// topologically sort the graph to work out calculation order
public Dictionary <string, int> CalculateWeights()
{
var remainingNodes = new SortedSet <int>(Nodes.Select(n => n.ID).Union(KeyNodes.Select(k => k.Value.ID)));
var markedNodes = new SortedSet <int>();
var processors = Nodes.ToDictionary(n => n.ID, n => RFGraphDefinition.GetFullName(n.GraphName, n.Label));
var visitOrder = new List <int>();
while (remainingNodes.Any())
{
var remainingNode = remainingNodes.First();
Visit(remainingNode, markedNodes, remainingNodes, visitOrder);
}
var weights = new Dictionary <string, int>();
int idx = 1;
visitOrder.Reverse();
foreach (var node in visitOrder)
{
if (processors.ContainsKey(node))
{
weights.Add(processors[node], idx++);
}
}
return(weights);
}
public Dictionary <string, SortedSet <string> > CalculateDependencies()
{
// for each node list nodes it depends on (i.e. reverse traverse)
var processors = Nodes.ToDictionary(n => n.ID, n => RFGraphDefinition.GetFullName(n.GraphName, n.Label));
var dependencies = new Dictionary <string, SortedSet <string> >();
foreach (var node in Nodes)
{
var visited = new SortedSet <int>();
var toVisit = new SortedSet <int>(Edges.Where(e => e.DestinationNode == node.ID).Select(e => e.SourceNode));
while (toVisit.Any())
{
var next = toVisit.First();
toVisit.Remove(next);
if (!visited.Contains(next))
{
visited.Add(next);
foreach (var source in Edges.Where(e => e.DestinationNode == next).Select(e => e.SourceNode))
{
if (!visited.Contains(source))
{
toVisit.Add(source);
}
}
}
}
dependencies.Add(processors[node.ID], new SortedSet <string>(visited.Where(v => processors.ContainsKey(v)).Select(v => processors[v])));
}
return(dependencies);
}
protected void AddGraph(RFGraphDefinition graphConfig)
{
foreach (var graphProcess in graphConfig.Processes.Values)
{
var graphProcessName = RFGraphDefinition.GetFullName(graphConfig.GraphName, graphProcess.Name);
_processes.Add(graphProcessName,
new RFEngineProcess(graphProcessName,
new RFEngineProcessDefinition
{
InstanceParams = i => i.ExtractParam().ConvertTo <RFEngineProcessorGraphInstanceParam>(),
Name = graphProcessName,
Description = graphProcess.Description,
Processor = () => new RFGraphProcess(graphProcess)
}, _config.KeyDomain));
// check for missing inputs
foreach (var p in graphProcess.Processor().CreateDomain().GetType().GetProperties())
{
if (RFReflectionHelpers.IsMandatory(p) && graphProcess.IOMappings.SingleOrDefault(m => m.Property.FullName() == p.FullName()) == null)
{
throw new RFSystemException(this, "Unmapped mandatory property {0} on processor {1}", p.FullName(), graphProcessName);
}
}
// auto-react to inputs
foreach (var ioMapping in graphProcess.IOMappings)
{
var ioBehaviour = ioMapping.Property.GetCustomAttributes(typeof(RFIOBehaviourAttribute), true).FirstOrDefault() as RFIOBehaviourAttribute;
var dateBehaviour = ioMapping.DateBehaviour;
if (ioBehaviour != null && ioBehaviour.IOBehaviour == RFIOBehaviour.Input)
{
switch (dateBehaviour)
{
case RFDateBehaviour.Range:
_reactors.Add(RFGraphReactor.RangeReactor(ioMapping.Key, graphProcessName, _context.GetReadingContext(), ioMapping.RangeUpdateFunc, graphProcess.Processor().MaxInstance));
break;
case RFDateBehaviour.Exact:
case RFDateBehaviour.Latest:
case RFDateBehaviour.Previous:
_reactors.Add(RFGraphReactor.SimpleReactor(ioMapping.Key, dateBehaviour, graphProcessName, _context.GetReadingContext(), graphProcess.Processor().MaxInstance));
break;
}
}
}
}
}
protected RFGraphProcessDefinition AddIOMapping <S>(Expression <Func <S, object> > property, RFCatalogKey key, RFIOBehaviour expectedBehvaiour, Func <RFGraphInstance, List <RFDate> > rangeRequestFunc = null,
Func <RFGraphInstance, RFDate> rangeUpdateFunc = null) where S : RFGraphProcessorDomain
{
var processor = Processor();
var domain = processor.CreateDomain();
if (domain.GetType() != typeof(S))
{
throw new RFLogicException(this, "IO Domain Type mismatch on processor {0}: {1} vs {2}", RFGraphDefinition.GetFullName(GraphName, Name),
domain.GetType().Name, typeof(S).Name);
}
var propertyInfo = property.GetProperty <S>();
var ioBehaviour = RFReflectionHelpers.GetIOBehaviour(propertyInfo);
if (ioBehaviour != expectedBehvaiour)
{
throw new RFLogicException(this, "Inconsistent IO direction {0} on property {1}, expected {2}.", ioBehaviour, propertyInfo.FullName(), expectedBehvaiour);
}
var dateBehaviour = RFReflectionHelpers.GetDateBehaviour(propertyInfo);
if (dateBehaviour == RFDateBehaviour.Range && (rangeRequestFunc == null || rangeUpdateFunc == null))
{
throw new RFLogicException(this, "Range input doesn't have range functions specified on property {0}.", propertyInfo.FullName());
}
IOMappings.Add(new RFGraphIOMapping {
Key = key, Property = propertyInfo, RangeRequestFunc = rangeRequestFunc, RangeUpdateFunc = rangeUpdateFunc, DateBehaviour = dateBehaviour
});
return(this);
}
public static RFGraphMap MapGraphs(IEnumerable <RFGraphDefinition> graphs, bool forPresentation = true)
{
var map = new RFGraphMap();
foreach (var graph in graphs)
{
foreach (var process in graph.Processes)
{
var name = RFGraphDefinition.GetFullName(graph.GraphName, process.Value.Name);
var processNode = new RFGraphMapNode(map)
{
Label = process.Value.Name,
GraphName = graph.GraphName,
NodeType = RFGraphMapNodeType.Processor,
FullType = process.Value.Processor().GetType().Name,
Description = process.Value.Description
};
map.Nodes.Add(processNode);
foreach (var ioMapping in process.Value.IOMappings)
{
if (ioMapping.PropertyName == "Status")
{
continue;
}
var ioBehaviour = RFReflectionHelpers.GetIOBehaviour(ioMapping.Property);
var dateBehaviour = ioMapping.DateBehaviour; //RFReflectionHelpers.GetDateBehaviour(ioMapping.Property);
if (!forPresentation)
{
// for graph sort we are only interested in exact date inputs and
// outputs, which should result in acycylical graph
if (ioBehaviour == RFIOBehaviour.State)
{
continue;
}
if (dateBehaviour != RFDateBehaviour.Exact && dateBehaviour != RFDateBehaviour.Range && dateBehaviour != RFDateBehaviour.Latest)
{
continue;
}
}
if (ioMapping.Key != null)
{
var rawKeyString = KeyLabel(ioMapping.Key.CreateForInstance(null));
var keyLabel = forPresentation ? graph.GraphName + rawKeyString : rawKeyString;
if (!map.KeyNodes.ContainsKey(keyLabel))
{
map.KeyNodes.Add(keyLabel, new RFGraphMapNode(map)
{
Label = rawKeyString,
RawKey = rawKeyString,
NodeType = RFGraphMapNodeType.Key,
GraphName = graph.GraphName,
FullType = ioMapping.Key.CreateForInstance(null).GetType().Name,
Description = ""
});
}
var keyNode = map.KeyNodes[keyLabel];
if (ioBehaviour == RFIOBehaviour.Input || ioBehaviour == RFIOBehaviour.State)
{
map.Edges.Add(new RFGraphMapEdge
{
SourceNode = keyNode.ID,
DestinationNode = processNode.ID,
Label = ioMapping.PropertyName,
EdgeType = ioBehaviour == RFIOBehaviour.Input ? RFGraphMapEdgeType.Input : RFGraphMapEdgeType.State
});
keyNode.Description += string.Format("{0} to {1} ({2})<br/>", ioBehaviour, processNode.Label, ioMapping.PropertyName);
}
if (ioBehaviour == RFIOBehaviour.Output)
{
map.Edges.Add(new RFGraphMapEdge
{
SourceNode = processNode.ID,
DestinationNode = keyNode.ID,
Label = ioMapping.PropertyName,
EdgeType = RFGraphMapEdgeType.Output
});
keyNode.Description += string.Format("{0} of {1} ({2})<br/>", ioBehaviour, processNode.Label, ioMapping.PropertyName);
}
}
else
{
// unbound item? check for other domain properties?
}
}
}
}
return(map);
}
public override string FriendlyString()
{
return(RFGraphDefinition.GetFullName(GraphName, ProcessName));
}