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--
-- QuickCheck tests
--
-----------------------------------------------------------------------------
import Data.Packed.Internal.Vector
import Data.Packed.Internal.Matrix
import LAPACK
import Test.QuickCheck
import Complex
{-
-- Bravo por quickCheck!
pinvProp1 tol m = (rank m == cols m) ==> pinv m <> m ~~ ident (cols m)
where infix 2 ~~
(~~) = approxEqual tol
pinvProp2 tol m = 0 < r && r <= c ==> (r==c) `trivial` (m <> pinv m <> m ~~ m)
where r = rank m
c = cols m
infix 2 ~~
(~~) = approxEqual tol
nullspaceProp tol m = cr > 0 ==> m <> nt ~~ zeros
where nt = trans (nullspace m)
cr = corank m
r = rows m
zeros = create [r,cr] $ replicate (r*cr) 0
-}
r >< c = f where
f l | dim v == r*c = matrixFromVector RowMajor c v
| otherwise = error $ "inconsistent list size = "
++show (dim v) ++"in ("++show r++"><"++show c++")"
where v = fromList l
r >|< c = f where
f l | dim v == r*c = matrixFromVector ColumnMajor c v
| otherwise = error $ "inconsistent list size = "
++show (dim v) ++"in ("++show r++"><"++show c++")"
where v = fromList l
ac = (2><3) [1 .. 6::Double]
bc = (3><4) [7 .. 18::Double]
mz = (2 >< 3) [1,2,3,4,5,6:+(1::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]
a |=| b = rows a == rows b &&
cols a == cols b &&
toList (cdat a) == toList (cdat b) &&
toList (fdat a) == toList (fdat b)
aprox fun a b = rows a == rows b &&
cols a == cols b &&
eps > aproxL fun (toList (t a)) (toList (t b))
where t = if (order a == RowMajor) `xor` isTrans a then cdat else fdat
aproxL fun v1 v2 = sum (zipWith (\a b-> fun (a-b)) v1 v2) / fromIntegral (length v1)
(|~|) = aprox abs
(|~~|) = aprox magnitude
v1 ~~ v2 = reshape 1 v1 |~~| reshape 1 v2
eps = 1E-8::Double
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
cc = mulC ac bf
cf = mulF af bc
r = mulC cc (trans cf)
rd = (2><2)
[ 43492.0, 50572.0
, 102550.0, 119242.0 :: Double]
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 (1,10)
n <- choose (1,10)
l <- vector (m*n)
ctype <- arbitrary
let h = if ctype then (m><n) else (m>|<n)
trMode <- arbitrary
let tr = if trMode then trans else id
return $ tr (h l)
coarbitrary = undefined
data PairM a = PairM (Matrix a) (Matrix a) deriving Show
instance (Num a, Field a, Arbitrary a) => Arbitrary (PairM a) where
arbitrary = do
a <- choose (1,10)
b <- choose (1,10)
c <- choose (1,10)
l1 <- vector (a*b)
l2 <- vector (b*c)
return $ PairM ((a><b) (map fromIntegral (l1::[Int]))) ((b><c) (map fromIntegral (l2::[Int])))
--return $ PairM ((a><b) l1) ((b><c) l2)
coarbitrary = undefined
data SqM a = SqM (Matrix a) deriving Show
instance (Field a, Arbitrary a) => Arbitrary (SqM a) where
arbitrary = do
n <- choose (1,10)
l <- vector (n*n)
return $ SqM $ (n><n) l
coarbitrary = undefined
data Sym a = Sym (Matrix a) deriving Show
instance (Field a, Arbitrary a, Num a) => Arbitrary (Sym a) where
arbitrary = do
SqM m <- arbitrary
return $ Sym (m `addM` trans m)
coarbitrary = undefined
data Her = Her (Matrix (Complex Double)) deriving Show
instance {-(Field a, Arbitrary a, Num a) =>-} Arbitrary Her where
arbitrary = do
SqM m <- arbitrary
return $ Her (m `addM` (liftMatrix conj) (trans 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 (1,10)
c <- choose (1,10)
l1 <- vector (a*a)
l2 <- vector (a*c)
return $ PairSM ((a><a) (map fromIntegral (l1::[Int]))) ((a><c) (map fromIntegral (l2::[Int])))
--return $ PairSM ((a><a) l1) ((a><c) l2)
coarbitrary = undefined
addM m1 m2 = liftMatrix2 addV m1 m2
addV v1 v2 = fromList $ zipWith (+) (toList v1) (toList v2)
type BaseType = Double
svdTestR prod m = u <> s <> trans v |~| m
&& u <> trans u |~| ident (rows m)
&& v <> trans v |~| ident (cols m)
where (u,s,v) = svdR m
(<>) = prod
svdTestC prod m = u <> s' <> (trans v) |~~| m
&& u <> (liftMatrix conj) (trans u) |~~| ident (rows m)
&& v <> (liftMatrix conj) (trans v) |~~| ident (cols m)
where (u,s,v) = svdC m
(<>) = prod
s' = liftMatrix comp s
eigTestC prod (SqM m) = (m <> v) |~~| (v <> diag s)
&& takeDiag ((liftMatrix conj (trans v)) <> v) ~~ constant (rows m) 1 --normalized
where (s,v) = eigC m
(<>) = prod
eigTestR prod (SqM m) = (liftMatrix comp m <> v) |~~| (v <> diag s)
-- && takeDiag ((liftMatrix conj (trans v)) <> v) ~~ constant (rows m) 1 --normalized ???
where (s,v) = eigR m
(<>) = prod
eigTestS prod (Sym m) = (m <> v) |~| (v <> diag s)
&& v <> trans v |~| ident (cols m)
where (s,v) = eigS m
(<>) = prod
eigTestH prod (Her m) = (m <> v) |~~| (v <> diag (comp s))
&& v <> (liftMatrix conj) (trans v) |~~| ident (cols m)
where (s,v) = eigH m
(<>) = prod
linearSolveSQTest fun eqfun singu prod (PairSM a b) = singu a || (a <> fun a b) ==== b
where (<>) = prod
(====) = eqfun
prec = 1E-15
singular fun m = s1 < prec || s2/s1 < prec
where (_,ss,v) = fun m
s = toList ss
s1 = maximum s
s2 = minimum s
{-
invTest msg m = do
assertBool msg $ m <> inv m =~= ident (rows m)
invComplexTest msg m = do
assertBool msg $ m <> invC m =~= identC (rows m)
invC m = linearSolveC m (identC (rows m))
identC n = toComplex(ident n, (0::Double) <>ident n)
-}
--------------------------------------------------------------------
pinvTest f feq m = (m <> f m <> m) `feq` m
where (<>) = mulF
pinvR m = linearSolveLSR m (ident (rows m))
pinvC m = linearSolveLSC m (ident (rows m))
pinvSVDR m = linearSolveSVDR Nothing m (ident (rows m))
pinvSVDC m = linearSolveSVDC Nothing m (ident (rows m))
main = do
putStrLn "--------- general -----"
quickCheck (\(Sym m) -> m |=| (trans m:: Matrix BaseType))
quickCheck $ \l -> null l || (toList . fromList) l == (l :: [BaseType])
quickCheck $ \m -> m |=| asC (m :: Matrix BaseType)
quickCheck $ \m -> m |=| asFortran (m :: Matrix BaseType)
quickCheck $ \m -> m |=| (asC . asFortran) (m :: Matrix BaseType)
putStrLn "--------- MULTIPLY ----"
quickCheck $ \(PairM m1 m2) -> mulC m1 m2 |=| mulF m1 (m2 :: Matrix BaseType)
quickCheck $ \(PairM m1 m2) -> mulC m1 m2 |=| trans (mulF (trans m2) (trans m1 :: Matrix BaseType))
quickCheck $ \(PairM m1 m2) -> mulC m1 m2 |=| multiplyG m1 (m2 :: Matrix BaseType)
putStrLn "--------- SVD ---------"
quickCheck (svdTestR mulC)
quickCheck (svdTestR mulF)
quickCheck (svdTestC mulC)
quickCheck (svdTestC mulF)
putStrLn "--------- EIG ---------"
quickCheck (eigTestC mulC)
quickCheck (eigTestC mulF)
quickCheck (eigTestR mulC)
quickCheck (eigTestR mulF)
quickCheck (eigTestS mulC)
quickCheck (eigTestS mulF)
quickCheck (eigTestH mulC)
quickCheck (eigTestH mulF)
putStrLn "--------- SOLVE ---------"
quickCheck (linearSolveSQTest linearSolveR (|~|) (singular svdR') mulC)
quickCheck (linearSolveSQTest linearSolveC (|~~|) (singular svdC') mulF)
quickCheck (pinvTest pinvR (|~|))
quickCheck (pinvTest pinvC (|~~|))
quickCheck (pinvTest pinvSVDR (|~|))
quickCheck (pinvTest pinvSVDC (|~~|))
kk = (2><2)
[ 1.0, 0.0
, -1.5, 1.0 ::Double]
|
