The only solution for this problem I know of requires `O(n)`

polygon *preprocessing* time. Afterwards each query point against a preprocessed polygon is handled in `O(lg n)`

time.

Just take a point `P`

inside the polygon (let's call it "pole") and for each vertex draw a ray exiting from `P`

and passing through the vertex. Consider this to be a polar coordinate system with origin at `P`

, with the entire polar plane subdivided into sectors by these rays. Now, given your query point, you just need to convert it to polar coordinates with origin at our pole `P`

. Then just perform binary search to determine the specific sector that contains the query point. The final inside/outside check within the sector (point vs. edge side test) is a trivial `O(1)`

operation. Each query is handled in `O(lg n)`

time needed for binary search.

This approach will actually work with a larger class of polygons than just convex ones. It covers the class of so called *star-shaped* polygons, i.e. polygons that have a point from which the whole interior of the polygon can be "seen" or "observed".

The `O(n)`

preprocessing time comes from the need to determine the location of the pole in advance.

**P.S.** I got to carried away thinking about more general case. If your polygon is convex, you can simply use any of its vertices as the pole. That way you get a `O(lg n)`

algorithm right away, no preprocessing required.

anypolygon (not just convex ones) and it is`O(n)`

. In this case the whole point is to come up with`O(lg n)`

algorithm by using the fact that the polygon isconvex. – AndreyT Mar 7 '11 at 19:11`O(n)`

, not`O(log(n))`

. – Bart Kiers Mar 7 '11 at 19:13