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For a well known and important algorithm, it seems quite weird that a C++ ( or .Net) implementation of Bentley-Ottmann Algorithm-- the implementation that can handle all the degenerated cases (i.e, not special assumption on the sweeping line and the number of intersection point and so on)--is simply not available. The only code I can found is here, but it doesn't seem to handle the generalized case.

Is Bentley-Ottmann Algorithm already implemented in any well tested library, such as Boost or LEDA? If yes, may I have the reference to it?

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Ngu, I've once implemented Bentley-Ottmann in Java which handles all corner cases. It has not been used in production code (AFAIK) but I did write a decent amount of unit tests for it. So if you're interested, I could post a link to my little library that has this algorithm. – Bart Kiers Dec 11 '10 at 10:22
The fact that Boost and LEDA don't provide Bentley-Ottmann could be because there are algorithms that out-perform Bentley-Ottmann. AFAIK, Bentley-Ottmann is one of the "easier" algorithms that find all intersections from a set of line segments. – Bart Kiers Dec 11 '10 at 10:27
@Bart, I would be grateful if you could provide me with the Java Link. Also, what are the other line intersection algorithms that are implemented in Boost that outperform Bentley-Ottmann? – Graviton Dec 11 '10 at 10:42
@Ngu, I'm not sure they are in Boost, but while implementing Bentley-Ottmann, I read that there are more difficult ones that are faster than Bentley-Ottmann. If there is such an algorithm in a library like Boost, I would imagine the faster one is included. I will make a release later today and post back here (I was just about to leave now). – Bart Kiers Dec 11 '10 at 10:49
@Ngu would the CGAL implementation help ?… – George Profenza Dec 11 '10 at 13:52
up vote 6 down vote accepted

CGAL has something in there with the same complexity as Bentley-Ottmann, O((n + k)*log(n)) where n is the number of segments and k is the number of intersections (not sure which algorithm they used):

//! \file examples/Arrangement_on_surface_2/sweep_line.cpp
// Computing intersection points among curves using the sweep line.

#include <CGAL/Cartesian.h>
#include <CGAL/MP_Float.h>
#include <CGAL/Quotient.h>
#include <CGAL/Arr_segment_traits_2.h>
#include <CGAL/Sweep_line_2_algorithms.h>
#include <list>

typedef CGAL::Quotient<CGAL::MP_Float>                  NT;
typedef CGAL::Cartesian<NT>                             Kernel;
typedef Kernel::Point_2                                 Point_2;
typedef CGAL::Arr_segment_traits_2<Kernel>              Traits_2;
typedef Traits_2::Curve_2                               Segment_2;

int main()
  // Construct the input segments.
  Segment_2 segments[] = {Segment_2 (Point_2 (1, 5), Point_2 (8, 5)),
                          Segment_2 (Point_2 (1, 1), Point_2 (8, 8)),
                          Segment_2 (Point_2 (3, 1), Point_2 (3, 8)),
                          Segment_2 (Point_2 (8, 5), Point_2 (8, 8))};

  // Compute all intersection points.
  std::list<Point_2>     pts;

  CGAL::compute_intersection_points (segments, segments + 4,
                                     std::back_inserter (pts));

  // Print the result.
  std::cout << "Found " << pts.size() << " intersection points: " << std::endl; 
  std::copy (pts.begin(), pts.end(),
             std::ostream_iterator<Point_2>(std::cout, "\n"));

  // Compute the non-intersecting sub-segments induced by the input segments.
  std::list<Segment_2>   sub_segs;

  CGAL::compute_subcurves(segments, segments + 4, std::back_inserter(sub_segs));

  std::cout << "Found " << sub_segs.size()
            << " interior-disjoint sub-segments." << std::endl;

  CGAL_assertion (CGAL::do_curves_intersect (segments, segments + 4));

  return 0;


Sorry, can't find the reference to a/the (slightly) faster algorithm.

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As suggested in your comment, here is an answer:

CGAL has an implementation for the Bently-Ottmann algorithm, you can find more about it in the Sweep line 2 section in the manual.

four input segments

@Bart already did the extra effort of exposing the implementation.

share|improve this answer has a discussion of the Bentley-Ottmann and Shamos-Hoey algorithms and their relationship. It ends with a c++ implementation based on binary trees. Interesting reference material if you do not want to link to Cgal or boost.

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The C++ implementation isn't really complete, it only has code to show if the line is self-intersecting or not. But not code to find all intersections. – ideasman42 Jul 4 '15 at 9:29

After looking around for this myself and not finding anything I could take and use for my own project - (with the possible exception of CGAL, however this is quite a big library to include for this one function), I decided to write my own reference implementation in Python3.

Its based on, but is written to make it more portable to other languages more easily.

Its a single file and tested to work with complex shapes.

At some point I intend to port this to a compiled language, but for now I'm using this as a test-case to ensure its working as expected.

For the source file see:

Example result: (73002 intersections from 14880 segments).

enter image description here

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