private static IEnumerable <Vertex <T> > SortTopologically <T> (IEnumerable <Vertex <T> > graph, bool throwIfOrderIsUndefined = false)
{
var graphAsList = graph.ToList();
var result = new List <Vertex <T> >(graphAsList.Count);
while (graphAsList.Any())
{
var independents = graphAsList
.Where(x => !result.Contains(x) && !graphAsList.Any(y => y.Dependencies.Contains(x)))
.ToList();
if (throwIfOrderIsUndefined && independents.Count > 1)
{
throw new UndefinedOrderException(independents.Select(x => x.Value));
}
var independent = independents.FirstOrDefault();
if (independent == null)
{
var scc = new StronglyConnectedComponentFinder <T>();
var enumerable = scc.DetectCycle(graphAsList).Select(x => x.Select(y => y.Value));
throw new CircularDependencyException(enumerable.Cast <IEnumerable>());
}
graphAsList.Remove(independent);
result.Add(independent);
}
return(result);
}
// B→D
// D→C
// A→B→C
// A→B→D→C
static void Main()
{
var feeder = new LineFeeder("data.txt");
var factory = new VertexFactory<string>();
foreach (var line in feeder)
{
var splittedLine = line.Split(',');
factory.Add(splittedLine[0],splittedLine[1]);
}
//var path = @"C:\Users\Eduard\Source\Repos\CycleDetection\data.txt";
var graph = new List<Vertex<string>>();
graph.AddRange(factory.VertexDictionary.Select(vde=>vde.Value));
var detector = new StronglyConnectedComponentFinder<string>();
var components = detector.DetectCycle(graph);
int index = 0;
foreach (var component in components)
{
Console.Write($"component {index++} : ");
foreach (var vertex in component)
{
Console.Write(vertex.Value + " ");
}
Console.WriteLine();
}
Console.ReadLine();
}
public void TwoIsolated3Cycles()
{
var graph = new List <Vertex <int> >();
var vA = new Vertex <int>(1);
var vB = new Vertex <int>(2);
var vC = new Vertex <int>(3);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vC);
vC.Dependencies.Add(vA);
graph.Add(vA);
graph.Add(vB);
graph.Add(vC);
var vD = new Vertex <int>(4);
var vE = new Vertex <int>(5);
var vF = new Vertex <int>(6);
vD.Dependencies.Add(vE);
vE.Dependencies.Add(vF);
vF.Dependencies.Add(vD);
graph.Add(vD);
graph.Add(vE);
graph.Add(vF);
var detector = new StronglyConnectedComponentFinder <int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(2, components.Count);
Assert.AreEqual(0, components.IndependentComponents().Count());
Assert.AreEqual(2, components.Cycles().Count());
Assert.IsTrue(components.All(c => c.Count == 3));
}
// B→D
// D→C
// A→B→C
// A→B→D→C
static void Main()
{
var feeder = new LineFeeder("data.txt");
var factory = new VertexFactory <string>();
foreach (var line in feeder)
{
var splittedLine = line.Split(',');
factory.Add(splittedLine[0], splittedLine[1]);
}
//var path = @"C:\Users\Eduard\Source\Repos\CycleDetection\data.txt";
var graph = new List <Vertex <string> >();
graph.AddRange(factory.VertexDictionary.Select(vde => vde.Value));
var detector = new StronglyConnectedComponentFinder <string>();
var components = detector.DetectCycle(graph);
int index = 0;
foreach (var component in components)
{
Console.Write($"component {index++} : ");
foreach (var vertex in component)
{
Console.Write(vertex.Value + " ");
}
Console.WriteLine();
}
Console.ReadLine();
}
public void Cycle3WithStub()
{
var graph = new List <Vertex <int> >();
var vA = new Vertex <int>(1);
var vB = new Vertex <int>(2);
var vC = new Vertex <int>(3);
var vD = new Vertex <int>(4);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vC);
vC.Dependencies.Add(vA);
vC.Dependencies.Add(vD);
graph.Add(vA);
graph.Add(vB);
graph.Add(vC);
graph.Add(vD);
var detector = new StronglyConnectedComponentFinder <int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(2, components.Count);
Assert.AreEqual(1, components.IndependentComponents().Count());
Assert.AreEqual(1, components.Cycles().Count());
Assert.AreEqual(1, components.Count(c => c.Count == 3));
Assert.AreEqual(1, components.Count(c => c.Count == 1));
Assert.IsTrue(components.Single(c => c.Count == 1).Single() == vD);
}
public void LinearTwoLines()
{
var graph = new List <Vertex <string> >();
var vA = new Vertex <string>("A");
var vB = new Vertex <string>("B");
var vC = new Vertex <string>("C");
var vD = new Vertex <string>("D");
vB.Dependencies.Add(vD);
vD.Dependencies.Add(vC);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vC);
graph.Add(vA);
graph.Add(vB);
graph.Add(vC);
var detector = new StronglyConnectedComponentFinder <string>();
StronglyConnectedComponentList <string> components = detector.DetectCycle(graph);
Assert.AreEqual(4, components.Count);
Assert.AreEqual(4, components.IndependentComponents().Count());
Assert.AreEqual(0, components.Cycles().Count());
Assert.AreEqual("C", components.First().First().Value);
Assert.AreEqual("D", components.Skip(1).First().First().Value);
Assert.AreEqual("B", components.Skip(2).First().First().Value);
Assert.AreEqual("A", components.Skip(3).First().First().Value);
}
public void EmptyGraph()
{
var detector = new StronglyConnectedComponentFinder <int>();
var cycles = detector.DetectCycle(new List <Vertex <int> >());
Assert.AreEqual(0, cycles.Count);
}
public void SingleVertex()
{
var graph = new List <Vertex <int> >();
graph.Add(new Vertex <int>(1));
var detector = new StronglyConnectedComponentFinder <int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(1, components.Count);
Assert.AreEqual(1, components.IndependentComponents().Count());
Assert.AreEqual(0, components.Cycles().Count());
}
public void Cycle2()
{
var graph = new List<Vertex<int>>();
var vA = new Vertex<int>(1);
var vB = new Vertex<int>(2);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vA);
graph.Add(vA);
graph.Add(vB);
var detector = new StronglyConnectedComponentFinder<int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(1, components.Count);
Assert.AreEqual(0, components.IndependentComponents().Count());
Assert.AreEqual(1, components.Cycles().Count());
Assert.AreEqual(2, components.First().Count);
}
public void Linear2()
{
var graph = new List <Vertex <int> >();
var vA = new Vertex <int>(1);
var vB = new Vertex <int>(2);
vA.Dependencies.Add(vB);
graph.Add(vA);
graph.Add(vB);
var detector = new StronglyConnectedComponentFinder <int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(2, components.Count);
Assert.AreEqual(2, components.IndependentComponents().Count());
Assert.AreEqual(0, components.Cycles().Count());
}
public void Cycle3()
{
var graph = new List <Vertex <int> >();
var vA = new Vertex <int>(1);
var vB = new Vertex <int>(2);
var vC = new Vertex <int>(3);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vC);
vC.Dependencies.Add(vA);
graph.Add(vA);
graph.Add(vB);
graph.Add(vC);
var detector = new StronglyConnectedComponentFinder <int>();
var components = detector.DetectCycle(graph);
Assert.Equal(1, components.Count);
Assert.Equal(0, components.IndependentComponents().Count());
Assert.Equal(1, components.Cycles().Count());
Assert.Equal(3, components.Single().Count);
}
public void Cycle3WithStub()
{
var graph = new List<Vertex<int>>();
var vA = new Vertex<int>(1);
var vB = new Vertex<int>(2);
var vC = new Vertex<int>(3);
var vD = new Vertex<int>(4);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vC);
vC.Dependencies.Add(vA);
vC.Dependencies.Add(vD);
graph.Add(vA);
graph.Add(vB);
graph.Add(vC);
graph.Add(vD);
var detector = new StronglyConnectedComponentFinder<int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(2, components.Count);
Assert.AreEqual(1, components.IndependentComponents().Count());
Assert.AreEqual(1, components.Cycles().Count());
Assert.AreEqual(1, components.Count(c => c.Count == 3));
Assert.AreEqual(1, components.Count(c => c.Count == 1));
Assert.IsTrue(components.Single(c => c.Count == 1).Single() == vD);
}
public void CycleWithDuplicates()
{
var testValues = new
{
A = TestValue.Create("a ", "e"),
B = TestValue.Create(" B", " c "),
A2 = TestValue.Create("A ", "C"),
C = TestValue.Create("C", "A", "D"),
D = TestValue.Create("d"),
E = TestValue.Create("E"),
};
var graph = new[]
{
testValues.A,
testValues.B,
testValues.C,
testValues.D,
testValues.E,
testValues.A2,
};
var ignoreCase = DerivedComparer.Create(StringComparer.OrdinalIgnoreCase, (string t) => t.Trim());
var equalityComparer = TestValue.CreateComparer(ignoreCase);
var vertexValueComparer = new VertexValueComparer <TestValue <string> >(equalityComparer);
var byValue = graph.ToLookup(t => t.Value, ignoreCase);
var vertices = VertexBuilder.BuildVertices(graph, s => s.DependsOn.SelectMany(d => byValue[d]), equalityComparer).ToList();
Assert.AreEqual(6, vertices.Count, "every source element should yield a vertex");
Assert.AreEqual(5, vertices.Distinct().Count(), "'A' and 'a ' should yield the exact same vertex");
var finder = new StronglyConnectedComponentFinder <TestValue <string> >();
var simpleComponents = finder.DetectCycle(vertices, vertexValueComparer);
var components = simpleComponents.ExtractCycles(equalityComparer);
Assert.AreEqual(4, components.Count, "It should be only 4 components");
Assert.AreEqual(3, components.IndependentComponents().Count(), "B, D & E are acylic");
Assert.AreEqual(1, components.Cycles().Count(), "Only 1 cycle should be found");
Assert.AreEqual
(2,
components.Take(2)
.SelectMany(t => t)
.Intersect(new[] { testValues.D, testValues.E })
.Count(),
"D & E should be the first components.");
var component3 = components.Skip(2).First();
var component4 = components.Skip(3).First();
Assert.AreEqual(component3.Count, 2, "3rd component should be a cycle of 2");
Assert.AreEqual
(component3.Intersect(new[] { testValues.A, testValues.C }).Count(),
2,
"3rd component should be a cycle of A & C");
Assert.AreEqual(testValues.B, component4.Single()); // 4th one has to be B (uses A)
}
public void TwoIsolated3Cycles()
{
var graph = new List<Vertex<int>>();
var vA = new Vertex<int>(1);
var vB = new Vertex<int>(2);
var vC = new Vertex<int>(3);
vA.Dependencies.Add(vB);
vB.Dependencies.Add(vC);
vC.Dependencies.Add(vA);
graph.Add(vA);
graph.Add(vB);
graph.Add(vC);
var vD = new Vertex<int>(4);
var vE = new Vertex<int>(5);
var vF = new Vertex<int>(6);
vD.Dependencies.Add(vE);
vE.Dependencies.Add(vF);
vF.Dependencies.Add(vD);
graph.Add(vD);
graph.Add(vE);
graph.Add(vF);
var detector = new StronglyConnectedComponentFinder<int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(2, components.Count);
Assert.AreEqual(0, components.IndependentComponents().Count());
Assert.AreEqual(2, components.Cycles().Count());
Assert.IsTrue(components.All(c => c.Count == 3));
}
public void EmptyGraph()
{
var graph = new List<Vertex<int>>();
var detector = new StronglyConnectedComponentFinder<int>();
var cycles = detector.DetectCycle(graph);
Assert.AreEqual(0, cycles.Count);
}
public void CycleWithDuplicates()
{
var testValues = new
{
A = TestValue.Create("a ", "e"),
B = TestValue.Create(" B", " c "),
A2 = TestValue.Create("A ", "C"),
C = TestValue.Create("C", "A", "D"),
D = TestValue.Create("d"),
E = TestValue.Create("E"),
};
var graph = new[]
{
testValues.A,
testValues.B,
testValues.C,
testValues.D,
testValues.E,
testValues.A2,
};
var ignoreCase = DerivedComparer.Create(StringComparer.OrdinalIgnoreCase, (string t) => t.Trim());
var equalityComparer = TestValue.CreateComparer(ignoreCase);
var vertexValueComparer = new VertexValueComparer<TestValue<string>>(equalityComparer);
var byValue = graph.ToLookup(t => t.Value, ignoreCase);
var vertices = VertexBuilder.BuildVertices(graph, s => s.DependsOn.SelectMany(d => byValue[d]), equalityComparer).ToList();
Assert.AreEqual(6, vertices.Count, "every source element should yield a vertex");
Assert.AreEqual(5, vertices.Distinct().Count(), "'A' and 'a ' should yield the exact same vertex");
var finder = new StronglyConnectedComponentFinder<TestValue<string>>();
var simpleComponents = finder.DetectCycle(vertices, vertexValueComparer);
var components = simpleComponents.ExtractCycles(equalityComparer);
Assert.AreEqual(4, components.Count, "It should be only 4 components");
Assert.AreEqual(3, components.IndependentComponents().Count(), "B, D & E are acylic");
Assert.AreEqual(1, components.Cycles().Count(), "Only 1 cycle should be found");
Assert.AreEqual
(2,
components.Take(2)
.SelectMany(t => t)
.Intersect(new[] { testValues.D, testValues.E })
.Count(),
"D & E should be the first components.");
var component3 = components.Skip(2).First();
var component4 = components.Skip(3).First();
Assert.AreEqual(component3.Count, 2, "3rd component should be a cycle of 2");
Assert.AreEqual
(component3.Intersect(new[] { testValues.A, testValues.C }).Count(),
2,
"3rd component should be a cycle of A & C");
Assert.AreEqual(testValues.B, component4.Single()); // 4th one has to be B (uses A)
}
public void SingleVertex()
{
var graph = new List<Vertex<int>>();
graph.Add(new Vertex<int>(1));
var detector = new StronglyConnectedComponentFinder<int>();
var components = detector.DetectCycle(graph);
Assert.AreEqual(1, components.Count);
Assert.AreEqual(1, components.IndependentComponents().Count());
Assert.AreEqual(0, components.Cycles().Count());
}