/// <summary> /// /// </summary> /// <param name="start0"></param> /// <param name="end0"></param> /// <param name="mc"></param> /// <param name="start1"></param> /// <param name="end1"></param> /// <param name="mco"></param> private void ComputeOverlaps(int start0, int end0, MonotoneChain mc, int start1, int end1, MonotoneChainOverlapAction mco) { ICoordinate p00 = pts[start0]; ICoordinate p01 = pts[end0]; ICoordinate p10 = mc.pts[start1]; ICoordinate p11 = mc.pts[end1]; // terminating condition for the recursion if (end0 - start0 == 1 && end1 - start1 == 1) { mco.Overlap(this, start0, mc, start1); return; } // nothing to do if the envelopes of these chains don't overlap mco.TempEnv1.Init(p00, p01); mco.TempEnv2.Init(p10, p11); if (!mco.TempEnv1.Intersects(mco.TempEnv2)) { return; } // the chains overlap, so split each in half and iterate (binary search) int mid0 = (start0 + end0) / 2; int mid1 = (start1 + end1) / 2; // Assert: mid != start or end (since we checked above for end - start <= 1) // check terminating conditions before recursing if (start0 < mid0) { if (start1 < mid1) { ComputeOverlaps(start0, mid0, mc, start1, mid1, mco); } if (mid1 < end1) { ComputeOverlaps(start0, mid0, mc, mid1, end1, mco); } } if (mid0 < end0) { if (start1 < mid1) { ComputeOverlaps(mid0, end0, mc, start1, mid1, mco); } if (mid1 < end1) { ComputeOverlaps(mid0, end0, mc, mid1, end1, mco); } } }
/// <summary> /// /// </summary> /// <param name="mc"></param> /// <param name="mco"></param> public virtual void ComputeOverlaps(MonotoneChain mc, MonotoneChainOverlapAction mco) { ComputeOverlaps(start, end, mc, mc.start, mc.end, mco); }