public bool Equals(Edge <T> other)
{
return(other != null &&
StartVertex.Equals(other.StartVertex) &&
EndVertex.Equals(other.EndVertex) &&
Weight.Equals(other.Weight));
}
public void RunWithBlockingConditionOnSecondEdge()
{
var condition = new Mock <IScheduleCondition>();
{
condition.Setup(c => c.CanTraverse(It.IsAny <CancellationToken>()))
.Returns(false);
}
var conditionStorage = ScheduleConditionStorage.CreateInstanceWithoutTimeline();
var conditionInfo = conditionStorage.Add(condition.Object, "a", "b");
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var middle1 = new InsertVertex(3);
graph.AddVertex(middle1);
var middle2 = new InsertVertex(4);
graph.AddVertex(middle2);
graph.AddEdge(new ScheduleEdge(start, middle1));
graph.AddEdge(new ScheduleEdge(start, middle2, conditionInfo.Id));
graph.AddEdge(new ScheduleEdge(middle1, end));
graph.AddEdge(new ScheduleEdge(middle2, end));
schedule = new Schedule(graph, start, end);
}
using (var info = new ScheduleExecutionInfo(new CurrentThreadTaskScheduler()))
{
using (var executor = new ScheduleExecutor(
new List <IProcesExecutableScheduleVertices>
{
new StartVertexProcessor(),
new EndVertexProcessor(),
new InsertVertexProcessor(),
},
conditionStorage,
schedule,
new ScheduleId(),
info))
{
var executionOrder = new List <int>();
executor.OnVertexProcess += (s, e) => executionOrder.Add(e.Vertex);
executor.Start();
Assert.That(executionOrder, Is.EquivalentTo(new[] { 1, 3, 2 }));
}
}
}
public void RunWithNonPassableEdgeSet()
{
var condition = new Mock <IScheduleCondition>();
{
condition.Setup(c => c.CanTraverse(It.IsAny <CancellationToken>()))
.Returns(false);
}
var conditionStorage = ScheduleConditionStorage.CreateInstanceWithoutTimeline();
var conditionInfo = conditionStorage.Add(condition.Object, "a", "b");
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var middle1 = new InsertVertex(3);
graph.AddVertex(middle1);
var middle2 = new InsertVertex(4);
graph.AddVertex(middle2);
graph.AddEdge(new ScheduleEdge(start, middle1, conditionInfo.Id));
graph.AddEdge(new ScheduleEdge(start, middle2, conditionInfo.Id));
graph.AddEdge(new ScheduleEdge(middle1, end));
graph.AddEdge(new ScheduleEdge(middle2, end));
schedule = new Schedule(graph, start, end);
}
using (var info = new ScheduleExecutionInfo(new CurrentThreadTaskScheduler()))
{
using (var executor = new ScheduleExecutor(
new List <IProcesExecutableScheduleVertices>
{
new StartVertexProcessor(),
new EndVertexProcessor(),
new InsertVertexProcessor(),
},
conditionStorage,
schedule,
new ScheduleId(),
info))
{
var state = ScheduleExecutionState.None;
executor.OnFinish += (s, e) => { state = e.State; };
executor.Start();
Assert.AreEqual(ScheduleExecutionState.NoTraversableEdgeFound, state);
}
}
}
public void SubScheduleWithLinkBackToParent()
{
var id = new ScheduleId();
var subScheduleId = new ScheduleId();
ISchedule subSchedule;
{
var subGraph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
var end = new EndVertex(2);
var vertex1 = new SubScheduleVertex(3, id);
subGraph.AddVertex(start);
subGraph.AddVertex(end);
subGraph.AddVertex(vertex1);
subGraph.AddEdge(new ScheduleEdge(start, vertex1));
subGraph.AddEdge(new ScheduleEdge(vertex1, end));
subSchedule = new Schedule(subGraph, start, end);
}
IScheduleVertex errorVertex;
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
var end = new EndVertex(2);
var vertex1 = new SubScheduleVertex(3, subScheduleId);
graph.AddVertex(start);
graph.AddVertex(end);
graph.AddVertex(vertex1);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, end));
schedule = new Schedule(graph, start, end);
errorVertex = vertex1;
}
var knownSchedules = new Mock <IStoreSchedules>();
{
knownSchedules.Setup(s => s.Contains(It.IsAny <ScheduleId>()))
.Returns <ScheduleId>(subScheduleId.Equals);
knownSchedules.Setup(s => s.Schedule(It.IsAny <ScheduleId>()))
.Returns <ScheduleId>(scheduleId => subSchedule);
}
var failures = new List <Tuple <ScheduleIntegrityFailureType, IScheduleVertex> >();
var verifier = new ScheduleVerifier(knownSchedules.Object);
var result = verifier.IsValid(
id,
schedule,
(f, v) => failures.Add(new Tuple <ScheduleIntegrityFailureType, IScheduleVertex>(f, v)));
Assert.IsFalse(result);
Assert.AreEqual(1, failures.Count);
Assert.AreEqual(ScheduleIntegrityFailureType.SubScheduleLinksBackToParentSchedule, failures[0].Item1);
Assert.AreSame(errorVertex, failures[0].Item2);
}
public bool ConnectsTo(Vertex <TV, TE, TF> vertex)
{
if (vertex == null)
{
return(false);
}
return(EndVertex.Equals(vertex) || StartVertex.Equals(vertex));
}
public void Create()
{
IScheduleVertex source = new StartVertex(10);
IScheduleVertex target = new EndVertex(11);
var condition = new ScheduleElementId();
var edge = new ScheduleEdge(source, target, condition);
Assert.AreSame(source, edge.Source);
Assert.AreSame(target, edge.Target);
Assert.AreSame(condition, edge.TraversingCondition);
}
public void CycleWithNoEdgesFromStart()
{
var knownSchedules = new Mock <IStoreSchedules>();
var verifier = new ScheduleVerifier(knownSchedules.Object);
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
var vertex3 = new InsertVertex(5);
graph.AddVertex(vertex3);
graph.AddEdge(new ScheduleEdge(start, end));
graph.AddEdge(new ScheduleEdge(vertex1, end));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, vertex3));
graph.AddEdge(new ScheduleEdge(vertex3, vertex1));
var schedule = new Schedule(graph, start, end);
var id = new ScheduleId();
var failures = new List <Tuple <ScheduleIntegrityFailureType, IScheduleVertex> >();
var result = verifier.IsValid(
id,
schedule,
(f, v) => failures.Add(new Tuple <ScheduleIntegrityFailureType, IScheduleVertex>(f, v)));
Assert.IsFalse(result);
Assert.AreEqual(3, failures.Count);
Assert.AreEqual(ScheduleIntegrityFailureType.ScheduleVertexIsNotReachableFromStart, failures[0].Item1);
Assert.AreSame(vertex1, failures[0].Item2);
Assert.AreEqual(ScheduleIntegrityFailureType.ScheduleVertexIsNotReachableFromStart, failures[1].Item1);
Assert.AreSame(vertex2, failures[1].Item2);
Assert.AreEqual(ScheduleIntegrityFailureType.ScheduleVertexIsNotReachableFromStart, failures[2].Item1);
Assert.AreSame(vertex3, failures[2].Item2);
}
private static Schedule CreateScheduleGraphWithOuterAndInnerLoop(
ScheduleConditionInformation outerLoopConditionInfo,
ScheduleConditionInformation innerLoopConditionInfo,
ScheduleActionInformation outerLoopInfo,
ScheduleActionInformation innerLoopInfo)
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
var vertex3 = new ExecutingActionVertex(5, outerLoopInfo.Id);
graph.AddVertex(vertex3);
var vertex4 = new InsertVertex(6);
graph.AddVertex(vertex4);
var vertex5 = new ExecutingActionVertex(7, innerLoopInfo.Id);
graph.AddVertex(vertex5);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end, outerLoopConditionInfo.Id));
graph.AddEdge(new ScheduleEdge(vertex2, vertex3));
graph.AddEdge(new ScheduleEdge(vertex3, vertex1, innerLoopConditionInfo.Id));
graph.AddEdge(new ScheduleEdge(vertex3, vertex4));
graph.AddEdge(new ScheduleEdge(vertex4, vertex5));
graph.AddEdge(new ScheduleEdge(vertex5, vertex3));
return(new Schedule(graph, start, end));
}
public void Register()
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
graph.AddEdge(new ScheduleEdge(start, end));
var schedule = new Schedule(graph, start, end);
var scheduleBuilder = new Mock <IBuildFixedSchedules>();
{
scheduleBuilder.Setup(s => s.Build())
.Returns(schedule);
scheduleBuilder.Setup(s => s.AddExecutingAction(It.IsAny <ScheduleElementId>()))
.Returns <ScheduleElementId>(s => new ExecutingActionVertex(0, s));
}
var actionId = new ScheduleActionRegistrationId(typeof(string), 0, "a");
var conditionId = new ScheduleConditionRegistrationId(typeof(string), 0, "a");
var owner = new Mock <IOwnScheduleDefinitions>();
{
owner.Setup(
o => o.StoreSchedule(
It.IsAny <ISchedule>(),
It.IsAny <Dictionary <ScheduleActionRegistrationId, ScheduleElementId> >(),
It.IsAny <Dictionary <ScheduleConditionRegistrationId, ScheduleElementId> >()))
.Callback <ISchedule, Dictionary <ScheduleActionRegistrationId, ScheduleElementId>, Dictionary <ScheduleConditionRegistrationId, ScheduleElementId> >(
(s, a, c) =>
{
Assert.That(a.Keys, Is.EquivalentTo(new List <ScheduleActionRegistrationId> {
actionId
}));
Assert.That(c.Keys, Is.EquivalentTo(new List <ScheduleConditionRegistrationId> {
conditionId
}));
});
}
var builder = new ScheduleDefinitionBuilder(owner.Object, scheduleBuilder.Object);
var vertex = builder.AddExecutingAction(actionId);
builder.LinkToEnd(vertex, conditionId);
builder.Register();
}
private static ISchedule BuildSchedule()
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
graph.AddEdge(new ScheduleEdge(start, end));
return(new Schedule(graph, start, end));
}
public void TraverseScheduleWithLoop()
{
// Making a schedule that looks like:
// start -> node1 --> node2 -> end
// ^ |
// |-- node3 <-|
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
var vertex3 = new InsertVertex(5);
graph.AddVertex(vertex3);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end));
graph.AddEdge(new ScheduleEdge(vertex2, vertex3));
graph.AddEdge(new ScheduleEdge(vertex3, vertex1));
schedule = new Schedule(graph, start, end);
}
var vertices = new List <int>();
schedule.TraverseAllScheduleVertices(
schedule.Start,
(vertex, edges) =>
{
vertices.Add(vertex.Index);
return(true);
});
Assert.That(vertices, Is.EquivalentTo(new[] { 1, 3, 4, 2, 5 }));
}
//public Line AsLine()
//{
// return Line.ByStartPointEndPoint(StartVertex.AsPoint(), EndVertex.AsPoint());
//}
#region override methods
//TODO: Improve overriding equality methods as per http://www.loganfranken.com/blog/687/overriding-equals-in-c-part-1/
/// <summary>
/// Override of Equal Method
/// </summary>
/// <param name="obj"></param>
/// <returns></returns>
public override bool Equals(object obj)
{
if (obj == null || GetType() != obj.GetType())
{
return(false);
}
gEdge e = (gEdge)obj;
if (StartVertex.Equals(e.StartVertex) && EndVertex.Equals(e.EndVertex))
{
return(true);
}
if (StartVertex.Equals(e.EndVertex) && EndVertex.Equals(e.StartVertex))
{
return(true);
}
return(false);
}
public void EndVertexWithOutboundEdges()
{
var knownSchedules = new Mock <IStoreSchedules>();
var verifier = new ScheduleVerifier(knownSchedules.Object);
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end));
graph.AddEdge(new ScheduleEdge(end, vertex1));
schedule = new Schedule(graph, start, end);
}
var id = new ScheduleId();
var failures = new List <Tuple <ScheduleIntegrityFailureType, IScheduleVertex> >();
var result = verifier.IsValid(
id,
schedule,
(f, v) => failures.Add(new Tuple <ScheduleIntegrityFailureType, IScheduleVertex>(f, v)));
Assert.IsFalse(result);
Assert.AreEqual(1, failures.Count);
Assert.AreEqual(ScheduleIntegrityFailureType.ScheduleIsMissingEnd, failures[0].Item1);
Assert.AreSame(schedule.End, failures[0].Item2);
}
public void Create()
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
graph.AddEdge(new ScheduleEdge(start, end));
var schedule = new Schedule(graph, start, end);
Assert.AreSame(start, schedule.Start);
Assert.AreSame(end, schedule.End);
Assert.That(schedule.Vertices, Is.EquivalentTo(new IScheduleVertex[] { start, end }));
Assert.AreEqual(1, schedule.NumberOfOutboundConnections(start));
Assert.AreEqual(1, schedule.NumberOfInboundConnections(end));
}
public void VertexWithMultipleEdgesInOneDirection()
{
var knownSchedules = new Mock <IStoreSchedules>();
var verifier = new ScheduleVerifier(knownSchedules.Object);
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, end));
graph.AddEdge(new ScheduleEdge(vertex1, end));
var schedule = new Schedule(graph, start, end);
var id = new ScheduleId();
var failures = new List <Tuple <ScheduleIntegrityFailureType, IScheduleVertex> >();
var result = verifier.IsValid(
id,
schedule,
(f, v) => failures.Add(new Tuple <ScheduleIntegrityFailureType, IScheduleVertex>(f, v)));
Assert.IsFalse(result);
Assert.AreEqual(1, failures.Count);
Assert.AreEqual(ScheduleIntegrityFailureType.VertexLinksToOtherVertexInMultipleWays, failures[0].Item1);
Assert.AreSame(vertex1, failures[0].Item2);
}
public void TraverseScheduleCompletely()
{
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end));
schedule = new Schedule(graph, start, end);
}
var vertices = new List <int>();
schedule.TraverseAllScheduleVertices(
schedule.Start,
(vertex, edges) =>
{
vertices.Add(vertex.Index);
return(true);
});
Assert.That(vertices, Is.EquivalentTo(new[] { 1, 3, 4, 2 }));
}
public double DistanceTo(gEdge edge)
{
// http://mathworld.wolfram.com/Line-LineDistance.html
if (this.IsCoplanarTo(edge))
{
var distances = new double[4] {
StartVertex.DistanceTo(edge),
EndVertex.DistanceTo(edge),
edge.StartVertex.DistanceTo(this),
edge.EndVertex.DistanceTo(this)
};
return(distances.Min());
}
else
{
var a = this.Direction;
var b = edge.Direction;
var c = gVector.ByTwoVertices(this.StartVertex, edge.StartVertex);
gVector cross = a.Cross(b);
double numerator = c.Dot(cross);
double denominator = cross.Length;
return(Math.Abs(numerator) / Math.Abs(denominator));
}
}
public void RunWithLoop()
{
bool passThrough = false;
var condition = new Mock <IScheduleCondition>();
{
condition.Setup(c => c.CanTraverse(It.IsAny <CancellationToken>()))
.Returns(() => passThrough);
}
var conditionStorage = ScheduleConditionStorage.CreateInstanceWithoutTimeline();
var conditionInfo = conditionStorage.Add(condition.Object, "a", "b");
var action = new Mock <IScheduleAction>();
{
action.Setup(a => a.Execute(It.IsAny <CancellationToken>()))
.Callback(() => passThrough = true);
}
var collection = ScheduleActionStorage.CreateInstanceWithoutTimeline();
var info = collection.Add(
action.Object,
"a",
"b");
// Making a schedule that looks like:
// start -> node1 --> node2 -> end
// ^ |
// |-- node3 <-|
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
var vertex3 = new ExecutingActionVertex(5, info.Id);
graph.AddVertex(vertex3);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end, conditionInfo.Id));
graph.AddEdge(new ScheduleEdge(vertex2, vertex3));
graph.AddEdge(new ScheduleEdge(vertex3, vertex1));
schedule = new Schedule(graph, start, end);
}
using (var executionInfo = new ScheduleExecutionInfo(new CurrentThreadTaskScheduler()))
{
using (var executor = new ScheduleExecutor(
new List <IProcesExecutableScheduleVertices>
{
new StartVertexProcessor(),
new EndVertexProcessor(),
new InsertVertexProcessor(),
new ActionVertexProcessor(collection),
},
conditionStorage,
schedule,
new ScheduleId(),
executionInfo))
{
var executionOrder = new List <int>();
executor.OnVertexProcess += (s, e) => executionOrder.Add(e.Vertex);
executor.Start();
Assert.That(executionOrder, Is.EquivalentTo(new[] { 1, 3, 4, 5, 3, 4, 2 }));
}
}
}
/// <summary>
/// Creates a String Representation of this HalfEdge.
/// </summary>
/// <returns>String representation of this HalfEdge.</returns>
public override string ToString()
{
return($"From: {StartVertex.ToString()} " +
$"To: {EndVertex.ToString()}");
}
public void RoundtripSerialize()
{
// Making a schedule that looks like:
// start -> node1 --> node2 -> end
// ^ |
// |-- node3 <-|
// ^ |
// node5--| |-> node4
// ^ |
// |--------------|
Schedule schedule;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new InsertVertex(3);
graph.AddVertex(vertex1);
var vertex2 = new InsertVertex(4);
graph.AddVertex(vertex2);
var vertex3 = new InsertVertex(5);
graph.AddVertex(vertex3);
var vertex4 = new InsertVertex(6);
graph.AddVertex(vertex4);
var vertex5 = new InsertVertex(7);
graph.AddVertex(vertex5);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end));
graph.AddEdge(new ScheduleEdge(vertex2, vertex3));
graph.AddEdge(new ScheduleEdge(vertex3, vertex1));
graph.AddEdge(new ScheduleEdge(vertex3, vertex4));
graph.AddEdge(new ScheduleEdge(vertex4, vertex5));
graph.AddEdge(new ScheduleEdge(vertex5, vertex3));
schedule = new Schedule(graph, start, end);
}
var otherSchedule = AssertExtensions.RoundTripSerialize(schedule);
var vertices = new List <int>();
otherSchedule.TraverseAllScheduleVertices(
otherSchedule.Start,
(vertex, edges) =>
{
vertices.Add(vertex.Index);
return(true);
});
Assert.That(vertices, Is.EquivalentTo(new[] { 1, 3, 4, 2, 5, 6, 7 }));
}
public override int GetHashCode()
{
return(31 + (IsPrimaryEdge ? 17 : -29)
+ 11 * EndVertex.GetHashCode());
}
/// <summary>
/// gEdge constructor by line
/// </summary>
/// <param name="line">line</param>
/// <returns name="edge">edge</returns>
//public static gEdge ByLine(Line line)
//{
// gVertex start = gVertex.ByCoordinates(line.StartPoint.X, line.StartPoint.Y, line.StartPoint.Z);
// gVertex end = gVertex.ByCoordinates(line.EndPoint.X, line.EndPoint.Y, line.EndPoint.Z);
// return new gEdge(start, end);
//}
#endregion
/// <summary>
/// Method to check if vertex belongs to edge
/// </summary>
/// <param name="vertex"></param>
/// <returns></returns>
public bool Contains(gVertex vertex)
{
return(StartVertex.Equals(vertex) || EndVertex.Equals(vertex));
}
public bool Connects(Vertex <TV, TE, TF> start, Vertex <TV, TE, TF> end)
{
return(EndVertex.Equals(end) && StartVertex.Equals(start));
}
public override int GetHashCode() => StartVertex.GetHashCode() ^ EndVertex.GetHashCode() ^ Weight;
private void OnEndVertex(TVertex vertex)
{
Debug.Assert(vertex != null);
EndVertex?.Invoke(vertex);
}
private static Schedule BuildSchedule(
ScheduleElementId action1,
ScheduleElementId action2,
ScheduleId scheduleId,
ScheduleElementId exitCondition,
ScheduleElementId passThroughCondition)
{
var variable = new Mock <IScheduleVariable>();
// Making a schedule that looks like:
// start --> node1 -----------------------> node2 -> end
// ^ |
// |-- node5 <-- node4 <-- node3<-|
// ^ |
// node7--| |-> node6
// ^ |
// |--------------|
Schedule schedule = null;
{
var graph = new BidirectionalGraph <IScheduleVertex, ScheduleEdge>();
var start = new StartVertex(1);
graph.AddVertex(start);
var end = new EndVertex(2);
graph.AddVertex(end);
var vertex1 = new ExecutingActionVertex(3, action1);
graph.AddVertex(vertex1);
var vertex2 = new ExecutingActionVertex(4, action2);
graph.AddVertex(vertex2);
var vertex3 = new SynchronizationStartVertex(5, new IScheduleVariable[] { variable.Object });
graph.AddVertex(vertex3);
var vertex4 = new ExecutingActionVertex(6, action2);
graph.AddVertex(vertex4);
var vertex5 = new SynchronizationEndVertex(7);
graph.AddVertex(vertex5);
var vertex6 = new SubScheduleVertex(8, scheduleId);
graph.AddVertex(vertex6);
var vertex7 = new InsertVertex(9);
graph.AddVertex(vertex7);
graph.AddEdge(new ScheduleEdge(start, vertex1));
graph.AddEdge(new ScheduleEdge(vertex1, vertex2));
graph.AddEdge(new ScheduleEdge(vertex2, end, exitCondition));
graph.AddEdge(new ScheduleEdge(vertex2, vertex3));
graph.AddEdge(new ScheduleEdge(vertex3, vertex4));
graph.AddEdge(new ScheduleEdge(vertex4, vertex5, passThroughCondition));
graph.AddEdge(new ScheduleEdge(vertex4, vertex6));
graph.AddEdge(new ScheduleEdge(vertex5, vertex1));
graph.AddEdge(new ScheduleEdge(vertex6, vertex7));
graph.AddEdge(new ScheduleEdge(vertex7, vertex4));
schedule = new Schedule(graph, start, end);
}
return(schedule);
}
/// <summary>
/// Override of GetHashCode Method
/// </summary>
/// <returns></returns>
public override int GetHashCode()
{
return(StartVertex.GetHashCode() ^ EndVertex.GetHashCode());
}
