# What is the optimal winning strategy for this modified blackjack game?

## Questions

Is there a best value to stay on so that I win the greatest percentage of games possible? If so, what is it?

Edit: Is there an exact probability of winning that can be calculated for a given limit, independent of whatever the opponent does? (I haven't done probability & statistics since college). I'd be interested in seeing that as an answer to contrast it with my simulated results.

Edit: Fixed bugs in my algorithm, updated result table.

## Background

I've been playing a modified blackjack game with some rather annoying rule tweaks from the standard rules. I've italicized the rules that are different from the standard blackjack rules, as well as included the rules of blackjack for those not familiar.

### Modified Blackjack Rules

1. Exactly two human players (dealer is irrelevant)
2. Each player is dealt two cards face down
• Neither player ever knows the value of any of the opponent's cards
• Neither player knows the value of the opponent's hand until both have finished the hand
3. Goal is to come as close to score of 21 as possible. Outcomes:
• If player's A & B have identical score, game is a draw
• If player's A & B both have a score over 21 (a bust), game is a draw
• If player A's score is <= 21 and player B has busted, player A wins
• If player A's score is greater than player B's, and neither have busted, player A wins
• Otherwise, player A has lost (B has won).
4. Cards are worth:
• Cards 2 through 10 are worth the corresponding amount of points
• Cards J, Q, K are worth 10 points
• Card Ace is worth 1 or 11 points
5. Each player may request additional cards one at a time until:
• The player doesn't want any more (stay)
• The player's score, with any Aces counted as 1, exceeds 21 (bust)
• Neither player knows how many cards the other has used at any time
6. Once both players have either stayed or busted the winner is determined per rule 3 above.
7. After each hand the entire deck is reshuffled and all 52 cards are in play again

### What is a deck of cards?

A deck of cards consists of 52 cards, four each of the following 13 values:

2, 3, 4, 5, 6, 7, 8, 9, 10, J, Q, K, A

No other property of the cards are relevant.

A Ruby representation of this is:

``````CARDS = ((2..11).to_a+[10]*3)*4
``````

## Algorithm

I've been approaching this as follows:

• I will always want to hit if my score is 2 through 11, as it is impossible to bust
• For each of the scores 12 through 21 I will simulate N hands against an opponent
• For these N hands, the score will be my "limit". Once I reach the limit or greater, I will stay.
• My opponent will follow the exact same strategy
• I will simulate N hands for every permutation of the sets (12..21), (12..21)
• Print the difference in wins and losses for each permutation as well as the net win loss difference

Here is the algorithm implemented in Ruby:

``````#!/usr/bin/env ruby
class Array
def shuffle
sort_by { rand }
end

def shuffle!
self.replace shuffle
end

def score
sort.each_with_index.inject(0){|s,(c,i)|
s+c > 21 - (size - (i + 1)) && c==11 ? s+1 : s+c
}
end
end

N=(ARGV[0]||100_000).to_i
NDECKS = (ARGV[1]||1).to_i

CARDS = ((2..11).to_a+[10]*3)*4*NDECKS
CARDS.shuffle

my_limits = (12..21).to_a
opp_limits = my_limits.dup

puts " " * 55 + "opponent_limit"
printf "my_limit |"
opp_limits.each do |result|
printf "%10s", result.to_s
end
printf "%10s", "net"
puts

printf "-" * 8 + " |"
print "  " + "-" * 8
opp_limits.each do |result|
print "  " + "-" * 8
end
puts

win_totals = Array.new(10)
win_totals.map! { Array.new(10) }

my_limits.each do |my_limit|
printf "%8s |", my_limit
\$stdout.flush
opp_limits.each do |opp_limit|

if my_limit == opp_limit # will be a tie, skip
win_totals[my_limit-12][opp_limit-12] = 0
print "        --"
\$stdout.flush
next
elsif win_totals[my_limit-12][opp_limit-12] # if previously calculated, print
printf "%10d", win_totals[my_limit-12][opp_limit-12]
\$stdout.flush
next
end

win = 0
lose = 0
draw = 0

N.times {
cards = CARDS.dup.shuffle
my_hand = [cards.pop, cards.pop]
opp_hand = [cards.pop, cards.pop]

# hit until I hit limit
while my_hand.score < my_limit
my_hand << cards.pop
end

# hit until opponent hits limit
while opp_hand.score < opp_limit
opp_hand << cards.pop
end

my_score = my_hand.score
opp_score = opp_hand.score
my_score = 0 if my_score > 21
opp_score = 0 if opp_score > 21

if my_hand.score == opp_hand.score
draw += 1
elsif my_score > opp_score
win += 1
else
lose += 1
end
}

win_totals[my_limit-12][opp_limit-12] = win-lose
win_totals[opp_limit-12][my_limit-12] = lose-win # shortcut for the inverse

printf "%10d", win-lose
\$stdout.flush
end
printf "%10d", win_totals[my_limit-12].inject(:+)
puts
end
``````

Usage

``````ruby blackjack.rb [num_iterations] [num_decks]
``````

The script defaults to 100,000 iterations and 4 decks. 100,000 takes about 5 minutes on a fast macbook pro.

### Output (N = 100 000)

``````                                                       opponent_limit
my_limit |        12        13        14        15        16        17        18        19        20        21       net
-------- |  --------  --------  --------  --------  --------  --------  --------  --------  --------  --------  --------
12 |        --     -7666    -13315    -15799    -15586    -10445     -2299     12176     30365     65631     43062
13 |      7666        --     -6962    -11015    -11350     -8925      -975     10111     27924     60037     66511
14 |     13315      6962        --     -6505     -9210     -7364     -2541      8862     23909     54596     82024
15 |     15799     11015      6505        --     -5666     -6849     -4281      4899     17798     45773     84993
16 |     15586     11350      9210      5666        --     -6149     -5207       546     11294     35196     77492
17 |     10445      8925      7364      6849      6149        --     -7790     -5317      2576     23443     52644
18 |      2299       975      2541      4281      5207      7790        --    -11848     -7123      8238     12360
19 |    -12176    -10111     -8862     -4899      -546      5317     11848        --    -18848     -8413    -46690
20 |    -30365    -27924    -23909    -17798    -11294     -2576      7123     18848        --    -28631   -116526
21 |    -65631    -60037    -54596    -45773    -35196    -23443     -8238      8413     28631        --   -255870
``````

### Interpretation

This is where I struggle. I'm not quite sure how to interpret this data. At first glance it seems like always staying at 16 or 17 is the way to go, but I'm not sure if it's that easy. I think it's unlikely that an actual human opponent would stay on 12, 13, and possibly 14, so should I throw out those opponent_limit values? Also, how can I modify this to take into account the variability of a real human opponent? e.g. a real human is likely to stay on 15 just based on a "feeling" and may also hit on 18 based on a "feeling"

-
Is this a programming question? You don't seem to have had trouble with the program, just with interpreting the results. –  T.J. Crowder Feb 20 '10 at 7:48
@T.J. Eh, there's an argument that it's not programming related. I tend to think of Mathematics and Computer Science as being very closely entwined though. I'm hoping that a combination of my reputation and thoroughness will get some answers to this, as I don't know any better places to ask it. (IRC is failing me). I'd be sad, but understanding if it were closed. –  hobodave Feb 20 '10 at 7:50
Yeah, there could be an argument that it's not programming-related, but it's interesting nonetheless, and it presents an algorithmic problem to be solved. That's like candy to us programmers :) I've written my own essay in response! –  Damovisa Feb 20 '10 at 8:54

I'm suspicious of your results. For example, if the opponent aims for 19, your data says that the best way to beat him is to hit until you reach 20. This does not pass a basic smell test. Are you sure you don't have a bug? If my opponent is striving for 19 or better, my strategy would be to avoid busting at all costs: stay on anything 13 or higher (maybe even 12?). Going for 20 has to wrong -- and not just by a small margin, but by a lot.

How do I know that your data is bad? Because the blackjack game you are playing isn't unusual. It's the way a dealer plays in most casinos: the dealer hits up to a target and then stops, regardless of what the other players hold in their hands. What is that target? Stand on hard 17 and hit soft 17. When you get rid of the bugs in your script, it should confirm that the casinos know their business.

When I make the following replacements to your code:

``````# Replace scoring method.
def score
s = inject(0) { |sum, c| sum + c }
return s if s < 21
n_aces = find_all { |c| c == 11 }.size
while s > 21 and n_aces > 0
s -= 10
n_aces -= 1
end
return s
end

# Replace section of code determining hand outcome.
my_score  = my_hand.score
opp_score = opp_hand.score
my_score  = 0 if my_score  > 21
opp_score = 0 if opp_score > 21
if my_score == opp_score
draw += 1
elsif my_score > opp_score
win += 1
else
lose += 1
end
``````

The results agree with the behavior of casino dealers: 17 is the optimal target.

``````n=10000
opponent_limit
my_limit |        12        13        14        15        16        17        18        19        20        21       net
-------- |  --------  --------  --------  --------  --------  --------  --------  --------  --------  --------  --------
12 |        --      -843     -1271     -1380     -1503     -1148      -137      1234      3113      6572
13 |       843        --      -642     -1041     -1141      -770       -93      1137      2933      6324
14 |      1271       642        --      -498      -784      -662        93      1097      2977      5945
15 |      1380      1041       498        --      -454      -242      -100       898      2573      5424
16 |      1503      1141       784       454        --      -174        69       928      2146      4895
17 |      1148       770       662       242       174        --        38       631      1920      4404
18 |       137        93       -93       100       -69       -38        --       489      1344      3650
19 |     -1234     -1137     -1097      -898      -928      -631      -489        --       735      2560
20 |     -3113     -2933     -2977     -2573     -2146     -1920     -1344      -735        --      1443
21 |     -6572     -6324     -5945     -5424     -4895     -4404     -3650     -2560     -1443        --
``````

The current design is inflexible. With a just little refactoring, you could achieve a clean separation between the operation of the game (dealing, shuffling, keeping running stats) and player decision making. This would allow you to test various strategies against each other. Currently, your strategies are embedded in loops that are all tangled up in the game operation code. Your experimentation would be better served by a design that allowed you to create new players and set their strategy at will.

-
@FM: I don't think your interpretation of the data is accurate. "For example, if the opponent aims for 19, your data says that the best way to beat him is to hit until you reach 20." - The win difference between 12 (1012) & 20 (1156) is negligible for this N (100,000). Also, what you're not seeing in this data is the ridiculously high number of draws for both players if they hit until 19 and 20, due to both busting. Thus for the few times where there isn't a draw someone staying on 20 will beat someone who stayed on 19. –  hobodave Feb 20 '10 at 18:44
@FM: "Note, in particular, that 21 + 21 = 42, not 44." Yes. If both hands total 44 then both have busted (a draw). If they both have 21 then it is a draw as well. –  hobodave Feb 20 '10 at 18:46
@FM: Crap. Now that I think about it, my_score + opp_score >= 44 is flawed. E.g. if I busted with 27 and the opponent has 17, then he won, it's not a draw. I'll fix my script to use (my_score > 21 && opp_score > 21) there and update accordingly, thanks. –  hobodave Feb 20 '10 at 18:49
@FM: (1) Have each player compute his own score after receiving a new card and then remember it, rather than recalculating it several times: If I do this I lose information about whether any existing cards are an Ace. –  hobodave Feb 20 '10 at 18:58
@hobodave I agree my comment about 21+21 was a little off the mark. But there was a bug nonetheless. :) Regarding the scoring, if you play a hand, then set the scores to zero for players who busted, your logic to decide who won will be easier to grasp. As far as soft aces go, each player needs to keep track of 2 elements: a hard score and a tally for N of soft aces. If a player exceeds 21, convert a soft ace (11) to a hard ace (1) and reduce the score by 10. –  FMc Feb 20 '10 at 19:17

1. It looks like there isn't a single dominating strategy based on a "hit limit":

• If you choose 16 your opponent can choose 17
• if you choose 17 your opponent can choose 18
• if you choose 18 your opponent can choose 19
• if you choose 19 your opponent can choose 20
• if you choose 20 your opponent can choose 12
• if you choose 12 your opponent can choose 16.

2. You do not mention whether players can see how many cards their opponent has drawn (I would guess so). I would expect this information to be incorporated into the "best" strategy. (answered)

With no information about the other players decisions, the game gets simpler. But since there is clearly no dominant "pure" strategy, the optimal strategy will be a "mixed" strategy. That is: a set of probabilities for each score from 12 to 21 for whether you should stop or draw another card (EDIT: you will need different probabilities for a given score with no aces vs the score with aces.) Executing the strategy then requires you to randomly choose (according to the probabilities) whether to stop or continue after each new draw. You can then find the Nash equilibrium for the game.

Of course, if you are only asking the simpler question: what is the optimal winning strategy against suboptimal players (for example ones that always stop on 16, 17, 18 or 19) you are asking an entirely diiferent question, and you will have to specify exactly in which way the other player is limited compared to you.

-
That's a good point, although the number of cards drawn might not tell you very much, particularly as the deck is shuffled every hand. Two cards could be anywhere from a score of 3 to a score of 21. That said, I see your point - if the player has only two cards, it's less likely they'll have a higher hand, but you can't rule it out. It'd be interesting to add that into the mix! –  Damovisa Feb 20 '10 at 9:17
@Rasmus: 2: I updated the question. You do not know. –  hobodave Feb 20 '10 at 9:19

Here are some thoughts about the data you've collected:

• It's mildly useful for telling you what your "hit limit" should be, but only if you know that your opponent is following a similar "hit limit" strategy.
• Even then, It's only really useful if you know what your opponent's "hit limit" is or is likely to be. You can just choose a limit that gives you more wins than them.
• You can more or less ignore the actual values in the table. It's whether they're positive or negative that matters.

To show your data another way, the first number is your opponent's limit, and the second group of numbers are the limits you can choose and win with. The one with an asterisk is the "winningest" choice:

``````12:   13, 14, 15, 16*, 17, 18
13:   14, 15, 16*, 17, 18, 19
14:   15, 16, 17*, 18, 19
15:   16, 17*, 18, 19
16:   17, 18*, 19
17:   18*, 19
18:   19*, 20
19:   12, 20*
20:   12*, 13, 14, 15, 16, 17
21:   12*, 13, 14, 15, 16, 17, 18, 19, 20
``````

From that, you can see that a hit limit of 17 or 18 is the safest option if the opponent is following a random "hit limit" selection strategy because 17 and 18 will beat 7/10 opponent "hit limits".

Of course if your opponent is human, you can't reply on them self-imposing a "hit limit" of under 18 or over 19, so that completely negates the previous calculations. I still think these numbers are useful however:

I agree that for any individual hand, you can be reasonably confident that your opponent will have a limit after which they will stop hitting, and they'll stay. If you can guess at that limit, you can choose your own limit based on that estimate.

If you think they're being optimistic or they're happy to risk it, choose a limit of 20 - you'll beat them in the long run provided their limit is above 17. If you're really confident, choose a limit of 12 - that will win if their limit is above 18 and there are much more frequent winnings to be had here.

If you think they're being conservative or risk averse, choose a limit of 18. That will win if they're staying anywhere below 18 themselves.

For neutral ground, maybe think about what your limit would be without any outside influence. Would you normally hit on a 16? A 17?

In short, you can only guess at what your opponent's limit is, but if you guess well, you can beat them over the long term with those statistics.

-
@Damovisa: You seem to come to some of the same conclusions that I do. ( My net column more or less indicates the same as your table ). My natural instinct would be to hit on 16 always, sometimes hit on 17, and never hit on 18. –  hobodave Feb 20 '10 at 9:24
What I surmise is that a player not following the same strategy of a hard hit limit would always stay on 19, 20, and 21, and always hit on 12 through 15. Thus for each hand they'd probably have a hit limit of 16, 17, 18, or 19 depending on whatever. This makes me thing that 19 might be the best hit limit to have, as it will tend to beat all of those hit limits in the long run, tying the 19. The only apparent way to beat this would be for the opponent to adopt this strategy and always use a hit limit of 12 or 20. –  hobodave Feb 20 '10 at 9:29
So, basically over say, 400,000 hands, it doesn't matter if they randomly decide to stay on any of 16 through 19. If they did each equally then I'd win roughly 2867, 3314, 2080, and 0 more games than them respectively. Is this flawed? –  hobodave Feb 20 '10 at 9:33
No, I think that's pretty accurate. You're assuming they're not choosing "bad" options; 16-19. If you choose 19 as your limit, you'll beat them in the long run. –  Damovisa Feb 20 '10 at 9:44