Floating-point arithmetic cannot store every number that you want it to. At some point, it has to approximate. Now, I'm guessing, the algorithm you got from Wikipedia is telling you:

```
y=mx+b
```

You know `m`

, you know `b`

, now plug in and make sure the equation holds true. Works great for mathematics. (The square root of 2 ) squared is equal to the square root of 4.

But now imagine you do that on a computer. The square root of 4 will come out exactly as 2, because computers are great at holding small integer numbers. However, your right hand side, the square root of 2, is going to be a bit off. You had to cut off some of the digits of it, so when you squared it, it might be 1.999998 or something like that. To accommodate for this, you need to check that `y is approx. mx+b`

, so:

```
tolerance = .01
x,y
rhs = m*x + b //right hand side
dif = abs(rhs - y)
if dif < tolerance //the point is approximately on the segment
```

Then you'll have to check the bounding box for it (find max x,y, min x,y)

Of course, these methods aren't perfect (http://xkcd.com/217/) but for most practical applications, they will hold true enough. If you REALLY need exact numbers, I would suggest using Wolfram Alpha (I hear there's some API or something) or just writing your own exact number library.

beginandendcoordinates (C algorithm). And one timebeginanddirection/lengthvector (Wikipedia). – Aufziehvogel Feb 24 '13 at 17:11