I just wrote the code for that in n-dimensions. I couldn't find a general solution easily.

```
// considering a rectangle object that contains two points (min and max)
double distance(const rectangle& a, const rectangle& b) const {
// whatever type you are using for points
point_type closest_point;
for (size_t i = 0; i < b.dimensions(); ++i) {
closest_point[i] = b.min[i] > a.min[i] ? a.max[i] : a.min[i];
}
// use usual euclidian distance here
return distance(a, closest_point);
}
```

For calculating the distance between a rectangle and a point you can:

```
double distance(const rectangle& a, const point_type& p) const {
double dist = 0.0;
for (size_t i = 0; i < dimensions(); ++i) {
double di = std::max(std::max(a.min[i] - p[i], p[i] - a.max[i]), 0.0);
dist += di * di;
}
return sqrt(dist);
}
```

If you want to rotate one of the rectangles, you need to rotate the coordinate system.

If you want to rotate both rectangles, you can rotate the coordinate system for rectangle `a`

. Then we have to change this line:

```
closest_point[i] = b.min[i] > a.min[i] ? a.max[i] : a.min[i];
```

because this considers there is only one candidate as the closest vertex in `b`

. You have to change it to check the distance to all vertexes in `b`

. It's always one of the vertexes.

See: https://i.sstatic.net/EKJmr.png