For starters, you pretty much need some implementation of a `Vector3`

class, whether you write your own, find a standalone implementation on the internet somewhere, or use a library that contains one like XNA or Sharp3D.Math.

Typically lines in 3d space are not represented by two points, but by parametric equations and operated on by vectors and not scalars. Your parametric equation would be of the form:

```
x = x1 + t(x2-x1), y = y1 + t(y2-y1), z = z1 + t(z2-z1)
```

The vector **u** is defined by the coefficients of `t`

. <x2-x1, y2-y1, z2-z1>.

The vector **PQ** is defined by your chosen point **Q** minus a point **P** on the line. Any point on the line can be chosen, so it would be simplest to just use the line `t = 0`

, which simplifies to x1, y1, and z1. <x3-x1, y3-y1, z3-z1>

The definition of the shortest distance between a point and a line in 3-space is as follows:

D = ||**PQ** x **u**|| / ||**u**||

Where `x`

is the cross product operator, and `|| ... ||`

gets the magnitude of the contained vector. Depending on which library you choose, your code may vary, but it should be very similar:

```
Vector3 u = new Vector3(x2 - x1, y2 - y1, z2 - z1);
Vector3 pq = new Vector3(x3 - x1, y3 - y1, z3 - z1);
float distance = Vector3.Cross(pq, u).Length / u.Length;
```

**Edit**: I just realized you wanted the actual point of intersection, and not the distance. The formula to find the actual point is a bit different. You need to use inner product space to get the component of **u** perpendicular to **PQ**. To do that, you need to find the component of **u** in the direction of **PQ**:

((**PQ** · **u**) / ||**u**||^2) * **u**

This gets us the **w1** component, but we want **w2**, which is the component between Q and the line:

**PQ** = **w1** + **w2**

**w2** = **PQ** - **w1**

From there, we take **w2** and add it to the point **Q** to get the point on the line nearest **Q**. In code this would be:

```
Vector3 p1 = new Vector3(x1, y1, z1);
Vector3 p2 = new Vector3(x2, y2, z2);
Vector3 q = new Vector3(x3, y3, z3);
Vector3 u = p2 - p1;
Vector3 pq = q - p1;
Vector3 w2 = pq - Vector3.Multiply(u, Vector3.Dot(pq, u) / u.LengthSquared);
Vector3 point = q - w2;
```

Where `point.X`

is `x4`

, `point.Y`

is `y4`

, and `point.Z`

is `z4`

.