Table of Contents
- 9.1. Overview
- 9.2. ConfiguredGraphFactory versus JanusGraphFactory
- 9.3. How Does the ConfiguredGraphFactory Work?
- 9.4. Accessing the Graphs
- 9.5. Listing the Graphs
- 9.6. Dropping a Graph
- 9.7. Configuring JanusGraph Server for ConfiguredGraphFactory
- 9.8. ConfigurationManagementGraph
- 9.9. JanusGraphManager
- 9.10. Examples
The JanusGraph Server can be configured to use the ConfiguredGraphFactory
.
The ConfiguredGraphFactory
is an access point to your graphs, similar
to the JanusGraphFactory
. These graph factories provide methods for
dynamically managing the graphs hosted on the server.
JanusGraphFactory
is a class that provides an access point to your
graphs by providing a Configuration object each time you access the graph.
ConfiguredGraphFactory
provides an access point to your graphs for which
you have previously created configurations using the
ConfigurationManagementGraph
. It also offers an access point to manage
graph configurations.
ConfigurationManagementGraph
allows you to manage graph configurations.
JanusGraphManager
is an internal server component that tracks
graph references, provided your graphs are configured to use it.
However, there is an important distinction between these two graph factories:
- The
ConfiguredGraphFactory
can only be used if you have configured your server to use theConfigurationManagementGraph
APIs at server start.
The benefits of using the ConfiguredGraphFactory
are that:
- You only need to supply a
String
to access your graphs, as opposed to theJanusGraphFactory
-- which requires you to specify information about the backend you wish to use when accessing a graph-- every time you open a graph. - If your ConfigurationManagementGraph is configured with a distributed storage backend then your graph configurations are available to all JanusGraph nodes in your cluster.
The ConfiguredGraphFactory
provides an access point to graphs under
two scenarios:
- You have already created a configuration for your specific graph
object using the
ConfigurationManagementGraph#createConfiguration
. In this scenario, your graph is opened using the previously created configuration for this graph. - You have already created a template configuration using the
ConfigurationManagementGraph#createTemplateConfiguration
. In this scenario, we create a configuration for the graph you are creating by copying over all attributes stored in your template configuration and appending the relevant graphName attribute, and we then open the graph according to that specific configuration.
You can either use ConfiguredGraphFactory.create("graphName")
or ConfiguredGraphFactory.open("graphName")
. Learn more about the difference
between these two options by reading the section below about the ConfigurationManagementGraph
.
ConfiguredGraphFactory.getGraphNames()
will return a set of graph names
for which you have created configurations using the ConfigurationManagementGraph
APIs.
JanusGraphFactory.getGraphNames()
on the other hand returns a set of graph names
for which you have instantiated and the references are stored inside the JanusGraphManager
.
ConfiguredGraphFactory.drop("graphName")
will drop the graph database, deleting all data in storage and indexing backends. The graph can be open or closed (will be closed as part of the drop operation). Furthermore, this will also remove any existing graph configuration in the ConfigurationManagementGraph
.
Important | |
---|---|
This is an irreversible operation that will delete all graph and index data. |
Important | |
---|---|
To ensure all graph representations are consistent across all JanusGraph nodes in your cluster, remove the graph from the |
To be able to use the ConfiguredGraphFactory
, you must configure your
server to use the ConfigurationManagementGraph
APIs. To do this, you
have to inject a graph variable named "ConfigurationManagementGraph" in your
server’s YAML’s graphs
map. For example:
graphManager: org.janusgraph.graphdb.management.JanusGraphManager graphs: { ConfigurationManagementGraph: conf/JanusGraph-configurationmanagement.properties }
In this example, our ConfigurationManagementGraph
graph will be
configured using the properties stored inside
conf/JanusGraph-configurationmanagement.properties
, which for
example, look like:
gremlin.graph=org.janusgraph.core.JanusGraphFactory storage.backend=cql graph.graphname=ConfigurationManagementGraph storage.hostname=127.0.0.1
Assuming the GremlinServer started successfully and the
ConfigurationManagementGraph
was successfully instantiated, then all the
APIs available on the ConfigurationManagementGraph
Singleton
will
also act upon said graph. Furthermore, this is the graph that will be
used to access the configurations used to create/open graphs using the
ConfiguredGraphFactory
.
Important | |
---|---|
The |
The ConfigurationManagementGraph
is a Singleton
that allows you to
create/update/remove configurations that you can use to access your
graphs using the ConfiguredGraphFactory
. See above on configuring your
server to enable use of these APIs.
Important | |
---|---|
The ConfiguredGraphFactory offers an access point to manage your
graph configurations managed by the |
The ConfigurationManagementGraph
singleton allows you to create
configurations used to open specific graphs, referenced by the
graph.graphname
property. For example:
map = new HashMap<String, Object>(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); map.put("graph.graphname", "graph1"); ConfiguredGraphFactory.createConfiguration(new MapConfiguration(map));
Then you could access this graph on any JanusGraph node using:
ConfiguredGraphFactory.open("graph1");
The ConfigurationManagementGraph
also allows you to create one
template configuration, which you can use to create many graphs using
the same configuration template. For example:
map = new HashMap<String, Object>(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); ConfiguredGraphFactory.createTemplateConfiguration(new MapConfiguration(map));
After doing this, you can create graphs using the template configuration:
ConfiguredGraphFactory.create("graph2");
This method will first create a new configuration for "graph2" by copying over all the properties associated with the template configuration and storing it on a configuration for this specific graph. This means that this graph can be accessed in, on any JanusGraph node, in the future by doing:
ConfiguredGraphFactory.open("graph2");
All interactions with both the JanusGraphFactory
and the
ConfiguredGraphFactory
that interact with configurations that define
the property graph.graphname
go through the JanusGraphManager
which
keeps track of graph references created on the given JVM. Think of it as
a graph cache. For this reason:
Important | |
---|---|
Any updates to a configuration are not guaranteed to take effect until you remove the graph in question on every JanusGraph node in your cluster. |
You can do so by calling:
ConfiguredGraphFactory.close("graph2");
Since graphs created using the template configuration first create a configuration for that graph in question using a copy and create method, this means that:
Important | |
---|---|
Any updates to a specific graph created using the template configuration are not guaranteed to take effect on the specific graph until:
|
1) We migrated our Cassandra data to a new server with a new IP address:
map = new HashMap(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); map.put("graph.graphname", "graph1"); ConfiguredGraphFactory.createConfiguration(new MapConfiguration(map)); g1 = ConfiguredGraphFactory.open("graph1"); // Update configuration map = new HashMap(); map.put("storage.hostname", "10.0.0.1"); ConfiguredGraphFactory.updateConfiguration("graph1", map); // Close graph ConfiguredGraphFactory.close("graph1"); // We are now guaranteed to use the updated configuration g1 = ConfiguredGraphFactory.open("graph1");
2) We added an Elasticsearch node to our setup:
map = new HashMap(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); map.put("graph.graphname", "graph1"); ConfiguredGraphFactory.createConfiguration(new MapConfiguration(map)); g1 = ConfiguredGraphFactory.open("graph1"); // Update configuration map = new HashMap(); map.put("index.search.backend", "elasticsearch"); map.put("index.search.hostname", "127.0.0.1"); map.put("index.search.elasticsearch.transport-scheme", "http"); ConfiguredGraphFactory.updateConfiguration("graph1", map); // Close graph ConfiguredGraphFactory.close("graph1"); // We are now guaranteed to use the updated configuration g1 = ConfiguredGraphFactory.open("graph1");
3) Update a graph configuration that was created using a template configuration that has been updated:
map = new HashMap(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); ConfiguredGraphFactory.createTemplateConfiguration(new MapConfiguration(map)); g1 = ConfiguredGraphFactory.create("graph1"); // Update template configuration map = new HashMap(); map.put("index.search.backend", "elasticsearch"); map.put("index.search.hostname", "127.0.0.1"); map.put("index.search.elasticsearch.transport-scheme", "http"); ConfiguredGraphFactory.updateTemplateConfiguration(new MapConfiguration(map)); // Remove Configuration ConfiguredGraphFactory.removeConfiguration("graph1"); // Close graph on all JanusGraph nodes ConfiguredGraphFactory.close("graph1"); // Recreate ConfiguredGraphFactory.create("graph1"); // Now this graph's configuration is guaranteed to be updated
The JanusGraphManager
is a Singleton
adhering to the TinkerPop graphManager specifications.
In particular, the JanusGraphManager
provides:
- a coordinated mechanism by which to instantiate graph references on a given JanusGraph node
- a graph reference tracker (or cache)
Any graph you create using the graph.graphname
property will go through the JanusGraphManager
and thus be instantiated in a coordinated fashion. The graph reference will also be placed in the graph cache on the JVM in question.
Thus, any graph you open using the graph.graphname
property that has already been instantiated on the JVM in question will be retrieved from the graph cache.
This is why updates to your configurations require a few steps to guarantee correctness.
This is a new configuration option you can use when defining a property in your configuration that defines how to access a graph. All configurations that include this property will result in the graph instantiation happening through the JanusGraphManager
(process explained above).
For backwards compatibility, any graphs that do not supply this parameter but supplied at server start in your graphs object in your .yaml file, these graphs will be bound through the JanusGraphManager denoted by their key
supplied for that graph. For example, if your .yaml graphs object looks like:
graphManager: org.janusgraph.graphdb.management.JanusGraphManager graphs { graph1: conf/graph1.properties, graph2: conf/graph2.properties }
but conf/graph1.properties
and conf/graph2.properties
do not include the property graph.graphname
, then these graphs will be stored in the JanusGraphManager and thus bound in your gremlin script executions as graph1
and graph2
, respectively.
For convenience, if your configuration used to open a graph specifies graph.graphname
, but does not specify the backend’s storage directory, tablename, or keyspacename, then the relevant parameter will automatically be set to the value of graph.graphname
. However, if you supply one of those parameters, that value will always take precedence. And if you supply neither, they default to the configuration option’s default value.
One special case is storage.root
configuration option. This is a new configuration option used to specify the base of the directory that will be used for any backend requiring local storage directory access. If you supply this parameter, you must also supply the graph.graphname
property, and the absolute storage directory will be equal to the value of the graph.graphname
property appended to the value of the storage.root
property.
Below are some example use cases:
1) Create a template configuration for my Cassandra backend such that each graph created using this configuration gets a unique keyspace equivalent to the String
<graphName> provided to the factory:
map = new HashMap(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); ConfiguredGraphFactory.createTemplateConfiguration(new MapConfiguration(map)); g1 = ConfiguredGraphFactory.create("graph1"); //keyspace === graph1 g2 = ConfiguredGraphFactory.create("graph2"); //keyspace === graph2 g3 = ConfiguredGraphFactory.create("graph3"); //keyspace === graph3
2) Create a template configuration for my BerkeleyJE backend such that each graph created using this configuration gets a unique storage directory equivalent to the "<storage.root>/<graph.graphname>":
map = new HashMap(); map.put("storage.backend", "berkeleyje"); map.put("storage.root", "/data/graphs"); ConfiguredGraphFactory.createTemplateConfiguration(new MapConfiguration(map)); g1 = ConfiguredGraphFactory.create("graph1"); //storage directory === /data/graphs/graph1 g2 = ConfiguredGraphFactory.create("graph2"); //storage directory === /data/graphs/graph2 g3 = ConfiguredGraphFactory.create("graph3"); //storage directory === /data/graphs/graph3
It is reccomended to use a sessioned connection when creating a Configured Graph Factory template. If a sessioned connection is not used the Configured Graph Factory Template creation must be sent to the server as a single line using semi-colons. See details on sessions can be found in Section 7.1.1.1, “Connecting to Gremlin Server”.
gremlin> :remote connect tinkerpop.server conf/remote.yaml session ==>Configured localhost/127.0.0.1:8182 gremlin> :remote console ==>All scripts will now be sent to Gremlin Server - [localhost:8182]-[5206cdde-b231-41fa-9e6c-69feac0fe2b2] - type ':remote console' to return to local mode gremlin> ConfiguredGraphFactory.open("graph"); Please create configuration for this graph using the ConfigurationManagementGraph API. gremlin> ConfiguredGraphFactory.create("graph"); Please create a template Configuration using the ConfigurationManagementGraph API. gremlin> map = new HashMap(); gremlin> map.put("storage.backend", "cql"); gremlin> map.put("storage.hostname", "127.0.0.1"); gremlin> map.put("GraphName", "graph1"); gremlin> ConfiguredGraphFactory.createConfiguration(new MapConfiguration(map)); Please include in your configuration the property "graph.graphname". gremlin> map = new HashMap(); gremlin> map.put("storage.backend", "cql"); gremlin> map.put("storage.hostname", "127.0.0.1"); gremlin> map.put("graph.graphname", "graph1"); gremlin> ConfiguredGraphFactory.createConfiguration(new MapConfiguration(map)); ==>null gremlin> ConfiguredGraphFactory.open("graph1").vertices(); gremlin> map = new HashMap(); map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); gremlin> map.put("graph.graphname", "graph1"); gremlin> ConfiguredGraphFactory.createTemplateConfiguration(new MapConfiguration(map)); Your template configuration may not contain the property "graph.graphname". gremlin> map = new HashMap(); gremlin> map.put("storage.backend", "cql"); map.put("storage.hostname", "127.0.0.1"); gremlin> ConfiguredGraphFactory.createTemplateConfiguration(new MapConfiguration(map)); ==>null // Each graph is now acting in unique keyspaces equivalent to the graphnames. gremlin> g1 = ConfiguredGraphFactory.open("graph1"); gremlin> g2 = ConfiguredGraphFactory.create("graph2"); gremlin> g3 = ConfiguredGraphFactory.create("graph3"); gremlin> g2.addVertex(); gremlin> l = []; gremlin> l << g1.vertices().size(); ==>0 gremlin> l << g2.vertices().size(); ==>1 gremlin> l << g3.vertices().size(); ==>0 // After a graph is created, you must access it using .open() gremlin> g2 = ConfiguredGraphFactory.create("graph2"); g2.vertices().size(); Configuration for graph "graph2" already exists. gremlin> g2 = ConfiguredGraphFactory.open("graph2"); g2.vertices().size(); ==>1