The max product of consecutive elements in an array

I was asked this algorithm question during my onsite interview. Since I was not asked to sign NDA, I post it here for an answer.

Given an array of REAL numbers that does not contain 0, find the consecutive elements that yield max product. The algorithm should run in linear time

I have considered the following approach: Use two arrays. First one is to use DP idea to record the current max absolute value product, the second array to record the number of negative elements met so far. The final result should be the largest max absolute value and the number of negative numbers be even.

I thought my method will work, but was interrupted during coding saying it will not work. Please let me know what is missing in the above approach.

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Hint: assume you only have positive numbers. What does the problem reduce to if you take the logarithm (any base) of each number? Now, how can you handle negative numbers as well? –  IVlad Sep 17 '13 at 1:14
Given the requirement for consecutive elements, and assuming an odd number of negatives, you'd need to try from both ends. –  Hot Licks Sep 17 '13 at 1:14
Thank you. I am trying to use @IVlad's hint to come up with a solution. So far I have figured out that if all numbers are positive, then the problem reduces to taking the log(anybase) of every number in the array and then finding the max sum of consecutive elements of the array. However I have not yet thought of a way to handle negative numbers. I am working on it. –  Shashank Sep 17 '13 at 2:00
You're not making sense. How does using logs make it any different from simply multiplying? And, assuming an even number of negatives, why wouldn't the solution just be the product of all elements in the array? And with odd negatives it would be the product up to the last negative, starting from either end. –  Hot Licks Sep 17 '13 at 2:31
(Ah, yes! Since these are real one needs to be concerned about values less than 1 (but still positive). That does make it messier.) –  Hot Licks Sep 17 '13 at 2:33

The algorithm is indeed O(n). When iterating the array, use a variable to store the max value found so far, a variable to store the max value of subarray that ends at a[i], and another variable to store minimum value that ends at a[i] to treat negative values.

``````float find_maximum(float arr[], int n) {
if (n <= 0) return NAN;

float max_at = arr[0];  // Maximum value that ends at arr[i]
float min_at = arr[0];  // Minimum value that ends at arr[i]
float max_value = max_at;

for (int i = 1; i < n; i++) {
float prev_max_at = max_at, prev_min_at = min_at;
max_at = max(arr[i], arr[i] * prev_min_at, arr[i] * prev_max_at);
min_at = min(arr[i], arr[i] * prev_min_at, arr[i] * prev_max_at);
max_value = max(max_value, max_at);
}
return max_value;
}
``````

For the case of requiring at least two elements in the product, the algorithm can be updated as following:

``````float find_maximum(float arr[], int n) {
if (n <= 1) return NAN;

float max_at = arr[0] * arr[1];  // Maximum value that ends at arr[i]
float min_at = arr[0] * arr[1];  // Minimum value that ends at arr[i]
float max_value = max_at;

for (int i = 2; i < n; i++) {
float prev_max_at = max_at, prev_min_at = min_at;
max_at = max(arr[i] * arr[i-1], arr[i] * prev_min_at, arr[i] * prev_max_at);
min_at = min(arr[i] * arr[i-1], arr[i] * prev_min_at, arr[i] * prev_max_at);
max_value = max(max_value, max_at);
}
return max_value;
}
``````
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Really nice job. O(n) and extremely simple as well. I was thinking way too hard. Kudos to you and +1 sir. –  Shashank Sep 17 '13 at 3:39
This answer looks correct. –  justhalf Sep 17 '13 at 3:39
Although this one will output `0.1` for `[0.1, -3, 0.1]`, which I believe should be the case, not as OP has mentioned –  justhalf Sep 17 '13 at 3:40
@justhalf Well even if it's not the case then he could just edit the arguments to his `max` function and take out `arr[i]` and it would work if the subarray must be at least two elements. –  Shashank Sep 17 '13 at 3:46
If you are saying the product must be at least of two elements, we can simply update the algorithm: In the beginning: max_at = arr[0] * arr[1]; Then: max_at = max(arr[i] * arr[i-1], arr[i] * prev_min_at, arr[i] * prev_max_at); The same for min_at –  Chen Pang Sep 17 '13 at 3:48

You can implement a variant of the Kadane algorithm (http://en.wikipedia.org/wiki/Maximum_subarray_problem) who runs with constant extra memory and linear in the size of the problem (no extra array,...)

If only strict positive numbers are given:

``````def max_subarray_mul(A):
max_ending_here = max_so_far = 1
for x in A:
if x > 0
max_ending_here = max(1,max_ending_here*x)
max_so_far = max(max_so_far, max_ending_here)
return max_so_far
``````

I'm still working on the part with negative numbers

Or a more expensive (in time) method is the following, but this will work with negative numbers:

``````def max_subarray_mul(A):
max_so_far = 1
n = length(A)
for i in 1...n:
x = A[i]
tmp = x
max_so_far = max(max_so_far,tmp)
for j in i+1...n:
tmp = tmp*A[j]
max_so_far = max(max_se_far,tmp)
return max_so_far
``````

Which runs in constant memory and `O(n²)` time

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if `x > 0`, `max_ending_here`, assuming it means what its name implies, can be just `x` itself and not `max_ending_here*x`. For example: `0.3 2.2`. `0.3 * 2.2 < 2.2`. –  IVlad Sep 17 '13 at 1:40
Point taken, made some typos, give me a minute, I will redesign it... –  CommuSoft Sep 17 '13 at 1:41

Using python notations:

• compute `min( prod( v[ 0: ] ), prod( v[ 1: ] ), ..., prod( v[ -1 ] ) )` and `max( prod( v[ 0: ] ), prod( v[ 1: ] ), ..., prod( v[ -1 ] ) )` in O(n)
• compute recursively the max product based on the fact that `maxpro(v) = max( maxpro(v[:-1]) * max( prod( v[ 0: ] ), prod( v[ 1: ] ), ..., prod( v[ -1 ] ) )`. This is O(n) too

Here is the code:

``````#
n = 5
vmax = 10

#
v = nr.randint( 1, vmax, n )
v *= nr.randint( 0, 2, n ) * 2 - 1
#
print v

#
prod_res = np.zeros( ( 2, n ), int )
prod_res[ 0, 0 ] = prod_res[ 1, 0 ] = v[ 0 ]
for i in xrange( 1, n ) :
prod_res[ 0, i ] = min( v[ i ], prod_res[ 1, i-1 ] * v[ i ], prod_res[ 0, i-1 ] * v[ i ] )
prod_res[ 1, i ] = max( v[ i ], prod_res[ 1, i-1 ] * v[ i ], prod_res[ 0, i-1 ] * v[ i ] )
#
print prod_res

#
def maxpro_naive( v ) :
return v[ 0 ] if ( len( v ) == 1 ) else max( maxpro_naive( v[ :-1 ] ), prod_res[ 1, len(v) -1 ] )
#
print maxpro_naive( v )
``````
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Ignoring negative numbers for the moment...

Let `A[i..j]` mean `A[i]*A[i+1]*...*A[j]`

The problem is to find `max(A[i..j])`

Notice that `A[i..j] = A[0..j] / A[0..i-1]`

So if we calculate `A[0..x]` for all x.

We can then determine `max(A[i..j]) = max(A[0..x]) / min(A[0..y])`

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Taking care of the thing if there are no 1's in the array and the product coming should not be 1 in that case. Here is my code:

``````#include<bits/stdc++.h>
using namespace std;

int max(int x, int y)
{ return (y > x)? y : x; }
int min(int x, int y)
{ return (y < x)? y : x; }
bool search(int a[],int k,int n)
{
for(int i=0;i<n;i++)
{
if(a[i]==k)
return true;
}
return false;
}

int maxSubArrayProduct(int a[], int size)
{
int maxpos = 1, minneg=1, i;
int pro_max = 1;

for (i = 0; i < size; i++)
{
if(a[i]<0)
{
int temp=maxpos;
maxpos=max(maxpos,minneg*a[i]);
minneg=min(minneg,temp*a[i]);
}
if(a[i]==0)
{maxpos=1;minneg=1;}
if(a[i]>0)
{
maxpos=maxpos*a[i];
minneg=min(minneg,minneg*a[i]);
}
if(pro_max<maxpos)
pro_max=maxpos;
}
return pro_max;
}

/* Driver program to test maxSubArrayProduct */
int main()
{
int a[] =  {-1,0,1};
int n = sizeof(a)/sizeof(a[0]);
int start=0,end=0;
int max_pro = maxSubArrayProduct(a, n);
if(max_pro==1)
if(search(a,1,n))max_pro=1;
else max_pro=0;
printf("Maximum contiguous product is %d\n", max_pro);
return 0;
}
``````
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