poly-0.4.0.0: test/Sparse.hs
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE UndecidableInstances #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
module Sparse
( testSuite
, ShortPoly(..)
) where
import Prelude hiding (gcd, quotRem, rem)
import Data.Euclidean (Euclidean(..), GcdDomain(..))
import Data.Function
import Data.Int
import Data.List (groupBy, sortOn)
import Data.Mod
import Data.Poly.Sparse
import qualified Data.Poly.Sparse.Semiring as S
import Data.Proxy
import Data.Semiring (Semiring)
import qualified Data.Vector as V
import qualified Data.Vector.Generic as G
import qualified Data.Vector.Unboxed as U
import Test.Tasty
import Test.Tasty.QuickCheck hiding (scale, numTests)
import Quaternion
import TestUtils
instance (Eq a, Semiring a, Arbitrary a, G.Vector v (Word, a)) => Arbitrary (Poly v a) where
arbitrary = S.toPoly . G.fromList <$> arbitrary
shrink = fmap (S.toPoly . G.fromList) . shrink . G.toList . unPoly
newtype ShortPoly a = ShortPoly { unShortPoly :: a }
deriving (Eq, Show, Semiring, GcdDomain, Euclidean)
instance (Eq a, Semiring a, Arbitrary a, G.Vector v (Word, a)) => Arbitrary (ShortPoly (Poly v a)) where
arbitrary = ShortPoly . S.toPoly . G.fromList . (\xs -> take (length xs `mod` 5) xs) <$> arbitrary
shrink = fmap (ShortPoly . S.toPoly . G.fromList) . shrink . G.toList . unPoly . unShortPoly
testSuite :: TestTree
testSuite = testGroup "Sparse"
[ arithmeticTests
, otherTests
, lawsTests
, evalTests
, derivTests
]
lawsTests :: TestTree
lawsTests = testGroup "Laws"
$ semiringTests ++ ringTests ++ numTests ++ euclideanTests ++ gcdDomainTests ++ isListTests ++ showTests
semiringTests :: [TestTree]
semiringTests =
[ mySemiringLaws (Proxy :: Proxy (Poly U.Vector ()))
, mySemiringLaws (Proxy :: Proxy (Poly U.Vector Int8))
, mySemiringLaws (Proxy :: Proxy (Poly V.Vector Integer))
, tenTimesLess
$ mySemiringLaws (Proxy :: Proxy (Poly U.Vector (Quaternion Int)))
]
ringTests :: [TestTree]
ringTests =
[ myRingLaws (Proxy :: Proxy (Poly U.Vector ()))
, myRingLaws (Proxy :: Proxy (Poly U.Vector Int8))
, myRingLaws (Proxy :: Proxy (Poly V.Vector Integer))
, myRingLaws (Proxy :: Proxy (Poly U.Vector (Quaternion Int)))
]
numTests :: [TestTree]
numTests =
[ myNumLaws (Proxy :: Proxy (Poly U.Vector Int8))
, myNumLaws (Proxy :: Proxy (Poly V.Vector Integer))
, tenTimesLess
$ myNumLaws (Proxy :: Proxy (Poly U.Vector (Quaternion Int)))
]
gcdDomainTests :: [TestTree]
gcdDomainTests =
[ myGcdDomainLaws (Proxy :: Proxy (ShortPoly (Poly V.Vector Integer)))
, tenTimesLess
$ myGcdDomainLaws (Proxy :: Proxy (ShortPoly (Poly V.Vector (Mod 3))))
, tenTimesLess
$ myGcdDomainLaws (Proxy :: Proxy (ShortPoly (Poly V.Vector Rational)))
]
euclideanTests :: [TestTree]
euclideanTests =
[ myEuclideanLaws (Proxy :: Proxy (ShortPoly (Poly V.Vector (Mod 3))))
, myEuclideanLaws (Proxy :: Proxy (ShortPoly (Poly V.Vector Rational)))
]
isListTests :: [TestTree]
isListTests =
[ myIsListLaws (Proxy :: Proxy (Poly U.Vector ()))
, myIsListLaws (Proxy :: Proxy (Poly U.Vector Int8))
, myIsListLaws (Proxy :: Proxy (Poly V.Vector Integer))
, tenTimesLess
$ myIsListLaws (Proxy :: Proxy (Poly U.Vector (Quaternion Int)))
]
showTests :: [TestTree]
showTests =
[ myShowLaws (Proxy :: Proxy (Poly U.Vector ()))
, myShowLaws (Proxy :: Proxy (Poly U.Vector Int8))
, myShowLaws (Proxy :: Proxy (Poly V.Vector Integer))
, tenTimesLess
$ myShowLaws (Proxy :: Proxy (Poly U.Vector (Quaternion Int)))
]
arithmeticTests :: TestTree
arithmeticTests = testGroup "Arithmetic"
[ testProperty "addition matches reference" $
\(xs :: [(Word, Int)]) ys -> toPoly (V.fromList (addRef xs ys)) ===
toPoly (V.fromList xs) + toPoly (V.fromList ys)
, testProperty "subtraction matches reference" $
\(xs :: [(Word, Int)]) ys -> toPoly (V.fromList (subRef xs ys)) ===
toPoly (V.fromList xs) - toPoly (V.fromList ys)
, tenTimesLess $
testProperty "multiplication matches reference" $
\(xs :: [(Word, Int)]) ys -> toPoly (V.fromList (mulRef xs ys)) ===
toPoly (V.fromList xs) * toPoly (V.fromList ys)
]
addRef :: Num a => [(Word, a)] -> [(Word, a)] -> [(Word, a)]
addRef [] ys = ys
addRef xs [] = xs
addRef xs@((xp, xc) : xs') ys@((yp, yc) : ys') =
case xp `compare` yp of
LT -> (xp, xc) : addRef xs' ys
EQ -> (xp, xc + yc) : addRef xs' ys'
GT -> (yp, yc) : addRef xs ys'
subRef :: Num a => [(Word, a)] -> [(Word, a)] -> [(Word, a)]
subRef [] ys = map (fmap negate) ys
subRef xs [] = xs
subRef xs@((xp, xc) : xs') ys@((yp, yc) : ys') =
case xp `compare` yp of
LT -> (xp, xc) : subRef xs' ys
EQ -> (xp, xc - yc) : subRef xs' ys'
GT -> (yp, negate yc) : subRef xs ys'
mulRef :: Num a => [(Word, a)] -> [(Word, a)] -> [(Word, a)]
mulRef xs ys
= map (\ws -> (fst (head ws), sum (map snd ws)))
$ groupBy ((==) `on` fst)
$ sortOn fst
$ [ (xp + yp, xc * yc) | (xp, xc) <- xs, (yp, yc) <- ys ]
otherTests :: TestTree
otherTests = testGroup "other" $ concat
[ otherTestGroup (Proxy :: Proxy Int8)
, otherTestGroup (Proxy :: Proxy (Quaternion Int))
]
otherTestGroup
:: forall a.
(Eq a, Show a, Semiring a, Num a, Arbitrary a, U.Unbox a, G.Vector U.Vector a)
=> Proxy a
-> [TestTree]
otherTestGroup _ =
[ testProperty "leading p 0 == Nothing" $
\p -> leading (monomial p 0 :: UPoly a) === Nothing
, testProperty "leading . monomial = id" $
\p c -> c /= 0 ==> leading (monomial p c :: UPoly a) === Just (p, c)
, testProperty "monomial matches reference" $
\p (c :: a) -> monomial p c === toPoly (V.fromList (monomialRef p c))
, tenTimesLess $
testProperty "scale matches multiplication by monomial" $
\p c (xs :: UPoly a) -> scale p c xs === monomial p c * xs
]
monomialRef :: Num a => Word -> a -> [(Word, a)]
monomialRef p c = [(p, c)]
evalTests :: TestTree
evalTests = testGroup "eval" $ concat
[ evalTestGroup (Proxy :: Proxy (Poly U.Vector Int8))
, evalTestGroup (Proxy :: Proxy (Poly V.Vector Integer))
, substTestGroup (Proxy :: Proxy (Poly U.Vector Int8))
]
evalTestGroup
:: forall v a.
(Eq a, Num a, Semiring a, Arbitrary a, Show a, Eq (v (Word, a)), Show (v (Word, a)), G.Vector v (Word, a))
=> Proxy (Poly v a)
-> [TestTree]
evalTestGroup _ =
[ testProperty "eval (p + q) r = eval p r + eval q r" $
\p q r -> e (p + q) r === e p r + e q r
, testProperty "eval (p * q) r = eval p r * eval q r" $
\p q r -> e (p * q) r === e p r * e q r
, testProperty "eval x p = p" $
\p -> e X p === p
, testProperty "eval (monomial 0 c) p = c" $
\c p -> e (monomial 0 c) p === c
, testProperty "eval' (p + q) r = eval' p r + eval' q r" $
\p q r -> e' (p + q) r === e' p r + e' q r
, testProperty "eval' (p * q) r = eval' p r * eval' q r" $
\p q r -> e' (p * q) r === e' p r * e' q r
, testProperty "eval' x p = p" $
\p -> e' S.X p === p
, testProperty "eval' (S.monomial 0 c) p = c" $
\c p -> e' (S.monomial 0 c) p === c
]
where
e :: Poly v a -> a -> a
e = eval
e' :: Poly v a -> a -> a
e' = S.eval
substTestGroup
:: forall v a.
(Eq a, Num a, Semiring a, Arbitrary a, Show a, Eq (v (Word, a)), Show (v (Word, a)), G.Vector v (Word, a))
=> Proxy (Poly v a)
-> [TestTree]
substTestGroup _ =
[ testProperty "subst x p = p" $
\p -> e X p === p
, testProperty "subst (monomial 0 c) p = monomial 0 c" $
\c p -> e (monomial 0 c) p === monomial 0 c
, testProperty "subst' x p = p" $
\p -> e' S.X p === p
, testProperty "subst' (S.monomial 0 c) p = S.monomial 0 c" $
\c p -> e' (S.monomial 0 c) p === S.monomial 0 c
]
where
e :: Poly v a -> Poly v a -> Poly v a
e = subst
e' :: Poly v a -> Poly v a -> Poly v a
e' = S.subst
derivTests :: TestTree
derivTests = testGroup "deriv"
[ testProperty "deriv = S.deriv" $
\(p :: Poly V.Vector Integer) -> deriv p === S.deriv p
, testProperty "integral = S.integral" $
\(p :: Poly V.Vector Rational) -> integral p === S.integral p
, testProperty "deriv . integral = id" $
\(p :: Poly V.Vector Rational) -> deriv (integral p) === p
, testProperty "deriv c = 0" $
\c -> deriv (monomial 0 c :: Poly V.Vector Int) === 0
, testProperty "deriv cX = c" $
\c -> deriv (monomial 0 c * X :: Poly V.Vector Int) === monomial 0 c
, testProperty "deriv (p + q) = deriv p + deriv q" $
\p q -> deriv (p + q) === (deriv p + deriv q :: Poly V.Vector Int)
, testProperty "deriv (p * q) = p * deriv q + q * deriv p" $
\p q -> deriv (p * q) === (p * deriv q + q * deriv p :: Poly V.Vector Int)
-- , testProperty "deriv (subst p q) = deriv q * subst (deriv p) q" $
-- \(p :: Poly V.Vector Int) (q :: Poly U.Vector Int) ->
-- deriv (subst p q) === deriv q * subst (deriv p) q
]