/// <summary>
/// Returns true if this db contains complex restrictions for the given vehicle types.
/// </summary>
public static bool HasComplexRestrictions(this RouterDb db, IEnumerable <string> vehicleTypes)
{
if (db.HasComplexRestrictions(string.Empty))
{
return(true);
}
foreach (var vehicleType in vehicleTypes)
{
if (db.HasComplexRestrictions(vehicleType))
{
return(true);
}
}
return(false);
}
/// <summary>
/// Returns true if this db contains complex restrictions for the given profile.
/// </summary>
public static bool HasComplexRestrictions(this RouterDb db, Profiles.Profile profile)
{
return(db.HasComplexRestrictions(profile.VehicleType));
}
/// <summary>
/// Calculates a route between the two locations.
/// </summary>
/// <returns></returns>
public sealed override Result <EdgePath <T> > TryCalculateRaw <T>(IProfileInstance profileInstance, WeightHandler <T> weightHandler, RouterPoint source, RouterPoint target,
RoutingSettings <T> settings)
{
try
{
if (!_db.Supports(profileInstance.Profile))
{
return(new Result <EdgePath <T> >("Routing profile is not supported.", (message) =>
{
return new Exception(message);
}));
}
var maxSearch = weightHandler.Infinite;
if (settings != null)
{
if (!settings.TryGetMaxSearch(profileInstance.Profile.FullName, out maxSearch))
{
maxSearch = weightHandler.Infinite;
}
}
EdgePath <T> path;
ContractedDb contracted;
bool useContracted = false;
if (_db.TryGetContracted(profileInstance.Profile, out contracted))
{ // contracted calculation.
useContracted = true;
if (_db.HasComplexRestrictions(profileInstance.Profile) && !contracted.HasEdgeBasedGraph)
{ // there is no edge-based graph for this profile but the db has complex restrictions, don't use the contracted graph.
Logging.Logger.Log("Router", Logging.TraceEventType.Warning,
"There is a vertex-based contracted graph but also complex restrictions. Not using the contracted graph, add an edge-based contracted graph.");
useContracted = false;
}
}
if (useContracted)
{ // use the contracted graph.
path = null;
List <uint> vertexPath = null;
if (!contracted.HasEdgeBasedGraph)
{ // use node-based routing.
var bidirectionalSearch = new Itinero.Algorithms.Contracted.BidirectionalDykstra <T>(contracted.NodeBasedGraph, weightHandler,
source.ToEdgePaths(_db, weightHandler, true), target.ToEdgePaths(_db, weightHandler, false));
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
vertexPath = bidirectionalSearch.GetPath();
}
else
{ // use edge-based routing.
var bidirectionalSearch = new Itinero.Algorithms.Contracted.EdgeBased.BidirectionalDykstra <T>(contracted.EdgeBasedGraph, weightHandler,
source.ToEdgePaths(_db, weightHandler, true), target.ToEdgePaths(_db, weightHandler, false), _db.GetGetRestrictions(profileInstance.Profile, null));
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
vertexPath = bidirectionalSearch.GetPath();
}
// expand vertex path using the regular graph.
path = _db.BuildEdgePath(weightHandler, source, target, vertexPath);
}
else
{ // use the regular graph.
if (_db.HasComplexRestrictions(profileInstance.Profile))
{
var sourceSearch = new Algorithms.Default.EdgeBased.Dykstra <T>(_db.Network.GeometricGraph.Graph, weightHandler,
_db.GetGetRestrictions(profileInstance.Profile, true), source.ToEdgePaths(_db, weightHandler, true), maxSearch, false);
var targetSearch = new Algorithms.Default.EdgeBased.Dykstra <T>(_db.Network.GeometricGraph.Graph, weightHandler,
_db.GetGetRestrictions(profileInstance.Profile, false), target.ToEdgePaths(_db, weightHandler, false), maxSearch, true);
var bidirectionalSearch = new Algorithms.Default.EdgeBased.BidirectionalDykstra <T>(sourceSearch, targetSearch, weightHandler);
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
path = bidirectionalSearch.GetPath();
}
else
{
var sourceSearch = new Dykstra <T>(_db.Network.GeometricGraph.Graph, null, weightHandler,
source.ToEdgePaths(_db, weightHandler, true), maxSearch, false);
var targetSearch = new Dykstra <T>(_db.Network.GeometricGraph.Graph, null, weightHandler,
target.ToEdgePaths(_db, weightHandler, false), maxSearch, true);
var bidirectionalSearch = new BidirectionalDykstra <T>(sourceSearch, targetSearch, weightHandler);
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
path = bidirectionalSearch.GetPath();
}
}
if (source.EdgeId == target.EdgeId)
{ // check for a shorter path on the same edge.
var edgePath = source.EdgePathTo(_db, weightHandler, target);
if (edgePath != null &&
weightHandler.IsSmallerThan(edgePath.Weight, path.Weight))
{
path = edgePath;
}
}
return(new Result <EdgePath <T> >(path));
}
catch (Exception ex)
{
return(new Result <EdgePath <T> >(ex.Message, (m) => ex));
}
}
/// <summary>
/// Creates a new contracted graph and adds it to the router db for the given profile.
/// </summary>
public static void AddContracted <T>(this RouterDb db, Profiles.Profile profile, WeightHandler <T> weightHandler, bool forceEdgeBased = false)
where T : struct
{
// create the raw directed graph.
ContractedDb contractedDb = null;
if (!forceEdgeBased)
{ // check if there are complex restrictions in the routerdb forcing edge-based contraction.
if (db.HasComplexRestrictions(profile))
{ // there are complex restrictions, use edge-based contraction, the only way to support these in a contracted graph.
forceEdgeBased = true;
}
}
lock (db)
{
if (forceEdgeBased)
{ // edge-based is needed when complex restrictions found.
var contracted = new DirectedDynamicGraph(weightHandler.DynamicSize);
var directedGraphBuilder = new Itinero.Algorithms.Contracted.EdgeBased.DirectedGraphBuilder <T>(db.Network.GeometricGraph.Graph, contracted,
weightHandler);
directedGraphBuilder.Run();
// contract the graph.
var priorityCalculator = new Itinero.Algorithms.Contracted.EdgeBased.EdgeDifferencePriorityCalculator <T>(contracted, weightHandler,
new Itinero.Algorithms.Contracted.EdgeBased.Witness.DykstraWitnessCalculator <T>(weightHandler, 4, 64));
priorityCalculator.DifferenceFactor = 5;
priorityCalculator.DepthFactor = 5;
priorityCalculator.ContractedFactor = 8;
var hierarchyBuilder = new Itinero.Algorithms.Contracted.EdgeBased.HierarchyBuilder <T>(contracted, priorityCalculator,
new Itinero.Algorithms.Contracted.EdgeBased.Witness.DykstraWitnessCalculator <T>(weightHandler, int.MaxValue, 64), weightHandler, db.GetGetRestrictions(profile, null));
hierarchyBuilder.Run();
contractedDb = new ContractedDb(contracted);
}
else
{ // vertex-based is ok when no complex restrictions found.
var contracted = new DirectedMetaGraph(ContractedEdgeDataSerializer.Size, weightHandler.MetaSize);
var directedGraphBuilder = new DirectedGraphBuilder <T>(db.Network.GeometricGraph.Graph, contracted, weightHandler);
directedGraphBuilder.Run();
// contract the graph.
var priorityCalculator = new EdgeDifferencePriorityCalculator(contracted,
new DykstraWitnessCalculator(int.MaxValue));
priorityCalculator.DifferenceFactor = 5;
priorityCalculator.DepthFactor = 5;
priorityCalculator.ContractedFactor = 8;
var hierarchyBuilder = new HierarchyBuilder <T>(contracted, priorityCalculator,
new DykstraWitnessCalculator(int.MaxValue), weightHandler);
hierarchyBuilder.Run();
contractedDb = new ContractedDb(contracted);
}
}
// add the graph.
lock (db)
{
db.AddContracted(profile, contractedDb);
}
}
/// <summary>
/// Calculates a route between the two locations.
/// </summary>
/// <returns></returns>
public sealed override Result <EdgePath <T> > TryCalculateRaw <T>(IProfileInstance profileInstance, WeightHandler <T> weightHandler, RouterPoint source, RouterPoint target,
RoutingSettings <T> settings)
{
try
{
if (!_db.Supports(profileInstance.Profile))
{
return(new Result <EdgePath <T> >("Routing profile is not supported.", (message) =>
{
return new Exception(message);
}));
}
var maxSearch = weightHandler.Infinite;
if (settings != null)
{
if (!settings.TryGetMaxSearch(profileInstance.Profile.FullName, out maxSearch))
{
maxSearch = weightHandler.Infinite;
}
}
ContractedDb contracted;
bool useContracted = false;
if (_db.TryGetContracted(profileInstance.Profile, out contracted))
{ // contracted calculation.
useContracted = true;
if (_db.HasComplexRestrictions(profileInstance.Profile) &&
(!contracted.HasEdgeBasedGraph && !contracted.NodeBasedIsEdgedBased))
{ // there is no edge-based graph for this profile but the db has complex restrictions, don't use the contracted graph.
Logging.Logger.Log("Router", Logging.TraceEventType.Warning,
"There is a vertex-based contracted graph but also complex restrictions. Not using the contracted graph, add an edge-based contracted graph.");
useContracted = false;
}
}
EdgePath <T> path = null;
if (source.EdgeId == target.EdgeId)
{ // check for a path on the same edge.
var edgePath = source.EdgePathTo(_db, weightHandler, target);
if (edgePath != null)
{
path = edgePath;
}
}
if (useContracted)
{ // use the contracted graph.
List <uint> vertexPath = null;
if (contracted.HasEdgeBasedGraph)
{ // use edge-based routing.
var bidirectionalSearch = new Itinero.Algorithms.Contracted.EdgeBased.BidirectionalDykstra <T>(contracted.EdgeBasedGraph, weightHandler,
source.ToEdgePaths(_db, weightHandler, true), target.ToEdgePaths(_db, weightHandler, false), _db.GetGetRestrictions(profileInstance.Profile, null));
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
if (path == null)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
}
else
{
vertexPath = bidirectionalSearch.GetPath();
}
}
else if (contracted.NodeBasedIsEdgedBased)
{// use vertex-based graph for edge-based routing.
var sourceDirectedId1 = new DirectedEdgeId(source.EdgeId, true);
var sourceDirectedId2 = new DirectedEdgeId(source.EdgeId, false);
var targetDirectedId1 = new DirectedEdgeId(target.EdgeId, true);
var targetDirectedId2 = new DirectedEdgeId(target.EdgeId, false);
var bidirectionalSearch = new Itinero.Algorithms.Contracted.BidirectionalDykstra <T>(contracted.NodeBasedGraph, null, weightHandler,
new EdgePath <T>[] { new EdgePath <T>(sourceDirectedId1.Raw), new EdgePath <T>(sourceDirectedId2.Raw) },
new EdgePath <T>[] { new EdgePath <T>(targetDirectedId1.Raw), new EdgePath <T>(targetDirectedId2.Raw) });
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
var directedEdgePath = Algorithms.Dual.BidirectionalDykstraExtensions.GetDualPath(bidirectionalSearch);
// convert directed edge-path to an original vertex path.
var enumerator = _db.Network.GetEdgeEnumerator();
vertexPath = new List <uint>();
var edge = new List <OriginalEdge>();
for (var i = 0; i < directedEdgePath.Count; i++)
{
var e = new DirectedEdgeId()
{
Raw = directedEdgePath[i]
};
enumerator.MoveToEdge(e.EdgeId);
var original = new OriginalEdge(enumerator.From, enumerator.To);
if (!e.Forward)
{
original = original.Reverse();
}
edge.Add(original);
if (vertexPath.Count == 0)
{
vertexPath.Add(original.Vertex1);
}
vertexPath.Add(original.Vertex2);
}
vertexPath[0] = Constants.NO_VERTEX;
vertexPath[vertexPath.Count - 1] = Constants.NO_VERTEX;
}
else
{ // use node-based routing.
var bidirectionalSearch = new Itinero.Algorithms.Contracted.BidirectionalDykstra <T>(contracted.NodeBasedGraph, _db.GetRestrictions(profileInstance.Profile), weightHandler,
source.ToEdgePaths(_db, weightHandler, true), target.ToEdgePaths(_db, weightHandler, false));
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
if (path == null)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
}
else
{
vertexPath = Algorithms.Contracted.BidirectionalDykstraExtensions.GetPath(bidirectionalSearch);
}
}
// expand vertex path using the regular graph.
if (vertexPath != null)
{
var localPath = _db.BuildEdgePath(weightHandler, source, target, vertexPath);
if (path == null ||
weightHandler.IsSmallerThan(localPath.Weight, path.Weight))
{
path = localPath;
}
}
}
else
{ // use the regular graph.
EdgePath <T> localPath = null;
if (_db.HasComplexRestrictions(profileInstance.Profile))
{
var sourceSearch = new Algorithms.Default.EdgeBased.Dykstra <T>(_db.Network.GeometricGraph.Graph, weightHandler,
_db.GetGetRestrictions(profileInstance.Profile, true), source.ToEdgePaths(_db, weightHandler, true), maxSearch, false);
var targetSearch = new Algorithms.Default.EdgeBased.Dykstra <T>(_db.Network.GeometricGraph.Graph, weightHandler,
_db.GetGetRestrictions(profileInstance.Profile, false), target.ToEdgePaths(_db, weightHandler, false), maxSearch, true);
var bidirectionalSearch = new Algorithms.Default.EdgeBased.BidirectionalDykstra <T>(sourceSearch, targetSearch, weightHandler);
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
if (path == null)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
}
else
{
localPath = bidirectionalSearch.GetPath();
}
}
else
{
var sourceSearch = new Dykstra <T>(_db.Network.GeometricGraph.Graph, _db.GetGetSimpleRestrictions(profileInstance.Profile), weightHandler,
source.ToEdgePaths(_db, weightHandler, true), maxSearch, false);
var targetSearch = new Dykstra <T>(_db.Network.GeometricGraph.Graph, _db.GetGetSimpleRestrictions(profileInstance.Profile), weightHandler,
target.ToEdgePaths(_db, weightHandler, false), maxSearch, true);
var bidirectionalSearch = new BidirectionalDykstra <T>(sourceSearch, targetSearch, weightHandler);
bidirectionalSearch.Run();
if (!bidirectionalSearch.HasSucceeded)
{
if (path == null)
{
return(new Result <EdgePath <T> >(bidirectionalSearch.ErrorMessage, (message) =>
{
return new RouteNotFoundException(message);
}));
}
}
else
{
localPath = bidirectionalSearch.GetPath();
}
}
// choose best path.
if (localPath != null)
{
if (path == null ||
weightHandler.IsSmallerThan(localPath.Weight, path.Weight))
{
path = localPath;
}
}
}
return(new Result <EdgePath <T> >(path));
}
catch (Exception ex)
{
return(new Result <EdgePath <T> >(ex.Message, (m) => ex));
}
}
