// Ryzom - MMORPG Framework // Copyright (C) 2010 Winch Gate Property Limited // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU Affero General Public License as // published by the Free Software Foundation, either version 3 of the // License, or (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Affero General Public License for more details. // // You should have received a copy of the GNU Affero General Public License // along with this program. If not, see . /* * Description of a the cycle of the Mirror Service and of a client service: * * Mirror Service (M) Client Service (C) * * 1. Receive master TICK from Tick Service TICK * | => Send TICK to local client services ------------> 1. Receive TICK => call tick update callback * | * 2. Receive messages from client services MSG to forward | * | => store them in message queue <------------ | * | Receive delta updates from remote MSs | * | => store them in pending deltas TOCK | * | Wait for all TOCKs from clients services <------------ When done, send TOCK to MS * | * * 3. Build and send delta to remote MSs * * 3.5 Wait for all delta updates received X: non-synchronized message callbacks * Receive delta updates of same TICK from * remote MSs that didn't answer before * * * 4. Send master TOCK to Tick Service * | * 5. Apply pending deltas to shared memory * | UMM * 6. Trigger processing of mirror changes ------------> 2. Execute notification callback to update * | and send messages to client services | mirror entities and process changes * | * 3. Receive messages and transport classes * | and execute callbacks * * Note: non-mirrored messages and non-mirror * transport classes may be received between * C1. and C2. and between C3. and C1. * * * X: non-synchronized message callbacks * * Parallelism and consistency: on one physical machine, the services read and write properties * in the same shared memory. It means changing a value by a service A is immediately reflected * to the service B if they are on the same physical machine. A side effect is that a value can * have changed between two successive readings. In most cases, this is not a problem, for exemple * if the property represents a colour or such an unimportant property. However, for certain kinds * of properties, it may be dangerous. For example, let's say _MyValue is a CMirrorPropValueRO. * The following code may lead to a crash: if (_MyValue() != 0) result=1.0f/_MyValue(); because * the value can become 0 at any time. The solution to this is to write: float value = _MyValue(); * if (value != 0) result=1.0f/value;. A similar problem can occur when storing a dataset row (e.g. * for targeting purpose): the result of the test isValid() can change. User should use the * temporary copy way. */ #include "mirror_service.h" #include "tick_proxy.h" extern NLMISC::CLog _QuickLog; static TTime BeginWaitForAllDeltaReceivedTime = 0; /* * From a client service */ void cbMessageToForward( CMessage& msgin, const string& serviceName, TServiceId serviceId ) { // The assert is not enabled, because in fact some messages *can* come when the state // is not ExpectingLocalTocks. How is it possible? When a service sends its message // in a cbServiceUp callback, or in a callback to a message not send using the mirror // system (?). This is not a problem as the message is only buffered. //nlassert( CTickProxy::State == ExpectingLocalTocks ); MSInstance->receiveMessageToForwardFromClient( msgin, serviceId ); } /* * From another MS */ void cbRecvDelta( CMessage& msgin, const string& serviceName, TServiceId serviceId ) { // The assert is not enabled, because in fact some delta *can* come when the state // is not ExpectingLocalTocks. How is it possible? Example: There are two MS, MS1 // has a client service. When MS1 sends its first delta packet, MS2 may not have // received its first Master Tick! This is not a problem as the message is only buffered. //nlassert( CTickProxy::State == ExpectingLocalTocks ); MSInstance->receiveDeltaFromRemoteMS( msgin, serviceId ); } /* * Sync received from master (see tick proxy) */ void cbOnMasterSync() { MSInstance->examineDeltaUpdatesReceivedBeforeSync(); CTickProxy::sendSyncs(); } /* * Master tick received (see tick proxy) */ void cbOnMasterTick() { MSInstance->masterTick(); } /* * Callback called when a client tocks back */ void cbDoNextTask() { MSInstance->doNextTask(); } /* * Return true if all delta updates have been received for the current tick */ inline bool CMirrorService::checkIfAllIncomingDeltasReceived() const { return _NbDeltaUpdatesReceived == _NbExpectedDeltaUpdates; } /* * Advance state in the mirror automaton */ void CMirrorService::doNextTask() { if ( ! _DeltaSent ) { if ( CTickProxy::checkIfAllClientTocksReceived() && checkIfAllATAcknowledgesReceived() ) { // Advance to step 3. buildAndSendAllOutgoingDeltas(); nlassert( _DeltaSent ); // Advance to step 4 if the required conditions are met. BeginWaitForAllDeltaReceivedTime = CTime::getLocalTime(); doNextTask(); } } else { if ( checkIfAllIncomingDeltasReceived() ) // { // Advance to step 4. CTickProxy::TimeMeasures.MirrorMeasure[WaitAllReceivedDeltaDuration] = (uint16)(CTime::getLocalTime() - BeginWaitForAllDeltaReceivedTime); nlassert( CTickProxy::checkIfAllClientTocksReceived() ); tockMasterAndProcessReceivedIncomingDeltas(); nlassert( ! CTickProxy::checkIfAllClientTocksReceived() ); } else /*if ( ! checkIfAllIncomingDeltasReceived() )*/ { // Shouldn't be negative if ( _NbExpectedDeltaUpdates-_NbDeltaUpdatesReceived < 0 ) nlwarning( "More delta updates received than expected: E%u R%u", _NbExpectedDeltaUpdates, _NbDeltaUpdatesReceived ); //nldebug( "Delta updates remaining: %hd", _NbExpectedDeltaUpdates-_NbDeltaUpdatesReceived ); } } } /* * */ void CMirrorService::displayAutomatonState( NLMISC::CLog *log ) { // TODO: add checkIfAllATAcknowledgesReceived()/_BlockedAwaitingATAck log->displayNL( "Tick %u, %s", CTickProxy::getGameCycle(), (CTickProxy::State == ExpectingMasterTick)?"expecting new tick":"expecting local tocks" ); if ( CTickProxy::State == ExpectingMasterTick ) { if ( _DeltaSent ) log->displayNL( "Delta sent; Master tock sent; => Steps 5-6" ); else log->displayNL( "Ready for step 1" ); } else if ( ! _DeltaSent ) { if ( CTickProxy::checkIfAllClientTocksReceived() ) log->displayNL( "Delta not sent; Received all tocks => Ready for step 3" ); else log->displayNL( "Delta not sent; Waiting for client tocks => Step 2" ); } else { if ( checkIfAllIncomingDeltasReceived() ) log->displayNL( "Delta sent; Received all deltas => Ready for step 4" ); else log->displayNL( "Delta sent; Waiting for deltas (%hd received on %hd) => Step 3.5", _NbDeltaUpdatesReceived, _NbExpectedDeltaUpdates ); } } /* * */ void CMirrorService::buildAndSendAllOutgoingDeltas() { // 3. Build and send delta to remote MSs buildAndSendAllDeltas(); _DeltaSent = true; // Apply release of client services applyServicesQuitting(); // Appply pending rescans applyPendingRescans(); } /* * */ void CMirrorService::tockMasterAndProcessReceivedIncomingDeltas() { // 4. Send master TOCK to Tick Service CTickProxy::sendMasterTock(); // 5. Apply pending deltas to shared memory applyPendingDeltas(); TTime BeforeSendUMM = CTime::getLocalTime(); // 6. Trigger processing of mirror changes and send messages to client services tellLocalServicesAndSendMessages(); // Reset incoming delta received counter and outgoing delta sent flag resetDeltaUpdatesReceived(); resetDeltaSent(); CTickProxy::setEndOfTick(); CTickProxy::TimeMeasures.MirrorMeasure[PrevSendUMMDuration] = (uint16)(CTime::getLocalTime() - BeforeSendUMM); } /* * Send ticks to local client services */ void CMirrorService::masterTick() { // 1. Send TICK to local client services CTickProxy::sendTicks(); doNextTask(); } /* * */ void CMirrorService::pushMessageToLocalQueue( std::vector& msgQueue, TServiceId senderId, NLMISC::CMemStream& msg ) { TMessageCarrier mc( true ); msgQueue.push_back( mc ); msgQueue.back().SenderId = senderId; msgQueue.back().Msg = msg; //nldebug( "Received msg from %s for local %s", servStr(senderId).c_str(), servStr(destId).c_str() ); } /* * */ void CMirrorService::pushMessageToLocalQueueFromMessage( std::vector& msgQueue, NLNET::CMessage& msgin ) { TMessageCarrier mc( true ); msgQueue.push_back( mc ); msgin.serial( msgQueue.back().SenderId ); msgin.serialMemStream( msgQueue.back().Msg ); } /* * */ void CMirrorService::receiveMessageToForwardFromClient( CMessage& msgin, TServiceId senderId ) { H_AUTO(receiveMessageToForwardFromClient); uint8 counter; msgin.serial( counter ); // there are no multiple messages, but there can be multiple destinations if ( counter == MSG_BROADCAST ) { CMemStream ms = msgin.extractStreamFromPos( msgin.getHeaderSize() + sizeof(counter) ); #ifdef NL_DEBUG string name = msgin.readTypeAtCurrentPos(); // warning: the pos is updated in msgin nldebug( "MSG: Broadcasting message from %s (msg %s, %u b)", servStr(senderId).c_str(), name.c_str(), ms.length() ); #endif pushMessageToLocalQueue( _MessagesToBroadcastLocally, senderId, ms ); _RemoteMSList.pushMessageToRemoteQueue( DEST_MSG_BROADCAST, senderId, ms ); } else { for ( uint i=0; i!=(uint)counter; ++i ) { TServiceId destId; msgin.serial( destId ); TClientServices::iterator ics = _ClientServices.find( destId ); if ( ics != _ClientServices.end() ) { // Destination service is local => buffer the message (which is found in the stream after the list of destinations) CMemStream m = msgin.extractStreamFromPos( msgin.getHeaderSize() + sizeof(counter) + counter*sizeof(destId) ); pushMessageToLocalQueue( GET_CLIENT_SERVICE_INFO(ics).Messages, senderId, m ); } else { // Destination service is remote => find the corresponding remote MS and buffer the message CMemStream m = msgin.extractStreamFromPos( msgin.getHeaderSize() + sizeof(counter) + counter*sizeof(destId) ); _RemoteMSList.pushMessageToRemoteQueue( (TServiceId)destId, (TServiceId)senderId, m ); } } } } /* * */ void CMirrorService::receiveDeltaFromRemoteMS( CMessage& msgin, TServiceId senderMSId ) { H_AUTO(receiveDeltaFromRemoteMS); // 2b. Receive delta updates from remote MSs => store them in pending deltas _PendingDeltas.push_back( make_pair( senderMSId, msgin ) ); // warning: msgin must be copied because below we advance the reading position of msgin //nldebug( "Received delta from %s", servStr(senderMSId).c_str() ); // Get the "wait for" mode of this remote MS delta bool waitForIt; msgin.serial( waitForIt ); if ( waitForIt ) // we assume it does not change during the lifetime of a particular remote MS { // Check if the sender is a new remote MS (search in the "delta update expectation list") std::list< TServiceId >::const_iterator it = find( _RemoteMSToWaitForDelta.begin(), _RemoteMSToWaitForDelta.end(), senderMSId ); if ( it == _RemoteMSToWaitForDelta.end() ) { _RemoteMSToWaitForDelta.push_back( senderMSId ); // _RemoteMSToWaitForDelta will not contain remote MSes for which we don't have to wait ++_NbExpectedDeltaUpdates; } } TGameCycle gamecycle; msgin.serial( gamecycle ); //nldebug( "%u: Rcvd Delta %u", CTickProxy::getGameCycle(), gamecycle ); _QuickLog.displayNL( "TCK-%u: Rcvd Delta %u from MS-%hu (NbExpectedDelta=%hd)", CTickProxy::getGameCycle(), gamecycle, senderMSId.get(), _NbExpectedDeltaUpdates ); // Count this delta update for the wait test only if its tick is the current tick or +1 (see explanation below) // Explanation: possibles cases: // // MS1 MS2 // | | // Tick1>| Tick1>| // Delta>|>Delta <====> Delta>|>Delta // |>Tock1 |>Tock1 // | | // | Tick2>| // Delta>| <----- |>Delta // Tick2>|>Delta -----> Delta>|>Tock2 // |>Tock2 | // if ( CTickProxy::State == ExpectingMasterTick ) { // If sync not received yet, defer possible incrementation of _NbDeltaUpdatesReceived // because we can't compare now the gamecycle of the delta update with the current gamecycle // (see examineDeltaUpdatesReceivedBeforeSync() called when receiving the sync) if ( CTickProxy::getGameCycle() == 0 ) { if ( waitForIt ) _GameCyclesOfDeltaReceivedBeforeSync.push_back( gamecycle ); return; } // Accept +1 only if received by advance (before the tick update) // Forbid >+1 // Discard <= else if ( gamecycle > CTickProxy::getGameCycle() ) { nlassert( gamecycle == CTickProxy::getGameCycle() + 1 ); if ( waitForIt ) ++_NbDeltaUpdatesReceived; } } else { // Accept == if received in the same tick // Forbid > // Discard < if ( gamecycle >= CTickProxy::getGameCycle() ) { nlassert( gamecycle == CTickProxy::getGameCycle() ); if ( waitForIt ) ++_NbDeltaUpdatesReceived; } } doNextTask(); } /* * Increment _NbDeltaUpdatesReceived for the number of times we have received a VALID delta update before sync * (valid = its tick = the current tick + 1) */ void CMirrorService::examineDeltaUpdatesReceivedBeforeSync() { if ( ! _GameCyclesOfDeltaReceivedBeforeSync.empty() ) { for ( vector::const_iterator ig=_GameCyclesOfDeltaReceivedBeforeSync.begin(); ig!=_GameCyclesOfDeltaReceivedBeforeSync.end(); ++ig ) { if ( (*ig) > CTickProxy::getGameCycle() ) ++_NbDeltaUpdatesReceived; } _GameCyclesOfDeltaReceivedBeforeSync.clear(); doNextTask(); } } /* * */ void CMirrorService::applyPendingDeltas() { H_AUTO(applyPendingDeltas); TTime BeforeApplyPendingDelta = CTime::getLocalTime(); // Binding counters (possibly with removals) for ( TSDataSetsMS::iterator ids=_SDataSets.begin(); ids!=_SDataSets.end(); ++ids ) { GET_SDATASET(ids).processReceivedBindingCounters(); } // Deltas vector< pair >::iterator ipd; for ( ipd=_PendingDeltas.begin(); ipd!=_PendingDeltas.end(); ++ipd ) { // processReceivedDelta( const_cast((*ipd).second), (*ipd).first ); processReceivedDelta( ipd->second, ipd->first ); } //if ( ! _PendingDeltas.empty() ) // nldebug( "Applied %u pending deltas", _PendingDeltas.size() ); _PendingDeltas.clear(); CTickProxy::TimeMeasures.MirrorMeasure[PrevApplyReceivedDeltaDuration] = (uint16)(CTime::getLocalTime() - BeforeApplyPendingDelta); } /* * */ void CMirrorService::tellLocalServicesAndSendMessages() { H_AUTO(tellUMM) TClientServices::iterator ics; for ( ics=_ClientServices.begin(); ics!=_ClientServices.end(); ++ics ) { //H_BEFORE(tellHeaderAndBroadcast); CMessage msgout( "UMM" ); // Update Mirror and Messages sint32 nbBufPos = msgout.reserve( sizeof(uint32) ); uint32 nbBroadcastedMsgs = 0; vector::const_iterator im; for ( im=_MessagesToBroadcastLocally.begin(); im!=_MessagesToBroadcastLocally.end(); ++im ) { if ( (*im).SenderId != (*ics).first ) // don't send to sender { serialToMessageFromLocalQueue( msgout, (*im) ); ++nbBroadcastedMsgs; } } //H_AFTER(tellHeaderAndBroadcast); for ( im=GET_CLIENT_SERVICE_INFO(ics).Messages.begin(); im!=GET_CLIENT_SERVICE_INFO(ics).Messages.end(); ++im ) { serialToMessageFromLocalQueue( msgout, (*im) ); } uint32 nbMsgs = nbBroadcastedMsgs + GET_CLIENT_SERVICE_INFO(ics).Messages.size(); msgout.poke( nbMsgs, nbBufPos ); //H_BEFORE(tellUMMSend); CUnifiedNetwork::getInstance()->send( (*ics).first, msgout ); //H_AFTER(tellUMMSend); //if ( nbMsgs != 0 ) // nldebug( "Sent UMM to %s with %u messages", servStr((*ics).first).c_str(), nbMsgs ); //H_AUTO(clearMessages); GET_CLIENT_SERVICE_INFO(ics).Messages.clear(); } _MessagesToBroadcastLocally.clear(); } /* * */ void CMirrorService::serialToMessageFromLocalQueue( CMessage& msgout, const TMessageCarrier& srcMsgInQueue ) { //H_AUTO(serialToMessageFromLocalQueue); msgout.serial( const_cast(srcMsgInQueue.SenderId) ); // Not using serialMemStream because the receiver will read the size and pass the entire message to the appropriate callback sint32 msgSize = (sint32)srcMsgInQueue.Msg.length(); msgout.serial( msgSize ); msgout.serialBuffer( const_cast(srcMsgInQueue.Msg.buffer()), srcMsgInQueue.Msg.length() ); } NLMISC_COMMAND( displayAutomatonState, "Display the current state of the MS automaton", "" ) { MSInstance->displayAutomatonState( &log ); return true; } NLMISC_COMMAND( doNextTask, "Update automaton state", "" ) { MSInstance->doNextTask(); return true; }