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)`

.