# SPOJ : Weighted Sum

You are given N integers, A[1] to A[N]. You have to assign weights to these integers such that their `weighted sum is maximized`. The weights should satisfy the following conditions :

1. Each weight should be an positive integer.
2. W[1] = 1
3. W[i] should be in the range [2, W[i-1] + 1] for i > 1

Weighted sum is defined as S = A[1] * W[1] + A[2] * W[2] + ... + A[N] * W[N]

eg :

``````n=4 , array[]={ 1 2 3 -4 } , answer = 6 when we assign { 1 2 3 2 } respective weights .
``````

So, as far as my understanding and research , no Greed solution is possible for it . I worked out many testcases on pen n paper , but couldn't get a greedy strategy .

Any ideas/hints/approaches people .

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Let `dp[i][j]` equal the maximum weighted sum we can make from `A[1..i]` by assigning weight `j` to `A[i]`. Clearly `dp[i][j] = j*A[i] + max(dp[i - 1][(j - 1)..N])`. There are `O(N^2)` states and our recurrence takes `O(N)` for each state so the overall time complexity will be `O(N^3)`. To reduce it to `O(N^2)` we can notice that there is significant overlap in our recurrence.

If `dp[i][j] = j * A[i] + max(dp[i - 1][(j - 1)..N])`, then

``````dp[i][j - 1] = (j - 1)*A[i] + max(dp[i - 1][(j - 2)..N]) = (j - 1)*A[i] + max(dp[i - 1][j - 2], dp[i - 1][(j - 1)..N]) = (j - 1)*A[i] + max(dp[i - 1][j - 2], dp[i][j] - j*A[i])
``````

Which means the recurrence takes only O(1) to compute, giving you O(N^2) time overall.

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There must be a typo in the last equation, shouldn't you have something like dp[i,j] - j*A[i] instead of dp[i,j] at the end? – user2566092 Aug 15 '13 at 20:45
Yeah, sorry about the error I had to type this up really fast – Felix Aug 15 '13 at 20:54
Given the structure I pointed out in my answer for the optimal solution, I think it might be possible to get O(N) but I think your answer is correct and it's cool to at least get down to O(N^2) – user2566092 Aug 15 '13 at 21:19

Fairly standard dynamic-programming methods can be used to solve this problem in O(N³) time. Let V(k,u) denote the best value that can be gotten using elements k...N when Wₖ₋₁ has the value u. Observe that V(k,u) is the maximum value of g·Aₖ+V(k-1,g) as g ranges from 2 to u+1, and that V(N,u) is (u+1)·AN if AN is positive, else 2·AN.

Note that u is at most k in any V(k,u) calculation, so there are N*(N-1)/2 possible values of (k,u), so the method as outlined uses O(N²) space and O(N³) time.

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O(n^3) is so so inefficient .. constraints on N<=10^5 . – Spandan Aug 15 '13 at 20:19
@Spandan: jwpat7 gave you a solution that solved your problem as you asked it. You never said anything like "Only solutions of O(N^2) are acceptable" so why the downvote? – AndyG Aug 15 '13 at 20:22

Not a solution but an idea: I would imagine some kind of hill climbing approach may give good results.

We can make the observation that the 'worst' best solution we can come up with assigns weights of

1 2 2 2 2 etc

That is, the lowest weight we can assign to any number not of index `0` is `2`. Therefore, the lowest weight we can assign to any negative number is `2`.

This initial weight distribution gives us a starting point.

I would wager that we could continually modify our weight distribution such that the sum is never decreased. That is, we never have to take a temporary hit to get a long-term gain.

The question is, what should our iteration strategy be? Because subsequent weights have some dependence on previous ones, how can we iterate?

Maybe you could do something where you take the first positive number and increment it as high as it can go, and then do the same for the next positive one, and the next.

Afterwards, you can address the first pair of (negative, positive) numbers in the sequence, where you increment both simultaneously (if possible) to see if the end result is better.

Then you perform another round of incrementing positive numbers after that sequence as high as they'll go, and then find the next pair of (negative, positive), and repeat.

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Here's a little insight that might enable you or someone else to come up with a really fast solution. Note that for an optimal solution, you can safely assume that at each step either you increase the weight by +1 from the previous weight, or you decrease the weight all the way down to the minimum of 2. To see this, suppose you have an optimal solution that violates the property. Then you have some weight > 2 at some position `i-1` and the next weight is also > 2 at position `i` but not an increase. Now consider the maximal length weakly increasing sub-sequence of weights in the optimal solution starting at position `i` (weakly increasing means that at each step in the sub-sequence, the weight does not decrease). By assumption, the optimal solution with this sub-sequence is no worse than the same solution except with the sub-sequence having 1 subtracted from all its weights. But this means that increasing all the weights in the sub-sequence by 1 will also not make the optimal solution any worse. Thus for an optimal solution, at each step you can safely assume that either you increase the weight by 1 or you set the weight to the minimum of 2.