# Generating sequence from Markov chain in Haskell

I would like to generate random sequences from a Markov chain. To generate the Markov chain I use the following code.

``````module Main where

import qualified Control.Monad.Random as R
import qualified Data.List as L
import qualified Data.Map as M

type TransitionMap = M.Map (String, String) Int
type MarkovChain = M.Map String [(String, Int)]

addTransition :: (String, String) -> TransitionMap -> TransitionMap
addTransition k = M.insertWith (+) k 1

fromTransitionMap :: TransitionMap -> MarkovChain
fromTransitionMap m =
M.fromList [(k, frequencies k) | k <- ks]
where ks = L.nub \$ map fst \$ M.keys m
frequencies a = map reduce \$ filter (outboundFor a) \$ M.toList m
outboundFor a k = fst (fst k) == a
reduce e = (snd (fst e), snd e)
``````

After collecting the statistics and generating a Markov Chain object I would like to generate random sequences. I could imagine this method could look something like that (pseudo-code)

``````generateSequence mc s
| s == "." = s
| otherwise = s ++ " " ++ generateSequence mc s'
where s' = drawRandomlyFrom \$ R.fromList \$ mc ! s
``````

I would greatly appreciate if someone could explain to me, how I should implement this function.

Edit

If anyone's interested it wasn't as difficult as I thought.

``````module Main where

import qualified Control.Monad.Random as R
import qualified Data.List as L
import qualified Data.Map as M

type TransitionMap = M.Map (String, String) Rational
type MarkovChain = M.Map String [(String, Rational)]

addTransition :: TransitionMap -> (String, String) -> TransitionMap
addTransition m k = M.insertWith (+) k 1 m

fromTransitionMap :: TransitionMap -> MarkovChain
fromTransitionMap m =
M.fromList [(k, frequencies k) | k <- ks]
where ks = L.nub \$ map fst \$ M.keys m
frequencies a = map reduce \$ filter (outboundFor a) \$ M.toList m
outboundFor a k = fst (fst k) == a
reduce e = (snd (fst e), snd e)

generateSequence :: (R.MonadRandom m) => MarkovChain -> String -> m String
generateSequence m s
| not (null s) && last s == '.' = return s
| otherwise = do
s' <- R.fromList \$ m M.! s
ss <- generateSequence m s'
return \$ if null s then ss else s ++ " " ++ ss

fromSample :: [String] -> MarkovChain
fromSample ss = fromTransitionMap \$ foldl addTransition M.empty \$ concatMap pairs ss
where pairs s = let ws = words s in zipWith (,) ("":ws) ws

sample :: [String]
sample = [ "I am a monster."
, "I am a rock star."
, "I want to go to Hawaii."
, "I want to eat a hamburger."
, "I have a really big headache."
, "Haskell  is a fun language."
, "Go eat a big hamburger."
, "Markov chains are fun to use."
]

main = do
s <- generateSequence (fromSample sample) ""
print s
``````

The only tiny annoyance is the fake `""` starting node.

• if `generateSequence` is to be run in `MonadRandom`, you'd need `return`s there. Commented Aug 13, 2014 at 12:58
• do you care to elaborate please? I'm not that experiences in the whole monad thing. I do understand enough, to see that ++ not gonna work if I try to concatenate a `String` and `Monad m => m a`. Second I'm not sure how `drawRandomlyFrom` function should look like Commented Aug 13, 2014 at 15:06

Not sure if this is what you're looking for. This compiles though:

``````generateSequence :: (R.MonadRandom m) => MarkovChain -> String -> m String
generateSequence mc s  | s == "." = return s
| otherwise = do
s' <- R.fromList \$ rationalize (mc M.! s)
s'' <- generateSequence mc s'
return \$ s ++ " " ++ s''

rationalize :: [(String,Int)] -> [(String,Rational)]
rationalize = map  (\(x,i) -> (x, toRational i))
``````

All random number generation needs to happen in either the `Random` monad or the `IO` monad. For your purpose, it's probably easiest to understand how to do that in the `IO` monad, using `evalRandIO`. In the example below, `getRandom` is the function we want to use. Now `getRandom` operates in the `Random` monad, but we can use `evalRandIO` to lift it to the `IO` monad, like this:

``````main :: IO ()
main = do
x <- evalRandIO getRandom :: IO Double
putStrLn \$ "Your random number is " ++ show x
``````

Note: The reason we have to add the type signature to the line that binds x is because in this particular example there are no other hints to tell the compiler what type we want `x` to be. However, if we used `x` in some way that makes it clear that we want it to be a `Double` (e.g., multiplying by another `Double`), then the type signature wouldn't be necessary.

Using your `MarkovChain` type, for a current state you can trivially get the available transitions in the form `[(`nextState`,`probability`)]`. (I'm using the word "probability" loosely, it doesn't need to be a true probability; any numeric weight is fine). This is what `fromList` in `Control.Monad.Random` is designed for. Again, it operates in the `Random` monad, but we can use `evalRandIO` to lift it to the `IO` monad. Suppose `transitions` is your list of transitions, having the type `[(`nextState`,`probability`)]`. Then, in the IO monad you can call:

``````nextState <- evalRandIO \$ fromList transitions
``````

You might instead want to create your own function that operates in the `Random` monad, like this:

``````getRandomTransition :: RandomGen g => MarkovChain -> String -> Rand g String
getRandomTransition currState chain = do
let transitions = lookup currState chain
fromList transitions
``````

Then you can call this function in the `IO` monad using `evalRandIO`, e.g.

``````nextState <- evalRandIO \$ getRandomTransition chain
``````