Attempting to solve google Code Jam 2010 final question.

http://code.google.com/codejam/contest/801485/dashboard#s=p4

**Ninjutsu problem in brief :**
Conside XY Plane. We have been given set of input points and a given rope tied to the origin. Ninja is going to circulate around the origin thus hitting various points. As soon as he hits a point obviously he would start circulating around this point with the remaining length of the rope. Challenge is to find maximum number of points he can hit/swipe.

**Restriction I have applied in this code :** Length of the rope remains constant

[In original problem the Ninja can reduce the length of the rope -> (thus the editor forcing us to use Dynamic Programming)]

Need your quick feedback on the approach taken or the code written so far - I have taken the approach as below.

- I have taken represented all the input points as C# Complex numbers.
- Using phase of polar co-ordinates to find collinear points.
**Condition 1:**If there are no collinear points on the minimum phase line, this point will be swiped its magnitude is less than Rope length.

**Condition 2:**Point having largest magnitude within length of rope will be swiped and smaller one will be left out. Once the first point has been swiped. I make this as the center for next iteration and Incremented sweepCount in the following lines.nSweep++; Complex center2; center2 = points[minPhaseMaxMagIndex];

I reduce the length of the rope now becomes originalLength - Magnitude of the point who is going to become new center. I do co-ordinate transformation using rectangular co-ordinate.

**Any suggestion on the code improvement or approach are most welcome. Thanks in all cases.**

```
class Ninjutsu
{
int N, R;
List<Complex> points;
Dictionary<Complex, List<Complex>> cp = new Dictionary<Complex, List<Complex>>();
int nSweep = 0;
private double GetPrincipalPhase(double x)
{
if (x >= 0)
return x;
else
return x + Math.PI;
}
public static void Main()
{
using (StreamReader sr = new StreamReader("Ninjutsu.IN"))
using (StreamWriter sw = new StreamWriter("Ninjutsu.OUT"))
{
int T = Convert.ToInt32(sr.ReadLine());
for (int tc = 0; tc < T; tc++)
{
int[] buf = sr.ReadLine().Split(' ').Select(x => int.Parse(x)).ToArray();
N = buf[0];
R = buf[1];
nSweep = 0;
cp.Clear();
points = new List<Complex>(N);
for (int i = 0; i < N; i++)
{
buf = sr.ReadLine().Split(' ').Select(x => int.Parse(x)).ToArray();
points.Add(new Complex(buf[0], buf[1])); //got the points
}
Complex center = new Complex(0, 0);
//first Swiped Point
//fsp = -1 indicates zero Sweep
Solve(R, center, points);
sw.WriteLine("Case #{0}: " + nSweep, tc + 1);
}//end TC loop
}
}
private List<Complex> GetNextPoints(double radius, Complex center)
{
List<Complex> nearPoints = points.OrderBy(d => Math.Sqrt(Math.Pow(d.Real - center.Real, 2) + Math.Pow(d.Imaginary - center.Imaginary, 2))).Skip(1).ToList();
List<Complex> nearReachablePoints = new List<Complex>();
//1 discard points which are farther than radius
for (int k = 0; k < nearPoints.Count; k++)
{
var d = nearPoints[k];
//Add those points which are within range of radius
//take nearest element distance wise, just make sure this nearest point should be collided when in anti-clockwise motion
double distFromCenter = Math.Sqrt(Math.Pow(d.Real - center.Real, 2) + Math.Pow(d.Imaginary - center.Imaginary, 2));
if (distFromCenter <= radius && GetPrincipalPhase(nearPoints[k].Phase) > GetPrincipalPhase(center.Phase))
{
nearReachablePoints.Add(d);
}
}
if (nearReachablePoints.Count > 0)
{
center = nearReachablePoints[0];
nSweep++;
}
return nearReachablePoints;
}
private void Solve(double radius, Complex center, List<Complex> points)
{
//find first point to be swiped by rope of length R
//x y mag & phase all are +ve
//so min of phase lies in 1st quad
double minPhaseWithinRadius = Math.PI; //max value of phase
List<int> minPhaseWithinRadiusIndexes = new List<int>();
double diffPhase, diffMag;
for (int i = 0; i < points.Count; i++)
{
diffPhase = GetPrincipalPhase(points[i].Phase - center.Phase);
diffMag = GetPrincipalPhase(points[i].Magnitude - center.Magnitude);
if (points[i] != center)
if (diffPhase <= minPhaseWithinRadius && diffMag < radius) //=R omitted since rotation around not feasible
{
minPhaseWithinRadius = diffPhase;
minPhaseWithinRadiusIndexes.Add(i);
}
}
//minP_indexList_within_Rad.count = 1 => no worries.
//if more than 1 point.. outer most point will be sweeped
//pick up the point with max Magnitude
double minPhaseMaxMagVal = int.MinValue;
int minPhaseMaxMagIndex = -1;
//if two points lie on the same line, point with largest mag with the radius will be swiped
if (minPhaseWithinRadiusIndexes.Count > 1)
{
for (int j = 0; j < minPhaseWithinRadiusIndexes.Count; j++)
{
if (points[minPhaseWithinRadiusIndexes[j]].Magnitude - center.Magnitude > minPhaseMaxMagVal)
{
minPhaseMaxMagVal = points[minPhaseWithinRadiusIndexes[j]].Magnitude - center.Magnitude;
minPhaseMaxMagIndex = minPhaseWithinRadiusIndexes[j];
}
}
//you can store skipped collinear point in (center, List<point>) pair if required
}
else if (minPhaseWithinRadiusIndexes.Count == 1)
{
//we have unique point having min. phase
minPhaseMaxMagIndex = minPhaseWithinRadiusIndexes[0];
}
//you got the point which will be sweeped now,. minPhaseMaxMagIndex
//hey u got new center..
else
{
Debug.WriteLine("how is it possible that there is no min. phase");
}
if (minPhaseMaxMagIndex != -1)
{
nSweep++;
Complex center2;
center2 = points[minPhaseMaxMagIndex];
List<Complex> transformedPoints = new List<Complex>();
for (int i = 0; i < points.Count; i++)
{
if (points[i] != center2)
transformedPoints.Add(new Complex(points[i].Real - center2.Real, points[i].Imaginary - center2.Imaginary));
}
cp.Add(center2, transformedPoints);
if (radius > center2.Magnitude)
Solve(radius - center2.Magnitude, center2, transformedPoints);
else
Debug.WriteLine("I have swiped what ever i could");
}
}
}
```