/* * See the file LICENSE for redistribution information. * * Copyright (c) 1998-2009 Oracle. All rights reserved. * * $Id$ */ #include "db_config.h" #include "db_int.h" #include "dbinc/db_page.h" #include "dbinc/db_join.h" #include "dbinc/btree.h" #include "dbinc/lock.h" static int __db_join_close_pp __P((DBC *)); static int __db_join_cmp __P((const void *, const void *)); static int __db_join_del __P((DBC *, u_int32_t)); static int __db_join_get __P((DBC *, DBT *, DBT *, u_int32_t)); static int __db_join_get_pp __P((DBC *, DBT *, DBT *, u_int32_t)); static int __db_join_getnext __P((DBC *, DBT *, DBT *, u_int32_t, u_int32_t)); static int __db_join_primget __P((DB *, DB_THREAD_INFO *, DB_TXN *, DB_LOCKER *, DBT *, DBT *, u_int32_t)); static int __db_join_put __P((DBC *, DBT *, DBT *, u_int32_t)); /* * Check to see if the Nth secondary cursor of join cursor jc is pointing * to a sorted duplicate set. */ #define SORTED_SET(jc, n) ((jc)->j_curslist[(n)]->dbp->dup_compare != NULL) /* * This is the duplicate-assisted join functionality. Right now we're * going to write it such that we return one item at a time, although * I think we may need to optimize it to return them all at once. * It should be easier to get it working this way, and I believe that * changing it should be fairly straightforward. * * We optimize the join by sorting cursors from smallest to largest * cardinality. In most cases, this is indeed optimal. However, if * a cursor with large cardinality has very few data in common with the * first cursor, it is possible that the join will be made faster by * putting it earlier in the cursor list. Since we have no way to detect * cases like this, we simply provide a flag, DB_JOIN_NOSORT, which retains * the sort order specified by the caller, who may know more about the * structure of the data. * * The first cursor moves sequentially through the duplicate set while * the others search explicitly for the duplicate in question. * */ /* * __db_join -- * This is the interface to the duplicate-assisted join functionality. * In the same way that cursors mark a position in a database, a cursor * can mark a position in a join. While most cursors are created by the * cursor method of a DB, join cursors are created through an explicit * call to DB->join. * * The curslist is an array of existing, initialized cursors and primary * is the DB of the primary file. The data item that joins all the * cursors in the curslist is used as the key into the primary and that * key and data are returned. When no more items are left in the join * set, the c_next operation off the join cursor will return DB_NOTFOUND. * * PUBLIC: int __db_join __P((DB *, DBC **, DBC **, u_int32_t)); */ int __db_join(primary, curslist, dbcp, flags) DB *primary; DBC **curslist, **dbcp; u_int32_t flags; { DBC *dbc; ENV *env; JOIN_CURSOR *jc; size_t ncurs, nslots; u_int32_t i; int ret; env = primary->env; dbc = NULL; jc = NULL; if ((ret = __os_calloc(env, 1, sizeof(DBC), &dbc)) != 0) goto err; if ((ret = __os_calloc(env, 1, sizeof(JOIN_CURSOR), &jc)) != 0) goto err; if ((ret = __os_malloc(env, 256, &jc->j_key.data)) != 0) goto err; jc->j_key.ulen = 256; F_SET(&jc->j_key, DB_DBT_USERMEM); F_SET(&jc->j_rdata, DB_DBT_REALLOC); for (jc->j_curslist = curslist; *jc->j_curslist != NULL; jc->j_curslist++) ; /* * The number of cursor slots we allocate is one greater than * the number of cursors involved in the join, because the * list is NULL-terminated. */ ncurs = (size_t)(jc->j_curslist - curslist); nslots = ncurs + 1; /* * !!! -- A note on the various lists hanging off jc. * * j_curslist is the initial NULL-terminated list of cursors passed * into __db_join. The original cursors are not modified; pristine * copies are required because, in databases with unsorted dups, we * must reset all of the secondary cursors after the first each * time the first one is incremented, or else we will lose data * which happen to be sorted differently in two different cursors. * * j_workcurs is where we put those copies that we're planning to * work with. They're lazily c_dup'ed from j_curslist as we need * them, and closed when the join cursor is closed or when we need * to reset them to their original values (in which case we just * c_dup afresh). * * j_fdupcurs is an array of cursors which point to the first * duplicate in the duplicate set that contains the data value * we're currently interested in. We need this to make * __db_join_get correctly return duplicate duplicates; i.e., if a * given data value occurs twice in the set belonging to cursor #2, * and thrice in the set belonging to cursor #3, and once in all * the other cursors, successive calls to __db_join_get need to * return that data item six times. To make this happen, each time * cursor N is allowed to advance to a new datum, all cursors M * such that M > N have to be reset to the first duplicate with * that datum, so __db_join_get will return all the dup-dups again. * We could just reset them to the original cursor from j_curslist, * but that would be a bit slower in the unsorted case and a LOT * slower in the sorted one. * * j_exhausted is a list of boolean values which represent * whether or not their corresponding cursors are "exhausted", * i.e. whether the datum under the corresponding cursor has * been found not to exist in any unreturned combinations of * later secondary cursors, in which case they are ready to be * incremented. */ /* We don't want to free regions whose callocs have failed. */ jc->j_curslist = NULL; jc->j_workcurs = NULL; jc->j_fdupcurs = NULL; jc->j_exhausted = NULL; if ((ret = __os_calloc(env, nslots, sizeof(DBC *), &jc->j_curslist)) != 0) goto err; if ((ret = __os_calloc(env, nslots, sizeof(DBC *), &jc->j_workcurs)) != 0) goto err; if ((ret = __os_calloc(env, nslots, sizeof(DBC *), &jc->j_fdupcurs)) != 0) goto err; if ((ret = __os_calloc(env, nslots, sizeof(u_int8_t), &jc->j_exhausted)) != 0) goto err; for (i = 0; curslist[i] != NULL; i++) { jc->j_curslist[i] = curslist[i]; jc->j_workcurs[i] = NULL; jc->j_fdupcurs[i] = NULL; jc->j_exhausted[i] = 0; } jc->j_ncurs = (u_int32_t)ncurs; /* * If DB_JOIN_NOSORT is not set, optimize secondary cursors by * sorting in order of increasing cardinality. */ if (!LF_ISSET(DB_JOIN_NOSORT)) qsort(jc->j_curslist, ncurs, sizeof(DBC *), __db_join_cmp); /* * We never need to reset the 0th cursor, so there's no * solid reason to use workcurs[0] rather than curslist[0] in * join_get. Nonetheless, it feels cleaner to do it for symmetry, * and this is the most logical place to copy it. * * !!! * There's no need to close the new cursor if we goto err only * because this is the last thing that can fail. Modifier of this * function beware! */ if ((ret = __dbc_dup(jc->j_curslist[0], jc->j_workcurs, DB_POSITION)) != 0) goto err; dbc->close = dbc->c_close = __db_join_close_pp; dbc->del = dbc->c_del = __db_join_del; dbc->get = dbc->c_get = __db_join_get_pp; dbc->put = dbc->c_put = __db_join_put; dbc->internal = (DBC_INTERNAL *)jc; dbc->dbp = primary; jc->j_primary = primary; /* Stash the first cursor's transaction here for easy access. */ dbc->txn = curslist[0]->txn; *dbcp = dbc; MUTEX_LOCK(env, primary->mutex); TAILQ_INSERT_TAIL(&primary->join_queue, dbc, links); MUTEX_UNLOCK(env, primary->mutex); return (0); err: if (jc != NULL) { if (jc->j_curslist != NULL) __os_free(env, jc->j_curslist); if (jc->j_workcurs != NULL) { if (jc->j_workcurs[0] != NULL) (void)__dbc_close(jc->j_workcurs[0]); __os_free(env, jc->j_workcurs); } if (jc->j_fdupcurs != NULL) __os_free(env, jc->j_fdupcurs); if (jc->j_exhausted != NULL) __os_free(env, jc->j_exhausted); __os_free(env, jc); } if (dbc != NULL) __os_free(env, dbc); return (ret); } /* * __db_join_close_pp -- * DBC->close pre/post processing for join cursors. */ static int __db_join_close_pp(dbc) DBC *dbc; { DB *dbp; DB_THREAD_INFO *ip; ENV *env; int handle_check, ret, t_ret; dbp = dbc->dbp; env = dbp->env; ENV_ENTER(env, ip); handle_check = IS_ENV_REPLICATED(env); if (handle_check && (ret = __db_rep_enter(dbp, 1, 0, dbc->txn != NULL)) != 0) { handle_check = 0; goto err; } ret = __db_join_close(dbc); if (handle_check && (t_ret = __env_db_rep_exit(env)) != 0 && ret == 0) ret = t_ret; err: ENV_LEAVE(env, ip); return (ret); } static int __db_join_put(dbc, key, data, flags) DBC *dbc; DBT *key; DBT *data; u_int32_t flags; { COMPQUIET(dbc, NULL); COMPQUIET(key, NULL); COMPQUIET(data, NULL); COMPQUIET(flags, 0); return (EINVAL); } static int __db_join_del(dbc, flags) DBC *dbc; u_int32_t flags; { COMPQUIET(dbc, NULL); COMPQUIET(flags, 0); return (EINVAL); } /* * __db_join_get_pp -- * DBjoin->get pre/post processing. */ static int __db_join_get_pp(dbc, key, data, flags) DBC *dbc; DBT *key, *data; u_int32_t flags; { DB *dbp; DB_THREAD_INFO *ip; ENV *env; u_int32_t handle_check, save_flags; int ret, t_ret; dbp = dbc->dbp; env = dbp->env; /* Save the original flags value. */ save_flags = flags; if (LF_ISSET(DB_READ_COMMITTED | DB_READ_UNCOMMITTED | DB_RMW)) { if (!LOCKING_ON(env)) return (__db_fnl(env, "DBC->get")); LF_CLR(DB_READ_COMMITTED | DB_READ_UNCOMMITTED | DB_RMW); } switch (flags) { case 0: case DB_JOIN_ITEM: break; default: return (__db_ferr(env, "DBC->get", 0)); } /* * A partial get of the key of a join cursor don't make much sense; * the entire key is necessary to query the primary database * and find the datum, and so regardless of the size of the key * it would not be a performance improvement. Since it would require * special handling, we simply disallow it. * * A partial get of the data, however, potentially makes sense (if * all possible data are a predictable large structure, for instance) * and causes us no headaches, so we permit it. */ if (F_ISSET(key, DB_DBT_PARTIAL)) { __db_errx(env, "DB_DBT_PARTIAL may not be set on key during join_get"); return (EINVAL); } ENV_ENTER(env, ip); handle_check = IS_ENV_REPLICATED(env); if (handle_check && (ret = __db_rep_enter(dbp, 1, 0, dbc->txn != NULL)) != 0) { handle_check = 0; goto err; } /* Restore the original flags value. */ flags = save_flags; ret = __db_join_get(dbc, key, data, flags); if (handle_check && (t_ret = __env_db_rep_exit(env)) != 0 && ret == 0) ret = t_ret; err: ENV_LEAVE(env, ip); __dbt_userfree(env, key, NULL, NULL); return (ret); } static int __db_join_get(dbc, key_arg, data_arg, flags) DBC *dbc; DBT *key_arg, *data_arg; u_int32_t flags; { DB *dbp; DBC *cp; DBT *key_n, key_n_mem; ENV *env; JOIN_CURSOR *jc; int db_manage_data, ret; u_int32_t i, j, operation, opmods; dbp = dbc->dbp; env = dbp->env; jc = (JOIN_CURSOR *)dbc->internal; operation = LF_ISSET(DB_OPFLAGS_MASK); /* !!! * If the set of flags here changes, check that __db_join_primget * is updated to handle them properly. */ opmods = LF_ISSET(DB_READ_COMMITTED | DB_READ_UNCOMMITTED | DB_RMW); /* * Since we are fetching the key as a datum in the secondary indices, * we must be careful of caller-specified DB_DBT_* memory * management flags. If necessary, use a stack-allocated DBT; * we'll appropriately copy and/or allocate the data later. */ if (F_ISSET(key_arg, DB_DBT_MALLOC | DB_DBT_USERCOPY | DB_DBT_USERMEM)) { /* We just use the default buffer; no need to go malloc. */ key_n = &key_n_mem; memset(key_n, 0, sizeof(DBT)); } else { /* * Either DB_DBT_REALLOC or the default buffer will work * fine if we have to reuse it, as we do. */ key_n = key_arg; } if (F_ISSET(key_arg, DB_DBT_USERCOPY)) key_arg->data = NULL; /* * If our last attempt to do a get on the primary key failed, * short-circuit the join and try again with the same key. */ if (F_ISSET(jc, JOIN_RETRY)) goto samekey; F_CLR(jc, JOIN_RETRY); retry: ret = __dbc_get(jc->j_workcurs[0], &jc->j_key, key_n, opmods | (jc->j_exhausted[0] ? DB_NEXT_DUP : DB_CURRENT)); if (ret == DB_BUFFER_SMALL) { jc->j_key.ulen <<= 1; if ((ret = __os_realloc(env, jc->j_key.ulen, &jc->j_key.data)) != 0) goto mem_err; goto retry; } /* * If ret == DB_NOTFOUND, we're out of elements of the first * secondary cursor. This is how we finally finish the join * if all goes well. */ if (ret != 0) goto err; /* * If jc->j_exhausted[0] == 1, we've just advanced the first cursor, * and we're going to want to advance all the cursors that point to * the first member of a duplicate duplicate set (j_fdupcurs[1..N]). * Close all the cursors in j_fdupcurs; we'll reopen them the * first time through the upcoming loop. */ for (i = 1; i < jc->j_ncurs; i++) { if (jc->j_fdupcurs[i] != NULL && (ret = __dbc_close(jc->j_fdupcurs[i])) != 0) goto err; jc->j_fdupcurs[i] = NULL; } /* * If jc->j_curslist[1] == NULL, we have only one cursor in the join. * Thus, we can safely increment that one cursor on each call * to __db_join_get, and we signal this by setting jc->j_exhausted[0] * right away. * * Otherwise, reset jc->j_exhausted[0] to 0, so that we don't * increment it until we know we're ready to. */ if (jc->j_curslist[1] == NULL) jc->j_exhausted[0] = 1; else jc->j_exhausted[0] = 0; /* We have the first element; now look for it in the other cursors. */ for (i = 1; i < jc->j_ncurs; i++) { DB_ASSERT(env, jc->j_curslist[i] != NULL); if (jc->j_workcurs[i] == NULL) /* If this is NULL, we need to dup curslist into it. */ if ((ret = __dbc_dup(jc->j_curslist[i], &jc->j_workcurs[i], DB_POSITION)) != 0) goto err; retry2: cp = jc->j_workcurs[i]; if ((ret = __db_join_getnext(cp, &jc->j_key, key_n, jc->j_exhausted[i], opmods)) == DB_NOTFOUND) { /* * jc->j_workcurs[i] has no more of the datum we're * interested in. Go back one cursor and get * a new dup. We can't just move to a new * element of the outer relation, because that way * we might miss duplicate duplicates in cursor i-1. * * If this takes us back to the first cursor, * -then- we can move to a new element of the outer * relation. */ --i; jc->j_exhausted[i] = 1; if (i == 0) { for (j = 1; jc->j_workcurs[j] != NULL; j++) { /* * We're moving to a new element of * the first secondary cursor. If * that cursor is sorted, then any * other sorted cursors can be safely * reset to the first duplicate * duplicate in the current set if we * have a pointer to it (we can't just * leave them be, or we'll miss * duplicate duplicates in the outer * relation). * * If the first cursor is unsorted, or * if cursor j is unsorted, we can * make no assumptions about what * we're looking for next or where it * will be, so we reset to the very * beginning (setting workcurs NULL * will achieve this next go-round). * * XXX: This is likely to break * horribly if any two cursors are * both sorted, but have different * specified sort functions. For, * now, we dismiss this as pathology * and let strange things happen--we * can't make rope childproof. */ if ((ret = __dbc_close( jc->j_workcurs[j])) != 0) goto err; if (!SORTED_SET(jc, 0) || !SORTED_SET(jc, j) || jc->j_fdupcurs[j] == NULL) /* * Unsafe conditions; * reset fully. */ jc->j_workcurs[j] = NULL; else /* Partial reset suffices. */ if ((__dbc_dup( jc->j_fdupcurs[j], &jc->j_workcurs[j], DB_POSITION)) != 0) goto err; jc->j_exhausted[j] = 0; } goto retry; /* NOTREACHED */ } /* * We're about to advance the cursor and need to * reset all of the workcurs[j] where j>i, so that * we don't miss any duplicate duplicates. */ for (j = i + 1; jc->j_workcurs[j] != NULL; j++) { if ((ret = __dbc_close(jc->j_workcurs[j])) != 0) goto err; jc->j_exhausted[j] = 0; if (jc->j_fdupcurs[j] == NULL) jc->j_workcurs[j] = NULL; else if ((ret = __dbc_dup(jc->j_fdupcurs[j], &jc->j_workcurs[j], DB_POSITION)) != 0) goto err; } goto retry2; /* NOTREACHED */ } if (ret == DB_BUFFER_SMALL) { jc->j_key.ulen <<= 1; if ((ret = __os_realloc(env, jc->j_key.ulen, &jc->j_key.data)) != 0) { mem_err: __db_errx(env, "Allocation failed for join key, len = %lu", (u_long)jc->j_key.ulen); goto err; } goto retry2; } if (ret != 0) goto err; /* * If we made it this far, we've found a matching * datum in cursor i. Mark the current cursor * unexhausted, so we don't miss any duplicate * duplicates the next go-round--unless this is the * very last cursor, in which case there are none to * miss, and we'll need that exhausted flag to finally * get a DB_NOTFOUND and move on to the next datum in * the outermost cursor. */ if (i + 1 != jc->j_ncurs) jc->j_exhausted[i] = 0; else jc->j_exhausted[i] = 1; /* * If jc->j_fdupcurs[i] is NULL and the ith cursor's dups are * sorted, then we're here for the first time since advancing * cursor 0, and we have a new datum of interest. * jc->j_workcurs[i] points to the beginning of a set of * duplicate duplicates; store this into jc->j_fdupcurs[i]. */ if (SORTED_SET(jc, i) && jc->j_fdupcurs[i] == NULL && (ret = __dbc_dup(cp, &jc->j_fdupcurs[i], DB_POSITION)) != 0) goto err; } err: if (ret != 0) return (ret); if (0) { samekey: /* * Get the key we tried and failed to return last time; * it should be the current datum of all the secondary cursors. */ if ((ret = __dbc_get(jc->j_workcurs[0], &jc->j_key, key_n, DB_CURRENT | opmods)) != 0) return (ret); F_CLR(jc, JOIN_RETRY); } /* * ret == 0; we have a key to return. * * If DB_DBT_USERMEM or DB_DBT_MALLOC is set, we need to copy the key * back into the dbt we were given for the key; call __db_retcopy. * Otherwise, assert that we do not need to copy anything and proceed. */ DB_ASSERT(env, F_ISSET(key_arg, DB_DBT_USERMEM | DB_DBT_MALLOC | DB_DBT_USERCOPY) || key_n == key_arg); if ((F_ISSET(key_arg, DB_DBT_USERMEM | DB_DBT_MALLOC | DB_DBT_USERCOPY)) && (ret = __db_retcopy(env, key_arg, key_n->data, key_n->size, NULL, NULL)) != 0) { /* * The retcopy failed, most commonly because we have a user * buffer for the key which is too small. Set things up to * retry next time, and return. */ F_SET(jc, JOIN_RETRY); return (ret); } /* * If DB_JOIN_ITEM is set, we return it; otherwise we do the lookup * in the primary and then return. */ if (operation == DB_JOIN_ITEM) return (0); /* * If data_arg->flags == 0--that is, if DB is managing the * data DBT's memory--it's not safe to just pass the DBT * through to the primary get call, since we don't want that * memory to belong to the primary DB handle (and if the primary * is free-threaded, it can't anyway). * * Instead, use memory that is managed by the join cursor, in * jc->j_rdata. */ if (!F_ISSET(data_arg, DB_DBT_MALLOC | DB_DBT_REALLOC | DB_DBT_USERMEM | DB_DBT_USERCOPY)) db_manage_data = 1; else db_manage_data = 0; if ((ret = __db_join_primget(jc->j_primary, dbc->thread_info, jc->j_curslist[0]->txn, jc->j_curslist[0]->locker, key_n, db_manage_data ? &jc->j_rdata : data_arg, opmods)) != 0) { if (ret == DB_NOTFOUND) { if (LF_ISSET(DB_READ_UNCOMMITTED) || (jc->j_curslist[0]->txn != NULL && F_ISSET( jc->j_curslist[0]->txn, TXN_READ_UNCOMMITTED))) goto retry; /* * If ret == DB_NOTFOUND, the primary and secondary * are out of sync; every item in each secondary * should correspond to something in the primary, * or we shouldn't have done the join this way. * Wail. */ ret = __db_secondary_corrupt(jc->j_primary); } else /* * The get on the primary failed for some other * reason, most commonly because we're using a user * buffer that's not big enough. Flag our failure * so we can return the same key next time. */ F_SET(jc, JOIN_RETRY); } if (db_manage_data && ret == 0) { data_arg->data = jc->j_rdata.data; data_arg->size = jc->j_rdata.size; } return (ret); } /* * __db_join_close -- * DBC->close for join cursors. * * PUBLIC: int __db_join_close __P((DBC *)); */ int __db_join_close(dbc) DBC *dbc; { DB *dbp; DB_THREAD_INFO *ip; ENV *env; JOIN_CURSOR *jc; int ret, t_ret; u_int32_t i; jc = (JOIN_CURSOR *)dbc->internal; dbp = dbc->dbp; env = dbp->env; ret = t_ret = 0; /* * Remove from active list of join cursors. Note that this * must happen before any action that can fail and return, or else * __db_close may loop indefinitely. */ MUTEX_LOCK(env, dbp->mutex); TAILQ_REMOVE(&dbp->join_queue, dbc, links); MUTEX_UNLOCK(env, dbp->mutex); ENV_ENTER(env, ip); /* * Close any open scratch cursors. In each case, there may * not be as many outstanding as there are cursors in * curslist, but we want to close whatever's there. * * If any close fails, there's no reason not to close everything else; * we'll just return the error code of the last one to fail. There's * not much the caller can do anyway, since these cursors only exist * hanging off a db-internal data structure that they shouldn't be * mucking with. */ for (i = 0; i < jc->j_ncurs; i++) { if (jc->j_workcurs[i] != NULL && (t_ret = __dbc_close(jc->j_workcurs[i])) != 0) ret = t_ret; if (jc->j_fdupcurs[i] != NULL && (t_ret = __dbc_close(jc->j_fdupcurs[i])) != 0) ret = t_ret; } ENV_LEAVE(env, ip); __os_free(env, jc->j_exhausted); __os_free(env, jc->j_curslist); __os_free(env, jc->j_workcurs); __os_free(env, jc->j_fdupcurs); __os_free(env, jc->j_key.data); if (jc->j_rdata.data != NULL) __os_ufree(env, jc->j_rdata.data); __os_free(env, jc); __os_free(env, dbc); return (ret); } /* * __db_join_getnext -- * This function replaces the DBC_CONTINUE and DBC_KEYSET * functionality inside the various cursor get routines. * * If exhausted == 0, we're not done with the current datum; * return it if it matches "matching", otherwise search * using DB_GET_BOTHC (which is faster than iteratively doing * DB_NEXT_DUP) forward until we find one that does. * * If exhausted == 1, we are done with the current datum, so just * leap forward to searching NEXT_DUPs. * * If no matching datum exists, returns DB_NOTFOUND, else 0. */ static int __db_join_getnext(dbc, key, data, exhausted, opmods) DBC *dbc; DBT *key, *data; u_int32_t exhausted, opmods; { int ret, cmp; DB *dbp; DBT ldata; int (*func) __P((DB *, const DBT *, const DBT *)); dbp = dbc->dbp; func = (dbp->dup_compare == NULL) ? __bam_defcmp : dbp->dup_compare; switch (exhausted) { case 0: /* * We don't want to step on data->data; use a new * DBT and malloc so we don't step on dbc's rdata memory. */ memset(&ldata, 0, sizeof(DBT)); F_SET(&ldata, DB_DBT_MALLOC); if ((ret = __dbc_get(dbc, key, &ldata, opmods | DB_CURRENT)) != 0) break; cmp = func(dbp, data, &ldata); if (cmp == 0) { /* * We have to return the real data value. Copy * it into data, then free the buffer we malloc'ed * above. */ if ((ret = __db_retcopy(dbp->env, data, ldata.data, ldata.size, &data->data, &data->size)) != 0) return (ret); __os_ufree(dbp->env, ldata.data); return (0); } /* * Didn't match--we want to fall through and search future * dups. We just forget about ldata and free * its buffer--data contains the value we're searching for. */ __os_ufree(dbp->env, ldata.data); /* FALLTHROUGH */ case 1: ret = __dbc_get(dbc, key, data, opmods | DB_GET_BOTHC); break; default: ret = EINVAL; break; } return (ret); } /* * __db_join_cmp -- * Comparison function for sorting DBCs in cardinality order. */ static int __db_join_cmp(a, b) const void *a, *b; { DBC *dbca, *dbcb; db_recno_t counta, countb; dbca = *((DBC * const *)a); dbcb = *((DBC * const *)b); if (__dbc_count(dbca, &counta) != 0 || __dbc_count(dbcb, &countb) != 0) return (0); return ((long)counta - (long)countb); } /* * __db_join_primget -- * Perform a DB->get in the primary, being careful not to use a new * locker ID if we're doing CDB locking. */ static int __db_join_primget(dbp, ip, txn, locker, key, data, flags) DB *dbp; DB_THREAD_INFO *ip; DB_TXN *txn; DB_LOCKER *locker; DBT *key, *data; u_int32_t flags; { DBC *dbc; u_int32_t rmw; int ret, t_ret; if ((ret = __db_cursor_int(dbp, ip, txn, dbp->type, PGNO_INVALID, 0, locker, &dbc)) != 0) return (ret); /* * The only allowable flags here are the two flags copied into "opmods" * in __db_join_get, DB_RMW and DB_READ_UNCOMMITTED. The former is an * op on the c_get call, the latter on the cursor call. It's a DB bug * if we allow any other flags down in here. */ rmw = LF_ISSET(DB_RMW); if (LF_ISSET(DB_READ_UNCOMMITTED) || (txn != NULL && F_ISSET(txn, TXN_READ_UNCOMMITTED))) F_SET(dbc, DBC_READ_UNCOMMITTED); if (LF_ISSET(DB_READ_COMMITTED) || (txn != NULL && F_ISSET(txn, TXN_READ_COMMITTED))) F_SET(dbc, DBC_READ_COMMITTED); LF_CLR(DB_READ_COMMITTED | DB_READ_UNCOMMITTED | DB_RMW); DB_ASSERT(dbp->env, flags == 0); F_SET(dbc, DBC_TRANSIENT); /* * This shouldn't be necessary, thanks to the fact that join cursors * swap in their own DB_DBT_REALLOC'ed buffers, but just for form's * sake, we mirror what __db_get does. */ SET_RET_MEM(dbc, dbp); ret = __dbc_get(dbc, key, data, DB_SET | rmw); if ((t_ret = __dbc_close(dbc)) != 0 && ret == 0) ret = t_ret; return (ret); } /* * __db_secondary_corrupt -- * Report primary/secondary inconsistencies. * * PUBLIC: int __db_secondary_corrupt __P((DB *)); */ int __db_secondary_corrupt(dbp) DB *dbp; { __db_err(dbp->env, DB_SECONDARY_BAD, "%s%s%s", dbp->fname == NULL ? "unnamed" : dbp->fname, dbp->dname == NULL ? "" : "/", dbp->dname == NULL ? "" : dbp->dname); return (DB_SECONDARY_BAD); }