LamdaCalculusV2

WIP: rewrite... too much...
2024-05-07 14:58:00 +02:00 · 2024-04-30 07:42:10 +02:00
12 changed files with 735 additions and 13164 deletions
--- a/haga.cabal
+++ b/haga.cabal
@ -40,6 +40,7 @@ library
                     , random
                     , random-fu
                     , random-shuffle
                     , semirings
                     , text
                     , wl-pprint-text
  default-language:    Haskell2010
@ -48,6 +49,7 @@ library
  other-modules:       CommonDefinition
  exposed-modules:     GA
                     , LambdaCalculus
                     , LambdaCalculusV2
                     , Pretty
                     , Utils
                     , LambdaDatasets.NurseryDefinition
--- a/lambda/lib/LambdaDatasets/NurseryDefinition.hs
+++ b/lambda/lib/LambdaDatasets/NurseryDefinition.hs
@ -13,20 +13,28 @@ import Protolude
 import CommonDefinition
 data NurseryClass = NotRecommend | Recommend | VeryRecommend | Priority | SpecPriority deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable NurseryClass
 data Parents = Usual | Pretentious | GreatPret deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable Parents
 data HasNurs = ProperNurs | LessProperNurs | ImproperNurs | CriticalNurs | VeryCritNurs deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable HasNurs
 data Form    = CompleteFamilyForm | CompletedFamilyForm | IncompleteFamilyForm | FosterFamilyForm deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable Form
 data Children = OneChild | TwoChilds | ThreeChilds | MoreChilds deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable Children
 data Housing = ConvenientHousing | LessConvHousing | CriticalHousing deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable Housing
 data Finance = ConvenientFinance | InconvFinance deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable Finance
 data Social = NotProblematicSocial | SlightlyProblematicSocial | ProblematicSocial deriving (Eq, Generic, Show, Enum, Bounded, Ord)
 instance Hashable Social
 data Health = NotRecommendHealth |RecommendedHealth | PriorityHealth  deriving (Eq, Generic, Show, Enum, Bounded, Ord)
-
+instance Hashable Health
--- a/lambda/src/LambdaDatasets/GermanDataset.hs
+++ b/lambda/src/LambdaDatasets/GermanDataset.hs
@ -38,7 +38,7 @@ lE =
            ((Ref.SomeTypeRep (Ref.TypeRep @(Int -> Int -> Int))), ["(+)", "(-)", "(*)"]),
            -- Logic
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Bool -> Bool))), ["(&&)", "(||)"]),
-            -- Ordered
+            -- Ordered Enums
            ((Ref.SomeTypeRep (Ref.TypeRep @(Int -> Int -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(AccountStatus -> AccountStatus -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(CreditHistory -> CreditHistory -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
@ -46,7 +46,7 @@ lE =
            ((Ref.SomeTypeRep (Ref.TypeRep @(EmploymentStatus -> EmploymentStatus -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(OtherDebtors -> OtherDebtors -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Job -> Job -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
-            -- Eq
+            -- Eq Enum
            ((Ref.SomeTypeRep (Ref.TypeRep @(GermanClass -> GermanClass -> Bool))), ["(==)", "(/=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Purpose -> Purpose -> Bool))), ["(==)", "(/=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(StatusAndSex -> StatusAndSex -> Bool))), ["(==)", "(/=)"]),
@ -55,7 +55,7 @@ lE =
            ((Ref.SomeTypeRep (Ref.TypeRep @(Housing -> Housing -> Bool))), ["(==)", "(/=)"]),
            -- Any Type
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Int -> Int -> Int))), ["if'"]),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> GermanClass -> GermanClass -> GermanClass))), ["if'"]),
+            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> GermanClass -> GermanClass -> GermanClass))), ["if'","if'","if'","if'","if'","if'","if'","if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> AccountStatus -> AccountStatus -> AccountStatus))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> CreditHistory -> CreditHistory -> CreditHistory))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Purpose -> Purpose -> Purpose))), ["if'"]),
@ -151,7 +151,6 @@ data LamdaExecutionEnv = LamdaExecutionEnv
 data FittnesRes = FittnesRes
  { total :: R,
    fitnessTotal :: R,
    costAccordingToDataset :: N,
    fitnessGeoMean :: R,
    fitnessMean :: R,
    accuracy :: R,
@ -190,9 +189,8 @@ evalResults ex trs = do
 evalResult :: LamdaExecutionEnv -> TypeRequester -> (AccountStatus -> Int -> CreditHistory -> Purpose -> Int -> Savings -> EmploymentStatus -> Int -> StatusAndSex -> OtherDebtors -> Int -> Property -> Int -> OtherPlans -> Housing -> Int -> Job -> Int -> Bool -> Bool -> GermanClass) -> (TypeRequester, FittnesRes)
 evalResult ex tr result = ( tr,
      FittnesRes
-        { total = (biasSmall - 1) - (fromIntegral costAccordingToDS),
+        { total = score,
          fitnessTotal = fitness',
          costAccordingToDataset = costAccordingToDS,
          fitnessMean = meanOfAccuricyPerClass resAndTarget,
          fitnessGeoMean = geomeanOfDistributionAccuracy resAndTarget,
          accuracy = acc,
@ -203,8 +201,7 @@ evalResult ex tr result = ( tr,
    where
    res = map (\(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t) -> result a b c d e f g h i j k l m n o p q r s t) (fst (dset ex))
    resAndTarget = (zip (snd (dset ex)) res)
-    acc = (foldr (\(actual,predicted) s -> if (actual == predicted) then s + 1 else s) 0 resAndTarget) / fromIntegral (length resAndTarget)
+    acc = (foldr (\ts s -> if ((fst ts) == (snd ts)) then s + 1 else s) 0 resAndTarget) / fromIntegral (length resAndTarget)
    costAccordingToDS = (foldr (\(actual,predicted) s -> if ((actual) == (predicted)) then s else (if actual == Deny then s+5 else s+1)) 0 resAndTarget)
    biasSmall = exp ((-(fromIntegral (countTrsR tr))) / 1000) -- 0 (schlecht) bis 1 (gut)
    fitness' = meanOfAccuricyPerClass resAndTarget
    score = fitness' + (biasSmall - 1)
--- a/lambda/src/LambdaDatasets/IrisDataset.hs
+++ b/lambda/src/LambdaDatasets/IrisDataset.hs
@ -34,17 +34,12 @@ lE =
  LambdaEnviroment
    { functions =
        Map.fromList
-          [  -- Math
+          [ ((Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Float))), ["(+)", "(-)", "(*)"]),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Float))), ["(+)", "(-)", "(*)"]),
+            ((Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Bool))), ["(>)", "(==)", "(>=)"]),
-            -- Logic
+            ((Ref.SomeTypeRep (Ref.TypeRep @(IrisClass -> IrisClass -> Bool))), ["(==)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Float -> Float -> Float))), ["if'","if'","if'","if'","if'","if'","if'","if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Bool -> Bool))), ["(&&)", "(||)"]),
-            -- Ordered
+            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> IrisClass -> IrisClass -> IrisClass))), ["if'","if'","if'","if'","if'","if'","if'","if'","if'","if'"])
            ((Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            -- Eq
            ((Ref.SomeTypeRep (Ref.TypeRep @(IrisClass -> IrisClass -> Bool))), ["(==)","(/=)"]),
            -- Any Type
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Float -> Float -> Float))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> IrisClass -> IrisClass -> IrisClass))), ["if'"])
          ],
      constants =
        Map.fromList
@ -53,13 +48,13 @@ lE =
            ((Ref.SomeTypeRep (Ref.TypeRep @(IrisClass))), [(fmap show (enumUniform Setosa Versicolor :: RVar IrisClass))])
          ],
      targetType = (Ref.SomeTypeRep (Ref.TypeRep @(Float -> Float -> Float -> Float -> IrisClass))),
-      maxDepth = 8,
+      maxDepth = 10,
      weights =
        ExpressionWeights
          { lambdaSpucker = 1,
-            lambdaSchlucker = 2,
+            lambdaSchlucker = 1,
            symbol = 30,
-            variable = 10,
+            variable = 100,
            constant = 5
          }
    }
@ -68,7 +63,7 @@ lEE :: LamdaExecutionEnv
 lEE =
  LamdaExecutionEnv
    { -- For now these need to define all available functions and types. Generic functions can be used.
-      imports = ["LambdaDatasets.IrisDefinition"],
+      imports = ["LambdaDatasets.IrisDataset"],
      training = True,
      trainingData =
        ( map fst (takeFraktion 0.8 irisTrainingData),
@ -89,7 +84,7 @@ shuffledLEE = do
  itD <- smpl $ shuffle irisTrainingData
  return  LamdaExecutionEnv
    { -- For now these need to define all available functions and types. Generic functions can be used.
-      imports = ["LambdaDatasets.IrisDefinition"],
+      imports = ["LambdaDatasets.IrisDataset"],
      training = True,
      trainingData =
        ( map fst (takeFraktion 0.8 itD),
@ -155,7 +150,7 @@ evalResults ex trs = do
 evalResult :: LamdaExecutionEnv -> TypeRequester -> (Float -> Float -> Float -> Float -> IrisClass) -> (TypeRequester, FittnesRes)
 evalResult ex tr result = ( tr,
      FittnesRes
-        { total = acc * 100 + (biasSmall - 1),
+        { total = score,
          fitnessTotal = fitness',
          fitnessMean = meanOfAccuricyPerClass resAndTarget,
          fitnessGeoMean = geomeanOfDistributionAccuracy resAndTarget,
--- a/lambda/src/LambdaDatasets/NurseryData.hs
+++ b/lambda/src/LambdaDatasets/NurseryData.hs
--- a/lambda/src/LambdaDatasets/NurseryDataset.hs
+++ b/lambda/src/LambdaDatasets/NurseryDataset.hs
@ -5,7 +5,7 @@
 {-# LANGUAGE NoImplicitPrelude #-}
 module LambdaDatasets.NurseryDataset
-  ( module LambdaCalculus,
+  ( module LambdaCalculusV2,
    module LambdaDatasets.NurseryDataset,
    module LambdaDatasets.NurseryData,
    module GA,
@ -19,8 +19,8 @@ import Data.Random.Distribution.Uniform
 import qualified Data.Text as T
 import Data.Tuple.Extra
 import GA
 import LambdaCalculusV2
 import LambdaDatasets.NurseryData
 import LambdaCalculus
 import qualified Language.Haskell.Interpreter as Hint
 import qualified Language.Haskell.Interpreter.Unsafe as Hint
 import Protolude
@ -29,171 +29,111 @@ import System.Random.MWC (createSystemRandom)
 import qualified Type.Reflection as Ref
 import Utils
-lE :: LambdaEnviroment
+operators :: [BoundSymbol]
 operators = [ -- Math
          -- Logic
          BoundSymbol (Ref.TypeRep @(Bool -> Bool -> Bool)) (&&) (Just "(&&)"),
          BoundSymbol (Ref.TypeRep @(Bool -> Bool -> Bool)) (||) (Just "(||)"),
          -- Ordered Enums
          BoundSymbol (Ref.TypeRep @(NurseryClass -> NurseryClass -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(NurseryClass -> NurseryClass -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(NurseryClass -> NurseryClass -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(NurseryClass -> NurseryClass -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Parents -> Parents -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Parents -> Parents -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Parents -> Parents -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Parents -> Parents -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(HasNurs -> HasNurs -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(HasNurs -> HasNurs -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(HasNurs -> HasNurs -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(HasNurs -> HasNurs -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Form -> Form -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Form -> Form -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Form -> Form -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Form -> Form -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Children -> Children -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Children -> Children -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Children -> Children -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Children -> Children -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Housing -> Housing -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Housing -> Housing -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Housing -> Housing -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Housing -> Housing -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Finance -> Finance -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Finance -> Finance -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Finance -> Finance -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Finance -> Finance -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Social -> Social -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Social -> Social -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Social -> Social -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Social -> Social -> Bool)) (>=) (Just "(>=)"),
          BoundSymbol (Ref.TypeRep @(Health -> Health -> Bool)) (>) (Just "(>)"),
          BoundSymbol (Ref.TypeRep @(Health -> Health -> Bool)) (==) (Just "(==)"),
          BoundSymbol (Ref.TypeRep @(Health -> Health -> Bool)) (/=) (Just "(/=)"),
          BoundSymbol (Ref.TypeRep @(Health -> Health -> Bool)) (>=) (Just "(>=)"),
          -- Eq Enum
          -- Any Type
          BoundSymbol (Ref.TypeRep @(Bool -> Int -> Int -> Int)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> NurseryClass -> NurseryClass -> NurseryClass)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Parents -> Parents -> Parents)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> HasNurs -> HasNurs -> HasNurs)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Form -> Form -> Form)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Children -> Children -> Children)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Housing -> Housing -> Housing)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Finance -> Finance -> Finance)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Social -> Social -> Social)) (if') (Just "if'"),
          BoundSymbol (Ref.TypeRep @(Bool -> Health -> Health -> Health)) (if') (Just "if'")
        ]
 lE :: LambdaEnviroment (Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass)
 lE =
  LambdaEnviroment
-    { functions =
+    { functions = operators,
        Map.fromList
          [ -- Math
            -- Logic
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Bool -> Bool))), ["(&&)", "(||)"]),
            -- Ordered
            ((Ref.SomeTypeRep (Ref.TypeRep @(NurseryClass -> NurseryClass -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Parents -> Parents -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(HasNurs -> HasNurs -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Form -> Form -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Children -> Children -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Housing -> Housing -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Finance -> Finance -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Social -> Social -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Health -> Health -> Bool))), ["(>)", "(==)", "(/=)", "(>=)"]),
            -- Eq
            -- Any Type
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Int -> Int -> Int))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> NurseryClass -> NurseryClass -> NurseryClass))), ["if'","if'","if'","if'","if'","if'","if'","if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Parents -> Parents -> Parents))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> HasNurs -> HasNurs -> HasNurs))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Form -> Form -> Form))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Children -> Children -> Children))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Housing -> Housing -> Housing))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Finance -> Finance -> Finance))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Social -> Social -> Social))), ["if'"]),
            ((Ref.SomeTypeRep (Ref.TypeRep @(Bool -> Health -> Health -> Health))), ["if'"])
          ],
      constants =
-        Map.fromList
+          [ ConstVal (Ref.TypeRep @(Bool)) (uniform True False),
-          [ ((Ref.SomeTypeRep (Ref.TypeRep @(Bool))), [(fmap show (uniform True False :: RVar Bool))]),
+            ConstVal (Ref.TypeRep @(NurseryClass)) (enumUniform NotRecommend SpecPriority),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(NurseryClass))), [(fmap show (enumUniform NotRecommend SpecPriority))]),
+            ConstVal (Ref.TypeRep @(Parents)) (enumUniform Usual GreatPret),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Parents))), [(fmap show (enumUniform Usual GreatPret))]),
+            ConstVal (Ref.TypeRep @(HasNurs)) (enumUniform ProperNurs VeryCritNurs),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(HasNurs))), [(fmap show (enumUniform ProperNurs VeryCritNurs ))]),
+            ConstVal (Ref.TypeRep @(Form)) (enumUniform CompleteFamilyForm FosterFamilyForm),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Form))), [(fmap show (enumUniform CompleteFamilyForm FosterFamilyForm ))]),
+            ConstVal (Ref.TypeRep @(Children)) (enumUniform OneChild MoreChilds),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Children))), [(fmap show (enumUniform OneChild MoreChilds ))]),
+            ConstVal (Ref.TypeRep @(Housing)) (enumUniform ConvenientHousing CriticalHousing),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Housing))), [(fmap show (enumUniform ConvenientHousing CriticalHousing ))]),
+            ConstVal (Ref.TypeRep @(Finance)) (enumUniform ConvenientFinance InconvFinance),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Finance))), [(fmap show (enumUniform ConvenientFinance InconvFinance ))]),
+            ConstVal (Ref.TypeRep @(Social)) (enumUniform NotProblematicSocial ProblematicSocial),
-            ((Ref.SomeTypeRep (Ref.TypeRep @(Social))), [(fmap show (enumUniform NotProblematicSocial ProblematicSocial ))]),
+            ConstVal (Ref.TypeRep @(Health)) (enumUniform NotRecommendHealth PriorityHealth)
            ((Ref.SomeTypeRep (Ref.TypeRep @(Health))), [(fmap show (enumUniform NotRecommendHealth PriorityHealth ))])
          ],
-      targetType = (Ref.SomeTypeRep (Ref.TypeRep @(Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass))),
+      maxDepth = 150,
      maxDepth = 8,
      weights =
        ExpressionWeights
-          { lambdaSpucker = 1,
+          { application = 2,
-            lambdaSchlucker = 2,
+            abstraction = 2,
-            symbol = 30,
+            variableReference = 300,
-            variable = 10,
+            constant = 1,
-            constant = 5
+            functionBias = 100
-          }
+          },
      mutationStrength = 10/150,
      crossoverStrength = 15/150
    }
 trainingFraction :: R
-trainingFraction = (2/3)
+trainingFraction = (2 / 3)
-lEE :: LamdaExecutionEnv
+lEE :: ExecutionEnviroment (Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass)
 lEE =
-  LamdaExecutionEnv
+  ExecutionEnviroment
    { -- For now these need to define all available functions and types. Generic functions can be used.
-      imports = ["LambdaDatasets.NurseryDefinition"],
+      fun = operators,
      training = True,
-      trainingData =
+      trainingData = nurseryTrainingData,
-        ( map fst (takeFraktion trainingFraction nurseryTrainingData),
+      testData = nurseryTrainingData
          map snd (takeFraktion trainingFraction nurseryTrainingData)
        ),
      testData =
        ( map fst (dropFraktion trainingFraction nurseryTrainingData),
          map snd (dropFraktion trainingFraction nurseryTrainingData)
        ),
      exTargetType = (Ref.SomeTypeRep (Ref.TypeRep @(Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass))),
      results = Map.empty
    }
-shuffledLEE :: IO LamdaExecutionEnv
+shuffledLEE :: IO (ExecutionEnviroment (Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass))
 shuffledLEE = do
  mwc <- liftIO createSystemRandom
  let smpl = ((sampleFrom mwc) :: RVar a -> IO a)
  itD <- smpl $ shuffle nurseryTrainingData
  return
-    LamdaExecutionEnv
+    ExecutionEnviroment
-      { -- For now these need to define all available functions and types. Generic functions can be used.
+      { fun = operators,
        imports = ["LambdaDatasets.NurseryDefinition"],
        training = True,
-        trainingData =
+        trainingData = nurseryTrainingData,
-          ( map fst (takeFraktion trainingFraction itD),
+        testData = nurseryTrainingData
            map snd (takeFraktion trainingFraction itD)
          ),
        testData =
          ( map fst (dropFraktion trainingFraction itD),
            map snd (dropFraktion trainingFraction itD)
          ),
        exTargetType = (Ref.SomeTypeRep (Ref.TypeRep @(Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass))),
        results = Map.empty
      }
 data LamdaExecutionEnv = LamdaExecutionEnv
  { -- For now these need to define all available functions and types. Generic functions can be used.
    imports :: [Text],
    training :: Bool,
    trainingData :: ([(Parents, HasNurs, Form, Children, Housing, Finance, Social, Health)], [NurseryClass]),
    testData :: ([(Parents, HasNurs, Form, Children, Housing, Finance, Social, Health)], [NurseryClass]),
    exTargetType :: TypeRep,
    -- todo: kindaHacky
    results :: Map TypeRequester FittnesRes
  }
 data FittnesRes = FittnesRes
  { total :: R,
    fitnessTotal :: R,
    fitnessGeoMean :: R,
    fitnessMean :: R,
    accuracy :: R,
    biasSize :: R,
    totalSize :: N
  }
  deriving (Show)
 instance Fitness FittnesRes where
  getR = total
 instance Evaluator TypeRequester LamdaExecutionEnv FittnesRes where
  fitness' env tr = (results env) Map.! tr
  calc env pop = do
    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 relevantResults (fromRight (error ("To insert is " <> show toInsert)) toInsert)
    return env {results = res}
 dset :: LamdaExecutionEnv -> ([(Parents, HasNurs, Form, Children, Housing, Finance, Social, Health)], [NurseryClass])
 dset lEE = if training lEE then trainingData lEE else testData lEE
 evalResults :: LamdaExecutionEnv -> [TypeRequester] -> Hint.InterpreterT IO [(TypeRequester, FittnesRes)]
 evalResults ex trs = do
  Hint.setImports $ (map T.unpack (imports ex)) ++ ["Protolude"]
  Hint.unsafeSetGhcOption "-O2"
  let arrayOfFunctionText = map toLambdaExpressionS trs
  let textOfFunctionArray = "[" <> T.intercalate "," arrayOfFunctionText <> "]"
  result <- Hint.interpret (T.unpack (textOfFunctionArray)) (Hint.as :: [Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass])
  return $ zipWith (evalResult ex) trs result
 evalResult :: LamdaExecutionEnv -> TypeRequester -> (Parents -> HasNurs -> Form -> Children -> Housing -> Finance -> Social -> Health -> NurseryClass) -> (TypeRequester, FittnesRes)
 evalResult ex tr result = ( tr,
      FittnesRes
        { total = acc * 100 + (biasSmall - 1),
          fitnessTotal = fitness',
          fitnessMean = meanOfAccuricyPerClass resAndTarget,
          fitnessGeoMean = geomeanOfDistributionAccuracy resAndTarget,
          accuracy = acc,
          biasSize = biasSmall,
          totalSize = countTrsR tr
        }
    )
    where
    res = map (\(a, b, c, d, e, f, g, h) -> result a b c d e f g h) (fst (dset ex))
    resAndTarget = (zip (snd (dset ex)) res)
    acc = (foldr (\ts s -> if ((fst ts) == (snd ts)) then s + 1 else s) 0 resAndTarget) / fromIntegral (length resAndTarget)
    biasSmall = exp ((-(fromIntegral (countTrsR tr))) / 1000) -- 0 (schlecht) bis 1 (gut)
    fitness' = meanOfAccuricyPerClass resAndTarget
    score = fitness' + (biasSmall - 1)
--- a/lambda/src/Main.hs
+++ b/lambda/src/Main.hs
@ -5,12 +5,11 @@
 import Options.Applicative
 import Pipes
 import Pretty
 import Protolude hiding (for)
 import System.IO
 -- import LambdaDatasets.IrisDataset
-- import LambdaDatasets.NurseryDataset
+import LambdaDatasets.NurseryDataset
-import LambdaDatasets.GermanDataset
+-- import LambdaDatasets.GermanDataset
 import Debug.Trace as DB
 import qualified Data.Map.Strict as Map
@ -27,7 +26,7 @@ options =
      ( long "iterations"
          <> short 'i'
          <> metavar "N"
-          <> value 1500
+          <> value 1
          <> help "Number of iterations"
      )
    <*> option
@ -59,7 +58,7 @@ main =
      selectionType = Tournament 3,
      termination = (steps (iterations opts)),
      poulationSize = (populationSize opts),
-      stepSize = 90,
+      nParents = 120,
      elitismRatio = 5/100
    }
    pop' <- runEffect (for (run cfg) logCsv)
@ -71,6 +70,6 @@ main =
  where
    format l s = do
      let f = fitness' l s
-      putErrText $ show f <> "\n" <> pretty s
+      putErrText $ show f <> "\n" <> output (lE) s
    logCsv = putText . csv
    csv (t, f) = show t <> " " <> show f
--- a/lib/GA.hs
+++ b/lib/GA.hs
@ -24,7 +24,7 @@
 -- In order to use it for a certain problem, basically, you have to make your
 -- solution type an instance of 'Individual' and then simply call the 'run'
 -- function.
-module GA (Environment (..), Fitness (..), Evaluator (..), Individual (..), GA.run, Tournament (..), N, R, Population, steps, bests, runTests, GaRunConfig (..)) where
+module GA (Environment (..), Fitness (..), Evaluator (..), Individual, GA.run, Tournament (..), N, R, Population, steps, bests, runTests, GaRunConfig (..)) where
 import Control.Arrow hiding (first, second)
 import Data.List.NonEmpty ((<|))
@ -51,7 +51,9 @@ type R = Double
 -- |
 --  An Environment that Individuals of type i can be created from
 --  It stores all information required to create and change Individuals correctly
-class (Pretty e, Individual i) => Environment i e | e -> i, i -> e where
+class (Individual i) => Environment i e | e -> i, i -> e where
  output :: e -> i -> Text
  -- |
  --  Generates a completely random individual.
  new :: e -> RVar i
@ -88,7 +90,7 @@ class (Pretty e, Individual i) => Environment i e | e -> i, i -> e where
 -- |
 --  An Evaluator that Individuals of type i can be evaluated by
 --  It stores all information required to evaluate an individuals fitness
-class (Individual i, Fitness r) => Evaluator i e r | e -> i r, i -> e where
+class (Individual i, Fitness r) => Evaluator i e r | e -> i r where
  -- |
  --  An individual's fitness. Higher values are considered “better”.
  --
@ -107,10 +109,9 @@ class (Individual i, Fitness r) => Evaluator i e r | e -> i r, i -> e where
  -- It is guaranteed that the e passed to fitness is the result of a calc function, where the individual was part of the Population passed.
  -- It may be smart to reuse known results between invocations.
  calc :: e -> Population i -> IO e
-  calc eval _ = do
+  calc eval _ = return eval
    return eval
-class (Pretty i, Ord i) => Individual i
+class (Ord i) => Individual i
 class (Show i) => Fitness i where
  getR :: i -> R
@ -324,18 +325,18 @@ shuffle' :: NonEmpty a -> RVar (NonEmpty a)
 shuffle' xs@(_ :| []) = return xs
 shuffle' xs = fmap (NE.fromList) (shuffle (toList xs))
 instance Pretty Integer where
  pretty i = "Found int: " <> show i
 instance Individual Integer
-newtype IntTestEnviroment = IntTestEnviroment ((Integer, Integer), Integer, N) deriving (Eq) -- IntTestEnviroment ((0,100000),10)
+newtype IntTestEnviroment = IntTestEnviroment ((Integer, Integer), Integer, N) deriving (Eq, Show) -- IntTestEnviroment ((0,100000),10)
 instance Pretty IntTestEnviroment where
  -- instance Pretty (Maybe Student) where
  pretty (IntTestEnviroment ((i, j), k, _)) = "IntTestEnviroment of Individuals between " <> (show i) <> " and " <> (show j) <> " variance when mutating is " <> (show k)
 instance Environment Integer IntTestEnviroment where
  output _ i = "Found int: " <> show i
  new (IntTestEnviroment ((from, to), _, _)) = uniform from to
  nX (IntTestEnviroment ((_, _), _, n)) = n
--- a/lib/LambdaCalculusV2.hs
+++ b/lib/LambdaCalculusV2.hs
@ -0,0 +1,578 @@
 {-# LANGUAGE DataKinds #-}
 {-# LANGUAGE DeriveTraversable #-}
 {-# LANGUAGE FlexibleContexts #-}
 {-# LANGUAGE FunctionalDependencies #-}
 {-# LANGUAGE GADTs #-}
 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
 {-# LANGUAGE KindSignatures #-}
 {-# LANGUAGE MultiParamTypeClasses #-}
 {-# LANGUAGE NamedFieldPuns #-}
 {-# LANGUAGE OverloadedStrings #-}
 {-# LANGUAGE PolyKinds #-}
 {-# LANGUAGE RankNTypes #-}
 {-# LANGUAGE ScopedTypeVariables #-}
 {-# LANGUAGE StandaloneDeriving #-}
 {-# LANGUAGE TemplateHaskell #-}
 {-# LANGUAGE TupleSections #-}
 {-# LANGUAGE TypeAbstractions #-}
 {-# LANGUAGE TypeApplications #-}
 {-# LANGUAGE TypeFamilies #-}
 {-# LANGUAGE NoImplicitPrelude #-}
 {-# LANGUAGE OverloadedLists #-}
 {-# LANGUAGE FlexibleInstances #-}
 module LambdaCalculusV2 where
 import Data.Dynamic
 import Data.Kind
 import qualified Data.Set as Set
 import qualified Data.List.NonEmpty as NE
 import qualified Data.Map.Strict as Map
 import Data.Random
 import Data.Typeable
 import Debug.Trace as DB
 import qualified Data.Text as T
 import GA
 import Protolude
 import Protolude.Error
 import Protolude.Partial
 import qualified Type.Reflection as Ref
 import Utils
 data BoundSymbol where
  BoundSymbol :: (Typeable a) => Ref.TypeRep a -> a -> Maybe Text -> BoundSymbol
 type Bindings = Map.Map (Ref.SomeTypeRep) Int
 data SomeSimplyTypedLambdaExpression where
  SomeSimplyTypedLambdaExpression :: (Typeable a) => SimplyTypedLambdaExpression a -> SomeSimplyTypedLambdaExpression
 -- We specify a and use GADTs to allow Haskell to guarantee full type safety over these expressions!
 -- This gurantees us that a SimplyTypedLambdaExpression a describes a lambda expression of type a!
 data SimplyTypedLambdaExpression t where
  Application :: (Typeable a, Typeable b) => SimplyTypedLambdaExpression (a -> b) -> SimplyTypedLambdaExpression a -> SimplyTypedLambdaExpression b -- e = e1 e2
  Abstraction :: (Typeable (a -> b), Typeable b) => Ref.TypeRep a -> SimplyTypedLambdaExpression (b) -> SimplyTypedLambdaExpression (a -> b) -- e = λx:a. e
  VariableReference :: (Typeable a) => Ref.TypeRep a -> Int -> SimplyTypedLambdaExpression a -- e = x this Includes predefined function use!
  Constant :: (Typeable a, Ord a, Hashable a, Show a) => a -> SimplyTypedLambdaExpression a -- e = c
 instance Eq (SimplyTypedLambdaExpression t) where
  e1 == e2 = compare e1 e2 == EQ
 instance Ord (SimplyTypedLambdaExpression t) where
  compare (Application (stleAtoB1 :: SimplyTypedLambdaExpression (a1 -> t)) (stleA1 :: SimplyTypedLambdaExpression a1)) (Application (stleAtoB2 :: SimplyTypedLambdaExpression (a2 -> t)) (stleA2 :: SimplyTypedLambdaExpression a2)) = case eqT @a1 @a2 of
    Just Refl -> (compare stleAtoB1 stleAtoB2) `thenCmp` (compare stleA1 stleA2)
    _ -> compare (Ref.SomeTypeRep (Ref.TypeRep @a1)) (Ref.SomeTypeRep (Ref.TypeRep @a2))
  compare (Abstraction rep1 stle1) (Abstraction rep2 stle2) = (compare rep1 rep2) `thenCmp` (compare stle1 stle2)
  compare (VariableReference repA inx1) (VariableReference repB inx2) = (compare repA repB) `thenCmp` (compare inx1 inx2)
  compare (Constant res1) (Constant res2) = compare res1 res2
  compare (Application _ _) _ = LT
  compare _ (Application _ _) = GT
  compare (Abstraction _ _) _ = LT
  compare _ (Abstraction _ _) = GT
  compare (VariableReference _ _) _ = LT
  compare _ (VariableReference _ _) = GT
 instance Hashable (SimplyTypedLambdaExpression t) where
  hashWithSalt salt (Application stleAtoB stleA) = salt `hashWithSalt` (1 :: Int) `hashWithSalt` stleAtoB `hashWithSalt` stleA
  hashWithSalt salt (Abstraction rep stle) = salt `hashWithSalt` (2 :: Int) `hashWithSalt` rep `hashWithSalt` stle
  hashWithSalt salt (VariableReference rep inx) = salt `hashWithSalt` (3 :: Int) `hashWithSalt` rep `hashWithSalt` inx
  hashWithSalt salt (Constant res) = salt `hashWithSalt` (4 :: Int) `hashWithSalt` res
 thenCmp :: Ordering -> Ordering -> Ordering
 thenCmp EQ o2 = o2
 thenCmp o1 _ = o1
 data ConstVal where
  ConstVal :: (Typeable a, Ord a, Hashable a, Show a) => Ref.TypeRep a -> RVar a -> ConstVal
 data ExpressionWeights = ExpressionWeights
  { application :: Int,
    abstraction :: Int,
    variableReference :: Int,
    constant :: Int,
    -- chance in percent an Application will (try to) work towards something from the boundVars becoming usable. I recommend values over 90.
    functionBias :: Int
  }
 data LambdaEnviroment a = LambdaEnviroment
  { functions :: [BoundSymbol],
    constants :: [ConstVal],
    maxDepth :: Int,
    weights :: ExpressionWeights,
    --  likelyhood of an sub-expression to be mutated
    mutationStrength :: Float,
    --  likelyhood of an crossover attempt at a sub-expression
    crossoverStrength :: Float
  }
 data FittnesRes = FittnesRes
  { total :: R,
    fitnessTotal :: R,
    fitnessGeoMean :: R,
    fitnessMean :: R,
    accuracy :: R,
    biasSize :: R,
    totalSize :: N
  }
  deriving (Show)
 instance Fitness FittnesRes where
  getR = total
 data Dataset t where
  Input :: (Typeable a, Typeable b) => [a] -> Dataset b -> Dataset (a -> b)
  Result :: (Typeable a, Eq a, Enum a, Bounded a) => [a] -> Dataset a
 data ExecutionEnviroment e = ExecutionEnviroment {
    fun :: [BoundSymbol],
    training :: Bool,
    trainingData :: Dataset e,
    testData :: Dataset e
  }
 data ResultList where
  Res :: (Typeable a, Eq a, Enum a, Bounded a) => [(a,a)] -> ResultList
 instance Typeable a => Evaluator (SimplyTypedLambdaExpression a) (ExecutionEnviroment a) FittnesRes where
  fitness' ee@(ExecutionEnviroment {fun}) e = evalResult ee e (eval fun e)
 evalResult :: ExecutionEnviroment a -> SimplyTypedLambdaExpression a -> a -> FittnesRes
 evalResult (ExecutionEnviroment {training, trainingData, testData}) tr result = FittnesRes
        { total = (\(Res r) -> meanOfDistributionAccuracy r) res,
          fitnessTotal = fitness',
          fitnessMean = (\(Res r) -> meanOfAccuricyPerClass r) res ,
          fitnessGeoMean = (\(Res r) -> meanOfDistributionAccuracy r) res,
          accuracy = acc,
          biasSize = biasSmall,
          totalSize = expSize tr
        }
    where
    dataS = (if training then trainingData else testData)
    res = apply result dataS
    acc = (\(Res r) -> (foldr (\(ts) s -> if ((fst ts) == (snd ts)) then s + 1 else s) 0 r) / fromIntegral (length r)) res
    biasSmall = exp ((-(fromIntegral (expSize tr))) / 1000) -- 0 (schlecht) bis 1 (gut)
    fitness' = (\(Res r) -> meanOfAccuricyPerClass r) res
    score = fitness' + (biasSmall - 1)
 apply :: a -> Dataset a -> ResultList
 apply fun (Input b c) = applyL (map fun b) c
 apply val (Result b) = Res (zip b (repeat val))
 applyL :: [a] -> Dataset a -> ResultList
 applyL fun (Input b c) = applyL (zipWith (\a b -> a b) fun b) c
 applyL val (Result b) = Res (zip b val)
 hasSymbolOfType :: forall (a :: Type). [BoundSymbol] -> Ref.TypeRep a -> Bool
 hasSymbolOfType bound tr = length ((getSymbolsOfType bound tr) :: [a]) /= 0
 getSymbolsOfType :: forall a. [BoundSymbol] -> Ref.TypeRep a -> [a]
 getSymbolsOfType bound tr = mapMaybe (getIfType tr) bound
 getBoundSymbolsOfType :: forall a. [BoundSymbol] -> Ref.TypeRep a -> [BoundSymbol]
 getBoundSymbolsOfType bound tr = mapMaybe (getSymbolIfType tr) bound
 getSymbolIfType :: forall a. Ref.TypeRep a -> BoundSymbol -> Maybe BoundSymbol
 getSymbolIfType rep b@(BoundSymbol t _ _)
  | Just Ref.HRefl <- t `Ref.eqTypeRep` rep = Just b
  | otherwise = Nothing
 getIfType :: forall a. Ref.TypeRep a -> BoundSymbol -> Maybe a
 getIfType rep (BoundSymbol t val _)
  | Just Ref.HRefl <- t `Ref.eqTypeRep` rep = Just val
  | otherwise = Nothing
 startingBindings :: [BoundSymbol] -> Bindings
 startingBindings functions = (foldr (\(BoundSymbol tr _ _) map -> Map.insertWith (+) (Ref.SomeTypeRep tr) 1 map) Map.empty functions)
 showSanifid :: (Show a) => a -> Text
 showSanifid var = T.replace " -> " "To" (show var)
 toDotE :: LambdaEnviroment a -> Text
 toDotE (LambdaEnviroment {functions}) = foldr (<>) "" (map (\(BoundSymbol tr _ t, inx) -> "\"" <> (showSanifid tr) <> show inx <> "\" [style = invis label = " <> fromJust t <>"\"]\n") (concatMap (\(Ref.SomeTypeRep k,v) -> zip (getBoundSymbolsOfType functions k)[0 .. (v-1)]) (Map.toList (startingBindings functions))))
 toDotI :: SimplyTypedLambdaExpression e -> Int -> Text
 toDotI (Application e1 e2) inx = "\"app" <> show inx <> "\" -- "  <> toDotI e1 (inx + 1) <> "\n" <> "\"app" <> show inx <> "\" -- "  <> toDotI e2 (inx + 1 + expSize e1)
 toDotI (Abstraction _ e) inx = "\"abs" <> show inx <> "\" -- "  <> toDotI e (inx + 1)
 toDotI (VariableReference tr i) _ = "\"" <> (showSanifid tr) <> show i <> "\""
 toDotI (Constant c) _ = "\"" <> show c <> "\""
 instance Eq SomeSimplyTypedLambdaExpression where
  e1 == e2 = compare e1 e2 == EQ
 instance Ord SomeSimplyTypedLambdaExpression where
  compare (SomeSimplyTypedLambdaExpression (e1 :: SimplyTypedLambdaExpression a)) (SomeSimplyTypedLambdaExpression (e2 :: SimplyTypedLambdaExpression b))
    | Just Refl <- eqT @a @b = compare e1 e2
    | otherwise = compare (Ref.SomeTypeRep (Ref.TypeRep @a)) (Ref.SomeTypeRep (Ref.TypeRep @b))
 instance Typeable a => Individual (SimplyTypedLambdaExpression a)
 instance Typeable a => Environment (SimplyTypedLambdaExpression a) (LambdaEnviroment a) where
  output env  i = toDotE env <> toDotI i 0
  nX _ = 3
  new env = DB.trace "new !" ((generateFromEnv env) :: RVar (SimplyTypedLambdaExpression a))
  mutate env le = (mutateUnwrapped env le)
  crossover1 env le  le2 = crossoverUnwrapper env le le2
 crossoverUnwrapper :: (Typeable a) => LambdaEnviroment a -> SimplyTypedLambdaExpression a -> SimplyTypedLambdaExpression a -> RVar (Maybe (SimplyTypedLambdaExpression a, SimplyTypedLambdaExpression a))
 crossoverUnwrapper env@(LambdaEnviroment {maxDepth, functions}) le1 le2 =
      ( do
          (tree1, tree2) <- crossedover le1 le2 env maxDepth (startingBindings functions)
          return $ if (tree2 == le2) then Nothing else Just (tree1, tree2)
      )
 crossedover :: forall a e. (Typeable a,Typeable e) => SimplyTypedLambdaExpression a -> SimplyTypedLambdaExpression e -> LambdaEnviroment e -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression a, SimplyTypedLambdaExpression e)
 crossedover le1 le2 env@(LambdaEnviroment {crossoverStrength, maxDepth, functions}) sizeLeft bound = do
  roll <- uniform 0 1
  let crossoverChild =
        ( case le1 of
            (Application e1 e2) ->
              ( do
                  (elm1, partner1) <- crossedover e1 le2 env ((sizeLeft - 1) - expSize e2) bound
                  (elm2, partner2) <- crossedover e2 le2 env ((sizeLeft - 1) - expSize e1) bound
                  leftMutated <- uniform False True
                  let mutateLeft = if partner1 == le2 then False else (if partner2 == le2 then False else leftMutated)
                  return $ if mutateLeft then (Application elm1 e2, partner1) else (Application e1 elm2, partner2)
              )
            (Abstraction tr e) ->
              ( do
                  (elm2, partner2) <- crossedover e le2 env (sizeLeft - 1) (Map.insertWith (+) (Ref.SomeTypeRep tr) 1 bound)
                  return $ (Abstraction tr elm2, partner2)
              )
            _ -> return (le1, le2)
        )
  if (roll < crossoverStrength)
    then
      ( do
          maybeSwapped <- trySwapSubtree le1 sizeLeft bound le2 maxDepth (startingBindings functions)
          case maybeSwapped of
            Just (ler1, ler2) -> return (ler1, ler2)
            _ -> crossoverChild
      )
    else crossoverChild
 trySwapSubtree :: forall a e.(Typeable a,Typeable e) =>  SimplyTypedLambdaExpression a -> Int -> Bindings -> SimplyTypedLambdaExpression e -> Int -> Bindings -> RVar (Maybe (SimplyTypedLambdaExpression a, SimplyTypedLambdaExpression e))
 trySwapSubtree le1 sizeLeft bound le2 sizeLeft2 bound2 = do
    let possible = possibleSwapSubtrees le1 sizeLeft bound le2 sizeLeft2 bound2
    case possible of
         [] -> return Nothing
         ne -> Just <$> randomElement ne
 possibleSwapSubtrees :: forall a e.(Typeable a,Typeable e) => SimplyTypedLambdaExpression a -> Int -> Bindings -> SimplyTypedLambdaExpression e -> Int -> Bindings -> [(SimplyTypedLambdaExpression a, SimplyTypedLambdaExpression e)]
 possibleSwapSubtrees le1 sizeLeft bound le2 sizeLeft2 bound2
  | Just Refl <- eqT @a @e =  if compatibleSubtree sizeLeft2 bound2 le1 && compatibleSubtree sizeLeft bound le2 then (adaptSubtree bound2 le1, adaptSubtree bound le2) : continue else continue
  | otherwise = continue
  where
    continue = (case le2 of
          Application e1 e2 -> (map (\(li1,li2) -> (li1, (Application e1 li2))) (possibleSwapSubtrees le1 sizeLeft bound e2 (sizeLeft2 - 1 - expSize e1) bound2) ) ++ (map (\(li1,li2) -> (li1, (Application li2 e2))) (possibleSwapSubtrees le1 sizeLeft bound e1 (sizeLeft2 - 1 - expSize e2) bound2) )
          Abstraction t e -> (map (\(li1,li2) -> (li1, (Abstraction t li2))) (possibleSwapSubtrees le1 sizeLeft bound e (sizeLeft2 - 1) (addToBindings t bound2)))
          _ -> [])
 addToBindings ::Ref.TypeRep a -> Bindings -> Bindings
 addToBindings t bound =  (Map.insertWith (+) (Ref.SomeTypeRep t) 1 bound)
 adaptSubtree :: Bindings -> SimplyTypedLambdaExpression e -> SimplyTypedLambdaExpression e
 adaptSubtree bound (Application e1 e2) = (Application (adaptSubtree bound e1) (adaptSubtree bound e2))
 adaptSubtree bound (Abstraction t e) = (Abstraction t (adaptSubtree (addToBindings t bound) e))
 adaptSubtree bound (VariableReference tr idx) =  (VariableReference tr (mod idx ( bound Map.! (Ref.SomeTypeRep tr))))
 adaptSubtree _ e = e
 compatibleSubtree :: Int -> Bindings -> SimplyTypedLambdaExpression e -> Bool
 compatibleSubtree sizeLeft bound subtree =  bound `bindingContains` (bindingReq subtree) && sizeLeft > (expSize subtree)
 expSize :: SimplyTypedLambdaExpression e -> Int
 expSize (Application e1 e2) = expSize e1 + expSize e2 + 1
 expSize (Abstraction _ e) = expSize e + 1
 expSize _ = 1
 bindingReq :: SimplyTypedLambdaExpression e -> Bindings
 bindingReq (Application e1 e2) = Map.unionWith (max) (bindingReq e1) (bindingReq e2)
 bindingReq (Abstraction tr e) = rmFromBindings tr (bindingReq e)
 bindingReq (VariableReference tr idx) = Map.singleton (Ref.SomeTypeRep tr) 1
 bindingReq (Constant _) = Map.empty
 rmFromBindings ::Ref.TypeRep a -> Bindings -> Bindings
 rmFromBindings t bound =  (Map.insertWith (\i1 i2 -> max 0 (i1 + i2)) (Ref.SomeTypeRep t) (- 1) bound)
 bindingContains :: Bindings -> Bindings -> Bool
 bindingContains superset subset = all (\(key,val) -> (fromMaybe 0 (Map.lookup key superset)) >= val ) (Map.toList subset)
 mutateUnwrapped :: (Typeable r) => LambdaEnviroment r -> SimplyTypedLambdaExpression r -> RVar (SimplyTypedLambdaExpression r)
 mutateUnwrapped env@(LambdaEnviroment {maxDepth, functions}) stle = mutated stle env maxDepth (startingBindings functions)
 mutated :: forall r a. (Typeable r) => SimplyTypedLambdaExpression r -> LambdaEnviroment a -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 mutated (Application e1 e2) env@(LambdaEnviroment {constants, mutationStrength}) sizeLeft bound = do
  roll <- uniform 0 1
  if (roll < mutationStrength)
    then generate env (Ref.TypeRep @r) constants sizeLeft bound
    else do
      sizeDistribution <- uniform 0 (sizeLeft - 1)
      elm1 <- mutated e1 env sizeDistribution bound
      elm2 <- mutated e2 env ((sizeLeft - 1) - sizeDistribution) bound
      return $ Application elm1 elm2
 mutated (Abstraction tr e) env@(LambdaEnviroment {constants, mutationStrength}) sizeLeft bound = do
  roll <- uniform 0 1
  if (roll < mutationStrength)
    then generate env (Ref.TypeRep @r) constants sizeLeft bound
    else do
      elm2 <- mutated e env (sizeLeft - 1) (Map.insertWith (+) (Ref.SomeTypeRep tr) 1 bound)
      return $ Abstraction tr elm2
 mutated stle env@(LambdaEnviroment {constants, mutationStrength}) sizeLeft bound = do
  roll <- uniform 0 1
  if (roll < mutationStrength) then generate env (Ref.TypeRep @r) constants sizeLeft bound else return stle
 test :: SimplyTypedLambdaExpression (Bool -> Int -> Int -> Int)
 test = Abstraction (Ref.typeRep @(Bool)) (Abstraction (Ref.typeRep @(Int)) (Abstraction (Ref.typeRep @(Int)) (Constant 5)))
 generateFromEnv :: forall r. (Typeable r) => LambdaEnviroment r -> RVar (SimplyTypedLambdaExpression r)
 generateFromEnv env@(LambdaEnviroment {functions, constants, maxDepth}) = generate env (Ref.TypeRep @r) constants maxDepth (foldr (\(BoundSymbol tr _ _) map -> Map.insertWith (+) (Ref.SomeTypeRep tr) 1 map) Map.empty functions)
 generate :: LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 generate env tr@(Ref.Fun (Ref.TypeRep @a) (Ref.TypeRep @b)) constantTypes sizeLeft bound
  | (sizeLeft > 0) && (Map.member (Ref.SomeTypeRep tr) bound) =  do
      let weight = weights env
      let options = [(application weight, genApplication env tr constantTypes sizeLeft bound), (abstraction weight, genAbstraction env tr constantTypes sizeLeft bound), (variableReference weight, genVariableReference env tr constantTypes sizeLeft bound)]
      expres <- selectWeighted options
      res <- expres
      return res
  | (sizeLeft > 0) =   do
      let weight = weights env
      let options = [(application weight + round (1000 * closestFractionMatch tr bndK), genApplication env tr constantTypes sizeLeft bound), (abstraction weight, genAbstraction env tr constantTypes sizeLeft bound)]
      expres <- selectWeighted options
      res <- expres
      return res
  -- Application can crate a fitting type in a smaller expression. e.g. if':: Bool -> (Int-> Int -> Bool) -> (Int-> Int -> Bool) -> (Int-> Int -> Bool) and target type (Int-> Int -> Bool) -> (Int-> Int -> Bool) -> (Int-> Int -> Bool) can be finished in one Application (if' True::(Int-> Int -> Bool) -> (Int-> Int -> Bool) -> (Int-> Int -> Bool)) and one Var or constant, but resoving it purely with Abstractions would require 5 abstractions and one constant or var
 --  | (any (< typeDepth tr) (mapMaybe (sizeMising tr) bndK)) =   do
 --      let weight = weights env
 --      let options = [(application weight + (typeDepth tr - (minimum (mapMaybe (sizeMising tr) bndK))), genApplication env tr constantTypes sizeLeft bound), (abstraction weight, genAbstraction env tr constantTypes sizeLeft bound)]
 --      expres <- selectWeighted options
 --      res <- expres
 --      return res
  | (Map.member (Ref.SomeTypeRep tr) bound) =   do
      let weight = weights env
      let options = [(abstraction weight, genAbstraction env tr constantTypes sizeLeft bound), (variableReference weight, genVariableReference env tr constantTypes sizeLeft bound)]
      expres <- selectWeighted options
      res <- expres
      return res
  | otherwise =   do
      res <- genAbstraction env tr constantTypes sizeLeft bound
      return res
  where
    bndK = Map.keys bound
 generate env tr constantTypes sizeLeft bound
  | (sizeLeft > 0) && (Map.member (Ref.SomeTypeRep tr) bound) =    do
      let weight = weights env
      let options = [(application weight, genApplication env tr constantTypes sizeLeft bound), (constant weight, genConstant tr constantTypes sizeLeft bound), (variableReference weight, genVariableReference env tr constantTypes sizeLeft bound)]
      expres <- selectWeighted options
      res <- expres
      return res
  | (sizeLeft > 0) =    do
      let weight = weights env
      let options = [(application weight + round (1000 * closestFractionMatch tr bndK), genApplication env tr constantTypes sizeLeft bound), (constant weight, genConstant tr constantTypes sizeLeft bound)]
      expres <- selectWeighted options
      res <- expres
      return res
  | (Map.member (Ref.SomeTypeRep tr) bound) =  do
      let weight = weights env
      let options = [(constant weight, genConstant tr constantTypes sizeLeft bound), (variableReference weight, genVariableReference env tr constantTypes sizeLeft bound)]
      expres <- selectWeighted options
      res <- expres
      return res
  | otherwise =   do
      res <- genConstant tr constantTypes sizeLeft bound
      return res
  where
    bndK = Map.keys bound
 genVariableReference :: LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genVariableReference _ tr@(Ref.TypeRep) _ _ bound = do
  typeIndex <- uniform 0 (((Map.!) bound (Ref.SomeTypeRep tr)) - 1)
  return $ (VariableReference tr typeIndex)
 genConstant :: Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genConstant (Ref.TypeRep @a) constantTypes _ _ = do
  val <- (constantGen constantTypes) :: RVar (SimplyTypedLambdaExpression a)
  return $ val
 constantGen :: forall a. (Typeable a) => [ConstVal] -> RVar (SimplyTypedLambdaExpression a)
 constantGen ((ConstVal tr rVal) : rest)
  | Just Ref.HRefl <- Ref.typeRep @a `Ref.eqTypeRep` tr = Constant <$> rVal
  | otherwise = constantGen rest
 constantGen [] = error $ "unknown constant " <> show (Ref.typeRep @a)
 genAbstraction :: forall r a. LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genAbstraction env tr@(Ref.Fun trA@(Ref.TypeRep) trB@(Ref.TypeRep)) constantTypes sizeLeft bound
  | Just Ref.HRefl <- Ref.typeRep @Type `Ref.eqTypeRep` Ref.typeRepKind trA,
    Just Ref.HRefl <- Ref.typeRep @Type `Ref.eqTypeRep` Ref.typeRepKind trB = do
      child <- generate env trB constantTypes (sizeLeft - 1) (Map.insertWith (+) (Ref.SomeTypeRep trA) 1 bound)
      return $ Abstraction trA child
 genAbstraction _ tr _ _ _ = error $ "cannot generate Abstraction for " <> show tr
 -- generate: e:a = e1:b->a e2:b
 -- the by far most complex functions in this module! why?
 -- 1. we need to sensibly limit how insane we make b, favorably without excluding anything completely!
 -- 2. we need this function to heavily lean towards generating an b->a available in Bindings, so we are likely to use any predefined functions... at all
 genApplication :: forall r c a. LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genApplication env@(LambdaEnviroment {weights}) tr constantTypes sizeLeft bound
  | (sizeLeft <= 0) = genApplicationClosestToCompletion env tr constantTypes bound
  | otherwise = do
      i <- uniform 0 100
      ( if i < (functionBias weights) && any (1 >) (mapMaybe (matchedFractionS tr) (Map.keys bound))
          then (genApplicationTowardsBound (maximum (filter (1 >) (mapMaybe (matchedFractionS tr) (Map.keys bound)))) env tr constantTypes sizeLeft bound)
          else (genRandomApplication env tr constantTypes sizeLeft bound)
        )
 closestFractionMatch :: Ref.TypeRep r -> [Ref.SomeTypeRep] -> Float
 closestFractionMatch tr trs | any (1 >) (mapMaybe (matchedFractionS tr) (trs)) = (maximum (filter (1 >) (mapMaybe (matchedFractionS tr) (trs))))
                            | otherwise = 0
 genRandomApplication :: forall a r c. LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genRandomApplication env tr constantTypes sizeLeft bound = do
  t1 <- randomType constantTypes
  genApplicationWithTypeOfS t1 env tr constantTypes sizeLeft bound
 randomType :: [ConstVal] -> RVar Ref.SomeTypeRep
 randomType constantTypes = do
  functon :: Int <- (uniform 0 100)
  ret <-
    if functon < 25
      then
        ( do
            tr1 <- randomType constantTypes
            tr2 <- randomType constantTypes
            return (mkFunTy tr1 tr2)
        )
      else
        ( do
            (ConstVal _ (_ :: RVar t1)) <- randomElement constantTypes
            return $ Ref.SomeTypeRep (Ref.TypeRep @t1)
        )
  return ret
 genApplicationClosestToCompletion :: forall r a. LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genApplicationClosestToCompletion env tr constantTypes bound = do
  (ref) <- nextTypeFromClosestBound tr bound
  genApplicationWithTypeOfS ref env tr constantTypes 0 bound
 nextTypeFromClosestBound :: Ref.TypeRep r -> Bindings -> RVar Ref.SomeTypeRep
 nextTypeFromClosestBound trB bound = randomElement ((getMinimasByMaybe (sizeMising trB) (filter (matchingTypesS trB) (Map.keys bound))))
 genApplicationTowardsBound :: forall r c a. Float -> LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genApplicationTowardsBound matchedFrac env tr constantTypes sizeLeft bound
  | nextMatchedFrac > 0 = do
      (f :: Float) <- uniform 0 1
      bs <- randomElement (filter (\bs -> Just matchedFrac == matchedFractionS tr bs) (Map.keys bound))
      if (f < matchedFrac + 1) then (genApplicationWithTypeOfS ((nextTypeS tr bs)) env tr constantTypes sizeLeft bound) else (genApplicationTowardsBound nextMatchedFrac env tr constantTypes sizeLeft bound)
  | otherwise = do
      bs <- randomElement (filter (\bs -> Just matchedFrac == matchedFractionS tr bs) (Map.keys bound))
      genApplicationWithTypeOfS ((nextTypeS tr bs)) env tr constantTypes sizeLeft bound
  where
    nextMatchedFrac = (if (any (matchedFrac >) (mapMaybe (matchedFractionS tr) (Map.keys bound))) then (maximum (filter (matchedFrac >) (mapMaybe (matchedFractionS tr) (Map.keys bound)))) else 0) --todo nicer!
 -- how many Base types will need to be generated for bound to fit onto tr. This equals the size of the subtree that needs to be generated.
 sizeMising :: Ref.TypeRep r -> Ref.SomeTypeRep -> Maybe Int
 sizeMising tr (Ref.SomeTypeRep trbs)
  | matchingTypes tr trbs = Just $ (typeDepth tr) - (typeDepth trbs)
  | otherwise = Nothing
 matchedFractionS :: Ref.TypeRep r -> Ref.SomeTypeRep -> Maybe Float
 matchedFractionS tr (Ref.SomeTypeRep trbs) = matchedFraction tr trbs
 matchedFraction :: Ref.TypeRep r -> Ref.TypeRep a -> Maybe Float
 matchedFraction tr trbs
  | matchingTypes tr trbs = Just $ fromIntegral (typeDepth trbs) / fromIntegral (typeDepth tr)
  | otherwise = Nothing
 nextTypeS :: Ref.TypeRep r -> Ref.SomeTypeRep -> Ref.SomeTypeRep
 nextTypeS tr (Ref.SomeTypeRep trbs) = nextType tr trbs
 nextType :: Ref.TypeRep r -> Ref.TypeRep a -> Ref.SomeTypeRep
 nextType trR@(Ref.Fun (from) (to)) avail
  | Just Ref.HRefl <- (to `Ref.eqTypeRep` avail),
    Just Ref.HRefl <- Ref.typeRep @Type `Ref.eqTypeRep` Ref.typeRepKind from =
      Ref.SomeTypeRep from
  | otherwise = nextType to avail
 nextType tra trbs = error ("can't extract nextType from " <> show tra <> " and " <> show trbs)
 matchingTypesS :: Ref.TypeRep r -> Ref.SomeTypeRep -> Bool
 matchingTypesS tr (Ref.SomeTypeRep trbs) = matchingTypes tr trbs
 matchingTypes :: Ref.TypeRep a -> Ref.TypeRep b -> Bool
 matchingTypes tra trb | Ref.SomeTypeRep tra == Ref.SomeTypeRep trb = True
 matchingTypes (Ref.Fun _ (traRes :: Ref.TypeRep aRes)) trb = matchingTypes (traRes :: Ref.TypeRep aRes) trb
 matchingTypes _ _ = False
 typeSize :: Ref.TypeRep r -> Int
 typeSize (Ref.Fun _ trb) = 1 + (typeSize trb)
 typeSize _ = 1
 typeDepth :: Ref.TypeRep r -> Int
 typeDepth (Ref.Fun _ (trb :: Ref.TypeRep b)) = 1 + (typeDepth (trb :: Ref.TypeRep b))
 typeDepth _ = 1
 genApplicationWithTypeOfS :: forall r a. Ref.SomeTypeRep -> LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genApplicationWithTypeOfS (Ref.SomeTypeRep btr@(Ref.TypeRep))
  | Just Ref.HRefl <- Ref.typeRep @Type `Ref.eqTypeRep` Ref.typeRepKind btr = genApplicationWithTypeOfB btr
 genApplicationWithTypeOfS (Ref.SomeTypeRep btr) = error $ "typeRepKind not Type: " <> show (Ref.typeRepKind btr)
 genApplicationWithTypeOfB :: forall r a (b :: Type). Ref.TypeRep b -> LambdaEnviroment a -> Ref.TypeRep r -> [ConstVal] -> Int -> Bindings -> RVar (SimplyTypedLambdaExpression r)
 genApplicationWithTypeOfB trB@(Ref.TypeRep) env trR@(Ref.TypeRep) constantTypes sizeLeft bound = do
  sizeDistribution <- uniform 0 (sizeLeft - 1)
  right <- generate env trB constantTypes sizeDistribution bound
  left <- generate env (Ref.Fun (Ref.TypeRep @b) trR) constantTypes ((sizeLeft - 1) - sizeDistribution) bound
  return $ Application left right
 selectWeighted :: [(Int, a)] -> RVar a
 selectWeighted x = do
  let total = Protolude.sum (map fst x)
  selection <- uniform 1 total
  return $ selectAtWeight selection (NE.fromList x)
 selectAtWeight :: Int -> NonEmpty (Int, a) -> a
 selectAtWeight _ (x :| []) = snd x
 selectAtWeight w (x :| xs)
  | fst x >= w = snd x
  | otherwise = selectAtWeight (w - fst x) (NE.fromList xs)
 eval :: [BoundSymbol] -> SimplyTypedLambdaExpression ex -> ex
 eval bound (Abstraction rep stle) = lam bound rep stle
 eval bound (Application stleAtoB stleA) = (eval bound stleAtoB) (eval bound stleA)
 eval bound (VariableReference rep inx) = (getSymbolsOfType bound rep) !! inx
 eval _ (Constant res) = res
 lam :: [BoundSymbol] -> Ref.TypeRep a -> SimplyTypedLambdaExpression (b) -> (a -> b)
 lam bound Ref.TypeRep stle = \(aVal :: a) -> eval (appendToBoundVar bound aVal) stle
 appendToBoundVar :: (Typeable a) => [BoundSymbol] -> a -> [BoundSymbol]
 appendToBoundVar bv val = bv ++ [BoundSymbol (Ref.typeOf val) val Nothing]
 listAppend :: (Typeable a) => a -> Maybe [Dynamic] -> Maybe [Dynamic]
 listAppend val (Just dyns) = Just (dyns ++ [toDyn val])
 listAppend val (Nothing) = Just [toDyn val]
 getMinimasBy :: (Ord b) => (a -> b) -> [a] -> [a]
 getMinimasBy fun as = filter (\a -> fun a == minOverAs) as
  where
    minOverAs = minimum (map fun as)
 getMinimasByMaybe :: (Ord b) => (a -> Maybe b) -> [a] -> [a]
 getMinimasByMaybe fun as = filter (\a -> fun a == Just minOverAs) as
  where
    minOverAs = minimum (mapMaybe fun as)
 getMaximasBy :: (Ord b) => (a -> b) -> [a] -> [a]
 getMaximasBy fun as = filter (\a -> fun a == maxOverAs) as
  where
    maxOverAs = maximum (map fun as)
 getMaximasByMaybe :: (Ord b) => (a -> Maybe b) -> [a] -> [a]
 getMaximasByMaybe fun as = filter (\a -> fun a == Just maxOverAs) as
  where
    maxOverAs = maximum (mapMaybe fun as)
--- a/lib/Utils.hs
+++ b/lib/Utils.hs
@ -20,6 +20,9 @@ geomeanOfAccuricyPerClass results = geomean $ map (accuracyInClass results) [min
 geomeanOfDistributionAccuracy :: (Enum r, Bounded r, Eq r) => [(r, r)] -> R
 geomeanOfDistributionAccuracy results = geomean $ map (distributionAccuracyForClass results) [minBound .. maxBound]
 meanOfDistributionAccuracy :: (Enum r, Bounded r, Eq r) => [(r, r)] -> R
 meanOfDistributionAccuracy results = mean $ 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
--- a/src-students/Main.hs
+++ b/src-students/Main.hs
@ -4,7 +4,6 @@
 import Options.Applicative
 import Pipes
 import Pretty
 import Protolude hiding (for)
 import System.IO
 import Seminar
@ -65,6 +64,6 @@ main =
  where
    format seminarL s = do
      let f = fitness' seminarL s
-      putErrText $ show f <> "\n" <> pretty s
+      putErrText $ show f <> "\n" <> output (AssignmentEnviroment (students prios, topics prios)) s
    logCsv = putText . csv
    csv (t, f) = show t <> " " <> show f
--- a/src-students/Seminar.hs
+++ b/src-students/Seminar.hs
@ -107,6 +107,14 @@ instance Pretty AssignmentEnviroment where
  pretty (AssignmentEnviroment (persons,assignables)) = "Persons: " <> show persons <> " Assignables: " <> show assignables
 instance Environment Assignment AssignmentEnviroment where
  output _ a =
    T.unlines (gene <$> a)
    where
      gene :: (Maybe Student, Maybe Topic) -> Text
      gene (s, t) =
        pretty s <> ": " <> pretty t
  new (AssignmentEnviroment (persons,assignables)) = do
    let aPadding = replicate (length persons - length assignables) Nothing
    let paddedAssignables = (Just <$> assignables) ++ aPadding
@ -139,14 +147,6 @@ instance Environment Assignment AssignmentEnviroment where
      f x v1 v2 i = if i <= x then v1 else v2
 instance Pretty Assignment where
  pretty (a) =
    T.unlines (gene <$> a)
    where
      gene :: (Maybe Student, Maybe Topic) -> Text
      gene (s, t) =
        pretty s <> ": " <> pretty t
 -- |
 -- The priority value given by a student to a topic including the case of her not
 -- receiving a topic.
Author	SHA1	Message	Date
Johannes Merl	17b64f263b	LamdaCalculusV2	2024-05-07 14:58:00 +02:00
Johannes Merl	d5fe65ab8c	WIP: rewrite... too much...	2024-04-30 07:42:10 +02:00