jrtechs
/
jrtechs-vis
mirror of https://github.com/jrtechs/vis.git


								class RepulsionSolver {

								  constructor(body, physicsBody, options) {

								    this.body = body;

								    this.physicsBody = physicsBody;

								    this.setOptions(options);

								  }


								  setOptions(options) {

								    this.options = options;

								  }

								  /**

								   * Calculate the forces the nodes apply on each other based on a repulsion field.

								   * This field is linearly approximated.

								   *

								   * @private

								   */

								  solve() {

								    var dx, dy, distance, fx, fy, repulsingForce, node1, node2;


								    var nodes = this.body.nodes;

								    var nodeIndices = this.physicsBody.physicsNodeIndices;

								    var forces = this.physicsBody.forces;


								    // repulsing forces between nodes

								    var nodeDistance = this.options.nodeDistance;


								    // approximation constants

								    var a = (-2 / 3) / nodeDistance;

								    var b = 4 / 3;


								    // we loop from i over all but the last entree in the array

								    // j loops from i+1 to the last. This way we do not double count any of the indices, nor i === j

								    for (let i = 0; i < nodeIndices.length - 1; i++) {

								      node1 = nodes[nodeIndices[i]];

								      for (let j = i + 1; j < nodeIndices.length; j++) {

								        node2 = nodes[nodeIndices[j]];


								        dx = node2.x - node1.x;

								        dy = node2.y - node1.y;

								        distance = Math.sqrt(dx * dx + dy * dy);


								        // same condition as BarnesHutSolver, making sure nodes are never 100% overlapping.

								        if (distance === 0) {

								          distance = 0.1*Math.random();

								          dx = distance;

								        }


								        if (distance < 2 * nodeDistance) {

								          if (distance < 0.5 * nodeDistance) {

								            repulsingForce = 1.0;

								          }

								          else {

								            repulsingForce = a * distance + b; // linear approx of  1 / (1 + Math.exp((distance / nodeDistance - 1) * steepness))

								          }

								          repulsingForce = repulsingForce / distance;


								          fx = dx * repulsingForce;

								          fy = dy * repulsingForce;


								          forces[node1.id].x -= fx;

								          forces[node1.id].y -= fy;

								          forces[node2.id].x += fx;

								          forces[node2.id].y += fy;

								        }

								      }

								    }

								  }

								}


								export default RepulsionSolver;