In general, no there is not a O(n) solution. There is a pixelated version that is better than O(n log n). It is, however, so hobbled in other ways that you'd be crazy to use it in practice.

You render the first polygon (using verts 0, 1, 2) into screen space, then re-render the verts themselves using a distinct ID so they can be identified later. For example, you might clear the frame buffer to RGBA ffffffff and use fffffffe for space that is covered by the convex hull. Each vertex would be rendered using its ID as its RGBA; 00000000, 00000001, etc.

A 16-bit example:

```
fffffffffffffff
fffffff0fffffff
ffffffeeeffffff
fffffeeeeefffff
ffffeeeeeeeffff
fffeeeeeeeeefff
ff2eeeeeeeee1ff
fffffffffffffff
```

Checking a new point is a simple lookup in the current frame buffer. If the pixel it occupies is 'shaded' with polygon or with a vertex ID, the new vertex is rejected.

If the new vertex is outside the existing polygon, you find the first pixel between the new vertex and some point inside the convex hull (something in the middle of the first poly works fine) and march along the circumference of the hull - in both directions - until you find yourself on the far side of the hull from the new vertex. (I'll leave this as an exercise to the user. There are plenty of solutions that all suck, from an efficiency perspective.) Fill in the poly defined by these two points and the new vertex with the ID for polygon space - being careful not to erase any vertex IDs - and go on to the next pixel.

When you're done, any pixel which contains a vertex ID that is not completely surrounded by hull IDs is a convex hull vertex.

While the algorithm's complexity is O(n) with the number of vertices, it's deficiencies are obvious. **Nobody in their right mind would use it unless they had a ridiculous, insane, staggering number of points** to process so that nearly every vertex would be immediately rejected, and unless they could accept the limitation of an aliased result.

Friends don't let friends implement this algorithm.