Getting towards an auto-dodecahedon detector for the 120-cell

2023-08-19 18:00:19 +10:00 · 2023-08-19 18:00:19 +10:00 · 5a09caef93
parent aa5501e14a
commit 5a09caef93
3 changed files with 116 additions and 509 deletions
--- a/docs/notes_120_cell.md
+++ b/docs/notes_120_cell.md
@ -1,4 +1,43 @@
 Steps forward -
 1. algorithm which, given a face, finds the two dodecahedra it belongs to
 2. using this, generate a list of all 120 dodecahedra:
 [ a b c d e f g h i j k l m n o p q r s t ] <- 20 vertices
 Check that each vertex appears in four of these
 Then - either manually start labelling them, or build an interface to help
 with the manual labelling
 1.
 For a face: there are five edges, and ten other faces sharing an edge.
 These edges are in two sets: one for each dodecahedron. The sets are defined
 by them sharing vertices which aren't in the first face.
 Go around a set of five, by pairs: for each pair, find the other neighbour - 
 this gives the next five faces.
 There's only one face left, which is defined by the shared other vertices of 
 the last five.
 /// old shit below that didn't work VVVV
 Chords: 1.74806 - the 120-cell has 7200 chords of this length
--- a/indexing_attempts/complicated_vectors.js
+++ b/indexing_attempts/complicated_vectors.js
@ -259,3 +259,36 @@ function nice_icosa(nodes, icosa) {
 }
 function find_by_chord(nodesid, n, d) {
 	const EPSILON = 0.02;
 	return Object.keys(nodesid).filter((n1) => {
 		const d2 = dist2(nodesid[n1], nodesid[n]);
 		return Math.abs(d2 - d ** 2) < EPSILON;
 	});
 }
 function has_chord(n1, n2, d) {
 	const d2 = dist2(n1, n2);
 	const EPSILON = 0.01;
 	return Math.abs(d2 - d ** 2) < EPSILON;
 }
 function find_all_chords(nodes) {
 	const chords = {};
 	for( let i = 0; i < nodes.length - 1; i++ ) {
 		for( let j = i + 1; j < nodes.length; j++ ) {
 			const n1 = nodes[i];
 			const n2 = nodes[j];
 			const chord = Math.sqrt(dist2(n1, n2)).toFixed(5);
 			if( !(chord in chords) ) {
 				chords[chord] = [];
 			} 
 			chords[chord].push([n1, n2]);
 		}
 	}
 	return chords;
 }
--- a/testbed.js
+++ b/testbed.js
@ -1,8 +1,5 @@
-// Utilities for generating sets of coordinates based on 
+//testbed for playing with stuff in node repl
 // permutations, even permutations and changes of sign.
 // Based on https://www.qfbox.info/epermute
 const THREE =require('three');
@ -169,93 +166,6 @@ function auto_detect_edges(nodes, neighbours, debug=false) {
 	return links;
 }
 // too small and simple to calculate
 const cell5 = () => {
 	const r5 = Math.sqrt(5);
 	const r2 = Math.sqrt(2) / 2;
 	return {
 		nodes: [
 	      {id:1, x: r2, y: r2, z: r2, w: -r2 / r5 },
 	      {id:2, x: r2, y: -r2, z: -r2, w: -r2 / r5 },
 	      {id:3, x: -r2, y: r2, z: -r2, w: -r2 / r5 },
 	      {id:4, x: -r2, y: -r2, z: r2, w: -r2 / r5 },
 	      {id:5, x: 0, y: 0, z: 0, w: 4 * r2 / r5 },
 		],
 		links: [
 			{ id:1, source:1, target: 2},
 			{ id:2, source:1, target: 3},
 			{ id:3, source:1, target: 4},
 			{ id:4, source:1, target: 5},
 			{ id:5, source:2, target: 3},
 			{ id:6, source:2, target: 4},
 			{ id:7, source:2, target: 5},
 			{ id:8, source:3, target: 4},
 			{ id:9, source:3, target: 5},
 			{ id:10, source:4, target: 5},
 		],
 		geometry: {
 			node_size: 0.02,
 			link_size: 0.02
 		}
 	};
 };
 const cell16 = () => {
 	let nodes = coordinates([1, 1, 1, 1],  0);
 	nodes = nodes.filter((n) => n.x * n.y * n.z * n.w > 0);
 	index_nodes(nodes);
 	scale_nodes(nodes, 0.75);
 	const links = auto_detect_edges(nodes, 6);
 	return {
 		nodes: nodes,
 		links: links,
 		geometry: {
 			node_size: 0.02,
 			link_size: 0.02
 		}
 	};
 };
 const tesseract = () => {
 	const nodes = coordinates([1, 1, 1, 1],  0);
 	index_nodes(nodes);
 	scale_nodes(nodes, Math.sqrt(2) / 2);
 	const links = auto_detect_edges(nodes, 4);
 	return {
 		nodes: nodes,
 		links: links,
 		geometry: {
 			node_size: 0.02,
 			link_size: 0.02
 		}
 	};
 }
 const cell24 = () => {
 	const nodes = coordinates([0, 0, 1, 1], 0);
 	index_nodes(nodes);
 	const links = auto_detect_edges(nodes, 6);
 	return {
 		nodes: nodes,
 		links: links,
 		geometry: {
 			node_size: 0.02,
 			link_size: 0.02
 		}
 	};
 }
 function make_120cell_vertices() {
@ -359,6 +269,49 @@ function auto_120cell_faces(links) {
 }
 // trying to go from faces to dodecahedra
 function shared_vertices(f1, f2) {
 	return f1.nodes.filter((f) => f2.nodes.includes(f));	
 }
 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;
 }
@ -380,426 +333,8 @@ const cell120 = () => {
 function make_600cell_vertices() {
 	const phi = 0.5 * (1 + Math.sqrt(5));  
 	const nodes = [
 		coordinates([0, 0, 0, 2],  0),
 		coordinates([1, 1, 1, 1],  1),
 		coordinates([phi, 1, 1 / phi, 0], 1, true)
 		].flat();
 	index_nodes(nodes);
 	return nodes;
 }
 function find_by_chord(nodesid, n, d) {
 	const EPSILON = 0.02;
 	return Object.keys(nodesid).filter((n1) => {
 		const d2 = dist2(nodesid[n1], nodesid[n]);
 		return Math.abs(d2 - d ** 2) < EPSILON;
 	});
 }
 function has_chord(n1, n2, d) {
 	const d2 = dist2(n1, n2);
 	const EPSILON = 0.01;
 	return Math.abs(d2 - d ** 2) < EPSILON;
 }
 function find_all_chords(nodes) {
 	const chords = {};
 	for( let i = 0; i < nodes.length - 1; i++ ) {
 		for( let j = i + 1; j < nodes.length; j++ ) {
 			const n1 = nodes[i];
 			const n2 = nodes[j];
 			const chord = Math.sqrt(dist2(n1, n2)).toFixed(5);
 			if( !(chord in chords) ) {
 				chords[chord] = [];
 			} 
 			chords[chord].push([n1, n2]);
 		}
 	}
 	return chords;
 }
 const cell600 = () => {
 	const nodes  = make_600cell_vertices();
 	const links = auto_detect_edges(nodes, 12);
 	return {
 		nodes: nodes,
 		links: links,
 		geometry: {
 			node_size: 0.08,
 			link_size: 0.02
 		}
 	}
 }
 // bad stuff
 function find_chords(chords, n) {
 	return chords.filter((c) => c[0].id === n.id || c[1].id === n.id);
 }
 function find_neighbours(chords, n) {
 	const c = find_chords(chords, n);
 	return c.map((c) => c[0].id === n.id ? c[1] : c[0])
 }
 // for a list of pairs [n1, n2] (these are nodes which share a common angle
 // from a center), find all the groups of nodes which don't appear in a pair
 // together
 function partition_nodes(pairs) {
 	let groups = [];
 	const seen = new Set();
 	for( const pair of pairs ) {
 		// both nodes are in a group already
 		if( seen.has(pair[0]) && seen.has(pair[1]) ) {
 			continue;
 		}
 		let already = false;
 		// check if either node is already in a group
 		for( const group of groups ) {
 			if( group.has(pair[0]) ) {
 				group.add(pair[1]);
 				seen.add(pair[1]);
 				already = true;
 				continue;
 			} else if( group.has(pair[1]) ) {
 				group.has(pair[0]);
 				seen.has(pair[0]);
 				already = true;
 				continue;
 			}
 		}
 		// if neither of the pair was in a former group, start a new group
 		if( !already ) {
 			groups.push(new Set(pair));
 		}
 		// collapse any groups which now have common elements
 		groups = collapse_groups(groups);
 	}
 	return groups;
 }
 // given a list of groups, if any have common elements, collapse them
 function collapse_groups(groups) {
 	const new_groups = [ ];
 	for( group of groups ) {
 		let collapsed = false;
 		for( new_group of new_groups ) {
 			const i = intersection(group, new_group);
 			if( i.size > 0 ) {
 				for( const e of group ) {
 					new_group.add(e);
 				}
 				collapsed = true;
 				break;
 			}
 		}
 		if( !collapsed ) {
 			new_groups.push(new Set(group));
 		}
 	}
 	return new_groups;
 }
 function intersection(s1, s2) {
 	const i = new Set();
 	for( const e of s1 ) {
 		if( s2.has(e) ) {
 			i.add(e)
 		}
 	}
 	return i;
 }
 function union(s1, s2) {
 	const u = new Set(s1);
 	for( const e of s2 ) {
 		u.add(e);
 	}
 	return u;
 }
 function vector_angle(n1, n2, n3) {
 	const v1 = new THREE.Vector4(n1.x, n1.y, n1.z, n1.w);
 	const v2 = new THREE.Vector4(n2.x, n2.y, n2.z, n2.w);
 	const v3 = new THREE.Vector4(n3.x, n3.y, n3.z, n3.w);
 	v2.sub(v1);
 	v3.sub(v1);
 	const dp = v2.dot(v3);
 	return Math.acos(dp / ( v2.length() * v3.length()));
 }
 function neighbour_angles_orig(chords, n) {
 	const ns = find_neighbours(chords, n);
 	const angles = {};
 	for( let i = 0; i < ns.length - 1; i++ ) {
 		for( let j = i + 1; j < ns.length; j++ ) {
 			const n2 = ns[i];
 			const n3 = ns[j];
 			const a = THREE.MathUtils.radToDeg(vector_angle(n, n2, n3));
 			const af = (a).toFixed(3);
 			if( ! (af in angles) ) {
 				angles[af] = [];
 			}
 			angles[af].push([n2.id, n3.id]);
 		}
 	}
 	return angles;
 }
 function neighbour_angles(chords, n, angle) {
 	const ns = find_neighbours(chords, n);
 	const pairs = [];
 	for( let i = 0; i < ns.length - 1; i++ ) {
 		for( let j = i + 1; j < ns.length; j++ ) {
 			const n2 = ns[i];
 			const n3 = ns[j];
 			const a = THREE.MathUtils.radToDeg(vector_angle(n, n2, n3));
 			const af = (a).toFixed(3);
 			if( af === angle ) {
 				pairs.push([n2.id, n3.id]);
 			}
 		}
 	}
 	return pairs;
 }
 function make_120_partition(nodes, n) {
 	const chords = find_all_chords(nodes);
 	const chord3 = chords["1.74806"];  // these are edges of the 600-cells;
 	const pairs60 = neighbour_angles(chord3, n, "60.000");
 	const icosas = partition_nodes(pairs60);
 	n.label = 1;
 	const angles = icosa_nodes(nodes, icosas[0]);
 	label_120_partition_r(nodes, chord3, 1, n, angles);
 }
 // recursive function to label a single 600-cell vertex partition of the 
 // 120-cell by following icosahedral nets
 // this doesn't work! completely - labels only 108-112
 function label_120_partition_r(nodes, chords, label, origin, neighbours) {
 	console.log(`label_120_partition_r ${origin.id}`);
 	console.log(neighbours.map((n) => n.id).join(', '));
 	// first try to label everything
 	const unlabelled = [];
 	for( const n of neighbours ) {
 		if( n.label === 0 ) {
 			console.log(`Labelled ${n.id} ${label}`);
 			n.label = label;
 			unlabelled.push(n);
 		} else if( n.label !== label ) {
 			console.log(`node ${n.id} is already in group ${n.label}`);
 			//return false;
 		}
 	}
 	for( const n of unlabelled ) { 
 		// the angles represent two icosahedral pyramids - partition them and
 		// pick the one which is at 60 to the edge we arrived on
 		//console.log(`looking for more neighbors for ${n}`);
 		const pairs60 = neighbour_angles(chords, n, "60.000");
 		const icosas = partition_nodes(pairs60);
 		const icosa = choose_icosa(nodes, origin, n, icosas);
 		const icosa_n = icosa_nodes(nodes, icosa);
 		console.log(`recursing to ${nice_icosa(nodes,icosa)}`);
 		return label_120_partition_r(nodes, chords, label, n, icosa_n);
 	}
 }
 // given a pair of icosa-sets, pick the one which is at the right angle to
 // the incoming vector
 function choose_icosa(nodes, origin, n1, icosas) {
 	for( const icosa of icosas ) {
 		const inodes = icosa_nodes(nodes, icosa);
 		const a60 = inodes.map((ni) => {
 			const a = THREE.MathUtils.radToDeg(vector_angle(n1, origin, ni));
 			return a.toFixed(3);
 		});
 		if( a60.filter((a) => a === "60.000").length > 0 ) {
 			return icosa;
 		}
 	}
 	console.log("No icosa found!");
 	return undefined;
 }
 function icosa_nodes(nodes, icosa) {
 	return Array.from(icosa).map((nid) => node_by_id(nodes, nid)).sort((a, b) => a.id - b.id);
 }
 function node_by_id(nodes, nid) {
 	const ns = nodes.filter((n) => n.id === nid);
 	return ns[0];
 }
 function enumerate_icosas(nodes) {
 	const chords = find_all_chords(nodes);
 	const chord3 = chords["1.74806"];  // these are edges of the 600-cells;
 	for( const n of nodes ) {
 		const pairs60 = neighbour_angles(chord3, n, "60.000");
 		const icosas = partition_nodes(pairs60);
 		for( const icosa of icosas ) {
 			const inodes = icosa_nodes(nodes, icosa);
 			console.log(icosa_to_csv(n.id, inodes).join(','));
 		}
 	}
 }
 function icosa_to_csv(nid, icosa) {
 	const cols = [ nid ];
 	const ia = icosa.map((n) => n.id);
 	for( let i = 1; i < 601; i++ ) {
 		if( ia.includes(i) ) {
 			cols.push(i);
 		} else {
 			cols.push('')
 		}
 	}
 	return cols;
 }
 function start_icosas(nodes, chords, origin) {
 	const pairs60 = neighbour_angles(chords, origin, "60.000");
 	return partition_nodes(pairs60).map((i) => nice_icosa(nodes, i));
 }
 function next_icosa(nodes, chords, origin, nid) {
 	const n = node_by_id(nodes, nid);
 	const pairs60 = neighbour_angles(chords, n, "60.000");
 	const icosas = partition_nodes(pairs60);
 	const icosa = choose_icosa(nodes, origin, n, icosas);
 	return nice_icosa(nodes, icosa);
 }
 function nice_icosa(nodes, icosa) {
 	return icosa_nodes(nodes, icosa).map((n) => n.id).join(', ');
 }
 // New approach with tetrahedral coloring
 function find_edges(links, nid) {
 	return links.filter((l) => l.source === nid || l.target === nid );
 }
 function find_adjacent(links, nid) {
 	return find_edges(links, nid).map((l) => {
 		if( l.source === nid ) {
 			return l.target;
 		} else {
 			return l.source;
 		}
 	});
 }
 function iterate_graph(nodes, links, n, fn) {
 	const queue = [];
 	const seen = {};
 	const nodes_id = {};
 	nodes.map((n) => nodes_id[n.id] = n);
 	queue.push(n.id);
 	seen[n.id] = true;
 	fn(n);
 	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]);
 			}
 		})
 	}
 }
 // stupid tetrahedral labelling
 // keeps getting stuck
 function naive_label_120cell(nodes, links, n) {
 	const nodes_id = {};
 	nodes.map((n) => nodes_id[n.id] = n);
 	iterate_graph(nodes, links, nodes[0], (n) => {
 		const cols = new Set();
 		const nbors = find_adjacent(links, n.id);
 		for( const nb of nbors ) {
 			if( nodes_id[nb].label > 0 ) {
 				cols.add(nodes_id[nb].label);
 			}
 			for( const nb2 of find_adjacent(links, nb) ) {
 				if( nb2 !== n.id && nodes_id[nb].label > 0 ) {
 					cols.add(nodes_id[nb2].label);
 				}
 			}
 		}
 		const pcols = [ 1, 2, 3, 4, 5 ].filter((c) => !cols.has(c));
 		if( pcols.length < 1 ) {
 			console.log(`Got stuck, no options at ${n.id}`);
 			return false;
 		} else {
 			n.label = pcols[0];
 			console.log(`found ${pcols.length} colors for node ${n.id}`);
 			console.log(`applied ${pcols[0]} to node ${n.id}`);
 			return true;
 		}
 	});
 }
 const nodes = make_120cell_vertices();
 const links = auto_detect_edges(nodes, 4);
 const faces = auto_120cell_faces(links);
 console.log('links');
 for( const link of links ) {
 	console.log(link);
 }
 console.log('faces');
 for( const face of faces ) {
 	console.log(face);
 }