public void ToString2()
{
ToStringTest(1, 2, 3, 4);
ToStringTest(
new TestVertex("1"),
new TestVertex("2"),
new TestVertex("3"),
new TestVertex("4"));
ToStringTest(
new EquatableTestVertex("1"),
new EquatableTestVertex("2"),
new EquatableTestVertex("3"),
new EquatableTestVertex("4"));
#region Local function
void ToStringTest <TVertex>(
TVertex vertex1,
TVertex vertex2,
TVertex vertex3,
TVertex vertex4)
{
var queue = new BinaryQueue <TVertex, double>(_ => 1.0);
// Empty heap => consistent
StringAssert.StartsWith(Consistent, queue.ToString2());
queue.Enqueue(vertex1);
queue.Enqueue(vertex2);
queue.Enqueue(vertex2);
queue.Enqueue(vertex3);
queue.Enqueue(vertex1);
StringAssert.StartsWith(Consistent, queue.ToString2());
queue.Dequeue();
queue.Dequeue();
StringAssert.StartsWith(Consistent, queue.ToString2());
queue.Dequeue();
queue.Dequeue();
queue.Dequeue();
StringAssert.StartsWith(Consistent, queue.ToString2());
queue.Enqueue(vertex4);
StringAssert.StartsWith(Consistent, queue.ToString2());
}
#endregion
}
/// <inheritdoc />
protected override void InternalCompute()
{
ThrowIfCancellationRequested();
while (_edges.Count > 0 && _visitedVertices.Count < VisitedGraph.VertexCount)
{
TEdge minEdge = _queue.Dequeue();
OnExamineEdge(minEdge);
if (!_sets.AreInSameSet(minEdge.Source, minEdge.Target))
{
OnTreeEdge(minEdge);
_sets.Union(minEdge.Source, minEdge.Target);
TVertex lastVertex;
if (_visitedVertices.Contains(minEdge.Source))
{
lastVertex = minEdge.Target;
_visitedVertices.Add(minEdge.Target);
}
else
{
lastVertex = minEdge.Source;
_visitedVertices.Add(minEdge.Source);
}
EnqueueEdgesFrom(lastVertex);
}
}
}
/// <inheritdoc />
protected override void InternalCompute()
{
while (_heap.Count != 0)
{
ThrowIfCancellationRequested();
TVertex vertex = _heap.Dequeue();
if (InDegrees[vertex] != 0)
{
throw new NonAcyclicGraphException();
}
_sortedVertices.Add(vertex);
OnVertexAdded(vertex);
// Update the count of its adjacent vertices
foreach (TEdge edge in VisitedGraph.OutEdges(vertex))
{
--InDegrees[edge.Target];
Debug.Assert(InDegrees[edge.Target] >= 0);
_heap.Update(edge.Target);
}
}
SortedVertices = _sortedVertices.ToArray();
}
protected override void InternalCompute()
{
var cancelManager = this.Services.CancelManager;
var ds = new ForestDisjointSet<TVertex>(this.VisitedGraph.VertexCount);
foreach (var v in this.VisitedGraph.Vertices)
ds.MakeSet(v);
if (cancelManager.IsCancelling)
return;
var queue = new BinaryQueue<TEdge, double>(this.edgeWeights);
foreach (var e in this.VisitedGraph.Edges)
queue.Enqueue(e);
if (cancelManager.IsCancelling)
return;
while (queue.Count > 0)
{
var e = queue.Dequeue();
this.OnExamineEdge(e);
if (!ds.AreInSameSet(e.Source, e.Target))
{
this.OnTreeEdge(e);
ds.Union(e.Source, e.Target);
}
}
}
/// <inheritdoc />
protected override void InternalCompute()
{
var sets = new ForestDisjointSet <TVertex>(VisitedGraph.VertexCount);
foreach (TVertex vertex in VisitedGraph.Vertices)
{
sets.MakeSet(vertex);
}
ThrowIfCancellationRequested();
var queue = new BinaryQueue <TEdge, double>(_edgeWeights);
foreach (TEdge edge in VisitedGraph.Edges)
{
queue.Enqueue(edge);
}
ThrowIfCancellationRequested();
while (queue.Count > 0)
{
TEdge edge = queue.Dequeue();
OnExamineEdge(edge);
if (!sets.AreInSameSet(edge.Source, edge.Target))
{
OnTreeEdge(edge);
sets.Union(edge.Source, edge.Target);
}
}
}
/// <inheritdoc />
protected override void InternalCompute()
{
ICancelManager cancelManager = Services.CancelManager;
while (_heap.Count != 0)
{
if (cancelManager.IsCancelling)
{
return;
}
TVertex vertex = _heap.Dequeue();
int degree = Degrees[vertex];
// 0 => isolated vertex
// 1 => single adjacent edge
if (degree != 0 && degree != 1 && !AllowCyclicGraph)
{
throw new NonAcyclicGraphException();
}
_sortedVertices.Add(vertex);
OnVertexAdded(vertex);
// Update the count of its adjacent vertices
UpdateAdjacentDegree(vertex);
}
SortedVertices = _sortedVertices.ToArray();
#region Local function
void UpdateAdjacentDegree(TVertex vertex)
{
foreach (TEdge edge in VisitedGraph.AdjacentEdges(vertex).Where(e => !e.IsSelfEdge()))
{
TVertex other = edge.GetOtherVertex(vertex);
--Degrees[other];
if (Degrees[other] < 0 && !AllowCyclicGraph)
{
throw new InvalidOperationException("Degree is negative, and cannot be.");
}
if (_heap.Contains(other))
{
_heap.Update(other);
}
}
}
#endregion
}
/// <inheritdoc />
protected override void InternalCompute()
{
ICancelManager cancelManager = Services.CancelManager;
InitializeInDegrees();
while (_heap.Count != 0)
{
if (cancelManager.IsCancelling)
{
return;
}
TVertex vertex = _heap.Dequeue();
if (Degrees[vertex] != 0 && !AllowCyclicGraph)
{
throw new NonAcyclicGraphException();
}
SortedVertices.Add(vertex);
OnVertexAdded(vertex);
// Update the count of its adjacent vertices
UpdateAdjacentDegree(vertex);
}
#region Local function
void UpdateAdjacentDegree(TVertex vertex)
{
foreach (TEdge edge in VisitedGraph.AdjacentEdges(vertex).Where(e => !e.IsSelfEdge()))
{
--Degrees[edge.Target];
if (Degrees[edge.Target] < 0 && !AllowCyclicGraph)
{
throw new InvalidOperationException("Degree is negative, and cannot be.");
}
if (_heap.Contains(edge.Target))
{
_heap.Update(edge.Target);
}
}
}
#endregion
}
/// <inheritdoc />
protected override void InternalCompute()
{
ICancelManager cancelManager = Services.CancelManager;
InitializeInDegrees();
while (_heap.Count != 0)
{
if (cancelManager.IsCancelling)
{
break;
}
TVertex vertex = _heap.Dequeue();
if (InDegrees[vertex] != 0)
{
throw new NonAcyclicGraphException();
}
SortedVertices.Add(vertex);
OnVertexAdded(vertex);
// Update the count of its successor vertices
IEnumerable <TEdge> successorEdges = _direction == TopologicalSortDirection.Forward
? VisitedGraph.OutEdges(vertex)
: VisitedGraph.InEdges(vertex);
foreach (TEdge edge in successorEdges)
{
if (edge.IsSelfEdge())
{
continue;
}
TVertex successor = _direction == TopologicalSortDirection.Forward
? edge.Target
: edge.Source;
--InDegrees[successor];
Debug.Assert(InDegrees[successor] >= 0);
_heap.Update(successor);
}
}
}
/// <inheritdoc />
protected override void InternalCompute()
{
ICancelManager cancelManager = Services.CancelManager;
var sets = new ForestDisjointSet <TVertex>(VisitedGraph.VertexCount);
foreach (TVertex vertex in VisitedGraph.Vertices)
{
sets.MakeSet(vertex);
}
if (cancelManager.IsCancelling)
{
return;
}
var queue = new BinaryQueue <TEdge, double>(_edgeWeights);
foreach (TEdge edge in VisitedGraph.Edges)
{
queue.Enqueue(edge);
}
if (cancelManager.IsCancelling)
{
return;
}
while (queue.Count > 0)
{
TEdge edge = queue.Dequeue();
OnExamineEdge(edge);
if (!sets.AreInSameSet(edge.Source, edge.Target))
{
OnTreeEdge(edge);
sets.Union(edge.Source, edge.Target);
}
}
}
/// <inheritdoc />
protected override void InternalCompute()
{
ICancelManager cancelManager = Services.CancelManager;
InitializeInDegrees();
while (_heap.Count != 0)
{
if (cancelManager.IsCancelling)
{
break;
}
TVertex vertex = _heap.Dequeue();
if (InDegrees[vertex] != 0)
{
throw new NonAcyclicGraphException();
}
SortedVertices.Add(vertex);
OnVertexAdded(vertex);
// Update the count of its adjacent vertices
foreach (TEdge edge in VisitedGraph.OutEdges(vertex))
{
if (edge.IsSelfEdge())
{
continue;
}
--InDegrees[edge.Target];
Debug.Assert(InDegrees[edge.Target] >= 0);
_heap.Update(edge.Target);
}
}
}
/// <inheritdoc />
protected override void InternalCompute()
{
while (_heap.Count != 0)
{
ThrowIfCancellationRequested();
TVertex vertex = _heap.Dequeue();
if (InDegrees[vertex] != 0)
{
throw new NonAcyclicGraphException();
}
_sortedVertices.Add(vertex);
OnVertexAdded(vertex);
// Update the count of its successor vertices
IEnumerable <TEdge> successorEdges = _direction == TopologicalSortDirection.Forward
? VisitedGraph.OutEdges(vertex)
: VisitedGraph.InEdges(vertex);
foreach (TEdge edge in successorEdges)
{
TVertex successor = _direction == TopologicalSortDirection.Forward
? edge.Target
: edge.Source;
--InDegrees[successor];
Debug.Assert(InDegrees[successor] >= 0);
_heap.Update(successor);
}
}
SortedVertices = _sortedVertices.ToArray();
}
protected override void InternalCompute()
{
var cancelManager = this.Services.CancelManager;
var visetedVert = new List <TVertex>();
var visetedEdges = new List <TEdge>();
var ds = new ForestDisjointSet <TVertex>(this.VisitedGraph.VertexCount);
foreach (var v in this.VisitedGraph.Vertices)
{
if (visetedVert.Count == 0)
{
visetedVert.Add(v);
}
ds.MakeSet(v);
}
if (cancelManager.IsCancelling)
{
return;
}
var queue = new BinaryQueue <TEdge, double>(this.edgeWeights);
foreach (var edge in this.VisitedGraph.Edges)
{
if (!visetedEdges.Contains(edge) && (visetedVert.Contains(edge.Source) || visetedVert.Contains(edge.Target)))
{
queue.Enqueue(edge);
visetedEdges.Add(edge);
}
}
if (cancelManager.IsCancelling)
{
return;
}
while (queue.Count > 0)
{
foreach (var edge in this.VisitedGraph.Edges)
{
if (!visetedEdges.Contains(edge) && (visetedVert.Contains(edge.Source) || visetedVert.Contains(edge.Target)))
{
queue.Enqueue(edge);
visetedEdges.Add(edge);
}
}
var e = queue.Dequeue();
this.OnExamineEdge(e);
if (!ds.AreInSameSet(e.Source, e.Target))
{
this.OnTreeEdge(e);
ds.Union(e.Source, e.Target);
if (visetedVert.Contains(e.Source))
{
visetedVert.Add(e.Target);
}
else
{
visetedVert.Add(e.Source);
}
}
}
}
protected override void InternalCompute()
{
var dic = new Dictionary <TVertex, HashSet <TEdge> >();
var cancelManager = this.Services.CancelManager;
var visetedVert = new HashSet <TVertex>();
var edges = new HashSet <TEdge>();
var queue = new BinaryQueue <TEdge, double>(this.edgeWeights);
var ds = new ForestDisjointSet <TVertex>(this.VisitedGraph.VertexCount);
foreach (var v in this.VisitedGraph.Vertices)
{
if (visetedVert.Count == 0)
{
visetedVert.Add(v);
}
ds.MakeSet(v);
dic.Add(v, new HashSet <TEdge>());
}
foreach (var e in this.VisitedGraph.Edges)
{
dic[e.Source].Add(e);
dic[e.Target].Add(e);
}
if (cancelManager.IsCancelling)
{
return;
}
var enumerator = visetedVert.GetEnumerator();
enumerator.MoveNext();
var lastVert = enumerator.Current;
foreach (var edge in dic[lastVert])
{
if (!edges.Contains(edge))
{
edges.Add(edge);
queue.Enqueue(edge);
}
}
if (cancelManager.IsCancelling)
{
return;
}
while (edges.Count > 0 && visetedVert.Count < VisitedGraph.VertexCount)
{
var mined = queue.Dequeue();
this.OnExamineEdge(mined);
if (!ds.AreInSameSet(mined.Source, mined.Target))
{
this.OnTreeEdge(mined);
ds.Union(mined.Source, mined.Target);
if (visetedVert.Contains(mined.Source))
{
lastVert = mined.Target;
visetedVert.Add(mined.Target);
}
else
{
lastVert = mined.Source;
visetedVert.Add(mined.Source);
}
foreach (var edge in dic[lastVert])
{
if (!edges.Contains(edge))
{
edges.Add(edge);
queue.Enqueue(edge);
}
}
}
}
}
public void ToPairsArray()
{
ToPairsArrayTest(1, 2, 3, 4);
ToPairsArrayTest(
new TestVertex("1"),
new TestVertex("2"),
new TestVertex("3"),
new TestVertex("4"));
ToPairsArrayTest(
new EquatableTestVertex("1"),
new EquatableTestVertex("2"),
new EquatableTestVertex("3"),
new EquatableTestVertex("4"));
#region Local function
void ToPairsArrayTest <TVertex>(
TVertex vertex1,
TVertex vertex2,
TVertex vertex3,
TVertex vertex4)
{
var distances = new Stack <double>(new[] { 123.0, 3.0, 2.0, 4.0, 5.0, 1.0 });
var queue = new BinaryQueue <TVertex, double>(_ => distances.Pop());
// Empty heap
CollectionAssert.IsEmpty(queue.ToPairsArray());
queue.Enqueue(vertex1);
queue.Enqueue(vertex2);
queue.Enqueue(vertex2);
queue.Enqueue(vertex3);
queue.Enqueue(vertex1);
// Array not sorted with distance
CollectionAssert.AreEquivalent(
new[]
{
new KeyValuePair <double, TVertex>(1.0, vertex1),
new KeyValuePair <double, TVertex>(5.0, vertex2),
new KeyValuePair <double, TVertex>(4.0, vertex2),
new KeyValuePair <double, TVertex>(2.0, vertex3),
new KeyValuePair <double, TVertex>(3.0, vertex1)
},
queue.ToPairsArray());
queue.Dequeue();
queue.Dequeue();
// Array not sorted with distance
CollectionAssert.AreEquivalent(
new[]
{
new KeyValuePair <double, TVertex>(3.0, vertex1),
new KeyValuePair <double, TVertex>(5.0, vertex2),
new KeyValuePair <double, TVertex>(4.0, vertex2)
},
queue.ToPairsArray());
queue.Dequeue();
queue.Dequeue();
queue.Dequeue();
CollectionAssert.IsEmpty(queue.ToPairsArray());
queue.Enqueue(vertex4);
CollectionAssert.AreEqual(
new[] { new KeyValuePair <double, TVertex>(123.0, vertex4) },
queue.ToPairsArray());
}
#endregion
}
