A graph’s structure is the topology formed by the explicit references between its vertices, edges, and properties. A vertex has incident edges. A vertex is adjacent to another vertex if they share an incident edge. A property is attached to an element and an element has a set of properties. A property is a key/value pair, where the key is always a character String. Conceptual knowledge of how a graph is composed is essential to end-users working with graphs, however, as mentioned earlier, the structure API is not the appropriate way for users to think when building applications with TinkerPop. The structure API is reserved for usage by graph providers. Those interested in implementing the structure API to make their graph system TinkerPop enabled can learn more about it in the Graph Provider documentation.

The primary way in which graphs are processed are via graph traversals. The TinkerPop process API is focused on allowing users to create graph traversals in a syntactically-friendly way over the structures defined in the previous section. A traversal is an algorithmic walk across the elements of a graph according to the referential structure explicit within the graph data structure. For example: "What software does vertex 1’s friends work on?" This English-statement can be represented in the following algorithmic/traversal fashion:

Traversals in Gremlin are spawned from a TraversalSource. The GraphTraversalSource is the typical "graph-oriented" DSL used throughout the documentation and will most likely be the most used DSL in a TinkerPop application. GraphTraversalSource provides two traversal methods.

The return type of V() and E() is a GraphTraversal. A GraphTraversal maintains numerous methods that return GraphTraversal. In this way, a GraphTraversal supports function composition. Each method of GraphTraversal is called a step and each step modulates the results of the previous step in one of five general ways.

Nearly every step in GraphTraversal either extends MapStep, FlatMapStep, FilterStep, SideEffectStep, or BranchStep.

Given the TinkerPop graph, the following query will return the names of all the people that the marko-vertex knows. The following query is demonstrated using Gremlin-Groovy.

Or, if the marko-vertex is already realized with a direct reference pointer (i.e. a variable), then the traversal can be spawned off that vertex.

TinkerPop maintains the reference implementation for the GTM, which is written in Java and thus available for the Java Virtual Machine (JVM). This is the classic model that TinkerPop has long been based on and many examples, blog posts and other resources on the internet will be demonstrated in this style. It is worth noting that the embedded mode is not restricted to just Java as a programming language. Any JVM language can take this approach and in some cases there are language specific wrappers that can help make Gremlin more convenient to use in the style and capability of that language. Examples of these wrappers include gremlin-scala and Ogre (for Clojure).

In this mode, users will start by creating a Graph instance, followed by a GraphTraversalSource which is the class from which Gremlin traversals are spawned. Graphs that allow this sort of direct instantiation are obviously ones that are JVM-based (or have a JVM-based connector) and directly implement TinkerPop interfaces.

The "graph" is then used to spawn a GraphTraversalSource as follows and typically, by convention, this variable is named "g":

While the TinkerPop Community strives to ensure consistent behavior among all modes of usage, the embedded mode does provide the greatest level of flexibility and control. There are a number of features that can only work if using a JVM language. The following list outlines a number of these available options:

A JVM-based graph may be hosted in TinkerPop’s Gremlin Server. Gremlin Server exposes the graph as an endpoint to which different clients can connect, essentially providing a remote GTM. Gremlin Server supports multiple methods for clients to interface with it:

Users are encouraged to use the bytecode-based approach with websockets because it allows them to write Gremlin in the language of their choice. Connecting looks somewhat similar to the embedded approach in that there is a need to create a GraphTraversalSource. In the embedded approach, the means for that object’s creation is derived from a Graph object which spawns it. In this case, however, the Graph instance exists only on the server which means that there is no Graph instance to create locally. The approach is to instead create a GraphTraversalSource anonymously with AnonymousTraversalSource and then apply some "remote" options that describe the location of the Gremlin Server to connect to:

As shown in the embedded approach in the previous section, once "g" is defined, writing Gremlin is structurally and conceptually the same irrespective of programming language.

Remote Gremlin Providers (RGPs) are showing up more and more often in the graph database space. In TinkerPop terms, this category of graph providers is defined by those who simply support the Gremlin language. Typically, these are server-based graphs, often cloud-based, which accept Gremlin scripts or bytecode as a request and return results. They will often implement Gremlin Server protocols, which enables TinkerPop drivers to connect to them as they would with Gremlin Server. Therefore, the typical connection approach is identical to the method of connection presented in the previous section with the exact same caveats pointed out toward the end.

Despite leveraging TinkerPop protocols and drivers as being typical, RGPs are not required to do so to be considered TinkerPop-enabled. RGPs may well have their own drivers and protocols that may plug into Gremlin Language Variants and may allow for more advanced options like better security, cluster awareness, batched requests or other features. The details of these different systems are outside the scope of this documentation, so be sure to consult their documentation for more information.

When on the JVM using an embedded graph, there is considerable flexibility for working with transactions. With the Graph API, transactions are controlled by an implementation of the Transaction interface and that object can be obtained from the Graph interface using the tx() method. It is important to note that the Transaction object does not represent a "transaction" itself. It merely exposes the methods for working with transactions (e.g. committing, rolling back, etc).

Most Graph implementations that supportsTransactions will implement an "automatic" ThreadLocal transaction, which means that when a read or write occurs after the Graph is instantiated, a transaction is automatically started within that thread. There is no need to manually call a method to "create" or "start" a transaction. Simply modify the graph as required and call graph.tx().commit() to apply changes or graph.tx().rollback() to undo them. When the next read or write action occurs against the graph, a new transaction will be started within that current thread of execution.

When using transactions in this fashion, especially in web application (e.g. HTTP server), it is important to ensure that transactions do not leak from one request to the next. In other words, unless a client is somehow bound via session to process every request on the same server thread, every request must be committed or rolled back at the end of the request. By ensuring that the request encapsulates a transaction, it ensures that a future request processed on a server thread is starting in a fresh transactional state and will not have access to the remains of one from an earlier request. A good strategy is to rollback a transaction at the start of a request, so that if it so happens that a transactional leak does occur between requests somehow, a fresh transaction is assured by the fresh request.

The available capability for transactions with Gremlin Server is dependent upon the method of interaction that is used. The preferred method for interacting with Gremlin Server is via websockets and bytecode based requests. The start of the Transactions Section describes this approach in detail with examples.

Gremlin Server also has the option to accept Gremlin-based scripts. The scripting approach provides access to the Graph API and thus also the transactional model described in the embedded section. Therefore a single script can have the ability to execute multiple transactions per request with complete control provided to the developer to commit or rollback transactions as needed.

There are two methods for sending scripts to Gremlin Server: sessionless and session-based. With sessionless requests there will always be an attempt to close the transaction at the end of the request with a commit if there are no errors or a rollback if there is a failure. It is therefore unnecessary to close transactions manually within scripts themselves. By default, session-based requests do not have this quality. The transaction will be held open on the server until the user closes it manually. There is an option to have automatic transaction management for sessions. More information on this topic can be found in the Considering Transactions Section and the Considering Sessions Section.

At this time, transactional patterns for Remote Gremlin Providers are largely in line with Gremlin Server. As most of RGPs do not expose a Graph instance, access to lower level transactional functions available to embedded graphs even in a sessionless fashion are not typically permitted. For example, without a Graph instance it is not possible to configure transaction close or read-write behaviors. The nature of what a "transaction" means will be dependent on the RGP as is the case with any TinkerPop-enabled graph system, so it is important to consult that systems documentation for more details.

The with() configuration adds arbitrary data to a TraversalSource which can then be used by graph providers as configuration options for a traversal execution. This configuration is similar to with()-modulator which has similar functionality when applied to an individual step.

The 0.33 value for the "providerDefinedVariable" will be bound to each traversal spawned that way. Consult the graph system being used to determine if any such configuration options are available.

The withBulk() configuration allows for control of bulking operations. This value is true by default allowing for normal bulking operations, but when set to false, introduces a subtle change in that behavior as shown in examples in sack()-step.

The withComputer() configuration adds a Computer that will be used to process the traversal and is necessary for OLAP based processing and steps that require that processing. See examples related to SparkGraphComputer or see examples in the computer required steps, like pageRank() or [shortestpath-shortestPath()].

The withSack() configuration adds a "sack" that can be accessed by traversals spawned from this source. This functionality is shown in more detail in the examples for (sack())-step.

The withSideEffect() configuration adds an arbitrary Object to traversals spawned from this source which can be accessed as a side-effect given the supplied key.

More practical examples can be found in other examples elsewhere in the documentation. The math()-step example and the where()-step example should both be helpful in examining this configuration step more closely.

The withStrategies() configuration allows inclusion of additional TraversalStrategy instances to be applied to any traversals spawned from the configured source. Please see the Traversal Strategy Section for more details on how this configuration works.

The withoutStrategies() configuration removes a particular TraversalStrategy from those to be applied to traversals spawned from the configured source. Please see the Traversal Strategy Section for more details on how this configuration works.

There are five general steps, each having a traversal and a lambda representation, by which all other specific steps described later extend.

The Traverser<S> object provides access to:

Typically, when a step is concatenated to a traversal a traversal is returned. In this way, a traversal is built up in a fluent, monadic fashion. However, some steps do not return a traversal, but instead, execute the traversal and return a result. These steps are known as terminal steps (terminal) and they are explained via the examples below.

There is also the promise() terminator step, which can only be used with remote traversals to Gremlin Server or RGPs. It starts a promise to execute a function on the current Traversal that will be completed in the future.

Finally, explain()-step is also a terminal step and is described in its own section.

Reasoning is the process of making explicit what is implicit in the data. What is explicit in a graph are the objects of the graph — i.e. vertices and edges. What is implicit in the graph is the traversal. In other words, traversals expose meaning where the meaning is determined by the traversal definition. For example, take the concept of a "co-developer." Two people are co-developers if they have worked on the same project together. This concept can be represented as a traversal and thus, the concept of "co-developers" can be derived. Moreover, what was once implicit can be made explicit via the addE()-step (map/sideEffect).

Additional References

addE(String), addE(Traversal)

The addV()-step is used to add vertices to the graph (map/sideEffect). For every incoming object, a vertex is created. Moreover, GraphTraversalSource maintains an addV() method.

Additional References

addV(), addV(String), addV(Traversal)

The aggregate()-step (sideEffect) is used to aggregate all the objects at a particular point of traversal into a Collection. The step is uses Scope to help determine the aggregating behavior. For global scope this means that the step will use eager evaluation in that no objects continue on until all previous objects have been fully aggregated. The eager evaluation model is crucial in situations where everything at a particular point is required for future computation. By default, when the overload of aggregate() is called without a Scope, the default is global. An example is provided below.

In recommendation systems, the above pattern is used:

Finally, aggregate()-step can be modulated via by()-projection.

For local scope the aggregation will occur in a lazy fashion.

It is important to note that EarlyLimitStrategy introduced in 3.3.5 alters the behavior of aggregate(local). Without that strategy (which is installed by default), there are two results in the aggregate() side-effect even though the interval selection is for 1 object. Realize that when the second object is on its way to the range() filter (i.e. [0..1]), it passes through aggregate() and thus, stored before filtered.

Additional References

aggregate(String), aggregate(Scope,String)

It is possible to filter list traversers using all()-step (filter). Every item in the list will be tested against the supplied predicate and if all of the items pass then the traverser is passed along the stream, otherwise it is filtered. Empty lists are passed along but null or non-iterable traversers are filtered out.

Additional References

all(P), P

The and()-step ensures that all provided traversals yield a result (filter). Please see or() for or-semantics.

The and()-step can take an arbitrary number of traversals. All traversals must produce at least one output for the original traverser to pass to the next step.

An infix notation can be used as well.

Additional References

and(Traversal…​)

It is possible to filter list traversers using any()-step (filter). All items in the list will be tested against the supplied predicate and if any of the items pass then the traverser is passed along the stream, otherwise it is filtered. Empty lists, null traversers, and non-iterable traversers are filtered out as well.

Additional References

any(P), P

The as()-step is not a real step, but a "step modulator" similar to by() and option(). With as(), it is possible to provide a label to the step that can later be accessed by steps and data structures that make use of such labels — e.g., select(), match(), and path.

A step can have any number of labels associated with it. This is useful for referencing the same step multiple times in a future step.

Additional References

as(String,String…​)

The asString()-step (map) returns the value of incoming traverser as strings. Null values are returned unchanged.

Additional References

asString() asString(Scope)

The asDate()-step (map) converts string or numeric input to Date.

For string input only ISO-8601 format is supported. For numbers, the value is considered as the number of the milliseconds since "the epoch" (January 1, 1970, 00:00:00 GMT). Date input is passed without changes.

If the incoming traverser is not a string, number or Date then an IllegalArgumentException will be thrown.

Additional References

asDate()

The barrier()-step (barrier) turns the lazy traversal pipeline into a bulk-synchronous pipeline. This step is useful in the following situations:

The theory behind a "bulking optimization" is simple. If there are one million traversers at vertex 1, then there is no need to calculate one million both()-computations. Instead, represent those one million traversers as a single traverser with a Traverser.bulk() equal to one million and execute both() once. A bulking optimization example is made more salient on a larger graph. Therefore, the example below leverages the Grateful Dead graph.

If barrier() is provided an integer argument, then the barrier will only hold n-number of unique traversers in its barrier before draining the aggregated traversers to the next step. This is useful in the aforementioned bulking optimization scenario with the added benefit of reducing the risk of an out-of-memory exception.

LazyBarrierStrategy inserts barrier()-steps into a traversal where appropriate in order to gain the "bulking optimization."

Additional References

barrier(), barrier(Consumer), barrier(int)

The branch() step splits the traverser to all the child traversals provided to it. Please see the General Steps section for more information, but also consider that branch() is the basis for more robust steps like choose() and union().

Additional References

map(Traversal)

The by()-step is not an actual step, but instead is a "step-modulator" similar to as() and option(). If a step is able to accept traversals, functions, comparators, etc. then by() is the means by which they are added. The general pattern is step().by()…​by(). Some steps can only accept one by() while others can take an arbitrary amount.

When a by() modulator does not produce a result, it is deemed "unproductive". An "unproductive" modulator will lead to the filtering of the traverser it is currently working with. The filtering will manifest in various ways depending on the step.

The following steps all support by()-modulation. Note that the semantics of such modulation should be understood on a step-by-step level and thus, as discussed in their respective section of the documentation.

Additional References

by(), by(Comparator), by(Function,Comparator), by(Function), by(Order), by(String), by(String,Comparator), by(T), by(Traversal), by(Traversal,Comparator), T, Order

The call() step allows for custom, provider-specific service calls either at the start of a traversal or mid-traversal. This allows Graph providers to expose operations not natively built into the Gremlin language, such as full text search, custom analytics, notification triggers, etc.

When called with no arguments, call() will produce a list of callable services available for the graph in use. This no-argument version is equivalent to call('--list'). This "directory service" is also capable of producing more verbose output describing all the services or an individual service:

The first argument to call() is always the name of the service call. Additionally, service calls can accept both static and dynamically produced parameters. Static parameters can be passed as a Map to the call() as the second argument. Individual static parameters can also be added using the .with() modulator. Dynamic parameters can be passed as a Map-producing Traversal as the second argument (no static parameters) or third argument (static + dynamic parameters). Additional individual dynamic parameters can be added using the .with() modulator.

Additional References

GraphTraversalSource:

call() call(String) call(String, Map) call(String, Traversal) call(String, Map, Traversal)

GraphTraversal:

call(String) call(String, Map) call(String, Traversal) call(String, Map, Traversal)

The cap()-step (barrier) iterates the traversal up to itself and emits the sideEffect referenced by the provided key. If multiple keys are provided, then a Map<String,Object> of sideEffects is emitted.

Additional References

cap(String,String…​)

The choose()-step (branch) routes the current traverser to a particular traversal branch option. With choose(), it is possible to implement if/then/else-semantics as well as more complicated selections.

If the "false"-branch is not provided, then if/then-semantics are implemented.

Note that choose() can have an arbitrary number of options and moreover, can take an anonymous traversal as its choice function.

The choose()-step can leverage the Pick.none option match. For anything that does not match a specified option, the none-option is taken.

Additional References

choose(Function), choose(Predicate,Traversal), choose(Predicate,Traversal,Traversal), choose(Traversal,Traversal), choose(Traversal,Traversal,Traversal), choose(Traversal)

The coalesce()-step evaluates the provided traversals in order and returns the first traversal that emits at least one element.