A graph is composed of a set of nodes and a set of edges connecting pairs of nodes. * *
There are three primary interfaces provided to represent graphs. In order of increasing * complexity they are: {@link Graph}, {@link ValueGraph}, and {@link Network}. You should generally * prefer the simplest interface that satisfies your use case. See the * "Choosing the right graph type" section of the Guava User Guide for more details. * *
{@code ValueGraph} supports the following use cases (definitions of * terms): * *
{@code ValueGraph}, as a subtype of {@code Graph}, explicitly does not support parallel edges, * and forbids implementations or extensions with parallel edges. If you need parallel edges, use * {@link Network}. (You can use a positive {@code Integer} edge value as a loose representation of * edge multiplicity, but the {@code *degree()} and mutation methods will not reflect your * interpretation of the edge value as its multiplicity.) * *
The implementation classes that {@code common.graph} provides are not public, by design. To * create an instance of one of the built-in implementations of {@code ValueGraph}, use the {@link * ValueGraphBuilder} class: * *
{@code
* MutableValueGraph graph = ValueGraphBuilder.directed().build();
* }
*
* {@link ValueGraphBuilder#build()} returns an instance of {@link MutableValueGraph}, which is a * subtype of {@code ValueGraph} that provides methods for adding and removing nodes and edges. If * you do not need to mutate a graph (e.g. if you write a method than runs a read-only algorithm on * the graph), you should use the non-mutating {@link ValueGraph} interface, or an {@link * ImmutableValueGraph}. * *
You can create an immutable copy of an existing {@code ValueGraph} using {@link * ImmutableValueGraph#copyOf(ValueGraph)}: * *
{@code
* ImmutableValueGraph immutableGraph = ImmutableValueGraph.copyOf(graph);
* }
*
* Instances of {@link ImmutableValueGraph} do not implement {@link MutableValueGraph} * (obviously!) and are contractually guaranteed to be unmodifiable and thread-safe. * *
The Guava User Guide has more * information on (and examples of) building graphs. * *
See the Guava User Guide for the {@code common.graph} package ("Graphs Explained") for * additional documentation, including: * *
This is equal to the union of {@link #predecessors(Object)} and {@link #successors(Object)}. * *
If {@code node} is removed from the graph after this method is called, the {@code Set} * {@code view} returned by this method will be invalidated, and will throw {@code * IllegalStateException} if it is accessed in any way, with the following exceptions: * *
In an undirected graph, this is equivalent to {@link #adjacentNodes(Object)}. * *
If {@code node} is removed from the graph after this method is called, the `Set` returned by
* this method will be invalidated, and will throw `IllegalStateException` if it is accessed in
* any way.
*
* @throws IllegalArgumentException if {@code node} is not an element of this graph
*/
@Override
Set In an undirected graph, this is equivalent to {@link #adjacentNodes(Object)}.
*
* This is not the same as "all nodes reachable from {@code node} by following outgoing
* edges". For that functionality, see {@link Graphs#reachableNodes(Graph, Object)}.
*
* If {@code node} is removed from the graph after this method is called, the {@code Set}
* {@code view} returned by this method will be invalidated, and will throw {@code
* IllegalStateException} if it is accessed in any way, with the following exceptions:
*
* This is equal to the union of incoming and outgoing edges.
*
* If {@code node} is removed from the graph after this method is called, the {@code Set}
* {@code view} returned by this method will be invalidated, and will throw {@code
* IllegalStateException} if it is accessed in any way, with the following exceptions:
*
* For directed graphs, this is equal to {@code inDegree(node) + outDegree(node)}.
*
* For undirected graphs, this is equal to {@code incidentEdges(node).size()} + (number of
* self-loops incident to {@code node}).
*
* If the count is greater than {@code Integer.MAX_VALUE}, returns {@code Integer.MAX_VALUE}.
*
* @throws IllegalArgumentException if {@code node} is not an element of this graph
*/
@Override
int degree(N node);
/**
* Returns the count of {@code node}'s incoming edges (equal to {@code predecessors(node).size()})
* in a directed graph. In an undirected graph, returns the {@link #degree(Object)}.
*
* If the count is greater than {@code Integer.MAX_VALUE}, returns {@code Integer.MAX_VALUE}.
*
* @throws IllegalArgumentException if {@code node} is not an element of this graph
*/
@Override
int inDegree(N node);
/**
* Returns the count of {@code node}'s outgoing edges (equal to {@code successors(node).size()})
* in a directed graph. In an undirected graph, returns the {@link #degree(Object)}.
*
* If the count is greater than {@code Integer.MAX_VALUE}, returns {@code Integer.MAX_VALUE}.
*
* @throws IllegalArgumentException if {@code node} is not an element of this graph
*/
@Override
int outDegree(N node);
/**
* Returns true if there is an edge that directly connects {@code nodeU} to {@code nodeV}. This is
* equivalent to {@code nodes().contains(nodeU) && successors(nodeU).contains(nodeV)}.
*
* In an undirected graph, this is equal to {@code hasEdgeConnecting(nodeV, nodeU)}.
*
* @since 23.0
*/
@Override
boolean hasEdgeConnecting(N nodeU, N nodeV);
/**
* Returns true if there is an edge that directly connects {@code endpoints} (in the order, if
* any, specified by {@code endpoints}). This is equivalent to {@code
* edges().contains(endpoints)}.
*
* Unlike the other {@code EndpointPair}-accepting methods, this method does not throw if the
* endpoints are unordered and the graph is directed; it simply returns {@code false}. This is for
* consistency with the behavior of {@link Collection#contains(Object)} (which does not generally
* throw if the object cannot be present in the collection), and the desire to have this method's
* behavior be compatible with {@code edges().contains(endpoints)}.
*
* @since 27.1
*/
@Override
boolean hasEdgeConnecting(EndpointPair In an undirected graph, this is equal to {@code edgeValueOrDefault(nodeV, nodeU,
* defaultValue)}.
*
* @throws IllegalArgumentException if {@code nodeU} or {@code nodeV} is not an element of this
* graph
*/
@CheckForNull
V edgeValueOrDefault(N nodeU, N nodeV, @CheckForNull V defaultValue);
/**
* Returns the value of the edge that connects {@code endpoints} (in the order, if any, specified
* by {@code endpoints}), if one is present; otherwise, returns {@code defaultValue}.
*
* If this graph is directed, the endpoints must be ordered.
*
* @throws IllegalArgumentException if either endpoint is not an element of this graph
* @throws IllegalArgumentException if the endpoints are unordered and the graph is directed
* @since 27.1
*/
@CheckForNull
V edgeValueOrDefault(EndpointPair Thus, two value graphs A and B are equal if all of the following are true:
*
* Graph properties besides {@link #isDirected() directedness} do not affect equality.
* For example, two graphs may be considered equal even if one allows self-loops and the other
* doesn't. Additionally, the order in which nodes or edges are added to the graph, and the order
* in which they are iterated over, are irrelevant.
*
* A reference implementation of this is provided by {@link AbstractValueGraph#equals(Object)}.
*/
@Override
boolean equals(@CheckForNull Object object);
/**
* Returns the hash code for this graph. The hash code of a graph is defined as the hash code of a
* map from each of its {@link #edges() edges} to the associated {@link #edgeValueOrDefault(N, N,
* V) edge value}.
*
* A reference implementation of this is provided by {@link AbstractValueGraph#hashCode()}.
*/
@Override
int hashCode();
}
*
*
* @throws IllegalArgumentException if {@code node} is not an element of this graph
*/
@Override
Set
*
*
* @throws IllegalArgumentException if {@code node} is not an element of this graph
* @since 24.0
*/
@Override
Set
*
*
*