This is not the ultimate solution. This is just a point where you can start from.

**UPD: Here is an extension of this answer, how to form ***contours* from given points.

Also, it's referred to this SO question with awesome anwers from WestLangley and Lee Stemkoski about the `.localToWorld()`

method of `THREE.Object3D()`

.

Let's imagine that you want to find points of intersection of a usual geometry (for example, `THREE.DodecahedronGeometry()`

).

The idea:

`THREE.Plane()`

has the `.intersectLine ( line, optionalTarget )`

method

A mesh contains faces (`THREE.Face3()`

)

Each face has `a, b, c`

properties, where indices of vertices are stored.

When we know indices of vertices, we can get them from the array of `vertices`

When we know coordinates of vertices of a face, we can build three `THREE.Line3()`

objects

When we have three lines, we can check if our plane intersects them.

If we have a point of intersection, we can store it in an array.

Repeat steps 3 - 7 for each face of the mesh

Some explanation with code:

We have `plane`

which is `THREE.PlaneGeometry()`

and `obj`

which is `THREE.DodecahedronGeometry()`

So, let's create a `THREE.Plane()`

:

```
var planePointA = new THREE.Vector3(),
planePointB = new THREE.Vector3(),
planePointC = new THREE.Vector3();
var mathPlane = new THREE.Plane();
plane.localToWorld(planePointA.copy(plane.geometry.vertices[plane.geometry.faces[0].a]));
plane.localToWorld(planePointB.copy(plane.geometry.vertices[plane.geometry.faces[0].b]));
plane.localToWorld(planePointC.copy(plane.geometry.vertices[plane.geometry.faces[0].c]));
mathPlane.setFromCoplanarPoints(planePointA, planePointB, planePointC);
```

Here, three vertices of any face of `plane`

are co-planar, thus we can create `mathPlane`

from them, using the `.setFromCoplanarPoints()`

method.

Then we'll loop through faces of our `obj`

:

```
var a = new THREE.Vector3(),
b = new THREE.Vector3(),
c = new THREE.Vector3();
obj.geometry.faces.forEach(function(face) {
obj.localToWorld(a.copy(obj.geometry.vertices[face.a]));
obj.localToWorld(b.copy(obj.geometry.vertices[face.b]));
obj.localToWorld(c.copy(obj.geometry.vertices[face.c]));
lineAB = new THREE.Line3(a, b);
lineBC = new THREE.Line3(b, c);
lineCA = new THREE.Line3(c, a);
setPointOfIntersection(lineAB, mathPlane);
setPointOfIntersection(lineBC, mathPlane);
setPointOfIntersection(lineCA, mathPlane);
});
```

where

```
var pointsOfIntersection = new THREE.Geometry();
...
var pointOfIntersection = new THREE.Vector3();
```

and

```
function setPointOfIntersection(line, plane) {
pointOfIntersection = plane.intersectLine(line);
if (pointOfIntersection) {
pointsOfIntersection.vertices.push(pointOfIntersection.clone());
};
}
```

In the end we'll make our points visible:

```
var pointsMaterial = new THREE.PointsMaterial({
size: .5,
color: "yellow"
});
var points = new THREE.Points(pointsOfIntersection, pointsMaterial);
scene.add(points);
```

jsfiddle example. Press the button there to get the points of intersection between the plane and the dodecahedron.