#if defined(__GLASGOW_HASKELL__) && __GLASGOW_HASKELL__ >= 702
#endif
module Linear.Matrix
( (!*!), (!+!), (!-!), (!*), (*!), (!!*), (*!!), (!!/)
, column
, adjoint
, M22, M23, M24, M32, M33, M34, M42, M43, M44
, m33_to_m44, m43_to_m44
, det22, det33, det44, inv22, inv33, inv44
, identity
, Trace(..)
, translation
, transpose
, fromQuaternion
, mkTransformation
, mkTransformationMat
, _m22, _m23, _m24
, _m32, _m33, _m34
, _m42, _m43, _m44
) where
#if __GLASGOW_HASKELL__ < 710
import Control.Applicative
#endif
import Control.Lens hiding (index)
import Control.Lens.Internal.Context
import Data.Distributive
import Data.Foldable as Foldable
import Data.Functor.Rep
import Linear.Quaternion
import Linear.V2
import Linear.V3
import Linear.V4
import Linear.Vector
import Linear.Conjugate
import Linear.Trace
#ifdef HLINT
#endif
column :: Representable f => LensLike (Context a b) s t a b -> Lens (f s) (f t) (f a) (f b)
column l f es = o <$> f i where
go = l (Context id)
i = tabulate $ \ e -> ipos $ go (index es e)
o eb = tabulate $ \ e -> ipeek (index eb e) (go (index es e))
infixl 7 !*!
(!*!) :: (Functor m, Foldable t, Additive t, Additive n, Num a) => m (t a) -> t (n a) -> m (n a)
f !*! g = fmap (\ f' -> Foldable.foldl' (^+^) zero $ liftI2 (*^) f' g) f
infixl 6 !+!
(!+!) :: (Additive m, Additive n, Num a) => m (n a) -> m (n a) -> m (n a)
as !+! bs = liftU2 (^+^) as bs
infixl 6 !-!
(!-!) :: (Additive m, Additive n, Num a) => m (n a) -> m (n a) -> m (n a)
as !-! bs = liftU2 (^-^) as bs
infixl 7 !*
(!*) :: (Functor m, Foldable r, Additive r, Num a) => m (r a) -> r a -> m a
m !* v = fmap (\r -> Foldable.sum $ liftI2 (*) r v) m
infixl 7 *!
(*!) :: (Num a, Foldable t, Additive f, Additive t) => t a -> t (f a) -> f a
f *! g = sumV $ liftI2 (*^) f g
infixl 7 *!!
(*!!) :: (Functor m, Functor r, Num a) => a -> m (r a) -> m (r a)
s *!! m = fmap (s *^) m
infixl 7 !!*
(!!*) :: (Functor m, Functor r, Num a) => m (r a) -> a -> m (r a)
(!!*) = flip (*!!)
infixl 7 !!/
(!!/) :: (Functor m, Functor r, Fractional a) => m (r a) -> a -> m (r a)
m !!/ s = fmap (^/ s) m
adjoint :: (Functor m, Distributive n, Conjugate a) => m (n a) -> n (m a)
adjoint = collect (fmap conjugate)
type M22 a = V2 (V2 a)
type M23 a = V2 (V3 a)
type M24 a = V2 (V4 a)
type M32 a = V3 (V2 a)
type M33 a = V3 (V3 a)
type M34 a = V3 (V4 a)
type M42 a = V4 (V2 a)
type M43 a = V4 (V3 a)
type M44 a = V4 (V4 a)
fromQuaternion :: Num a => Quaternion a -> M33 a
fromQuaternion (Quaternion w (V3 x y z)) =
V3 (V3 (12*(y2+z2)) (2*(x*yz*w)) (2*(x*z+y*w)))
(V3 (2*(x*y+z*w)) (12*(x2+z2)) (2*(y*zx*w)))
(V3 (2*(x*zy*w)) (2*(y*z+x*w)) (12*(x2+y2)))
where x2 = x * x
y2 = y * y
z2 = z * z
mkTransformationMat :: Num a => M33 a -> V3 a -> M44 a
mkTransformationMat (V3 r1 r2 r3) (V3 tx ty tz) =
V4 (snoc3 r1 tx) (snoc3 r2 ty) (snoc3 r3 tz) (V4 0 0 0 1)
where snoc3 (V3 x y z) = V4 x y z
mkTransformation :: Num a => Quaternion a -> V3 a -> M44 a
mkTransformation = mkTransformationMat . fromQuaternion
m43_to_m44 :: Num a => M43 a -> M44 a
m43_to_m44
(V4 (V3 a b c)
(V3 d e f)
(V3 g h i)
(V3 j k l)) =
V4 (V4 a b c 0)
(V4 d e f 0)
(V4 g h i 0)
(V4 j k l 1)
m33_to_m44 :: Num a => M33 a -> M44 a
m33_to_m44 (V3 r1 r2 r3) = V4 (vector r1) (vector r2) (vector r3) (point 0)
identity :: (Num a, Traversable t, Applicative t) => t (t a)
identity = scaled (pure 1)
translation :: (Representable t, R3 t, R4 v) => Lens' (t (v a)) (V3 a)
translation = column _w._xyz
_m22 :: (Representable t, R2 t, R2 v) => Lens' (t (v a)) (M22 a)
_m22 = column _xy._xy
_m23 :: (Representable t, R2 t, R3 v) => Lens' (t (v a)) (M23 a)
_m23 = column _xyz._xy
_m24 :: (Representable t, R2 t, R4 v) => Lens' (t (v a)) (M24 a)
_m24 = column _xyzw._xy
_m32 :: (Representable t, R3 t, R2 v) => Lens' (t (v a)) (M32 a)
_m32 = column _xy._xyz
_m33 :: (Representable t, R3 t, R3 v) => Lens' (t (v a)) (M33 a)
_m33 = column _xyz._xyz
_m34 :: (Representable t, R3 t, R4 v) => Lens' (t (v a)) (M34 a)
_m34 = column _xyzw._xyz
_m42 :: (Representable t, R4 t, R2 v) => Lens' (t (v a)) (M42 a)
_m42 = column _xy._xyzw
_m43 :: (Representable t, R4 t, R3 v) => Lens' (t (v a)) (M43 a)
_m43 = column _xyz._xyzw
_m44 :: (Representable t, R4 t, R4 v) => Lens' (t (v a)) (M44 a)
_m44 = column _xyzw._xyzw
det22 :: Num a => M22 a -> a
det22 (V2 (V2 a b) (V2 c d)) = a * d b * c
det33 :: Num a => M33 a -> a
det33 (V3 (V3 a b c)
(V3 d e f)
(V3 g h i)) = a * (e*if*h) d * (b*ic*h) + g * (b*fc*e)
det44 :: Num a => M44 a -> a
det44 (V4 (V4 i00 i01 i02 i03)
(V4 i10 i11 i12 i13)
(V4 i20 i21 i22 i23)
(V4 i30 i31 i32 i33)) =
let
s0 = i00 * i11 i10 * i01
s1 = i00 * i12 i10 * i02
s2 = i00 * i13 i10 * i03
s3 = i01 * i12 i11 * i02
s4 = i01 * i13 i11 * i03
s5 = i02 * i13 i12 * i03
c5 = i22 * i33 i32 * i23
c4 = i21 * i33 i31 * i23
c3 = i21 * i32 i31 * i22
c2 = i20 * i33 i30 * i23
c1 = i20 * i32 i30 * i22
c0 = i20 * i31 i30 * i21
in s0 * c5 s1 * c4 + s2 * c3 + s3 * c2 s4 * c1 + s5 * c0
inv22 :: Floating a => M22 a -> M22 a
inv22 m@(V2 (V2 a b) (V2 c d)) = (1 / det) *!! V2 (V2 d (b)) (V2 (c) a)
where det = det22 m
inv33 :: Floating a => M33 a -> M33 a
inv33 m@(V3 (V3 a b c)
(V3 d e f)
(V3 g h i))
= (1 / det) *!! V3 (V3 a' b' c')
(V3 d' e' f')
(V3 g' h' i')
where a' = cofactor (e,f,h,i)
b' = cofactor (c,b,i,h)
c' = cofactor (b,c,e,f)
d' = cofactor (f,d,i,g)
e' = cofactor (a,c,g,i)
f' = cofactor (c,a,f,d)
g' = cofactor (d,e,g,h)
h' = cofactor (b,a,h,g)
i' = cofactor (a,b,d,e)
cofactor (q,r,s,t) = det22 (V2 (V2 q r) (V2 s t))
det = det33 m
transpose :: (Distributive g, Functor f) => f (g a) -> g (f a)
transpose = distribute
inv44 :: Fractional a => M44 a -> M44 a
inv44 (V4 (V4 i00 i01 i02 i03)
(V4 i10 i11 i12 i13)
(V4 i20 i21 i22 i23)
(V4 i30 i31 i32 i33)) =
let s0 = i00 * i11 i10 * i01
s1 = i00 * i12 i10 * i02
s2 = i00 * i13 i10 * i03
s3 = i01 * i12 i11 * i02
s4 = i01 * i13 i11 * i03
s5 = i02 * i13 i12 * i03
c5 = i22 * i33 i32 * i23
c4 = i21 * i33 i31 * i23
c3 = i21 * i32 i31 * i22
c2 = i20 * i33 i30 * i23
c1 = i20 * i32 i30 * i22
c0 = i20 * i31 i30 * i21
det = s0 * c5 s1 * c4 + s2 * c3 + s3 * c2 s4 * c1 + s5 * c0
invDet = recip det
in invDet *!! V4 (V4 (i11 * c5 i12 * c4 + i13 * c3)
(i01 * c5 + i02 * c4 i03 * c3)
(i31 * s5 i32 * s4 + i33 * s3)
(i21 * s5 + i22 * s4 i23 * s3))
(V4 (i10 * c5 + i12 * c2 i13 * c1)
(i00 * c5 i02 * c2 + i03 * c1)
(i30 * s5 + i32 * s2 i33 * s1)
(i20 * s5 i22 * s2 + i23 * s1))
(V4 (i10 * c4 i11 * c2 + i13 * c0)
(i00 * c4 + i01 * c2 i03 * c0)
(i30 * s4 i31 * s2 + i33 * s0)
(i20 * s4 + i21 * s2 i23 * s0))
(V4 (i10 * c3 + i11 * c1 i12 * c0)
(i00 * c3 i01 * c1 + i02 * c0)
(i30 * s3 + i31 * s1 i32 * s0)
(i20 * s3 i21 * s1 + i22 * s0))