This is easier to conceptualize if you imagine your hexagon as being made up of vectors - lines with a magnitude (distance) and a direction (angle from the west-to-east horizon rotating counterclockwise).

Call the vector from A to B D. If you use some trigonometry to figure out the geometry of a hexagon, D's magnitude is two times the length of the side of the hexagon. So, we can use this to construct vectors that are as large as our other hexagon sides, and thereby get the hexagon's other points.

Take the vector D, halve its magnitude, rotate it 60 degrees ccw and add this new vector to A's position. This gives you P.

Do the same thing but rotate it 60 degrees cw and add this to A's position. This gives you R.

Similarly, Q is the vector D halved, rotated 60 degrees cw, inverted and added to B's position.

Finally, M is the vector D halved, rotated 60 degrees ccw, inverted and added to B's position.

(To convert a vector into x distance moved and y distance moved, multiply the magnitude by the cos of the angle and by the sin of the angle respectively. Make sure you are using radians if radians are needed and degrees if degrees are needed.)