# Help with maths/coding on possible combinations of a set to make up a total - C#

I have a coding/maths problem that I need help translating into C#. It's a poker chip calculator that takes in the BuyIn, the number of players and the total amount of chips for each colour (there are x amount of colours) and their value.

It then shows you every possible combination of chips per person to equal the Buy In. The user can then pick the chipset distribution they would like to use. It's best illustrated with a simple example.

• Number of Players: 1
• 10 Red Chips, \$1 value
• 10 Blue Chips, \$2 value
• 10 Green Chips, \$5 value

So, the possible combinations are:

R/B/G

• 10/0/0
• 8/1/0
• 6/2/0
• 5/0/1
• 4/3/0
• 2/4/0
• 1/2/1

etc.

I have spent a lot of time trying to come up with an algorithm in C#/.NET to work this out. I am stumbling on the variable factor - there's usually only 3 or 4 different chips colours in a set, but there could be any amount. If you have more than one player than you have to count up until TotalChips / NumberOfPlayers.

I started off with a loop through all the chips and then looping from 0 up to NumberOfChips for that colour. And this is pretty much where I have spent the last 4 hours... how do I write the code to loop through x amount of chips and check the value of the sum of the chips and add it to a collection if it equals the BuyIn? I need to change my approach radically methinks...

Can anyone put me on the right track on how to solve this please? Pseudo code would work - thank you for any advice!

The below is my attempt so far - it's hopeless (and wont compile, just an example to show you my thought process so far) - Might be better not to look at it as it might biased you on a solution...

``````   private void SplitChips(List<ChipSuggestion> suggestions)
{

decimal checkTotal = 0;
ChipSuggestion suggestion;

//loop through each colour
foreach (Chip chip in (PagedCollectionView)gridChips.ItemsSource)
{
//for each value, loop through them all again
foreach (Chip currentChip in (PagedCollectionView)gridChips.ItemsSource)
{
//start at 0 and go all the way up
for (int i = 0; i < chip.TotalChipsInChipset; i++)
{
checkTotal = currentChip.ChipValue * i;

//if it is greater than than ignore and stop
if (checkTotal > valueRequired)
{
break;
}
else
{
//if it is equal to then this is a match
if (checkTotal == valueRequired)
{
suggestion = new ChipSuggestion();
suggestion.SuggestionName = "Suggestion";

chipRed.NumberPerPlayer = i;

chipBlue.NumberPerPlayer = y;

chipGreen.NumberPerPlayer = 0;

break;
}

}
}
}
}
}
``````
-
Just so I understand the question: You have a set of different chips you can use, worth different amounts. You have a target amount (\$10 in your example), and you want to work out all the combinations of those chips you could use to reach that target amount? What does "number of players" have to do with the solution? – Lasse V. Karlsen Jul 11 '10 at 14:06
Yes, so NumberOfPlayers affects the number of chips. There are X amount of chips in your chip set, and if you have 2 players and use 5 reds per person then you need 5*2 reds. – Rodney Jul 11 '10 at 15:24

Here's an implementation that reads the number of chips, the chips (their worth and amount) and the buyin and displays the results in your example format. I have explained it through comments, let me know if you have any questions.

``````class Test
{
static int numChips;
static List<int> chips = new List<int>(); // chips[i] = value of chips of color i
static List<int> amountOfChips = new List<int>(); // amountOfChips[i] = number of chips of color i

static void generateSolutions(int sum, int[] solutions, int last)
{
if (sum > buyIn) // our sum is too big, return
return;

if (sum == buyIn) // our sum is just right, print the solution
{
for (int i = 0; i < chips.Count; ++i)
Console.Write("{0}/", solutions[i]);
Console.WriteLine();

return; // and return
}

for (int i = last; i < chips.Count; ++i) // try adding another chip with the same value as the one added at the last step.
// this ensures that no duplicate solutions will be generated, since we impose an order of generation
if (amountOfChips[i] != 0)
{
--amountOfChips[i]; // decrease the amount of chips
++solutions[i]; // increase the number of times chip i has been used

generateSolutions(sum + chips[i], solutions, i); // recursive call

++amountOfChips[i]; // (one of) chip i is no longer used
--solutions[i]; // so it's no longer part of the solution either
}
}

static void Main()
{
Console.WriteLine("Enter the number of chips types:");
Console.WriteLine("Enter {0} chips values:", numChips);
for (int i = 0; i < numChips; ++i)

Console.WriteLine("Enter {0} chips amounts:", numChips);
for (int i = 0; i < numChips; ++i)

int[] solutions = new int[numChips];

generateSolutions(0, solutions, 0);
}
}
``````

10
Enter the number of chips types:
3
Enter 3 chips values:
1
2
5
Enter 3 chips amounts:
10
10
10
10/0/0/
8/1/0/
6/2/0/
5/0/1/
4/3/0/
3/1/1/
2/4/0/
1/2/1/
0/5/0/
0/0/2/

-
Thanks a million IVlad - I can't believe you answered that in half an hour without a full knowledge of the problem when I battled for hours... One question - your solution does not take into account Number Of Players - this affects the amount of chips available - do I take this line: if (amountOfChips[i] != 0) and divide it by NumberOfPlayers (ie. chips available per person) when I initiate the array? Thanks again. – Rodney Jul 13 '10 at 19:58
@Rodney - I don't really understand how number of players matters :). This gives you all the possible combinations for a single player. So let's take your example. If you have 3 players, then I'm guessing one of them picks his chips first, right? If the first one picks `8/1/0`, then the second one is left to pick from `10 - 8 = 2 reds, 10 - 1 = 9 greens, 10 - 0 = 10 blues`. After the second one picks, the possibilities are again reduced for the third. So I would think you just subtract the choice of each player then rerun the same algorithm. Let me know if this isn't what you have in mind. – IVlad Jul 13 '10 at 20:08
I see this in your post: `If you have more than one player than you have to count up until TotalChips / NumberOfPlayers.` - in this case, I would just divide each `amountOfChips[i]` by `numPlayers` before running the algorithm. I don't really follow the logic of dividing the chips by the number of players though. – IVlad Jul 13 '10 at 20:10

Break the problem down recursively by the number of kinds of chips.

For the base case, how many ways are there to make an \$X buy-in with zero chips? If X is zero, there is one way: no chips. If X is more than zero, there are no ways to do it.

Now we need to solve the problem for N kinds of chips, given the solution for N - 1. We can take one kind of chip, and consider every possible number of that chip up to the buy-in. For example, if the chip is \$2, and the buy-in is \$5, try using 0, 1, or 2 of them. For each of these tries, we have to use only the remaining N - 1 chips to make up the remaining value. We can solve that by doing a recursive call, and then adding our current chip to each solution it returns.

``````private static IEnumerable<IEnumerable<Tuple<Chip, int>>> GetAllChipSuggestions(List<Chip> chips, int players, int totalValue)
{
return GetAllChipSuggestions(chips, players, totalValue, 0);
}

private static IEnumerable<IEnumerable<Tuple<Chip, int>>> GetAllChipSuggestions(List<Chip> chips, int players, int totalValue, int firstChipIndex)
{
if (firstChipIndex == chips.Count)
{
// Base case: we have no chip types remaining
if (totalValue == 0)
{
// One way to make 0 with no chip types
return new[] { Enumerable.Empty<Tuple<Chip, int>>() };
}
else
{
// No ways to make more than 0 with no chip types
return Enumerable.Empty<IEnumerable<Tuple<Chip, int>>>();
}
}
else
{
// Recursive case: try each possible number of this chip type
var allSuggestions = new List<IEnumerable<Tuple<Chip, int>>>();
var currentChip = chips[firstChipIndex];
var maxChips = Math.Min(currentChip.TotalChipsInChipset / players, totalValue / currentChip.ChipValue);
for (var chipCount = 0; chipCount <= maxChips; chipCount++)
{
var currentChipSuggestion = new[] { Tuple.Create(currentChip, chipCount) };
var remainingValue = totalValue - currentChip.ChipValue * chipCount;
// Get all combinations of chips after this one that make up the rest of the value
foreach (var suggestion in GetAllChipSuggestions(chips, players, remainingValue, firstChipIndex + 1))
{
}
}
return allSuggestions;
}
}
``````
-
Quartermeister - thanks VERY much for the great solution - I am just trying to work through and understand it (it's quite advanced syntax for me!) - I'll get back to you in a while ;) – Rodney Jul 13 '10 at 21:27

For some large combinations this is propably not solvable in finite time. (It is a NP problem)

http://en.wikipedia.org/wiki/Knapsack_problem