Correct package name, add draft for GA module

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David Pätzel 2019-10-17 17:25:25 +02:00
parent 6ab1a2acba
commit 1d62a5cbea
2 changed files with 196 additions and 1 deletions

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cabal-version: 2.2 cabal-version: 2.2
name: GA-PFP name: ga
version: 0.1.0.0 version: 0.1.0.0
-- synopsis: -- synopsis:
-- description: -- description:

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src/GA.hs Normal file
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{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE DeriveFoldable #-}
{-# LANGUAGE DeriveTraversable #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE NoImplicitPrelude #-}
{-# LANGUAGE TupleSections #-}
module GA where
import Protolude
import Control.Arrow hiding (first)
import qualified Data.List as L
import Data.List.NonEmpty ((<|))
import qualified Data.List.NonEmpty as NE
import Data.Random
import Data.Random.Distribution.Categorical
import Data.Random.Sample
import Test.QuickCheck hiding (sample, shuffle)
import Test.QuickCheck.Instances
import Test.QuickCheck.Monadic
import Pretty
-- TODO Enforce this being > 0
type N = Int
type R = Float
class Eq i => Individual i where
{-|
Generates a completely random individual given an existing individual.
We have to add @i@ here as a parameter in order to be able to inject stuff.
TODO This (and also, Seminar.I, which contains an ugly parameter @p@) has to
be done nicer!
-}
new :: (MonadRandom m) => i -> m i
{-|
Generates a random population of the given size.
-}
population :: (MonadRandom m) => N -> i -> m (Population i)
population 0 _ = undefined
population n i = Pop . NE.fromList <$> replicateM n (new i)
mutate :: (MonadRandom m) => i -> m i
crossover1 :: (MonadRandom m) => i -> i -> m (Maybe (i, i))
-- TODO Perhaps rather add a 'features' function (and parametrize select1 etc. with fitness function)?
fitness :: (Monad m) => i -> m R
{-|
Performs an n-point crossover.
Given the function for single-point crossover, 'crossover1', this function can
be derived through recursion and a monad combinator (which is also the default
implementation).
-}
crossover :: (MonadRandom m) => Int -> i -> i -> m (Maybe (i, i))
crossover n i1 i2
| n <= 0 = return $ Just (i1, i2)
| otherwise = do
isM <- crossover1 i1 i2
maybe (return Nothing) (uncurry (crossover (n - 1))) isM
-- TODO Do i want to model the population using Data.Vector.Sized?
{-|
It would be nice to model populations as GADTs but then no functor instance were
possible:
> data Population a where
> Pop :: Individual a => NonEmpty a -> Population a
-}
newtype Population a = Pop { unPop :: NonEmpty a }
deriving (Foldable, Functor, Semigroup, Show, Traversable)
instance (Arbitrary i) => Arbitrary (Population i) where
arbitrary = Pop <$> arbitrary
{-|
Selects one individual from the population using proportionate selection.
-}
proportionate1 :: (Individual i, MonadRandom m) => Population i -> m i
proportionate1 pop =
sequence ((\ i -> (, i) <$> fitness i) <$> pop) >>=
sample . fromWeightedList . NE.toList . unPop
-- TODO Perhaps use stochastic acceptance for performance?
{-|
Selects @n@ individuals from the population using proportionate selection.
-}
-- TODO Perhaps use Data.Vector.Sized for the result?
proportionate
:: (Individual i, MonadRandom m)
=> N -> Population i -> m (NonEmpty i)
proportionate n pop
| n > 1 = (<|) <$> proportionate1 pop <*> proportionate (n - 1) pop
| otherwise = (:|) <$> proportionate1 pop <*> return []
{-|
Produce offspring circularly.
-}
children :: (Individual i, MonadRandom m) => N -> NonEmpty i -> m (NonEmpty i)
children _ (i :| []) = (:| []) <$> mutate i
children nX (i1 :| [i2]) = children2 nX i1 i2
children nX (i1 :| i2 : is') =
(<>) <$> children2 nX i1 i2 <*> children nX (NE.fromList is')
children2 :: (Individual i, MonadRandom m) => N -> i -> i -> m (NonEmpty i)
children2 nX i1 i2 = do
-- TODO Add crossover probability?
(i3, i4) <- fromMaybe (i1, i2) <$> crossover nX i1 i2
i5 <- mutate i3
i6 <- mutate i4
return $ i5 :| [i6]
{-|
The @k@ worst individuals in the population.
-}
bestBy :: (Individual i, Monad m) => N -> (i -> m R) -> Population i -> m [i]
bestBy k f =
fmap (NE.take k . fmap fst . NE.sortBy (comparing (Down . snd))) .
traverse (\ i -> (i, ) <$> f i) . unPop
-- TODO no trivial instance for worst
-- prop_worstLength :: Int -> Population Int -> Property
-- prop_worstLength k pop = monadicIO $ (k ==) . length <$> worst k pop
worst :: (Individual i, Monad m) => N -> Population i -> m [i]
worst = flip bestBy (fmap (1 /) . fitness)
bests :: (Individual i, Monad m) => N -> Population i -> m [i]
bests = flip bestBy fitness
ga' nParents nX pop term nResult = do
pop <- ga nParents nX pop term
res <- bests nResult pop
sequence $ putText . pretty <$> res
ga
:: (Individual i, MonadRandom m, Monad m)
=> N -> N -> Population i -> Termination i -> m (Population i)
ga nParents nX pop term = ga' nParents nX pop term 0
where
ga'
:: (Individual i, MonadRandom m, Monad m)
=> N -> N -> Population i -> Termination i -> N -> m (Population i)
ga' nParents nX pop term t = do
-- trace (show t <> ": " <> show (length pop)) $ return ()
is <- proportionate nParents pop
i :| is' <- children nX is
-- traceShow (length is') $ return ()
iWorsts <- worst nParents pop
-- traceShow (length iWorsts) $ return ()
-- for the fromList to not fail, n < length pop
-- replace the worst ones
let pop' = Pop $ i :| is' <> foldr L.delete (NE.toList . unPop $ pop) iWorsts
-- replace fitness proportionally
-- let pop' = Pop <$> proportionate (length pop) (pop <> Pop is')
if term pop' t
then
return pop'
else
ga' nParents nX pop' term (t + 1)
-- * Termination criteria
{-|
Termination decisions may take into account the current population and the
current iteration number.
-}
type Termination i = Population i -> N -> Bool
{-|
Termination after a number of steps.
-}
steps :: N -> Termination i
steps tEnd _ t = t >= tEnd