Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Having a polygon with no holes and self-intersections defined by N vertices. Choosing a reflex vertex V of this polygon. I need to find any other vertex U of the same polygon which is "visible" from the vertex V. By visible I mean, that a line segment between V and U lies completely inside the polygon.

Is there an algorithm to do that in O(N) time or better? Is there an algorithm that can find all visible vertices in O(N) time?

A quick research suggests that for a given polygon and any point inside this polygon a visibility polygon can be constructed in O(N). I assume that finding a single visible vertex should be even easier.

share|improve this question
    
Well, there's the binary space partition. It allows visibility checks in O(N), but has a much more complicated setup, so it'd only be good for you if you're checking the same polygon repeatedly, and I'm guessing you're not... –  Xavier Holt Nov 17 '12 at 11:17
    
@XavierHolt: Actually I will do that search multiple times for different vertices V, so a setup that is at most O(N*log N) is OK. But a check in O(N) is probably not sufficient. I could do O(N) check without any data structure just by iterating through all edges of the polygon. –  Juraj Blaho Nov 17 '12 at 11:26

5 Answers 5

up vote 2 down vote accepted

This problem was solved 30 years ago:

ElGindy and Avis, "A linear algorithm for computing the visibility polygon from a point", J. Algorithms 2, 1981, p. 186--197.

There is a very nice paper by Joe & Simpson, 1985, "Visibility of a simple polygon from a point," that offers carefully verified pseudocode: (PDF download link). This surely has been implemented many times since, in many languages. For example, there is a link at the Wikipedia article on the topic.

share|improve this answer

You can test any individual vertex in O(n) time, and hence test all vertices in O(n^2). To test any if any individual vertex U is visible from V, construct the line between V and U. Let us call this line L. Now, test L to see if it intersects any of the polygon edges. If it does not, U is not obscured from V. If it does, U is obscured.

Further, you can test if L lies within the polygon like so: Assume the incident edges on V are E1 and E2. Calculate the signed angles between E1 and E2 (call this a1) and between E1 and L (call this a2). The sign of a2 should be the same as a1 (i.e., L is on the 'same' side of E1 as E2 is), and a2 should be smaller than a1 (i.e., L 'comes before' E2).

Be careful with your intersection tests, as L will trivially intersect the polygon edges incident to V. You can ignore these intersections.

Also, if U shares any of the edges incident to V, U is trivially visible from V.

share|improve this answer
1  
Which U should I choose? Your algorithm is O(N^2). –  Juraj Blaho Nov 17 '12 at 11:04
    
Surely, you also need to check that L lies inside the polygon –  panda-34 Nov 17 '12 at 11:06
    
Ah, these are good points. Will re-edit. –  River Nov 17 '12 at 11:09
    
And you should choose the first U that passes the test. –  River Nov 17 '12 at 11:22
    
OK, but after edit it is still O(N^2). I am only interested in O(N) algorithm. –  Juraj Blaho Nov 17 '12 at 11:23

You could use a triangulation of the polygon.

Assuming you have a triangulation T, a set of visible vertices U for a vertex V could be found by examining associated internal edges in the triangulation. Specifically, if the set of triangles attached to V are traversed and the internal edges identified (those that appear twice!), the set U is all edge vertices except V.

Note that this is not necessarily all visible vertices from V, just a set with |U| >= 0 (must be at least one internal edge from V). It is efficient though - only O(m) where m is the number of triangles/edges visited, which is essentially O(1) for reasonable inputs.

Of course, you would need to build a triangulation first. There are efficient algorithms that allow a constrained Delaunay triangulation to be built in O(n*log(n)), but that's not quite O(n). Good constrained Delaunay implementations can be found in Triangle and CGAL.

share|improve this answer
    
Thanks. A valid answer, but I would rather not implement it this way. Implementation of algorithm for triangulation in O(N*log(N)) is not trivial. –  Juraj Blaho Nov 17 '12 at 11:39

Just keep going in some direction through vertices starting with V and update list of visible vertices. If I didn't miss anything, that will be O(n).

For simplicity let's call V visible.

I've tried for a day to put it in words, failed and used pseudo-code :)

visible_vertices = {V}
for each next segment in counter-clockwise polygon traversal
  if segment is counter-clockwise (looking from V)
    if (visible_vertices.last -> segment.end) is counter-clockwise
      visible_vertices.add(segment.end)
  else
    while segment hides visible_vertices.last or segment.start=visible_vertices.last
      visible_vertices.remove_last
share|improve this answer

I've modified the algorithm as it was incorrect. I hope this time it covers all cases!.

Start from a reflex a, let a' the next vertex and follow the polygon until you find an edge that crosses a--a' in the side a', let b the point of intersection of this edge with the line a--a' and c the end point of the edge (the one to the right of a--c).

Now continue going through the edges of the polygon, and if an edge crosses the segment a--b from left to right then set b to the new point of intersection and c to the end vertex. When you finish we have a triangle a--b--c. Now starting again from c look every vertex to see if it is inside the triangle a--b--c and in that case set c to the new vertex. At the end a--c is a diagonal of the polygon.

Here is an implementation in C that assumes that the reflex point a is in P[0]:

struct pt {
    double x,y;
    friend pt operator+(pt a, pt b){a.x+=b.x; a.y+=b.y; return a;}
    friend pt operator-(pt a, pt b){a.x-=b.x; a.y-=b.y; return a;}
    friend pt operator*(pt a, double k){a.x*=k; a.y*=k; return a;}
    bool leftof(pt a, pt b) const{
        // returns true if the *this point is left of the segment a--b.
        return (b.x-a.x)*(y-a.y) - (x-a.x)*(b.y-a.y) > 0;
    }
};
pt intersect(pt a, pt b, pt c, pt d){// (see O'rourke p.222)
    double s,t, denom;
    denom = (a.x-b.x)*(d.y-c.y)+ (d.x-c.x)*(b.y-a.y);
    s = ( a.x*(d.y-c.y)+c.x*(a.y-d.y)+d.x*(c.y-a.y) )/denom;
    return a + (b-a)*s;
}
/**
    P is a polygon, P[0] is a reflex (the inside angle at P[0] is > pi).
    finds a vertex t such that P[0]--P[t] is a diagonal of the polygon.
**/
int diagonal( vector<pt> P ){
    pt a = P[0], b = P[1]; //alias
    int j=2;
    if( !b.leftof(a,P[j]) ){
        // find first edge cutting a--b to the right of b
        for(int k = j+1; k+1 < int(P.size()); ++k)
            if( P[k].leftof(a,b) && P[k+1].leftof(b,a) && b.leftof(P[k+1],P[k]) )
                j = k,
                b = intersect( a,b,P[k],P[k+1] );
        // find nearest edge cutting the segment a--b 
        for(int k = j+1; k+1 < int(P.size()); ++k)
            if( P[k].leftof(a,b) && P[k+1].leftof(b,a) &&
                a.leftof(P[k+1],P[k]) && b.leftof(P[k],P[k+1]) ){
                b = intersect( a,b,P[k],P[k+1] );
                j = k+1;
            }
    }
    for(int k = j+1; k+1 < int(P.size()); ++k)
        if( P[k].leftof(a,b) && P[k].leftof(b,P[j]) && P[k].leftof(P[j],a) )
            j = k;
    return j;
}
share|improve this answer
    
This seems to almost work. But there is a problem when the polygon is winded too much (spiral polygon), the first found vertex c would not be found correctly. Also the check if a d is inside a triangle may be insufficient, because it may block the visibility of c even if it is not in the triangle. –  Juraj Blaho Nov 20 '12 at 9:45

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.