{-# OPTIONS_GHC -fglasgow-exts -fallow-undecidable-instances #-} module Main where import Data.Packed.Internal((>|<), fdat, cdat, multiply', multiplyG, MatrixOrder(..),debug) import Numeric.GSL hiding (sin,cos,exp,choose) import Numeric.LinearAlgebra import Numeric.LinearAlgebra.Linear(Linear) import Numeric.LinearAlgebra.LAPACK import Numeric.GSL.Matrix(svdg) import qualified Numeric.GSL.Matrix as GSL import Test.QuickCheck hiding (test) import Test.HUnit hiding ((~:),test) import System.Random(randomRs,mkStdGen) import System.Info type RM = Matrix Double type CM = Matrix (Complex Double) dist :: (Normed t, Num t) => t -> t -> Double dist a b = pnorm Infinity (a-b) infixl 4 |~| a |~| b = a :~8~: b data Aprox a = (:~) a Int (~:) :: (Normed a, Num a) => Aprox a -> a -> Bool a :~n~: b = dist a b < 10^^(-n) maxdim = 10 instance (Arbitrary a, RealFloat a) => Arbitrary (Complex a) where arbitrary = do r <- arbitrary i <- arbitrary return (r:+i) coarbitrary = undefined instance (Field a, Arbitrary a) => Arbitrary (Matrix a) where arbitrary = do --m <- sized $ \max -> choose (1,1+3*max) m <- choose (1,maxdim) n <- choose (1,maxdim) l <- vector (m*n) ctype <- arbitrary let h = if ctype then (m>| Arbitrary (PairM a) where arbitrary = do a <- choose (1,maxdim) b <- choose (1,maxdim) c <- choose (1,maxdim) l1 <- vector (a*b) l2 <- vector (b*c) return $ PairM ((a> Arbitrary (SqM a) where arbitrary = do n <- choose (1,maxdim) l <- vector (n*n) return $ SqM $ (n> Arbitrary (Sym a) where arbitrary = do SqM m <- arbitrary return $ Sym (m + trans m) coarbitrary = undefined data Her = Her (Matrix (Complex Double)) deriving Show her (Her a) = a instance {-(Field a, Arbitrary a, Num a) =>-} Arbitrary Her where arbitrary = do SqM m <- arbitrary return $ Her (m + ctrans m) coarbitrary = undefined data PairSM a = PairSM (Matrix a) (Matrix a) deriving Show instance (Num a, Field a, Arbitrary a) => Arbitrary (PairSM a) where arbitrary = do a <- choose (1,maxdim) c <- choose (1,maxdim) l1 <- vector (a*a) l2 <- vector (a*c) return $ PairSM ((a> Arbitrary (Vector a) where arbitrary = do --m <- sized $ \max -> choose (1,1+3*max) m <- choose (1,maxdim^2) l <- vector m return $ fromList l coarbitrary = undefined data PairV a = PairV (Vector a) (Vector a) instance (Field a, Arbitrary a) => Arbitrary (PairV a) where arbitrary = do --m <- sized $ \max -> choose (1,1+3*max) m <- choose (1,maxdim^2) l1 <- vector m l2 <- vector m return $ PairV (fromList l1) (fromList l2) coarbitrary = undefined ---------------------------------------------------------------------- test str b = TestCase $ assertBool str b ---------------------------------------------------------------------- pseudorandomR seed (n,m) = reshape m $ fromList $ take (n*m) $ randomRs (-100,100) $ mkStdGen seed pseudorandomC seed (n,m) = toComplex (pseudorandomR seed (n,m), pseudorandomR (seed+1) (n,m)) bigmat = m + trans m :: RM where m = pseudorandomR 18 (1000,1000) bigmatc = mc + ctrans mc ::CM where mc = pseudorandomC 19 (1000,1000) ---------------------------------------------------------------------- m = (3><3) [ 1, 2, 3 , 4, 5, 7 , 2, 8, 4 :: Double ] mc = (3><3) [ 1, 2, 3 , 4, 5, 7 , 2, 8, i ] mr = (3><4) [ 1, 2, 3, 4, 2, 4, 6, 8, 1, 1, 1, 2:: Double ] mrc = (3><4) [ 1, 2, 3, 4, 2, 4, 6, 8, i, i, i, 2 ] a = (3><4) [ 1, 0, 0, 0 , 0, 2, 0, 0 , 0, 0, 0, 0 :: Double ] b = (3><4) [ 1, 0, 0, 0 , 0, 2, 3, 0 , 0, 0, 4, 0 :: Double ] ac = (2><3) [1 .. 6::Double] bc = (3><4) [7 .. 18::Double] af = (2>|<3) [1,4,2,5,3,6::Double] bf = (3>|<4) [7,11,15,8,12,16,9,13,17,10,14,18::Double] ------------------------------------------------------- detTest = det m == 26 && det mc == 38 :+ (-3) invTest m = degenerate m || m <> inv m |~| ident (rows m) pinvTest m = m <> p <> m |~| m && p <> m <> p |~| p && hermitian (m<>p) && hermitian (p<>m) where p = pinv m square m = rows m == cols m orthonormal m = square m && m <> ctrans m |~| ident (rows m) hermitian m = m |~| ctrans m svdTest svd m = u <> real d <> trans v |~| m && orthonormal u && orthonormal v where (u,d,v) = full svd m svdTest' svd m = m |~| 0 || u <> real (diag s) <> trans v |~| m where (u,s,v) = economy svd m eigTest m = complex m <> v |~| v <> diag s where (s, v) = eig m eigTestSH m = m <> v |~| v <> real (diag s) && orthonormal v && m |~| v <> real (diag s) <> ctrans v where (s, v) = eigSH m rank m | m |~| 0 = 0 | otherwise = dim s where (_,s,_) = economy svd m zeros (r,c) = reshape c (constant 0 (r*c)) ones (r,c) = zeros (r,c) + 1 degenerate m = rank m < min (rows m) (cols m) prec = 1E-15 singular m = s1 < prec || s2/s1 < prec where (_,ss,_) = svd m s = toList ss s1 = maximum s s2 = minimum s nullspaceTest m = null nl || m <> n |~| zeros (r,c) -- 0 where nl = nullspacePrec 1 m n = fromColumns nl r = rows m c = cols m - rank m -------------------------------------------------------------------- polyEval cs x = foldr (\c ac->ac*x+c) 0 cs polySolveTest' p = length p <2 || last p == 0|| 1E-8 > maximum (map magnitude $ map (polyEval (map (:+0) p)) (polySolve p)) polySolveTest = test "polySolve" (polySolveTest' [1,2,3,4]) --------------------------------------------------------------------- quad f a b = fst $ integrateQAGS 1E-9 100 f a b -- A multiple integral can be easily defined using partial application quad2 f a b g1 g2 = quad h a b where h x = quad (f x) (g1 x) (g2 x) volSphere r = 8 * quad2 (\x y -> sqrt (r*r-x*x-y*y)) 0 r (const 0) (\x->sqrt (r*r-x*x)) epsTol = 1E-8::Double integrateTest = test "integrate" (abs (volSphere 2.5 - 4/3*pi*2.5^3) < epsTol) --------------------------------------------------------------------- besselTest = test "bessel_J0_e" ( abs (r-expected) < e ) where (r,e) = bessel_J0_e 5.0 expected = -0.17759677131433830434739701 exponentialTest = test "exp_e10_e" ( abs (v*10^e - expected) < 4E-2 ) where (v,e,err) = exp_e10_e 30.0 expected = exp 30.0 gammaTest = test "gamma" (gamma 5 == 24.0) --------------------------------------------------------------------- cholRTest = chol ((2><2) [1,2,2,9::Double]) == (2><2) [1,2,0,2.23606797749979] cholCTest = chol ((2><2) [1,2,2,9::Complex Double]) == (2><2) [1,2,0,2.23606797749979] --------------------------------------------------------------------- qrTest qr m = q <> r |~| m && q <> ctrans q |~| ident (rows m) where (q,r) = qr m --------------------------------------------------------------------- asFortran m = (rows m >|< cols m) $ toList (fdat m) asC m = (rows m >< cols m) $ toList (cdat m) mulC a b = multiply' RowMajor a b mulF a b = multiply' ColumnMajor a b --------------------------------------------------------------------- tests = do putStrLn "--------- internal -----" quickCheck ((\m -> m == trans m).sym :: Sym Double -> Bool) quickCheck ((\m -> m == trans m).sym :: Sym (Complex Double) -> Bool) quickCheck $ \l -> null l || (toList . fromList) l == (l :: [Double]) quickCheck $ \l -> null l || (toList . fromList) l == (l :: [Complex Double]) quickCheck $ \m -> m == asC (m :: RM) quickCheck $ \m -> m == asC (m :: CM) quickCheck $ \m -> m == asFortran (m :: RM) quickCheck $ \m -> m == asFortran (m :: CM) quickCheck $ \m -> m == (asC . asFortran) (m :: RM) quickCheck $ \m -> m == (asC . asFortran) (m :: CM) putStrLn "--------- multiply ----" quickCheck $ \(PairM m1 m2) -> mulC m1 m2 == mulF m1 (m2 :: RM) quickCheck $ \(PairM m1 m2) -> mulC m1 m2 == mulF m1 (m2 :: CM) quickCheck $ \(PairM m1 m2) -> mulC m1 m2 == trans (mulF (trans m2) (trans m1 :: RM)) quickCheck $ \(PairM m1 m2) -> mulC m1 m2 == trans (mulF (trans m2) (trans m1 :: CM)) quickCheck $ \(PairM m1 m2) -> mulC m1 m2 == multiplyG m1 (m2 :: RM) quickCheck $ \(PairM m1 m2) -> mulC m1 m2 == multiplyG m1 (m2 :: CM) putStrLn "--------- svd ---------" quickCheck (svdTest svdR) quickCheck (svdTest svdRdd) quickCheck (svdTest svdC) quickCheck (svdTest' svdR) quickCheck (svdTest' svdRdd) quickCheck (svdTest' svdC) quickCheck (svdTest' svdg) putStrLn "--------- eig ---------" quickCheck (eigTest . sqm :: SqM Double -> Bool) quickCheck (eigTest . sqm :: SqM (Complex Double) -> Bool) quickCheck (eigTestSH . sym :: Sym Double -> Bool) quickCheck (eigTestSH . her :: Her -> Bool) putStrLn "--------- inv ------" quickCheck (invTest . sqm :: SqM Double -> Bool) quickCheck (invTest . sqm :: SqM (Complex Double) -> Bool) putStrLn "--------- pinv ------" quickCheck (pinvTest . sqm :: SqM Double -> Bool) if os == "mingw32" then putStrLn "complex pinvTest skipped in this OS" else quickCheck (pinvTest . sqm :: SqM (Complex Double) -> Bool) putStrLn "--------- chol ------" runTestTT $ TestList [ test "cholR" cholRTest , test "cholC" cholRTest ] putStrLn "--------- qr ---------" quickCheck (qrTest GSL.qr) quickCheck (qrTest (GSL.unpackQR . GSL.qrPacked)) quickCheck (qrTest ( unpackQR . GSL.qrPacked)) quickCheck (qrTest qr ::RM->Bool) quickCheck (qrTest qr ::CM->Bool) putStrLn "--------- nullspace ------" quickCheck (nullspaceTest :: RM -> Bool) quickCheck (nullspaceTest :: CM -> Bool) putStrLn "--------- vector operations ------" quickCheck $ (\u -> sin u ^ 2 + cos u ^ 2 |~| (1::RM)) quickCheck $ (\u -> sin u ** 2 + cos u ** 2 |~| (1::RM)) quickCheck $ (\u -> cos u * tan u |~| sin (u::RM)) quickCheck $ (\u -> (cos u * tan u) :~6~: sin (u::CM)) runTestTT $ TestList [ test "arith1" $ ((ones (100,100) * 5 + 2)/0.5 - 7)**2 |~| (49 :: RM) , test "arith2" $ (((1+i) .* ones (100,100) * 5 + 2)/0.5 - 7)**2 |~| ( (140*i-51).*1 :: CM) , test "arith3" $ exp (i.*ones(10,10)*pi) + 1 |~| 0 , test "<\\>" $ (3><2) [2,0,0,3,1,1::Double] <\> 3|>[4,9,5] |~| 2|>[2,3] ] putStrLn "--------- GSL ------" quickCheck $ \v -> ifft (fft v) |~| v runTestTT $ TestList [ gammaTest , besselTest , exponentialTest , integrateTest , polySolveTest , test "det" detTest ] bigtests = do putStrLn "--------- big matrices -----" runTestTT $ TestList [ test "eigS" $ eigTestSH bigmat , test "eigH" $ eigTestSH bigmatc , test "eigR" $ eigTest bigmat , test "eigC" $ eigTest bigmatc ] main = tests