public void Simple()
{
IVertexListGraph g = GraphFactory.Simple();
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
strong.Compute();
checkStrong(strong);
}
public void RegularLattice()
{
IVertexListGraph g = GraphFactory.RegularLattice(10,10);
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
strong.Compute();
checkStrong(strong);
}
public void FileDependency()
{
IVertexListGraph g = GraphFactory.FileDependency();
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
strong.Compute();
checkStrong(strong);
}
public void Loop()
{
IVertexListGraph g = GraphFactory.Loop();
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
Assert.AreEqual(1, strong.Compute());
strong.Compute();
checkStrong(strong);
}
public void OneVertex()
{
AdjacencyGraph g =new AdjacencyGraph(true);
IVertex v1 = g.AddVertex();
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
Assert.AreEqual(1, strong.Compute());
checkStrong(strong);
}
public void EmptyGraph()
{
IVertexListGraph g = GraphFactory.EmptyParallelEdgesAllowed();
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
Assert.AreEqual(0, strong.Compute());
checkStrong(strong);
}
/// <summary>
/// Computes the strong components.
/// </summary>
/// <remarks>
/// <para>
/// Thread safe.
/// </para>
/// </remarks>
/// <param name="g">graph to explore</param>
/// <param name="components">component map where results are recorded</param>
/// <returns>number of strong components</returns>
public static int StrongComponents(
IVertexListGraph g,
VertexIntDictionary components)
{
StrongComponentsAlgorithm strong =
new StrongComponentsAlgorithm(g, components);
return(strong.Compute());
}
public void TwoVertexOnEdge()
{
AdjacencyGraph g =new AdjacencyGraph(true);
IVertex v1 = g.AddVertex();
IVertex v2 = g.AddVertex();
IEdge e = g.AddEdge(v1,v2);
StrongComponentsAlgorithm strong = new StrongComponentsAlgorithm(g);
Assert.AreEqual(2, strong.Compute());
checkStrong(strong);
}
internal void ComputeComponents()
{
if (components == null)
{
components = new VertexIntDictionary();
}
// components is a MAP containing vertex number as key & component_id as value. It maps every vertex in input graph to SCC vertex ID which contains it
StrongComponentsAlgorithm algo = new StrongComponentsAlgorithm(
VisitedGraph,
this.components
);
algo.Compute();
}
internal void ComputeComponents()
{
if( components == null )
components = new VertexIntDictionary();
// components is a MAP containing vertex number as key & component_id as value. It maps every vertex in input graph to SCC vertex ID which contains it
StrongComponentsAlgorithm algo = new StrongComponentsAlgorithm(
VisitedGraph,
this.components
);
algo.Compute();
}
private void checkStrong(StrongComponentsAlgorithm strong)
{
Assert.AreEqual(strong.VisitedGraph.VerticesCount, strong.Components.Count);
Assert.AreEqual(strong.VisitedGraph.VerticesCount, strong.DiscoverTimes.Count);
Assert.AreEqual(strong.VisitedGraph.VerticesCount, strong.Roots.Count);
foreach(IVertex v in strong.VisitedGraph.Vertices)
{
Assert.IsTrue(strong.Components.Contains(v));
Assert.IsTrue(strong.DiscoverTimes.Contains(v));
}
foreach(DictionaryEntry de in strong.Components)
{
Assert.IsNotNull(de.Key);
Assert.IsNotNull(de.Value);
Assert.LowerEqualThan((int)de.Value,strong.Count);
}
foreach(DictionaryEntry de in strong.DiscoverTimes)
{
Assert.IsNotNull(de.Key);
Assert.IsNotNull(de.Value);
}
}
/// <summary>
/// Computes the strong components.
/// </summary>
/// <remarks>
/// <para>
/// Thread safe.
/// </para>
/// </remarks>
/// <param name="g">graph to explore</param>
/// <param name="components">component map where results are recorded</param>
/// <returns>number of strong components</returns>
public static int StrongComponents(
IVertexListGraph g,
VertexIntDictionary components)
{
StrongComponentsAlgorithm strong =
new StrongComponentsAlgorithm(g,components);
return strong.Compute();
}
public CondensedTypeGraph(bool allowParallel)
: base(new CondensedVertexProvider(), new EdgeProvider(), allowParallel)
{
_sccCountalg = new StrongComponentsAlgorithm(this);
}
public CondensedTypeGraph()
: base(new CondensedVertexProvider(), new EdgeProvider(), false)
{
_sccCountalg = new StrongComponentsAlgorithm(this);
}
public TypeDependencyGraph TypeDepAnalysis(List<TypeReference> typesToExamine)
{
TypeDependencyGraph tdg = new TypeDependencyGraph();
StrongComponentsAlgorithm scgo = new StrongComponentsAlgorithm(this);
scgo.Compute();
Dictionary<int, List<IVertex>> sccMap = new Dictionary<int, List<IVertex>>();
foreach (System.Collections.DictionaryEntry de in scgo.Components)
{
IVertex v = (IVertex)de.Key;
int scc_id = (int)de.Value;
if (!sccMap.ContainsKey(scc_id))
{
sccMap[scc_id] = new List<IVertex>();
}
sccMap[scc_id].Add(v);
}
Stack<List<TypeVertex>> PendingEdges = new Stack<List<TypeVertex>>();
List<TypeVertex> VertexToRemove = new List<TypeVertex>();
VertexEventHandler discV = delegate(Object s, VertexEventArgs e)
{
PendingEdges.Push(new List<TypeVertex>());
TypeVertex tv = (TypeVertex)e.Vertex;
if (scgo.Components.Contains(tv) && sccMap[scgo.Components[tv]].Count > 1)
{
tv.SCCNum = scgo.Components[tv];
tdg.AddVertex(tv);
}
else if (typesToExamine.Contains(tv.TypeRef))
{
tdg.AddVertex(tv);
}
else
{
VertexToRemove.Add(tv);
}
};
VertexEventHandler finishV = delegate(Object s, VertexEventArgs e)
{
TypeVertex tv = (TypeVertex)e.Vertex;
List<TypeVertex> pes = PendingEdges.Pop();
if (tdg.ContainsVertex(tv))
{
foreach (TypeVertex target in pes)
{
if (tdg.ContainsVertex(target) && !tdg.ContainsEdge(tv, target))
tdg.AddEdge(tv, target);
}
}
};
EdgeEventHandler treeedge = delegate(Object o, EdgeEventArgs e)
{
PendingEdges.Peek().Add((TypeVertex)e.Edge.Target);
};
DepthFirstSearchAlgorithm dfs = new DepthFirstSearchAlgorithm(this);
dfs.DiscoverVertex += discV;
dfs.FinishVertex += finishV;
dfs.TreeEdge += treeedge;
dfs.Compute();
foreach (TypeVertex v in VertexToRemove)
{
this.RemoveVertex(v);
}
return tdg;
}
