finish German
This commit is contained in:
parent
4286ee36d9
commit
8432103a18
16
haga.cabal
16
haga.cabal
|
@ -49,9 +49,9 @@ library
|
|||
, Pretty
|
||||
, Szenario191
|
||||
, LambdaCalculus
|
||||
, IrisDataset
|
||||
, IrisData
|
||||
|
||||
, GermanDataset
|
||||
, GermanData
|
||||
, Utils
|
||||
executable haga
|
||||
build-depends: base
|
||||
, bytestring
|
||||
|
@ -83,8 +83,9 @@ executable haga
|
|||
, Pretty
|
||||
, Szenario191
|
||||
, LambdaCalculus
|
||||
, IrisDataset
|
||||
, IrisData
|
||||
, GermanDataset
|
||||
, GermanData
|
||||
, Utils
|
||||
|
||||
executable haga-test
|
||||
build-depends: base
|
||||
|
@ -118,5 +119,6 @@ executable haga-test
|
|||
, Pretty
|
||||
, Szenario191
|
||||
, LambdaCalculus
|
||||
, IrisDataset
|
||||
, IrisData
|
||||
, GermanDataset
|
||||
, GermanData
|
||||
, Utils
|
||||
|
|
|
@ -136,12 +136,8 @@ irisTrainingData =
|
|||
((5.7, 2.5, 5.0, 2.0), Virginica),
|
||||
((6.8, 2.8, 4.8, 1.4), Versicolor),
|
||||
((6.3, 2.9, 5.6, 1.8), Virginica),
|
||||
((6.0, 2.2, 4.0, 1.0), Versicolor)
|
||||
]
|
||||
|
||||
irisTestData :: [((Float, Float, Float, Float), IrisClass)]
|
||||
irisTestData =
|
||||
[ ((5.0, 3.5, 1.6, 0.6), Setosa),
|
||||
((6.0, 2.2, 4.0, 1.0), Versicolor),
|
||||
((5.0, 3.5, 1.6, 0.6), Setosa),
|
||||
((4.6, 3.1, 1.5, 0.2), Setosa),
|
||||
((4.8, 3.4, 1.6, 0.2), Setosa),
|
||||
((4.8, 3.0, 1.4, 0.3), Setosa),
|
||||
|
@ -172,3 +168,4 @@ irisTestData =
|
|||
((6.1, 2.6, 5.6, 1.4), Virginica),
|
||||
((6.6, 2.9, 4.6, 1.3), Versicolor)
|
||||
]
|
||||
|
||||
|
|
|
@ -15,6 +15,7 @@ where
|
|||
import qualified Data.List.NonEmpty as NE
|
||||
import qualified Data.Map.Strict as Map
|
||||
import Data.Random
|
||||
import System.Random.MWC (createSystemRandom)
|
||||
import Data.Random.Distribution.Uniform
|
||||
import qualified Data.Text as T
|
||||
import Data.Tuple.Extra
|
||||
|
@ -24,6 +25,7 @@ import IrisData
|
|||
import qualified Language.Haskell.Interpreter as Hint
|
||||
import qualified Language.Haskell.Interpreter.Unsafe as Hint
|
||||
import Protolude
|
||||
import Utils
|
||||
import Protolude.Error
|
||||
import qualified Type.Reflection as Ref
|
||||
|
||||
|
@ -64,15 +66,35 @@ irisLEE =
|
|||
imports = ["IrisDataset"],
|
||||
training = True,
|
||||
trainingData =
|
||||
( map fst irisTrainingData,
|
||||
map snd irisTrainingData
|
||||
( map fst (takeFraktion 0.8 irisTrainingData),
|
||||
map snd (takeFraktion 0.8 irisTrainingData)
|
||||
),
|
||||
testData =
|
||||
( map fst irisTestData,
|
||||
map snd irisTestData
|
||||
( map fst (dropFraktion 0.8 irisTrainingData),
|
||||
map snd (dropFraktion 0.8 irisTrainingData)
|
||||
),
|
||||
exTargetType = (Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Float -> Float -> IrisClass))),
|
||||
results = Map.empty
|
||||
}
|
||||
|
||||
shuffledIrisLEE :: IO LamdaExecutionEnv
|
||||
shuffledIrisLEE = do
|
||||
mwc <- liftIO createSystemRandom
|
||||
let smpl = ((sampleFrom mwc) :: RVar a -> IO a)
|
||||
itD <- smpl $ shuffle irisTrainingData
|
||||
return LamdaExecutionEnv
|
||||
{ -- For now these need to define all available functions and types. Generic functions can be used.
|
||||
imports = ["IrisDataset"],
|
||||
training = True,
|
||||
trainingData =
|
||||
( map fst (takeFraktion 0.8 itD),
|
||||
map snd (takeFraktion 0.8 itD)
|
||||
),
|
||||
testData =
|
||||
( map fst (dropFraktion 0.8 itD),
|
||||
map snd (dropFraktion 0.8 itD)
|
||||
),
|
||||
exTargetType = (Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Float -> Float -> IrisClass))),
|
||||
-- todo: kindaHacky
|
||||
results = Map.empty
|
||||
}
|
||||
|
||||
|
@ -92,8 +114,9 @@ data FittnesRes = FittnesRes
|
|||
fitnessTotal :: R,
|
||||
fitnessGeoMean :: R,
|
||||
fitnessMean :: R,
|
||||
accuracy :: Int,
|
||||
biasSize :: R
|
||||
accuracy :: R,
|
||||
biasSize :: R,
|
||||
totalSize :: N
|
||||
}
|
||||
deriving (Show)
|
||||
|
||||
|
@ -104,10 +127,11 @@ instance Evaluator TypeRequester LamdaExecutionEnv FittnesRes where
|
|||
fitness' env tr = (results env) Map.! tr
|
||||
|
||||
calc env pop = do
|
||||
let toAdd = NE.filter (\k -> not (Map.member k (results env))) pop
|
||||
let relevantResults = Map.filterWithKey (\k _ -> contains pop k) (results env)
|
||||
let toAdd = NE.filter (\k -> not (Map.member k relevantResults)) pop
|
||||
toInsert <- Hint.runInterpreter (evalResults env toAdd)
|
||||
let insertPair (key, val) m = Map.insert key val m
|
||||
let res = foldr insertPair (results env) (fromRight (error ("To insert is " <> show toInsert)) toInsert)
|
||||
let res = foldr insertPair relevantResults (fromRight (error ("To insert is " <> show toInsert)) toInsert)
|
||||
return env {results = res}
|
||||
|
||||
dset :: LamdaExecutionEnv -> ([(Float, Float, Float, Float)], [IrisClass])
|
||||
|
@ -123,7 +147,7 @@ evalResult ex tr = do
|
|||
result <- Hint.interpret (T.unpack (toLambdaExpressionS tr)) (Hint.as :: Float -> Float -> Float -> Float -> IrisClass)
|
||||
let res = map (\(a, b, c, d) -> result a b c d) (fst (dset ex))
|
||||
let resAndTarget = (zip (snd (dset ex)) res)
|
||||
let acc = (foldr (\ts s -> if ((fst ts) == (snd ts)) then s + 1 else s) 0 resAndTarget) :: Int
|
||||
let acc = (foldr (\ts s -> if ((fst ts) == (snd ts)) then s + 1 else s) 0 resAndTarget) / fromIntegral (length resAndTarget)
|
||||
let biasSmall = exp ((-(fromIntegral (countTrsR tr)))/1000) -- 0 (schlecht) bis 1 (gut)
|
||||
let fitness' = meanOfAccuricyPerClass resAndTarget
|
||||
let score = fitness' + (biasSmall - 1)
|
||||
|
@ -135,7 +159,8 @@ evalResult ex tr = do
|
|||
fitnessMean = meanOfAccuricyPerClass resAndTarget,
|
||||
fitnessGeoMean = geomeanOfDistributionAccuracy resAndTarget,
|
||||
accuracy = acc,
|
||||
biasSize = biasSmall
|
||||
biasSize = biasSmall,
|
||||
totalSize = countTrsR tr
|
||||
}
|
||||
)
|
||||
|
||||
|
|
|
@ -9,7 +9,7 @@
|
|||
|
||||
module LambdaCalculus where
|
||||
|
||||
import Data.List (foldr1, last, nub, intersect, (!!), (\\))
|
||||
import Data.List (foldr1, intersect, last, nub, (!!), (\\))
|
||||
import qualified Data.List.NonEmpty as NE
|
||||
import qualified Data.Map.Strict as Map
|
||||
import Data.Maybe
|
||||
|
@ -17,14 +17,15 @@ import Data.Random
|
|||
import qualified Data.Text as T
|
||||
import Data.Tuple.Extra
|
||||
import Data.Typeable
|
||||
import Debug.Trace as DB
|
||||
import GA
|
||||
import Pretty
|
||||
import Protolude
|
||||
import Protolude.Error
|
||||
import Debug.Trace as DB
|
||||
import Test.QuickCheck hiding (sample, shuffle)
|
||||
import Test.QuickCheck.Monadic (assert, monadicIO)
|
||||
import qualified Type.Reflection as Ref
|
||||
import Utils
|
||||
|
||||
data ExpressionWeights = ExpressionWeights
|
||||
{ lambdaSpucker :: Int,
|
||||
|
@ -73,7 +74,6 @@ exampleLE =
|
|||
|
||||
type BoundVars = [TypeRep]
|
||||
|
||||
|
||||
-- we need a dynamic typ with a concept of equality here, should we want to interpret the result, instead of compiling it...
|
||||
type ConVal = Text
|
||||
|
||||
|
@ -96,7 +96,6 @@ toLambdaExpressionS (TR _ (Nothing) _) = "Invalid Lambda Epr"
|
|||
|
||||
-- data LambdaExpression = LambdaSpucker TypeRequester TypeRequester BoundVars | LambdaSchlucker TypeRequester BoundVars | Symbol ConVal [TypeRequester] BoundVars | Var TypeRep Int [TypeRequester] BoundVars | Constan ConVal deriving (Eq, Ord, Show)
|
||||
|
||||
|
||||
eToLambdaExpressionS :: LambdaExpression -> Text
|
||||
eToLambdaExpressionS (LambdaSpucker typeRequester1 typeRequester2 boundVars) = "(\\l" <> showSanifid (last boundVars) <> show (count boundVars (last boundVars) - 1) <> " -> " <> toLambdaExpressionS typeRequester2 <> ") " <> toLambdaExpressionS typeRequester1
|
||||
eToLambdaExpressionS (LambdaSchlucker typeRequester boundVars) = "\\l" <> showSanifid (last boundVars) <> show (count boundVars (last boundVars) - 1) <> " -> " <> toLambdaExpressionS typeRequester
|
||||
|
@ -179,7 +178,7 @@ genLambdaSchlucker env@(LambdaEnviroment functions constants _ _ weights) depthL
|
|||
let args = typeRepArgs target
|
||||
let lambaType = fromJust (head args)
|
||||
let toFind = last args
|
||||
typeRequester <- genTypeRequester env depthLeft toFind (boundVar ++ [lambaType])
|
||||
typeRequester <- genTypeRequester env (depthLeft + 1) toFind (boundVar ++ [lambaType])
|
||||
return (LambdaSchlucker typeRequester (boundVar ++ [lambaType]))
|
||||
|
||||
genLambdaConst :: LambdaEnviroment -> Int -> TypeRep -> BoundVars -> RVar LambdaExpression
|
||||
|
@ -234,100 +233,119 @@ instance Environment TypeRequester LambdaEnviroment where
|
|||
return tr
|
||||
|
||||
mutate env@(LambdaEnviroment _ _ _ maxDepth _) tr = do
|
||||
let trCount = countTrsR (tr)
|
||||
selectedTR <- uniform 1 trCount
|
||||
let (depthAt, (TR trep _ bound)) = depthLeftAndTypeAtR tr selectedTR maxDepth
|
||||
res <- genTypeRequester env depthAt trep bound
|
||||
return $ replaceAtR selectedTR tr res
|
||||
selfCrossover <- uniform True False
|
||||
co <- crossover1 env tr tr
|
||||
if selfCrossover && isJust co
|
||||
then do
|
||||
let (tr1, tr2) = fromJust co
|
||||
return $ minimumBy (compare `on` countTrsR) [tr1, tr2]
|
||||
else do
|
||||
let trCount = countTrsR (tr)
|
||||
selectedTR <- uniform 1 trCount
|
||||
let (depthAt, (TR trep _ bound)) = depthLeftAndTypeAtR tr selectedTR maxDepth
|
||||
res <- genTypeRequester env depthAt trep bound
|
||||
return $ replaceAtR selectedTR tr res
|
||||
|
||||
nX _ = 3 -- todo!
|
||||
|
||||
crossover1 env@(LambdaEnviroment _ _ _ maxDepth _) tr1 tr2 = do
|
||||
let trCount = countTrsR tr1
|
||||
selectedIndex1 <- uniform 1 trCount
|
||||
let (depthAt, selectedTr1@(TR _ _ bound1)) = depthLeftAndTypeAtR tr1 selectedIndex1 maxDepth
|
||||
let indexes = findIndicesWhere tr2 (isCompatibleTr selectedTr1) 0
|
||||
if length indexes == 0 then return Nothing else (do
|
||||
(selectedTr2@(TR _ _ bound2),selectedIndex2) <- randomElement indexes
|
||||
selectedTr2 <- adaptBoundVars selectedTr2 bound1
|
||||
selectedTr1 <- adaptBoundVars selectedTr1 bound2
|
||||
let child1 = replaceAtR selectedIndex1 tr1 selectedTr2
|
||||
let child2 = replaceAtR selectedIndex2 tr2 selectedTr1
|
||||
return $ Just (child1, child2)
|
||||
)
|
||||
|
||||
let (depthAt1, selectedTr1@(TR _ _ bound1)) = depthLeftAndTypeAtR tr1 selectedIndex1 maxDepth
|
||||
let depthLeftNeeded = depthOfTR selectedTr1
|
||||
let indexes = findIndicesWhere tr2 (isCompatibleTr selectedTr1 (maxDepth - depthAt1) depthLeftNeeded) 0 0
|
||||
if length indexes == 0
|
||||
then return Nothing
|
||||
else
|
||||
( do
|
||||
(selectedTr2@(TR _ _ bound2), selectedIndex2) <- randomElement indexes
|
||||
selectedTr2 <- adaptBoundVars selectedTr2 bound1
|
||||
selectedTr1 <- adaptBoundVars selectedTr1 bound2
|
||||
let child1 = replaceAtR selectedIndex1 tr1 selectedTr2
|
||||
let child2 = replaceAtR selectedIndex2 tr2 selectedTr1
|
||||
return $ Just (child1, child2)
|
||||
)
|
||||
|
||||
-- helper
|
||||
adaptBoundVars:: TypeRequester -> BoundVars -> RVar TypeRequester
|
||||
depthOfTR :: TypeRequester -> Int
|
||||
depthOfTR (TR _ (Just le@(LambdaSchlucker _ _)) _) = maximum (0:(map depthOfTR (asList le)))
|
||||
depthOfTR (TR _ (Just le) _) = maximum (0:(map depthOfTR (asList le))) + 1
|
||||
depthOfTR _ = error "le Not Just (depthOfTR)"
|
||||
|
||||
adaptBoundVars :: TypeRequester -> BoundVars -> RVar TypeRequester
|
||||
adaptBoundVars tr@(TR _ _ bvOld) bvNew = do
|
||||
newIndexMap <- generateConversionIndexMap bvOld bvNew
|
||||
return $ convertTr tr bvOld bvNew newIndexMap
|
||||
|
||||
convertTr:: TypeRequester -> BoundVars -> BoundVars -> Map TypeRep (Int -> Int) -> TypeRequester
|
||||
convertTr :: TypeRequester -> BoundVars -> BoundVars -> Map TypeRep (Int -> Int) -> TypeRequester
|
||||
convertTr tr@(TR tRp (Just le) bvCurr) bvOld bvNew mapper = TR tRp (Just (convertLe le bvOld bvNew mapper)) (bvNew ++ (bvCurr \\ bvOld))
|
||||
convertTr _ _ _ _ = error "le Not Just (convertTr)"
|
||||
|
||||
|
||||
-- data LambdaExpression = LambdaSpucker TypeRequester TypeRequester BoundVars | LambdaSchlucker TypeRequester BoundVars | Symbol ConVal [TypeRequester] BoundVars | Var TypeRep Int [TypeRequester] BoundVars | Constan ConVal deriving (Eq, Ord, Show)
|
||||
convertLe:: LambdaExpression -> BoundVars -> BoundVars -> Map TypeRep (Int -> Int) -> LambdaExpression
|
||||
convertLe :: LambdaExpression -> BoundVars -> BoundVars -> Map TypeRep (Int -> Int) -> LambdaExpression
|
||||
convertLe (LambdaSpucker tr1 tr2 bvCurr) bvOld bvNew mapper = LambdaSpucker (convertTrf tr1) (convertTrf tr2) (bvNew ++ (bvCurr \\ bvOld))
|
||||
where convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
where
|
||||
convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
convertLe (LambdaSchlucker tr bvCurr) bvOld bvNew mapper = LambdaSchlucker (convertTrf tr) (bvNew ++ (bvCurr \\ bvOld))
|
||||
where convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
where
|
||||
convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
convertLe (Symbol cv trs bvCurr) bvOld bvNew mapper = Symbol cv (map convertTrf trs) (bvNew ++ (bvCurr \\ bvOld))
|
||||
where convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
where
|
||||
convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
convertLe (Var varType varNumber trs bvCurr) bvOld bvNew mapper = Var varType ((fromMaybe identity (Map.lookup varType mapper)) varNumber) (map convertTrf trs) (bvNew ++ (bvCurr \\ bvOld))
|
||||
where convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
where
|
||||
convertTrf tr = convertTr tr bvOld bvNew mapper
|
||||
convertLe le@(Constan _) _ _ _ = le
|
||||
|
||||
|
||||
generateConversionIndexMap:: BoundVars -> BoundVars -> RVar (Map TypeRep (Int -> Int))
|
||||
generateConversionIndexMap :: BoundVars -> BoundVars -> RVar (Map TypeRep (Int -> Int))
|
||||
generateConversionIndexMap bvOld bvNew = do
|
||||
funcs <- mapM (\bT -> genMapper (count bvOld bT - 1) (count bvNew bT - 1)) (nub bvOld)
|
||||
return $ Map.fromList $ zip (nub bvOld) funcs
|
||||
|
||||
genMapper:: Int -> Int -> RVar (Int -> Int)
|
||||
genMapper i j | i == j = return identity
|
||||
| i < j = return $ \int -> if int <= i then int else int + (j-i)
|
||||
| i > j = do
|
||||
permutationForUnbound <- genPermutation i j
|
||||
return $ genMapperRandomAssment i j permutationForUnbound
|
||||
| otherwise = error "impossible case in genMapper"
|
||||
genMapper :: Int -> Int -> RVar (Int -> Int)
|
||||
genMapper i j
|
||||
| i == j = return identity
|
||||
| i < j = return $ \int -> if int <= i then int else int + (j - i)
|
||||
| i > j = do
|
||||
permutationForUnbound <- genPermutation i j
|
||||
return $ genMapperRandomAssment i j permutationForUnbound
|
||||
| otherwise = error "impossible case in genMapper"
|
||||
|
||||
genMapperRandomAssment:: Int -> Int -> [Int] -> Int -> Int
|
||||
genMapperRandomAssment i j permutationForUnbound int | int <= j = int
|
||||
| int > i = int - (i-j)
|
||||
| otherwise = permutationForUnbound !! (int - j - 1)
|
||||
genMapperRandomAssment :: Int -> Int -> [Int] -> Int -> Int
|
||||
genMapperRandomAssment i j permutationForUnbound int
|
||||
| int <= j = int
|
||||
| int > i = int - (i - j)
|
||||
| otherwise = permutationForUnbound !! (int - j - 1)
|
||||
|
||||
genPermutation:: Int -> Int -> RVar [Int]
|
||||
genPermutation :: Int -> Int -> RVar [Int]
|
||||
genPermutation i j = replicateM (i - j) (uniform 0 j)
|
||||
|
||||
isCompatibleTr:: TypeRequester -> TypeRequester -> Bool
|
||||
isCompatibleTr tr1@(TR trep1 _ bound1) tr2@(TR trep2 _ bound2) | trep1 == trep2 = allUsedBound (usedVars bound1 tr1) bound2 && allUsedBound (usedVars bound2 tr2) bound1
|
||||
| otherwise = False
|
||||
isCompatibleTr :: TypeRequester -> Int -> Int -> TypeRequester -> Int -> Bool
|
||||
isCompatibleTr tr1@(TR trep1 _ bound1) maxDepthOfTR2 maxDepthOfNode tr2@(TR trep2 _ bound2) depthOfNode
|
||||
| trep1 == trep2 = allUsedBound (usedVars bound1 tr1) bound2 && allUsedBound (usedVars bound2 tr2) bound1 && maxDepthOfTR2 >= (depthOfTR tr2) && maxDepthOfNode >= depthOfNode
|
||||
| otherwise = False
|
||||
|
||||
allUsedBound :: BoundVars -> BoundVars -> Bool
|
||||
allUsedBound used available = all (\x -> any (== x) available) used
|
||||
|
||||
|
||||
usedVars :: BoundVars -> TypeRequester -> BoundVars
|
||||
usedVars boundOld tr@(TR trep1 (Just (Var trp ind trs _)) _) = if any (== trp) boundOld && count boundOld trp > ind then trp : concatMap (usedVars boundOld) trs else concatMap (usedVars boundOld) trs
|
||||
usedVars boundOld tr@(TR trep1 (Just le) _) = concatMap (usedVars boundOld) (asList le)
|
||||
usedVars boundOld tr@(TR trep1 (Just le) _) = concatMap (usedVars boundOld) (asList le)
|
||||
usedVars _ _ = error "Nothing in usedVars"
|
||||
|
||||
boundsConvertable :: BoundVars -> BoundVars -> Bool
|
||||
boundsConvertable bv1 bv2 = length (nub bv2) == length (nub bv1) && length (intersect (nub bv1) bv2) == length (nub bv1)
|
||||
|
||||
boundsConvertable:: BoundVars -> BoundVars -> Bool
|
||||
boundsConvertable bv1 bv2 = length (nub bv2) == length (nub bv1) && length (intersect (nub bv1) bv2) == length (nub bv1)
|
||||
findIndicesWhere :: TypeRequester -> (TypeRequester -> Int -> Bool) -> Int -> Int -> [(TypeRequester, Int)]
|
||||
findIndicesWhere tr@(TR _ (Just le@(LambdaSchlucker _ _)) _) filte indx currDepth = if filte tr currDepth then (tr, indx + 1) : (findIndicesWhere' (asList le) filte (indx + 1) (currDepth)) else (findIndicesWhere' (asList le) filte (indx + 1) (currDepth))
|
||||
findIndicesWhere tr@(TR _ lE _) filte indx currDepth = case lE of
|
||||
Just le -> if filte tr currDepth then (tr, indx + 1) : (findIndicesWhere' (asList le) filte (indx + 1) (currDepth + 1)) else (findIndicesWhere' (asList le) filte (indx + 1) (currDepth + 1))
|
||||
Nothing -> error "Nothing in findIndicesWhere"
|
||||
|
||||
|
||||
findIndicesWhere:: TypeRequester -> (TypeRequester -> Bool) -> Int -> [(TypeRequester, Int)]
|
||||
findIndicesWhere tr@(TR t lE _) filte indx = case lE of
|
||||
Just le -> if filte tr then (tr, indx+1):(findIndicesWhere' (asList le) filte (indx+1)) else (findIndicesWhere' (asList le) filte (indx+1))
|
||||
Nothing -> error "Nothing in findIndicesWhere"
|
||||
|
||||
findIndicesWhere':: [TypeRequester] -> (TypeRequester -> Bool) -> Int -> [(TypeRequester, Int)]
|
||||
findIndicesWhere' [] _ _ = []
|
||||
findIndicesWhere' [tr] f indx = (findIndicesWhere tr f indx)
|
||||
findIndicesWhere' (tr:trs) f indx = (findIndicesWhere tr f indx) ++ (findIndicesWhere' trs f (indx + countTrsR tr))
|
||||
findIndicesWhere' :: [TypeRequester] -> (TypeRequester -> Int -> Bool) -> Int -> Int -> [(TypeRequester, Int)]
|
||||
findIndicesWhere' [] _ _ _ = []
|
||||
findIndicesWhere' [tr] f indx currDepth = (findIndicesWhere tr f indx currDepth)
|
||||
findIndicesWhere' (tr : trs) f indx currDepth = (findIndicesWhere tr f indx currDepth) ++ (findIndicesWhere' trs f (indx + countTrsR tr) currDepth)
|
||||
|
||||
replaceAtR :: Int -> TypeRequester -> TypeRequester -> TypeRequester
|
||||
replaceAtR 1 _ with = with
|
||||
|
@ -351,6 +369,7 @@ depthLeftAndTypeAtR (TR _ (Just le) _) indexLeft depthLeft = depthLeftAndTypeAt
|
|||
depthLeftAndTypeAtR (TR _ Nothing _) indexLeft depthLeft = error "Nothing in depthLeftAndTypeAtR"
|
||||
|
||||
depthLeftAndTypeAt :: LambdaExpression -> Int -> Int -> (Int, TypeRequester)
|
||||
depthLeftAndTypeAt le@(LambdaSchlucker tr bv) indexLeft depthLeft = depthLeftAndTypeInSubtreeWithIndex (asList le) indexLeft (depthLeft + 1)
|
||||
depthLeftAndTypeAt le indexLeft depthLeft = depthLeftAndTypeInSubtreeWithIndex (asList le) indexLeft depthLeft
|
||||
|
||||
depthLeftAndTypeInSubtreeWithIndex :: [TypeRequester] -> Int -> Int -> (Int, TypeRequester)
|
||||
|
@ -365,17 +384,6 @@ countTrsR tr@(TR t lE _) = case lE of
|
|||
countTrs :: LambdaExpression -> Int
|
||||
countTrs le = sum (map countTrsR (asList le))
|
||||
|
||||
repeatedly :: (a -> Maybe a) -> a -> [a]
|
||||
repeatedly f x = case f x of
|
||||
Nothing -> []
|
||||
Just y -> y : repeatedly f y
|
||||
|
||||
count :: (Eq a) => [a] -> a -> Int
|
||||
count [] find = 0
|
||||
count ys find = length xs
|
||||
where
|
||||
xs = [xs | xs <- ys, xs == find]
|
||||
|
||||
-- Test Stuff
|
||||
|
||||
testConstInt :: TypeRequester
|
||||
|
@ -535,34 +543,3 @@ eToLambdaExpressionShort (Constan (valS)) = valS
|
|||
|
||||
res :: Int -> ResClass
|
||||
res = ((\lInt0 -> ((iteClass ((eqInt ((lInt0) :: (Int)) ((1) :: (Int))) :: (Bool)) ((Class1) :: (ResClass)) ((iteClass ((eqInt ((lInt0) :: (Int)) ((2) :: (Int))) :: (Bool)) ((Class2) :: (ResClass)) ((iteClass ((eqInt ((lInt0) :: (Int)) ((3) :: (Int))) :: (Bool)) ((Class3) :: (ResClass)) ((Class3) :: (ResClass))) :: (ResClass))) :: (ResClass))) :: (ResClass))) :: (Int -> ResClass))
|
||||
|
||||
|
||||
meanOfAccuricyPerClass :: (Enum r, Bounded r, Eq r) => [(r, r)] -> R
|
||||
meanOfAccuricyPerClass results = mean $ map (accuracyInClass results) [minBound .. maxBound]
|
||||
|
||||
geomeanOfAccuricyPerClass :: (Enum r, Bounded r, Eq r) => [(r, r)] -> R
|
||||
geomeanOfAccuricyPerClass results = geomean $ map (accuracyInClass results) [minBound .. maxBound]
|
||||
|
||||
geomeanOfDistributionAccuracy :: (Enum r, Bounded r, Eq r) => [(r, r)] -> R
|
||||
geomeanOfDistributionAccuracy results = geomean $ map (distributionAccuracyForClass results) [minBound .. maxBound]
|
||||
|
||||
distributionAccuracyForClass :: (Eq r) => [(r, r)] -> r -> R
|
||||
distributionAccuracyForClass results clas = (1 - (min 1 (fromIntegral (abs ((length (inResClass results clas)) - (length (inClass results clas)))) / fromIntegral (length (inClass results clas))))) * 100
|
||||
|
||||
mean :: (Show f, Floating f) => [f] -> f
|
||||
mean values = (sum values) * (1 / (fromIntegral (length values)))
|
||||
|
||||
geomean :: (Show f, Floating f) => [f] -> f
|
||||
geomean values = (product values) ** (1 / (fromIntegral (length values)))
|
||||
|
||||
accuracyInClass :: (Eq r) => [(r, r)] -> r -> R
|
||||
accuracyInClass results clas = ((accuracy'(inResClass results clas)) * 100) / fromIntegral (length (inClass results clas))
|
||||
|
||||
inClass :: (Eq r) => [(r, r)] -> r -> [(r, r)]
|
||||
inClass results clas = (filter ((clas ==) . fst) results)
|
||||
|
||||
inResClass :: (Eq r) => [(r, r)] -> r -> [(r, r)]
|
||||
inResClass results clas = (filter ((clas ==) . snd) results)
|
||||
|
||||
accuracy' :: (Eq r) => [(r, r)] -> R
|
||||
accuracy' results = fromIntegral $ length (filter (\(target, res) -> (res == target)) results)
|
||||
|
|
23
src/Main.hs
23
src/Main.hs
|
@ -9,7 +9,7 @@ import Protolude hiding (for)
|
|||
import System.IO
|
||||
-- import Szenario212Pun
|
||||
-- import Szenario191
|
||||
import IrisDataset
|
||||
import GermanDataset
|
||||
import Debug.Trace as DB
|
||||
import qualified Data.Map.Strict as Map
|
||||
|
||||
|
@ -26,7 +26,7 @@ options =
|
|||
( long "iterations"
|
||||
<> short 'i'
|
||||
<> metavar "N"
|
||||
<> value 500
|
||||
<> value 1000
|
||||
<> help "Number of iterations"
|
||||
)
|
||||
<*> option
|
||||
|
@ -51,18 +51,19 @@ main :: IO ()
|
|||
main =
|
||||
execParser optionsWithHelp >>= \opts -> do
|
||||
hSetBuffering stdout NoBuffering
|
||||
let env = irisLE
|
||||
germanLEE <- shuffledGermanLEE
|
||||
let env = germanLE
|
||||
let selType = Tournament 3
|
||||
let run' = run irisLEE env selType 40 (5 / 100) (populationSize opts) (steps (iterations opts))
|
||||
let run' = run germanLEE env selType 80 (5 / 100) (populationSize opts) (steps (iterations opts))
|
||||
pop' <- runEffect (for run' logCsv)
|
||||
irisLEE' <- calc irisLEE pop'
|
||||
let (res, _) = bests irisLEE' 5 pop'
|
||||
let irisLEE' = irisLEE {training = False}
|
||||
irisLEE' <- calc irisLEE' res
|
||||
mapM_ (format irisLEE') res
|
||||
germanLEE' <- calc germanLEE pop'
|
||||
let (res, _) = bests germanLEE' 5 pop'
|
||||
let germanLEE' = germanLEE {training = False}
|
||||
germanLEE' <- calc germanLEE' res
|
||||
mapM_ (format germanLEE') res
|
||||
where
|
||||
format irisL s = do
|
||||
let f = fitness' irisL s
|
||||
format germanL s = do
|
||||
let f = fitness' germanL s
|
||||
putErrText $ show f <> "\n" <> pretty s
|
||||
logCsv = putText . csv
|
||||
csv (t, f) = show t <> " " <> show f
|
||||
|
|
Loading…
Reference in New Issue
Block a user