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Given n non-negative integers a1, a2, ..., an, where each represents a point at coordinate (i, ai). n vertical lines are drawn such that the two endpoints of line i is at (i, ai) and (i, 0). Find two lines, which together with x-axis forms a container, such that the container contains the most water.

Note: You may not slant the container.

One solution could be that we take each and every line and find area with every line. This takes O(n^2). Not time efficient.

Another Solution could be, we can use DP to find the maximum area uptil every index, and then at index n, we will get the maximum area. I think its O(n)

Could there be more better solutions. Please tell, thanks in advance.

share|improve this question
    
Can you provide an image? – user unknown May 20 '12 at 2:34
    
Can you elaborate on the DP you are thinking of. Since there is no relation between i and ai, I think you will have to consider all the combinations, Because for two points i and j, the area will be (i-j)*min(ai,aj). I don't think you can maximize this. – sukunrt May 20 '12 at 6:12
1  
Just use the solutions for stackoverflow.com/q/4311694/4279 – J.F. Sebastian May 20 '12 at 14:10
    
@J.F.Sebastian Not sure if the problems are equivalent. Take a simple case: 100, x, 200. if x<100 the optimal answer in histogram example would depend on the value of x, but not in this example. – ElKamina May 20 '12 at 15:50
    
@ElKamina: You're right. I should've said that the problems are merely related. – J.F. Sebastian May 21 '12 at 16:45
up vote 3 down vote accepted

Many people here are mistaking this problem to maximal rectangle problem, which is not the case.

Solution

  1. Delete all the elements aj such that ai >= aj =< ak and i > j < k. This can be done in linear time.
    1. Find the maximum value am
    2. Let as = a1
    3. For j = 2 through m-1, if as >= aj, delete aj, else as = aj
    4. Let as = an
    5. For j = n-1 through m+1, if as >= aj, delete aj, else as = aj
  2. Notice that the resulting values look like a pyramid, that is, all the elements on the left of the maximum are strictly increasing and on the right are strictly decreasing.
  3. i=1, j=n. m is location of max.
  4. While i<=m and j>=m
    1. Find area between ai and aj and keep track of the max
    2. If ai < aj, i+=1, else j-=1

Complexity is linear (O(n))

share|improve this answer
    
Consider 4 at 3, 10 at 4, 10 at 5, 4 at 6. Largest two are 10 at 4 and 5, volume 10. Check volume for 4 at 3 to 10 at 5 - volume 8 - no improvement. Check volume for 10 at 4 to 4 at 6 - volume 8 - no improvement, but 4 at 3 to 4 at 6 is volume 12 - would be better but missed. In general you can have a wide low answer which is missed because inside is a narrow high answer that splits it in two. – mcdowella May 21 '12 at 4:07
    
@mcdowella Yes. That is true! I will refine my answer soon. But the key will be to ignore numbers that have at least one larger number on the either side. – ElKamina May 21 '12 at 7:20
    
@mcdowella See my updated solution. It is linear time now. – ElKamina May 21 '12 at 17:25
    
@ElKamina Thank you very much for such a good answer. – Luv May 23 '12 at 20:42
int maxArea(vector<int> &height) {
    int ret = 0;
    int left = 0, right = height.size() - 1;
    while (left < right) {
        ret = max(ret, (right - left) * min(height[left], height[right]));
        if (height[left] <= height[right])
            left++;
        else
            right--;
    }
    return ret;
}
share|improve this answer
    
In general, code-only answers tend not to be so good. Why not explain the answer? – Justin Apr 18 '15 at 1:05

Here is an implementation with Java:

Basic idea is to use two pointers from front and back, and calculate the area along the way.

public int maxArea(int[] height) {
    int i = 0, j = height.length-1;
    int max = Integer.MIN_VALUE;

    while(i < j){
        int area = (j-i) * Math.min(height[i], height[j]);
        max = Math.max(max, area);
        if(height[i] < height[j]){
            i++;
        }else{
            j--;
        }
    }

    return max;
}
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This problem can be solved in linear time.

  1. Construct a list of possible left walls (position+height pairs), in order from highest to lowest. This is done by taking the leftmost possible wall and adding it to the list, then going through all possible walls, from left to right, and taking every wall that is larger than the last wall added to the list. For example, for the array

    2 5 4 7 3 6 2 1 3
    

    your possible left walls would be (pairs are (pos, val)):

    (3, 7) (1, 5) (0, 2)
    
  2. Construct a list of possible right walls in the same way, but going from right to left. For the above array the possible right walls would be:

    (3, 7) (5, 6) (8, 3)
    
  3. Start your water level as high as possible, that is the minimum of heights of the walls at the front of the two lists. Calculate the total volume of water using those walls (it might be negative or zero, but that is ok), then drop the water level by popping an element off of one of the lists such that the water level drops the least. Calculate the possible water volume at each of these heights and take the max.

Running this algorithm on these lists would look like this:

L: (3, 7) (1, 5) (0, 2)  # if we pop this one then our water level drops to 5
R: (3, 7) (5, 6) (8, 3)  # so we pop this one since it will only drop to 6
Height = 7
Volume = (3 - 3) * 7 = 0
Max = 0

L: (3, 7) (1, 5) (0, 2)  # we pop this one now so our water level drops to 5
R: (5, 6) (8, 3)         # instead of 3, like if we popped this one
Height = 6
Volume = (5 - 3) * 6 = 12
Max = 12

L: (1, 5) (0, 2)
R: (5, 6) (8, 3)
Height = 5
Volume = (5 - 1) * 5 = 20
Max = 20


L: (1, 5) (0, 2)
R: (8, 3)
Height = 3
Volume = (8 - 1) * 3 = 21
Max = 21

L: (0, 2)
R: (8, 3)
Height = 2
Volume = (8 - 0) * 2 = 16
Max = 21

Steps 1, 2, and 3 all run in linear time, so the complete solution also takes linear time.

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This problem is a simpler version of The Maximal Rectangle Problem. The given situation can be view as a binary matrix. Consider the rows of the matrix as X-axis and columns as Y-axis. For every element a[i] in the array, set

Matrix[i][0] = Matrix[i][1] = ..... = Matrix[i][a[i]] = 1

For e.g - For a[] = { 5, 3, 7, 1}, our binary matrix is given by:

1111100
1110000
1111111
1000000
share|improve this answer
1  
Your representation is right, but it is not the maximal rectangle problem. If i,j are selected the solution the volume is min(ai,aj)*|i-j| . But in maximal rectangle, the volume is min(ai..aj)*|i-j| (assuming i<j ). – ElKamina May 20 '12 at 15:54

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