fourdjs/label120cell.js

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// code for generating the 120-cell labels
// has some overlap with permute - FIXME
const THREE =require('three');
function pandita(a) {
const n = a.length;
for( let k = n - 2; k >= 0; k-- ) {
if( a[k] < a[k + 1] ) {
for( let l = n - 1; l >= 0; l-- ) {
if( a[k] < a[l] ) {
const tmp = a[k];
a[k] = a[l];
a[l] = tmp;
const revtail = a.slice(k + 1);
revtail.reverse();
for( let i = 0; i < revtail.length; i++ ) {
a[k + 1 + i] = revtail[i];
}
return Math.floor(revtail.length / 2) + 1;
}
}
console.log("Shouldn't get here");
process.exit();
}
}
return false;
}
function permutations_old(a) {
a.sort();
const ps = [ [...a] ];
let running = true;
while( running ) {
const s = pandita(a);
if( s ) {
ps.push([...a]);
} else {
running = false;
}
}
return ps;
}
function permutations(a) {
a.sort();
const ps = [ [...a] ];
let running = true;
while( pandita(a) > 0 ) {
ps.push([...a]);
}
return ps;
}
function permutations_even(a) {
a.sort();
let parity = 'even';
const ps = [ [...a] ];
let running = true;
while( running ) {
const s = pandita(a);
if( s ) {
if( parity === 'even' ) {
if( s % 2 === 1 ) {
parity = 'odd';
}
} else {
if( s % 2 === 1 ) {
parity = 'even';
}
}
if( parity === 'even' ) {
ps.push([...a]);
}
} else {
running = false;
}
}
return ps;
}
// for a given permutation, say [ 1, 1, 0, 0 ], return all
// of the valid changes of sign, so:
// [ [1, 1, 0, 0 ], [ -1, 1, 0, 0 ], [ 1, -1, 0, 0 ], [-1, -1, 0, 0 ]]
// ie don't do it on the zeros
function expand_sign(a, label) {
const expanded = [];
const exv = a.map((v) => v ? [ -v, v ] : [ 0 ]);
for( const xv of exv[0] ) {
for( const yv of exv[1] ) {
for( const zv of exv[2] ) {
for( const wv of exv[3] ) {
expanded.push({label: label, x: xv, y:yv, z:zv, w:wv});
}
}
}
}
return expanded;
}
function coordinates(a, id0=1, even=false) {
const ps = even ? permutations_even(a) : permutations(a);
const coords = [];
for( const p of ps ) {
const expanded = expand_sign(p, 0);
coords.push(...expanded);
}
return coords;
}
function index_nodes(nodes, scale) {
let i = 1;
for( const n of nodes ) {
n["id"] = i;
i++;
}
}
function scale_nodes(nodes, scale) {
for( const n of nodes ) {
for( const a of [ 'x', 'y', 'z', 'w' ] ) {
n[a] = scale * n[a];
}
}
}
function dist2(n1, n2) {
return (n1.x - n2.x) ** 2 + (n1.y - n2.y) ** 2 + (n1.z - n2.z) ** 2 + (n1.w - n2.w) ** 2;
}
export function auto_detect_edges(nodes, neighbours, debug=false) {
const seen = {};
const nnodes = nodes.length;
const links = [];
let id = 1;
for( const n1 of nodes ) {
const d2 = [];
for( const n2 of nodes ) {
d2.push({ d2: dist2(n1, n2), id: n2.id });
}
d2.sort((a, b) => a.d2 - b.d2);
const closest = d2.slice(1, neighbours + 1);
if( debug ) {
console.log(`closest = ${closest.length}`);
console.log(closest);
}
for( const e of closest ) {
const ids = [ n1.id, e.id ];
ids.sort();
const fp = ids.join(',');
if( !seen[fp] ) {
seen[fp] = true;
links.push({ id: id, label: 0, source: n1.id, target: e.id });
id++;
}
}
}
if( debug ) {
console.log(`Found ${links.length} edges`)
}
return links;
}
export function make_120cell_vertices() {
const phi = 0.5 * (1 + Math.sqrt(5));
const r5 = Math.sqrt(5);
const phi2 = phi * phi;
const phiinv = 1 / phi;
const phi2inv = 1 / phi2;
const nodes = [
coordinates([0, 0, 2, 2], 0),
coordinates([1, 1, 1, r5], 0),
coordinates([phi, phi, phi, phi2inv], 0),
coordinates([phiinv, phiinv, phiinv, phi2], 0),
coordinates([phi2, phi2inv, 1, 0], 0, true),
coordinates([r5, phiinv, phi, 0], 0, true),
coordinates([2, 1, phi, phiinv], 0, true),
].flat();
index_nodes(nodes);
// scale_nodes(nodes, 0.5);
return nodes;
}
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// face detection for the 120-cell
// NOTE: all of these return node ids, not nodes
// return all the links which connect to a node
function nodes_links(links, nodeid) {
return links.filter((l) => l.source === nodeid || l.target === nodeid);
}
// filter to remove a link to a given id from a set of links
function not_to_this(link, nodeid) {
return !(link.source === nodeid || link.target === nodeid);
}
// given nodes n1, n2, return all neighbours of n2 which are not n1
function unmutuals(links, n1id, n2id) {
const nlinks = nodes_links(links, n2id).filter((l) => not_to_this(l, n1id));
return nlinks.map((l) => {
if( l.source === n2id ) {
return l.target;
} else {
return l.source;
}
})
}
function fingerprint(ids) {
const sids = [...ids];
sids.sort();
return sids.join(',');
}
export function auto_120cell_faces(links) {
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const faces = [];
const seen = {};
let id = 1;
for( const edge of links ) {
const v1 = edge.source;
const v2 = edge.target;
const n1 = unmutuals(links, v2, v1);
const n2 = unmutuals(links, v1, v2);
const shared = [];
for( const a of n1 ) {
const an = unmutuals(links, v1, a);
for( const d of n2 ) {
const dn = unmutuals(links, v2, d);
for( const x of an ) {
for( const y of dn ) {
if( x == y ) {
shared.push([v1, a, x, d, v2])
}
}
}
}
}
if( shared.length !== 3 ) {
console.log(`Bad shared faces for ${edge.id} ${v1} ${v2}`);
}
for( const face of shared ) {
const fp = fingerprint(face);
if( !seen[fp] ) {
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faces.push({ id: id, edge: edge.id, v1: edge.source, v2: edge.target, fingerprint: fp, nodes: face });
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id++;
seen[fp] = true;
}
}
}
return faces;
}
// trying to go from faces to dodecahedra
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function shared_vertices(f1, f2) {
return f1.nodes.filter((f) => f2.nodes.includes(f));
}
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function adjacent_faces(f1, f2) {
// adjacent faces which share an edge, not just a vertex
const intersect = shared_vertices(f1, f2);
if( intersect.length < 2 ) {
return false;
}
if( intersect.length > 2 ) {
console.log(`warning: faces ${f1.id} and ${f2.id} have too many common vertices`);
}
return true;
}
function find_adjacent_faces(faces, face) {
const neighbours = faces.filter((f) => f.id !== face.id && adjacent_faces(f, face));
return neighbours;
}
function find_dodeca_mutuals(faces, f1, f2) {
// for any two adjacent faces, find their common neighbours where
// all three share exactly one vertex (this, I think, guarantees that
// all are on the same dodecahedron)
const n1 = find_adjacent_faces(faces, f1);
const n2 = find_adjacent_faces(faces, f2);
const common = n1.filter((f1) => n2.filter((f2) => f1.id === f2.id).length > 0 );
// there's one extra here - the third which has two nodes in common with
// both f1 and f2 - filter it out
const mutuals = common.filter((cf) => {
const shared = cf.nodes.filter((n) => f1.nodes.includes(n) && f2.nodes.includes(n));
return shared.length === 1
});
return mutuals;
}
function find_dodeca_next(faces, dodeca, f1, f2) {
// of a pair of mutuals, return the one we haven't already got
const m = find_dodeca_mutuals(faces, f1, f2);
if( dodeca.filter((f) => f.id === m[0].id ).length > 0 ) {
m.shift();
}
return m[0];
}
function faces_to_dodecahedron(faces, f1, f2, flip=false) {
const dodecahedron = [ f1, f2 ];
// take f1 as the 'center', get the other four around it from f2
const fs = find_dodeca_mutuals(faces, f1, f2);
const f3 = flip ? fs[1] : fs[0];
const f6 = flip ? fs[0] : fs[1];
dodecahedron.push(f3);
const f4 = find_dodeca_next(faces, dodecahedron, f1, f3);
dodecahedron.push(f4);
const f5 = find_dodeca_next(faces, dodecahedron, f1, f4);
dodecahedron.push(f5);
dodecahedron.push(f6);
// get the next ring
const f7 = find_dodeca_next(faces, dodecahedron, f6, f2);
dodecahedron.push(f7);
const f8 = find_dodeca_next(faces, dodecahedron, f2, f3);
dodecahedron.push(f8);
const f9 = find_dodeca_next(faces, dodecahedron, f3, f4);
dodecahedron.push(f9);
const f10 = find_dodeca_next(faces, dodecahedron, f4, f5);
dodecahedron.push(f10);
const f11 = find_dodeca_next(faces, dodecahedron, f5, f6);
dodecahedron.push(f11);
// get the last
const f12 = find_dodeca_next(faces, dodecahedron, f7, f8);
dodecahedron.push(f12);
return dodecahedron;
}
// from a face and one neighbouring node, return a dodecahedron
// Set 'flip' to true if we're coming to this dodecahedron from a
// face on a previous one so that the chirality doesn't get inverted
function face_plus_to_dodecahedron(faces, f1, node, flip=false) {
const neighbours = find_adjacent_faces(faces, f1);
const nodens = neighbours.filter((f) => f.nodes.includes(node));
return faces_to_dodecahedron(faces, f1, nodens[0], flip); // does it matter which?
}
// for three faces, return their common vertex (if they have one)
function find_dodeca_vertex(f1, f2, f3) {
const v12 = f1.nodes.filter((n) => f2.nodes.includes(n));
const v123 = v12.filter((n) => f3.nodes.includes(n));
if( v123.length === 1 ) {
return v123[0];
} else {
console.log(`warning: faces ${f1.id} ${f2.id} ${f3.id} don't share 1 vertex`);
return false;
}
}
const VERTEX_MAP = [
[ 0, 1, 5 ],
[ 0, 1, 2 ],
[ 0, 2, 3 ],
[ 0, 3, 4 ],
[ 0, 4, 5 ],
[ 1, 5, 6 ],
[ 1, 2, 7 ],
[ 2, 3, 8 ],
[ 3, 4, 9 ],
[ 4, 5, 10 ],
[ 1, 6, 7 ],
[ 2, 7, 8 ],
[ 3, 8, 9 ],
[ 4, 9, 10 ],
[ 5, 6, 10 ],
[ 6, 7, 11 ],
[ 7, 8, 11 ],
[ 8, 9, 11 ],
[ 9, 10, 11 ],
[ 6, 10, 11 ],
];
function dodecahedron_vertices(faces) {
const face_sets = VERTEX_MAP.map((vs) => vs.map((v) => faces[v]));
return face_sets.map((fs) => find_dodeca_vertex(...fs));
}
// p is the permutation of the first face
function dodecahedron_colours(vertices, p) {
const LEFT_PART = [
1, 2, 3, 4, 5, 3, 4, 5, 1, 2, 5, 1, 2, 3, 4, 2, 3, 4, 5, 1,
];
const RIGHT_PART = [
1, 2, 3, 4, 5, 4, 5, 1, 2, 3, 3, 4, 5, 1, 2, 1, 2, 3, 4, 5,
];
const part = LEFT_PART;
const colours = {};
for( let i = 0; i < 20; i++ ) {
const v = vertices[i];
const colour = p[part[i] - 1];
colours[v] = colour;
}
return colours;
}
// p is the permutation of the first face
function colour_dodecahedron_from_face(dd, p) {
const vertices = dodecahedron_vertices(dd);
return dodecahedron_colours(vertices, p);
}
// from a dodecahedron and a face, get the adjoining dodecahedron
function follow_face_to_dodeca(faces, startdd, nextf, flip=false) {
const neighbours = find_adjacent_faces(faces, nextf);
const nextnbors = neighbours.filter((f) => !startdd.includes(f));
return faces_to_dodecahedron(faces, nextf, nextnbors[0], flip);
}
function find_edges(links, nid) {
return links.filter((l) => l.source === nid || l.target === nid );
}
function find_adjacent_nodes(links, nid) {
return find_edges(links, nid).map((l) => {
if( l.source === nid ) {
return l.target;
} else {
return l.source;
}
});
}
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function node_by_id(nodes, nid) {
const ns = nodes.filter((n) => n.id === nid);
return ns[0];
}
function find_adjacent_labels(nodes, links, nid) {
return find_adjacent_nodes(links, nid).map(
(nid) => node_by_id(nodes, nid).label
);
}
function colour_next_dodeca_maybe(nodes, links, faces, colours, dd, nextf, nextdd) {
const lastvs = dodecahedron_vertices(dd);
const nextvs = dodecahedron_vertices(nextdd);
// get the initial colour permutations from the existing labels;
const p = [];
for( let i = 0; i < 5; i ++ ) {
p[i] = colours[nextvs[i]];
}
const nlabels = colour_dodecahedron_from_face(nextdd, p);
// check if this is inconsistent with the original dd
const n = nextf.nodes[0];
const nbors = find_adjacent_nodes(links, n);
const nextns = nbors.filter((n) => !lastvs.includes(n));
const lastns = nbors.filter((n) => !nextvs.includes(n));
const lastcol = colours[lastns[0]];
const nextcol = nlabels[nextns[0]];
if( lastcol === nextcol ) {
// one node in the adjoining face has two same-coloured neighbours
// console.log('chirality mismatch');
// console.log(` test node ${n}`);
// console.log(` neighbours ${lastns[0]} ${nextns[0]}`);
return false;
}
return nlabels;
}
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function meridian(nodes, links, faces, startf, startn, dir=11, max=10) {
const o = face_plus_to_dodecahedron(faces, startf, startn);
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const colours = colour_dodecahedron_from_face(o, [ 1, 2, 3, 4, 5 ] );
const dds = follow_meridian(nodes, links, faces, colours, o, dir, max);
const labels = { 1: [], 2:[], 3:[], 4:[], 5:[] };
for( const vstr in colours ) {
labels[colours[vstr]].push(Number(vstr));
}
return { dodecahedra: dds, labels: labels };
}
function all_meridians(nodes, links, faces, startf, startn) {
const o = face_plus_to_dodecahedron(faces, startf, startn);
const colours = colour_dodecahedron_from_face(o, [ 1, 2, 3, 4, 5 ] );
// first meridian
const dds = follow_meridian(nodes, links, faces, colours, o, 11, 10);
for ( const f of [ 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 ] ) {
follow_meridian(nodes, links, faces, colours, o, f, 4);
}
const labels = { 1: [], 2:[], 3:[], 4:[], 5:[] };
for( const vstr in colours ) {
labels[colours[vstr]].push(Number(vstr));
}
return labels;
}
// go along a meridian
// modifies colours
function follow_meridian(nodes, links, faces, colours, odd, dir, max) {
let ncolours = {};
const dds = [ odd ];
while( ncolours && dds.length < max ) {
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const dd = dds[dds.length - 1];
const nextf = dds.length === 1 ? dd[dir] : dd[11];
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let nextdd = follow_face_to_dodeca(faces, dd, nextf);
ncolours = colour_next_dodeca_maybe(nodes, links, faces, colours, dd, nextf, nextdd);
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if( !ncolours ) {
nextdd = follow_face_to_dodeca(faces, dd, nextf, true);
ncolours = colour_next_dodeca_maybe(nodes, links, faces, colours, dd, nextf, nextdd);
if( !ncolours ) {
console.log("*** two mismatches");
}
}
for( const vertex in ncolours ) {
if( vertex in colours ) {
if( colours[vertex] !== ncolours[vertex] ) {
console.log(`*** label mismatch at ${vertex}: ${colours[vertex]}/${ncolours[vertex]}`);
}
} else {
colours[vertex] = ncolours[vertex];
}
}
dds.push(nextdd);
}
return dds;
}
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function follow_and_colour(nodes, links, faces, colours, dd, face) {
let nextdd = follow_face_to_dodeca(faces, dd, face);
let ncolours = colour_next_dodeca_maybe(nodes, links, faces, colours, dd, face, nextdd);
if( !ncolours ) {
nextdd = follow_face_to_dodeca(faces, dd, face, true);
ncolours = colour_next_dodeca_maybe(nodes, links, faces, colours, dd, face, nextdd);
if( !ncolours ) {
console.log("two mismatches");
}
}
return [ nextdd, ncolours ];
}
function add_colours(colours, ncolours) {
for( const vertex in ncolours ) {
if( vertex in colours ) {
if( colours[vertex] !== ncolours[vertex] ) {
console.log(`label mismatch at ${vertex}: ${colours[vertex]}/${ncolours[vertex]}`);
}
} else {
colours[vertex] = ncolours[vertex];
}
}
}
// "arctic circle" - this one works
function arctic(nodes, links, faces, startf, startn, max) {
console.log(startf);
const pole = face_plus_to_dodecahedron(faces, startf, startn);
const dds = [ pole ];
// colour first cell
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const colours = colour_dodecahedron_from_face(dds[0], [ 1, 2, 3, 4, 5 ] );
const vs = dodecahedron_vertices(dds[0]);
let ncolours = {};
for( const face of pole ) {
let nextdd = follow_face_to_dodeca(faces, pole, face);
ncolours = colour_next_dodeca_maybe(nodes, links, faces, colours, pole, face, nextdd);
if( !ncolours ) {
nextdd = follow_face_to_dodeca(faces, pole, face, true);
ncolours = colour_next_dodeca_maybe(nodes, links, faces, colours, pole, face, nextdd);
if( !ncolours ) {
console.log("two mismatches");
}
}
for( const vertex in ncolours ) {
if( vertex in colours ) {
if( colours[vertex] !== ncolours[vertex] ) {
console.log(`label mismatch at ${vertex}: ${colours[vertex]}/${ncolours[vertex]}`);
}
} else {
colours[vertex] = ncolours[vertex];
}
}
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dds.push(nextdd);
}
const labels = { 1: [], 2:[], 3:[], 4:[], 5:[] };
for( const vstr in colours ) {
labels[colours[vstr]].push(Number(vstr));
}
return { dodecahedra: dds, labels: labels };
}
// this is the one that works
export function label_120cell(nodes, links, faces, startf, startn) {
const pole = face_plus_to_dodecahedron(faces, startf, startn);
const dds = [ pole ];
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const seen = {};
seen[dd_fingerprint(pole)] = true;
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const colours = colour_dodecahedron_from_face(dds[0], [ 1, 2, 3, 4, 5 ] );
const vs = dodecahedron_vertices(dds[0]);
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for( const face of pole ) {
const [ nextdd, ncolours ] = follow_and_colour(
nodes, links, faces, colours, pole, face
);
add_colours(colours, ncolours);
dds.push(nextdd);
seen[dd_fingerprint(nextdd)] = true;
}
// go around all of the arctic circle and grow all faces
// 1, 12, 20, 12, 30 = 75
// 0 1 13, 33, 45
for( const a of dds.slice(1, 13) ) {
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for( const i of [ 6, 7, 8, 9, 10 ] ) {
const [ nextdd, ncolours ] = follow_and_colour(
nodes, links, faces, colours, a, a[i]
);
const fp = dd_fingerprint(nextdd);
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if( !(fp in seen) ) {
add_colours(colours, ncolours);
dds.push(nextdd);
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seen[fp] = true;
}
}
}
// meridians = 45
for( const a of dds.slice(1, 13) ) {
const [ nextdd, ncolours ] = follow_and_colour(
nodes, links, faces, colours, a, a[11]
);
const fp = dd_fingerprint(nextdd);
if( !(fp in seen) ) {
add_colours(colours, ncolours);
dds.push(nextdd);
seen[fp] = true;
}
}
// the 30 equatorials?
for( const a of dds.slice(13, 46) ) {
for( const i of [ 6, 7, 8, 9, 10 ] ) {
const [ nextdd, ncolours ] = follow_and_colour(
nodes, links, faces, colours, a, a[i]
);
const fp = dd_fingerprint(nextdd);
if( !(fp in seen) ) {
add_colours(colours, ncolours);
dds.push(nextdd);
seen[fp] = true;
}
}
}
for( const a of dds.slice(33, 76) ) {
for( const i of [ 6, 7, 8, 9, 10 ] ) {
const [ nextdd, ncolours ] = follow_and_colour(
nodes, links, faces, colours, a, a[i]
);
const fp = dd_fingerprint(nextdd);
if( !(fp in seen) ) {
add_colours(colours, ncolours);
dds.push(nextdd);
seen[fp] = true;
}
}
}
// this should get the rest or explode!
for( const a of dds ) {
for( const i of [ 6, 7, 8, 9, 10 ] ) {
const [ nextdd, ncolours ] = follow_and_colour(
nodes, links, faces, colours, a, a[i]
);
const fp = dd_fingerprint(nextdd);
if( !(fp in seen) ) {
add_colours(colours, ncolours);
dds.push(nextdd);
seen[fp] = true;
}
}
}
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const labels = { 1: [], 2:[], 3:[], 4:[], 5:[] };
for( const vstr in colours ) {
labels[colours[vstr]].push(Number(vstr));
}
return { dodecahedra: dds, labels: labels };
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}
// for a face, pick an edge, and then find the other two faces which
// share this edge. These can be used as the starting points for the
// first face's two dodecahedra
function find_edge_neighbours(faces, face) {
const n1 = face.nodes[0];
const n2 = face.nodes[1];
return faces.filter((f) => f.id !== face.id && f.nodes.includes(n1) && f.nodes.includes(n2));
}
// each face is in two dodecahedra: this returns them both
function face_to_dodecahedra(faces, f) {
const edge_friends = find_edge_neighbours(faces, f);
const d1 = make_dodecahedron(faces, f, edge_friends[0]);
const d2 = make_dodecahedron(faces, f, edge_friends[1]);
return [ d1, d2 ];
}
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// brute-force calculation of all dodecahedra
function dd_fingerprint(dodecahedron) {
const ids = dodecahedron.map((face) => face.id);
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ids.sort((a, b) => a - b);
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return ids.join(',');
}
function make_120cell_cells(faces) {
const dodecas = [];
const seen = {};
let i = 1;
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for( const face of faces ) {
const dds = face_to_dodecahedra(faces, face);
for( const dd of dds ) {
const fp = dd_fingerprint(dd);
if( ! (fp in seen) ) {
const d = {
id: i,
faces: dd,
nodes: dodecahedron_vertices(dd),
}
dodecas.push(d);
i += 1;
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seen[fp] = 1;
}
}
}
return dodecas;
}
function dodeca_travers(nodes, links, n, fn) {
const queue = [];
const seen = {};
const nodes_id = {};
queue.push(n.id);
while( queue.length > 0 ) {
const v = queue.shift();
find_adjacent(links, v).map((aid) => {
if( !(aid in seen) ) {
seen[aid] = true;
queue.push(aid);
fn(nodes_id[aid]);
}
})
}
}
const cell120 = () => {
const nodes = make_120cell_vertices();
const links = auto_detect_edges(nodes, 4);
return {
nodes: nodes,
links: links,
geometry: {
node_size: 0.02,
link_size: 0.02
}
}
}
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function dodeca_nodes(dd) {
const ns = new Set();
for( const face of dd.faces ) {
for( const node of face.nodes ) {
ns.add(node);
}
}
dd.nodes = Array.from(ns);
}
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function label_nodes(nodes, ids, label) {
nodes.filter((n) => ids.includes(n.id)).map((n) => n.label = label);
}
function meridian_label_120cell(nodes) {
const MERIDIAN_COLOURED ={"1":[27,38,49,61,68,74,87,105,120,126,131,140,149,156,165,174,179,185,200,207,210,218,223,226,231,234,239,241,253,258,263,265,272,274,279,284,285,289,296,300,301,306,311,313,320,324,325,331,334,339,342,347,350,356,357,367,369,376,378,383,388,389,393,400,413,414,419,420,425,440,449,453,458,460,469,471,473,474,487,488,490,494,499,503,511,512,513,514,525,527,530,532,539,543,546,550,555,558,563,566,572,573,580,581,592,593],"2":[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,18,19,21,22,23,24,25,28,30,31,34,35,37,40,41,46,47,50,51,53,56,57,60,62,63,66,67,69,72,73,76,78,83,85,88,90,93,97,103,106,107,109,112,113,116,118,119,122,123,125,129,132,134,135,138,139,141,144,145,148,150,151,155,157,160,161,164,166,167,170,171,173,177,180,182,183,187,189,192,193,196,198,202,203,205,208,209,212,214,215],"3":[26,39,45,52,64,65,94,99,108,117,127,130,137,152,153,168,175,178,188,197,206,211,219,222,227,230,235,238,245,251,268,269,273,280,283,286,292,293,299,302,305,312,316,317,321,328,330,335,349,355,358,363,366,370,375,377,384,385,392,394,399,404,405,415,416,417,418,426,437,439,441,445,452,456,457,459,470,472,475,485,486,491,495,498,502,509,510,515,516,526,529,531,538,542,547,551,554,559,562,567,569,576,577,584,588,597],"4":[32,33,43,54,58,71,77,84,101,110,115,121,136,143,146,159,162,169,184,204,213,220,221,228,229,236,237,249,260,261,271,276,277,281,288,290,295,297,304,308,309,315,318,322,327,329,336,340,341,351,354,359,361,368,371,374,379,382,387,390,396,397,409,410,423,424,430,433,435,443,447,450,454,461,463,466,468,477,478,483,484,489,493,500,504,507,508,517,518,522,533,535,540,544,545,549,553,560,561,568,570,583,587,590,595,598],"5":[29,36,42,55,59,70,80,81,89,111,114,133,142,147,163,181,191,194,201,216,217,224,225,232,233,240,243,246,255,267,270,275,278,282,287,291,294,298,303,307,310,314,319,323,326,332,333,337,344,345,352,353,360,364,365,372,373,380,381,395,398,402,407,411,412,421,422,429,436,442,446,451,455,462,464,465,467,479,481,482,492,496,497,501,505,506,519,520,521,523,534,536,537,541,548,552,556,557,564,565,574,579,586,591,594,599]};
for( const cstr in MERIDIAN_COLOURED ) {
label_nodes(nodes, MERIDIAN_COLOURED[cstr], Number(cstr));
}
//label_nodes(nodes, [313], 6);
}
function check_120cell_nodes(nodes) {
nodes.map((n) => {
const vs = find_adjacent_labels(nodes, links, n.id);
vs.push(n.label);
console.log(`Node ${n.id} and neighbours ${vs}`);
const fp = vs.sort().join(',');
if( fp !== "1,2,3,4,5" ) {
console.log(`Label error ${n.id} ${fp}`)
}
});
}
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function make_dodecahedron_vertices() {
const phi = 0.5 * (1 + Math.sqrt(5));
const phiinv = 1 / phi;
const nodes = [
{ x: 1, y: 1, z: 1, w: 0 },
{ x: 1, y: 1, z: -1, w: 0 },
{ x: 1, y: -1, z: 1, w: 0 },
{ x: 1, y: -1, z: -1, w: 0 },
{ x: -1, y: 1, z: 1, w: 0 },
{ x: -1, y: 1, z: -1, w: 0 },
{ x: -1, y: -1, z: 1, w: 0 },
{ x: -1, y: -1, z: -1, w: 0 }
].flat();
scale_nodes(nodes, 0.5);
return nodes;
}
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// const nodes = make_120cell_vertices();
// const links = auto_detect_edges(nodes, 4);
// const faces = auto_120cell_faces(links);
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// console.log("Calculating 120-cell colours")
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// const a2 = arctic_two(nodes, links, faces, faces[0], 341)
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// console.log(`got ${a2.dodecahedra.length}`);
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// const labels = a2.labels;
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// console.log("labelling nodes");
// for( const cstr in labels ) {
// label_nodes(nodes, labels[cstr], Number(cstr));
// }
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