) while ((kid = TAILQ_FIRST(&txn->kids)) != NULL) if ((t_ret = __txn_abort(kid)) != 0) return (__env_panic(env, t_ret)); /* * If there are any log records, write a log record and sync the log, * else do no log writes. If the commit is for a child transaction, * we do not need to commit the child synchronously since it may still * abort (if its parent aborts), and otherwise its parent or ultimate * ancestor will write synchronously. */ if (DBENV_LOGGING(env) && (!IS_ZERO_LSN(td->last_lsn) || STAILQ_FIRST(&txn->logs) != NULL)) { if (txn->parent == NULL) { /* * We are about to free all the read locks for this * transaction below. Some of those locks might be * handle locks which should not be freed, because * they will be freed when the handle is closed. Check * the events and preprocess any trades now so we don't * release the locks below. */ if ((ret = __txn_doevents(env, txn, TXN_PREPARE, 1)) != 0) goto err; memset(&request, 0, sizeof(request)); if (LOCKING_ON(env)) { request.op = DB_LOCK_PUT_READ; if (IS_REP_MASTER(env) && !IS_ZERO_LSN(td->last_lsn)) { memset(&list_dbt, 0, sizeof(list_dbt)); request.obj = &list_dbt; } ret = __lock_vec(env, txn->locker, 0, &request, 1, NULL); } if (ret == 0 && !IS_ZERO_LSN(td->last_lsn)) { ret = __txn_regop_log(env, txn, &td->visible_lsn, LOG_FLAGS(txn), TXN_COMMIT, (int32_t)time(NULL), id, request.obj); if (ret == 0) td->last_lsn = td->visible_lsn; #ifdef DIAGNOSTIC if (ret == 0) { DB_LSN s_lsn; DB_ASSERT(env, __log_current_lsn( env, &s_lsn, NULL, NULL) == 0); DB_ASSERT(env, LOG_COMPARE( &td->visible_lsn, &s_lsn) <= 0); COMPQUIET(s_lsn.file, 0); } #endif } if (request.obj != NULL && request.obj->data != NULL) __os_free(env, request.obj->data); if (ret != 0) goto err; } else { /* Log the commit in the parent! */ if (!IS_ZERO_LSN(td->last_lsn) && (ret = __txn_child_log(env, txn->parent, &((TXN_DETAIL *)txn->parent->td)->last_lsn, 0, txn->txnid, &td->last_lsn)) != 0) { goto err; } if (STAILQ_FIRST(&txn->logs) != NULL) { /* * Put the child first so we back it out first. * All records are undone in reverse order. */ STAILQ_CONCAT(&txn->logs, &txn->parent->logs); txn->parent->logs = txn->logs; STAILQ_INIT(&txn->logs); } F_SET(txn->parent, TXN_CHILDCOMMIT); } } if (txn->txn_list != NULL) { __db_txnlist_end(env, txn->txn_list); txn->txn_list = NULL; } if (ret != 0) goto err; /* * Check for master leases at the end of only a normal commit. * If we're a child, that is not a perm record. If we are a * master and cannot get valid leases now, something happened * during the commit. The only thing to do is panic. */ if (txn->parent == NULL && IS_REP_MASTER(env) && IS_USING_LEASES(env) && (ret = __rep_lease_check(env, 1)) != 0) { return (__env_panic(env, ret)); } /* This is OK because __txn_end can only fail with a panic. */ return (__txn_end(txn, 1)); err: /* * If we are prepared, then we "must" be able to commit. We panic here * because even though the coordinator might be able to retry it is not * clear it would know to do that. Otherwise we'll try to abort. If * that is successful, then we return whatever was in ret (that is, the * reason we failed). If the abort was unsuccessful, abort probably * returned DB_RUNRECOVERY and we need to propagate that up. */ if (td->status == TXN_PREPARED) return (__env_panic(env, ret)); if ((t_ret = __txn_abort(txn)) != 0) ret = t_ret; return (ret); } /* * __txn_abort_pp -- * Interface routine to TXN->abort. */ static int __txn_abort_pp(txn) DB_TXN *txn; { DB_THREAD_INFO *ip; ENV *env; int not_child, ret, t_ret; env = txn->mgrp->env; not_child = txn->parent == NULL; ENV_ENTER(env, ip); ret = __txn_abort(txn); if (not_child && IS_ENV_REPLICATED(env) && (t_ret = __op_rep_exit(env)) != 0 && ret == 0) ret = t_ret; ENV_LEAVE(env, ip); return (ret); } /* * __txn_abort -- * Abort a transaction. * * PUBLIC: int __txn_abort __P((DB_TXN *)); */ int __txn_abort(txn) DB_TXN *txn; { DB_LOCKREQ request; DB_TXN *kid; ENV *env; REGENV *renv; REGINFO *infop; TXN_DETAIL *td; u_int32_t id; int ret; env = txn->mgrp->env; td = txn->td; /* Ensure that abort always fails fatally. */ if ((ret = __txn_isvalid(txn, TXN_OP_ABORT)) != 0) return (__env_panic(env, ret)); /* * Try to abort any unresolved children. * * Abort either succeeds or panics the region. As soon as we * see any failure, we just get out of here and return the panic * up. */ while ((kid = TAILQ_FIRST(&txn->kids)) != NULL) if ((ret = __txn_abort(kid)) != 0) return (ret); infop = env->reginfo; renv = infop->primary; /* * No mutex is needed as envid is read-only once it is set. */ id = renv->envid; /* * Fast path -- no need to do anything fancy if there were no * modifications (e.g., log records) for this transaction. * We still call txn_undo to cleanup the txn_list from our * children. */ if (IS_ZERO_LSN(td->last_lsn) && STAILQ_FIRST(&txn->logs) == NULL) { if (txn->txn_list == NULL) goto done; else goto undo; } if (LOCKING_ON(env)) { /* Allocate a locker for this restored txn if necessary. */ if (txn->locker == NULL && (ret = __lock_getlocker(env->lk_handle, txn->txnid, 1, &txn->locker)) != 0) return (__env_panic(env, ret)); /* * We are about to free all the read locks for this transaction * below. Some of those locks might be handle locks which * should not be freed, because they will be freed when the * handle is closed. Check the events and preprocess any * trades now so that we don't release the locks below. */ if ((ret = __txn_doevents(env, txn, TXN_ABORT, 1)) != 0) return (__env_panic(env, ret)); /* Turn off timeouts. */ if ((ret = __lock_set_timeout(env, txn->locker, 0, DB_SET_TXN_TIMEOUT)) != 0) return (__env_panic(env, ret)); if ((ret = __lock_set_timeout(env, txn->locker, 0, DB_SET_LOCK_TIMEOUT)) != 0) return (__env_panic(env, ret)); request.op = DB_LOCK_UPGRADE_WRITE; request.obj = NULL; if ((ret = __lock_vec( env, txn->locker, 0, &request, 1, NULL)) != 0) return (__env_panic(env, ret)); } undo: if ((ret = __txn_undo(txn)) != 0) return (__env_panic(env, ret)); /* * Normally, we do not need to log aborts. However, if we * are a distributed transaction (i.e., we have a prepare), * then we log the abort so we know that this transaction * was actually completed. */ done: if (DBENV_LOGGING(env) && td->status == TXN_PREPARED && (ret = __txn_regop_log(env, txn, &td->last_lsn, LOG_FLAGS(txn), TXN_ABORT, (int32_t)time(NULL), id, NULL)) != 0) return (__env_panic(env, ret)); /* __txn_end always panics if it errors, so pass the return along. */ return (__txn_end(txn, 0)); } /* * __txn_discard -- * Interface routine to TXN->discard. */ static int __txn_discard(txn, flags) DB_TXN *txn; u_int32_t flags; { DB_THREAD_INFO *ip; ENV *env; int ret, t_ret; env = txn->mgrp->env; ENV_ENTER(env, ip); ret = __txn_discard_int(txn, flags); if (IS_ENV_REPLICATED(env) && (t_ret = __op_rep_exit(env)) != 0 && ret == 0) ret = t_ret; ENV_LEAVE(env, ip); return (ret); } /* * __txn_discard -- * Free the per-process resources associated with this txn handle. * * PUBLIC: int __txn_discard_int __P((DB_TXN *, u_int32_t flags)); */ int __txn_discard_int(txn, flags) DB_TXN *txn; u_int32_t flags; { DB_TXN *freep; DB_TXNMGR *mgr; ENV *env; int ret; COMPQUIET(flags, 0); mgr = txn->mgrp; env = mgr->env; freep = NULL; if ((ret = __txn_isvalid(txn, TXN_OP_DISCARD)) != 0) return (ret); /* Should be no children. */ DB_ASSERT(env, TAILQ_FIRST(&txn->kids) == NULL); /* Free the space. */ MUTEX_LOCK(env, mgr->mutex); mgr->n_discards++; if (F_ISSET(txn, TXN_MALLOC)) { TAILQ_REMOVE(&mgr->txn_chain, txn, links); freep = txn; } MUTEX_UNLOCK(env, mgr->mutex); if (freep != NULL) __os_free(env, freep); return (0); } /* * __txn_prepare -- * Flush the log so a future commit is guaranteed to succeed. * * PUBLIC: int __txn_prepare __P((DB_TXN *, u_int8_t *)); */ int __txn_prepare(txn, gid) DB_TXN *txn; u_int8_t *gid; { DBT list_dbt, xid; DB_LOCKREQ request; DB_THREAD_INFO *ip; DB_TXN *kid; ENV *env; TXN_DETAIL *td; u_int32_t lflags; int ret; env = txn->mgrp->env; td = txn->td; if ((ret = __txn_isvalid(txn, TXN_OP_PREPARE)) != 0) return (ret); if (F_ISSET(txn, TXN_DEADLOCK)) return (__db_txn_deadlock_err(env, txn)); ENV_ENTER(env, ip); /* Commit any unresolved children. */ while ((kid = TAILQ_FIRST(&txn->kids)) != NULL) if ((ret = __txn_commit(kid, DB_TXN_NOSYNC)) != 0) goto err; /* * In XA, the global transaction ID in the txn_detail structure is * already set; in a non-XA environment, we must set it here. XA * requires that the transaction be either ENDED or SUSPENDED when * prepare is called, so we know that if the xa_status isn't in one * of those states, then we are calling prepare directly and we need * to fill in the td->xid. */ if ((ret = __txn_doevents(env, txn, TXN_PREPARE, 1)) != 0) goto err; memset(&request, 0, sizeof(request)); if (LOCKING_ON(env)) { request.op = DB_LOCK_PUT_READ; if (!IS_ZERO_LSN(td->last_lsn)) { memset(&list_dbt, 0, sizeof(list_dbt)); request.obj = &list_dbt; } if ((ret = __lock_vec(env, txn->locker, 0, &request, 1, NULL)) != 0) goto err; } if (DBENV_LOGGING(env)) { memset(&xid, 0, sizeof(xid)); if (td->xa_status != TXN_XA_ENDED && td->xa_status != TXN_XA_SUSPENDED) /* Regular prepare; fill in the gid. */ memcpy(td->xid, gid, sizeof(td->xid)); xid.size = sizeof(td->xid); xid.data = td->xid; lflags = DB_LOG_COMMIT | DB_FLUSH; if ((ret = __txn_xa_regop_log(env, txn, &td->last_lsn, lflags, TXN_PREPARE, &xid, td->format, td->gtrid, td->bqual, &td->begin_lsn, request.obj)) != 0) __db_err( env, ret, "DB_TXN->prepare: log_write failed"); if (request.obj != NULL && request.obj->data != NULL) __os_free(env, request.obj->data); if (ret != 0) goto err; } MUTEX_LOCK(env, txn->mgrp->mutex); td->status = TXN_PREPARED; MUTEX_UNLOCK(env, txn->mgrp->mutex); err: ENV_LEAVE(env, ip); return (ret); } /* * __txn_id -- * Return the transaction ID. * * PUBLIC: u_int32_t __txn_id __P((DB_TXN *)); */ u_int32_t __txn_id(txn) DB_TXN *txn; { return (txn->txnid); } /* * __txn_get_name -- * Get a descriptive string from a transaction. * * PUBLIC: int __txn_get_name __P((DB_TXN *, const char **)); */ int __txn_get_name(txn, namep) DB_TXN *txn; const char **namep; { *namep = txn->name; return (0); } /* * __txn_set_name -- * Set a descriptive string for a transaction. * * PUBLIC: int __txn_set_name __P((DB_TXN *, const char *)); */ int __txn_set_name(txn, name) DB_TXN *txn; const char *name; { DB_THREAD_INFO *ip; DB_TXNMGR *mgr; ENV *env; TXN_DETAIL *td; size_t len; int ret; char *p; mgr = txn->mgrp; env = mgr->env; td = txn->td; len = strlen(name) + 1; if ((ret = __os_realloc(env, len, &txn->name)) != 0) return (ret); memcpy(txn->name, name, len); ENV_ENTER(env, ip); TXN_SYSTEM_LOCK(env); if (td->name != INVALID_ROFF) { __env_alloc_free( &mgr->reginfo, R_ADDR(&mgr->reginfo, td->name)); td->name = INVALID_ROFF; } if ((ret = __env_alloc(&mgr->reginfo, len, &p)) != 0) { TXN_SYSTEM_UNLOCK(env); __db_errx(env, "Unable to allocate memory for transaction name"); __os_free(env, txn->name); txn->name = NULL; ENV_LEAVE(env, ip); return (ret); } TXN_SYSTEM_UNLOCK(env); td->name = R_OFFSET(&mgr->reginfo, p); memcpy(p, name, len); #ifdef DIAGNOSTIC /* * If DIAGNOSTIC is set, map the name into the log so users can track * operations through the log. */ if (DBENV_LOGGING(env)) (void)__log_printf(env, txn, "transaction %#lx named %s", (u_long)txn->txnid, name); #endif ENV_LEAVE(env, ip); return (0); } /* * __txn_set_timeout -- * ENV->set_txn_timeout. * PUBLIC: int __txn_set_timeout __P((DB_TXN *, db_timeout_t, u_int32_t)); */ int __txn_set_timeout(txn, timeout, op) DB_TXN *txn; db_timeout_t timeout; u_int32_t op; { DB_THREAD_INFO *ip; ENV *env; int ret; env = txn->mgrp->env; if (op != DB_SET_TXN_TIMEOUT && op != DB_SET_LOCK_TIMEOUT) return (__db_ferr(env, "DB_TXN->set_timeout", 0)); ENV_ENTER(env, ip); ret = __lock_set_timeout( env, txn->locker, timeout, op); ENV_LEAVE(txn->mgrp->env, ip); return (ret); } /* * __txn_isvalid -- * Return 0 if the DB_TXN is reasonable, otherwise panic. */ static int __txn_isvalid(txn, op) const DB_TXN *txn; txnop_t op; { DB_TXNMGR *mgr; DB_TXNREGION *region; ENV *env; TXN_DETAIL *td; mgr = txn->mgrp; env = mgr->env; region = mgr->reginfo.primary; /* Check for recovery. */ if (!F_ISSET(txn, TXN_COMPENSATE) && F_ISSET(region, TXN_IN_RECOVERY)) { __db_errx(env, "operation not permitted during recovery"); goto err; } /* Check for live cursors. */ if (txn->cursors != 0) { __db_errx(env, "transaction has active cursors"); goto err; } /* Check transaction's state. */ td = txn->td; /* Handle any operation specific checks. */ switch (op) { case TXN_OP_DISCARD: /* * Since we're just tossing the per-process space; there are * a lot of problems with the transaction that we can tolerate. */ /* Transaction is already been reused. */ if (txn->txnid != td->txnid) return (0); /* * What we've got had better be either a prepared or * restored transaction. */ if (td->status != TXN_PREPARED && !F_ISSET(td, TXN_DTL_RESTORED)) { __db_errx(env, "not a restored transaction"); return (__env_panic(env, EINVAL)); } return (0); case TXN_OP_PREPARE: if (txn->parent != NULL) { /* * This is not fatal, because you could imagine an * application that simply prepares everybody because * it doesn't distinguish between children and parents. * I'm not arguing this is good, but I could imagine * someone doing it. */ __db_errx(env, "Prepare disallowed on child transactions"); return (EINVAL); } break; case TXN_OP_ABORT: case TXN_OP_COMMIT: default: break; } switch (td->status) { case TXN_PREPARED: if (op == TXN_OP_PREPARE) { __db_errx(env, "transaction already prepared"); /* * Txn_prepare doesn't blow away the user handle, so * in this case, give the user the opportunity to * abort or commit. */ return (EINVAL); } break; case TXN_RUNNING: break; case TXN_ABORTED: case TXN_COMMITTED: default: __db_errx(env, "transaction already %s", td->status == TXN_COMMITTED ? "committed" : "aborted"); goto err; } return (0); err: /* * If there's a serious problem with the transaction, panic. TXN * handles are dead by definition when we return, and if you use * a cursor you forgot to close, we have no idea what will happen. */ return (__env_panic(env, EINVAL)); } /* * __txn_end -- * Internal transaction end routine. */ static int __txn_end(txn, is_commit) DB_TXN *txn; int is_commit; { DB_LOCKREQ request; DB_TXNLOGREC *lr; DB_TXNMGR *mgr; DB_TXNREGION *region; ENV *env; TXN_DETAIL *ptd, *td; db_mutex_t mvcc_mtx; int do_closefiles, ret; mgr = txn->mgrp; env = mgr->env; region = mgr->reginfo.primary; do_closefiles = 0; /* Process commit events. */ if ((ret = __txn_doevents(env, txn, is_commit ? TXN_COMMIT : TXN_ABORT, 0)) != 0) return (__env_panic(env, ret)); /* * Release the locks. * * __txn_end cannot return an simple error, we MUST return * success/failure from commit or abort, ignoring any internal * errors. So, we panic if something goes wrong. We can't * deadlock here because we're not acquiring any new locks, * so DB_LOCK_DEADLOCK is just as fatal as any other error. */ if (LOCKING_ON(env)) { /* Allocate a locker for this restored txn if necessary. */ if (txn->locker == NULL && (ret = __lock_getlocker(env->lk_handle, txn->txnid, 1, &txn->locker)) != 0) return (__env_panic(env, ret)); request.op = txn->parent == NULL || is_commit == 0 ? DB_LOCK_PUT_ALL : DB_LOCK_INHERIT; request.obj = NULL; if ((ret = __lock_vec(env, txn->locker, 0, &request, 1, NULL)) != 0) return (__env_panic(env, ret)); } /* End the transaction. */ td = txn->td; if (td->nlog_dbs != 0 && (ret = __txn_dref_fname(env, txn)) != 0) return (__env_panic(env, ret)); if (td->mvcc_ref != 0 && IS_MAX_LSN(td->visible_lsn)) { DB_ASSERT(env, !is_commit); /* * In the abort path, we need to make sure that the versions * become visible to future transactions. We need to set * visible_lsn before setting td->status to ensure safe reads * of visible_lsn in __memp_fget. */ if ((ret = __log_current_lsn(env, &td->visible_lsn, NULL, NULL)) != 0) return (__env_panic(env, ret)); } TXN_SYSTEM_LOCK(env); td->status = is_commit ? TXN_COMMITTED : TXN_ABORTED; SH_TAILQ_REMOVE(®ion->active_txn, td, links, __txn_detail); if (F_ISSET(td, TXN_DTL_RESTORED)) { region->stat.st_nrestores--; do_closefiles = region->stat.st_nrestores == 0; } if (td->name != INVALID_ROFF) { __env_alloc_free( &mgr->reginfo, R_ADDR(&mgr->reginfo, td->name)); td->name = INVALID_ROFF; } if (txn->parent != NULL) { ptd = txn->parent->td; SH_TAILQ_REMOVE(&ptd->kids, td, klinks, __txn_detail); } else if ((mvcc_mtx = td->mvcc_mtx) != MUTEX_INVALID) { MUTEX_LOCK(env, mvcc_mtx); if (td->mvcc_ref != 0) { SH_TAILQ_INSERT_HEAD(®ion->mvcc_txn, td, links, __txn_detail); #ifdef HAVE_STATISTICS if (++region->stat.st_nsnapshot > region->stat.st_maxnsnapshot) region->stat.st_maxnsnapshot = region->stat.st_nsnapshot; #endif td = NULL; } MUTEX_UNLOCK(env, mvcc_mtx); if (td != NULL) if ((ret = __mutex_free(env, &td->mvcc_mtx)) != 0) return (__env_panic(env, ret)); } if (td != NULL) { if (td->nlog_slots != TXN_NSLOTS) __env_alloc_free(&mgr->reginfo, R_ADDR(&mgr->reginfo, td->log_dbs)); __env_alloc_free(&mgr->reginfo, td); } #ifdef HAVE_STATISTICS if (is_commit) region->stat.st_ncommits++; else region->stat.st_naborts++; --region->stat.st_nactive; #endif TXN_SYSTEM_UNLOCK(env); /* * The transaction cannot get more locks, remove its locker info, * if any. */ if (LOCKING_ON(env) && (ret = __lock_freefamilylocker(env->lk_handle, txn->locker)) != 0) return (__env_panic(env, ret)); if (txn->parent != NULL) TAILQ_REMOVE(&txn->parent->kids, txn, klinks); /* Free the space. */ while ((lr = STAILQ_FIRST(&txn->logs)) != NULL) { STAILQ_REMOVE(&txn->logs, lr, __txn_logrec, links); __os_free(env, lr); } if (txn->name != NULL) { __os_free(env, txn->name); txn->name = NULL; } if (F_ISSET(txn, TXN_MALLOC)) { MUTEX_LOCK(env, mgr->mutex); TAILQ_REMOVE(&mgr->txn_chain, txn, links); MUTEX_UNLOCK(env, mgr->mutex); __os_free(env, txn); } if (do_closefiles) { /* * Otherwise, we have resolved the last outstanding prepared * txn and need to invalidate the fileids that were left * open for those txns and then close them. */ (void)__dbreg_invalidate_files(env, 1); (void)__dbreg_close_files(env, 1); if (IS_REP_MASTER(env)) F_CLR(env->rep_handle, DBREP_OPENFILES); F_CLR(env->lg_handle, DBLOG_OPENFILES); mgr->n_discards = 0; (void)__txn_checkpoint(env, 0, 0, DB_CKP_INTERNAL | DB_FORCE); } return (0); } static int __txn_dispatch_undo(env, txn, rdbt, key_lsn, txnlist) ENV *env; DB_TXN *txn; DBT *rdbt; DB_LSN *key_lsn; DB_TXNHEAD *txnlist; { int ret; txnlist->td = txn->td; ret = __db_dispatch(env, &env->recover_dtab, rdbt, key_lsn, DB_TXN_ABORT, txnlist); if (ret == DB_SURPRISE_KID) { F_SET(txn, TXN_CHILDCOMMIT); ret = 0; } if (ret == 0 && F_ISSET(txn, TXN_CHILDCOMMIT) && IS_ZERO_LSN(*key_lsn)) ret = __db_txnlist_lsnget(env, txnlist, key_lsn, 0); return (ret); } /* * __txn_undo -- * Undo the transaction with id txnid. */ static int __txn_undo(txn) DB_TXN *txn; { DBT rdbt; DB_LOGC *logc; DB_LSN key_lsn; DB_TXN *ptxn; DB_TXNHEAD *txnlist; DB_TXNLOGREC *lr; DB_TXNMGR *mgr; ENV *env; int ret, t_ret; mgr = txn->mgrp; env = mgr->env; logc = NULL; txnlist = NULL; ret = 0; if (!LOGGING_ON(env)) return (0); /* * This is the simplest way to code this, but if the mallocs during * recovery turn out to be a performance issue, we can do the * allocation here and use DB_DBT_USERMEM. */ memset(&rdbt, 0, sizeof(rdbt)); /* * Allocate a txnlist for children and aborted page allocs. * We need to associate the list with the maximal parent * so that aborted pages are recovered when that transaction * is committed or aborted. */ for (ptxn = txn->parent; ptxn != NULL && ptxn->parent != NULL;) ptxn = ptxn->parent; if (ptxn != NULL && ptxn->txn_list != NULL) txnlist = ptxn->txn_list; else if (txn->txn_list != NULL) txnlist = txn->txn_list; else if ((ret = __db_txnlist_init(env, txn->thread_info, 0, 0, NULL, &txnlist)) != 0) return (ret); else if (ptxn != NULL) ptxn->txn_list = txnlist; /* * Take log records from the linked list stored in the transaction, * then from the log. */ STAILQ_FOREACH(lr, &txn->logs, links) { rdbt.data = lr->data; rdbt.size = 0; LSN_NOT_LOGGED(key_lsn); ret = __txn_dispatch_undo(env, txn, &rdbt, &key_lsn, txnlist); if (ret != 0) { __db_err(env, ret, "DB_TXN->abort: in-memory log undo failed"); goto err; } } key_lsn = ((TXN_DETAIL *)txn->td)->last_lsn; if (!IS_ZERO_LSN(key_lsn) && (ret = __log_cursor(env, &logc)) != 0) goto err; while (!IS_ZERO_LSN(key_lsn)) { /* * The dispatch routine returns the lsn of the record * before the current one in the key_lsn argument. */ if ((ret = __logc_get(logc, &key_lsn, &rdbt, DB_SET)) == 0) { ret = __txn_dispatch_undo(env, txn, &rdbt, &key_lsn, txnlist); } if (ret != 0) { __db_err(env, ret, "DB_TXN->abort: log undo failed for LSN: %lu %lu", (u_long)key_lsn.file, (u_long)key_lsn.offset); goto err; } } err: if (logc != NULL && (t_ret = __logc_close(logc)) != 0 && ret == 0) ret = t_ret; if (ptxn == NULL && txnlist != NULL) __db_txnlist_end(env, txnlist); return (ret); } /* * __txn_activekids -- * Return if this transaction has any active children. * * PUBLIC: int __txn_activekids __P((ENV *, u_int32_t, DB_TXN *)); */ int __txn_activekids(env, rectype, txn) ENV *env; u_int32_t rectype; DB_TXN *txn; { /* * On a child commit, we know that there are children (i.e., the * committing child at the least. In that case, skip this check. */ if (F_ISSET(txn, TXN_COMPENSATE) || rectype == DB___txn_child) return (0); if (TAILQ_FIRST(&txn->kids) != NULL) { __db_errx(env, "Child transaction is active"); return (EPERM); } return (0); } /* * __txn_force_abort -- * Force an abort record into the log if the commit record * failed to get to disk. * * PUBLIC: int __txn_force_abort __P((ENV *, u_int8_t *)); */ int __txn_force_abort(env, buffer) ENV *env; u_int8_t *buffer; { DB_CIPHER *db_cipher; HDR hdr, *hdrp; u_int32_t offset, opcode, sum_len; u_int8_t *bp, *key, chksum[DB_MAC_KEY]; size_t hdrsize, rec_len; int ret; db_cipher = env->crypto_handle; /* * This routine depends on the layout of HDR and the __txn_regop * __txn_xa_regop records in txn.src. We are passed the beginning * of the commit record in the log buffer and overwrite the * commit with an abort and recalculate the checksum. */ hdrsize = CRYPTO_ON(env) ? HDR_CRYPTO_SZ : HDR_NORMAL_SZ; hdrp = (HDR *)buffer; memcpy(&hdr.prev, buffer + SSZ(HDR, prev), sizeof(hdr.prev)); memcpy(&hdr.len, buffer + SSZ(HDR, len), sizeof(hdr.len)); rec_len = hdr.len - hdrsize; offset = sizeof(u_int32_t) + sizeof(u_int32_t) + sizeof(DB_LSN); if (CRYPTO_ON(env)) { key = db_cipher->mac_key; sum_len = DB_MAC_KEY; if ((ret = db_cipher->decrypt(env, db_cipher->data, &hdrp->iv[0], buffer + hdrsize, rec_len)) != 0) return (__env_panic(env, ret)); } else { key = NULL; sum_len = sizeof(u_int32_t); } bp = buffer + hdrsize + offset; opcode = TXN_ABORT; memcpy(bp, &opcode, sizeof(opcode)); if (CRYPTO_ON(env) && (ret = db_cipher->encrypt(env, db_cipher->data, &hdrp->iv[0], buffer + hdrsize, rec_len)) != 0) return (__env_panic(env, ret)); __db_chksum(&hdr, buffer + hdrsize, rec_len, key, chksum); memcpy(buffer + SSZA(HDR, chksum), chksum, sum_len); return (0); } /* * __txn_preclose -- * Before we can close an environment, we need to check if we were in the * middle of taking care of restored transactions. If so, close the files * we opened. * * PUBLIC: int __txn_preclose __P((ENV *)); */ int __txn_preclose(env) ENV *env; { DB_TXNMGR *mgr; DB_TXNREGION *region; int do_closefiles, ret; mgr = env->tx_handle; region = mgr->reginfo.primary; do_closefiles = 0; TXN_SYSTEM_LOCK(env); if (region != NULL && region->stat.st_nrestores <= mgr->n_discards && mgr->n_discards != 0) do_closefiles = 1; TXN_SYSTEM_UNLOCK(env); if (do_closefiles) { /* * Set the DBLOG_RECOVER flag while closing these files so they * do not create additional log records that will confuse future * recoveries. */ F_SET(env->lg_handle, DBLOG_RECOVER); ret = __dbreg_close_files(env, 0); F_CLR(env->lg_handle, DBLOG_RECOVER); } else ret = 0; return (ret); } /* * __txn_reset -- * Reset the last txnid to its minimum value, and log the reset. * * PUBLIC: int __txn_reset __P((ENV *)); */ int __txn_reset(env) ENV *env; { DB_LSN scrap; DB_TXNREGION *region; region = env->tx_handle->reginfo.primary; region->last_txnid = TXN_MINIMUM; DB_ASSERT(env, LOGGING_ON(env)); return (__txn_recycle_log(env, NULL, &scrap, 0, TXN_MINIMUM, TXN_MAXIMUM)); } /* * txn_set_txn_lsnp -- * Set the pointer to the begin_lsn field if that field is zero. * Set the pointer to the last_lsn field. */ static void __txn_set_txn_lsnp(txn, blsnp, llsnp) DB_TXN *txn; DB_LSN **blsnp, **llsnp; { TXN_DETAIL *td; td = txn->td; *llsnp = &td->last_lsn; while (txn->parent != NULL) txn = txn->parent; td = txn->td; if (IS_ZERO_LSN(td->begin_lsn)) *blsnp = &td->begin_lsn; }