import { BufferGeometry } from '../core/BufferGeometry.js'; import { Float32BufferAttribute } from '../core/BufferAttribute.js'; import { Vector3 } from '../math/Vector3.js'; class TorusKnotGeometry extends BufferGeometry { constructor(radius = 1, tube = 0.4, tubularSegments = 64, radialSegments = 8, p = 2, q = 3) { super(); this.type = 'TorusKnotGeometry'; this.parameters = { radius: radius, tube: tube, tubularSegments: tubularSegments, radialSegments: radialSegments, p: p, q: q, }; tubularSegments = Math.floor(tubularSegments); radialSegments = Math.floor(radialSegments); // buffers const indices = []; const vertices = []; const normals = []; const uvs = []; // helper variables const vertex = new Vector3(); const normal = new Vector3(); const P1 = new Vector3(); const P2 = new Vector3(); const B = new Vector3(); const T = new Vector3(); const N = new Vector3(); // generate vertices, normals and uvs for (let i = 0; i <= tubularSegments; ++i) { // the radian "u" is used to calculate the position on the torus curve of the current tubular segement const u = (i / tubularSegments) * p * Math.PI * 2; // now we calculate two points. P1 is our current position on the curve, P2 is a little farther ahead. // these points are used to create a special "coordinate space", which is necessary to calculate the correct vertex positions calculatePositionOnCurve(u, p, q, radius, P1); calculatePositionOnCurve(u + 0.01, p, q, radius, P2); // calculate orthonormal basis T.subVectors(P2, P1); N.addVectors(P2, P1); B.crossVectors(T, N); N.crossVectors(B, T); // normalize B, N. T can be ignored, we don't use it B.normalize(); N.normalize(); for (let j = 0; j <= radialSegments; ++j) { // now calculate the vertices. they are nothing more than an extrusion of the torus curve. // because we extrude a shape in the xy-plane, there is no need to calculate a z-value. const v = (j / radialSegments) * Math.PI * 2; const cx = -tube * Math.cos(v); const cy = tube * Math.sin(v); // now calculate the final vertex position. // first we orient the extrusion with our basis vectos, then we add it to the current position on the curve vertex.x = P1.x + (cx * N.x + cy * B.x); vertex.y = P1.y + (cx * N.y + cy * B.y); vertex.z = P1.z + (cx * N.z + cy * B.z); vertices.push(vertex.x, vertex.y, vertex.z); // normal (P1 is always the center/origin of the extrusion, thus we can use it to calculate the normal) normal.subVectors(vertex, P1).normalize(); normals.push(normal.x, normal.y, normal.z); // uv uvs.push(i / tubularSegments); uvs.push(j / radialSegments); } } // generate indices for (let j = 1; j <= tubularSegments; j++) { for (let i = 1; i <= radialSegments; i++) { // indices const a = (radialSegments + 1) * (j - 1) + (i - 1); const b = (radialSegments + 1) * j + (i - 1); const c = (radialSegments + 1) * j + i; const d = (radialSegments + 1) * (j - 1) + i; // faces indices.push(a, b, d); indices.push(b, c, d); } } // build geometry this.setIndex(indices); this.setAttribute('position', new Float32BufferAttribute(vertices, 3)); this.setAttribute('normal', new Float32BufferAttribute(normals, 3)); this.setAttribute('uv', new Float32BufferAttribute(uvs, 2)); // this function calculates the current position on the torus curve function calculatePositionOnCurve(u, p, q, radius, position) { const cu = Math.cos(u); const su = Math.sin(u); const quOverP = (q / p) * u; const cs = Math.cos(quOverP); position.x = radius * (2 + cs) * 0.5 * cu; position.y = radius * (2 + cs) * su * 0.5; position.z = radius * Math.sin(quOverP) * 0.5; } } static fromJSON(data) { return new TorusKnotGeometry(data.radius, data.tube, data.tubularSegments, data.radialSegments, data.p, data.q); } } export { TorusKnotGeometry, TorusKnotGeometry as TorusKnotBufferGeometry };