It depends on the type of polygon.
If your polygons are convex then an ordered list of vertices will describe one and both separating axis and GJK will be applicable algorithms.
If your polygons are concave but simple (ie, the edges never intersect) then an ordered list of vertices is still sufficient but neither separating axis or GJK is suitable.
If your polygons are complex (ie, edges may intersect) then you'll need the vertex list and a filling rule. The rule established which parts of the plane are considered to be inside the polygon and which are outside.
For example, imagine a polygon like a pentagram:
The difference in filling rules is the difference in whether the five-sided hole in the middle is part of the polygon or simply a hole.
All of the more complicated types of polygon can be broken down into multiple instances of the simpler kinds of polygon so it's quite normal just to put a flag in the ground and declare that you're interested in convex polygons only — that's exactly what GPUs do, for example.
Assuming you're defining collisions as simply whether or not two polygons overlap, the separating axes theorem is very simple and definitely the way to go. If you're planning to produce a scene with lots of polygons then you'll probably also want a broad phase, which is a quick way to flag a whole bunch of polygons as definitely not overlapping before you do the expensive test to find out which of the remainder still are.
An obvious example is bin sorting — suppose you divided your screen into 16 pixel vertical strips then for each polygon you could (i) determine which bins it touches; (ii) test it against all polygons already in those bins; (iii) add it to the bins. That'd probably mean you never even consider applying the test quite a lot of the time. That specific scheme has some obvious problems, depending on your scene, but smarter algorithms exist.