There are many ways you could do this; here's one simple way.

Imagine a circle of radius *R* centred on the origin, and a square of side *2R* centred on the origin, we want to map all of the points within and on the boundary of the circle (with coordinates *(x,y)*) to points within and on the boundary of the square. Note that we can also describe points within the circle using polar coordinates *(r, ø)* (that's supposed to be a phi), where

x = r cos ø,

y = r sin ø

(ie *r^2 = x^2 + y^2* and *r <= 1*). Then imagine other coordinates *x' = a(ø) x = a(ø) r cos ø*, and *y' = a(ø) y* (ie, we decide that *a* won't depend on *r*).

In order to map the boundary of the circle (*r = 1*) to the boundary of the square (*x' = R*), we must have, for *ø < 45deg*, *x' = a(ø) R cos ø = R*, so we must have *a(ø) = 1/cos ø*. Similarly, for *45 < ø < 90* we must have the boundary of the circle map to *y' = R*, giving *a(ø) = 1/sin ø* in that region. Continuing round the circle, we see that *a(ø)* must always be positive, so the final mapping from the circle to the square is

x' = a(ø) x,

y' = a(ø) y

where

*ø* = |arctan *y/x*| = arctan |*y/x*|

and

*a(ø) = 1/cos ø*, when *ø* <= 45 deg (ie, when *x < y*), and

*a(ø) = 1/sin ø*, when *ø* > 45 deg.

That immediately gives you the mapping in the other direction. If you have coordinates *(x', y')* on the square (where *x' <= R* and *y' <= R*), then

*x = x'/a(ø)*

*y = y'/a(ø)*

with *a(ø)* as above.

A much simpler mapping, though, is to calculate the *(r, ø)* for the desired position on the circle, and map that to *x' = r* and *y' = ø*. That also maps every point in the circle into a rectangle, and vice versa, and might have better properties, *depending on what you want to do*.

So that's the real question: what is it you're actually aiming to do here?