For the benefit of people who find this question in future -

As Oscar Lopez and Priyank Bhatnagar, have pointed out, this is the coin change (change-giving, change-making) problem.

In *general*, the dynamic programming solution they have proposed is the optimal solution - both in terms of (provably!) always producing the required sum using the fewest items, and in terms of execution speed. If your basis numbers are arbitrary, then use the dynamic programming solution.

If your basis numbers are "nice", however, a simpler *greedy* algorithm will do.

For example, the Australian currency system uses denominations of `$100, $50, $20, $10, $5, $2, $1, $0.50, $0.20, $0.10, $0.05`

. Optimal change can be given for any amount by repeatedly giving the largest unit of change possible until the remaining amount is zero (or less than five cents.)

Here's an instructive implementation of the greedy algorithm, illustrating the concept.

```
def greedy_give_change (denominations, amount):
# Sort from largest to smallest
denominations = sorted(denominations, reverse=True)
# number of each note/coin given
change_given = list()
for d in denominations:
while amount > d:
change_given.append(d)
amount -= d
return change_given
australian_coins = [100, 50, 20, 10, 5, 2, 1, 0.50, 0.20, 0.10, 0.05]
change = greedy_give_change(australian_coins, 313.37)
print (change) # [100, 100, 100, 10, 2, 1, 0.2, 0.1, 0.05]
print (sum(change)) # 313.35
```

For the specific example in the original post (`denominations = [1, 4, 5, 10]`

and `amount = 8`

) the greedy solution is not optimal - it will give `[5, 1, 1, 1]`

. But the greedy solution is much faster and simpler than the dynamic programming solution, so if you *can* use it, you should!