# Min-Coin change - Best solution for a limited set

I was reading about the min-coin change problem some time ago and I want to implement it for an hypothetical automatic machine.

However, an automatic machine only has a limited access to coins and it would be good to return the minimum amount of coins needed to limit the need of the small motor that provides each coin.

The greedy algorithm can not be used here has we want the best solution, also for the machine to work needs to know what coins of each type and how many are needed. The other fact is that sometimes the machines doesn't have enough coins to give the change needed and that should light a small LED as soon as it detects it.

This is different from the questions I've seen here in stackoverflow, some use the ugly greedy approach and others don't take in consideration a real condition, the limited amount of coins. This is more applicable to real world problems.

If I am wrong I will remove the question, just wanted to have some good, stable and definite directions that could be used in real problems in the next years.

This is my first question and I hope it helps someone in the future.

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I don't know about limitation on motors of ATM, so I could see only one problem - there is not enough coins of desired value.

``````    protected void CalculateCoins(int sum)
{
int remainder = sum;
int required = 0;

// Array of coins should be sorted by value of coins
CoinQnt[] normalizedCoins = new CoinQnt[]
{
new CoinQnt { Value = 50, Qnt = 1 }
, new CoinQnt { Value = 20, Qnt = 100 }
, new CoinQnt { Value = 10, Qnt = 100 }
, new CoinQnt { Value = 5, Qnt = 100 }
, new CoinQnt { Value = 2, Qnt = 100 }
, new CoinQnt { Value = 1, Qnt = 100 }
};

Debug("Splitting {0}", sum);
// Loop through available coins
foreach( CoinQnt c in normalizedCoins )
{
if( remainder >= c.Value )
{
// Determine how many coins we need and how many are left
required = Math.Min(remainder / c.Value, c.Qnt);
Debug("Using {0} qnt of {1}", required, c.Value);
remainder -= required * c.Value;
}
}
}
``````
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This is a good example of code, however it doesn't solve the min-coin problem. For example, for example if we had to make change for 1095 of a given currency, and we had 1 banknote of 1000, 20 of 20 and 5 of 19, the result would be different from optimal. This program would give us 1000 * 1 + 4 * 20. While the optimal would be 1000 + 19*5 which is equal to 1095. –  TantoDano Mar 12 '12 at 15:55
Yes, you are right. Possible solution could be to split sum into all availables combinations. –  Aleksej Vasinov Mar 13 '12 at 7:51