# How to implement a dealer class without storing a deck of cards?

• Question

Even only 52 cards, the `permutationIndex` where I describe in Explanations section, would be a huge number; it is a number in one of `52!`, and need 29 bytes to store.

Thus I don't know a simple way to calculate the `permutationIndex` of a huge range, and store the index with a mininal cost, or maybe it can also be calculated. I'm thinking solution of this question would be three algorithms:

1. An algorithm which compute the correct `permutationIndex` to implement the `Dealing` method

2. An algorithm which compute the correct `permutationIndex` to implement the `Collect` method

3. An algorithm which stores(or computes) `permutationIndex` with a minimal cost

• Explanations

I originally try to implement a integer handle generator of a range from `int.MinVale` to `int.MaxValue` using permutation.

Because the range is really huge for that, thus I start from implement a `Dealer` class with 52 cards which doesn't really store a deck of cards like hashset or array, and even don't want random(except initial).

With a given range of ordinal numbers, I consider every sequence of one of full permutations has a index, and named it `permutationIndex`. I use the index to remember which permutation it is and don't really store a sequence. The sequence is one of the possible order of the deck of card.

And here is an example of emulation in animated graphics to show what I thought of.

Everytime I dealt a card, I change the `permutationIndex` and `dealt`(count of dealt cards), that I know which cards are those dealt, and which are still in hand. When I collect a dealt card back, I'll know the card number, and put it on the top, it's also become the card for next time to deal. In the animation, `colleted` is the card number.

• Description of code

A conceptual sample `Dealer` class for only three 3 is as following. The code is written in , and I'm also considering any solutions.

Here're some descriptions of the sample code

• With the method `Dealing()`, we get a number of the card which treat as dealt. It always returns the right most number (relevant to the array) and then rolls the number left from it (say the next available) to the right most position by changing `permutationIndex`.

• The method `Collect(int)` is for collecting and put the dealt cards back into the deck. It would change `permutationIndex` also, according to what the number of card was returned back to the dealer.

• The integer `dealt` tells how many cards we've dealt; from the left most to the count stored in `dealt` are dealt cards. With `permutationIndex`, we know the sequence of cards.

• The `int[,]` array in the sample code is not used, just for helping imagine the permutations. The switch statements are considered to be implemented with algorithms which compute for the `permutationIndex`.

• The `permutationIndex` is the same thing described in this answer of
Fast permutation -> number -> permutation mapping algorithms

• Sample code

``````public static class Dealer {
public static void Collect(int number) {
if(1>dealt)
throw new IndexOutOfRangeException();

switch(permutationIndex) {
case 5:
case 0:
switch(number) {
case 3:
break;

case 2:
permutationIndex=1;
break;

case 1:
permutationIndex=4;
break;
}

break;

case 4:
case 3:
switch(number) {
case 3:
permutationIndex=5;
break;

case 2:
permutationIndex=2;
break;

case 1:
break;
}

break;

case 2:
case 1:
switch(number) {
case 3:
permutationIndex=0;
break;

case 2:
break;

case 1:
permutationIndex=3;
break;
}

break;
}

--dealt;
}

public static int Dealing() {
if(dealt>2)
throw new IndexOutOfRangeException();

var number=0;

switch(permutationIndex) {
case 5:
permutationIndex=3;
number=3;
break;

case 4:
permutationIndex=0;
number=1;
break;

case 3:
permutationIndex=1;
number=1;
break;

case 2:
permutationIndex=4;
number=2;
break;

case 1:
permutationIndex=5;
number=2;
break;

case 0:
permutationIndex=2;
number=3;
break;
}

++dealt;
return number;
}

static int[,] sample=
new[,] {
{ 1, 2, 3 }, // 0
{ 1, 3, 2 }, // 1
{ 3, 1, 2 }, // 2
{ 3, 2, 1 }, // 3
{ 2, 3, 1 }, // 4
{ 2, 1, 3 }, // 5
};

static int permutationIndex;
static int dealt;
}
``````
-
Why not use auto-incremented value to get a new handle? –  Sergey Brunov Jan 31 '13 at 6:29
@KenKin, for example, you want the handle 1 will be available after `Release(1)`, i.e. next `GetHandle()` call will return handle 1? –  Sergey Brunov Jan 31 '13 at 6:37
Storing the `permutationIndex` will need 29 bytes, Storing the deck in a byte array will need 52 bytes. That means you just gain 23 bytes but your code will be much longer and complex. So you trade a negligible reduction of data space for a significant increase of code space. –  Henry Feb 8 '13 at 7:19
"How can we accomplish this?" - accomplish what, precisely? There are more than 2<sup>32</sup> possible permutations, so unless you're happy with some sequences being impossible to deal, it's hard to see how you're going to manage with just an `int` as storage... –  Jon Skeet Mar 1 '13 at 10:51
I'm still not seeing a question - nor a reason to use a 29-byte integer with pretty complicated arithmetic instead of either a 52-byte or 39-byte array with the appropriate cards pre-dealt. –  Jon Skeet Mar 1 '13 at 19:24

Not exactly what you are trying to accomplish here, but if you want to deal from a random ordering of a deck of cards, you use a shuffle algorithm. The typical shuffle algorithm is Fisher-Yates. The shuffle algorithm will create an array listing the card numbers in random order ( 13,5,7,18,22,... etc ). To deal you start at the first element in the array and continue forward.

-
The amount of memory you would need to deal with permutations of 52! would be greater than the amount of memory needed for a shuffle. –  Tyler Durden Feb 6 '13 at 18:55
I'm not saying to store full permutations, but a huge numerical index. We would need to store only one huge number. –  Ken Kin Feb 6 '13 at 19:02
I know what is required. Any implementation that involves manipulating the permutation information for 52 different items will require a lot more memory than a shuffle. If you think you are saving memory or computational speed by avoiding a shuffle you are operating under a mistaken assumption. –  Tyler Durden Feb 7 '13 at 15:38
Actually, storing 52 "ints" would take at least 52*(1 byte)=416 bits, or 52*(6 bits)=312 bits=39 bytes (considering we could store each card number in an integer number of bits, and pack them). This carries more information than just the permutation, which will carry 226 bits of information or 29 bytes. The computational overhead is huge, though, so it seems like the best way to go is to store 52 bytes. After all "minimal cost" isn't defined just by how much memory we use. Memory is much cheaper than CPU these days. Also, complexity is majorly reduced which makes it far easier to make it work. –  DDS Feb 8 '13 at 17:22
Please note that when you paste all the bits of the list of cards together, you essentially get 1 huge number. The only real difference between this and a permutation number is that you can, in the list, store a deck that has duplicates. This takes up the extra bits. That base-52 list would take at least 297 bits vs 226 bits for the permutation. All in all, storing "1 huge number" is the exact same as storing a list of small numbers. –  DDS Feb 8 '13 at 17:26

I am also struggling to see the whole picture here, but you could convert each permutation to base(52) with a single character representing each card and have a string representing each permutation.

So Spades could be `1-9 (ace - 9)`, `0ABC (10, J Q K)`, then `DEFG`... starting the hearts and so on.

So a deck of 3 cards, 2 Spade (2), 3 Heart (F) and 2 Diamond (say e), would have these permutation numbers:

``````2Fe
2eF
F2e
Fe2
eF2
e2F
``````

You could convert these back and forth to a int/long/bigint by doing base 52 to base 10 conversions.

So e2F would be `F + 2*52 + e * 52^2` which would be `16 + 2*52 + 43*52*52 = 116392`

So 116392 would be your permutation number.

(btw. I'm guessing about it 2 diamond being 'e' and 43, you can count it up and see exact what it would be)

-

One way to tackle this is to use (pseudo)random number generator (like a Mersenne Twister), then store only the seed number for each deal. Since you get the same sequence of random numbers each time from the same seed, it serves to represent the whole deal (using the random numbers generated from that seed to drive what cards are dealt).

[edit...]

Some pseudo-code for the deal:

``````while (#cards < cardsNeed)
card = getCard(random())
continue
[do something with the card...]
``````
-
After you edit I understand what you told. I think that I don't really enumerate the cards unless that is necessary. Likely this question is used to replace `random` with certain. I originally describe this question in a `HandleGenerater`, but perhaps it confused people. A dealer class is, in fact, an analogy of such a generator. –  Ken Kin Feb 8 '13 at 23:54

If I've understood you right, the following code implements this:

``````public class Dealer {
public int Dealing() {
var number=
_freeCards.Count>0
?_freeCards.Dequeue()
:_lastNumber++;

return number;
}

public void Collect(int number) {
if(!_dealtCards.Remove(number))
throw new ArgumentException("Card is not in use", "number");

_freeCards.Enqueue(number);
}

readonly Queue<int> _freeCards=new Queue<int>(); // "Pool" of free cards.
int _lastNumber;
}
``````
-
Maybe I should change the title to `how to implement a dealer class without recording all the cards`. –  Ken Kin Jan 31 '13 at 6:56
@KenKin, yes, that would be great. –  Sergey Brunov Jan 31 '13 at 6:58
@KenKin, oh, wait a minute. Maybe we can implement a method something like `GetPermutation(handle)` to get the array? Then, there is no need to store the entire permutation. –  Sergey Brunov Jan 31 '13 at 7:05
@KenKin, by now I haven't understood completely the functionality you want to implement. Could you please add something like unit-test for the class you're implementing to the question? –  Sergey Brunov Jan 31 '13 at 7:17
@KenKin, I have not seen the clear correlation between the manager and permutations. The manager is something like a deck of cards? Maybe it would be better to add some image or diagram to improve the question? –  Sergey Brunov Jan 31 '13 at 7:48

While I have a bit of a problem understanding what you are really trying to accomplish here, I suppose a coprime will generate a bunch of permutation numbers; that is: if you don't care too much about the distribution. You can use the Euclidian algorithm for that.

Algebra (set theory) states that you can simply use x = (x + coprime) % set.Length to get all elements in the set. I suppose each coprime is a permutation number as you describe it.

That said I'm not sure what distribution you get when using a generated coprime as 'random number generator'; I suppose certain distributions will occur more frequently than others and that a lot of distributions will be excluded from the generated numbers, for the simple reason that the generator will pick numbers in a ring. I'm being a bit creative here so perhaps it fits your needs, although it probably won't be the answer you're looking for.

-
I'm actually not wanting random numbers. Instead, I want algorithms, which oprerates on the `permutationIndex`, whatever the number of a dealt card is collected, it only changes the index, so does `Dealing()`. Most of time we don't enumerate on the sequence of cards, and trying keep it unknown unless the enumeration is really needed. –  Ken Kin Feb 10 '13 at 2:25

I really don't get your question, but I interpret it like this: you want to calculate the `permutationIndex` of a sequence of 52 cards. A given permutation index maps one-to-one to a sequence of cards. Since there are 52! possible arrangements of 52 cards, you'll need at least 226 bits, or 29 bytes. So, your `permutationIndex` will already be very big!

Since your permutation index is already 29 bytes long, some extra bytes won't make much of a difference and make the solution a lot easier.

For example, you could map each letter of the Latin alphabet to a card. Given that we have 26 lower case letters, 26 upper case letters, we have lo and behold 52 letters available to represent the 52 cards.

```  abcdefghijklm      nopqrstuvwxyz
♥ A234567890JQK    ♦ A234567890JQK

ABCDEFGHIJKLM      NOPQRSTUVWXYZ
♣ A234567890JQK    ♠ A234567890JQK
```

Now you can make a string of 52 letters. Each unique letter string represents a unique permutation of 52 cards. With this you can:

• Generate a random string of letters to get a random permutation.
• Immediately find out what card is where just by looking at the letter at a given position.
• Shuffle, reorder, insert and remove cards easily.

Each character in a string is represented (in C#) as a 16-bit Unicode value, but for 52 cards you would only need 6 bits. So you have some more options to choose a representation:

1. 832 bits, or 104 bytes: string of 52 Unicode characters
2. 416 bits, or 52 bytes: array of 52 bytes
3. 320 bits, or 40 bytes: array of 10 32-bit integers to hold 52 * 6 bits
4. 312 bits, or 39 bytes: array of 39 bytes to hold 52 * 6 bits
5. 226 bits, or 29 bytes: absolute lower bound

Representations 3 and 4 require quite some clever bit fiddling to get the 6 bits for a specific card out of the sequence. I would recommend representation 2, which preserves most of the advantages mentioned above.

When you are using a binary representation instead of a character string representation, then you can create an enum with a unique value for each card, and use that:

``````public enum Cards : byte
{
HeartsAce
HeartsTwo
// ...
HeartsTen
HeartsJack
HeartsQueen
HeartsKing
DiamondsAce
DiamondsTwo
// ...
}
``````
-
@KenKin I don't really understand your comment. With 'I'm finding' you mean 'I need'? You need an algorithm to go from a permutation index to a sequence of cards and the other way around...? –  Virtlink Mar 6 '13 at 19:28
Thank you very much. I'm not a native English speaker. If the comment is confusing, then I'm removing it. What I mean is, I need to implement the class with the ways which do the things with the `permutationIndex`, and not other ways. –  Ken Kin Mar 6 '13 at 19:43

You have working - and extremely efficient c# example for The kth Permutation of Order n (aka PermutationIndex) at this very old post:

For those interested in Combinations topic:

I suggest that you read through, before going into specific implementation.

-
Thank you. How I operate on the index without enumerating it's elements? –  Ken Kin Mar 7 '13 at 22:57
As I said, you have to read all article and check source code. Example would be: var result = new Permutation(3, 1).ToString(). You get this - "( 0 2 1 )", which is 2nd permutation (index 1), of 3 elements. –  Nenad Mar 8 '13 at 19:05
I would think that I have a better implemention of that, though I implemented without it telling the index, but I think that I could; see Check if permutations of characters are contained in text file. –  Ken Kin Mar 8 '13 at 19:57
both these code based on the same algorithm; but my question is perform the operations with the index, according to some rule not known to me, without enumerating on the elements. This algorithm actually construct the index by internally built the sequence. Then I'd be better use a hashset or array directly, rather with `permutationIndex`. Thus, it's not the answer for me. –  Ken Kin Mar 8 '13 at 19:58
Algorith doesn't enumarate on elements, but again, you would need to read article to know that. It is just capable to tell you "44th permutation of 5 elements is ....". And it is able to do few more things. Anyway... good luck! –  Nenad Mar 8 '13 at 20:43

Like the others I am not sure what you want to do but if you want to save as much space a possible on the communication/storage of the dealt cards I would do the following:

I would store the cards dealt on a single Long using a enum with the flag attribute so I could use bitwise comparisons to see which card has been dealt.

Because each card is a separate "flag" with a unique number which is set to the exponent of 2 so they will never clash.

In total even if you deal all the cards the storage will still be 8 bytes. any extra data you need you can bolt on the end.

Please see the working example below.

``````using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace ConsoleApplication12
{
class Program
{
static void Main(string[] args)
{
// Because each card is unique you could use Flag attributed Enum see the enum below and set each item a unique value I used 2 to the power of 52
Cards cardsdealt = Cards.Clubs_10 | Cards.Clubs_2 | Cards.Diamonds_3;

if ((cardsdealt & Cards.Clubs_10) == Cards.Clubs_10)
{
Console.WriteLine("Card.Clubs_10 was dealt");
}

// Storage would always be 8 bytes for the long data type
}

[Flags]
public enum Cards : long
{
Hearts_Ace = 8192,
Hearts_2 = 16384,
Hearts_3 = 32768,
Hearts_4 = 65536,
Hearts_5 = 131072,
Hearts_6 = 262144,
Hearts_7 = 524288,
Hearts_8 = 1048576,
Hearts_9 = 2097152,
Hearts_10 = 4194304,
Hearts_Jack = 8388608,
Hearts_Queen = 16777216,
Hearts_King = 33554432,
Diamonds_Ace = 67108864,
Diamonds_2 = 134217728,
Diamonds_3 = 268435456,
Diamonds_4 = 536870912,
Diamonds_5 = 1073741824,
Diamonds_6 = 2147483648,
Diamonds_7 = 4294967296,
Diamonds_8 = 8589934592,
Diamonds_9 = 17179869184,
Diamonds_10 = 34359738368,
Diamonds_Jack = 68719476736,
Diamonds_Queen = 137438953472,
Diamonds_King = 274877906944,
Clubs_Ace = 549755813888,
Clubs_2 = 1099511627776,
Clubs_3 = 2199023255552,
Clubs_4 = 4398046511104,
Clubs_5 = 8796093022208,
Clubs_6 = 17592186044416,
Clubs_7 = 35184372088832,
Clubs_8 = 70368744177664,
Clubs_9 = 140737488355328,
Clubs_10 = 281474976710656,
Clubs_Jack = 562949953421312,
Clubs_Queen = 1125899906842620,
Clubs_King = 2251799813685250,

}
}
}
``````
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You could use this enum to control the entire game state and the dealing of cards –  dmportella Mar 7 '13 at 12:56