I'm assuming you mean the Euclidean distance. If you're working in the plane, then the answer is simple.

First, compute the equation of the line in the form

```
ax + by + c = 0
```

In slope-intercept form, this is the same as

```
y = (-a/b)x + (-c/b)
```

Now compute the distance from any point (p,q) to the line by

```
|a*p + b*q + c| / (a^2 + b^2)^(1/2)
```

For more than 2 dimensions, it's probably easiest to think in terms of parametrized vectors. This means think of points on the line as

```
p(t) = (A1 + (B1-A1)*t, A2 + (B2-A2)*t, ..., An + (Bn-An)*t)
```

where the two points are `A = (A1,...,An)`

and `B = (B1,...,Bn)`

. Let `X = (X1,...,Xn)`

be any other point. Then the distance between `X`

and `p(t)`

, the point on the line corresponding to `t`

, is the square root of

```
[(A1-X1) + (B1-A1)t]^2 + ... + [(An-Xn) + (Bn-An)t]^2
```

The distance to the line is the distance to `p(t)`

where `t`

is the unique value minimizing this distance. To compute that, just take the derivative with respect to `t`

and set it to `0`

. It's a very straightforward problem from here, so I'll leave that bit to you.

If you want a further hint, then check out this link for the 3-dimensional case which reduces nicely.