# Removal of billboards from given ones

I came across this question

ADZEN is a very popular advertising firm in your city. In every road you can see their advertising billboards. Recently they are facing a serious challenge , MG Road the most used and beautiful road in your city has been almost filled by the billboards and this is having a negative effect on
the natural view. On people's demand ADZEN has decided to remove some of the billboards in such a way that there are no more than K billboards standing together in any part of the road. You may assume the MG Road to be a straight line with N billboards.Initially there is no gap between any two adjecent billboards. ADZEN's primary income comes from these billboards so the billboard removing process has to be done in such a way that the billboards remaining at end should give maximum possible profit among all possible final configurations.Total profit of a configuration is the sum of the profit values of all billboards present in that configuration. Given N,K and the profit value of each of the N billboards, output the maximum profit that can be obtained from the remaining billboards under the conditions given.

Input description

1st line contain two space seperated integers N and K. Then follow N lines describing the profit value of each billboard i.e ith line contains the profit value of ith billboard.

``````    Sample Input
6 2
1
2
3
1
6
10

Sample Output
21
``````

Explanation

In given input there are 6 billboards and after the process no more than 2 should be together. So remove 1st and 4th billboards giving a configuration _ 2 3 _ 6 10 having a profit of 21. No other configuration has a profit more than 21.So the answer is 21.

``````    Constraints
1 <= N <= 1,00,000(10^5)
1 <= K <= N
0 <= profit value of any billboard <= 2,000,000,000(2*10^9)
``````

I think that we have to select minimum cost board in first k+1 boards and then repeat the same untill last,but this was not giving correct answer for all cases. i tried upto my knowledge,but unable to find solution. if any one got idea please kindly share your thougths.

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so is this homework? –  soulcheck Feb 21 '12 at 13:03
–  Flexo May 13 '12 at 8:45
@HighPerformanceMark Mine does! ;) –  J. Steen Aug 16 '12 at 11:37

It's a typical DP problem. Lets say that P(n,k) is the maximum profit of having k billboards up to the position n on the road. Then you have following formula:

`````` P(n,k) = max(P(n-1,k), P(n-1,k-1) + C(n))
P(i,0) = 0 for i = 0..n
``````

Where c(n) is the profit from putting the nth billboard on the road. Using that formula to calculate P(n, k) bottom up you'll get the solution in O(nk) time.

I'll leave up to you to figure out why that formula holds.

edit

It still is a DP problem, just the formula is different. Let's say that P(v,i) means the maximum profit at point v where last cluster of billboards has size i. Then P(v,i) can be described using following formulas:

``````P(v,i) = P(v-1,i-1) + C(v) if i > 0
P(v,0) = max(P(v-1,i) for i = 0..min(k, v))
P(0,0) = 0
``````

You need to find `max(P(n,i) for i = 0..k))`.

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i can't understand this "k billboards upto the position n ",can you please elaborate.here what is k? .Is it the value given in input(i.e) atmost k billboards are consequetive –  user1218927 Feb 21 '12 at 12:20
imagine that the road is a integer axis. In each point you can either have the billboard standing or not. So "k billboards up to the position n" means that you have k billboards put in some positions up to the position n. Ie. 3 billboards up to the position 5 means either: `BB_B_` or `B_B_B` or `BBB__` etc... –  soulcheck Feb 21 '12 at 12:23
how you will check that atmost k are grouped or not.and also mention that the k value given in problem and you mentioned are same or not –  user1218927 Feb 21 '12 at 12:29
Ah, ok. Didn't notice that. –  soulcheck Feb 21 '12 at 12:38
@user1218927 see my update. –  soulcheck Feb 21 '12 at 12:53

This problem is one of the challenges posted in www.interviewstreet.com ...

I'm happy to say I got this down recently, but not quite satisfied and wanted to see if there's a better method out there.

soulcheck's DP solution above is straightforward, but won't be able to solve this completely due to the fact that K can be as big as N, meaning the DP complexity will be O(NK) for both runtime and space.

Another solution is to do branch-and-bound, keeping track the best sum so far, and prune the recursion if at some level, that is, if currSumSoFar + SUM(a[currIndex..n)) <= bestSumSoFar ... then exit the function immediately, no point of processing further when the upper-bound won't beat best sum so far.

The branch-and-bound above got accepted by the tester for all but 2 test-cases. Fortunately, I noticed that the 2 test-cases are using small K (in my case, K < 300), so the DP technique of O(NK) suffices.

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The DP technique is fast enough. I am getting std::bad_alloc though, :(. –  Hindol Nov 12 '12 at 4:52

soulcheck's (second) DP solution is correct in principle. There are two improvements you can make using these observations:

1) It is unnecessary to allocate the entire DP table. You only ever look at two rows at a time.

2) For each row (the v in P(v, i)), you are only interested in the i's which most increase the max value, which is one more than each i that held the max value in the previous row. Also, i = 1, otherwise you never consider blanks.

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This looks like a linear programming problem. This problem would be linear, but for the requirement that no more than K adjacent billboards may remain.

See wikipedia for a general treatment: http://en.wikipedia.org/wiki/Linear_programming

Visit your university library to find a good textbook on the subject.

There are many, many libraries to assist with linear programming, so I suggest you do not attempt to code an algorithm from scratch. Here is a list relevant to Python: http://wiki.python.org/moin/NumericAndScientific/Libraries

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It's apparent from the question that it's meant to be "coded from scratch". It's looks like something that would show up in a Java programming challenge. –  LastCoder Feb 21 '12 at 19:40
@LastCoder: Perhaps. In any case, this is the acme of what you should not code from scratch (almost on a par with crypto code), because it's easy to get wrong. –  Marcin Feb 21 '12 at 19:42
Nope, you can not formulate constraints into canonical form, therefore, it is not LP. –  Ivor Prebeg Nov 27 '12 at 9:24
@IvorPrebeg Do you just ignore the parts of answers that make your comments invalid? –  Marcin Nov 27 '12 at 19:29

Let `P[i]` (where i=1..n) be the maximum profit for billboards `1..i` IF WE REMOVE billboard `i`. It is trivial to calculate the answer knowing all P[i]. The baseline algorithm for calculating P[i] is as follows:

``````for i=1,N
{
P[i]=-infinity;
for j = max(1,i-k-1)..i-1
{
P[i] = max( P[i], P[j] + C[j+1]+..+C[i-1] );
}
}
``````

Now the idea that allows us to speed things up. Let's say we have two different valid configurations of billboards `1` through `i` only, let's call these configurations `X1` and `X2`. If billboard `i` is removed in configuration `X1` and `profit(X1) >= profit(X2)` then we should always prefer configuration `X1` for billboards `1..i` (by `profit()` I meant the profit from billboards `1..i` only, regardless of configuration for `i+1..n`). This is as important as it is obvious.

We introduce a doubly-linked list of tuples `{idx,d}`: `{{idx1,d1}, {idx2,d2}, ..., {idxN,dN}}`.

• `p->idx` is index of the last billboard removed. `p->idx` is increasing as we go through the list: `p->idx < p->next->idx`
• `p->d` is the sum of elements `(C[p->idx]+C[p->idx+1]+..+C[p->next->idx-1])` if `p` is not the last element in the list. Otherwise it is the sum of elements up to the current position minus one: `(C[p->idx]+C[p->idx+1]+..+C[i-1])`.

Here is the algorithm:

``````P[1] = 0;
// sum of elements starting from the index at top of the list
sum = C[0]; // C[list->begin()->idx]+C[list->begin()->idx+1]+...+C[i-1]
for i=2..N
{
if( i - list->begin()->idx > k + 1 ) // the head of the list is "too far"
{
sum = sum - list->begin()->d
list.RemoveNodeFromBeginning()
}
// At this point the list should containt at least the element
// added on the previous iteration. Calculating P[i].
P[i] = P[list.begin()->idx] + sum
// Updating list.end()->d and removing "unnecessary nodes"
// based on the criterion described above
list.end()->d = list.end()->d + C[i]
while(
(list is not empty) AND
(P[i] >= P[list.end()->idx] + list.end()->d - C[list.end()->idx]) )
{
if( list.size() > 1 )
{
list.end()->prev->d += list.end()->d
}
list.RemoveNodeFromEnd();
}
sum = sum + C[i]
}
``````
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``````//shivi..coding is adictive!!
#include<stdio.h>

long long int arr[100001];
long long  int sum[100001];
long long  int including[100001],excluding[100001];
long long int maxim(long long int a,long long int b)
{if(a>b) return a;return b;}

int main()
{
int N,K;
scanf("%d%d",&N,&K);
for(int i=0;i<N;++i)scanf("%lld",&arr[i]);

sum[0]=arr[0];
including[0]=sum[0];
excluding[0]=sum[0];
for(int i=1;i<K;++i)
{
sum[i]+=sum[i-1]+arr[i];
including[i]=sum[i];
excluding[i]=sum[i];
}

long long int maxi=0,temp=0;
for(int i=K;i<N;++i)
{
sum[i]+=sum[i-1]+arr[i];
for(int j=1;j<=K;++j)
{
temp=sum[i]-sum[i-j];
if(i-j-1>=0)
temp+=including[i-j-1];
if(temp>maxi)maxi=temp;
}
including[i]=maxi;
excluding[i]=including[i-1];
}
printf("%lld",maxim(including[N-1],excluding[N-1]));
}

//here is the code...passing all but 1 test case :) comment improvements...simple DP
``````
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I coded it in c++ using DP in O(nlogk). Idea is to maintain a multiset with next k values for a given position. This multiset will typically have k values in mid processing. Each time you move an element and push new one. Art is how to maintain this list to have the profit[i] + answer[i+2]. More details on set:

```

/*
* Observation 1: ith state depends on next k states i+2....i+2+k
* We maximize across this states added on them "accumulative" sum
*
* Let Say we have list of numbers of state i+1, that is list of {profit + state solution}, How to get states if ith solution
*
* Say we have following data k = 3
*
* Indices:     0   1   2   3   4
* Profits:     1   3   2   4   2
* Solution:    ?   ?   5   3   1
*
* Answer for [1] = max(3+3, 5+1, 9+0) = 9
*
* Indices:     0   1   2   3   4
* Profits:     1   3   2   4   2
* Solution:    ?   9   5   3   1
*
* Let's find answer for [0], using set of [1].
*
* First, last entry should be removed. then we have (3+3, 5+1)
*
* Now we should add 1+5, but entries should be incremented with 1
*      (1+5, 4+3, 6+1) -> then find max.
*
*  Could we do it in other way but instead of processing list. Yes, we simply add 1 to all elements
*
*  answer is same as: 1 + max(1-1+5, 3+3, 5+1)
*
*/
```

``````ll dp()
{
multiset<ll, greater<ll> > set;

mem[n-1] = profit[n-1];

ll sumSoFar = 0;

lpd(i, n-2, 0)
{
if(sz(set) == k)

if(i+2 < n)
{
sumSoFar += profit[i];
}

if(n-i <= k)
mem[i] = profit[i] + mem[i+1];
else
mem[i] = max(mem[i+1], *set.begin()+sumSoFar);
}

return mem[0];
}
``````
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