fourdjs/fourDShape.js

154 lines
3.8 KiB
JavaScript

import * as THREE from 'three';
const HYPERPLANE = 2.0;
class FourDShape extends THREE.Group {
constructor(node_ms, link_ms, face_ms, structure) {
super();
this.node_ms = node_ms;
this.link_ms = link_ms;
this.face_ms = face_ms;
this.nodes4 = structure.nodes;
this.nodes3 = {};
this.links = structure.links;
this.faces = ( "faces" in structure ) ? structure.faces : [];
this.node_size = structure.geometry.node_size;
this.link_size = structure.geometry.link_size;
this.node_scale = 1;
this.link_scale = 1;
this.hyperplane = HYPERPLANE;
this.initShapes();
}
// if a node/link has no label, use the 0th material
getMaterial(entity, materials) {
if( "label" in entity ) {
return materials[entity.label];
} else {
return materials[0];
}
}
makeNode(material, v3) {
const geometry = new THREE.SphereGeometry(this.node_size);
const sphere = new THREE.Mesh(geometry, material);
sphere.position.copy(v3);
this.add(sphere);
return sphere;
}
makeLink(material, link) {
const n1 = this.nodes3[link.source].v3;
const n2 = this.nodes3[link.target].v3;
const length = n1.distanceTo(n2);
const centre = new THREE.Vector3();
centre.lerpVectors(n1, n2, 0.5);
const geometry = new THREE.CylinderGeometry(this.link_size, this.link_size, 1);
const cyl = new THREE.Mesh(geometry, material);
const edge = new THREE.Group();
edge.add(cyl);
edge.position.copy(centre);
edge.scale.copy(new THREE.Vector3(1, 1, length));
edge.lookAt(n2);
cyl.rotation.x = Math.PI / 2.0;
this.add(edge);
return edge;
}
updateLink(link) {
const n1 = this.nodes3[link.source].v3;
const n2 = this.nodes3[link.target].v3;
const length = n1.distanceTo(n2);
const centre = new THREE.Vector3();
centre.lerpVectors(n1, n2, 0.5);
link.object.scale.copy(new THREE.Vector3(this.link_scale, this.link_scale, length));
link.object.position.copy(centre);
link.object.lookAt(n2);
link.object.children[0].rotation.x = Math.PI / 2.0;
}
setFaceGeometry(face, geometry) {
const values = [];
for( const f of face.nodes ) {
const v3 = this.nodes3[f].v3;
values.push(v3.x);
values.push(v3.y);
values.push(v3.z);
}
const v3 = this.nodes3[face.nodes[0]].v3;
values.push(v3.x);
values.push(v3.y);
values.push(v3.z);
const vertices = new Float32Array(values);
geometry.setAttribute( 'position', new THREE.BufferAttribute( vertices, 3 ) );
}
makeFace(material, face) {
const geometry = new THREE.BufferGeometry();
this.setFaceGeometry(face, geometry)
const mesh = new THREE.Mesh( geometry, material );
this.add(mesh);
return mesh;
}
fourDtoV3(x, y, z, w, rotations) {
const v4 = new THREE.Vector4(x, y, z, w);
for ( const m4 of rotations ) {
v4.applyMatrix4(m4);
}
const k = this.hyperplane / (this.hyperplane + v4.w);
return new THREE.Vector3(v4.x * k, v4.y * k, v4.z * k);
}
initShapes() {
for( const n of this.nodes4 ) {
const v3 = this.fourDtoV3(n.x, n.y, n.z, n.w, []);
const material = this.getMaterial(n, this.node_ms);
this.nodes3[n.id] = {
v3: v3,
object: this.makeNode(material, v3)
};
}
for( const l of this.links ) {
const material = this.getMaterial(l, this.link_ms);
l.object = this.makeLink(material, l);
}
for( const f of this.faces ) {
const material = this.getMaterial(f, this.face_ms);
f.object = this.makeFace(material, f);
}
}
render3(rotations) {
this.scalev3 = new THREE.Vector3(this.node_scale, this.node_scale, this.node_scale);
for( const n of this.nodes4 ) {
const v3 = this.fourDtoV3(n.x, n.y, n.z, n.w, rotations);
this.nodes3[n.id].v3 = v3;
this.nodes3[n.id].object.position.copy(v3);
this.nodes3[n.id].object.scale.copy(this.scalev3);
}
for( const l of this.links ) {
this.updateLink(l);
}
for( const f of this.faces ) {
this.setFaceGeometry(f, f.object.geometry);
}
}
}
export { FourDShape };