# Computational geometry algorithm

I ran into the following problem and I have hard time solving it. C is my language of preference but any programming language would be ok. Could anybody help? Thanks a lot for your answers.

Problem:
The array A of positive integers contains N elements. A big ant stands at (0,0) heading North. It moves A[0] steps forward and turns by 90 degrees clockwise. Then it moves A[1] steps forward and turns clockwise by 90 degrees. And so on.

``````For example, given
A[0] = 1  A[1] = 3  A[2] = 2
A[3] = 5  A[4] = 4  A[5] = 4
A[6] = 6  A[7] = 3  A[8] = 2

The ant walks as follows:
(0,0)   -> (0,1)     1st move, 1 step  North
(0,1)   -> (3,1)     2nd move, 3 steps East
(3,1)   -> (3,-1)    3rd move, 2 steps South
(3,-1)  -> (-2,-1)   4th move, 5 steps West
(-2,-1) -> (-2,3)    5th move, 4 steps North
(-2,3)  -> (2,3)     6th move, 4 steps East
(2,3)   -> (2,-3)    7th move, 6 steps South
(2,-3)  -> (-1,-3)   8th move, 3 steps West
(-1,-3) -> (-1,-1)   9th move, 2 steps North

In 7th and 9th move the ant touches its previous path, namely:
at point (2,1) in the 7th move,
at point (2,-1) in the 7th move,
at point (-1,-1) in the 9th move
``````

Write a function

``````int ant_cross(int A[], int N);
``````

which given a description of ant's walk in an array A, returns the number of the move, in which the ant for the first time touches its previous path, or 0 if such situation does not occur.

Assume that:
N is an integer within the range [1..100,000];
each element of array A is an integer within the range [1..1,000,000].

For example, given an array A as illustrated above, the function should return 7, because the ant touches its previous path at point (2,1) in the 7th move.

Complexity:
expected worst-case time complexity is O(N);
expected worst-case space complexity is O(1), beyond input storage (not counting the storage required for input arguments).
Elements of input arrays can be modified.

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So, is an ant or a turtle? –  danatel Jan 29 '13 at 20:11
Yeah, exactly @danatel. This is a detail upon which the solution depends largely. –  user529758 Jan 29 '13 at 20:13
Names have been changed to protect the innocent ;-) –  Gerhat Jan 29 '13 at 20:14
So, you want us to solve your homework? What have you done with it? –  Eddy_Em Jan 29 '13 at 20:14
I solved it in a way that doesn't satisfy the complexity requested. It's not a homework. –  Gerhat Jan 29 '13 at 20:16
show 5 more comments

Notice that when the ant first crosses its own path, say at step n, then the path at step n-3 or n-5 is crossed. So you have to follow the path and only check possible intersection of n-th segment with (n-4)-th segment and (n-6)-th. This clearly satisfy the complexity conditions...

For example to check if segment with index n crosses segment with index n-3 you only have to check if ´A[n] > A[n-2] && A[n-1]

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How do you calculate the segment start-end points and where do you store them? If you use an array for this then you got up to O(N) space complexity. –  Gerhat Jan 29 '13 at 20:19
It is actually `n-3` and `n-5` and if I am not mistaken the `n-3` can only occur if the total number of steps taken is exactly `4`. For larger numbers the first crossing will always be of the segment taken `n-5` steps earlier –  Pankrates Jan 29 '13 at 20:29
It is completely wrong, consider the following example: 3, 2, 2, 1, 1, 0, 0, 2. The last step cross the path of the first step. –  Thomash Jan 29 '13 at 20:54
You are correct if we assume that `0` is an allowed number of steps to make –  Pankrates Jan 29 '13 at 20:58
@Thomash: 0 is not a positive number –  Emanuele Paolini Jan 29 '13 at 21:01
show 2 more comments

The key point here is finding the movement that will force the ant to enter into an innerloop. An innerloop is a sequence of moves (north,east, south,west) that will ultimately lead to the ant crossing an old path. Once we have found that movement we have to keep looking for the moment the ant crosses an old path just by examining the length of each step with its parallel version (north and south are parallel). There's a special case just when we find out that we are going into an innerloop for the first time. In this case comparing the step with its parallel version could be an error, that's why we have to do a little bit of calculation and adjust the metrics to prevent this from happening.

The code has been written in C#. The syntax is similar to C. Any doubt or bug send email to a.castano@lab.matcom.uh.cu and arnaldo.skywalker@gmail.com

``````class Program
{
static void Main(string[] args)
{
var A1 = new [] {1, 3, 2, 5, 4, 4, 6, 3, 2};
var A2 = new[] { 1, 3, 2, 5, 4, 4, 3, 3, 2 };
var A3 = new[] { 1, 3, 2, 5, 4, 4, 1, 3, 2 };
var A4 = new[] { 1, 3, 2, 2, 4, 4, 1, 3, 2 };

Console.WriteLine("The first time it touches a previous path is at movement {0}",AntCross(A1));
}

public static int AntCross(int[] A)
{
var innerLoop = false;
var firstTime = true;

for (var i = 0; i < A.Length; i++)            // O(n)
{
if (innerLoop)
{
if (firstTime)
{
if (A[i] > SolveMetrics(A, i))    // O(1)
return i + 1;
firstTime = false;
}
else
if (A[i] > A[i - 2])
return i + 1;

continue;
}

innerLoop = CheckInnerLoop(A, i, i - 2);   // O(1)
}

return 0;
}

private static int SolveMetrics(int[] A, int i)
{
if (i - 2 >= 0 && i - 4 >= 0)
return Math.Abs(A[i - 2] - A[i - 4]);
return 0;
}

private static bool CheckInnerLoop(int [] A, int position, int parallelPosition)
{
if (parallelPosition < 0)
return false;

return A[position] < A[parallelPosition];
}
}
``````
-

Disclaimer: I assume that `0` number of steps per move is not allowed and that a parallel crossing does not count as a crossing.

Consider the drawings. We can have two scenarios for a crossing. First one: Take `p1` as a starting point anywhere in the complete path. `A[n]` will take it to `p2`, `A[n+1]` to `p3` and `A[n+2]`will take it to `p4`. Now you can see that if the segment made by `A[n+3]` is crossing another segment it can only and only cross the segment made by `A[n]`.

``````         n+3
|
|    n
Start p1 _ _ |_ _ _ _.p2
|       |
|       | n+1
|       |
p4 ._ _ _ _. p3
n+2
``````

The second possibility is illustrated by the next picture.

``````                      n+4
p5._ _ _ _ _ _.p6
|           | n+5
|        n  |
|      p1_ _|_.p2
n+3 |           | |
|           | | n+1
|             |
p4 ._ _ _ _ _ _ _. p3
n+2
``````

This shows us that at any time all we need to have, are the last 6 sets of coordinates i.e. `(p1, p2, p3 p4, p5, p6)`.

To check if the next move will cross any segment of the current path you check whether the new move will cross the segment `p3-p4`. If not then you check if `p1-p2` will be crossed. If not than the new segment will not cross the current path and we update our coordinates by removing the first coordinate `p1` in the array and 'pushing' on the newly created coordinate. Note that you only need to check two segments, since the segments `p2-p3` and `p4-p5` are parallel to the new segment and `p3-p4` the other two can never be crossed since they share a common coordinate).

This is of `O(N)` time complexity and `O(1)` space complexity. You only ever store 6 sets of integers (2 integers per set in this 2-dimensional problem) independent of `N`

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It is as wrong as manu-fatto's answer. –  Thomash Jan 29 '13 at 20:55