Fix ghcid support.

[majurity.git] / test / QuickCheck.hs

{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
module QuickCheck where

import Test.QuickCheck
import Test.Tasty
import Test.Tasty.QuickCheck

import Control.Arrow (first)
import Control.Monad (replicateM)
import Data.Hashable (Hashable)
import qualified Data.Map.Strict as Map
import Data.Ratio
import GHC.Exts (IsList(..))
import Prelude
import System.Random (Random(..))
import qualified Data.Set as Set

import Majority.Judgment
import Types

quickchecks :: TestTree
quickchecks =
        testGroup "QuickCheck"
         [ testProperty "arbitraryMerits" $ \(SameLength (Merit x::Merit G6,Merit y::Merit G6)) ->
                Map.keys x == Map.keys y &&
                sum x == sum y
         , testGroup "MajorityValue"
                 [ testProperty "compare" $ \(SameLength (x::MajorityValue G6,y)) ->
                        expandValue x`compare` expandValue y == x`compare`y
                 ]
         {-
         , testProperty "majorityGauge and majorityValue consistency" $
                 \(SameLength (x@(Merit xs)::Merit G6,y@(Merit ys))) ->
                        not (all (==0) xs || all (==0) ys) ==>
                        case majorityGauge x`compare`majorityGauge y of
                         LT -> majorityValue x < majorityValue y
                         GT -> majorityValue x > majorityValue y
                         EQ -> True
         -}
         ]

-- | Decompress a 'MajorityValue'.
expandValue :: MajorityValue a -> [a]
expandValue (MajorityValue ms) = 
        let d = foldr lcm 1 (denominator . middleShare <$> ms) in
        go $ (\m -> (numerator (middleShare m) * d, lowGrade m, highGrade m)) <$> ms
        where
        go [] = []
        go ((s,l,h):xs) = concat (replicate (fromIntegral s) [l, h]) ++ go xs

-- | @arbitraryMerits n@ arbitrarily generates 'n' lists of 'Merit'
-- for the same arbitrary grades,
-- and with the same total 'Share' of individual judgments.
arbitraryMerits :: forall g. (Bounded g, Enum g, Ord g) => Int -> Gen [Merit g]
arbitraryMerits n = sized $ \shareSum -> do
        minG <- choose (fromEnum(minBound::g), fromEnum(maxBound::g))
        maxG <- choose (minG, fromEnum(maxBound::g))
        let gs::[g] = toEnum minG`enumFromTo`toEnum maxG
        let lenGrades = maxG - minG + 1
        replicateM n $ do
                shares  <- resize shareSum $ arbitrarySizedPositiveRationalSum lenGrades
                shares' :: [Share] <- arbitraryPad (lenGrades - length shares) (return 0) shares
                return $ Merit $ fromList $ zip gs shares'

-- | @arbitrarySizedNaturalSum maxLen@
-- arbitrarily chooses a list of 'length' at most 'maxLen',
-- containing 'Int's summing up to 'sized'.
arbitrarySizedNaturalSum :: Int -> Gen [Int]
arbitrarySizedNaturalSum maxLen = sized (go maxLen)
        where
        go :: Int -> Int -> Gen [Int]
        go len tot | len <= 0 = return []
                   | len == 1 = return [tot]
                   | tot <= 0 = return [tot]
        go len tot = do
                d <- choose (0, tot)
                (d:) <$> go (len-1) (tot - d)

-- | @arbitrarySizedPositiveRationalSum maxLen@
-- arbitrarily chooses a list of 'length' at most 'maxLen',
-- containing positive 'Rational's summing up to 'sized'.
arbitrarySizedPositiveRationalSum :: Int -> Gen [Rational]
arbitrarySizedPositiveRationalSum maxLen = sized (go maxLen . fromIntegral)
        where
        go :: Int -> Rational -> Gen [Rational]
        go len tot | len <= 0 = return []
                   | len == 1 = return [tot]
                   | tot <= 0 = return [tot]
        go len tot = do
                d <- choose (0, tot)
                (d:) <$> go (len-1) (tot - d)

instance Random Rational where
        randomR (minR, maxR) g =
                if d - b == 0
                then first (% b) $ randomR (a, c) g
                else first (bd2ac . nat2bd) $ randomR (0, toInteger (maxBound::Int)) g
                where
                a = numerator   minR
                b = denominator minR
                c = numerator   maxR
                d = denominator maxR
                nat2bd x = ((d - b) % toInteger (maxBound::Int)) * (x%1) + (b%1)
                bd2ac x = alpha * x + beta
                        where
                        alpha = (c-a) % (d-b)
                        beta = (a%1) - alpha * (b%1)
                
        random = randomR (toInteger (minBound::Int)%1, toInteger (maxBound::Int)%1)

-- | @arbitraryPad n pad xs@
-- arbitrarily grows list 'xs' with 'pad' elements
-- up to length 'n'.
arbitraryPad :: (Num i, Integral i) => i -> Gen a -> [a] -> Gen [a]
arbitraryPad n pad [] = replicateM (fromIntegral n) pad
arbitraryPad n pad xs = do
        (r, xs') <- go n xs
        if r > 0
         then arbitraryPad r pad xs'
         else return xs'
        where
        go r xs' | r <= 0 = return (0,xs')
        go r [] =  arbitrary >>= \b ->
                if b then pad >>= \p -> ((p:)<$>) <$> go (r-1) []
                     else return (r,[])
        go r (x:xs') = arbitrary >>= \b ->
                if b then pad >>= \p -> (([p,x]++)<$>) <$> go (r-1) xs'
                     else ((x:)<$>) <$> go r xs'

-- | Like 'nub', but O(n * log n).
nubList :: Ord a => [a] -> [a]
nubList = go Set.empty where
        go _ [] = []
        go s (x:xs) | x`Set.member`s = go s xs
                    | otherwise      = x:go (Set.insert x s) xs

instance Arbitrary G6 where
        arbitrary = arbitraryBoundedEnum
instance (Arbitrary g, Bounded g, Enum g, Ord g, Show g) => Arbitrary (Merit g) where
        arbitrary = head <$> arbitraryMerits 1
        shrink (Merit m) = Merit <$> shrink m
instance
 ( Arbitrary c, Bounded c, Enum c, Eq c, Hashable c, Show c
 , Arbitrary g, Bounded g, Enum g, Ord g, Show g
 ) => Arbitrary (MeritByChoice c g) where
        arbitrary = do
                minP <- choose (fromEnum(minBound::c), fromEnum(maxBound::c))
                maxP <- choose (minP, fromEnum(maxBound::c))
                let ps = toEnum minP`enumFromTo`toEnum maxP
                let ms = arbitraryMerits (maxP - minP + 1)
                fromList . zip ps <$> ms
instance (Bounded g, Eq g, Integral g, Arbitrary g) => Arbitrary (MajorityValue g) where
        arbitrary = head . (majorityValue <$>) <$> arbitraryMerits 1
        shrink (MajorityValue vs) = MajorityValue <$> shrink vs
instance (Bounded g, Enum g) => Arbitrary (Middle g) where
        arbitrary = do
                lowG  <- choose (fromEnum(minBound::g), fromEnum(maxBound::g))
                highG <- choose (lowG, fromEnum(maxBound::g))
                share <- choose (0, 1)
                return $ Middle share (toEnum lowG) (toEnum highG)

-- * Type 'SameLength'
newtype SameLength a = SameLength a
 deriving (Eq, Show)
instance Functor SameLength where
        fmap f (SameLength x) = SameLength (f x)
instance (Arbitrary g, Bounded g, Enum g, Ord g) => Arbitrary (SameLength (MajorityValue g, MajorityValue g)) where
        arbitrary = do
                SameLength (x,y) <- arbitrary
                return $ SameLength (MajorityValue x, MajorityValue y)
instance (Arbitrary g, Bounded g, Enum g, Ord g) => Arbitrary (SameLength (Merit g, Merit g)) where
        arbitrary = do
                vs <- arbitraryMerits 2
                case vs of
                 [x,y] -> return $ SameLength (x,y)
                 _ -> undefined
instance (Arbitrary g, Bounded g, Enum g, Ord g) => Arbitrary (SameLength ([Middle g], [Middle g])) where
        arbitrary = do
                SameLength (m0, m1) <- arbitrary
                return $ SameLength
                 ( unMajorityValue $ majorityValue m0
                 , unMajorityValue $ majorityValue m1 )