# All possible combinations of card/poker hands for a set of players

I am looking for an elegant(fast) python function that produces every combination from the following two arrays.

``````cards = ["8H", "8S", "8C", "8D", "9H", "9S", "9C", "9D", "10H", "10S", "10C", "10D", "AH", "AS", "AC", "AD"]
players = ["_1", "_1", "_1", "_2", "_2", "_2", "_3", "_3", "_3", "_4", "_4", "_4", "_To", "_To", "_To", "_Tc"]
``````

A combination would look like:

``````[('8H', '_1'), ('8S', '_1'), ('8C', '_1'), ('8D', '_2'), ('9H', '_2'), ('9S', '_2'), ('9C', '_3'), ('9D', '_3'), ('10H', '_3'), ('10S', '_4'), ('10C', '_4'), ('10D', '_4'), ('AH', '_To'), ('AS', '_To'), ('AC', '_To'), ('AD', '_Tc')]
``````

But! without equals, what I mean with that. Example:

If cards would be:

``````["a", "b", "c", "d"]
``````

If players would be:

``````["1", "1", "2", "2"]
``````

Result:

``````[1a, 1b, 2c, 2d]
[1a, 1c, 2b, 2d]
[1a, 1d, 2b, 2c]
[1b, 1c, 2a, 2d]
[1b, 1d, 2a, 2c]
[1c, 1d, 2a, 2b]
``````

Not for example:

``````[1a, 1b, 2d, 2c]
``````

Player 2 having (c and d) is equal to (d and c)

I have tried a function of `itertools`, like `combinations` and `permutations` but without luck. Rejecting equals after having all combinations is not really an option, because of the state space explosion.

I hope someone has a solution, because google search for this specific problem failed.

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I've made the title and tags a little bit more appropriate and relevant for this question; the previous title wasn't something people are going to be searching on for this particular (poker related) problem. And the "space" and "state" tags were picked without paying attention to their meaning. – Erik Allik Mar 12 '14 at 17:16

I'd suggest using a recursive algorithm.

I'm using generators for the code to run in constant-space, as well as start producing results ASAP as opposed to a huge result at the end; see http://www.dabeaz.com/generators/ if you haven't heard of generators before.

As a side note, I'd suggest using a normalized data structure to hold your list of players and hand sizes to start with, so that the line with `groupby` wouldn't be necessary at all... And in any case, it's generally a good idea to keep your data normalized by default/most of the time and only use denormalized/flattened forms for example for certain algorithms that might need or run faster with flat structures.

Here's the code; feel free to propose clean-ups/simplifications:

``````from itertools import combinations, groupby, islice

cards = ["a", "b", "c", "d"]
players = ["1", "1", "2", "2"]

def hand_combinations(players, cards):
# convert ["1", "1", "2", "2"] into [("1", 2), ("2", 2)]
players = list((x, len(list(y))) for x, y in groupby(players))

# sets are faster to operate on in our case
cards = set(cards)

def generate(players, cards):
if not players:
yield []
else:
# pick the first player
player_name, player_hand_size = players[0]
# and then walk over all the possible hands for this player
for player_hand in combinations(cards, player_hand_size):
# for each hand, use the cards that are left to build all the
# possible hands for the rest of the players in this iteration
for tail in generate(players[1:], cards - set(player_hand)):
yield [(player_name, player_hand)] + tail

return generate(players, cards)

# take only the 100 first combinations; otherwise it'll take
# forever with the larger example
combos = islice(hand_combinations(players, cards), 0, 100)

# convert back to the flat structure
flattened = [
' '.join(
player_name + ':' + card
for player_name, player_cards in combo
for card in player_cards
)
for combo in combos
]

from pprint import pprint
pprint(flattened)
``````

Outputs:

``````['1:a 1:c 2:b 2:d',
'1:a 1:b 2:c 2:d',
'1:a 1:d 2:c 2:b',
'1:c 1:b 2:a 2:d',
'1:c 1:d 2:a 2:b',
'1:b 1:d 2:a 2:c']
``````

or with the larger examople:

``````['_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:8D _To:AH _To:9S _To:10D _Tc:8S',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:8D _To:AH _To:9S _To:8S _Tc:10D',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:8D _To:AH _To:10D _To:8S _Tc:9S',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:8D _To:9S _To:10D _To:8S _Tc:AH',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:10D _To:AH _To:9S _To:8D _Tc:8S',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:10D _To:AH _To:9S _To:8S _Tc:8D',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:10D _To:AH _To:8D _To:8S _Tc:9S',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:10D _To:9S _To:8D _To:8S _Tc:AH',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:AH _To:8S _To:9S _To:10D _Tc:8D',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:AH _To:8S _To:9S _To:8D _Tc:10D',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:AH _To:8S _To:10D _To:8D _Tc:9S',
'_1:AS _1:9H _1:8H _2:AC _2:10H _2:AD _3:10S _3:10C _3:9C _4:8C _4:9D _4:AH _To:9S _To:10D _To:8D _Tc:8S',
...
``````
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Tanx! This work very well, now some optimization. – Pieter Bosma Mar 12 '14 at 17:32
@user3411641: maybe I'm missing something but I can't really see where you could optimize anything... the code should run in constant space if you don't evaluate eagerly, and emits results as soon as you start it. – Erik Allik Mar 12 '14 at 17:34
Well, more in a way to have no memory overflow. – Pieter Bosma Mar 12 '14 at 17:56
@user3411641: the code above won't ever overflow/fill the memory if you use the return value properly (i.e. lazily). see the provided link about generators for more information on how to take full advantage of generators/laziness. – Erik Allik Mar 12 '14 at 19:02

Okay, so what you actually want is:

``````set(tuple(zip(p, players)) for p in it.permutations(cards))
``````

But that takes way too much time. So let's try.

``````cards = set(["8H", "8S", "8C", "8D", "9H", "9S", "9C", "9D", "10H", "10S", "10C", "10D", "AH", "AS", "AC", "AD"])

def deals(cards, players, cards_per_player):
if not cards:
yield []
return
for hand in it.combinations(cards, cards_per_player[0]):
hand = set(hand)
for deal in deals(cards - hand, players[1:], cards_per_player[1:]):
yield zip([players[0]]*len(hand), hand) + deal

> for deal in deals(cards, ['_1', '_2', '_3', '_4', '_Tc', '_To'], [3,3,3,3,1,3]):
print deal
``````

Which still takes a long time, but it's a lot of ways to deal the cards.

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This results in only one combination, I need all combinations. Like the abcd example. Looking into the product function now. – Pieter Bosma Mar 12 '14 at 16:55
@user3411641 Okay, I see what you meant. Updated. – U2EF1 Mar 12 '14 at 17:19

You could use an array of cards per person, and put the cards in order, so when you match the two arrays, they will be the same. You could use a tuple(size 2) for each card, where the first element could represent the value in range(13), and the second element would be the color (also represented with a number in range(4) ). You can easily generate the deck with a double for loop, maybe as a dictionary and after dealing the cards, you can remove the ones that you already used, so there will be no duplicates, and when you dealt all the hands (if you have the code it will be easy to modify it to have different number of players) you can order the hands, compare it with the database that you already have, and don't save it if there is a match, also you can save the remainder of the deck, to do some statistics if you want, than you can have all the possible dealings for every situation, which will be a huge database regardless. This way you will have all possibilities, with no duplicates in the hands or within hands of players. (player one having the hand of player two in a different deal and vice versa) I hope this helped you, or someone else. I'm not giving code examples, because this question is more like a how to solve this problem, and the others gave you coding tips. Also this approach can be done even if you just started python and only did some tutorials until now. Good luck ;)

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