**Given:**

- (X,Y) coordinate, which is the position of a vehicle.
- Array of (X,Y)'s, which are vertices in a polyline. Note that the polyline consists of straight segments only, no arcs.

**What I want:**

- To calculate whether the vehicle is to the left or to the right of the polyline (or on top, ofcourse).

**My approach:**

- Iterate over all line-segments, and compute the distance to each segment. Then for the closest segment you do a simple left-of test (as explained here for instance).

**Possible issues:**

- When three points form an angle smaller than 90 degrees (such as shown in the image blow), a more complicated scenario arises. When the vehicle is in the red segment as shown below, the closest segment can be either one of the two. However, the
*left-of*test will yield*right*if the first segment is chosen as the closest segment, and*left*otherwise. We can easily see (at least, I hope), that the correct result should be that the vehicle is*left*of the polyline.

**My question:**

- How can I
*elegantly*, but mostly*efficiently*take care of this specific situation?

**My fix so far:**

- Compute for both segments a point on that segment, starting from the vertex point.
- Compute the distance from the vehicle to both of the points, using Euclidian distance
- Keep the segment for which the computed point is the closest.

I am not very happy with this fix, because I feel like I am missing a far more elegant solution, my fix feels rather "hacky". Efficiency is key though, because it is used on a realtime embedded system.

Existing codebase is in C++, so if you want to write in a specific language, C++ has my preference. Thanks!

**[edit]**
I changed **my fix**, from a perpendicular point to a parallel point, as I think it is easier to follow the line segment than compute the outward normal.