/* ------------------------------------------------------------------- * * bdberl: Berkeley DB Driver for Erlang * Copyright (c) 2008 The Hive. All rights reserved. * * ------------------------------------------------------------------- */ #include #include #include #include #include "hive_hash.h" #include "bdberl_drv.h" #include "bin_helper.h" /** * Function prototypes */ static int open_database(const char* name, DBTYPE type, PortData* data, int* errno); static int close_database(int dbref, PortData* data); static int add_dbref(PortData* data, int dbref); static int del_dbref(PortData* data, int dbref); static int add_portref(int dbref, ErlDrvPort port); static int del_portref(int dbref, ErlDrvPort port); static int alloc_dbref(); static void* zalloc(unsigned int size); /** * Global instance of DB_ENV; only a single one exists per O/S process. */ static DB_ENV* G_DB_ENV; /** * Global variable to track the return code from opening the DB_ENV. We track this * value so as to provide a useful error code when the user attempts to open the * port and it fails due to an error that occurred when opening the environment. */ static int G_DB_ENV_ERROR; /** * G_DATABASES is a global array of Database structs. Used to track currently opened DB* * handles and ensure that they get cleaned up when all ports which were using them exit or * explicitly close them. * * This array is allocated when the driver is first initialized and does not grow/shrink * dynamically. G_DATABASES_SIZE contains the size of the array. G_DATABASES_NAMES is a hash of * filenames to array index for an opened Database. * * All access to G_DATABASES and G_DATABASES_NAMES must be protected by the read/write lock * G_DATABASES_RWLOCK. */ static Database* G_DATABASES; static int G_DATABASES_SIZE; static ErlDrvRWLock* G_DATABASES_RWLOCK; static hive_hash* G_DATABASES_NAMES; /** * Helpful macros */ #define READ_LOCK(L) erl_drv_rwlock_rlock(L) #define READ_UNLOCK(L) erl_drv_rwlock_runlock(L) #define PROMOTE_READ_LOCK(L) { erl_drv_rwlock_runlock(L); erl_drv_rwlock_rwlock(L); } #define WRITE_LOCK(L) erl_drv_rwlock_rwlock(L) #define WRITE_UNLOCK(L) erl_drv_rwlock_rwunlock(L) DRIVER_INIT(bdberl_drv) { printf("DRIVER INIT\n"); // Setup flags we'll use to init the environment int flags = DB_INIT_LOCK | /* Enable support for locking */ DB_INIT_TXN | /* Enable support for transactions */ DB_INIT_MPOOL | /* Enable support for memory pools */ DB_RECOVER | /* Enable support for recovering from failures */ DB_CREATE | /* Create files as necessary */ DB_REGISTER | /* Run recovery if needed */ DB_THREAD; /* Make the environment free-threaded */ // Initialize global environment -- use environment variable DB_HOME to // specify where the working directory is db_env_create(&G_DB_ENV, 0); G_DB_ENV_ERROR = G_DB_ENV->open(G_DB_ENV, 0, flags, 0); if (G_DB_ENV_ERROR == 0) { // Use the BDBERL_MAX_DBS environment value to determine the max # of // databases to permit the VM to open at once. Defaults to 1024. G_DATABASES_SIZE = 1024; char* max_dbs_str = getenv("BDBERL_MAX_DBS"); if (max_dbs_str != 0) { G_DATABASES_SIZE = atoi(max_dbs_str); if (G_DATABASES_SIZE <= 0) { G_DATABASES_SIZE = 1024; } } // BDB is setup -- allocate structures for tracking databases G_DATABASES = (Database*) driver_alloc(sizeof(Database) * G_DATABASES_SIZE); memset(G_DATABASES, '\0', sizeof(Database) * G_DATABASES_SIZE); G_DATABASES_RWLOCK = erl_drv_rwlock_create("bdberl_drv: G_DATABASES_RWLOCK"); G_DATABASES_NAMES = hive_hash_new(G_DATABASES_SIZE); } else { // Something bad happened while initializing BDB; in this situation we // cleanup and set the environment to zero. Attempts to open ports will // fail and the user will have to sort out how to resolve the issue. G_DB_ENV->close(G_DB_ENV, 0); G_DB_ENV = 0; } return &bdberl_drv_entry; } static ErlDrvData bdberl_drv_start(ErlDrvPort port, char* buffer) { // Make sure we have a functional environment -- if we don't, // bail... if (!G_DB_ENV) { return ERL_DRV_ERROR_BADARG; } PortData* d = (PortData*)driver_alloc(sizeof(PortData)); memset(d, '\0', sizeof(PortData)); // Save handle to the port d->port = port; // Make sure port is running in binary mode set_port_control_flags(port, PORT_CONTROL_FLAG_BINARY); return (ErlDrvData)d; } static void bdberl_drv_stop(ErlDrvData handle) { PortData* d = (PortData*)handle; // TODO: Terminate any txns // Close all the databases we previously opened while (d->dbrefs) { close_database(d->dbrefs->dbref, d); } // Release the port instance data driver_free(handle); } static void bdberl_drv_finish() { // Driver is unloading -- cleanup and shut down the BDB environment. Note that we assume // all ports have been released and thuse all databases/txns/etc are also gone. G_DB_ENV->close(G_DB_ENV, 0); driver_free(G_DATABASES); erl_drv_rwlock_destroy(G_DATABASES_RWLOCK); hive_hash_destroy(G_DATABASES_NAMES); } static int bdberl_drv_control(ErlDrvData handle, unsigned int cmd, char* inbuf, int inbuf_sz, char** outbuf, int outbuf_sz) { PortData* d = (PortData*)handle; switch(cmd) { case CMD_OPEN_DB: { // Extract the type code and filename from the inbuf // Expect: Type:8, Name/bytes, NULL:8 DBTYPE type = (DBTYPE)((char)*inbuf); char* name = (char*)(inbuf+1); int dbref; int status; int rc = open_database(name, type, d, &dbref); if (rc == 0) { status = STATUS_OK; } else { status = STATUS_ERROR; dbref = rc; } // Pack the status and dbref (or errno) into a binary and return it // Byte 0 : Status // Byte 1..4: dbref/errno BinHelper bh; bin_helper_init(&bh, 5); bin_helper_push_byte(&bh, status); bin_helper_push_int32(&bh, dbref); *outbuf = (char*)bh.bin; return bh.bin->orig_size; } case CMD_CLOSE_DB: { // TODO: If data is inflight, fail. Abort any open txns. // Take the provided dbref and attempt to close it int dbref = *((int*)inbuf); int rc = close_database(dbref, d); // Setup to return the rc BinHelper bh; bin_helper_init(&bh, 4); bin_helper_push_int32(&bh, rc); *outbuf = (char*)bh.bin; return bh.bin->orig_size; } } *outbuf = 0; return 0; } static void bdberl_drv_ready_async(ErlDrvData handle, ErlDrvThreadData thread_data) { } static void bdberl_drv_process_exit(ErlDrvData handle, ErlDrvMonitor *monitor) { } static int open_database(const char* name, DBTYPE type, PortData* data, int* dbref_res) { *dbref_res = -1; READ_LOCK(G_DATABASES_RWLOCK); // Look up the database by name in our hash table Database* database = (Database*)hive_hash_get(G_DATABASES_NAMES, name); if (database) { // Convert the database pointer into a dbref int dbref = database - G_DATABASES; // Great, the database was previously opened by someone else. Add it to our // list of refs, and if it's a new addition also register this port with the // Database structure in G_DATABASES if (add_dbref(data, dbref)) { // Need to update G_DATABASES -- grab the write lock PROMOTE_READ_LOCK(G_DATABASES_RWLOCK); // Add a reference to this port add_portref(dbref, data->port); // Release RW lock and return the ref WRITE_UNLOCK(G_DATABASES_RWLOCK); *dbref_res = dbref; return 0; } else { // Already in our list of opened databases -- unlock and return the reference READ_UNLOCK(G_DATABASES_RWLOCK); *dbref_res = dbref; return 0; } } else { // This database hasn't been opened yet -- grab a write lock PROMOTE_READ_LOCK(G_DATABASES_RWLOCK); // While waiting on the write lock, another thread could have slipped in and // opened the database, so do one more check to see if the database is already // open database = (Database*)hive_hash_get(G_DATABASES_NAMES, name); if (database) { // Database got created while we were waiting on the write lock, add a reference // to our port and drop the lock ASAP int dbref = database - G_DATABASES; add_portref(dbref, data->port); WRITE_UNLOCK(G_DATABASES_RWLOCK); add_dbref(data, dbref); *dbref_res = dbref; return 0; } // Database hasn't been created while we were waiting on write lock, so // create/open it // Find the first available slot in G_DATABASES; the index will be our // reference for database operations int dbref = alloc_dbref(); if (dbref < 0) { // No more slots available WRITE_UNLOCK(G_DATABASES_RWLOCK); return ERROR_MAX_DBS; } // Create the DB handle DB* db; int rc = db_create(&db, G_DB_ENV, 0); if (rc != 0) { // Failure while creating the database handle -- drop our lock and return // the code WRITE_UNLOCK(G_DATABASES_RWLOCK); return rc; } // Attempt to open our database rc = db->open(db, 0, name, 0, type, DB_CREATE | DB_AUTO_COMMIT | DB_THREAD, 0); if (rc != 0) { // Failure while opening the database -- cleanup the handle, drop the lock // and return db->close(db, 0); WRITE_UNLOCK(G_DATABASES_RWLOCK); return rc; } // Database is open. Store all the data into the allocated ref G_DATABASES[dbref].db = db; G_DATABASES[dbref].name = strdup(name); G_DATABASES[dbref].ports = zalloc(sizeof(PortList)); G_DATABASES[dbref].ports->port = data->port; // Make entry in hash table of names hive_hash_add(G_DATABASES_NAMES, G_DATABASES[dbref].name, &(G_DATABASES[dbref])); // Drop the write lock WRITE_UNLOCK(G_DATABASES_RWLOCK); // Add the dbref to the port list add_dbref(data, dbref); *dbref_res = dbref; return 0; } } static int close_database(int dbref, PortData* data) { printf("Closing %d for port %p\n", dbref, data->port); // Remove this database from our list if (del_dbref(data, dbref)) { // Something was actually deleted from our list -- now we need to disassociate the // calling port with the global database structure. WRITE_LOCK(G_DATABASES_RWLOCK); assert(G_DATABASES[dbref].db != 0); assert(G_DATABASES[dbref].ports != 0); // Now disassociate this port from the database's port list del_portref(dbref, data->port); // Finally, if there are no other references to the database, close out // the database completely Database* database = &G_DATABASES[dbref]; if (database->ports == 0) { printf("Closing actual database for dbref %d\n", dbref); // Close out the BDB handle database->db->close(database->db, 0); // Remove the entry from the names map hive_hash_remove(G_DATABASES_NAMES, database->name); free((char*)database->name); // Zero out the whole record memset(database, '\0', sizeof(Database)); } WRITE_UNLOCK(G_DATABASES_RWLOCK); return 1; } return 0; } static void* zalloc(unsigned int size) { void* res = driver_alloc(size); memset(res, '\0', size); return res; } #define zfree(p) driver_free(p) static int add_portref(int dbref, ErlDrvPort port) { PortList* current = G_DATABASES[dbref].ports; if (current) { PortList* last = 0; do { // If the current item matches our port, bail -- nothing to do here if (current->port == port) { return 0; } last = current; current = current->next; } while (current != 0); // At the end of the list -- allocate a new entry for this por current = (PortList*)zalloc(sizeof(PortList)); current->port = port; last->next = current; return 1; } else { // Current was initially NULL, so alloc the first one and add it. current = zalloc(sizeof(PortList)); current->port = port; G_DATABASES[dbref].ports = current; return 1; } } static int del_portref(int dbref, ErlDrvPort port) { PortList* current = G_DATABASES[dbref].ports; PortList* last = 0; while (current) { if (current->port == port) { // Found our match -- look back and connect the last item to our next if (last) { last->next = current->next; } else { G_DATABASES[dbref].ports = current->next; } // Delete this entry zfree(current); return 1; } last = current; current = current->next; } // Didn't delete anything return 0; } /** * Add a db reference to a port's DbRefList. Returns 1 if added; 0 if already present */ static int add_dbref(PortData* data, int dbref) { DbRefList* current = data->dbrefs; if (current) { DbRefList* last = 0; do { if (current->dbref == dbref) { return 0; } last = current; current = current->next; } while (current != 0); // At the end of the list -- allocate a new entry current = zalloc(sizeof(DbRefList)); current->dbref = dbref; last->next = current; return 1; } else { // Current was initially NULL, so alloc the first one current = zalloc(sizeof(DbRefList)); current->dbref = dbref; data->dbrefs = current; return 1; } } /** * Delete a db reference from a port's DbRefList. Returns 1 if deleted; 0 if not */ static int del_dbref(PortData* data, int dbref) { DbRefList* current = data->dbrefs; DbRefList* last = 0; while (current) { if (current->dbref == dbref) { // Found our match -- look back and connect the last item to our next if (last) { last->next = current->next; } else { data->dbrefs = current->next; } // Delete this entry zfree(current); return 1; } last = current; current = current->next; } // Didn't delete anything return 0; } /** * Allocate a Database structure; find first available slot in G_DATABASES and return the * index of it. If no free slots are available, return -1 */ static int alloc_dbref() { int i; for (i = 0; i < G_DATABASES_SIZE; i++) { if (G_DATABASES[i].db == 0) { return i; } } return -1; }