There are many algorithms to solve this and Agnius algorithm works fine. However I prefer the below since it seems more intuitive (you can do it on a piece of paper) and they don't rely on finding the smallest distance between lines but rather the distance between a point and a line.
The hard part is implementing the mathematical functions to find the distance between a line and a point, and to find if a point is facing a line. You can solve all this with simple trigonometry though. I have below the methodologies to do this.
For polygons (triangles, rectangles, hexagons, etc.) in arbitrary angles
- If polygons overlap, return 0
- Draw a line between the centres of the two polygons.
- Choose the intersecting edge from each polygon. (Here we reduce the problem)
- Find the smallest distance from these two edges. (You could just loop through each 4 points and look for the smallest distance to the edge of the other shape).
These algorithms work as long as any two edges of the shape don't create angles more than 180 degrees. The reason is that if something is above 180 degrees then it means that the some corners are inflated inside, like in a star.
Smallest distance between an edge and a point
- If point is not facing the face, then return the smallest of the two distances between the point and the edge cornerns.
- Draw a triangle from the three points (edge's points plus the solo point).
- We can easily get the distances between the three drawn lines with Pythagorean Theorem.
- Get the area of the triangle with Heron's formula.
- Calculate the height now with
Area = 12⋅base⋅height with
base being the edge's length.
Check to see if a point faces an edge
As before you make a triangle from an edge and a point. Now using the Cosine law you can find all the angles with just knowing the edge distances. As long as each angle from the edge to the point is below 90 degrees, the point is facing the edge.
I have an implementation in Python for all this here if you are interested.