2

I have a series of polygons, represented in 3 vector3 objects. ie:

{
  "a": [1,2],
  "b": [3,4],
  "c": [5,6]
}

Where a,b,c are the three points of a triangle, and the index's 0,1 are x,y respectively.

If this object was in an array, with 50 or so other triangles, each having a shared vertex, what algorithm per se could I potentially run to create some sort of array of indexes of sibling triangles?

3
  • If it's only 50 triangles it doesn't worth the time to over-engineer it. Just check every pair and determine if they are siblings/
    – amit
    Jan 17, 2016 at 21:47
  • Only 1 shared vertex or at least 1? Do you assume that is ever possible to find a sibling triangle with a shared vertex?
    – RevoLab
    Jan 17, 2016 at 21:48
  • @amit - There are about 400+ triangles, used 50 as an arbitrary number being that surely the algorithm should scale? But yeah, maybe like you said there comes a point where you need to optimize the resolution as opposed to brute force. But with that in mind, I need this operation to happen pretty quick. Jan 17, 2016 at 22:40

1 Answer 1

1

If you want to find triangles that share a common vertex, create an object whose keys are the vertices and whose values are arrays of triangles or indices/keys in an array or object of triangles.

Say you have an array of triangles that doesn't change and you store the triangles by index of that array:

var tria = [
    {a: [1, 2], b: [3, 4], c: [0, 6]}, 
    // more triangles ...
];

var adjacent = {};

function addAdjacent(vertex, tria) {
    if (!(vertex in adjacent)) adjacent[vertex] = [];
    adjacent[vertex].push(tria);

}

for (var i = 0; i < tria.length; i++) {
    var t = tria[i];

    addAdjacent(t.a, i);
    addAdjacent(t.b, i);
    addAdjacent(t.c, i);
}

Then you can look up vertices in adjacent and get an array of connected triangles. This function tells you whether two triangles are adjacent. If so, it returns the common node, if not, it returns null:

function isAdjacent(x, y) {
    var t = tria[x];

    if (t.a in adjacent && ~adjacent[t.a].indexOf(y)) return t.a;
    if (t.b in adjacent && ~adjacent[t.b].indexOf(y)) return t.b;
    if (t.c in adjacent && ~adjacent[t.c].indexOf(y)) return t.c;

    return null;
}

If you want to find triangles with common edges, you can use this approach, too. Your key then consists of two vertices. You must find a way to make the ordering of the vertices unique, so that the edge [1, 2], [5, 0] is equivalent to its reverse, [5, 0], [1, 2]. One way to do this is to make the smaller vertex the first point of the edge. (Smaller means the vertex with the smaller x coordinate and if that is equal n both points the vertex with the smaller y coordinate.)

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