Chapter 14. Transaction Log

JanusGraph can automatically log transactional changes for additional processing or as a record of change. To enable logging for a particular transaction, specify the name of the target log during the start of the transaction.

tx = graph.buildTransaction().logIdentifier('addedPerson').start()
u = tx.addVertex(label, 'human')
u.property('name', 'proteros')
u.property('age', 36)
tx.commit()

Upon commit, any changes made during the transaction are logged to the user logging system into a log named addedPerson. The user logging system is a configurable logging backend with a JanusGraph compatible log interface. By default, the log is written to a separate store in the primary storage backend which can be configured as described below. The log identifier specified during the start of the transaction identifies the log in which the changes are recorded thereby allowing different types of changes to be recorded in separate logs for individual processing.

tx = graph.buildTransaction().logIdentifier('battle').start()
h = tx.traversal().V().has('name', 'hercules').next()
m = tx.addVertex(label, 'monster')
m.property('name', 'phylatax')
h.addEdge('battled', m, 'time', 22)
tx.commit()

JanusGraph provides a user transaction log processor framework to process the recorded transactional changes. The transaction log processor is opened via JanusGraphFactory.openTransactionLog(JanusGraph) against a previously opened JanusGraph graph instance. One can then add processors for a particular log which holds transactional changes.

import java.util.concurrent.atomic.*;
import org.janusgraph.core.log.*;
import java.util.concurrent.*;
logProcessor = JanusGraphFactory.openTransactionLog(g);
totalHumansAdded = new AtomicInteger(0);
totalGodsAdded = new AtomicInteger(0);
logProcessor.addLogProcessor("addedPerson").
        setProcessorIdentifier("addedPersonCounter").
        setStartTimeNow().
        addProcessor(new ChangeProcessor() {
            @Override
            public void process(JanusGraphTransaction tx, TransactionId txId, ChangeState changeState) {
                for (v in changeState.getVertices(Change.ADDED)) {
                    if (v.label().equals("human")) totalHumansAdded.incrementAndGet();
                }
            }
        }).
        addProcessor(new ChangeProcessor() {
            @Override
            public void process(JanusGraphTransaction tx, TransactionId txId, ChangeState changeState) {
                for (v in changeState.getVertices(Change.ADDED)) {
                    if (v.label().equals("god")) totalGodsAdded.incrementAndGet();
                }
            }
        }).
        build();

In this example, a log processor is built for the user transaction log named addedPerson to process the changes made in transactions which used the addedPerson log identifier. Two change processors are added to this log processor. The first processor counts the number of humans added and the second counts the number of gods added to the graph.

When a log processor is built against a particular log, such as the addedPerson log in the example above, it will start reading transactional change records from the log immediately upon successful construction and initialization up to the head of the log. The start time specified in the builder marks the time point in the log where the log processor will start reading records. Optionally, one can specify an identifier for the log processor in the builder. The log processor will use the identifier to regularly persist its state of processing, i.e. it will maintain a marker on the last read log record. If the log processor is later restarted with the same identifier, it will continue reading from the last read record. This is particularly useful when the log processor is supposed to run for long periods of time and is therefore likely to fail. In such failure situations, the log processor can simply be restarted with the same identifier. It must be ensured that log processor identifiers are unique in a JanusGraph cluster in order to avoid conflicts on the persisted read markers.

A change processor must implement the ChangeProcessor interface. It’s process() method is invoked for each change record read from the log with a JanusGraphTransaction handle, the id of the transaction that caused the change, and a ChangeState container which holds the transactional changes. The change state container can be queried to retrieve individual elements that were part of the change state. In the example, all added vertices are retrieved. Refer to the API documentation for a description of all the query methods on ChangeState. The provided transaction id can be used to investigate the origin of the transaction which is uniquely identified by the combination of the id of the JanusGraph instance that executed the transaction (txId.getInstanceId()) and the instance specific transaction id (txId.getTransactionId()). In addition, the time of the transaction is available through txId.getTransactionTime().

Change processors are executed individually and in multiple threads. If a change processor accesses global state it must be ensured that such state allows concurrent access. While the log processor reads log records sequentially, the changes are processed in multiple threads so it cannot be guaranteed that the log order is preserved in the change processors.

Note, that log processors run each registered change processor at least once for each record in the log which means that a single transactional change record may be processed multiple times under certain failure conditions. One cannot add or remove change processor from a running log processor. In other words, a log processor is immutable after it is built. To change log processing, start a new log processor and shut down an existing one.

logProcessor.addLogProcessor("battle").
        setProcessorIdentifier("battleTimer").
        setStartTimeNow().
        addProcessor(new ChangeProcessor() {
            @Override
            public void process(JanusGraphTransaction tx, TransactionId txId, ChangeState changeState) {
                h = tx.V().has("name", "hercules").toList().iterator().next();
                for (edge in changeState.getEdges(h, Change.ADDED, Direction.OUT, "battled")) {
                    if (edge.<Integer>value("time")>1000)
                        h.property("oldFighter", true);
                }
            }
        }).
        build();

The log processor above processes transactions for the battle log identifier with a single change processor which evaluates battled edges that were added to Hercules. This example demonstrates that the transaction handle passed into the change processor is a normal JanusGraphTransaction which query the JanusGraph graph and make changes to it.

14.1. Transaction Log Use Cases

14.1.1. Record of Change

The user transaction log can be used to keep a record of all changes made against the graph. By using separate log identifiers, changes can be recorded in different logs to distinguish separate transaction types.

At any time, a log processor can be built which can processes all recorded changes starting from the desired start time. This can be used for forensic analysis, to replay changes against a different graph, or to compute an aggregate.

14.1.2. Downstream Updates

It is often the case that a JanusGraph graph cluster is part of a larger architecture. The user transaction log and the log processor framework provide the tools needed to broadcast changes to other components of the overall system without slowing down the original transactions causing the change. This is particularly useful when transaction latencies need to be low and/or there are a number of other systems that need to be alerted to a change in the graph.

14.1.3. Triggers

The user transaction log provides the basic infrastructure to implement triggers that can scale to a large number of concurrent transactions and very large graphs. A trigger is registered with a particular change of data and either triggers an event in an external system or additional changes to the graph. At scale, it is not advisable to implement triggers in the original transaction but rather process triggers with a slight delay through the log processor framework. The second example shows how changes to the graph can be evaluated and trigger additional modifications.

14.2. Log Configuration

There are a number of configuration options to fine tune how the log processor reads from the log. Refer to the complete list of configuration options Chapter 15, Configuration Reference for the options under the log namespace. To configure the user transaction log, use the log.user namespace. The options listed there allow the configuration of the number of threads to be used, the number of log records read in each batch, the read interval, and whether the transaction change records should automatically expire and be removed from the log after a configurable amount of time (TTL).