public static void terminateFloatValueLayer(ref getFloatValueDelegate get_del)
{
int c = f_dlg2id[get_del];
foreach (MetricPoint n in id2nodelist[c])
{
n.f_id2value.Remove(c);
}
id2nodelist.Remove(c);
f_dlg2id.Remove(get_del);
get_del = null;
}
public static void newFloatValueLayer(out getFloatValueDelegate get_del, out setFloatValueDelegate set_del)
{
Random r = new Random();
int c = r.Next(int.MaxValue);
while (f_dlg2id.ContainsValue(c))
{
c = r.Next(int.MaxValue);
}
get_del = delegate(MetricPoint node)
{
MetricPoint n = (MetricPoint)node;
if (n.f_id2value.ContainsKey(c))
{
return(n.f_id2value[c]);
}
else
{
n.f_id2value.Add(c, double.MaxValue);
MetricPoint.id2nodelist[c].Add(node);
}
return(double.MaxValue);
};
f_dlg2id.Add(get_del, c);
set_del = delegate(MetricPoint node, double val)
{
MetricPoint n = (MetricPoint)node;
if (n.f_id2value.ContainsKey(c))
{
n.f_id2value[c] = val;
}
else
{
n.f_id2value.Add(c, val);
MetricPoint.id2nodelist[c].Add(node);
}
};
id2nodelist.Add(c, new List <MetricPoint>());
}
public void defineNodeDirVectors(int[] initial_set, out getFloatValueDelegate getProximaDst, out setFloatValueDelegate setProximaDst)
{
float curr_value = 0;
List <VascularNode> curr_front;
curr_front = new List <VascularNode>();
List <VascularNode> tmp_curr_front = new List <VascularNode>();
foreach (var id in initial_set)
{
curr_front.Add(vascular_system[0]);
}
getFloatValueDelegate get_del;
setFloatValueDelegate set_del;
VascularNode.newFloatValueLayer(out get_del, out set_del);
foreach (var n in curr_front)
{
set_del(n, curr_value);
}
while (true)
{
foreach (var n in curr_front)
{
foreach (var ng in n.neighbours)
{
if (get_del(ng) > curr_value)
{
set_del(ng, curr_value);
tmp_curr_front.Add(ng);
}
}
}
if (curr_front.Count == 0)
{
break;
}
curr_front = new List <VascularNode>(tmp_curr_front);
tmp_curr_front.Clear();
curr_value += 1.0f;
}
foreach (var n in vascular_system)
{
if (n.neighbours.Count < 3)
{
//Console.WriteLine(n.id);
//if (n.id == 1717)
//{
// Console.WriteLine("1");
//}
//Console.WriteLine(get_del(n.neighbours.First()));
//Console.WriteLine(get_del(n));
if (n.neighbours.Last().position < n.neighbours.First().position)
{
n.neighbours.Reverse();
}
n.defDirVector();
}
}
getProximaDst = get_del;
setProximaDst = set_del;
}
public void defineNet(getFloatValueDelegate getProximalDistance, setFloatValueDelegate setProximalDistance, List <ClotNode> ClotNodes)
{
int count_id = vascular_system.Count;
foreach (var n in vascular_system)
{
n.defDirVector();
}
// this we should get from import
List <VascularNode> knot_nodes = getSubsystem(x => x.nodetype == 1);
List <VascularNode> term_nodes = getSubsystem(x => x.nodetype == 2);
for (int i = 0; i < ClotNodes.Count; i++)
{
ClotNodes[i].Node = vascular_system.Find(x => x.id == ClotNodes[i].Node_id);
}
foreach (var node in ClotNodes)
{
node.Node.nodetype = 3;
}
foreach (var node in vascular_system)
{
if (node.nodetype == 3)
{
foreach (var nnode in node.neighbours)
{
if (nnode.nodetype <= 1)
{
node.nodetype = 4;
term_nodes.Add(node);
}
}
}
}
// remove connections between clot boundary and the clot (terminal definition)
foreach (var node in vascular_system)
{
if (node.nodetype >= 3)
{
List <VascularNode> dellist = new List <VascularNode>();
foreach (var nnode in node.neighbours)
{
if (nnode.nodetype == 4)
{
//term_nodes.Add(node);
dellist.Add(nnode);
}
}
foreach (var nnode in dellist)
{
node.excludeNeighbour(nnode);
nnode.excludeNeighbour(node);
}
}
}
//List<int> list = new List<int>();
//foreach (var node in ClotNodes)
//{
// list.Add(node.Clot_id);
//}
//list = list.Distinct().ToList();
////List<ClotNode> clotboundary = new List<ClotNode>();
//foreach (int clotid in list)
//{
// List<ClotNode> listnodes = new List<ClotNode>();
// foreach (var node in ClotNodes)
// {
// if (node.Clot_id == clotid)
// listnodes.Add(node);
// }
// List<VascularNode> Node1 = getSubsystem(x => x.id == listnodes[0].Node_id);
// List<VascularNode> Node2 = getSubsystem(x => x.id == listnodes[listnodes.Count - 1].Node_id);
// //clotboundary.Add(listnodes[0]);
// //clotboundary.Add(listnodes[listnodes.Count - 1]);
//}
knots = new List <Knot>();
bounds = new List <BoundaryCondition>();
foreach (var tn in term_nodes)
{
bounds.Add(new BoundaryCondition(tn, 0)); // Just abstract BC, which do nothing
}
foreach (var kn in knot_nodes)
{
knots.Add(new Knot(kn, 0)); // Just abstract knot, which do nothing and don't pass the solution through itself
}
//foreach (var kn in knot_nodes)
//{
// List<VascularNode> b_nodes = new List<VascularNode>();
// List<VascularNode> n_nodes = new List<VascularNode>(kn.neighbours);
// // change this part to switch roles for temp nodes
// foreach (var n in n_nodes)
// {
// Vector1 pos = kn.position - (kn.position - n.position) * 0.001;
// double r = Math.Sqrt(n.lumen_sq_0 / Math.PI);
// VascularNode b_n = new VascularNode(count_id, pos, r);
// b_n.neighbours.Add(kn);
// b_n.neighbours.Add(n);
// setProximalDistance(b_n, (getProximalDistance(kn) + getProximalDistance(n)) / 2);
// kn.neighbours.Remove(n);// do we need to remove neighbours?
// n.neighbours.Remove(kn);
// kn.addNeighbour(b_n);
// n.addNeighbour(b_n);
// b_nodes.Add(b_n);
// count_id++;
// }
// knots.Add(new Knot(kn, 0)); // Just abstract knot, which do nothing and don't pass the solution through itself
//}
List <string> writeText = new List <string>();
threads = new List <Thread> ();
node2thread = new Dictionary <VascularNode, Thread>();
getBoolValueDelegate isProcessed;
setBoolValueDelegate setProcessed;
VascularNode.newBoolValueLayer(out isProcessed, out setProcessed);
VascularNode curr_node;
//VascularNode next_node;
foreach (var kn in knots)
{
setProcessed(kn.core_node, true);
}
// Define threads starting from bounds
foreach (var bc in bounds)
{
curr_node = bc.core_node;
List <VascularNode> protothread = new List <VascularNode>();
while (true)
{
protothread.Add(curr_node);
setProcessed(curr_node, true);
try
{
curr_node = curr_node.neighbours.First(x => (!isProcessed(x)));
}
catch
{
break;
}
}
if (protothread.Count > 1)
{
//if(getProximalDistance(protothread.First()) > getProximalDistance(protothread.Last()))
if (protothread[1].position > protothread.Last().position)
{
protothread.Reverse();
}
threads.Add(new Thread(protothread));
foreach (var n in protothread)
{
node2thread.Add(n, threads.Last());
}
}
}
// Define threads starting from knots
foreach (var kn in knots)
{
foreach (var start in kn.nodes)
{
curr_node = start;
List <VascularNode> protothread = new List <VascularNode>();
while (true)
{
protothread.Add(curr_node);
setProcessed(curr_node, true);
try
{
curr_node = curr_node.neighbours.First(x => (!isProcessed(x)));
}
catch
{
break;
}
}
if (protothread.Count > 1)
{
//if(getProximalDistance(protothread.First()) > getProximalDistance(protothread.Last()))
if (protothread[1].position > protothread.Last().position)
{
protothread.Reverse();
}
threads.Add(new Thread(protothread));
foreach (var n in protothread)
{
node2thread.Add(n, threads.Last());
}
}
}
}
VascularNode.terminateBoolValueLayer(ref isProcessed);
}
