Reduce a sequence in most optimal way

We are given a sequence `a` of `n` numbers. The reduction of sequence `a` is defined as replacing the elements `a[i]` and `a[i+1]` with `max(a[i],a[i+1])`.

Each reduction operation has a cost defined as `max(a[i],a[i+1])`. After `n-1` reductions a sequence of length `1` is obtained.

Now our goal is to print the cost of the optimal reduction of the given sequence `a` such that the resulting sequence of length 1 has the minimum cost.

e.g.:

``````1

2

3

Output :

5
``````

An O(N^2) solution is trivial. Any ideas?

EDIT1: People are asking about my idea, so my idea was to traverse through the sequence pairwise and for each pair check cost and in the end reduce the pair with least cost.

``````1 2 3
2 3     <=== Cost is 2
``````

So reduce above sequence to

``````2 3
``````

now again traverse through sequence, we get cost as 3

``````2 3
3       <=== Cost is 3
``````

So total cost is 2+3=5

Above algorithm is of O(N^2). That is why I was asking for some more optimized idea.

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Any ideas? Plenty. I'm more interrested in your ideas and where you are stuck. –  Sani Huttunen Mar 5 '13 at 1:24
do you think a greedy algorithm would work? like, reduce starting from the smallest to biggest. Then the optimal reduction would be the sum of all numbers in the array excluding the smallest one. In the example provided it would be 2+3 = 5 –  dudeofea Mar 5 '13 at 1:30
Not sure if this is homework (or what grasp on algorithms you have), but you can turn this into a graph problem. I did not prove this one, but if you try the greedy method be sure to prove it, but it seems possible since a reduction is defined as `max(a[i], a[i+1])`. Notice that, by this definition, `max(a[i], a[i+2])` is not a valid reduction anyway. –  RageD Mar 5 '13 at 1:36
There is something I don't understand: Why is the cost of the resulting sequence of length 1 of any importance? And how is that defined anyway? You defined cost only for reduction operations, but how is the cost of the resulting sequence defined? (Note that the content of the resulting sequence will always be the same anyway, not matter how we find it.) –  jogojapan Mar 5 '13 at 1:48
Probably the last sentence should be: The goal is to define the order of reduction operations such that the total cost of reducing the sequence to length 1 is minimal. –  jogojapan Mar 5 '13 at 1:52

`O(n)` solution:

High-level:

One pass algorithm in which a stack will be constructed such that it will have a strict decreasing ordering (with `top()` being the smallest) and `arr[pos] < stack.top()`. The algorithm will ensure this ordering. This stack allows us to know exactly which elements should be merged in which order.

Pseudo-code:

``````stack = empty
for pos = 0:length
// stack.top > arr[pos] is implicit
if stack.top > arr[pos] > arr[pos+1]
stack.push(arr[pos])
else if stack.top > arr[pos+1] > arr[pos]
merge(arr[pos], arr[pos+1])
else while arr[pos+1] > stack.top > arr[pos]
merge(arr[pos], stack.pop)
``````

Java code:

``````Stack<Integer> stack = new Stack<Integer>();
int cost = 0;
int arr[] = {10,1,2,3,4,5};
for (int pos = 0; pos < arr.length; pos++)
if (pos < arr.length-1 && (stack.empty() || stack.peek() >= arr[pos+1]))
if (arr[pos] > arr[pos+1])
stack.push(arr[pos]);
else
cost += arr[pos+1]; // merge pos and pos+1
else
{
int last = Integer.MAX_VALUE; // required otherwise a merge may be missed
while (!stack.empty() && (pos == arr.length-1 || stack.peek() < arr[pos+1]))
{
last = stack.peek();
cost += stack.pop(); // merge stack.pop() and pos or the last popped item
}
if (last != Integer.MAX_VALUE)
{
int costTemp = Integer.MAX_VALUE;
if (!stack.empty())
costTemp = stack.peek();
if (pos != arr.length-1)
costTemp = Math.min(arr[pos+1], costTemp);
cost += costTemp;
}
}
System.out.println(cost);
``````
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+1 nice idea buddy –  SIGSTP Mar 7 '13 at 3:18

I am confused if you mean by "cost" of reduction "computational cost" i.e. an operation taking time `max(a[i],a[i+1])` or simply something you want to calculate. If it is the latter, then the following algorithm is better than O(n^2):

1. sort the list, or more precise, define `b[i]` s.t. `a[b[i]]` is the sorted list: O(n) if you can use RADIX sort, O(n log n) otherwise.
2. starting from the second-lowest item `i` in the sorted list: if left/right is lower than i, then perform reduction: O(1) for each item, update list from 2, O(n) in total.

I have no idea if that is the optimal solution, but it's O(n) for integers and O(n log n), otherwise.

edit: Realized that removing a precomputing step made it much simpler

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I have clearly mentioned that cost of reduction is defined as max(a[i],a[i+1]) i.e. reducing sequence 2,3 has cost max(2,3) i.e. 3 –  SIGSTP Mar 5 '13 at 2:13
well, then you can just replace O(1) in step 3 with O(K) with `K=max(a[i])` and you get a O(n log n +n K) solution. –  bpeter Mar 5 '13 at 2:17

If you don't consider it cheating to sort the list, then do it in `n log n` time and then merge the first two entries recursively. The total cost in this case will be the sum of the entries minus the smallest entry. This is optimal since

1. the cost will be the sum of `n-1` entries (with repeats allowed)
2. the `i`th smallest entry can appear at most `i-1` times in the cost function

The same fundamental idea works even if the list isn't sorted. An optimal solution is to merge the smallest element with its smallest neighbor. To see that this is optimal, note that

1. the cost will be the sum of `n-1` entries (with repeats allowed)
2. entry `a_i` can appear at most `j-1` times in the cost function, where `j` is the length of the longest consecutive subsequence containing `a_i` such that `a_i` is the maximum element of the subsequence

In the worst case, the sequence is decreasing and the time is `O(n^2)`.

-

Greedy approach indeed works.

You can always reduce the smallest number with its smaller neighbor.

Proof: we have to reduce smallest number at some point. Any reduction of a neighbor will make the value of neighbor at least the same(possibly) bigger, so operation that reduces minimal element a[i] will always have cost c>=min(a[i-1], a[i+1])

Now we need to

1. quickly find/remove smallest number
2. find its neigbors

I'd go with 2 RMQs on that. Doing operation 2 as a binary search. Which gives us O(N * log^2(N))

EDIT: first RMQ - values. When you remove an element put some big value there
second RMQ - "presence". 0 or 1 (value is there/isn't there). To find a [for example] left neighbor of a[i], you need to find the greatest `l`, that `sum[l,i-1] = 1`.

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Doing a binary search assumes the list is sorted, in which case the optimal solution is to merge the first two entries (or last two is the sequence is decreasing). –  PengOne Mar 5 '13 at 5:30
Sorry, I didn't have a lot of time when writing the answer. Implication was: do a binary search over second rmq. –  kilotaras Mar 5 '13 at 19:08

Consider the whole array as leaves of a balanced binary tree (not a search tree). At each intermediate node you will have the larger of the two children. The first round will be to delete the children and make their parent as the leaf. In each iteration you will lose one level of the tree and hence the number of rounds will be the height of the tree which is ceil(log(n)).

For example:

``````1 4 2 8 5 7 (6 items means number of iterations = ceil(log(6) = 3)
4 8 7
8 7
8
``````

After understanding the question better, you can still construct the tree in O(n) and traverse it in post-order. That should give you an O(n) solution. The tree constructed will have at most 2*(2^ceil(log(n))) nodes which is O(n) extra space complexity.

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You answer the wrong question. The number of reductions is always (n-1). But reduction (1,2,100)->(1,100)->(100) has cost 200 while (1,2,100)->(2,100)->(100) has cost 101. –  kilotaras Mar 5 '13 at 2:03
Yes, but your way of calculating the number of operations is also incorrect: In each iteration, all leaves must be taken into account, not just one. So this isn't O(log n). –  jogojapan Mar 5 '13 at 2:05
Thanks! Understood and edited the algorithm. It was tough to understand without the example. We should be able to get an O(n) space and O(n) time solution with the same data structure. –  user1952500 Mar 5 '13 at 2:38