/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1997,2008 Oracle. All rights reserved. * * $Id: bt_recno.c,v 12.40 2008/02/12 16:42:54 bschmeck Exp $ */ #include "db_config.h" #include "db_int.h" #include "dbinc/db_page.h" #include "dbinc/btree.h" #include "dbinc/lock.h" #include "dbinc/mp.h" static int __ram_add __P((DBC *, db_recno_t *, DBT *, u_int32_t, u_int32_t)); static int __ram_source __P((DB *)); static int __ram_sread __P((DBC *, db_recno_t)); static int __ram_update __P((DBC *, db_recno_t, int)); /* * In recno, there are two meanings to the on-page "deleted" flag. If we're * re-numbering records, it means the record was implicitly created. We skip * over implicitly created records if doing a cursor "next" or "prev", and * return DB_KEYEMPTY if they're explicitly requested.. If not re-numbering * records, it means that the record was implicitly created, or was deleted. * We skip over implicitly created or deleted records if doing a cursor "next" * or "prev", and return DB_KEYEMPTY if they're explicitly requested. * * If we're re-numbering records, then we have to detect in the cursor that * a record was deleted, and adjust the cursor as necessary on the next get. * If we're not re-numbering records, then we can detect that a record has * been deleted by looking at the actual on-page record, so we completely * ignore the cursor's delete flag. This is different from the B+tree code. * It also maintains whether the cursor references a deleted record in the * cursor, and it doesn't always check the on-page value. */ #define CD_SET(cp) { \ if (F_ISSET(cp, C_RENUMBER)) \ F_SET(cp, C_DELETED); \ } #define CD_CLR(cp) { \ if (F_ISSET(cp, C_RENUMBER)) { \ F_CLR(cp, C_DELETED); \ cp->order = INVALID_ORDER; \ } \ } #define CD_ISSET(cp) \ (F_ISSET(cp, C_RENUMBER) && F_ISSET(cp, C_DELETED) ? 1 : 0) /* * Macros for comparing the ordering of two cursors. * cp1 comes before cp2 iff one of the following holds: * cp1's recno is less than cp2's recno * recnos are equal, both deleted, and cp1's order is less than cp2's * recnos are equal, cp1 deleted, and cp2 not deleted */ #define C_LESSTHAN(cp1, cp2) \ (((cp1)->recno < (cp2)->recno) || \ (((cp1)->recno == (cp2)->recno) && \ ((CD_ISSET((cp1)) && CD_ISSET((cp2)) && (cp1)->order < (cp2)->order) || \ (CD_ISSET((cp1)) && !CD_ISSET((cp2)))))) /* * cp1 is equal to cp2 iff their recnos and delete flags are identical, * and if the delete flag is set their orders are also identical. */ #define C_EQUAL(cp1, cp2) \ ((cp1)->recno == (cp2)->recno && CD_ISSET((cp1)) == CD_ISSET((cp2)) && \ (!CD_ISSET((cp1)) || (cp1)->order == (cp2)->order)) /* * Do we need to log the current cursor adjustment? */ #define CURADJ_LOG(dbc) \ (DBC_LOGGING((dbc)) && (dbc)->txn != NULL && (dbc)->txn->parent != NULL) /* * After a search, copy the found page into the cursor, discarding any * currently held lock. */ #define STACK_TO_CURSOR(cp, ret) { \ int __t_ret; \ (cp)->page = (cp)->csp->page; \ (cp)->pgno = (cp)->csp->page->pgno; \ (cp)->indx = (cp)->csp->indx; \ if ((__t_ret = __TLPUT(dbc, (cp)->lock)) != 0 && (ret) == 0) \ ret = __t_ret; \ (cp)->lock = (cp)->csp->lock; \ (cp)->lock_mode = (cp)->csp->lock_mode; \ } /* * __ram_open -- * Recno open function. * * PUBLIC: int __ram_open __P((DB *, DB_THREAD_INFO *, * PUBLIC: DB_TXN *, const char *, db_pgno_t, u_int32_t)); */ int __ram_open(dbp, ip, txn, name, base_pgno, flags) DB *dbp; DB_THREAD_INFO *ip; DB_TXN *txn; const char *name; db_pgno_t base_pgno; u_int32_t flags; { BTREE *t; DBC *dbc; int ret, t_ret; COMPQUIET(name, NULL); t = dbp->bt_internal; /* Start up the tree. */ if ((ret = __bam_read_root(dbp, ip, txn, base_pgno, flags)) != 0) return (ret); /* * If the user specified a source tree, open it and map it in. * * !!! * We don't complain if the user specified transactions or threads. * It's possible to make it work, but you'd better know what you're * doing! */ if (t->re_source != NULL && (ret = __ram_source(dbp)) != 0) return (ret); /* If we're snapshotting an underlying source file, do it now. */ if (F_ISSET(dbp, DB_AM_SNAPSHOT)) { /* Allocate a cursor. */ if ((ret = __db_cursor(dbp, ip, NULL, &dbc, 0)) != 0) return (ret); /* Do the snapshot. */ if ((ret = __ram_update(dbc, DB_MAX_RECORDS, 0)) != 0 && ret == DB_NOTFOUND) ret = 0; /* Discard the cursor. */ if ((t_ret = __dbc_close(dbc)) != 0 && ret == 0) ret = t_ret; } return (ret); } /* * __ram_append -- * Recno append function. * * PUBLIC: int __ram_append __P((DBC *, DBT *, DBT *)); */ int __ram_append(dbc, key, data) DBC *dbc; DBT *key, *data; { BTREE_CURSOR *cp; int ret; cp = (BTREE_CURSOR *)dbc->internal; /* * Make sure we've read in all of the backing source file. If * we found the record or it simply didn't exist, add the * user's record. */ ret = __ram_update(dbc, DB_MAX_RECORDS, 0); if (ret == 0 || ret == DB_NOTFOUND) ret = __ram_add(dbc, &cp->recno, data, DB_APPEND, 0); /* Return the record number. */ if (ret == 0 && key != NULL) ret = __db_retcopy(dbc->env, key, &cp->recno, sizeof(cp->recno), &dbc->rkey->data, &dbc->rkey->ulen); return (ret); } /* * __ramc_del -- * Recno DBC->del function. * * PUBLIC: int __ramc_del __P((DBC *)); */ int __ramc_del(dbc) DBC *dbc; { BKEYDATA bk; BTREE *t; BTREE_CURSOR *cp; DB *dbp; DBT hdr, data; DB_LSN lsn; int exact, nc, ret, stack, t_ret; dbp = dbc->dbp; cp = (BTREE_CURSOR *)dbc->internal; t = dbp->bt_internal; stack = 0; /* * The semantics of cursors during delete are as follows: in * non-renumbering recnos, records are replaced with a marker * containing a delete flag. If the record referenced by this cursor * has already been deleted, we will detect that as part of the delete * operation, and fail. * * In renumbering recnos, cursors which represent deleted items * are flagged with the C_DELETED flag, and it is an error to * call c_del a second time without an intervening cursor motion. */ if (CD_ISSET(cp)) return (DB_KEYEMPTY); /* Search the tree for the key; delete only deletes exact matches. */ if ((ret = __bam_rsearch(dbc, &cp->recno, SR_DELETE, 1, &exact)) != 0) goto err; if (!exact) { ret = DB_NOTFOUND; goto err; } stack = 1; /* Copy the page into the cursor. */ if ((ret = __memp_dirty(dbp->mpf, &cp->csp->page, dbc->thread_info, dbc->txn, dbc->priority, 0)) != 0) goto err; STACK_TO_CURSOR(cp, ret); if (ret != 0) goto err; /* * If re-numbering records, the on-page deleted flag can only mean * that this record was implicitly created. Applications aren't * permitted to delete records they never created, return an error. * * If not re-numbering records, the on-page deleted flag means that * this record was implicitly created, or, was deleted at some time. * The former is an error because applications aren't permitted to * delete records they never created, the latter is an error because * if the record was "deleted", we could never have found it. */ if (B_DISSET(GET_BKEYDATA(dbp, cp->page, cp->indx)->type)) { ret = DB_KEYEMPTY; goto err; } if (F_ISSET(cp, C_RENUMBER)) { /* Delete the item, adjust the counts, adjust the cursors. */ if ((ret = __bam_ditem(dbc, cp->page, cp->indx)) != 0) goto err; if ((ret = __bam_adjust(dbc, -1)) != 0) goto err; if ((ret = __ram_ca(dbc, CA_DELETE, &nc)) != 0) goto err; if (nc > 0 && CURADJ_LOG(dbc) && (ret = __bam_rcuradj_log(dbp, dbc->txn, &lsn, 0, CA_DELETE, cp->root, cp->recno, cp->order)) != 0) goto err; /* * If the page is empty, delete it. * * We never delete a root page. First, root pages of primary * databases never go away, recno or otherwise. However, if * it's the root page of an off-page duplicates database, then * it can be deleted. We don't delete it here because we have * no way of telling the primary database page holder (e.g., * the hash access method) that its page element should cleaned * up because the underlying tree is gone. So, we keep the page * around until the last cursor referencing the empty tree is * are closed, and then clean it up. */ if (NUM_ENT(cp->page) == 0 && PGNO(cp->page) != cp->root) { /* * We want to delete a single item out of the last page * that we're not deleting. */ ret = __bam_dpages(dbc, 0, 0); /* * Regardless of the return from __bam_dpages, it will * discard our stack and pinned page. */ stack = 0; cp->page = NULL; } } else { /* Use a delete/put pair to replace the record with a marker. */ if ((ret = __bam_ditem(dbc, cp->page, cp->indx)) != 0) goto err; B_TSET_DELETED(bk.type, B_KEYDATA); bk.len = 0; DB_INIT_DBT(hdr, &bk, SSZA(BKEYDATA, data)); DB_INIT_DBT(data, "", 0); if ((ret = __db_pitem(dbc, cp->page, cp->indx, BKEYDATA_SIZE(0), &hdr, &data)) != 0) goto err; } t->re_modified = 1; err: if (stack && (t_ret = __bam_stkrel(dbc, STK_CLRDBC)) != 0 && ret == 0) ret = t_ret; return (ret); } /* * __ramc_get -- * Recno DBC->get function. * * PUBLIC: int __ramc_get * PUBLIC: __P((DBC *, DBT *, DBT *, u_int32_t, db_pgno_t *)); */ int __ramc_get(dbc, key, data, flags, pgnop) DBC *dbc; DBT *key, *data; u_int32_t flags; db_pgno_t *pgnop; { BTREE_CURSOR *cp; DB *dbp; int cmp, exact, ret; COMPQUIET(pgnop, NULL); dbp = dbc->dbp; cp = (BTREE_CURSOR *)dbc->internal; LF_CLR(DB_MULTIPLE|DB_MULTIPLE_KEY); retry: switch (flags) { case DB_CURRENT: /* * If we're using mutable records and the deleted flag is * set, the cursor is pointing at a nonexistent record; * return an error. */ if (CD_ISSET(cp)) return (DB_KEYEMPTY); break; case DB_NEXT_DUP: /* * If we're not in an off-page dup set, we know there's no * next duplicate since recnos don't have them. If we * are in an off-page dup set, the next item assuredly is * a dup, so we set flags to DB_NEXT and keep going. */ if (!F_ISSET(dbc, DBC_OPD)) return (DB_NOTFOUND); /* FALLTHROUGH */ case DB_NEXT_NODUP: /* * Recno databases don't have duplicates, set flags to DB_NEXT * and keep going. */ /* FALLTHROUGH */ case DB_NEXT: flags = DB_NEXT; /* * If record numbers are mutable: if we just deleted a record, * we have to avoid incrementing the record number so that we * return the right record by virtue of renumbering the tree. */ if (CD_ISSET(cp)) { /* * Clear the flag, we've moved off the deleted record. */ CD_CLR(cp); break; } if (cp->recno != RECNO_OOB) { ++cp->recno; break; } /* FALLTHROUGH */ case DB_FIRST: flags = DB_NEXT; cp->recno = 1; break; case DB_PREV_DUP: /* * If we're not in an off-page dup set, we know there's no * previous duplicate since recnos don't have them. If we * are in an off-page dup set, the previous item assuredly * is a dup, so we set flags to DB_PREV and keep going. */ if (!F_ISSET(dbc, DBC_OPD)) return (DB_NOTFOUND); /* FALLTHROUGH */ case DB_PREV_NODUP: /* * Recno databases don't have duplicates, set flags to DB_PREV * and keep going. */ /* FALLTHROUGH */ case DB_PREV: flags = DB_PREV; if (cp->recno != RECNO_OOB) { if (cp->recno == 1) { ret = DB_NOTFOUND; goto err; } --cp->recno; break; } /* FALLTHROUGH */ case DB_LAST: flags = DB_PREV; if (((ret = __ram_update(dbc, DB_MAX_RECORDS, 0)) != 0) && ret != DB_NOTFOUND) goto err; if ((ret = __bam_nrecs(dbc, &cp->recno)) != 0) goto err; if (cp->recno == 0) { ret = DB_NOTFOUND; goto err; } break; case DB_GET_BOTHC: /* * If we're doing a join and these are offpage dups, * we want to keep searching forward from after the * current cursor position. Increment the recno by 1, * then proceed as for a DB_SET. * * Otherwise, we know there are no additional matching * data, as recnos don't have dups. return DB_NOTFOUND. */ if (F_ISSET(dbc, DBC_OPD)) { cp->recno++; break; } ret = DB_NOTFOUND; goto err; /* NOTREACHED */ case DB_GET_BOTH: case DB_GET_BOTH_RANGE: /* * If we're searching a set of off-page dups, we start * a new linear search from the first record. Otherwise, * we compare the single data item associated with the * requested record for a match. */ if (F_ISSET(dbc, DBC_OPD)) { cp->recno = 1; break; } /* FALLTHROUGH */ case DB_SET: case DB_SET_RANGE: if ((ret = __ram_getno(dbc, key, &cp->recno, 0)) != 0) goto err; break; default: ret = __db_unknown_flag(dbp->env, "__ramc_get", flags); goto err; } /* * For DB_PREV, DB_LAST, DB_SET and DB_SET_RANGE, we have already * called __ram_update() to make sure sufficient records have been * read from the backing source file. Do it now for DB_CURRENT (if * the current record was deleted we may need more records from the * backing file for a DB_CURRENT operation), DB_FIRST and DB_NEXT. * (We don't have to test for flags == DB_FIRST, because the switch * statement above re-set flags to DB_NEXT in that case.) */ if ((flags == DB_NEXT || flags == DB_CURRENT) && ((ret = __ram_update(dbc, cp->recno, 0)) != 0) && ret != DB_NOTFOUND) goto err; for (;; ++cp->recno) { /* Search the tree for the record. */ if ((ret = __bam_rsearch(dbc, &cp->recno, F_ISSET(dbc, DBC_RMW) ? SR_FIND_WR : SR_FIND, 1, &exact)) != 0) goto err; if (!exact) { ret = DB_NOTFOUND; goto err; } /* Copy the page into the cursor. */ STACK_TO_CURSOR(cp, ret); if (ret != 0) goto err; /* * If re-numbering records, the on-page deleted flag means this * record was implicitly created. If not re-numbering records, * the on-page deleted flag means this record was implicitly * created, or, it was deleted at some time. Regardless, we * skip such records if doing cursor next/prev operations or * walking through off-page duplicates, and fail if they were * requested explicitly by the application. */ if (B_DISSET(GET_BKEYDATA(dbp, cp->page, cp->indx)->type)) switch (flags) { case DB_NEXT: case DB_PREV: (void)__bam_stkrel(dbc, STK_CLRDBC); goto retry; case DB_GET_BOTH: case DB_GET_BOTH_RANGE: /* * If we're an OPD tree, we don't care about * matching a record number on a DB_GET_BOTH * -- everything belongs to the same tree. A * normal recno should give up and return * DB_NOTFOUND if the matching recno is deleted. */ if (F_ISSET(dbc, DBC_OPD)) { (void)__bam_stkrel(dbc, STK_CLRDBC); continue; } ret = DB_NOTFOUND; goto err; default: ret = DB_KEYEMPTY; goto err; } if (flags == DB_GET_BOTH || flags == DB_GET_BOTHC || flags == DB_GET_BOTH_RANGE) { if ((ret = __bam_cmp(dbp, dbc->thread_info, dbc->txn, data, cp->page, cp->indx, __bam_defcmp, &cmp)) != 0) return (ret); if (cmp == 0) break; if (!F_ISSET(dbc, DBC_OPD)) { ret = DB_NOTFOUND; goto err; } (void)__bam_stkrel(dbc, STK_CLRDBC); } else break; } /* Return the key if the user didn't give us one. */ if (!F_ISSET(dbc, DBC_OPD) && !F_ISSET(key, DB_DBT_ISSET)) { ret = __db_retcopy(dbp->env, key, &cp->recno, sizeof(cp->recno), &dbc->rkey->data, &dbc->rkey->ulen); F_SET(key, DB_DBT_ISSET); } /* The cursor was reset, no further delete adjustment is necessary. */ err: CD_CLR(cp); return (ret); } /* * __ramc_put -- * Recno DBC->put function. * * PUBLIC: int __ramc_put __P((DBC *, DBT *, DBT *, u_int32_t, db_pgno_t *)); */ int __ramc_put(dbc, key, data, flags, pgnop) DBC *dbc; DBT *key, *data; u_int32_t flags; db_pgno_t *pgnop; { BTREE_CURSOR *cp; DB *dbp; DB_LSN lsn; ENV *env; u_int32_t iiflags; int exact, nc, ret, t_ret; void *arg; COMPQUIET(pgnop, NULL); dbp = dbc->dbp; env = dbp->env; cp = (BTREE_CURSOR *)dbc->internal; /* * DB_KEYFIRST and DB_KEYLAST mean different things if they're * used in an off-page duplicate tree. If we're an off-page * duplicate tree, they really mean "put at the beginning of the * tree" and "put at the end of the tree" respectively, so translate * them to something else. */ if (F_ISSET(dbc, DBC_OPD)) switch (flags) { case DB_KEYFIRST: cp->recno = 1; flags = DB_BEFORE; break; case DB_KEYLAST: if ((ret = __ram_add(dbc, &cp->recno, data, DB_APPEND, 0)) != 0) return (ret); if (CURADJ_LOG(dbc) && (ret = __bam_rcuradj_log(dbp, dbc->txn, &lsn, 0, CA_ICURRENT, cp->root, cp->recno, cp->order)) != 0) return (ret); return (0); default: break; } /* * Handle normal DB_KEYFIRST/DB_KEYLAST; for a recno, which has * no duplicates, these are identical and mean "put the given * datum at the given recno". */ if (flags == DB_KEYFIRST || flags == DB_KEYLAST || flags == DB_NOOVERWRITE) { ret = __ram_getno(dbc, key, &cp->recno, 1); if (ret == 0 || ret == DB_NOTFOUND) ret = __ram_add(dbc, &cp->recno, data, flags, 0); return (ret); } /* * If we're putting with a cursor that's marked C_DELETED, we need to * take special care; the cursor doesn't "really" reference the item * corresponding to its current recno, but instead is "between" that * record and the current one. Translate the actual insert into * DB_BEFORE, and let the __ram_ca work out the gory details of what * should wind up pointing where. */ if (CD_ISSET(cp)) iiflags = DB_BEFORE; else iiflags = flags; split: if ((ret = __bam_rsearch(dbc, &cp->recno, SR_INSERT, 1, &exact)) != 0) goto err; /* * An inexact match is okay; it just means we're one record past the * end, which is reasonable if we're marked deleted. */ DB_ASSERT(env, exact || CD_ISSET(cp)); /* Copy the page into the cursor. */ STACK_TO_CURSOR(cp, ret); if (ret != 0) goto err; ret = __bam_iitem(dbc, key, data, iiflags, 0); t_ret = __bam_stkrel(dbc, STK_CLRDBC); if (t_ret != 0 && (ret == 0 || ret == DB_NEEDSPLIT)) ret = t_ret; else if (ret == DB_NEEDSPLIT) { arg = &cp->recno; if ((ret = __bam_split(dbc, arg, NULL)) != 0) goto err; goto split; } if (ret != 0) goto err; switch (flags) { /* Adjust the cursors. */ case DB_AFTER: if ((ret = __ram_ca(dbc, CA_IAFTER, &nc)) != 0) goto err; /* * We only need to adjust this cursor forward if we truly added * the item after the current recno, rather than remapping it * to DB_BEFORE. */ if (iiflags == DB_AFTER) ++cp->recno; /* Only log if __ram_ca found any relevant cursors. */ if (nc > 0 && CURADJ_LOG(dbc) && (ret = __bam_rcuradj_log(dbp, dbc->txn, &lsn, 0, CA_IAFTER, cp->root, cp->recno, cp->order)) != 0) goto err; break; case DB_BEFORE: if ((ret = __ram_ca(dbc, CA_IBEFORE, &nc)) != 0) goto err; --cp->recno; /* Only log if __ram_ca found any relevant cursors. */ if (nc > 0 && CURADJ_LOG(dbc) && (ret = __bam_rcuradj_log(dbp, dbc->txn, &lsn, 0, CA_IBEFORE, cp->root, cp->recno, cp->order)) != 0) goto err; break; case DB_CURRENT: /* * We only need to do an adjustment if we actually * added an item, which we only would have done if the * cursor was marked deleted. */ if (!CD_ISSET(cp)) break; /* Only log if __ram_ca found any relevant cursors. */ if ((ret = __ram_ca(dbc, CA_ICURRENT, &nc)) != 0) goto err; if (nc > 0 && CURADJ_LOG(dbc) && (ret = __bam_rcuradj_log(dbp, dbc->txn, &lsn, 0, CA_ICURRENT, cp->root, cp->recno, cp->order)) != 0) goto err; break; default: break; } /* Return the key if we've created a new record. */ if (!F_ISSET(dbc, DBC_OPD) && (flags == DB_AFTER || flags == DB_BEFORE) && key != NULL) ret = __db_retcopy(env, key, &cp->recno, sizeof(cp->recno), &dbc->rkey->data, &dbc->rkey->ulen); /* The cursor was reset, no further delete adjustment is necessary. */ err: CD_CLR(cp); return (ret); } /* * __ram_ca -- * Adjust cursors. Returns the number of relevant cursors. * * PUBLIC: int __ram_ca __P((DBC *, ca_recno_arg, int *)); */ int __ram_ca(dbc_arg, op, foundp) DBC *dbc_arg; ca_recno_arg op; int *foundp; { BTREE_CURSOR *cp, *cp_arg; DB *dbp, *ldbp; DBC *dbc; ENV *env; db_recno_t recno; u_int32_t order; int adjusted, found; dbp = dbc_arg->dbp; env = dbp->env; cp_arg = (BTREE_CURSOR *)dbc_arg->internal; recno = cp_arg->recno; /* * It only makes sense to adjust cursors if we're a renumbering * recno; we should only be called if this is one. */ DB_ASSERT(env, F_ISSET(cp_arg, C_RENUMBER)); MUTEX_LOCK(env, env->mtx_dblist); /* * Adjust the cursors. See the comment in __bam_ca_delete(). * * If we're doing a delete, we need to find the highest * order of any cursor currently pointing at this item, * so we can assign a higher order to the newly deleted * cursor. Unfortunately, this requires a second pass through * the cursor list. */ if (op == CA_DELETE) { FIND_FIRST_DB_MATCH(env, dbp, ldbp); for (order = 1; ldbp != NULL && ldbp->adj_fileid == dbp->adj_fileid; ldbp = TAILQ_NEXT(ldbp, dblistlinks)) { MUTEX_LOCK(env, dbp->mutex); TAILQ_FOREACH(dbc, &ldbp->active_queue, links) { cp = (BTREE_CURSOR *)dbc->internal; if (cp_arg->root == cp->root && recno == cp->recno && CD_ISSET(cp) && order <= cp->order && !MVCC_SKIP_CURADJ(dbc, cp->root)) order = cp->order + 1; } MUTEX_UNLOCK(env, dbp->mutex); } } else order = INVALID_ORDER; /* Now go through and do the actual adjustments. */ FIND_FIRST_DB_MATCH(env, dbp, ldbp); for (found = 0; ldbp != NULL && ldbp->adj_fileid == dbp->adj_fileid; ldbp = TAILQ_NEXT(ldbp, dblistlinks)) { MUTEX_LOCK(env, dbp->mutex); TAILQ_FOREACH(dbc, &ldbp->active_queue, links) { cp = (BTREE_CURSOR *)dbc->internal; if (cp_arg->root != cp->root || MVCC_SKIP_CURADJ(dbc, cp->root)) continue; ++found; adjusted = 0; switch (op) { case CA_DELETE: if (recno < cp->recno) { --cp->recno; /* * If the adjustment made them equal, * we have to merge the orders. */ if (recno == cp->recno && CD_ISSET(cp)) cp->order += order; } else if (recno == cp->recno && !CD_ISSET(cp)) { CD_SET(cp); cp->order = order; } break; case CA_IBEFORE: /* * IBEFORE is just like IAFTER, except that we * adjust cursors on the current record too. */ if (C_EQUAL(cp_arg, cp)) { ++cp->recno; adjusted = 1; } goto iafter; case CA_ICURRENT: /* * If the original cursor wasn't deleted, we * just did a replacement and so there's no * need to adjust anything--we shouldn't have * gotten this far. Otherwise, we behave * much like an IAFTER, except that all * cursors pointing to the current item get * marked undeleted and point to the new * item. */ DB_ASSERT(env, CD_ISSET(cp_arg)); if (C_EQUAL(cp_arg, cp)) { CD_CLR(cp); break; } /* FALLTHROUGH */ case CA_IAFTER: iafter: if (!adjusted && C_LESSTHAN(cp_arg, cp)) { ++cp->recno; adjusted = 1; } if (recno == cp->recno && adjusted) /* * If we've moved this cursor's recno, * split its order number--i.e., * decrement it by enough so that * the lowest cursor moved has order 1. * cp_arg->order is the split point, * so decrement by one less than that. */ cp->order -= (cp_arg->order - 1); break; } } MUTEX_UNLOCK(dbp->env, dbp->mutex); } MUTEX_UNLOCK(env, env->mtx_dblist); if (foundp != NULL) *foundp = found; return (0); } /* * __ram_getno -- * Check the user's record number, and make sure we've seen it. * * PUBLIC: int __ram_getno __P((DBC *, const DBT *, db_recno_t *, int)); */ int __ram_getno(dbc, key, rep, can_create) DBC *dbc; const DBT *key; db_recno_t *rep; int can_create; { DB *dbp; db_recno_t recno; dbp = dbc->dbp; /* If passed an empty DBT from Java, key->data may be NULL */ if (key->size != sizeof(db_recno_t)) { __db_errx(dbp->env, "illegal record number size"); return (EINVAL); } /* Check the user's record number. */ if ((recno = *(db_recno_t *)key->data) == 0) { __db_errx(dbp->env, "illegal record number of 0"); return (EINVAL); } if (rep != NULL) *rep = recno; /* * Btree can neither create records nor read them in. Recno can * do both, see if we can find the record. */ return (dbc->dbtype == DB_RECNO ? __ram_update(dbc, recno, can_create) : 0); } /* * __ram_update -- * Ensure the tree has records up to and including the specified one. */ static int __ram_update(dbc, recno, can_create) DBC *dbc; db_recno_t recno; int can_create; { BTREE *t; DB *dbp; DBT *rdata; db_recno_t nrecs; int ret; dbp = dbc->dbp; t = dbp->bt_internal; /* * If we can't create records and we've read the entire backing input * file, we're done. */ if (!can_create && t->re_eof) return (0); /* * If we haven't seen this record yet, try to get it from the original * file. */ if ((ret = __bam_nrecs(dbc, &nrecs)) != 0) return (ret); if (!t->re_eof && recno > nrecs) { if ((ret = __ram_sread(dbc, recno)) != 0 && ret != DB_NOTFOUND) return (ret); if ((ret = __bam_nrecs(dbc, &nrecs)) != 0) return (ret); } /* * If we can create records, create empty ones up to the requested * record. */ if (!can_create || recno <= nrecs + 1) return (0); rdata = &dbc->my_rdata; rdata->flags = 0; rdata->size = 0; while (recno > ++nrecs) if ((ret = __ram_add(dbc, &nrecs, rdata, 0, BI_DELETED)) != 0) return (ret); return (0); } /* * __ram_source -- * Load information about the backing file. */ static int __ram_source(dbp) DB *dbp; { BTREE *t; ENV *env; char *source; int ret; env = dbp->env; t = dbp->bt_internal; /* Find the real name, and swap out the one we had before. */ if ((ret = __db_appname(env, DB_APP_DATA, t->re_source, 0, NULL, &source)) != 0) return (ret); __os_free(env, t->re_source); t->re_source = source; /* * !!! * It's possible that the backing source file is read-only. We don't * much care other than we'll complain if there are any modifications * when it comes time to write the database back to the source. */ if ((t->re_fp = fopen(t->re_source, "rb")) == NULL) { ret = __os_get_errno(); __db_err(env, ret, "%s", t->re_source); return (ret); } t->re_eof = 0; return (0); } /* * __ram_writeback -- * Rewrite the backing file. * * PUBLIC: int __ram_writeback __P((DB *)); */ int __ram_writeback(dbp) DB *dbp; { BTREE *t; DBC *dbc; DBT key, data; DB_THREAD_INFO *ip; ENV *env; FILE *fp; db_recno_t keyno; int ret, t_ret; u_int8_t delim, *pad; t = dbp->bt_internal; env = dbp->env; fp = NULL; pad = NULL; /* If the file wasn't modified, we're done. */ if (!t->re_modified) return (0); /* If there's no backing source file, we're done. */ if (t->re_source == NULL) { t->re_modified = 0; return (0); } /* * We step through the records, writing each one out. Use the record * number and the dbp->get() function, instead of a cursor, so we find * and write out "deleted" or non-existent records. The DB handle may * be threaded, so allocate memory as we go. */ memset(&key, 0, sizeof(key)); key.size = sizeof(db_recno_t); key.data = &keyno; memset(&data, 0, sizeof(data)); F_SET(&data, DB_DBT_REALLOC); /* Allocate a cursor. */ ENV_GET_THREAD_INFO(env, ip); if ((ret = __db_cursor(dbp, ip, NULL, &dbc, 0)) != 0) return (ret); /* * Read any remaining records into the tree. * * !!! * This is why we can't support transactions when applications specify * backing (re_source) files. At this point we have to read in the * rest of the records from the file so that we can write all of the * records back out again, which could modify a page for which we'd * have to log changes and which we don't have locked. This could be * partially fixed by taking a snapshot of the entire file during the * DB->open as DB->open is transaction protected. But, if a checkpoint * occurs then, the part of the log holding the copy of the file could * be discarded, and that would make it impossible to recover in the * face of disaster. This could all probably be fixed, but it would * require transaction protecting the backing source file. * * XXX * This could be made to work now that we have transactions protecting * file operations. Margo has specifically asked for the privilege of * doing this work. */ if ((ret = __ram_update(dbc, DB_MAX_RECORDS, 0)) != 0 && ret != DB_NOTFOUND) goto err; /* * Close any existing file handle and re-open the file, truncating it. */ if (t->re_fp != NULL) { if (fclose(t->re_fp) != 0) { ret = __os_get_errno(); __db_err(env, ret, "%s", t->re_source); goto err; } t->re_fp = NULL; } if ((fp = fopen(t->re_source, "wb")) == NULL) { ret = __os_get_errno(); __db_err(env, ret, "%s", t->re_source); goto err; } /* * We'll need the delimiter if we're doing variable-length records, * and the pad character if we're doing fixed-length records. */ delim = t->re_delim; for (keyno = 1;; ++keyno) { switch (ret = __db_get(dbp, ip, NULL, &key, &data, 0)) { case 0: if (data.size != 0 && fwrite(data.data, 1, data.size, fp) != data.size) goto write_err; break; case DB_KEYEMPTY: if (F_ISSET(dbp, DB_AM_FIXEDLEN)) { if (pad == NULL) { if ((ret = __os_malloc( env, t->re_len, &pad)) != 0) goto err; memset(pad, t->re_pad, t->re_len); } if (fwrite(pad, 1, t->re_len, fp) != t->re_len) goto write_err; } break; case DB_NOTFOUND: ret = 0; goto done; default: goto err; } if (!F_ISSET(dbp, DB_AM_FIXEDLEN) && fwrite(&delim, 1, 1, fp) != 1) { write_err: ret = __os_get_errno(); __db_err(env, ret, "%s: write failed to backing file", t->re_source); goto err; } } err: done: /* Close the file descriptor. */ if (fp != NULL && fclose(fp) != 0) { t_ret = __os_get_errno(); __db_err(env, t_ret, "%s", t->re_source); if (ret == 0) ret = t_ret; } /* Discard the cursor. */ if ((t_ret = __dbc_close(dbc)) != 0 && ret == 0) ret = t_ret; /* Discard memory allocated to hold the data items. */ if (data.data != NULL) __os_ufree(env, data.data); if (pad != NULL) __os_free(env, pad); if (ret == 0) t->re_modified = 0; return (ret); } /* * __ram_sread -- * Read records from a source file. */ static int __ram_sread(dbc, top) DBC *dbc; db_recno_t top; { BTREE *t; DB *dbp; DBT data, *rdata; db_recno_t recno; size_t len; int ch, ret, was_modified; t = dbc->dbp->bt_internal; dbp = dbc->dbp; was_modified = t->re_modified; if ((ret = __bam_nrecs(dbc, &recno)) != 0) return (ret); /* * Use the record key return memory, it's only a short-term use. * The record data return memory is used by __bam_iitem, which * we'll indirectly call, so use the key so as not to collide. */ len = F_ISSET(dbp, DB_AM_FIXEDLEN) ? t->re_len : 256; rdata = &dbc->my_rkey; if (rdata->ulen < len) { if ((ret = __os_realloc( dbp->env, len, &rdata->data)) != 0) { rdata->ulen = 0; rdata->data = NULL; return (ret); } rdata->ulen = (u_int32_t)len; } memset(&data, 0, sizeof(data)); while (recno < top) { data.data = rdata->data; data.size = 0; if (F_ISSET(dbp, DB_AM_FIXEDLEN)) for (len = t->re_len; len > 0; --len) { if ((ch = fgetc(t->re_fp)) == EOF) { if (data.size == 0) goto eof; break; } ((u_int8_t *)data.data)[data.size++] = ch; } else for (;;) { if ((ch = fgetc(t->re_fp)) == EOF) { if (data.size == 0) goto eof; break; } if (ch == t->re_delim) break; ((u_int8_t *)data.data)[data.size++] = ch; if (data.size == rdata->ulen) { if ((ret = __os_realloc(dbp->env, rdata->ulen *= 2, &rdata->data)) != 0) { rdata->ulen = 0; rdata->data = NULL; return (ret); } else data.data = rdata->data; } } /* * Another process may have read this record from the input * file and stored it into the database already, in which * case we don't need to repeat that operation. We detect * this by checking if the last record we've read is greater * or equal to the number of records in the database. */ if (t->re_last >= recno) { ++recno; if ((ret = __ram_add(dbc, &recno, &data, 0, 0)) != 0) goto err; } ++t->re_last; } if (0) { eof: t->re_eof = 1; ret = DB_NOTFOUND; } err: if (!was_modified) t->re_modified = 0; return (ret); } /* * __ram_add -- * Add records into the tree. */ static int __ram_add(dbc, recnop, data, flags, bi_flags) DBC *dbc; db_recno_t *recnop; DBT *data; u_int32_t flags, bi_flags; { BTREE_CURSOR *cp; int exact, ret, stack, t_ret; cp = (BTREE_CURSOR *)dbc->internal; retry: /* Find the slot for insertion. */ if ((ret = __bam_rsearch(dbc, recnop, SR_INSERT | (flags == DB_APPEND ? SR_APPEND : 0), 1, &exact)) != 0) return (ret); stack = 1; /* Copy the page into the cursor. */ STACK_TO_CURSOR(cp, ret); if (ret != 0) goto err; if (exact && flags == DB_NOOVERWRITE && !CD_ISSET(cp) && !B_DISSET(GET_BKEYDATA(dbc->dbp, cp->page, cp->indx)->type)) { ret = DB_KEYEXIST; goto err; } /* * The application may modify the data based on the selected record * number. */ if (flags == DB_APPEND && dbc->dbp->db_append_recno != NULL && (ret = dbc->dbp->db_append_recno(dbc->dbp, data, *recnop)) != 0) goto err; /* * Select the arguments for __bam_iitem() and do the insert. If the * key is an exact match, or we're replacing the data item with a * new data item, replace the current item. If the key isn't an exact * match, we're inserting a new key/data pair, before the search * location. */ switch (ret = __bam_iitem(dbc, NULL, data, exact ? DB_CURRENT : DB_BEFORE, bi_flags)) { case 0: /* * Don't adjust anything. * * If we inserted a record, no cursors need adjusting because * the only new record it's possible to insert is at the very * end of the tree. The necessary adjustments to the internal * page counts were made by __bam_iitem(). * * If we overwrote a record, no cursors need adjusting because * future DBcursor->get calls will simply return the underlying * record (there's no adjustment made for the DB_CURRENT flag * when a cursor get operation immediately follows a cursor * delete operation, and the normal adjustment for the DB_NEXT * flag is still correct). */ break; case DB_NEEDSPLIT: /* Discard the stack of pages and split the page. */ (void)__bam_stkrel(dbc, STK_CLRDBC); stack = 0; if ((ret = __bam_split(dbc, recnop, NULL)) != 0) goto err; goto retry; /* NOTREACHED */ default: goto err; } err: if (stack && (t_ret = __bam_stkrel(dbc, STK_CLRDBC)) != 0 && ret == 0) ret = t_ret; return (ret); }