All the previous implementations do not use rounding and thus have a large error:
Here's how to do this in fixed point math:
I'm using X.1u prevision (1 LSB is used for fraction part).

```
//center = (max_x + min_x) / 2
center = max_x + min_x // zero error here
// distance = old_x - center
distance = (old_x << 1) - center // zero error here
//new_x = center + (distance * factor)
new_x = (**1** + center + (distance * factor)) >> 1
return new_x
```

If factor is a fixed point (integer) too with N bits describing the fraction then new_x can be calculated as:

```
new_x = ( (1 << N) + (center << N) + (distance * factor) ) >> (N + 1)
```

**(center << N)** has N+1 fraction bits
**distance * factor** has N+1 fraction bits
**(1 << N)** is a 'half' as **1 << (N+1)** is 'one' in the above fixed point precision.

After understanding each part, the above line can be compacted:

```
new_x = ( ((1 + center) << N) + (distance * factor) ) >> (N + 1)
```

The used integer type should be large enough, off course. If the valid range is unknown, one should check the input to this function and something else. In most cases this isn't needed.

This is as good as it get in fixed point math. This is how HW circuits perform integer math operations.

addfloats in order from smallest to largest (in absolute value), so you could expand the expression, sort and then sum. – Kerrek SB Jun 24 '11 at 17:24`float`

to a`double`

or something unbound, etc.) for intermediate calculations can also minimize errors. – user166390 Jun 24 '11 at 17:26`floats`

its around 1e-38). I don't think your problem comes from there. – CygnusX1 Jun 24 '11 at 18:53