public void run() {
for (int i = start; i <= end; i++) {
for (int j = i + 1; j < cc.getNodeNumber(); j++) {
// double distance = calculateEuclideanDistance(cc.getCCPositions(), dim, i,j);
double distance = 0;
double dummy = 0;
for (int d = 0; d < dim; d++) {
dummy = (cc.getCCPositions()[i][d] - cc.getCCPositions()[j][d]);
distance += (dummy * dummy);
}
distance = Math.sqrt(distance);
if (distance < FORCEnDLayoutConfig.MIN_DISTANCE) continue;
/*
* calculate attraction or repulsion force
*
* attraction:
* log(d(i,j)+1) x cost(i,j) x attraction factor
* ---------------------------------------------
* number of nodes
*
* repulsion:
* cost(i,j) x repulsion factor
* -------------------------------
* log(d(i,j)+1) x number of nodes
*
*/
if (cc.getCCEdges().getEdgeCost(i, j) > 0) {
double force =
(Math.log(distance + 1) * cc.getCCEdges().getEdgeCost(i, j) * attraction)
/ distance;
for (int d = 0; d < dim; d++) {
double displacement = (cc.getCCPositions()[j][d] - cc.getCCPositions()[i][d]) * force;
synchronized (allDisplacements) {
allDisplacements[i][d] += displacement;
allDisplacements[j][d] -= displacement;
}
}
} else {
double force =
((cc.getCCEdges().getEdgeCost(i, j) * repulsion) / Math.log(distance + 1))
/ distance;
for (int d = 0; d < dim; d++) {
double displacement = (cc.getCCPositions()[j][d] - cc.getCCPositions()[i][d]) * force;
synchronized (allDisplacements) {
allDisplacements[i][d] += displacement;
allDisplacements[j][d] -= displacement;
}
}
}
}
}
}
/**
* Calculates the displacement vector for all nodes and saves it in a 2D double array.
*
* @param allDisplacements The displacement values for all nodes.
* @param cc The current ConnectedComponent object.
* @param dim The current dimensions the layouting is run in.
* @param param The parameters object for FORCEnD.
* @param temperature
*/
public static void calculateDisplacementVectors(
double[][] allDisplacements,
ConnectedComponent cc,
int dim,
FORCEnDParameters param,
double temperature) {
setDisplacementsToZero(allDisplacements, cc.getNodeNumber(), dim);
double attraction = param.getAttractionFactor() / cc.getNodeNumber();
double repulsion = param.getRepulsionFactor() / cc.getNodeNumber();
int[] list = new int[cc.getNodeNumber()];
if (TaskConfig.useThreads) {
// if(false){
ExecutorService es =
java.util.concurrent.Executors.newFixedThreadPool(TaskConfig.maxNoThreads);
for (int i = 0; i < TaskConfig.maxNoThreads; i++) {
DisplacementCalculator s =
new DisplacementCalculator(
attraction,
repulsion,
allDisplacements,
cc,
dim,
list,
(int) Math.rint((double) cc.getNodeNumber() / TaskConfig.maxNoThreads) * i,
Math.min(
(int) Math.rint((double) cc.getNodeNumber() / TaskConfig.maxNoThreads) * (i + 1)
- 1,
cc.getNodeNumber() - 1));
es.execute(s);
}
// for (int i = 0; i < cc.getNodeNumber(); i++) {
// int start = i;
// int end = i;
// int estimatedOperation = cc.getNodeNumber()-i;
//
// while(estimatedOperation<((cc.getNodeNumber()*(cc.getNodeNumber()-1))/2)/TaskConfig.maxNoThreads){
// if(i==cc.getNodeNumber()) break;
// end++;
// i++;
// estimatedOperation+=cc.getNodeNumber()-i;
// }
// DisplacementCalculator s = new
// DisplacementCalculator(attraction,repulsion,allDisplacements,cc,dim,list,start,end);
// es.execute(s);
// }
es.shutdown();
try {
es.awaitTermination(5, java.util.concurrent.TimeUnit.HOURS);
} catch (InterruptedException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
} else {
double distance, force, displacement;
for (int i = 0; i < cc.getNodeNumber(); i++) {
/*
* only need to calculate the forces for j<i, because force(i,j) =
* force(j,i)
* if it should at some stage not be the case, then change
* this!
*/
for (int j = i + 1; j < cc.getNodeNumber(); j++) {
distance = calculateEuclideanDistance(cc.getCCPositions(), dim, i, j);
if (distance < FORCEnDLayoutConfig.MIN_DISTANCE) continue;
/*
* calculate attraction or repulsion force
*
* attraction:
* log(d(i,j)+1) x cost(i,j) x attraction factor
* ---------------------------------------------
* number of nodes
*
* repulsion:
* cost(i,j) x repulsion factor
* -------------------------------
* log(d(i,j)+1) x number of nodes
*
*/
if (cc.getCCEdges().getEdgeCost(i, j) > 0) {
force =
(Math.log(distance + 1) * cc.getCCEdges().getEdgeCost(i, j) * attraction)
/ distance;
for (int d = 0; d < dim; d++) {
displacement = (cc.getCCPositions()[j][d] - cc.getCCPositions()[i][d]) * force;
allDisplacements[i][d] += displacement;
allDisplacements[j][d] -= displacement;
}
} else {
force =
((cc.getCCEdges().getEdgeCost(i, j) * repulsion) / Math.log(distance + 1))
/ distance;
for (int d = 0; d < dim; d++) {
displacement = (cc.getCCPositions()[j][d] - cc.getCCPositions()[i][d]) * force;
allDisplacements[i][d] += displacement;
allDisplacements[j][d] -= displacement;
}
}
}
}
}
//
}
