/* -------------------------------- * InitPostgres * Initialize POSTGRES. * * The database can be specified by name, using the in_dbname parameter, or by * OID, using the dboid parameter. In the latter case, the actual database * name can be returned to the caller in out_dbname. If out_dbname isn't * NULL, it must point to a buffer of size NAMEDATALEN. * * In bootstrap mode no parameters are used. The autovacuum launcher process * doesn't use any parameters either, because it only goes far enough to be * able to read pg_database; it doesn't connect to any particular database. * In walsender mode only username is used. * * As of PostgreSQL 8.2, we expect InitProcess() was already called, so we * already have a PGPROC struct ... but it's not completely filled in yet. * * Note: * Be very careful with the order of calls in the InitPostgres function. * -------------------------------- */ void InitPostgres(const char *in_dbname, Oid dboid, const char *username, char *out_dbname) { bool bootstrap = IsBootstrapProcessingMode(); bool am_superuser; char *fullpath; char dbname[NAMEDATALEN]; elog(DEBUG3, "InitPostgres"); /* * Add my PGPROC struct to the ProcArray. * * Once I have done this, I am visible to other backends! */ InitProcessPhase2(); /* * Initialize my entry in the shared-invalidation manager's array of * per-backend data. * * Sets up MyBackendId, a unique backend identifier. */ MyBackendId = InvalidBackendId; SharedInvalBackendInit(false); if (MyBackendId > MaxBackends || MyBackendId <= 0) elog(FATAL, "bad backend ID: %d", MyBackendId); /* Now that we have a BackendId, we can participate in ProcSignal */ ProcSignalInit(MyBackendId); /* * Also set up timeout handlers needed for backend operation. We need * these in every case except bootstrap. */ if (!bootstrap) { RegisterTimeout(DEADLOCK_TIMEOUT, CheckDeadLock); RegisterTimeout(STATEMENT_TIMEOUT, StatementTimeoutHandler); RegisterTimeout(LOCK_TIMEOUT, LockTimeoutHandler); } /* * bufmgr needs another initialization call too */ InitBufferPoolBackend(); /* * Initialize local process's access to XLOG. */ if (IsUnderPostmaster) { /* * The postmaster already started the XLOG machinery, but we need to * call InitXLOGAccess(), if the system isn't in hot-standby mode. * This is handled by calling RecoveryInProgress and ignoring the * result. */ (void) RecoveryInProgress(); } else { /* * We are either a bootstrap process or a standalone backend. Either * way, start up the XLOG machinery, and register to have it closed * down at exit. */ StartupXLOG(); on_shmem_exit(ShutdownXLOG, 0); } /* * Initialize the relation cache and the system catalog caches. Note that * no catalog access happens here; we only set up the hashtable structure. * We must do this before starting a transaction because transaction abort * would try to touch these hashtables. */ RelationCacheInitialize(); InitCatalogCache(); InitPlanCache(); /* Initialize portal manager */ EnablePortalManager(); /* Initialize stats collection --- must happen before first xact */ if (!bootstrap) pgstat_initialize(); /* * Load relcache entries for the shared system catalogs. This must create * at least entries for pg_database and catalogs used for authentication. */ RelationCacheInitializePhase2(); /* * Set up process-exit callback to do pre-shutdown cleanup. This is the * first before_shmem_exit callback we register; thus, this will be the * last thing we do before low-level modules like the buffer manager begin * to close down. We need to have this in place before we begin our first * transaction --- if we fail during the initialization transaction, as is * entirely possible, we need the AbortTransaction call to clean up. */ before_shmem_exit(ShutdownPostgres, 0); /* The autovacuum launcher is done here */ if (IsAutoVacuumLauncherProcess()) return; /* * Start a new transaction here before first access to db, and get a * snapshot. We don't have a use for the snapshot itself, but we're * interested in the secondary effect that it sets RecentGlobalXmin. (This * is critical for anything that reads heap pages, because HOT may decide * to prune them even if the process doesn't attempt to modify any * tuples.) */ if (!bootstrap) { /* statement_timestamp must be set for timeouts to work correctly */ SetCurrentStatementStartTimestamp(); StartTransactionCommand(); /* * transaction_isolation will have been set to the default by the * above. If the default is "serializable", and we are in hot * standby, we will fail if we don't change it to something lower. * Fortunately, "read committed" is plenty good enough. */ XactIsoLevel = XACT_READ_COMMITTED; (void) GetTransactionSnapshot(); } /* * Perform client authentication if necessary, then figure out our * postgres user ID, and see if we are a superuser. * * In standalone mode and in autovacuum worker processes, we use a fixed * ID, otherwise we figure it out from the authenticated user name. */ if (bootstrap || IsAutoVacuumWorkerProcess()) { InitializeSessionUserIdStandalone(); am_superuser = true; } else if (!IsUnderPostmaster) { InitializeSessionUserIdStandalone(); am_superuser = true; if (!ThereIsAtLeastOneRole()) ereport(WARNING, (errcode(ERRCODE_UNDEFINED_OBJECT), errmsg("no roles are defined in this database system"), errhint("You should immediately run CREATE USER \"%s\" SUPERUSER;.", username))); } else if (IsBackgroundWorker) { if (username == NULL) { InitializeSessionUserIdStandalone(); am_superuser = true; } else { InitializeSessionUserId(username); am_superuser = superuser(); } } else { /* normal multiuser case */ Assert(MyProcPort != NULL); PerformAuthentication(MyProcPort); InitializeSessionUserId(username); am_superuser = superuser(); } /* * If we're trying to shut down, only superusers can connect, and new * replication connections are not allowed. */ if ((!am_superuser || am_walsender) && MyProcPort != NULL && MyProcPort->canAcceptConnections == CAC_WAITBACKUP) { if (am_walsender) ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("new replication connections are not allowed during database shutdown"))); else ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("must be superuser to connect during database shutdown"))); } /* * Binary upgrades only allowed super-user connections */ if (IsBinaryUpgrade && !am_superuser) { ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("must be superuser to connect in binary upgrade mode"))); } /* * The last few connections slots are reserved for superusers. Although * replication connections currently require superuser privileges, we * don't allow them to consume the reserved slots, which are intended for * interactive use. */ if ((!am_superuser || am_walsender) && ReservedBackends > 0 && !HaveNFreeProcs(ReservedBackends)) ereport(FATAL, (errcode(ERRCODE_TOO_MANY_CONNECTIONS), errmsg("remaining connection slots are reserved for non-replication superuser connections"))); /* Check replication permissions needed for walsender processes. */ if (am_walsender) { Assert(!bootstrap); if (!superuser() && !has_rolreplication(GetUserId())) ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("must be superuser or replication role to start walsender"))); } /* * If this is a plain walsender only supporting physical replication, we * don't want to connect to any particular database. Just finish the * backend startup by processing any options from the startup packet, and * we're done. */ if (am_walsender && !am_db_walsender) { /* process any options passed in the startup packet */ if (MyProcPort != NULL) process_startup_options(MyProcPort, am_superuser); /* Apply PostAuthDelay as soon as we've read all options */ if (PostAuthDelay > 0) pg_usleep(PostAuthDelay * 1000000L); /* initialize client encoding */ InitializeClientEncoding(); /* report this backend in the PgBackendStatus array */ pgstat_bestart(); /* close the transaction we started above */ CommitTransactionCommand(); return; } /* * Set up the global variables holding database id and default tablespace. * But note we won't actually try to touch the database just yet. * * We take a shortcut in the bootstrap case, otherwise we have to look up * the db's entry in pg_database. */ if (bootstrap) { MyDatabaseId = TemplateDbOid; MyDatabaseTableSpace = DEFAULTTABLESPACE_OID; } else if (in_dbname != NULL) { HeapTuple tuple; Form_pg_database dbform; tuple = GetDatabaseTuple(in_dbname); if (!HeapTupleIsValid(tuple)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", in_dbname))); dbform = (Form_pg_database) GETSTRUCT(tuple); MyDatabaseId = HeapTupleGetOid(tuple); MyDatabaseTableSpace = dbform->dattablespace; /* take database name from the caller, just for paranoia */ strlcpy(dbname, in_dbname, sizeof(dbname)); } else if (OidIsValid(dboid)) { /* caller specified database by OID */ HeapTuple tuple; Form_pg_database dbform; tuple = GetDatabaseTupleByOid(dboid); if (!HeapTupleIsValid(tuple)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database %u does not exist", dboid))); dbform = (Form_pg_database) GETSTRUCT(tuple); MyDatabaseId = HeapTupleGetOid(tuple); MyDatabaseTableSpace = dbform->dattablespace; Assert(MyDatabaseId == dboid); strlcpy(dbname, NameStr(dbform->datname), sizeof(dbname)); /* pass the database name back to the caller */ if (out_dbname) strcpy(out_dbname, dbname); } else { /* * If this is a background worker not bound to any particular * database, we're done now. Everything that follows only makes * sense if we are bound to a specific database. We do need to * close the transaction we started before returning. */ if (!bootstrap) CommitTransactionCommand(); return; } /* * Now, take a writer's lock on the database we are trying to connect to. * If there is a concurrently running DROP DATABASE on that database, this * will block us until it finishes (and has committed its update of * pg_database). * * Note that the lock is not held long, only until the end of this startup * transaction. This is OK since we will advertise our use of the * database in the ProcArray before dropping the lock (in fact, that's the * next thing to do). Anyone trying a DROP DATABASE after this point will * see us in the array once they have the lock. Ordering is important for * this because we don't want to advertise ourselves as being in this * database until we have the lock; otherwise we create what amounts to a * deadlock with CountOtherDBBackends(). * * Note: use of RowExclusiveLock here is reasonable because we envision * our session as being a concurrent writer of the database. If we had a * way of declaring a session as being guaranteed-read-only, we could use * AccessShareLock for such sessions and thereby not conflict against * CREATE DATABASE. */ if (!bootstrap) LockSharedObject(DatabaseRelationId, MyDatabaseId, 0, RowExclusiveLock); /* * Now we can mark our PGPROC entry with the database ID. * * We assume this is an atomic store so no lock is needed; though actually * things would work fine even if it weren't atomic. Anyone searching the * ProcArray for this database's ID should hold the database lock, so they * would not be executing concurrently with this store. A process looking * for another database's ID could in theory see a chance match if it read * a partially-updated databaseId value; but as long as all such searches * wait and retry, as in CountOtherDBBackends(), they will certainly see * the correct value on their next try. */ MyProc->databaseId = MyDatabaseId; /* * We established a catalog snapshot while reading pg_authid and/or * pg_database; but until we have set up MyDatabaseId, we won't react to * incoming sinval messages for unshared catalogs, so we won't realize it * if the snapshot has been invalidated. Assume it's no good anymore. */ InvalidateCatalogSnapshot(); /* * Recheck pg_database to make sure the target database hasn't gone away. * If there was a concurrent DROP DATABASE, this ensures we will die * cleanly without creating a mess. */ if (!bootstrap) { HeapTuple tuple; tuple = GetDatabaseTuple(dbname); if (!HeapTupleIsValid(tuple) || MyDatabaseId != HeapTupleGetOid(tuple) || MyDatabaseTableSpace != ((Form_pg_database) GETSTRUCT(tuple))->dattablespace) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("It seems to have just been dropped or renamed."))); } /* * Now we should be able to access the database directory safely. Verify * it's there and looks reasonable. */ fullpath = GetDatabasePath(MyDatabaseId, MyDatabaseTableSpace); if (!bootstrap) { if (access(fullpath, F_OK) == -1) { if (errno == ENOENT) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("The database subdirectory \"%s\" is missing.", fullpath))); else ereport(FATAL, (errcode_for_file_access(), errmsg("could not access directory \"%s\": %m", fullpath))); } ValidatePgVersion(fullpath); } SetDatabasePath(fullpath); /* * It's now possible to do real access to the system catalogs. * * Load relcache entries for the system catalogs. This must create at * least the minimum set of "nailed-in" cache entries. */ RelationCacheInitializePhase3(); /* set up ACL framework (so CheckMyDatabase can check permissions) */ initialize_acl(); /* * Re-read the pg_database row for our database, check permissions and set * up database-specific GUC settings. We can't do this until all the * database-access infrastructure is up. (Also, it wants to know if the * user is a superuser, so the above stuff has to happen first.) */ if (!bootstrap) CheckMyDatabase(dbname, am_superuser); /* * Now process any command-line switches and any additional GUC variable * settings passed in the startup packet. We couldn't do this before * because we didn't know if client is a superuser. */ if (MyProcPort != NULL) process_startup_options(MyProcPort, am_superuser); /* Process pg_db_role_setting options */ process_settings(MyDatabaseId, GetSessionUserId()); /* Apply PostAuthDelay as soon as we've read all options */ if (PostAuthDelay > 0) pg_usleep(PostAuthDelay * 1000000L); /* * Initialize various default states that can't be set up until we've * selected the active user and gotten the right GUC settings. */ /* set default namespace search path */ InitializeSearchPath(); /* initialize client encoding */ InitializeClientEncoding(); /* report this backend in the PgBackendStatus array */ if (!bootstrap) pgstat_bestart(); /* close the transaction we started above */ if (!bootstrap) CommitTransactionCommand(); }
/* -------------------------------- * InitPostgres * Initialize POSTGRES. * * The database can be specified by name, using the in_dbname parameter, or by * OID, using the dboid parameter. In the latter case, the actual database * name can be returned to the caller in out_dbname. If out_dbname isn't * NULL, it must point to a buffer of size NAMEDATALEN. * * In bootstrap mode no parameters are used. The autovacuum launcher process * doesn't use any parameters either, because it only goes far enough to be * able to read pg_database; it doesn't connect to any particular database. * In walsender mode only username is used. * * As of PostgreSQL 8.2, we expect InitProcess() was already called, so we * already have a PGPROC struct ... but it's not completely filled in yet. * * Note: * Be very careful with the order of calls in the InitPostgres function. * -------------------------------- */ void InitPostgres(const char *in_dbname, Oid dboid, const char *username, char *out_dbname) { bool bootstrap = IsBootstrapProcessingMode(); bool am_superuser; GucContext gucctx; char *fullpath; char dbname[NAMEDATALEN]; elog(DEBUG3, "InitPostgres"); /* * Add my PGPROC struct to the ProcArray. * * Once I have done this, I am visible to other backends! */ InitProcessPhase2(); /* * Initialize my entry in the shared-invalidation manager's array of * per-backend data. * * Sets up MyBackendId, a unique backend identifier. */ MyBackendId = InvalidBackendId; SharedInvalBackendInit(false); if (MyBackendId > MaxBackends || MyBackendId <= 0) elog(FATAL, "bad backend id: %d", MyBackendId); /* Now that we have a BackendId, we can participate in ProcSignal */ ProcSignalInit(MyBackendId); /* * bufmgr needs another initialization call too */ InitBufferPoolBackend(); /* * Initialize local process's access to XLOG, if appropriate. In * bootstrap case we skip this since StartupXLOG() was run instead. */ if (!bootstrap) (void) RecoveryInProgress(); /* * Initialize the relation cache and the system catalog caches. Note that * no catalog access happens here; we only set up the hashtable structure. * We must do this before starting a transaction because transaction abort * would try to touch these hashtables. */ RelationCacheInitialize(); InitCatalogCache(); InitPlanCache(); /* Initialize portal manager */ EnablePortalManager(); /* Initialize stats collection --- must happen before first xact */ if (!bootstrap) pgstat_initialize(); /* * Load relcache entries for the shared system catalogs. This must create * at least an entry for pg_database. */ RelationCacheInitializePhase2(); /* * Set up process-exit callback to do pre-shutdown cleanup. This has to * be after we've initialized all the low-level modules like the buffer * manager, because during shutdown this has to run before the low-level * modules start to close down. On the other hand, we want it in place * before we begin our first transaction --- if we fail during the * initialization transaction, as is entirely possible, we need the * AbortTransaction call to clean up. */ on_shmem_exit(ShutdownPostgres, 0); /* The autovacuum launcher is done here */ if (IsAutoVacuumLauncherProcess()) return; /* * Start a new transaction here before first access to db, and get a * snapshot. We don't have a use for the snapshot itself, but we're * interested in the secondary effect that it sets RecentGlobalXmin. (This * is critical for anything that reads heap pages, because HOT may decide * to prune them even if the process doesn't attempt to modify any * tuples.) */ if (!bootstrap) { StartTransactionCommand(); (void) GetTransactionSnapshot(); } /* * Set up the global variables holding database id and default tablespace. * But note we won't actually try to touch the database just yet. * * We take a shortcut in the bootstrap and walsender case, otherwise we * have to look up the db's entry in pg_database. */ if (bootstrap || am_walsender) { MyDatabaseId = TemplateDbOid; MyDatabaseTableSpace = DEFAULTTABLESPACE_OID; } else if (in_dbname != NULL) { HeapTuple tuple; Form_pg_database dbform; tuple = GetDatabaseTuple(in_dbname); if (!HeapTupleIsValid(tuple)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", in_dbname))); dbform = (Form_pg_database) GETSTRUCT(tuple); MyDatabaseId = HeapTupleGetOid(tuple); MyDatabaseTableSpace = dbform->dattablespace; /* take database name from the caller, just for paranoia */ strlcpy(dbname, in_dbname, sizeof(dbname)); } else { /* caller specified database by OID */ HeapTuple tuple; Form_pg_database dbform; tuple = GetDatabaseTupleByOid(dboid); if (!HeapTupleIsValid(tuple)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database %u does not exist", dboid))); dbform = (Form_pg_database) GETSTRUCT(tuple); MyDatabaseId = HeapTupleGetOid(tuple); MyDatabaseTableSpace = dbform->dattablespace; Assert(MyDatabaseId == dboid); strlcpy(dbname, NameStr(dbform->datname), sizeof(dbname)); /* pass the database name back to the caller */ if (out_dbname) strcpy(out_dbname, dbname); } /* Now we can mark our PGPROC entry with the database ID */ /* (We assume this is an atomic store so no lock is needed) */ MyProc->databaseId = MyDatabaseId; /* * Now, take a writer's lock on the database we are trying to connect to. * If there is a concurrently running DROP DATABASE on that database, this * will block us until it finishes (and has committed its update of * pg_database). * * Note that the lock is not held long, only until the end of this startup * transaction. This is OK since we are already advertising our use of * the database in the PGPROC array; anyone trying a DROP DATABASE after * this point will see us there. * * Note: use of RowExclusiveLock here is reasonable because we envision * our session as being a concurrent writer of the database. If we had a * way of declaring a session as being guaranteed-read-only, we could use * AccessShareLock for such sessions and thereby not conflict against * CREATE DATABASE. */ if (!bootstrap && !am_walsender) LockSharedObject(DatabaseRelationId, MyDatabaseId, 0, RowExclusiveLock); /* * Recheck pg_database to make sure the target database hasn't gone away. * If there was a concurrent DROP DATABASE, this ensures we will die * cleanly without creating a mess. */ if (!bootstrap && !am_walsender) { HeapTuple tuple; tuple = GetDatabaseTuple(dbname); if (!HeapTupleIsValid(tuple) || MyDatabaseId != HeapTupleGetOid(tuple) || MyDatabaseTableSpace != ((Form_pg_database) GETSTRUCT(tuple))->dattablespace) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("It seems to have just been dropped or renamed."))); } /* * Now we should be able to access the database directory safely. Verify * it's there and looks reasonable. */ fullpath = GetDatabasePath(MyDatabaseId, MyDatabaseTableSpace); if (!bootstrap && !am_walsender) { if (access(fullpath, F_OK) == -1) { if (errno == ENOENT) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("The database subdirectory \"%s\" is missing.", fullpath))); else ereport(FATAL, (errcode_for_file_access(), errmsg("could not access directory \"%s\": %m", fullpath))); } ValidatePgVersion(fullpath); } SetDatabasePath(fullpath); /* * It's now possible to do real access to the system catalogs. * * Load relcache entries for the system catalogs. This must create at * least the minimum set of "nailed-in" cache entries. */ RelationCacheInitializePhase3(); /* * Perform client authentication if necessary, then figure out our * postgres user ID, and see if we are a superuser. * * In standalone mode and in autovacuum worker processes, we use a fixed * ID, otherwise we figure it out from the authenticated user name. */ if (bootstrap || IsAutoVacuumWorkerProcess()) { InitializeSessionUserIdStandalone(); am_superuser = true; } else if (!IsUnderPostmaster) { InitializeSessionUserIdStandalone(); am_superuser = true; if (!ThereIsAtLeastOneRole()) ereport(WARNING, (errcode(ERRCODE_UNDEFINED_OBJECT), errmsg("no roles are defined in this database system"), errhint("You should immediately run CREATE USER \"%s\" SUPERUSER;.", username))); } else { /* normal multiuser case */ Assert(MyProcPort != NULL); PerformAuthentication(MyProcPort); InitializeSessionUserId(username); am_superuser = superuser(); } /* set up ACL framework (so CheckMyDatabase can check permissions) */ initialize_acl(); /* Process pg_db_role_setting options */ process_settings(MyDatabaseId, GetSessionUserId()); /* * Re-read the pg_database row for our database, check permissions and set * up database-specific GUC settings. We can't do this until all the * database-access infrastructure is up. (Also, it wants to know if the * user is a superuser, so the above stuff has to happen first.) */ if (!bootstrap && !am_walsender) CheckMyDatabase(dbname, am_superuser); /* * If we're trying to shut down, only superusers can connect. */ if (!am_superuser && MyProcPort != NULL && MyProcPort->canAcceptConnections == CAC_WAITBACKUP) ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("must be superuser to connect during database shutdown"))); /* * Check a normal user hasn't connected to a superuser reserved slot. */ if (!am_superuser && ReservedBackends > 0 && !HaveNFreeProcs(ReservedBackends)) ereport(FATAL, (errcode(ERRCODE_TOO_MANY_CONNECTIONS), errmsg("connection limit exceeded for non-superusers"))); /* * Now process any command-line switches that were included in the startup * packet, if we are in a regular backend. We couldn't do this before * because we didn't know if client is a superuser. */ gucctx = am_superuser ? PGC_SUSET : PGC_BACKEND; if (MyProcPort != NULL && MyProcPort->cmdline_options != NULL) { /* * The maximum possible number of commandline arguments that could * come from MyProcPort->cmdline_options is (strlen + 1) / 2; see * pg_split_opts(). */ char **av; int maxac; int ac; maxac = 2 + (strlen(MyProcPort->cmdline_options) + 1) / 2; av = (char **) palloc(maxac * sizeof(char *)); ac = 0; av[ac++] = "postgres"; /* Note this mangles MyProcPort->cmdline_options */ pg_split_opts(av, &ac, MyProcPort->cmdline_options); av[ac] = NULL; Assert(ac < maxac); (void) process_postgres_switches(ac, av, gucctx); } /* * Process any additional GUC variable settings passed in startup packet. * These are handled exactly like command-line variables. */ if (MyProcPort != NULL) { ListCell *gucopts = list_head(MyProcPort->guc_options); while (gucopts) { char *name; char *value; name = lfirst(gucopts); gucopts = lnext(gucopts); value = lfirst(gucopts); gucopts = lnext(gucopts); SetConfigOption(name, value, gucctx, PGC_S_CLIENT); } } /* Apply PostAuthDelay as soon as we've read all options */ if (PostAuthDelay > 0) pg_usleep(PostAuthDelay * 1000000L); /* * Initialize various default states that can't be set up until we've * selected the active user and gotten the right GUC settings. */ /* set default namespace search path */ InitializeSearchPath(); /* initialize client encoding */ InitializeClientEncoding(); /* reset the database for walsender */ if (am_walsender) MyProc->databaseId = MyDatabaseId = InvalidOid; /* report this backend in the PgBackendStatus array */ if (!bootstrap) pgstat_bestart(); /* close the transaction we started above */ if (!bootstrap) CommitTransactionCommand(); }
/* -------------------------------- * InitPostgres * Initialize POSTGRES. * * The database can be specified by name, using the in_dbname parameter, or by * OID, using the dboid parameter. In the latter case, the computed database * name is passed out to the caller as a palloc'ed string in out_dbname. * * In bootstrap mode no parameters are used. * * The return value indicates whether the userID is a superuser. (That * can only be tested inside a transaction, so we want to do it during * the startup transaction rather than doing a separate one in postgres.c.) * * As of PostgreSQL 8.2, we expect InitProcess() was already called, so we * already have a PGPROC struct ... but it's not filled in yet. * * Note: * Be very careful with the order of calls in the InitPostgres function. * -------------------------------- */ bool InitPostgres(const char *in_dbname, Oid dboid, const char *username, char **out_dbname) { bool bootstrap = IsBootstrapProcessingMode(); bool autovacuum = IsAutoVacuumWorkerProcess(); bool am_superuser; char *fullpath; char dbname[NAMEDATALEN]; /* * Set up the global variables holding database id and path. But note we * won't actually try to touch the database just yet. * * We take a shortcut in the bootstrap case, otherwise we have to look up * the db name in pg_database. */ if (bootstrap) { MyDatabaseId = TemplateDbOid; MyDatabaseTableSpace = DEFAULTTABLESPACE_OID; } else { /* * Find tablespace of the database we're about to open. Since we're * not yet up and running we have to use one of the hackish * FindMyDatabase variants, which look in the flat-file copy of * pg_database. * * If the in_dbname param is NULL, lookup database by OID. */ if (in_dbname == NULL) { if (!FindMyDatabaseByOid(dboid, dbname, &MyDatabaseTableSpace)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database %u does not exist", dboid))); MyDatabaseId = dboid; /* pass the database name to the caller */ *out_dbname = pstrdup(dbname); } else { if (!FindMyDatabase(in_dbname, &MyDatabaseId, &MyDatabaseTableSpace)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", in_dbname))); /* our database name is gotten from the caller */ strlcpy(dbname, in_dbname, NAMEDATALEN); } } fullpath = GetDatabasePath(MyDatabaseId, MyDatabaseTableSpace); SetDatabasePath(fullpath); /* * Finish filling in the PGPROC struct, and add it to the ProcArray. (We * need to know MyDatabaseId before we can do this, since it's entered * into the PGPROC struct.) * * Once I have done this, I am visible to other backends! */ InitProcessPhase2(); /* * Initialize my entry in the shared-invalidation manager's array of * per-backend data. * * Sets up MyBackendId, a unique backend identifier. */ MyBackendId = InvalidBackendId; SharedInvalBackendInit(); if (MyBackendId > MaxBackends || MyBackendId <= 0) elog(FATAL, "bad backend id: %d", MyBackendId); /* * bufmgr needs another initialization call too */ InitBufferPoolBackend(); /* * Initialize local process's access to XLOG. In bootstrap case we may * skip this since StartupXLOG() was run instead. */ if (!bootstrap) InitXLOGAccess(); /* * Initialize the relation cache and the system catalog caches. Note that * no catalog access happens here; we only set up the hashtable structure. * We must do this before starting a transaction because transaction abort * would try to touch these hashtables. */ RelationCacheInitialize(); InitCatalogCache(); InitPlanCache(); /* Initialize portal manager */ EnablePortalManager(); /* Initialize stats collection --- must happen before first xact */ if (!bootstrap) pgstat_initialize(); /* * Set up process-exit callback to do pre-shutdown cleanup. This has to * be after we've initialized all the low-level modules like the buffer * manager, because during shutdown this has to run before the low-level * modules start to close down. On the other hand, we want it in place * before we begin our first transaction --- if we fail during the * initialization transaction, as is entirely possible, we need the * AbortTransaction call to clean up. */ on_shmem_exit(ShutdownPostgres, 0); /* * Start a new transaction here before first access to db, and get a * snapshot. We don't have a use for the snapshot itself, but we're * interested in the secondary effect that it sets RecentGlobalXmin. */ if (!bootstrap) { StartTransactionCommand(); (void) GetTransactionSnapshot(); } /* * Now that we have a transaction, we can take locks. Take a writer's * lock on the database we are trying to connect to. If there is a * concurrently running DROP DATABASE on that database, this will block us * until it finishes (and has updated the flat file copy of pg_database). * * Note that the lock is not held long, only until the end of this startup * transaction. This is OK since we are already advertising our use of * the database in the PGPROC array; anyone trying a DROP DATABASE after * this point will see us there. * * Note: use of RowExclusiveLock here is reasonable because we envision * our session as being a concurrent writer of the database. If we had a * way of declaring a session as being guaranteed-read-only, we could use * AccessShareLock for such sessions and thereby not conflict against * CREATE DATABASE. */ if (!bootstrap) LockSharedObject(DatabaseRelationId, MyDatabaseId, 0, RowExclusiveLock); /* * Recheck the flat file copy of pg_database to make sure the target * database hasn't gone away. If there was a concurrent DROP DATABASE, * this ensures we will die cleanly without creating a mess. */ if (!bootstrap) { Oid dbid2; Oid tsid2; if (!FindMyDatabase(dbname, &dbid2, &tsid2) || dbid2 != MyDatabaseId || tsid2 != MyDatabaseTableSpace) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("It seems to have just been dropped or renamed."))); } /* * Now we should be able to access the database directory safely. Verify * it's there and looks reasonable. */ if (!bootstrap) { if (access(fullpath, F_OK) == -1) { if (errno == ENOENT) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("The database subdirectory \"%s\" is missing.", fullpath))); else ereport(FATAL, (errcode_for_file_access(), errmsg("could not access directory \"%s\": %m", fullpath))); } ValidatePgVersion(fullpath); } /* * It's now possible to do real access to the system catalogs. * * Load relcache entries for the system catalogs. This must create at * least the minimum set of "nailed-in" cache entries. */ RelationCacheInitializePhase2(); /* * Figure out our postgres user id, and see if we are a superuser. * * In standalone mode and in the autovacuum process, we use a fixed id, * otherwise we figure it out from the authenticated user name. */ if (bootstrap || autovacuum) { InitializeSessionUserIdStandalone(); am_superuser = true; } else if (!IsUnderPostmaster) { InitializeSessionUserIdStandalone(); am_superuser = true; if (!ThereIsAtLeastOneRole()) ereport(WARNING, (errcode(ERRCODE_UNDEFINED_OBJECT), errmsg("no roles are defined in this database system"), errhint("You should immediately run CREATE USER \"%s\" CREATEUSER;.", username))); } else { /* normal multiuser case */ InitializeSessionUserId(username); am_superuser = superuser(); } /* set up ACL framework (so CheckMyDatabase can check permissions) */ initialize_acl(); /* * Read the real pg_database row for our database, check permissions and * set up database-specific GUC settings. We can't do this until all the * database-access infrastructure is up. (Also, it wants to know if the * user is a superuser, so the above stuff has to happen first.) */ if (!bootstrap) CheckMyDatabase(dbname, am_superuser); /* * If we're trying to shut down, only superusers can connect. */ if (!am_superuser && MyProcPort != NULL && MyProcPort->canAcceptConnections == CAC_WAITBACKUP) ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("must be superuser to connect during database shutdown"))); /* * Check a normal user hasn't connected to a superuser reserved slot. */ if (!am_superuser && ReservedBackends > 0 && !HaveNFreeProcs(ReservedBackends)) ereport(FATAL, (errcode(ERRCODE_TOO_MANY_CONNECTIONS), errmsg("connection limit exceeded for non-superusers"))); /* * Initialize various default states that can't be set up until we've * selected the active user and gotten the right GUC settings. */ /* set default namespace search path */ InitializeSearchPath(); /* initialize client encoding */ InitializeClientEncoding(); /* report this backend in the PgBackendStatus array */ if (!bootstrap) pgstat_bestart(); /* close the transaction we started above */ if (!bootstrap) CommitTransactionCommand(); return am_superuser; }
/* -------------------------------- * InitPostgres * Initialize POSTGRES. * * The database can be specified by name, using the in_dbname parameter, or by * OID, using the dboid parameter. In the latter case, the actual database * name can be returned to the caller in out_dbname. If out_dbname isn't * NULL, it must point to a buffer of size NAMEDATALEN. * * In bootstrap mode no parameters are used. * * The return value indicates whether the userID is a superuser. (That * can only be tested inside a transaction, so we want to do it during * the startup transaction rather than doing a separate one in postgres.c.) * * As of PostgreSQL 8.2, we expect InitProcess() was already called, so we * already have a PGPROC struct ... but it's not filled in yet. * * Note: * Be very careful with the order of calls in the InitPostgres function. * -------------------------------- */ void InitPostgres(const char *in_dbname, Oid dboid, const char *username, char *out_dbname) { bool bootstrap = IsBootstrapProcessingMode(); bool autovacuum = IsAutoVacuumProcess(); bool am_superuser; char *fullpath; char dbname[NAMEDATALEN]; /* * Add my PGPROC struct to the ProcArray. * * Once I have done this, I am visible to other backends! */ InitProcessPhase2(); /* Initialize SessionState entry */ SessionState_Init(); /* Initialize memory protection */ GPMemoryProtect_Init(); /* * Initialize my entry in the shared-invalidation manager's array of * per-backend data. * * Sets up MyBackendId, a unique backend identifier. */ MyBackendId = InvalidBackendId; SharedInvalBackendInit(false); if (MyBackendId > MaxBackends || MyBackendId <= 0) elog(FATAL, "bad backend id: %d", MyBackendId); /* Now that we have a BackendId, we can participate in ProcSignal */ ProcSignalInit(MyBackendId); /* * bufmgr needs another initialization call too */ InitBufferPoolBackend(); /* * Initialize local process's access to XLOG. In bootstrap case we may * skip this since StartupXLOG() was run instead. */ if (!bootstrap) InitXLOGAccess(); /* * Initialize the relation cache and the system catalog caches. Note that * no catalog access happens here; we only set up the hashtable structure. * We must do this before starting a transaction because transaction abort * would try to touch these hashtables. */ RelationCacheInitialize(); InitCatalogCache(); /* Initialize portal manager */ EnablePortalManager(); /* Initialize stats collection --- must happen before first xact */ if (!bootstrap) pgstat_initialize(); /* * Load relcache entries for the shared system catalogs. This must create * at least entries for pg_database and catalogs used for authentication. */ RelationCacheInitializePhase2(); /* * Set up process-exit callback to do pre-shutdown cleanup. This has to * be after we've initialized all the low-level modules like the buffer * manager, because during shutdown this has to run before the low-level * modules start to close down. On the other hand, we want it in place * before we begin our first transaction --- if we fail during the * initialization transaction, as is entirely possible, we need the * AbortTransaction call to clean up. */ on_shmem_exit(ShutdownPostgres, 0); /* TODO: autovacuum launcher should be done here? */ /* * Start a new transaction here before first access to db, and get a * snapshot. We don't have a use for the snapshot itself, but we're * interested in the secondary effect that it sets RecentGlobalXmin. */ if (!bootstrap) { StartTransactionCommand(); (void) GetTransactionSnapshot(); } /* * Figure out our postgres user id, and see if we are a superuser. * * In standalone mode and in the autovacuum process, we use a fixed id, * otherwise we figure it out from the authenticated user name. */ if (bootstrap || autovacuum) { InitializeSessionUserIdStandalone(); am_superuser = true; } else if (!IsUnderPostmaster) { InitializeSessionUserIdStandalone(); am_superuser = true; if (!ThereIsAtLeastOneRole()) ereport(WARNING, (errcode(ERRCODE_UNDEFINED_OBJECT), errmsg("no roles are defined in this database system"), errhint("You should immediately run CREATE USER \"%s\" CREATEUSER;.", username))); } else { /* normal multiuser case */ Assert(MyProcPort != NULL); PerformAuthentication(MyProcPort); InitializeSessionUserId(username); am_superuser = superuser(); } /* * Check a normal user hasn't connected to a superuser reserved slot. */ if (!am_superuser && ReservedBackends > 0 && !HaveNFreeProcs(ReservedBackends)) ereport(FATAL, (errcode(ERRCODE_TOO_MANY_CONNECTIONS), errmsg("connection limit exceeded for non-superusers"), errSendAlert(true))); /* * If walsender, we don't want to connect to any particular database. Just * finish the backend startup by processing any options from the startup * packet, and we're done. */ if (am_walsender) { Assert(!bootstrap); /* * We don't have replication role, which existed in postgres. */ if (!superuser()) ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("must be superuser role to start walsender"))); /* process any options passed in the startup packet */ if (MyProcPort != NULL) process_startup_options(MyProcPort, am_superuser); /* Apply PostAuthDelay as soon as we've read all options */ if (PostAuthDelay > 0) pg_usleep(PostAuthDelay * 1000000L); /* initialize client encoding */ InitializeClientEncoding(); /* report this backend in the PgBackendStatus array */ pgstat_bestart(); /* close the transaction we started above */ CommitTransactionCommand(); return; } /* * Set up the global variables holding database id and path. But note we * won't actually try to touch the database just yet. * * We take a shortcut in the bootstrap case, otherwise we have to look up * the db name in pg_database. */ if (bootstrap) { MyDatabaseId = TemplateDbOid; MyDatabaseTableSpace = DEFAULTTABLESPACE_OID; } else if (in_dbname != NULL) { HeapTuple tuple; Form_pg_database dbform; tuple = GetDatabaseTuple(in_dbname); if (!HeapTupleIsValid(tuple)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", in_dbname))); dbform = (Form_pg_database) GETSTRUCT(tuple); MyDatabaseId = HeapTupleGetOid(tuple); MyDatabaseTableSpace = dbform->dattablespace; /* take database name from the caller, just for paranoia */ strlcpy(dbname, in_dbname, sizeof(dbname)); pfree(tuple); } else { /* caller specified database by OID */ HeapTuple tuple; Form_pg_database dbform; tuple = GetDatabaseTupleByOid(dboid); if (!HeapTupleIsValid(tuple)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database %u does not exist", dboid))); dbform = (Form_pg_database) GETSTRUCT(tuple); MyDatabaseId = HeapTupleGetOid(tuple); MyDatabaseTableSpace = dbform->dattablespace; Assert(MyDatabaseId == dboid); strlcpy(dbname, NameStr(dbform->datname), sizeof(dbname)); /* pass the database name back to the caller */ if (out_dbname) strcpy(out_dbname, dbname); pfree(tuple); } /* Now we can mark our PGPROC entry with the database ID */ /* (We assume this is an atomic store so no lock is needed) */ MyProc->databaseId = MyDatabaseId; /* * Now, take a writer's lock on the database we are trying to connect to. * If there is a concurrently running DROP DATABASE on that database, this * will block us until it finishes (and has committed its update of * pg_database). * * Note that the lock is not held long, only until the end of this startup * transaction. This is OK since we are already advertising our use of * the database in the PGPROC array; anyone trying a DROP DATABASE after * this point will see us there. * * Note: use of RowExclusiveLock here is reasonable because we envision * our session as being a concurrent writer of the database. If we had a * way of declaring a session as being guaranteed-read-only, we could use * AccessShareLock for such sessions and thereby not conflict against * CREATE DATABASE. */ if (!bootstrap) LockSharedObject(DatabaseRelationId, MyDatabaseId, 0, RowExclusiveLock); /* * Recheck pg_database to make sure the target database hasn't gone away. * If there was a concurrent DROP DATABASE, this ensures we will die * cleanly without creating a mess. */ if (!bootstrap) { HeapTuple tuple; tuple = GetDatabaseTuple(dbname); if (!HeapTupleIsValid(tuple) || MyDatabaseId != HeapTupleGetOid(tuple) || MyDatabaseTableSpace != ((Form_pg_database) GETSTRUCT(tuple))->dattablespace) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("It seems to have just been dropped or renamed."))); } fullpath = GetDatabasePath(MyDatabaseId, MyDatabaseTableSpace); if (!bootstrap) { if (access(fullpath, F_OK) == -1) { if (errno == ENOENT) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exist", dbname), errdetail("The database subdirectory \"%s\" is missing.", fullpath))); else ereport(FATAL, (errcode_for_file_access(), errmsg("could not access directory \"%s\": %m", fullpath))); } ValidatePgVersion(fullpath); } SetDatabasePath(fullpath); /* * It's now possible to do real access to the system catalogs. * * Load relcache entries for the system catalogs. This must create at * least the minimum set of "nailed-in" cache entries. */ RelationCacheInitializePhase3(); /* * Now we have full access to catalog including toast tables, * we can process pg_authid.rolconfig. This ought to come before * processing startup options so that it can override the settings. */ if (!bootstrap) ProcessRoleGUC(); /* set up ACL framework (so CheckMyDatabase can check permissions) */ initialize_acl(); /* * Re-read the pg_database row for our database, check permissions and set * up database-specific GUC settings. We can't do this until all the * database-access infrastructure is up. (Also, it wants to know if the * user is a superuser, so the above stuff has to happen first.) */ if (!bootstrap) CheckMyDatabase(dbname, am_superuser); /* * Now process any command-line switches and any additional GUC variable * settings passed in the startup packet. We couldn't do this before * because we didn't know if client is a superuser. */ if (MyProcPort != NULL) process_startup_options(MyProcPort, am_superuser); /* * Maintenance Mode: allow superuser to connect when * gp_maintenance_conn GUC is set. We cannot check it until * process_startup_options parses the GUC. */ if (gp_maintenance_mode && Gp_role == GP_ROLE_DISPATCH && !(superuser() && gp_maintenance_conn)) ereport(FATAL, (errcode(ERRCODE_INSUFFICIENT_PRIVILEGE), errmsg("maintenance mode: connected by superuser only"), errSendAlert(false))); /* * MPP: If we were started in utility mode then we only want to allow * incoming sessions that specify gp_session_role=utility as well. This * lets the bash scripts start the QD in utility mode and connect in but * protect ourselves from normal clients who might be trying to connect to * the system while we startup. */ if ((Gp_role == GP_ROLE_UTILITY) && (Gp_session_role != GP_ROLE_UTILITY)) { ereport(FATAL, (errcode(ERRCODE_CANNOT_CONNECT_NOW), errmsg("System was started in master-only utility mode - only utility mode connections are allowed"))); } /* Apply PostAuthDelay as soon as we've read all options */ if (PostAuthDelay > 0) pg_usleep(PostAuthDelay * 1000000L); /* set default namespace search path */ InitializeSearchPath(); /* initialize client encoding */ InitializeClientEncoding(); /* report this backend in the PgBackendStatus array */ if (!bootstrap) pgstat_bestart(); /* * MPP package setup * * Primary function is to establish connctions to the qExecs. * This is SKIPPED when the database is in bootstrap mode or * Is not UnderPostmaster. */ if (!bootstrap && IsUnderPostmaster) { cdb_setup(); on_proc_exit( cdb_cleanup, 0 ); } /* * MPP SharedSnapshot Setup */ if (Gp_role == GP_ROLE_DISPATCH) { addSharedSnapshot("Query Dispatcher", gp_session_id); } else if (Gp_role == GP_ROLE_DISPATCHAGENT) { SharedLocalSnapshotSlot = NULL; } else if (Gp_segment == -1 && Gp_role == GP_ROLE_EXECUTE && !Gp_is_writer) { /* * Entry db singleton QE is a user of the shared snapshot -- not a creator. * The lookup will occur once the distributed snapshot has been received. */ lookupSharedSnapshot("Entry DB Singleton", "Query Dispatcher", gp_session_id); } else if (Gp_role == GP_ROLE_EXECUTE) { if (Gp_is_writer) { addSharedSnapshot("Writer qExec", gp_session_id); } else { /* * NOTE: This assumes that the Slot has already been * allocated by the writer. Need to make sure we * always allocate the writer qExec first. */ lookupSharedSnapshot("Reader qExec", "Writer qExec", gp_session_id); } } /* close the transaction we started above */ if (!bootstrap) CommitTransactionCommand(); return; }
/* * FtsProbeMain */ NON_EXEC_STATIC void ftsMain(int argc, char *argv[]) { sigjmp_buf local_sigjmp_buf; char *fullpath; IsUnderPostmaster = true; am_ftsprobe = true; /* Stay away from PMChildSlot */ MyPMChildSlot = -1; /* reset MyProcPid */ MyProcPid = getpid(); /* Lose the postmaster's on-exit routines */ on_exit_reset(); /* Identify myself via ps */ init_ps_display("ftsprobe process", "", "", ""); SetProcessingMode(InitProcessing); /* * reread postgresql.conf if requested */ pqsignal(SIGHUP, sigHupHandler); /* * Presently, SIGINT will lead to autovacuum shutdown, because that's how * we handle ereport(ERROR). It could be improved however. */ pqsignal(SIGINT, ReqFtsFullScan); /* request full-scan */ pqsignal(SIGTERM, die); pqsignal(SIGQUIT, quickdie); /* we don't do any ftsprobe specific cleanup, just use the standard. */ pqsignal(SIGALRM, handle_sig_alarm); pqsignal(SIGPIPE, SIG_IGN); pqsignal(SIGUSR1, procsignal_sigusr1_handler); /* We don't listen for async notifies */ pqsignal(SIGUSR2, RequestShutdown); pqsignal(SIGFPE, FloatExceptionHandler); pqsignal(SIGCHLD, SIG_DFL); /* * Copied from bgwriter */ CurrentResourceOwner = ResourceOwnerCreate(NULL, "FTS Probe"); /* Early initialization */ BaseInit(); /* See InitPostgres()... */ InitProcess(); InitBufferPoolBackend(); InitXLOGAccess(); SetProcessingMode(NormalProcessing); /* * If an exception is encountered, processing resumes here. * * See notes in postgres.c about the design of this coding. */ if (sigsetjmp(local_sigjmp_buf, 1) != 0) { /* Prevents interrupts while cleaning up */ HOLD_INTERRUPTS(); /* Report the error to the server log */ EmitErrorReport(); /* * We can now go away. Note that because we'll call InitProcess, a * callback will be registered to do ProcKill, which will clean up * necessary state. */ proc_exit(0); } /* We can now handle ereport(ERROR) */ PG_exception_stack = &local_sigjmp_buf; PG_SETMASK(&UnBlockSig); /* * Add my PGPROC struct to the ProcArray. * * Once I have done this, I am visible to other backends! */ InitProcessPhase2(); /* * Initialize my entry in the shared-invalidation manager's array of * per-backend data. * * Sets up MyBackendId, a unique backend identifier. */ MyBackendId = InvalidBackendId; SharedInvalBackendInit(false); if (MyBackendId > MaxBackends || MyBackendId <= 0) elog(FATAL, "bad backend id: %d", MyBackendId); /* * bufmgr needs another initialization call too */ InitBufferPoolBackend(); /* heap access requires the rel-cache */ RelationCacheInitialize(); InitCatalogCache(); /* * It's now possible to do real access to the system catalogs. * * Load relcache entries for the system catalogs. This must create at * least the minimum set of "nailed-in" cache entries. */ RelationCacheInitializePhase2(); /* * In order to access the catalog, we need a database, and a * tablespace; our access to the heap is going to be slightly * limited, so we'll just use some defaults. */ if (!FindMyDatabase(probeDatabase, &MyDatabaseId, &MyDatabaseTableSpace)) ereport(FATAL, (errcode(ERRCODE_UNDEFINED_DATABASE), errmsg("database \"%s\" does not exit", probeDatabase))); /* Now we can mark our PGPROC entry with the database ID */ /* (We assume this is an atomic store so no lock is needed) */ MyProc->databaseId = MyDatabaseId; fullpath = GetDatabasePath(MyDatabaseId, MyDatabaseTableSpace); SetDatabasePath(fullpath); RelationCacheInitializePhase3(); /* shmem: publish probe pid */ ftsProbeInfo->fts_probePid = MyProcPid; /* main loop */ FtsLoop(); /* One iteration done, go away */ proc_exit(0); }