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Magnitude Pole: An element in an array whose left hand side elements are lesser than or equal to it and whose right hand side element are greater than or equal to it.

For Example: 3,1,4,5,9,7,6,11 Answer: 5 & 11.

I was asked this question in an interview and I have to return the index of the element and only return the first element that met the condition.

My logic:

  1. Take two MultiSet (So that we can consider duplicate as well), one for right hand side of the element and one for left hand side of the element(the pole).
  2. Start with 0th element and put rest all elements in the "right set".
  3. Base condition if this 0th element is lesser or equal to all element on "right set" then return its index.
  4. Else put this into "left set" and start with element at index 1.
  5. Traverse the Array and each time pick the maximum value from "left set" and minimum value from "right set" and compare.
  6. At any instant of time for any element all the value to its left are in the "left set" and value to its right are in the "right set"

Code:

int magnitudePole (const vector<int> &A) {  
   multiset<int> left, right;        
   int left_max, right_min;          
   int size = A.size();
   for (int i = 1; i < size; ++i)
       right.insert(A[i]);
   right_min = *(right.begin()); 
   if(A[0] <= right_min)
       return 0;
   left.insert(A[0]);
   for (int i = 1; i < size; ++i) {
       right.erase(right.find(A[i]));
       left_max = *(--left.end());
       if (right.size() > 0)
           right_min = *(right.begin());
       if (A[i] > left_max && A[i] <= right_min)
           return i;
       else
           left.insert(A[i]);
   }
   return -1;
}

My questions:

  • I was told that my logic is incorrect, I am not able to understand why this logic is incorrect (though I have checked for some cases and it is returning right index)
  • For my own curiosity how to do this without using any set/multiset in O(n) time.
share|improve this question
    
The description you give of the logic behind your algorithm seems a little imprecise about the details (when do you erase from the RHS? when do you compare? when do you insert in the LHS?) but in general the idea seems correct, as it is basically a brute force search that uses multisets to help with the bookkeeping. –  us2012 Mar 13 '13 at 22:34
    
Actually it was online test so I coded it first but when they replied that it was wrong so I just told them that this is what I did. So may be my algorithm is not in detail but they judge based on the algorithm in the code. –  JackSparrow Mar 13 '13 at 22:37
1  
does 4 is not a Magnitude Pole? –  Imran Rizvi Feb 25 '14 at 16:30

8 Answers 8

up vote 8 down vote accepted

For an O(n) algorithm:

  1. Count the largest element from n[0] to n[k] for all k in [0, length(n)), save the answer in an array maxOnTheLeft. This costs O(n);
  2. Count the smallest element from n[k] to n[length(n)-1] for all k in [0, length(n)), save the answer in an array minOnTheRight. This costs O(n);
  3. Loop through the whole thing and find any n[k] with maxOnTheLeft <= n[k] <= minOnTheRight. This costs O(n).

And you code is (at least) wrong here:

if (A[i] > left_max && A[i] <= right_min) // <-- should be >= and <=
share|improve this answer
    
Thanks for prompt answer. Your algorithm is correct, just now I realised yes I missed that "=" but as per the interviewer my algorithm is incorrect :( –  JackSparrow Mar 13 '13 at 22:33
1  
Won't this be O(n²)? –  iamnotmaynard Mar 13 '13 at 22:35
2  
@iamnotmaynard: Why? O(N)+O(N)+...O(N) any constant times = O(N). –  Ziyao Wei Mar 13 '13 at 22:36
    
Finding the largest element from n[0] to n[k] for any given k is O(n). Doing this for all k in [0, length(n)] (which is == n) will be O(n²). Wouldn't it? –  iamnotmaynard Mar 13 '13 at 22:38
1  
@iamnotmaynard Just do it incrementally would make it linear. –  Ziyao Wei Mar 13 '13 at 22:38
  • Create two bool[N] called NorthPole and SouthPole (just to be humorous.
  • step forward through A[]tracking maximum element found so far, and set SouthPole[i] true if A[i] > Max(A[0..i-1])
  • step backward through A[] and set NorthPole[i] true if A[i] < Min(A[i+1..N-1)
  • step forward through NorthPole and SouthPole to find first element with both set true.

O(N) in each step above, as visiting each node once, so O(N) overall.

share|improve this answer

for Java :

    public int magnitude(int[] A) {

    int length = A.length;
    // the sense of maxes is : what's the maximum number from the beginning of the array till the current position
    int[] maxes = new int[A.length];
    // the sense of mins is : what's the minimum number from the current position till the end of the array
    int[] mins = new int[A.length];

    int max = maxes[0] = Integer.MIN_VALUE;
    int min = mins[length - 1] = Integer.MAX_VALUE;

    // mins and maxes list are built incrementally
    for (int i = length - 1; i >= 0; --i) {
        if (A[i] < min) {
            min = A[i];
        }
        mins[i] = min;
    }

    for (int i = 0; i < length; i++) {
        if (A[i] > max) {
            max = A[i];
        }
        maxes[i] = max;
    }

    for (int i = 0; i < length; i++) {
        if (A[i] >= maxes[i] && A[i] <= mins[i]) {
            return i;
        }
    }

    return -1;
}
share|improve this answer

Your logic seems perfectly correct (didn't check the implementation, though) and can be implemented to give an O(n) time algorithm! Nice job thinking in terms of sets.

Your right set can be implemented as a stack which supports a min, and the left set can be implemented as a stack which supports a max and this gives an O(n) time algorithm.

Having a stack which supports max/min is a well known interview question and can be done so each operation (push/pop/min/max is O(1)).

To use this for your logic, the pseudo code will look something like this

foreach elem in a[n-1 to 0]
    right_set.push(elem)

while (right_set.has_elements()) {
   candidate = right_set.pop();
   if (left_set.has_elements() && left_set.max() <= candidate <= right_set.min()) {
       break;
   } else if (!left.has_elements() && candidate <= right_set.min() {
        break;
   }
   left_set.push(candidate);
}

return candidate
share|improve this answer
    
Yeah at that time I forgot that I can use stack. –  JackSparrow Mar 13 '13 at 22:44
    
@JackSparrow: Implementation details :-). I really like the way you thought about this. It has some maturity to it! –  Knoothe Mar 13 '13 at 22:46
    
Thanks :) but as per them my algorithm is incorrect :( –  JackSparrow Mar 13 '13 at 22:50
    
@JackSparrow: It might be that your implementation is wrong. Are they claiming that the logic you have is incorrect? Did they say what the flaw was? –  Knoothe Mar 13 '13 at 22:51
    
@JackSparrow, btw, I just looked at your implementation. It seems like you are assuming right_min is at the beginning and left_max is at the end. That is incorrect. You need to walk through the whole set in your implementation. –  Knoothe Mar 13 '13 at 22:53

I saw this problem on Codility, solved it with Perl:

sub solution {
        my (@A) = @_;            

        my ($max, $min) = ($A[0], $A[-1]);
        my %candidates;

        for my $i (0..$#A) {
                if ($A[$i] >= $max) {
                        $max = $A[$i];
                        $candidates{$i}++;
                }
        }
        for my $i (reverse 0..$#A) {
                if ($A[$i] <= $min) {
                        $min = $A[$i];
                        return $i if $candidates{$i};
                }
        }
        return -1;
}
share|improve this answer

How about the following code? I think its efficiency is not good in the worst case, but it's expected efficiency would be good.

    int getFirstPole(int* a, int n)
{
    int leftPole = a[0];
    for(int i = 1; i < n; i++)
    {
        if(a[j] >= leftPole)
        {
            int j = i;
            for(; j < n; j++)
            {
                if(a[j] < a[i])
                {
                    i = j+1;  //jump the elements between i and j                   
                    break;
                }
                else if (a[j] > a[i])
                    leftPole = a[j];
            }
            if(j == n) // if no one is less than a[i] then return i
                return i;
        }
    }
    return 0;
}
share|improve this answer
  1. Create array of ints called mags, and int variable called maxMag.
  2. For each element in source array check if element is greater or equal to maxMag.
  3. If is: add element to mags array and set maxMag = element.
  4. If isn't: loop through mags array and remove all elements lesser.

Result: array of magnitude poles

share|improve this answer

Interesting question, I am having my own solution in C# which I have given below, read the comments to understand my approach.

public int MagnitudePoleFinder(int[] A)
{
    //Create a variable to store Maximum Valued Item i.e. maxOfUp
    int maxOfUp = A[0];

    //if list has only one value return this value
    if (A.Length <= 1) return A[0];

    //create a collection for all candidates for magnitude pole that will be found in the iteration
    var magnitudeCandidates = new List<KeyValuePair<int, int>>();

    //add the first element as first candidate
    var a = A[0];
    magnitudeCandidates.Add(new KeyValuePair<int, int>(0, a));

    //lets iterate
    for (int i = 1; i < A.Length; i++)
    {
        a = A[i];
        //if this item is maximum or equal to all above items ( maxofUp will hold max value of all the above items)
        if (a >= maxOfUp)
        {
            //add it to candidate list
            magnitudeCandidates.Add(new KeyValuePair<int, int>(i, a));
            maxOfUp = a;
        }
        else
        {
            //remote all the candidates having greater values to this item
            magnitudeCandidates = magnitudeCandidates.Except(magnitudeCandidates.Where(c => c.Value > a)).ToList();
        }
    }
    //if no candidate return -1
    if (magnitudeCandidates.Count == 0) return -1;
    else
        //return value of first candidate
        return magnitudeCandidates.First().Key;
}
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