int Test::ServantI::getTotalBalance(const Current& current) { Test::AccountPrxSeq proxies = getAccounts(current); // // Need to start a transaction to ensure a consistent result // Freeze::TransactionalEvictorPtr te = Freeze::TransactionalEvictorPtr::dynamicCast(_evictor); for(;;) { test(te->getCurrentTransaction() == 0); Freeze::ConnectionPtr con = Freeze::createConnection(current.adapter->getCommunicator(), _remoteEvictor->envName()); te->setCurrentTransaction(con->beginTransaction()); int total = 0; try { for(size_t i = 0; i < proxies.size(); ++i) { total += proxies[i]->getBalance(); } te->getCurrentTransaction()->rollback(); te->setCurrentTransaction(0); return total; } catch(const Freeze::TransactionalEvictorDeadlockException&) { te->getCurrentTransaction()->rollback(); te->setCurrentTransaction(0); // retry } catch(...) { te->getCurrentTransaction()->rollback(); te->setCurrentTransaction(0); throw; } } return -1; }
// _bankPrx->reloadBets(); // // Create players / recreate missing players missing players using a transaction // (the transaction is not really necessary here, but a good demo) // const string players[] = { "al", "bob", "charlie", "dave", "ed", "fred", "gene", "herb", "irvin", "joe", "ken", "lance" }; Freeze::ConnectionPtr connection = Freeze::createConnection(communicator(), _envName); Freeze::TransactionPtr tx = connection->beginTransaction(); _playerEvictor->setCurrentTransaction(tx); for(size_t i = 0; i < 12; ++i) { Ice::Identity ident = { players[i], "player" }; if(!_playerEvictor->hasObject(ident)) { _playerEvictor->add(new PlayerI, ident); } } tx->commit(); assert(_playerEvictor->getCurrentTransaction() == 0); connection = 0;
int WarehouseServer::run(int argc, char* argv[]) { bool useSimpleEvictor = argc > 1 && string(argv[1]) == "simple"; if(useSimpleEvictor) { cout << "Using SimpleEvictor" << endl; } else { cout << "Using Evictor implemented with IceUtil::Cache" << endl; } Ice::ObjectAdapterPtr adapter = communicator()->createObjectAdapter("Warehouse"); const string envName = "db"; const string dbName = "items"; { // // Open our database, a Freeze dictionary. // Freeze::ConnectionPtr connection = Freeze::createConnection(communicator(), envName); Database db(connection, dbName); if(db.empty()) { cout << "Creating new database..." << flush; // // Populate database with objectCount entries. // ItemInfo info; connection->beginTransaction(); for(int i = 0; i < objectCount; ++i) { ostringstream os; os << "P/N " << i; string name = os.str(); info.description = "The description of " + name; info.unitPrice = i + 0.95f; info.quantityInStock = i; info.filler = string(5000, 'x'); db.put(Database::value_type(name, info)); } connection->currentTransaction()->commit(); cout << "done" << endl; } } CurrentDatabase currentDb(communicator(), envName, dbName); // // This servant locator (evictor) will intercept all categories. // if(useSimpleEvictor) { adapter->addServantLocator(new SimpleEvictor(currentDb, evictorSize), ""); } else { adapter->addServantLocator(new Evictor(currentDb, evictorSize), ""); } adapter->activate(); communicator()->waitForShutdown(); return EXIT_SUCCESS; }
static int run(const Ice::StringSeq& originalArgs, const Ice::CommunicatorPtr& communicator) { vector<string> oldCppArgs; vector<string> newCppArgs; bool debug; bool ice = true; // Needs to be true in order to create default definitions. bool underscore; string outputFile; bool ignoreTypeChanges; bool purgeObjects; bool catastrophicRecover; bool suppress; string inputFile; vector<string> oldSlice; vector<string> newSlice; bool evictor; string keyTypeNames; string valueTypeNames; string dbEnvName, dbName, dbEnvNameNew; bool allDb = false; IceUtilInternal::Options opts; opts.addOpt("h", "help"); opts.addOpt("v", "version"); opts.addOpt("D", "", IceUtilInternal::Options::NeedArg, "", IceUtilInternal::Options::Repeat); opts.addOpt("U", "", IceUtilInternal::Options::NeedArg, "", IceUtilInternal::Options::Repeat); opts.addOpt("d", "debug"); opts.addOpt("", "underscore"); opts.addOpt("o", "", IceUtilInternal::Options::NeedArg); opts.addOpt("i"); opts.addOpt("p"); opts.addOpt("c"); opts.addOpt("w"); opts.addOpt("f", "", IceUtilInternal::Options::NeedArg); opts.addOpt("", "include-old", IceUtilInternal::Options::NeedArg, "", IceUtilInternal::Options::Repeat); opts.addOpt("", "include-new", IceUtilInternal::Options::NeedArg, "", IceUtilInternal::Options::Repeat); opts.addOpt("", "old", IceUtilInternal::Options::NeedArg, "", IceUtilInternal::Options::Repeat); opts.addOpt("", "new", IceUtilInternal::Options::NeedArg, "", IceUtilInternal::Options::Repeat); opts.addOpt("a"); opts.addOpt("e"); opts.addOpt("", "key", IceUtilInternal::Options::NeedArg); opts.addOpt("", "value", IceUtilInternal::Options::NeedArg); const string appName = originalArgs[0]; vector<string> args; try { args = opts.parse(originalArgs); } catch(const IceUtilInternal::BadOptException& e) { cerr << appName << ": " << e.reason << endl; usage(appName); return EXIT_FAILURE; } if(opts.isSet("help")) { usage(appName); return EXIT_SUCCESS; } if(opts.isSet("version")) { cout << ICE_STRING_VERSION << endl; return EXIT_SUCCESS; } if(opts.isSet("D")) { vector<string> optargs = opts.argVec("D"); for(vector<string>::const_iterator i = optargs.begin(); i != optargs.end(); ++i) { oldCppArgs.push_back("-D" + *i); newCppArgs.push_back("-D" + *i); } } if(opts.isSet("U")) { vector<string> optargs = opts.argVec("U"); for(vector<string>::const_iterator i = optargs.begin(); i != optargs.end(); ++i) { oldCppArgs.push_back("-U" + *i); newCppArgs.push_back("-U" + *i); } } debug = opts.isSet("debug"); underscore = opts.isSet("underscore"); if(opts.isSet("o")) { outputFile = opts.optArg("o"); } ignoreTypeChanges = opts.isSet("i"); purgeObjects = opts.isSet("p"); catastrophicRecover = opts.isSet("c"); suppress = opts.isSet("w"); if(opts.isSet("f")) { inputFile = opts.optArg("f"); } if(opts.isSet("include-old")) { vector<string> optargs = opts.argVec("include-old"); for(vector<string>::const_iterator i = optargs.begin(); i != optargs.end(); ++i) { oldCppArgs.push_back("-I" + *i); } } if(opts.isSet("include-new")) { vector<string> optargs = opts.argVec("include-new"); for(vector<string>::const_iterator i = optargs.begin(); i != optargs.end(); ++i) { newCppArgs.push_back("-I" + *i); } } if(opts.isSet("old")) { vector<string> optargs = opts.argVec("old"); for(vector<string>::const_iterator i = optargs.begin(); i != optargs.end(); ++i) { oldSlice.push_back(*i); } } if(opts.isSet("new")) { vector<string> optargs = opts.argVec("new"); for(vector<string>::const_iterator i = optargs.begin(); i != optargs.end(); ++i) { newSlice.push_back(*i); } } evictor = opts.isSet("e"); if(opts.isSet("key")) { keyTypeNames = opts.optArg("key"); } if(opts.isSet("value")) { valueTypeNames = opts.optArg("value"); } if(outputFile.empty()) { if(args.size() == 2) { allDb = true; } else if(args.size() != 3) { usage(appName); return EXIT_FAILURE; } } else { if(args.size() == 1) { allDb = true; } else if(args.size() != 0) { usage(appName); return EXIT_FAILURE; } } if(allDb && (!keyTypeNames.empty() || !valueTypeNames.empty())) { usage(appName); return EXIT_FAILURE; } if(inputFile.empty() && !allDb && !evictor && (keyTypeNames.empty() || valueTypeNames.empty())) { usage(appName); return EXIT_FAILURE; } if(args.size() > 0) { dbEnvName = args[0]; } if(args.size() > 1) { if(allDb) { dbEnvNameNew = args[1]; } else { dbName = args[1]; } } if(args.size() > 2) { dbEnvNameNew = args[2]; } if(args.size() > 3) { cerr << appName << ": too many arguments" << endl; usage(appName); return EXIT_FAILURE; } // // Freeze creates a lock file by default to prevent multiple processes from opening // the same database environment simultaneously. In the case of a read-only program // such as transformdb, however, we still want to be able to open the environment despite // the lock. This assumes of course that the other process has opened the environment // with DbPrivate=0. If DbPrivate=0 is also set for dumpdb, we disable the lock. // if(!catastrophicRecover && outputFile.empty()) { Ice::PropertiesPtr props = communicator->getProperties(); string prefix = "Freeze.DbEnv." + args[0]; if(props->getPropertyAsIntWithDefault(prefix + ".DbPrivate", 1) == 0) { props->setProperty(prefix + ".LockFile", "0"); } } Slice::UnitPtr oldUnit = Slice::Unit::createUnit(true, true, ice, underscore); FreezeScript::Destroyer<Slice::UnitPtr> oldD(oldUnit); if(!FreezeScript::parseSlice(appName, oldUnit, oldSlice, oldCppArgs, debug, "-D__TRANSFORMDB__")) { return EXIT_FAILURE; } Slice::UnitPtr newUnit = Slice::Unit::createUnit(true, true, ice, underscore); FreezeScript::Destroyer<Slice::UnitPtr> newD(newUnit); if(!FreezeScript::parseSlice(appName, newUnit, newSlice, newCppArgs, debug, "-D__TRANSFORMDB__")) { return EXIT_FAILURE; } // // Install the evictor types in the Slice units. // FreezeScript::createEvictorSliceTypes(oldUnit); FreezeScript::createEvictorSliceTypes(newUnit); // // Read the catalog if necessary. // FreezeScript::CatalogDataMap catalog; if(allDb) { try { catalog = FreezeScript::readCatalog(communicator, dbEnvName); } catch(const FreezeScript::FailureException& ex) { cerr << appName << ": " << ex.reason() << endl; return EXIT_FAILURE; } if(catalog.empty()) { cerr << appName << ": no databases in environment `" << dbEnvName << "'" << endl; return EXIT_FAILURE; } } // // If no input file was provided, then we need to analyze the Slice types. // string descriptors; if(inputFile.empty()) { ostringstream out; vector<string> missingTypes; vector<string> analyzeErrors; FreezeScript::TransformAnalyzer analyzer(oldUnit, newUnit, ignoreTypeChanges, out, missingTypes, analyzeErrors); const string evictorKeyName = "::Ice::Identity"; const string oldEvictorValueName = "::Freeze::ObjectRecord"; const string newEvictorValueName = "Object"; if(allDb) { // // Add a <database> element for each database in the catalog. // for(FreezeScript::CatalogDataMap::iterator p = catalog.begin(); p != catalog.end(); ++p) { string keyName, valueName; if(p->second.evictor) { keyName = p->second.key; valueName = p->second.value; if(keyName.empty()) { keyName = evictorKeyName; } if(valueName.empty()) { valueName = oldEvictorValueName; } } else { keyName = p->second.key; valueName = p->second.value; } // // Look up the key and value types in the old and new Slice definitions. // Slice::TypePtr oldKeyType = findType(oldUnit, keyName); if(!oldKeyType) { cerr << appName << ": type `" << keyName << "' from database `" << p->first << "' not found in old Slice definitions" << endl; } Slice::TypePtr newKeyType = findType(newUnit, keyName); if(!newKeyType) { cerr << appName << ": type `" << keyName << "' from database `" << p->first << "' not found in new Slice definitions" << endl; } Slice::TypePtr oldValueType = findType(oldUnit, valueName); if(!oldValueType) { cerr << appName << ": type `" << valueName << "' from database `" << p->first << "' not found in old Slice definitions" << endl; } Slice::TypePtr newValueType; if(p->second.evictor) { // // The new evictor does not keep stats // newValueType = findType(newUnit, newEvictorValueName); } else { newValueType = findType(newUnit, valueName); } if(!newValueType) { cerr << appName << ": type `" << valueName << "' from database `" << p->first << "' not found in new Slice definitions" << endl; } // // If we are generating an output file, we do not consider a missing type to be // an error. Since the type information comes from the catalog of the old // environment, it's possible that the key or value types are not present in // the new Slice definitions. Rather than abort at this point, we simply emit // a partially-defined <database> element that must be edited by the user. // // If we are not generating an output file, we have to stop now. // if(outputFile.empty() && (!oldKeyType || !newKeyType || !oldValueType || !newValueType)) { return EXIT_FAILURE; } analyzer.addDatabase(p->first, oldKeyType, newKeyType, oldValueType, newValueType); } } else { string oldKeyName, newKeyName, oldValueName, newValueName; string::size_type pos; if(!evictor && (keyTypeNames.empty() || valueTypeNames.empty())) { usage(appName); return EXIT_FAILURE; } if(!keyTypeNames.empty()) { pos = keyTypeNames.find(','); if(pos == 0 || pos == keyTypeNames.size()) { usage(appName); return EXIT_FAILURE; } if(pos == string::npos) { oldKeyName = keyTypeNames; newKeyName = keyTypeNames; } else { oldKeyName = keyTypeNames.substr(0, pos); newKeyName = keyTypeNames.substr(pos + 1); } } if(!valueTypeNames.empty()) { pos = valueTypeNames.find(','); if(pos == 0 || pos == valueTypeNames.size()) { usage(appName); return EXIT_FAILURE; } if(pos == string::npos) { oldValueName = valueTypeNames; newValueName = valueTypeNames; } else { oldValueName = valueTypeNames.substr(0, pos); newValueName = valueTypeNames.substr(pos + 1); } } if(evictor) { if(oldKeyName.empty()) { oldKeyName = evictorKeyName; } if(newKeyName.empty()) { newKeyName = evictorKeyName; } if(oldValueName.empty()) { oldValueName = newEvictorValueName; } if(newValueName.empty()) { newValueName = newEvictorValueName; } } // // Look up the key and value types in the old and new Slice definitions. // Slice::TypePtr oldKeyType = findType(oldUnit, oldKeyName); if(!oldKeyType) { cerr << appName << ": type `" << oldKeyName << "' not found in old Slice definitions" << endl; } Slice::TypePtr newKeyType = findType(newUnit, newKeyName); if(!newKeyType) { cerr << appName << ": type `" << newKeyName << "' not found in new Slice definitions" << endl; } Slice::TypePtr oldValueType = findType(oldUnit, oldValueName); if(!oldValueType) { cerr << appName << ": type `" << oldValueName << "' not found in old Slice definitions" << endl; } Slice::TypePtr newValueType = findType(newUnit, newValueName); if(!newValueType) { cerr << appName << ": type `" << newValueName << "' not found in new Slice definitions" << endl; } // // Stop now if any of the types could not be found. // if(!oldKeyType || !newKeyType || !oldValueType || !newValueType) { return EXIT_FAILURE; } analyzer.addDatabase("", oldKeyType, newKeyType, oldValueType, newValueType); } analyzer.finish(); if(!analyzeErrors.empty()) { for(vector<string>::const_iterator p = analyzeErrors.begin(); p != analyzeErrors.end(); ++p) { cerr << appName << ": " << *p << endl; } } if(!missingTypes.empty()) { sort(missingTypes.begin(), missingTypes.end()); unique(missingTypes.begin(), missingTypes.end()); if(!analyzeErrors.empty()) { cerr << endl; } cerr << "The following types had no matching definitions in the new Slice:" << endl; for(vector<string>::const_iterator p = missingTypes.begin(); p != missingTypes.end(); ++p) { cerr << " " << *p << endl; } } if(!analyzeErrors.empty()) { return EXIT_FAILURE; } descriptors = out.str(); if(!outputFile.empty()) { // // No nativeToUTF8 conversion necessary here, no string converter is installed // by wmain() on Windows and args are assumbed to be UTF8 on Unix platforms. // IceUtilInternal::ofstream of(outputFile); if(!of.good()) { cerr << appName << ": unable to open file `" << outputFile << "'" << endl; return EXIT_FAILURE; } of << descriptors; of.close(); return EXIT_SUCCESS; } } else { // // Read the input file. // // No nativeToUTF8 conversion necessary here, no string converter is installed // by wmain() on Windows and args are assumbed to be UTF8 on Unix platforms. // IceUtilInternal::ifstream in(inputFile); char buff[1024]; while(true) { in.read(buff, 1024); descriptors.append(buff, static_cast<size_t>(in.gcount())); if(in.gcount() < 1024) { break; } } in.close(); } if(dbEnvName == dbEnvNameNew) { cerr << appName << ": database environment names must be different" << endl; return EXIT_FAILURE; } FreezeScript::ObjectFactoryPtr objectFactory = new FreezeScript::ObjectFactory; communicator->addObjectFactory(objectFactory, ""); // // Transform the database. // DbEnv dbEnv(0); DbEnv dbEnvNew(0); Freeze::TransactionPtr txNew; Freeze::ConnectionPtr connection; Freeze::ConnectionPtr connectionNew; vector<Db*> dbs; int status = EXIT_SUCCESS; try { #ifdef _WIN32 // // Berkeley DB may use a different C++ runtime. // dbEnv.set_alloc(::malloc, ::realloc, ::free); dbEnvNew.set_alloc(::malloc, ::realloc, ::free); #endif // // Open the old database environment. Use DB_RECOVER_FATAL if -c is specified. // No transaction is created for the old environment. // // DB_THREAD is for compatibility with Freeze (the catalog) // { u_int32_t flags = DB_THREAD | DB_CREATE | DB_INIT_TXN | DB_INIT_MPOOL; if(catastrophicRecover) { flags |= DB_INIT_LOG | DB_RECOVER_FATAL; } dbEnv.open(dbEnvName.c_str(), flags, FREEZE_SCRIPT_DB_MODE); } // // We're creating a connection just to make sure the database environment // isn't locked. // connection = Freeze::createConnection(communicator, dbEnvName, dbEnv); // // Open the new database environment and start a transaction. // // // DB_THREAD is for compatibility with Freeze (the catalog) // { u_int32_t flags = DB_INIT_LOG | DB_INIT_MPOOL | DB_INIT_TXN | DB_RECOVER | DB_CREATE | DB_THREAD; dbEnvNew.open(dbEnvNameNew.c_str(), flags, FREEZE_SCRIPT_DB_MODE); } // // TODO: handle properly DbHome config (currently it will break if it's set for the new env) // // // Open the catalog of the new environment, and start a transaction. // connectionNew = Freeze::createConnection(communicator, dbEnvNameNew, dbEnvNew); txNew = connectionNew->beginTransaction(); DbTxn* txnNew = Freeze::getTxn(txNew); if(allDb) { // // Transform all databases in the old catalog. // for(FreezeScript::CatalogDataMap::iterator p = catalog.begin(); p != catalog.end(); ++p) { transformDb(p->second.evictor, communicator, objectFactory, dbEnv, dbEnvNew, p->first, connectionNew, dbs, oldUnit, newUnit, txnNew, purgeObjects, suppress, descriptors); } } else { transformDb(evictor, communicator, objectFactory, dbEnv, dbEnvNew, dbName, connectionNew, dbs, oldUnit, newUnit, txnNew, purgeObjects, suppress, descriptors); } } catch(const DbException& ex) { cerr << appName << ": database error: " << ex.what() << endl; status = EXIT_FAILURE; } catch(const IceUtil::FileLockException&) { cerr << appName << ": error: database environment is locked" << endl; status = EXIT_FAILURE; } catch(...) { try { if(txNew != 0) { txNew->rollback(); txNew = 0; } if(connectionNew) { connectionNew->close(); connectionNew = 0; } if(connection) { connection->close(); connection = 0; } for(vector<Db*>::iterator p = dbs.begin(); p != dbs.end(); ++p) { Db* db = *p; db->close(0); delete db; } try { dbEnv.close(0); } catch(const DbException&) { } try { dbEnvNew.close(0); } catch(const DbException&) { } } catch(const DbException& ex) { cerr << appName << ": database error: " << ex.what() << endl; } throw; } if(txNew != 0) { try { if(status == EXIT_FAILURE) { txNew->rollback(); } else { txNew->commit(); // // Checkpoint to migrate changes from the log to the database(s). // dbEnvNew.txn_checkpoint(0, 0, DB_FORCE); } for(vector<Db*>::iterator p = dbs.begin(); p != dbs.end(); ++p) { Db* db = *p; db->close(0); delete db; } } catch(const DbException& ex) { cerr << appName << ": database error: " << ex.what() << endl; status = EXIT_FAILURE; } } // Clear the transaction before closing the database environment. txNew = 0; if(connectionNew) { connectionNew->close(); connectionNew = 0; } if(connection) { connection->close(); connection = 0; } try { dbEnv.close(0); } catch(const DbException&) { } try { dbEnvNew.close(0); } catch(const DbException&) { } return status; }