# The simplest algorithm for poker hand evaluation

I am thinking about poker hand (5 cards) evaluation in `Java`. Now I am looking for simplicity and clarity rather than performance and efficiency. I probably can write a "naive" algorithm but it requires a lot of code.

I saw also a few poker evaluation libraries, which use hashing and bitwise operations, but they look rather complex.

What is the "cleanest and simplest" algorithm for poker hand evaluation ?

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This is very simple, clean and well explained: nsayer.blogspot.com/2007/07/… –  iccthedral Apr 28 '12 at 13:29
There are lots and lots of (probably) relevant question in the "related" sidebar on the right. Do none of them answer your question? –  Oliver Charlesworth Apr 28 '12 at 13:30
@OliCharlesworth I saw mostly links to existing libraries –  Michael Apr 28 '12 at 13:34
@iccthedral I didn't like it too much, evaluating all 21 combinations of 5 cards in a 7 card set seems very inefficient. There are algorithms to determine the best hand out of 7 cards without having to look at every combination and the algorithm is just slightly more complicated than the one for 5 cards. –  Jubbat Mar 25 '14 at 5:51

Here is a very short but complete histogram based 5 card poker scoring function in Python (2.x). It will get considerably longer if converted to Java.

``````def poker(hands):
scores = [(i, score(hand.split())) for i, hand in enumerate(hands)]
winner = sorted(scores , key=lambda x:x[1])[-1][0]
return hands[winner]

def score(hand):
ranks = '23456789TJQKA'
rcounts = {ranks.find(r): ''.join(hand).count(r) for r, _ in hand}.items()
score, ranks = zip(*sorted((cnt, rank) for rank, cnt in rcounts)[::-1])
if len(score) == 5:
if ranks[0:2] == (12, 3): #adjust if 5 high straight
ranks = (3, 2, 1, 0, -1)
straight = ranks[0] - ranks[4] == 4
flush = len({suit for _, suit in hand}) == 1
'''no pair, straight, flush, or straight flush'''
score = ([1, (3,1,1,1)], [(3,1,1,2), (5,)])[flush][straight]
return score, ranks

>>> poker(['8C TS KC 9H 4S', '7D 2S 5D 3S AC', '8C AD 8D AC 9C', '7C 5H 8D TD KS'])
``````
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I think this one needs more upvotes... you couldn't write it shorter in any other language. –  Johannes P Dec 26 '13 at 15:34
I don't think this is complete: `>>> poker(['8C TS KC 9H 4S', '7D 2S 5D 3S AC', '8C AD 8D AC 9C', '7C 5H 8D TD KS', 'QC QD QS JS TC', 'AH KH QH JH TH'])` `'QC QD QS JS TC'` –  ihgann Jul 23 '14 at 19:18
Thanks for catching that, should work now. –  dansalmo Jul 24 '14 at 15:19
This doesn't work, it will choose a Three of a Kind over a Straight. `poker(['JC JH JD 5C 8D', '2D 3C 4S 5D 6C'])` will return `'JC JH JD 5C 8D'` –  Tom Oct 27 '14 at 6:17
You should be able to fix this by simple using `score = ([1, (3,1,1,1)], [(3,1,1,2), (5,)])[flush][straight]` –  Tom Oct 27 '14 at 21:55

Lookup tables are the most straightforward and simplest solution to the problem, and also the fastest. The trick is managing the size of the table and keeping the mode of use simple enough to process very quickly (space–time tradeoff). Obviously, in theory you could just encode each hand that could be held and have an array of evaluations, then --poof-- one table lookup and you are done. Unfortunately, such a table would be huge and unmanageable for most machines, and would invariably have you thrashing disks anyway as memory gets swapped out lots.

The so-called two-plus-two solution sports a big 10M table, but literally involves one table lookup for each card in the hand. You are not likely to find a faster and simpler to understand algorithm.

Other solutions involve more compressed tables with more complex indexing, but they are readily comprehensible and pretty fast (although much slower than 2+2). This is where you see language concerning hashing and so forth -- tricks to reduce a table size to more manageable sizes.

In any case, lookup solutions are orders of magnitude faster than the historgram-sort-dance-on-your-head-compare-special-case-and-by-the-way-was-it-a-flush solutions, almost none of which are worthy of a second glance.

A good summary of algorithms can be found here.

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If you just want to understand how it works here is simple algorithm:

``````HandStrength(ourcards,boardcards)
{
ahead = tied = behind = 0
ourrank = Rank(ourcards,boardcards)
/* Consider all two-card combinations
of the remaining cards. */
for each case(oppcards)
{
opprank = Rank(oppcards,boardcards)
if(ourrank>opprank)
else if(ourrank==opprank)
tied += 1
else /* < */
behind += 1
}
return(handstrength)
}
``````

It is from "ALGORITHMS AND ASSESSMENT IN COMPUTER POKER" by Darse Billings.

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Here's a naive approach to five-card hand comparison that I'm using to help initially populate a lookup table:

Instead of being as terse as possible, I prioritized type safety and clear, self-documenting code. If you're not familiar with the Guava types I'm using, you can browse their documentation.

And I'll include the code here (minus static imports for the enum constants at the bottom), although it's really too long to comfortably view in an answer.

``````import static com.google.common.base.Preconditions.checkArgument;
import static java.util.Comparator.comparing;
import static java.util.Comparator.comparingInt;

import java.util.Comparator;
import java.util.EnumSet;
import java.util.Set;
import java.util.function.Function;

public class Hand implements Comparable<Hand> {
public final Category category;

public Hand(Set<Card> cards) {
checkArgument(cards.size() == 5);
Set<Suit> suits = EnumSet.noneOf(Suit.class);
Multiset<Rank> ranks = EnumMultiset.create(Rank.class);
for (Card card : cards) {
}
Set<Entry<Rank>> entries = ranks.entrySet();
for (Entry<Rank> entry : byCountThenRank.immutableSortedCopy(entries)) {
}
Rank first = distinctRanks.getFirst();
int distinctCount = distinctRanks.size();
if (distinctCount == 5) {
boolean flush = suits.size() == 1;
if (first.ordinal() - distinctRanks.getLast().ordinal() == 4) {
category = flush ? STRAIGHT_FLUSH : STRAIGHT;
}
else if (first == ACE && distinctRanks.get(1) == FIVE) {
category = flush ? STRAIGHT_FLUSH : STRAIGHT;
// ace plays low, move to end
}
else {
category = flush ? FLUSH : HIGH_CARD;
}
}
else if (distinctCount == 4) {
category = ONE_PAIR;
}
else if (distinctCount == 3) {
category = ranks.count(first) == 2 ? TWO_PAIR : THREE_OF_A_KIND;
}
else {
category = ranks.count(first) == 3 ? FULL_HOUSE : FOUR_OF_A_KIND;
}
}

@Override
public final int compareTo(Hand that) {
return byCategoryThenRanks.compare(this, that);
}

private static final Ordering<Entry<Rank>> byCountThenRank;

private static final Comparator<Hand> byCategoryThenRanks;

static {
Comparator<Entry<Rank>> byCount = comparingInt(Entry::getCount);
Comparator<Entry<Rank>> byRank = comparing(Entry::getElement);
byCountThenRank = from(byCount.thenComparing(byRank));
Comparator<Hand> byCategory = comparing((Hand hand) -> hand.category);
Function<Hand, Iterable<Rank>> getRanks =
(Hand hand) -> hand.distinctRanks;
Comparator<Hand> byRanks =
comparing(getRanks, natural().lexicographical());
byCategoryThenRanks = byCategory.thenComparing(byRanks);
}

public enum Category {
HIGH_CARD,
ONE_PAIR,
TWO_PAIR,
THREE_OF_A_KIND,
STRAIGHT,
FLUSH,
FULL_HOUSE,
FOUR_OF_A_KIND,
STRAIGHT_FLUSH;
}

public enum Rank {
TWO,
THREE,
FOUR,
FIVE,
SIX,
SEVEN,
EIGHT,
NINE,
TEN,
JACK,
QUEEN,
KING,
ACE;
}

public enum Suit {
DIAMONDS,
CLUBS,
HEARTS,
}

public enum Card {
TWO_DIAMONDS(TWO, DIAMONDS),
THREE_DIAMONDS(THREE, DIAMONDS),
FOUR_DIAMONDS(FOUR, DIAMONDS),
FIVE_DIAMONDS(FIVE, DIAMONDS),
SIX_DIAMONDS(SIX, DIAMONDS),
SEVEN_DIAMONDS(SEVEN, DIAMONDS),
EIGHT_DIAMONDS(EIGHT, DIAMONDS),
NINE_DIAMONDS(NINE, DIAMONDS),
TEN_DIAMONDS(TEN, DIAMONDS),
JACK_DIAMONDS(JACK, DIAMONDS),
QUEEN_DIAMONDS(QUEEN, DIAMONDS),
KING_DIAMONDS(KING, DIAMONDS),
ACE_DIAMONDS(ACE, DIAMONDS),

TWO_CLUBS(TWO, CLUBS),
THREE_CLUBS(THREE, CLUBS),
FOUR_CLUBS(FOUR, CLUBS),
FIVE_CLUBS(FIVE, CLUBS),
SIX_CLUBS(SIX, CLUBS),
SEVEN_CLUBS(SEVEN, CLUBS),
EIGHT_CLUBS(EIGHT, CLUBS),
NINE_CLUBS(NINE, CLUBS),
TEN_CLUBS(TEN, CLUBS),
JACK_CLUBS(JACK, CLUBS),
QUEEN_CLUBS(QUEEN, CLUBS),
KING_CLUBS(KING, CLUBS),
ACE_CLUBS(ACE, CLUBS),

TWO_HEARTS(TWO, HEARTS),
THREE_HEARTS(THREE, HEARTS),
FOUR_HEARTS(FOUR, HEARTS),
FIVE_HEARTS(FIVE, HEARTS),
SIX_HEARTS(SIX, HEARTS),
SEVEN_HEARTS(SEVEN, HEARTS),
EIGHT_HEARTS(EIGHT, HEARTS),
NINE_HEARTS(NINE, HEARTS),
TEN_HEARTS(TEN, HEARTS),
JACK_HEARTS(JACK, HEARTS),
QUEEN_HEARTS(QUEEN, HEARTS),
KING_HEARTS(KING, HEARTS),
ACE_HEARTS(ACE, HEARTS),

public final Rank rank;

public final Suit suit;

Card(Rank rank, Suit suit) {
this.rank = rank;
this.suit = suit;
}
}
}
``````
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If you are representing a hand as an array of, for example, `Card` objects, then I would have methods for looping through this array and determining if it has a 2-of-a-kind, flush etc - and if it does, what type it is; so you could have the `3ofaKind()` method return 5 if a hand had three 5s. Then I would establish a hierarchy of possibilities (e.g. 3 of a kind is higher than 2 of a kind) and work from there. The methods themselves should be pretty straightforward to write.

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Don't forget that some 3-of-a-kind's are better than others –  Jeffrey Apr 28 '12 at 14:53

I would use this one as a basis:

https://github.com/andrewprock/jpoker

It should be pretty straightforward.

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@gdejohn, fixed. –  Andrew Prock Jan 27 '14 at 15:41
That's a few thousand lines compared to the python solution that would be 10 lines if it worked. Would be great if we could find a solution for dansalmo's code. –  Nicolas Sep 27 at 2:01

The code from dansalmo above is definitely the most elegant version, however it doesn't work in Python 3 because it throws an error: "TypeError: unorderable types: tuple() < int()".

score = ... needs to be written as tuple instead of integer as follows:

``````def poker(hands):
scores = [(i, score(hand.split())) for i, hand in enumerate(hands)]
winner = sorted(scores , key=lambda x:x[1])[-1][0] # <++++THIS LINE THROWS AN ERROR ++++
return hands[winner]

def score(hand):
ranks = '23456789TJQKA'
rcounts = {ranks.find(r): ''.join(hand).count(r) for r, _ in hand}.items()
score, ranks = zip(*sorted((cnt, rank) for rank, cnt in rcounts)[::-1])
if len(score) == 5:
if ranks[0:2] == (12, 3): #adjust if 5 high straight
ranks = (3, 2, 1, 0, -1)
straight = ranks[0] - ranks[4] == 4
flush = len({suit for _, suit in hand}) == 1
'''no pair, straight, flush, or straight flush'''
score = ([(1, ), (3,1,1,1)], [(3,1,1,2), (5,)])[flush][straight]

>>> poker(['8C TS KC 9H 4S', '7D 2S 5D 3S AC', '8C AD 8D AC 9C', '7C 5H 8D TD KS'])