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You have N guards in a line each with a demand of coins. You can skip paying a guard only if his demand is less than what you have totally paid before reaching him. Find the least number of coins you spend to cross all guards.

I think its a DP problem but can't come up with a formula. Another approach would be to binary search on the answer, but how do I verify if a number of coins is a possible answer?

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What are the constraints on N and the demands of coins? –  Armen Tsirunyan Feb 4 '13 at 12:29
@ArmenTsirunyan i guess n is just a number of guards, that is "variable" likewise the demand which is variable to each guard –  Vogel612 Feb 4 '13 at 12:31
can you skip more than one guard ? ex. 5 2 3 7, spend 5, then skip 2 & 3 ? –  Rami Jarrar Feb 4 '13 at 12:53
Yes, but obviously in this case you want to pay 5 and 2, and nothing else. –  zmbq Feb 4 '13 at 13:05
yes as zmbq said. –  marti Feb 4 '13 at 13:06

3 Answers 3

up vote 9 down vote accepted

This is indeed a dynamic programming problem.

Consider the function f(i, j), which is true (one) if there is an assignment of the first i guards which give you cost j. You can arrange function f(i, j) in a table of size n x S, where S is the sum of all the guards demand.

Let us denote d_i as the demand of guard i. You can easily compute the column f(i+1) if you have f(i) by simply scanning f(i) and assigning f(i+1, j + d_i) as one if f(i + 1, j) is true and j < d_i, or f(i + 1, j) if j >= d_i.

This runs in O(nS) time and O(S) space (you only need to keep two columns per time), which is only pseudopolynomial (and quadratic-like if demands are somehow bounded and does not grow with n).

A common trick to reduce the complexity of a DP problem is to get an upper bound B on the value of the optimal solution. This way, you can prune unnecessary rows, obtaining a time complexity of O(nB) (well, even S is an upper-bound, but a very naïve one).

It turns out that, in our case, B = 2M, where M is the maximum demand of a guard. In fact, consider the function best_assignment(i), which gives you the minimum amount of coins to pass the first i guards. Let j be the guard with demand M. If best_assignment(j - 1) > M, then obviously the best assignment for the whole sequence is pay the guards for the best assignment of the first j-1 guards and skip the others, otherwise the upper-bound is given by best_assignment(j - 1) + M < 2M. But how much best_assignment(j - 1) can be in the first case? It cannot be more than 2M. This can be proven by contradiction. Let us suppose that best_assignment(j - 1) > 2M. In this assignment, the guard j-1 is paid? No, because 2M - d_{j-1} > d_{j-1}, thus it does not need to be paid. The same argument holds for j-2, j-3, ... 1, thus no guard is paid, which is absurd unless M = 0 (a very naïve case to be checked).

Since the upper-bound is proved to be 2M, the DP illustrated above with n columns and 2M rows solves the problem, with time complexity O(nM) and space complexity O(M).

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Excellent answer. Very interesting and well displayed. –  Rerito Feb 4 '13 at 14:21
Thank you. This is still a pseudopolynomial solution, so it would be interesting to know if there is a fully polynomial one. I think that, most probably, there is one which identifies "compulsory payments" (i.e., those cases where you have to pay a guard) and deals smartly with it, but unfortunately I don't have time to further think about this problem. –  akappa Feb 4 '13 at 14:28
The complexity should be a little optimized if a balanced tree is used to represent a given f(i) column. The leaves of the tree should be the sums spent s such that f(i, s) = TRUE. This is the only improvement that came to my mind at the time –  Rerito Feb 4 '13 at 14:39
Since you only need to walk the list of possible assignment, a list is more appropriate. This will likely lower the practical efficiency of the algorithm, but unfortunately not the asymptotical one. –  akappa Feb 4 '13 at 14:47
@akappa don't you think you will get wrong in 51 , 50 , 52 ... acc . to your solution you get 51 + 52 but correct ans should be 51 + 50 –  aseem Feb 10 at 9:54
function crossCost(amtPaidAlready, curIdx, demands){
    //base case: we are at the end of the line
    if (curIdx >= demands.size()){
        return amtPaidAlready;

    costIfWePay = crossCost(amtPaidAlready + demands[curIdx], curIdx+1, demands);
    //can we skip paying the guard?
    if (demands[curIdx] < amtPaidAlready){
        costIfWeDontPay = crossCost(amtPaidAlready, curIdx+1, demands);
        return min(costIfWePay, costIfWeDontPay);
    //can't skip paying
        return costIfWePay;

This runs in O(2^N) time because it may call itself twice per execution. It's a good candidate for memoization, because it is a pure function with no side effects.

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+1 This solution can be very much efficient if the sum of all demands is small. That's why I asked OP if there were any constraints on inputs –  Armen Tsirunyan Feb 4 '13 at 13:25

Here's my approach:

int guards[N];
int minSpent;

void func(int pos, int current_spent){
    if(pos > N)
    if(pos == N && current_spent < minSpent){
        minSpent = current_spent;

    if(guards[pos] < current_spent)      // If current guard can be skipped
        func(pos+1,current_spent);       // just skip it to the next guard
    func(pos+1,current_spent+guards[pos]);   // In either cases try taking the current guard

Used in this way:

minSpent = MAX_NUM; 

This will try all possibilities its O(2^N), hope this helps.

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no, its not the same,, it will try all possibilities,, can you give a counter example, i've tried it, it works great :) –  Rami Jarrar Feb 4 '13 at 13:18
You're right, my bad ! I deleted the erroneous comment. –  Rerito Feb 4 '13 at 13:46

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