Here's an example based on coin tossing. The problem is as follows:
You have two coins, labeled Biased and Fair. The Biased coin has two heads, and the Fair coin has one head and one tail. Pick one of these coins at random, toss it and observe the result. If the result is a head, what is the probability that you picked the Biased coin?
We can model this in Haskell as follows. First, you need the types of coin and their faces
data CoinType = Fair | Biased deriving (Show)
data Coin = Head | Tail deriving (Eq,Show)
We know that tossing a fair coin can come up either Head or Tail whereas the biased coin always comes up Head. We model this with a list of possible alternatives (where implicitly, each possibility is equally likely).
toss Fair = [Head, Tail]
toss Biased = [Head, Head]
We also need a function that picks the fair or biased coin at random
pick = [Fair, Biased]
Then we put it all together like this
experiment = do
coin <- pick -- Pick a coin at random
result <- toss coin -- Toss it, to get a result
guard (result == Head) -- We only care about results that come up Heads
return coin -- Return which coin was used in this case
Notice that although the code reads like we're just running the experiment once, but the list monad is modelling nondeterminism, and actually following out all possible paths. Therefore the result is
>> experiment
[Biased, Biased, Fair]
Because all the possibilities are equally likely, we can conclude that there is a 2/3 chance that we have the biased coin, and only a 1/3 chance that we have the fair coin.
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