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I was asked this Interview Question (C++,algos)and had no idea how to solve it.

Given an array say Arr[N] containing Cartesian coordinates of N distinct points count the number of triples (Arr[P], Arr[Q], Arr[R]) such that P < Q < R < N and the points Arr[P], Arr[Q], Arr[R] are collinear (i.e lie on the same straight line).

Any ideas? What algorithm can I use for this?

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1  
+1 Nice question. –  Nawaz Aug 20 '11 at 11:11
3  
I assume you're looking for something better than just brute force? –  john Aug 20 '11 at 11:13
    
Yes. I am looking for worst case time complexity of O(N2log(N)) –  user7 Aug 20 '11 at 11:16

5 Answers 5

up vote 6 down vote accepted

The following is probably not optimized, but its complexity is the one your interviewer requested.

First create a list of (a,b,c) values for each couple of points (N² complexity) --> (a,b,c) stands for the cartesian equation of a straight line a*x+b*y+c=0 Given two points and their coordinates (xa, ya) and (xb, yb), computing (a,b,c) is simple. Either you can find a solution to

ya=alpha*xa+beta  
yb=alpha*xb+beta

(if (xb-xa) != 0)
alpha = (yb-ya)/(xb-xa)
beta = ya - alpha*xa
a = alpha
b = -1
c = beta

or to

xa = gamma*ya+delta
xb = gamma*yb+delta
(you get the point)

The solvable set of equations can then be rewritten in the more general form

a*x+b*y+c = 0

Then sort the list (N² log(N²) complexity therefore N²log(N) complexity).

Iterate over elements of the list. If two sequential elements are equal, corresponding points are collinear. N² complexity.

You might want to add a last operation to filter duplicate results, but you should be fine, complexity-wise.

EDIT : i updated a bit the algorithm while coding it to make it more simple and optimal. Here it goes.

#include <map>
#include <set>
#include <vector>
#include <iostream>

struct StraightLine
{
    double a,b,c;
    StraightLine() : a(0.),b(0.),c(0.){}
    bool isValid() { return a!=0. || b!= 0.; }
    bool operator<(StraightLine const& other) const
    {
        if( a < other.a ) return true;
        if( a > other.a ) return false;
        if( b < other.b ) return true;
        if( b > other.b ) return false;
        if( c < other.c ) return true;
        return false;
    }
};

struct Point { 
    double x, y; 
    Point() : x(0.), y(0.){}
    Point(double p_x, double p_y) : x(p_x), y(p_y){}
};

StraightLine computeLine(Point const& p1, Point const& p2)
{
    StraightLine line;
    if( p2.x-p1.x != 0.)
    {
        line.b = -1;
        line.a = (p2.y - p1.y)/(p2.x - p1.x);
    }
    else if( p2.y - p1.y != 0. )
    {
        line.a = -1;
        line.b = (p2.x-p1.x)/(p2.y-p1.y);
    }
    line.c = - line.a * p1.x - line.b * p1.y;
    return line;
}

int main()
{
    std::vector<Point> points(9);
    for( int i = 0 ; i < 3 ; ++i )
    {
        for( int j = 0; j < 3 ; ++j )
        {
            points[i*3+j] = Point((double)i, (double)j);
        }
    }


    size_t nbPoints = points.size();
    typedef std::set<size_t> CollinearPoints;
    typedef std::map<StraightLine, CollinearPoints> Result;
    Result result;

    for( int i = 0 ; i < nbPoints ; ++i )
    {
        for( int j = i + 1 ; j < nbPoints ; ++j )
        {
            StraightLine line = computeLine(points[i], points[j]);
            if( line.isValid() )
            {
                result[line].insert(i);
                result[line].insert(j);
            }
        }
    }

    for( Result::iterator currentLine = result.begin() ; currentLine != result.end(); ++currentLine )
    {
        if( currentLine->second.size() <= 2 )
        {
            continue;
        }
        std::cout << "Line";
        for( CollinearPoints::iterator currentPoint = currentLine->second.begin() ; currentPoint != currentLine->second.end() ; ++currentPoint )
        {
            std::cout << " ( " << points[*currentPoint].x << ", " << points[*currentPoint].y << ")";
        }
        std::cout << std::endl;
    }
    return 0;
}
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1  
Can you tell me how I can go about computing a,b,c ? –  user7 Aug 20 '11 at 11:46
    
still don't get it..call me dumb but u'll have to break it down for me.. –  user7 Aug 20 '11 at 12:34
    
thank you for the explanation! –  user7 Aug 20 '11 at 13:28
    
Now all I have to do is code the whole thing.How do I convert the step "Iterate over elements of the list. If two sequential elements are equal, corresponding points are collinear" into code? Can you explain the pseudocode? –  user7 Aug 20 '11 at 13:43
    
Store the elements (a,b,c) with the points they refer to, as in struct CollinearElement{ int a; int b; int c; Point p1; Point p2; }; Create an operator < which can compare CollinearElement objects. If you don't know how to iterate over elements of a list, you probably need to read some standard library (STL) documentation. –  Benoît Aug 21 '11 at 0:25

Instead of 3 loops, whish is O(n³), precompute the slopes of all lines given by two points Arr[P], Arr[Q]. That's O(n²). Then compare these slopes.

You can improve that further sorting the lines by their slope during computation or afterwards, which is O(n log n). After that finding lines with the same slope is O(n).

But you may have to pay a price for that by implementing a data structure, when you want to know, which points are collinear.

I think the key point of an interview question is not to give the perfect algorithm, but to identify and discuss the problems within an idea.

Edit:

Brute force approach:

#include <iostream>
#include <vector>

struct Point { int x, y; };
bool collinear(Point P, Point Q, Point R)
{
  // TODO: have to look up for math ... see icCube's answer
  return false; 
}

int main()
{
  std::vector<Point> v;

  Point a;
  while (std::cin >> a.x >> a.y)
  {
    v.push_back(a);
  }

  int count = 0;
  for (int p = 0; p < v.size(); ++p)
  {
    for (int q = p+1; q < v.size(); ++q)
    {
      for (int r = q+1; r < v.size(); ++r)
      {
        if (collinear(v[p], v[q], v[r])) ++count;
      }
    }  
  }
  std::cout << count << '\n';
  return 0;
}
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1  
Trust me. the key point was not to discuss. I was asked to write a compilable program that was verified by an online judge for efficiency and correctness. –  user7 Aug 20 '11 at 11:34
    
@user639309: Oh, it's about real code? Adjusted my answer for that. –  René Richter Aug 20 '11 at 12:01
    
thank you for the brute force approach. I would have still liked to find an optimal solution. –  user7 Aug 20 '11 at 12:02
    
@user639309: Well ..., will I get that job then? –  René Richter Aug 20 '11 at 12:32
    
of course. However the online judge gave full marks to the optimal solution only.. –  user7 Aug 20 '11 at 12:55

If it's 2 dimension points: 3 points (P,Q,R) are collinear if (P,Q), (P,R) define the same slope.

m = (p.x - q.x) / (p.y - q.y)  ; slope

Somehow you need to check all possible combinations and check, an efficient algo is trick as the first naive is N*(N-1)*(N-2)...

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It's trivial to see that you can get all the pairs of points and their slope & y-intercepts in O(n^2) time. So the output is:

IndexB Slope Y-Intercept IndexA

Of course, we won't insert any entries where IndexA = IndexB.

Let's have this table indexed on (IndexB,Slope,Y), which forces our insert into this table as O(log(n))

After we fill out this table with new records (B',S',Y',A'), we check to see if we already have an element such that B'=A of the existing table and B!=A' of the new record (meaning we have a unique triplet) that matches the slope and Y-intercept (meaning collinear). If this is the case and A < B < B', increment the count by 1.

EDIT: One clarifying remark. We need to make sure that we fill this table "backwards" first, taking all the pairs that wouldn't satisfy A < B (< C). This ensures that they will exist in the table before we start testing for their existence.

EDIT: Wow my C++ is rusty... took a while.

#include <iostream>
#include <vector>
#include <set>
#include <stdlib.h>
#include <math.h>

using namespace std;

#define ADD_POINT(xparam,yparam) { point x; x.x = xparam; x.y = yparam; points.push_back(x); };

#define EPSILON .001

class line {
public:
  double slope;
  double y;
  int a;
  int b;

  bool operator< (const line &other) const{
    if(this->a < other.a)
      return true;
    else if(this->a==other.a){
      if(this->slope-other.slope < -EPSILON)
        return true;
      else if(fabs(this->slope-other.slope) < EPSILON){
        if(this->y-other.y < -EPSILON)
          return true;
        else
          return false;
      }else
        return false;
    }else
      return false;
  }

  line(double slope, double y, int a, int b){
    this->slope = slope;
    this->y = y;
    this->a = a;
    this->b = b;
  }

  line(const line &other){
    this->slope = other.slope;
    this->y = other.y;
    this->a = other.a;
    this->b = other.b;
  }
};

class point {
public:
  double x;
  double y;
};

int main(){
  vector<point> points;
  ADD_POINT(0,0);
  ADD_POINT(7,28);
  ADD_POINT(1,1);
  ADD_POINT(2,3);
  ADD_POINT(2,4);
  ADD_POINT(3,5);
  ADD_POINT(3,14);
  ADD_POINT(5,21);
  ADD_POINT(9,35);

  multiset<line> lines;
  for(unsigned int x=0;x<points.size();x++){
    for(unsigned int y=0;y<points.size();y++){
      if(x!=y){ // No lines with the same point
        point a = points[x];
        point b = points[y];
        double slope = (a.y-b.y)/(a.x-b.x);
        double yint;
        yint = a.y-a.x*slope;
        line newline(slope,yint,x,y);
        lines.insert(newline);
      } 
    }
  }

  for(multiset<line>::const_iterator p = lines.begin(); p != lines.end(); ++p){
    //cout << "Line: " << p->a << " " << p->b << " " << p->slope << " " << p->y << endl;
    line theline = *p;
    line conj(theline.slope,theline.y,theline.b,-1);
    multiset<line>::iterator it;
    pair<multiset<line>::iterator,multiset<line>::iterator> ret;
    ret = lines.equal_range(conj);
    for(it = ret.first; it!=ret.second; ++it){
      //cout << "  Find: " << it->a << " " << it->b << " " << it->slope << " " << it->y << endl;
      int a = theline.a;
      int b = theline.b;
      int c = it->b;
      if(a < b && b < c){
        cout << a << " " << b << " " << c << std::endl;
      }
    }
  }


  //cout << points[0].x << std::endl;

}
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2  
Could you explain that first part to a humble mathematician like me to whom it is not trivial? –  Beta Aug 20 '11 at 12:49
    
Yea..I did not get it either. Can you kindly skip the SQL and explain the algorithm? –  user7 Aug 20 '11 at 12:54
    
@Beta Lol, sorry typo. –  Stefan Mai Aug 20 '11 at 12:58
    
@user639306 Let me know what part is confusing. Create the list, sort it, iterate over it O(n^2) looking to see if a corresponding element exists O(log(n)) –  Stefan Mai Aug 20 '11 at 13:02
    
It did not understand the part where you build the table/list.after we first compute the slope and y intercept of each pair of point –  user7 Aug 20 '11 at 13:07

I have this solution tell if there is a better one,

Sort all the points according to the slope they make with the x axis or any other axis you want ( O(n* logn) ). Now all you have to do if go through the sorted list and find points which have same slope either inpositive or negative direction( this can be done in linear time i.e. O(n) ) . Lets say you get m such points for one case then increment the answer by C(m,3)..

Total time depends on how good you implement C(m,3)

But asymptotically O(N logN)

Edit: After seeing icCube's comment i realize that we cannot take any axis..so for the above defined algo taking the slope calculating point as one of the n points ( thus n times ) should be my best guess. But it makes the algorithm N*N*Log(N)

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what does c(n,3) stand for? –  user7 Aug 20 '11 at 11:21
    
all possible ways of choosing 3 objects out of n.en.wikipedia.org/wiki/Combination –  FUD Aug 20 '11 at 11:23
1  
Also in this case C(n,3) should be a trivial constant time calculation as the 3 is always constant.. ( now that i think more deeply )..so C(n,3) = n*(n-1)*)(n-2) / 3*2*1 –  FUD Aug 20 '11 at 11:25
    
ok. How do I go about implementing C(n,3) ? Did you mean m or n in C(n,3)? –  user7 Aug 20 '11 at 11:26
4  
Sorry, don't thinks so -> (1,1), (2,3), (3,5) are colinear but slope is 1,2/3,3/5 –  ic3 Aug 20 '11 at 11:35

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