N
- Node parameter typeV
- Value parameter type@Beta public abstract class AbstractValueGraph<N,V> extends Object implements ValueGraph<N,V>
ValueGraph
. It is recommended to extend
this class rather than implement ValueGraph
directly.
The methods implemented in this class should not be overridden unless the subclass admits a more efficient implementation.
Constructor and Description |
---|
AbstractValueGraph() |
Modifier and Type | Method and Description |
---|---|
Graph<N> |
asGraph()
Returns a live view of this graph as a
Graph . |
int |
degree(N node)
Returns the count of
node 's incident edges, counting self-loops twice (equivalently,
the number of times an edge touches node ). |
protected long |
edgeCount()
Returns the number of edges in this graph; used to calculate the size of
edges() . |
Set<EndpointPair<N>> |
edges()
|
boolean |
equals(Object obj)
Indicates whether some other object is "equal to" this one.
|
boolean |
hasEdgeConnecting(N nodeU,
N nodeV)
Returns true if there is an edge directly connecting
nodeU to nodeV . |
int |
hashCode()
Returns a hash code value for the object.
|
Set<EndpointPair<N>> |
incidentEdges(N node)
Returns the edges in this graph whose endpoints include
node . |
int |
inDegree(N node)
Returns the count of
node 's incoming edges (equal to predecessors(node).size() )
in a directed graph. |
int |
outDegree(N node)
Returns the count of
node 's outgoing edges (equal to successors(node).size() )
in a directed graph. |
String |
toString()
Returns a string representation of this graph.
|
clone, finalize, getClass, notify, notifyAll, wait, wait, wait
adjacentNodes, allowsSelfLoops, degree, edges, edgeValueOrDefault, hasEdgeConnecting, incidentEdges, inDegree, isDirected, nodeOrder, nodes, outDegree, predecessors, successors
public AbstractValueGraph()
public Graph<N> asGraph()
ValueGraph
Graph
. The resulting Graph
will have an
edge connecting node A to node B if this ValueGraph
has an edge connecting A to B.asGraph
in interface ValueGraph<N,V>
public final boolean equals(@NullableDecl Object obj)
java.lang.Object
The equals
method implements an equivalence relation
on non-null object references:
x
, x.equals(x)
should return
true
.
x
and y
, x.equals(y)
should return true
if and only if
y.equals(x)
returns true
.
x
, y
, and z
, if
x.equals(y)
returns true
and
y.equals(z)
returns true
, then
x.equals(z)
should return true
.
x
and y
, multiple invocations of
x.equals(y)
consistently return true
or consistently return false
, provided no
information used in equals
comparisons on the
objects is modified.
x
,
x.equals(null)
should return false
.
The equals
method for class Object
implements
the most discriminating possible equivalence relation on objects;
that is, for any non-null reference values x
and
y
, this method returns true
if and only
if x
and y
refer to the same object
(x == y
has the value true
).
Note that it is generally necessary to override the hashCode
method whenever this method is overridden, so as to maintain the
general contract for the hashCode
method, which states
that equal objects must have equal hash codes.
equals
in interface ValueGraph<N,V>
equals
in class Object
obj
- the reference object with which to compare.true
if this object is the same as the obj
argument; false
otherwise.Object.hashCode()
,
HashMap
public final int hashCode()
java.lang.Object
HashMap
.
The general contract of hashCode
is:
hashCode
method
must consistently return the same integer, provided no information
used in equals
comparisons on the object is modified.
This integer need not remain consistent from one execution of an
application to another execution of the same application.
equals(Object)
method, then calling the hashCode
method on each of
the two objects must produce the same integer result.
Object.equals(java.lang.Object)
method, then calling the hashCode
method on each of the
two objects must produce distinct integer results. However, the
programmer should be aware that producing distinct integer results
for unequal objects may improve the performance of hash tables.
As much as is reasonably practical, the hashCode method defined by
class Object
does return distinct integers for distinct
objects. (This is typically implemented by converting the internal
address of the object into an integer, but this implementation
technique is not required by the
Java™ programming language.)
hashCode
in interface ValueGraph<N,V>
hashCode
in class Object
Object.equals(java.lang.Object)
,
System.identityHashCode(java.lang.Object)
protected long edgeCount()
edges()
. This
implementation requires O(|N|) time. Classes extending this one may manually keep track of the
number of edges as the graph is updated, and override this method for better performance.public Set<EndpointPair<N>> edges()
public Set<EndpointPair<N>> incidentEdges(N node)
node
.public int degree(N node)
node
's incident edges, counting self-loops twice (equivalently,
the number of times an edge touches node
).
For directed graphs, this is equal to inDegree(node) + outDegree(node)
.
For undirected graphs, this is equal to incidentEdges(node).size()
+ (number of
self-loops incident to node
).
If the count is greater than Integer.MAX_VALUE
, returns Integer.MAX_VALUE
.
public int inDegree(N node)
node
's incoming edges (equal to predecessors(node).size()
)
in a directed graph. In an undirected graph, returns the degree(Object)
.
If the count is greater than Integer.MAX_VALUE
, returns Integer.MAX_VALUE
.
public int outDegree(N node)
node
's outgoing edges (equal to successors(node).size()
)
in a directed graph. In an undirected graph, returns the degree(Object)
.
If the count is greater than Integer.MAX_VALUE
, returns Integer.MAX_VALUE
.
public boolean hasEdgeConnecting(N nodeU, N nodeV)
nodeU
to nodeV
. This is
equivalent to nodes().contains(nodeU) && successors(nodeU).contains(nodeV)
.
In an undirected graph, this is equal to hasEdgeConnecting(nodeV, nodeU)
.
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