# Stable merging two arrays to maximize product of adjacent elements

The following is an interview question which I am unable to answer in a complexity less than an exponential complexity. Though it seems to be an DP problem, I am unable to form the base cases and analyze it properly. Any help is appreciated.

You are given 2 arrays of size 'n' each. You need to stable-merge these arrays such that in the new array sum of product of consecutive elements is maximized.

For example

A= { 2, 1, 3}

B= { 3, 7, 9}

On Stable merging A and B will give an array C with '2n' elements say C={c1, c2, c3, c4, c5, c6} You need to find a new array C by merging (stable) A and B such that sum= c1*c2 + c3*c4 + c5* c6..... n terms is maximum.

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This link may be helpful, ocf.berkeley.edu/~wwu/cgi-bin/yabb/… –  Rupak Jul 27 '12 at 6:53
He has already mentioned we have to do stable merging. Stable means that the order for the numbers must be retained. Means 2 in the first array should always come before 1 in the first array. Just have a look at what stability is en.wikipedia.org/wiki/Sorting_algorithm#Stability –  dejavu Jul 29 '12 at 13:55

Lets define c[i,j] as solution of same problem but array start from i to end for left. And j to end for right. So c[0,0] will give solution to original problem.

c[i,j] consists of.

1. MaxValue = the max value.
2. NeedsPairing = true or false = depending on left most element is unpaired.
3. Child = [p,q] or NULL = defining child key which ends up optimal sum till this level.

Now defining the optimal substructure for this DP

`c[i,j] = if(NeedsPairing) { left[i]*right[j] } + Max { c[i+1, j], c[i, j+1] }`

It's captured more in detail in this code.

``````if (lstart == lend)
{
if (rstart == rend)
{
nodeResult = new NodeData() { Max = 0, Child = null, NeedsPairing = false };
}
else
{
nodeResult = new NodeData()
{
Max = ComputeMax(right, rstart),
NeedsPairing = (rend - rstart) % 2 != 0,
Child = null
};
}
}
else
{
if (rstart == rend)
{
nodeResult = new NodeData()
{
Max = ComputeMax(left, lstart),
NeedsPairing = (lend - lstart) % 2 != 0,
Child = null
};
}
else
{
var downLef = Solve(left, lstart + 1, right, rstart);

var lefResNode = new NodeData()
{
Child = Tuple.Create(lstart + 1, rstart),
};

if (downLef.NeedsPairing)
{
lefResNode.Max = downLef.Max + left[lstart] * right[rstart];
lefResNode.NeedsPairing = false;
}
else
{
lefResNode.Max = downLef.Max;
lefResNode.NeedsPairing = true;
}

var downRt = Solve(left, lstart, right, rstart + 1);

var rtResNode = new NodeData()
{
Child = Tuple.Create(lstart, rstart + 1),
};

if (downRt.NeedsPairing)
{
rtResNode.Max = downRt.Max + right[rstart] * left[lstart];
rtResNode.NeedsPairing = false;
}
else
{
rtResNode.Max = downRt.Max;
rtResNode.NeedsPairing = true;
}

if (lefResNode.Max > rtResNode.Max)
{
nodeResult = lefResNode;
}
else
{
nodeResult = rtResNode;
}
}
}
``````

And we use memoization to prevent solving sub problem again.

``````Dictionary<Tuple<int, int>, NodeData> memoization = new Dictionary<Tuple<int, int>, NodeData>();
``````

And in end we use NodeData.Child to trace back the path.

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For A = {a1,a2,...,an}, B = {b1,b2,...,bn},

Define DP[i,j] as the maximum stable-merging sum between {ai,...,an} and {bj,...,bn}.

(1 <= i <= n+1, 1 <= j <= n+1)

DP[n+1,n+1] = 0, DP[n+1,k] = bk*bk+1 +...+ bn-1*bn, DP[k,n+1] = ak*ak+1 +...+ an-1*an.

DP[n,k] = max{an*bk + bk+1*bk+2 +..+ bn-1*bn, DP[n,k+2] + bk*bk+1}

DP[k,n] = max{ak*bn + ak+1*ak+2 +..+ an-1*an, DP[k+2,n] + ak*ak+1}

DP[i,j] = max{DP[i+2,j] + ai*ai+1, DP[i,j+2] + bi*bi+1, DP[i+1,j+1] + ai*bi}.

And you return DP[1,1].

Explanation: In each step you have to consider 3 options: take first 2 elements from remaining A, take first 2 element from remaining B, or take both from A and B (Since you can't change the order of A and B, you will have to take the first from A and first from B).

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I can't see how your algorithm does not take into account twice or more the same element of one set. –  Bentoy13 Jul 27 '12 at 11:30
Look here - DP[i+1,j+1] + ai*bi, one from A and one from B –  barak1412 Jul 27 '12 at 14:21
Sorry, it's not what I mean. How do you ensure in your algorithm that you don't have taken one element of A or B twice in different terms of the sum? I can't figure it out. –  Bentoy13 Aug 1 '12 at 7:48
If I decide to take an element, I increase the index - so I can't take the same element again. For example, if I choose to take the 2 elements from A and don't use B this step, DP[i+2,j] will return. So we don't have the possibility to take ai or a+1 again. –  barak1412 Aug 1 '12 at 13:53
Ok it convinces me :). +1 for this pretty solution by the way! –  Bentoy13 Aug 1 '12 at 14:06

My solution is rather simple. I just explore all the possible stable merges. Following the working C++ program:

``````#include<iostream>

using namespace std;

void find_max_sum(int *arr1, int len1, int *arr2, int len2, int sum, int& max_sum){
if(len1 >= 2)
find_max_sum(arr1+2, len1-2, arr2, len2, sum+(arr1[0]*arr1[1]), max_sum);
if(len1 >= 1 && len2 >= 1)
find_max_sum(arr1+1, len1-1, arr2+1, len2-1, sum+(arr1[0]*arr2[0]), max_sum);
if(len2 >= 2)
find_max_sum(arr1, len1, arr2+2, len2-2, sum+(arr2[0]*arr2[1]), max_sum);
if(len1 == 0 && len2 == 0 && sum > max_sum)
max_sum = sum;
}

int main(){
int arr1[3] = {2,1,3};
int arr2[3] = {3,7,9};
int max_sum=0;
find_max_sum(arr1, 3, arr2, 3, 0, max_sum);
cout<<max_sum<<endl;
return 0;
}
``````
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Above solution is quite simple. You can visualize it by making a tree with children as {a1[0],a1[1]}, {a1[0],a2[0]} and {a2[0],a2[1]}. Now expand each node with possible children (max 3) depending on the elements left in the arrays. –  ashwanilabs Jul 29 '12 at 13:38
this is of exponential complexity! won't even return for array size like 70 elements/ –  Ankush Aug 5 '12 at 1:47

Define `F(i, j)` as the maximal pairwise sum that can be achieved by stable merging `Ai...An` and `Bj...Bn`.

At each step in the merge, we can choose one of three options:

1. Take the first two remaining elements of `A`.
2. Take the first remaining element of `A` and the first remaining element of `B`.
3. Take the first two remaining elements of `B`.

Thus, `F(i, j)` can be defined recursively as:

``````F(n, n) = 0
F(i, j) = max
(
AiAi+1 + F(i+2, j), //Option 1
AiBj + F(i+1, j+1), //Option 2
BjBj+1 + F(i, j+2)  //Option 3
)
``````

To find the optimal merging of the two lists, we need to find `F(0, 0)`, naively, this would involve computing intermediate values many times, but by caching each `F(i, j)` as it is found, the complexity is reduced to `O(n^2)`.

Here is some quick and dirty c++ that does this:

``````#include <iostream>

#define INVALID -1

int max(int p, int q, int r)
{
return p >= q && p >= r ? p : q >= r ? q : r;
}

int F(int i, int j, int * a, int * b, int len, int * cache)
{
if (cache[i * (len + 1) + j] != INVALID)
return cache[i * (len + 1) + j];

int p = 0, q = 0, r = 0;

if (i < len && j < len)
p = a[i] * b[j] + F(i + 1, j + 1, a, b, len, cache);

if (i + 1 < len)
q = a[i] * a[i + 1] + F(i + 2, j, a, b, len, cache);

if (j + 1 < len)
r = b[j] * b[j + 1] + F(i, j + 2, a, b, len, cache);

return cache[i * (len + 1) + j] = max(p, q, r);
}

int main(int argc, char ** argv)
{
int a[] = {2, 1, 3};
int b[] = {3, 7, 9};
int len = 3;

int cache[(len + 1) * (len + 1)];
for (int i = 0; i < (len + 1) * (len + 1); i++)
cache[i] = INVALID;

cache[(len + 1) * (len + 1)  - 1] = 0;

std::cout << F(0, 0, a, b, len, cache) << std::endl;
}
``````

If you need the actual merged sequence rather than just the sum, you will also have to cache which of `p, q, r` was selected and backtrack.

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Check my solution. Will give an answer in O(n) time. I didn't find any contradicting test case stackoverflow.com/a/11709668/808203 –  dejavu Jul 29 '12 at 17:02

One way to solve it by dynamic programming is to always store:

S[ i ][ j ][ l ] = "Best way to merge A[1,...,i] and B[1,...,j] such that, if l == 0, the last element is A[i], and if l == 1, the last element is B[j]".

Then, the DP would be (pseudo-code, insert any number at A[0] and B[0], and let the actual input be in A[1]...A[n], B[1]...B[n]):

``````S[0][0][0] = S[0][0][1] = S[1][0][0] = S[0][1][1] = 0; // If there is only 0 or 1 element at the merged vector, the answer is 0
S[1][0][1] = S[0][1][1] = -infinity; // These two cases are impossible
for i = 1...n:
for j = 1...n:
// Note that the cases involving A[0] or B[0] are correctly handled by "-infinity"
// First consider the case when the last element is A[i]
S[i][j][0] = max(S[i-1][j][0] + A[i-1]*A[i], // The second to last is A[i-1].
S[i-1][j][1] + B[j]*A[i]); // The second to last is B[j]
// Similarly consider when the last element is B[j]
S[i][j][1] = max(S[i][j-1][0] + A[i]*B[j], // The second to last is A[i]
S[i][j-1][1] + B[j-1]*B[j]); // The second to last is B[j-1]
// The answer is the best way to merge all elements of A and B, leaving either A[n] or B[n] at the end.
return max(S[n][n][0], S[n][n][1]);
``````
-

Merge it and sort it. May be merge sort. Sorted array give max value.(Merge is just append the arrays). complexity is nlogn.

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Although I don't doubt that a sorted array does maximize the sum of products, the OP needs it such that the order of elements in the original array is preserved. So, using the example, `{1, 2, 3, 3, 7, 9}` is not acceptable because the 2 needs to remain in front of the 1. –  Dennis Meng Aug 1 '12 at 22:18
this won't work. –  Ankush Aug 5 '12 at 1:45

Here's a solution in Clojure, if you're interested in something a little more off the beaten path. It's O(n3), as it just generates all n2 stable merges and spends n time summing the products. There's a lot less messing with offsets and arithmetic than the array-based imperative solutions I've seen, which hopefully makes the algorithm stand out more. And it's pretty flexible, too: if you want to, for example, include c2*c3 as well as c1*c2 and c3*c4, you can simply replace `(partition 2 coll)` with `(partition 2 1 coll)`.

``````;; return a list of all possible ways to stably merge the two input collections
(defn stable-merges [xs ys]
(lazy-seq
(cond (empty? xs) [ys]
(empty? ys) [xs]
:else (concat (let [[x & xs] xs]
(for [merge (stable-merges xs ys)]
(cons x merge)))
(let [[y & ys] ys]
(for [merge (stable-merges xs ys)]
(cons y merge)))))))

;; split up into chunks of two, multiply, and add the results
(defn sum-of-products [coll]
(apply + (for [[a b] (partition 2 coll)]
(* a b))))

;; try all the merges, find the one with the biggest sum
(defn best-merge [xs ys]
(apply max-key sum-of-products (stable-merges xs ys)))

user> (best-merge [2 1 5] [3 7 9])
(2 1 3 5 7 9)
``````
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how is re-computation of sub problem prevented here? –  Ankush Aug 5 '12 at 1:52
It's not. I just put together something that's better than the "exponential complexity" the OP was claiming he had. TBH it's hard to imagine being any slower than n^3, since that's how fast a brute-force solution is. –  amalloy Aug 5 '12 at 3:31

I think it would be better if you provide few more test cases. But I think the normal merging of two arrays similar to merging done in merge sort will solve the problem.

The pseudocode for merging arrays is given on Wiki.

Basically it is the normal `merging algorithm used in Merge Sort`. In Merge sort the, arrays are sorted but here we are applying same merging algorithm for unsorted arrays.

`Step 0`: Let `i` be the index for `first array(A)` and `j` be the `index for second array(B`). `i=0 , j=0`

`Step 1`: `Compare A[i]=2 & B[j]=3`. Since `2<3` it will be the first element of the new `merged array(C)`. `i=1, j=0` (Add that number to the new array which is lesser)

`Step 2`: Again `Compare A[i]=1 and B[j]=3. 1<3` therefore `insert 1 in C. i++, j=0;`

`Step 3`: Again `Compare A[i]=3 and B[j]=3`. `Any number can go in C(both are same). i++, j=0;` (Basically we are increasing the index of that array from which number is inserted)

`Step 4`: Since the `array A is complete` just directly `insert the elements of Array B in C`. Otherwise repeat previous steps.

``````Array C = { 2, 1, 3, 3, 7,9}
``````

I haven't done much research on it. So if there is any test case which could fail, please provide one.

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Why only merge sort? If the ordering doesn't make sense in terms of stable merging then any algorithm solves the issue. See my answer here: stackoverflow.com/a/11709421/538514 –  Viktor Stolbin Jul 29 '12 at 13:42
I havent said I am using merge sort. Am not doing any sorting. Just using the merging alogrithm used in merge sort. Your solution is wrong because we have to do stable merging(en.wikipedia.org/wiki/Sorting_algorithm#Stability –  dejavu Jul 29 '12 at 13:53
@Android Perhaps I misunderstood, but I think applying this algorithm to `{2, 1, 9}, {7, 3, 3}` yields `{2, 1, 7, 3, 3, 9}` when the optimal solution is `{2, 1, 9, 7, 3, 3}` –  verdesmarald Jul 29 '12 at 23:51
try [10, 0, 100] and [1,2,3], with your technique you would get [1, 2, 3, 10, 0, 100], so the answer would be 1*2+2*3+3*10+10*0+0*100, but we should have a solution > 100*3 = 300 –  robert king Jul 30 '12 at 0:13