I am in the process of writing a function to test for the intersection of a rectangle with a superellipse. The rectangle will always be axis-aligned whereas the superellipse may be oriented with an angle of rotation alpha.

In the case of an axis-aligned rectangle intersecting an axis-aligned superellipse I have written these two short functions that work beautifully. The code is concise, clear and efficient. If possible, I would like to keep a similar structure for the new more general function.

Here is what I have for detecting if an axis-aligned rectangle intersects an axis-aligned superellipse:

```
double fclamp(double x, double min, double max)
{
if (x <= min) return min;
if (x >= max) return max;
return x;
}
bool rect_intersects_superellipse(const t_rect *rect, double cx, double cy, double rx, double ry, double exponent)
{
t_pt closest;
closest.x = fclamp(cx, rect->x, rect->x + rect->width);
closest.y = fclamp(cy, rect->y, rect->y + rect->height);
return point_inside_superellipse(&closest, cx, cy, rx, ry, exponent);
}
bool point_inside_superellipse(const t_pt *pt, double cx, double cy, double rx, double ry, double exponent)
{
double dx = fabs(pt->x - cx);
double dy = fabs(pt->y - cy);
double dxp = pow(dx, exponent);
double dyp = pow(dy, exponent);
double rxp = pow(rx, exponent);
double ryp = pow(ry, exponent);
return (dxp * ryp + dyp * rxp) <= (rxp * ryp);
}
```

This works correctly but - as I said - only for an axis-aligned superellipse.

Now I would like to generalize it to an oriented superellipse, keeping the algorithm structure as close to the above as possible. The obvious expansion of the previous two functions would then become something like:

```
bool rect_intersects_oriented_superellipse(const t_rect *rect, double cx, double cy, double rx, double ry, double exponent, double radians)
{
t_pt closest;
closest.x = fclamp(cx, rect->x, rect->x + rect->width);
closest.y = fclamp(cy, rect->y, rect->y + rect->height);
return point_inside_oriented_superellipse(&closest, cx, cy, rx, ry, exponent, radians);
}
bool point_inside_oriented_superellipse(const t_pt *pt, double cx, double cy, double rx, double ry, double exponent, double radians)
{
double dx = pt->x - cx;
double dy = pt->y - cy;
if (radians) {
double c = cos(radians);
double s = sin(radians);
double new_x = dx * c - dy * s;
double new_y = dx * s + dy * c;
dx = new_x;
dy = new_y;
}
double dxp = pow(fabs(dx), exponent);
double dyp = pow(fabs(dy), exponent);
double rxp = pow(rx, exponent);
double ryp = pow(ry, exponent);
return (dxp * ryp + dyp * rxp) < (rxp * ryp);
}
```

For an oriented superellipse, the above doesn’t work correctly, even though `point_inside_oriented_superellipse()`

by itself works as expected. I cannot use the above functions to test for an intersection with an axis-aligned rectangle. I have been researching online for about a week now and I have found some solutions requiring an inverse matrix transform to equalize the superellipse axes and bring its origin at (0, 0). The tradeoff is that now my rectangle won’t be a rectangle anymore and certainly not axis-aligned. I would like to avoid going down that route.
My question is to show how to make the above algorithm work keeping its structure more or less unaltered. If it is not possible to keep the same algorithmic structure, please show the simplest, most efficient algorithm to test for the intersection between an axis-aligned rectangle and an oriented superellipse. I only need to know if the intersection occurred or not (boolean result).
The range of the exponent parameter can vary from 0.25 to 100.0.

Thanks for any assistance.