Copyright	(c) Justus Sagemüller 2015
License	GPL v3
Maintainer	(@) sagemueller $ geo.uni-koeln.de
Stability	experimental
Portability	portable
Safe Haskell	None
Language	Haskell2010

Data.Manifold.Types

Contents

Index / ASCII names
Linear manifolds
Hyperspheres
- General form: Stiefel manifolds
- Specific examples
Projective spaces
Intervals/disks/cones
Affine subspaces
- Lines
- Hyperplanes
Linear mappings
Misc
Orphan instances

Description

Several commonly-used manifolds, represented in some simple way as Haskell data types. All these are in the PseudoAffine class.

Synopsis

Index / ASCII names

type Real0 = ℝ⁰ Source #

type Real1 = ℝ Source #

type RealPlus = ℝay Source #

type Real2 = ℝ² Source #

type Real3 = ℝ³ Source #

type Sphere0 = S⁰ Source #

type Sphere1 = S¹ Source #

type Sphere2 = S² Source #

type Projective1 = ℝP¹ Source #

type Projective2 = ℝP² Source #

type Disk1 = D¹ Source #

type Disk2 = D² Source #

type Cone = CD¹ Source #

type OpenCone = Cℝay Source #

Linear manifolds

data ZeroDim s :: * -> * #

Constructors

Origin

Instances

LtdErrorShow ℝ⁰ Source #
Methods ltdErrorShowWitness :: LtdErrorShowWitness ℝ⁰ showsPrecShade'_errorLtdC :: Int -> Shade' ℝ⁰ -> ShowS prettyShowsPrecShade :: Int -> Shade ℝ⁰ -> ShowS prettyShowsPrecShade' :: Int -> Shade' ℝ⁰ -> ShowS Source #
Refinable ℝ⁰ Source #
Methods debugView :: Maybe (DebugView ℝ⁰) subShade' :: Shade' ℝ⁰ -> Shade' ℝ⁰ -> Bool Source # refineShade' :: Shade' ℝ⁰ -> Shade' ℝ⁰ -> Maybe (Shade' ℝ⁰) Source # convolveMetric :: Functor p => p ℝ⁰ -> Metric ℝ⁰ -> Metric ℝ⁰ -> Metric ℝ⁰ Source # convolveShade' :: Shade' ℝ⁰ -> Shade' (Needle ℝ⁰) -> Shade' ℝ⁰ Source #
Eq (ZeroDim s)
Methods (==) :: ZeroDim s -> ZeroDim s -> Bool # (/=) :: ZeroDim s -> ZeroDim s -> Bool #
Show (ZeroDim s)
Methods showsPrec :: Int -> ZeroDim s -> ShowS # show :: ZeroDim s -> String # showList :: [ZeroDim s] -> ShowS #
Monoid (ZeroDim s)
Methods mempty :: ZeroDim s # mappend :: ZeroDim s -> ZeroDim s -> ZeroDim s # mconcat :: [ZeroDim s] -> ZeroDim s #
AdditiveGroup (ZeroDim s)
Methods zeroV :: ZeroDim s # (^+^) :: ZeroDim s -> ZeroDim s -> ZeroDim s # negateV :: ZeroDim s -> ZeroDim s # (^-^) :: ZeroDim s -> ZeroDim s -> ZeroDim s #
AdditiveGroup s => InnerSpace (ZeroDim s)
Methods (<.>) :: ZeroDim s -> ZeroDim s -> Scalar (ZeroDim s) #
VectorSpace (ZeroDim s)
Associated Types type Scalar (ZeroDim s) :: * # Methods (*^) :: Scalar (ZeroDim s) -> ZeroDim s -> ZeroDim s #
HasBasis (ZeroDim s)
Associated Types type Basis (ZeroDim s) :: * # Methods basisValue :: Basis (ZeroDim s) -> ZeroDim s # decompose :: ZeroDim s -> [(Basis (ZeroDim s), Scalar (ZeroDim s))] # decompose' :: ZeroDim s -> Basis (ZeroDim s) -> Scalar (ZeroDim s) #
AffineSpace (ZeroDim s)
Associated Types type Diff (ZeroDim s) :: * # Methods (.-.) :: ZeroDim s -> ZeroDim s -> Diff (ZeroDim s) # (.+^) :: ZeroDim s -> Diff (ZeroDim s) -> ZeroDim s #
RieszDecomposable (ZeroDim ℝ)
Methods rieszDecomposition :: (FiniteDimensional v, (* ~ v) (DualVector v), (* ~ Scalar v) (Scalar (ZeroDim ℝ))) => (v +> ZeroDim ℝ) -> [(Basis (ZeroDim ℝ), v)]
TensorDecomposable (ZeroDim ℝ)
Methods tensorDecomposition :: (ZeroDim ℝ ⊗ w) -> [(Basis (ZeroDim ℝ), w)] showsPrecBasis :: Functor p => p (ZeroDim ℝ) -> Int -> Basis (ZeroDim ℝ) -> ShowS
(Fractional' s, SemiInner s) => SemiInner (ZeroDim s)
Methods dualBasisCandidates :: [(Int, ZeroDim s)] -> Forest (Int, DualVector (ZeroDim s)) # tensorDualBasisCandidates :: (SemiInner w, (* ~ Scalar w) (Scalar (ZeroDim s))) => [(Int, ZeroDim s ⊗ w)] -> Forest (Int, DualVector (ZeroDim s ⊗ w)) # symTensorDualBasisCandidates :: [(Int, SymmetricTensor (Scalar (ZeroDim s)) (ZeroDim s))] -> Forest (Int, SymmetricTensor (Scalar (ZeroDim s)) (DualVector (ZeroDim s))) # symTensorTensorDualBasisCandidates :: (SemiInner w, (* ~ Scalar w) (Scalar (ZeroDim s))) => [(Int, SymmetricTensor (Scalar (ZeroDim s)) (ZeroDim s) ⊗ w)] -> Forest (Int, SymmetricTensor (Scalar (ZeroDim s)) (ZeroDim s) +> DualVector w) #
Num' s => FiniteDimensional (ZeroDim s)
Associated Types data SubBasis (ZeroDim s) :: * # Methods entireBasis :: SubBasis (ZeroDim s) # enumerateSubBasis :: SubBasis (ZeroDim s) -> [ZeroDim s] # subbasisDimension :: SubBasis (ZeroDim s) -> Int # decomposeLinMap :: (LSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s +> w) -> (SubBasis (ZeroDim s), DList w) # decomposeLinMapWithin :: (LSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => SubBasis (ZeroDim s) -> (ZeroDim s +> w) -> Either (SubBasis (ZeroDim s), DList w) (DList w) # recomposeSB :: SubBasis (ZeroDim s) -> [Scalar (ZeroDim s)] -> (ZeroDim s, [Scalar (ZeroDim s)]) # recomposeSBTensor :: (FiniteDimensional w, (* ~ Scalar w) (Scalar (ZeroDim s))) => SubBasis (ZeroDim s) -> SubBasis w -> [Scalar (ZeroDim s)] -> (ZeroDim s ⊗ w, [Scalar (ZeroDim s)]) # recomposeLinMap :: (LSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => SubBasis (ZeroDim s) -> [w] -> (ZeroDim s +> w, [w]) # recomposeContraLinMap :: (LinearSpace w, (* ~ Scalar w) (Scalar (ZeroDim s)), Functor f) => (f (Scalar w) -> w) -> f (DualVector (ZeroDim s)) -> ZeroDim s +> w # recomposeContraLinMapTensor :: (FiniteDimensional u, LinearSpace w, (* ~ Scalar u) (Scalar (ZeroDim s)), (* ~ Scalar w) (Scalar (ZeroDim s)), Functor f) => (f (Scalar w) -> w) -> f (ZeroDim s +> DualVector u) -> (ZeroDim s ⊗ u) +> w # uncanonicallyFromDual :: DualVector (ZeroDim s) -+> ZeroDim s # uncanonicallyToDual :: ZeroDim s -+> DualVector (ZeroDim s) #
Num' s => TensorSpace (ZeroDim s)
Associated Types type TensorProduct (ZeroDim s) w :: * # Methods scalarSpaceWitness :: ScalarSpaceWitness (ZeroDim s) # linearManifoldWitness :: LinearManifoldWitness (ZeroDim s) # zeroTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => ZeroDim s ⊗ w # toFlatTensor :: ZeroDim s -+> (ZeroDim s ⊗ Scalar (ZeroDim s)) # fromFlatTensor :: (ZeroDim s ⊗ Scalar (ZeroDim s)) -+> ZeroDim s # addTensors :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ w) -> (ZeroDim s ⊗ w) -> ZeroDim s ⊗ w # subtractTensors :: (TensorSpace (ZeroDim s), TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ w) -> (ZeroDim s ⊗ w) -> ZeroDim s ⊗ w # scaleTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => Bilinear (Scalar (ZeroDim s)) (ZeroDim s ⊗ w) (ZeroDim s ⊗ w) # negateTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ w) -+> (ZeroDim s ⊗ w) # tensorProduct :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => Bilinear (ZeroDim s) w (ZeroDim s ⊗ w) # tensorProducts :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => [(ZeroDim s, w)] -> ZeroDim s ⊗ w # transposeTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ w) -+> (w ⊗ ZeroDim s) # fmapTensor :: (TensorSpace w, TensorSpace x, (* ~ Scalar w) (Scalar (ZeroDim s)), (* ~ Scalar x) (Scalar (ZeroDim s))) => Bilinear (w -+> x) (ZeroDim s ⊗ w) (ZeroDim s ⊗ x) # fzipTensorWith :: (TensorSpace u, TensorSpace w, TensorSpace x, (* ~ Scalar u) (Scalar (ZeroDim s)), (* ~ Scalar w) (Scalar (ZeroDim s)), (* ~ Scalar x) (Scalar (ZeroDim s))) => Bilinear ((w, x) -+> u) (ZeroDim s ⊗ w, ZeroDim s ⊗ x) (ZeroDim s ⊗ u) # coerceFmapTensorProduct :: Functor p => p (ZeroDim s) -> Coercion * a b -> Coercion * (TensorProduct (ZeroDim s) a) (TensorProduct (ZeroDim s) b) # wellDefinedVector :: ZeroDim s -> Maybe (ZeroDim s) # wellDefinedTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ w) -> Maybe (ZeroDim s ⊗ w) #
Num' s => LinearSpace (ZeroDim s)
Associated Types type DualVector (ZeroDim s) :: * # Methods dualSpaceWitness :: DualSpaceWitness (ZeroDim s) # linearId :: ZeroDim s +> ZeroDim s # idTensor :: ZeroDim s ⊗ DualVector (ZeroDim s) # sampleLinearFunction :: (TensorSpace w, (* ~ Scalar (ZeroDim s)) (Scalar w)) => (ZeroDim s -+> w) -+> (ZeroDim s +> w) # toLinearForm :: DualVector (ZeroDim s) -+> (ZeroDim s +> Scalar (ZeroDim s)) # fromLinearForm :: (ZeroDim s +> Scalar (ZeroDim s)) -+> DualVector (ZeroDim s) # coerceDoubleDual :: Coercion * (ZeroDim s) (DualVector (DualVector (ZeroDim s))) # trace :: (ZeroDim s +> ZeroDim s) -+> Scalar (ZeroDim s) # contractTensorMap :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s +> (ZeroDim s ⊗ w)) -+> w # contractMapTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ (ZeroDim s +> w)) -+> w # contractTensorFn :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s -+> (ZeroDim s ⊗ w)) -+> w # contractLinearMapAgainst :: (LinearSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => Bilinear (ZeroDim s +> w) (w -+> ZeroDim s) (Scalar (ZeroDim s)) # applyDualVector :: Bilinear (DualVector (ZeroDim s)) (ZeroDim s) (Scalar (ZeroDim s)) # applyLinear :: (TensorSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => Bilinear (ZeroDim s +> w) (ZeroDim s) w # composeLinear :: (LinearSpace w, TensorSpace x, (* ~ Scalar w) (Scalar (ZeroDim s)), (* ~ Scalar x) (Scalar (ZeroDim s))) => Bilinear (w +> x) (ZeroDim s +> w) (ZeroDim s +> x) # tensorId :: (LinearSpace w, (* ~ Scalar w) (Scalar (ZeroDim s))) => (ZeroDim s ⊗ w) +> (ZeroDim s ⊗ w) # applyTensorFunctional :: (LinearSpace u, (* ~ Scalar u) (Scalar (ZeroDim s))) => Bilinear (DualVector (ZeroDim s ⊗ u)) (ZeroDim s ⊗ u) (Scalar (ZeroDim s)) # applyTensorLinMap :: (LinearSpace u, TensorSpace w, (* ~ Scalar u) (Scalar (ZeroDim s)), (* ~ Scalar w) (Scalar (ZeroDim s))) => Bilinear ((ZeroDim s ⊗ u) +> w) (ZeroDim s ⊗ u) w #
Semimanifold (ZeroDim k)
Associated Types type Needle (ZeroDim k) :: * # type Interior (ZeroDim k) :: * # Methods (.+~^) :: Interior (ZeroDim k) -> Needle (ZeroDim k) -> ZeroDim k # fromInterior :: Interior (ZeroDim k) -> ZeroDim k # toInterior :: ZeroDim k -> Maybe (Interior (ZeroDim k)) # translateP :: Tagged * (ZeroDim k) (Interior (ZeroDim k) -> Needle (ZeroDim k) -> Interior (ZeroDim k)) # (.-~^) :: Interior (ZeroDim k) -> Needle (ZeroDim k) -> ZeroDim k # semimanifoldWitness :: SemimanifoldWitness (ZeroDim k) #
PseudoAffine (ZeroDim k)
Methods (.-~.) :: ZeroDim k -> ZeroDim k -> Maybe (Needle (ZeroDim k)) # (.-~!) :: ZeroDim k -> ZeroDim k -> Needle (ZeroDim k) # pseudoAffineWitness :: PseudoAffineWitness (ZeroDim k) #
Atlas (ZeroDim s) Source #
Associated Types type ChartIndex (ZeroDim s) :: * Source # Methods chartReferencePoint :: ChartIndex (ZeroDim s) -> ZeroDim s Source # interiorChartReferencePoint :: Functor p => p (ZeroDim s) -> ChartIndex (ZeroDim s) -> Interior (ZeroDim s) Source # lookupAtlas :: ZeroDim s -> ChartIndex (ZeroDim s) Source #
Geodesic (ZeroDim s) Source #
Methods geodesicBetween :: ZeroDim s -> ZeroDim s -> Maybe (D¹ -> ZeroDim s) Source # geodesicWitness :: GeodesicWitness (ZeroDim s) Source # middleBetween :: ZeroDim s -> ZeroDim s -> Maybe (ZeroDim s) Source #
NumPrime s => LocallyCoercible (V0 s) (ZeroDim s) Source #
Methods locallyTrivialDiffeomorphism :: V0 s -> ZeroDim s Source # coerceNeedle :: Functor p => p (V0 s, ZeroDim s) -> Needle (V0 s) -+> Needle (ZeroDim s) Source # coerceNeedle' :: Functor p => p (V0 s, ZeroDim s) -> Needle' (V0 s) -+> Needle' (ZeroDim s) Source # coerceNorm :: Functor p => p (V0 s, ZeroDim s) -> Metric (V0 s) -> Metric (ZeroDim s) Source # coerceVariance :: Functor p => p (V0 s, ZeroDim s) -> Metric' (V0 s) -> Metric' (ZeroDim s) Source # oppositeLocalCoercion :: CanonicalDiffeomorphism (ZeroDim s) (V0 s) Source # interiorLocalCoercion :: Functor p (->) (->) => p (V0 s, ZeroDim s) -> CanonicalDiffeomorphism (Interior (V0 s)) (Interior (ZeroDim s)) Source #
NumPrime s => LocallyCoercible (ZeroDim s) (V0 s) Source #
Methods locallyTrivialDiffeomorphism :: ZeroDim s -> V0 s Source # coerceNeedle :: Functor p => p (ZeroDim s, V0 s) -> Needle (ZeroDim s) -+> Needle (V0 s) Source # coerceNeedle' :: Functor p => p (ZeroDim s, V0 s) -> Needle' (ZeroDim s) -+> Needle' (V0 s) Source # coerceNorm :: Functor p => p (ZeroDim s, V0 s) -> Metric (ZeroDim s) -> Metric (V0 s) Source # coerceVariance :: Functor p => p (ZeroDim s, V0 s) -> Metric' (ZeroDim s) -> Metric' (V0 s) Source # oppositeLocalCoercion :: CanonicalDiffeomorphism (V0 s) (ZeroDim s) Source # interiorLocalCoercion :: Functor p (->) (->) => p (ZeroDim s, V0 s) -> CanonicalDiffeomorphism (Interior (ZeroDim s)) (Interior (V0 s)) Source #
NumPrime s => LocallyCoercible (ZeroDim s) (ZeroDim s) Source #
Methods locallyTrivialDiffeomorphism :: ZeroDim s -> ZeroDim s Source # coerceNeedle :: Functor p => p (ZeroDim s, ZeroDim s) -> Needle (ZeroDim s) -+> Needle (ZeroDim s) Source # coerceNeedle' :: Functor p => p (ZeroDim s, ZeroDim s) -> Needle' (ZeroDim s) -+> Needle' (ZeroDim s) Source # coerceNorm :: Functor p => p (ZeroDim s, ZeroDim s) -> Metric (ZeroDim s) -> Metric (ZeroDim s) Source # coerceVariance :: Functor p => p (ZeroDim s, ZeroDim s) -> Metric' (ZeroDim s) -> Metric' (ZeroDim s) Source # oppositeLocalCoercion :: CanonicalDiffeomorphism (ZeroDim s) (ZeroDim s) Source # interiorLocalCoercion :: Functor p (->) (->) => p (ZeroDim s, ZeroDim s) -> CanonicalDiffeomorphism (Interior (ZeroDim s)) (Interior (ZeroDim s)) Source #
type Scalar (ZeroDim s)
type Scalar (ZeroDim s) = s
type Basis (ZeroDim s)
type Basis (ZeroDim s) = Void
type Diff (ZeroDim s)
type Diff (ZeroDim s) = ZeroDim s
data SubBasis (ZeroDim s)
data SubBasis (ZeroDim s) = ZeroBasis
type DualVector (ZeroDim s)
type DualVector (ZeroDim s) = ZeroDim s
type Interior (ZeroDim k)
type Interior (ZeroDim k) = ZeroDim k
type Needle (ZeroDim k)
type Needle (ZeroDim k) = ZeroDim k
type ChartIndex (ZeroDim s) Source #
type ChartIndex (ZeroDim s) = ()
type TensorProduct (ZeroDim s) v
type TensorProduct (ZeroDim s) v = ZeroDim s

type ℝ = Double #

type ℝ⁰ = ZeroDim ℝ #

type ℝ¹ = V1 ℝ Source #

type ℝ² = V2 ℝ Source #

type ℝ³ = V3 ℝ Source #

type ℝ⁴ = V4 ℝ Source #

Hyperspheres

General form: Stiefel manifolds

newtype Stiefel1 v Source #

Constructors

Stiefel1
Fields getStiefel1N :: DualVector v

Instances

Show (DualVector v) => Show (Stiefel1 v) Source #
Methods showsPrec :: Int -> Stiefel1 v -> ShowS # show :: Stiefel1 v -> String # showList :: [Stiefel1 v] -> ShowS #
(Geodesic v, FiniteFreeSpace v, FiniteFreeSpace (DualVector v), LinearSpace v, (~) * (Scalar v) ℝ, Geodesic (DualVector v), InnerSpace (DualVector v)) => Geodesic (Stiefel1 v) Source #
Methods geodesicBetween :: Stiefel1 v -> Stiefel1 v -> Maybe (D¹ -> Stiefel1 v) Source # geodesicWitness :: GeodesicWitness (Stiefel1 v) Source # middleBetween :: Stiefel1 v -> Stiefel1 v -> Maybe (Stiefel1 v) Source #
type Interior (Stiefel1 v) #
type Interior (Stiefel1 v) = Stiefel1 v
type Needle (Stiefel1 v) #
type Needle (Stiefel1 v)

stiefel1Project Source #

Arguments

:: LinearSpace v
=> DualVector v	Must be nonzero.
-> Stiefel1 v

stiefel1Embed :: (HilbertSpace v, RealFloat (Scalar v)) => Stiefel1 v -> v Source #

Specific examples

class (PseudoAffine v, InnerSpace v, NaturallyEmbedded (UnitSphere v) (DualVector v)) => HasUnitSphere v where Source #

Associated Types

type UnitSphere v :: * Source #

Methods

stiefel :: UnitSphere v -> Stiefel1 v Source #

unstiefel :: Stiefel1 v -> UnitSphere v Source #

Instances

HasUnitSphere ℝ Source #
Associated Types type UnitSphere ℝ :: * Source # Methods stiefel :: UnitSphere ℝ -> Stiefel1 ℝ Source # unstiefel :: Stiefel1 ℝ -> UnitSphere ℝ Source #
HasUnitSphere ℝ³ Source #
Associated Types type UnitSphere ℝ³ :: * Source # Methods stiefel :: UnitSphere ℝ³ -> Stiefel1 ℝ³ Source # unstiefel :: Stiefel1 ℝ³ -> UnitSphere ℝ³ Source #
HasUnitSphere ℝ² Source #
Associated Types type UnitSphere ℝ² :: * Source # Methods stiefel :: UnitSphere ℝ² -> Stiefel1 ℝ² Source # unstiefel :: Stiefel1 ℝ² -> UnitSphere ℝ² Source #

data S⁰ :: * #

The zero-dimensional sphere is actually just two points. Implementation might therefore change to ℝ⁰ + ℝ⁰: the disjoint sum of two single-point spaces.

Constructors

PositiveHalfSphere
NegativeHalfSphere

Instances

Eq S⁰
Methods (==) :: S⁰ -> S⁰ -> Bool # (/=) :: S⁰ -> S⁰ -> Bool #
Show S⁰
Methods showsPrec :: Int -> S⁰ -> ShowS # show :: S⁰ -> String # showList :: [S⁰] -> ShowS #
Semimanifold S⁰
Associated Types type Needle S⁰ :: * # type Interior S⁰ :: * # Methods (.+~^) :: Interior S⁰ -> Needle S⁰ -> S⁰ # fromInterior :: Interior S⁰ -> S⁰ # toInterior :: S⁰ -> Maybe (Interior S⁰) # translateP :: Tagged * S⁰ (Interior S⁰ -> Needle S⁰ -> Interior S⁰) # (.-~^) :: Interior S⁰ -> Needle S⁰ -> S⁰ # semimanifoldWitness :: SemimanifoldWitness S⁰ #
PseudoAffine S⁰
Methods (.-~.) :: S⁰ -> S⁰ -> Maybe (Needle S⁰) # (.-~!) :: S⁰ -> S⁰ -> Needle S⁰ # pseudoAffineWitness :: PseudoAffineWitness S⁰ #
Atlas S⁰ Source #
Associated Types type ChartIndex S⁰ :: * Source # Methods chartReferencePoint :: ChartIndex S⁰ -> S⁰ Source # interiorChartReferencePoint :: Functor p => p S⁰ -> ChartIndex S⁰ -> Interior S⁰ Source # lookupAtlas :: S⁰ -> ChartIndex S⁰ Source #
Geodesic S⁰ Source #
Methods geodesicBetween :: S⁰ -> S⁰ -> Maybe (D¹ -> S⁰) Source # geodesicWitness :: GeodesicWitness S⁰ Source # middleBetween :: S⁰ -> S⁰ -> Maybe S⁰ Source #
type Interior S⁰
type Interior S⁰ = S⁰
type Needle S⁰
type Needle S⁰ = ZeroDim ℝ
type ChartIndex S⁰ Source #
type ChartIndex S⁰ = S⁰

newtype S¹ :: * #

The unit circle.

Constructors

S¹
Fields φParamS¹ :: Double Must be in range `[-π, π[`.

Instances

Show S¹
Methods showsPrec :: Int -> S¹ -> ShowS # show :: S¹ -> String # showList :: [S¹] -> ShowS #
Semimanifold S¹
Associated Types type Needle S¹ :: * # type Interior S¹ :: * # Methods (.+~^) :: Interior S¹ -> Needle S¹ -> S¹ # fromInterior :: Interior S¹ -> S¹ # toInterior :: S¹ -> Maybe (Interior S¹) # translateP :: Tagged * S¹ (Interior S¹ -> Needle S¹ -> Interior S¹) # (.-~^) :: Interior S¹ -> Needle S¹ -> S¹ # semimanifoldWitness :: SemimanifoldWitness S¹ #
PseudoAffine S¹
Methods (.-~.) :: S¹ -> S¹ -> Maybe (Needle S¹) # (.-~!) :: S¹ -> S¹ -> Needle S¹ # pseudoAffineWitness :: PseudoAffineWitness S¹ #
Atlas S¹ Source #
Associated Types type ChartIndex S¹ :: * Source # Methods chartReferencePoint :: ChartIndex S¹ -> S¹ Source # interiorChartReferencePoint :: Functor p => p S¹ -> ChartIndex S¹ -> Interior S¹ Source # lookupAtlas :: S¹ -> ChartIndex S¹ Source #
Geodesic S¹ Source #
Methods geodesicBetween :: S¹ -> S¹ -> Maybe (D¹ -> S¹) Source # geodesicWitness :: GeodesicWitness S¹ Source # middleBetween :: S¹ -> S¹ -> Maybe S¹ Source #
type Interior S¹
type Interior S¹ = S¹
type Needle S¹
type Needle S¹ = ℝ
type ChartIndex S¹ Source #
type ChartIndex S¹ = S⁰

data S² Source #

The ordinary unit sphere.

Constructors

S²
Fields ϑParamS² :: !Double Range `[0, π[`. φParamS² :: !Double Range `[-π, π[`.

Instances

Show S² Source #
Methods showsPrec :: Int -> S² -> ShowS # show :: S² -> String # showList :: [S²] -> ShowS #
Atlas S² Source #
Associated Types type ChartIndex S² :: * Source # Methods chartReferencePoint :: ChartIndex S² -> S² Source # interiorChartReferencePoint :: Functor p => p S² -> ChartIndex S² -> Interior S² Source # lookupAtlas :: S² -> ChartIndex S² Source #
type Interior S² #
type Interior S² = S²
type Needle S² #
type Needle S² = ℝ²
type ChartIndex S² Source #
type ChartIndex S² = S⁰

Projective spaces

type ℝP¹ = S¹ #

data ℝP² Source #

The two-dimensional real projective space, implemented as a unit disk with opposing points on the rim glued together.

Constructors

ℝP²
Fields rParamℝP² :: !Double Range `[0, 1]`. φParamℝP² :: !Double Range `[-π, π[`.

Instances

Show ℝP² Source #
Methods showsPrec :: Int -> ℝP² -> ShowS # show :: ℝP² -> String # showList :: [ℝP²] -> ShowS #
type Interior ℝP² #
type Interior ℝP² = ℝP²
type Needle ℝP² #
type Needle ℝP² = ℝ²

Intervals/disks/cones

newtype D¹ :: * #

The “one-dimensional disk” – really just the line segment between the two points -1 and 1 of 'S⁰', i.e. this is simply a closed interval.

Constructors

D¹
Fields xParamD¹ :: Double Range `[-1, 1]`.

Instances

Show D¹
Methods showsPrec :: Int -> D¹ -> ShowS # show :: D¹ -> String # showList :: [D¹] -> ShowS #
Semimanifold D¹
Associated Types type Needle D¹ :: * # type Interior D¹ :: * # Methods (.+~^) :: Interior D¹ -> Needle D¹ -> D¹ # fromInterior :: Interior D¹ -> D¹ # toInterior :: D¹ -> Maybe (Interior D¹) # translateP :: Tagged * D¹ (Interior D¹ -> Needle D¹ -> Interior D¹) # (.-~^) :: Interior D¹ -> Needle D¹ -> D¹ # semimanifoldWitness :: SemimanifoldWitness D¹ #
PseudoAffine D¹
Methods (.-~.) :: D¹ -> D¹ -> Maybe (Needle D¹) # (.-~!) :: D¹ -> D¹ -> Needle D¹ # pseudoAffineWitness :: PseudoAffineWitness D¹ #
IntervalLike D¹ Source #
Methods toClosedInterval :: D¹ -> D¹ Source #
type Interior D¹
type Interior D¹ = ℝ
type Needle D¹
type Needle D¹ = ℝ

data D² Source #

The standard, closed unit disk. Homeomorphic to the cone over 'S¹', but not in the the obvious, “flat” way. (And not at all, despite the identical ADT definition, to the projective space 'ℝP²'!)

Constructors

D²
Fields rParamD² :: !Double Range `[0, 1]`. φParamD² :: !Double Range `[-π, π[`.

Instances

Show D² Source #
Methods showsPrec :: Int -> D² -> ShowS # show :: D² -> String # showList :: [D²] -> ShowS #

type ℝay = Cℝay ℝ⁰ Source #

Better known as ℝ⁺ (which is not a legal Haskell name), the ray of positive numbers (including zero, i.e. closed on one end).

data CD¹ x Source #

A (closed) cone over a space x is the product of x with the closed interval 'D¹' of “heights”, except on its “tip”: here, x is smashed to a single point.

This construct becomes (homeomorphic-to-) an actual geometric cone (and to 'D²') in the special case x = 'S¹'.

Constructors

CD¹
Fields hParamCD¹ :: !Double Range `[0, 1]` pParamCD¹ :: !x Irrelevant at `h = 0`.

Instances

Show x => Show (CD¹ x) Source #
Methods showsPrec :: Int -> CD¹ x -> ShowS # show :: CD¹ x -> String # showList :: [CD¹ x] -> ShowS #
type Interior (CD¹ m) #
type Interior (CD¹ m)
type Needle (CD¹ m) #
type Needle (CD¹ m)

data Cℝay x Source #

An open cone is homeomorphic to a closed cone without the “lid”, i.e. without the “last copy” of x, at the far end of the height interval. Since that means the height does not include its supremum, it is actually more natural to express it as the entire real ray, hence the name.

Constructors

Cℝay
Fields hParamCℝay :: !Double Range `[0, ∞[` pParamCℝay :: !x Irrelevant at `h = 0`.

Instances

Show x => Show (Cℝay x) Source #
Methods showsPrec :: Int -> Cℝay x -> ShowS # show :: Cℝay x -> String # showList :: [Cℝay x] -> ShowS #
type Interior (Cℝay m) #
type Interior (Cℝay m)
type Needle (Cℝay m) #
type Needle (Cℝay m)

Affine subspaces

Lines

data Line x Source #

Constructors

Line
Fields lineHandle :: x lineDirection :: Stiefel1 (Needle' x)

lineAsPlaneIntersection :: forall x. (WithField ℝ Manifold x, FiniteDimensional (Needle' x)) => Line x -> [Cutplane x] Source #

Hyperplanes

data Cutplane x Source #

Oriented hyperplanes, naïvely generalised to PseudoAffine manifolds: Cutplane p w represents the set of all points q such that (q.-~.p) ^<.> w ≡ 0.

In vector spaces this is indeed a hyperplane; for general manifolds it should behave locally as a plane, globally as an (n−1)-dimensional submanifold.

Constructors

Cutplane
Fields sawHandle :: x cutNormal :: Stiefel1 (Needle x)

Instances

(Show x, Show (Needle' x)) => Show (Cutplane x) Source #
Methods showsPrec :: Int -> Cutplane x -> ShowS # show :: Cutplane x -> String # showList :: [Cutplane x] -> ShowS #

normalPlane Source #

Arguments

:: x	Some point lying in the desired plane.
-> Needle' x	Co-vector perpendicular to the plane. Must be nonzero.
-> Cutplane x

fathomCutDistance Source #

Arguments

:: (WithField ℝ PseudoAffine x, LinearSpace (Needle x))
=> Cutplane x	Hyperplane to measure the distance from.
-> Metric' x	Metric to use for measuring that distance. This can only be accurate if the metric is valid both around the cut-plane's `sawHandle`, and around the points you measure. (Strictly speaking, we would need parallel transport to ensure this).
-> x	Point to measure the distance to.
-> Maybe ℝ	A signed number, giving the distance from plane to point with indication on which side the point lies. `Nothing` if the point isn't reachable from the plane.

sideOfCut :: (WithField ℝ PseudoAffine x, LinearSpace (Needle x)) => Cutplane x -> x -> Maybe S⁰ Source #

cutPosBetween :: WithField ℝ Manifold x => Cutplane x -> (x, x) -> Maybe D¹ Source #

Linear mappings

data LinearMap s v w :: * -> * -> * -> * #

The tensor product between one space's dual space and another space is the space spanned by vector–dual-vector pairs, in bra-ket notation written as

m = ∑ |w⟩⟨v|

Any linear mapping can be written as such a (possibly infinite) sum. The TensorProduct data structure only stores the linear independent parts though; for simple finite-dimensional spaces this means e.g. LinearMap ℝ ℝ³ ℝ³ effectively boils down to an ordinary matrix type, namely an array of column-vectors |w⟩.

(The ⟨v| dual-vectors are then simply assumed to come from the canonical basis.)

For bigger spaces, the tensor product may be implemented in a more efficient sparse structure; this can be defined in the TensorSpace instance.

Instances

Num' s => EnhancedCat (->) (LinearMap s)
Methods arr :: (Object (LinearMap s) b, Object (LinearMap s) c, Object (->) b, Object (->) c) => LinearMap s b c -> b -> c #
(Show (SubBasis (DualVector u)), Show (SubBasis v)) => Show (SubBasis (LinearMap s u v))
Methods showsPrec :: Int -> SubBasis (LinearMap s u v) -> ShowS # show :: SubBasis (LinearMap s u v) -> String # showList :: [SubBasis (LinearMap s u v)] -> ShowS #
Num' s => Morphism (LinearMap s)
Methods first :: (ObjectPair (LinearMap s) b d, ObjectPair (LinearMap s) c d) => LinearMap s b c -> LinearMap s (b, d) (c, d) # second :: (ObjectPair (LinearMap s) d b, ObjectPair (LinearMap s) d c) => LinearMap s b c -> LinearMap s (d, b) (d, c) # (***) :: (ObjectPair (LinearMap s) b b', ObjectPair (LinearMap s) c c') => LinearMap s b c -> LinearMap s b' c' -> LinearMap s (b, b') (c, c') #
Num' s => PreArrow (LinearMap s)
Methods (&&&) :: (Object (LinearMap s) b, ObjectPair (LinearMap s) c c') => LinearMap s b c -> LinearMap s b c' -> LinearMap s b (c, c') # terminal :: Object (LinearMap s) b => LinearMap s b (UnitObject (LinearMap s)) # fst :: ObjectPair (LinearMap s) x y => LinearMap s (x, y) x # snd :: ObjectPair (LinearMap s) x y => LinearMap s (x, y) y #
Category (LinearMap s)
Associated Types type Object (LinearMap s :: * -> * -> *) o :: Constraint # Methods id :: Object (LinearMap s) a => LinearMap s a a # (.) :: (Object (LinearMap s) a, Object (LinearMap s) b, Object (LinearMap s) c) => LinearMap s b c -> LinearMap s a b -> LinearMap s a c #
Num' s => Cartesian (LinearMap s)
Associated Types type PairObjects (LinearMap s :: * -> * -> ) a b :: Constraint # type UnitObject (LinearMap s :: -> * -> ) :: # Methods swap :: (ObjectPair (LinearMap s) a b, ObjectPair (LinearMap s) b a) => LinearMap s (a, b) (b, a) # attachUnit :: ((* ~ u) (UnitObject (LinearMap s)), ObjectPair (LinearMap s) a u) => LinearMap s a (a, u) # detachUnit :: ((* ~ u) (UnitObject (LinearMap s)), ObjectPair (LinearMap s) a u) => LinearMap s (a, u) a # regroup :: (ObjectPair (LinearMap s) a b, ObjectPair (LinearMap s) b c, ObjectPair (LinearMap s) a (b, c), ObjectPair (LinearMap s) (a, b) c) => LinearMap s (a, (b, c)) ((a, b), c) # regroup' :: (ObjectPair (LinearMap s) a b, ObjectPair (LinearMap s) b c, ObjectPair (LinearMap s) a (b, c), ObjectPair (LinearMap s) (a, b) c) => LinearMap s ((a, b), c) (a, (b, c)) #
Num' s => EnhancedCat (LinearMap s) (LinearFunction s)
Methods arr :: (Object (LinearFunction s) b, Object (LinearFunction s) c, Object (LinearMap s) b, Object (LinearMap s) c) => LinearFunction s b c -> LinearMap s b c #
Num' s => EnhancedCat (LinearFunction s) (LinearMap s)
Methods arr :: (Object (LinearMap s) b, Object (LinearMap s) c, Object (LinearFunction s) b, Object (LinearFunction s) c) => LinearMap s b c -> LinearFunction s b c #
EnhancedCat (Affine s) (LinearMap s) #
Methods arr :: (Object (LinearMap s) b, Object (LinearMap s) c, Object (Affine s) b, Object (Affine s) c) => LinearMap s b c -> Affine s b c #
(Num' s, LinearSpace v, (~) * (Scalar v) s) => Monoidal (LinearMap s v) (LinearFunction s) (LinearFunction s)
Methods pureUnit :: LinearFunction s (UnitObject (LinearFunction s)) (LinearMap s v (UnitObject (LinearFunction s))) # fzipWith :: (ObjectPair (LinearFunction s) a b, Object (LinearFunction s) c, ObjectPair (LinearFunction s) (LinearMap s v a) (LinearMap s v b), Object (LinearFunction s) (LinearMap s v c)) => LinearFunction s (a, b) c -> LinearFunction s (LinearMap s v a, LinearMap s v b) (LinearMap s v c) #
(LinearSpace v, Num' s, (~) * (Scalar v) s) => Functor (LinearMap s v) (LinearFunction s) (LinearFunction s)
Methods fmap :: (Object (LinearFunction s) a, Object (LinearFunction s) (LinearMap s v a), Object (LinearFunction s) b, Object (LinearFunction s) (LinearMap s v b)) => LinearFunction s a b -> LinearFunction s (LinearMap s v a) (LinearMap s v b) #
(LinearSpace v, (~) * (Scalar v) s) => Functor (LinearMap s v) (Coercion ) (Coercion )
Methods fmap :: (Object (Coercion ) a, Object (Coercion ) (LinearMap s v a), Object (Coercion ) b, Object (Coercion ) (LinearMap s v b)) => Coercion * a b -> Coercion * (LinearMap s v a) (LinearMap s v b) #
(LinearSpace v, TensorSpace w, (~) * (Scalar v) s, (~) * (Scalar w) s) => AdditiveGroup (LinearMap s v w)
Methods zeroV :: LinearMap s v w # (^+^) :: LinearMap s v w -> LinearMap s v w -> LinearMap s v w # negateV :: LinearMap s v w -> LinearMap s v w # (^-^) :: LinearMap s v w -> LinearMap s v w -> LinearMap s v w #
(LinearSpace v, TensorSpace w, (~) * (Scalar v) s, (~) * (Scalar w) s) => VectorSpace (LinearMap s v w)
Associated Types type Scalar (LinearMap s v w) :: * # Methods (*^) :: Scalar (LinearMap s v w) -> LinearMap s v w -> LinearMap s v w #
(LinearSpace u, TensorSpace v, (~) * s (Scalar u), (~) * s (Scalar v)) => AffineSpace (LinearMap s u v)
Associated Types type Diff (LinearMap s u v) :: * # Methods (.-.) :: LinearMap s u v -> LinearMap s u v -> Diff (LinearMap s u v) # (.+^) :: LinearMap s u v -> Diff (LinearMap s u v) -> LinearMap s u v #
(LinearSpace u, SemiInner (DualVector u), SemiInner v, (~) * (Scalar u) s, (~) * (Scalar v) s) => SemiInner (LinearMap s u v)
Methods dualBasisCandidates :: [(Int, LinearMap s u v)] -> Forest (Int, DualVector (LinearMap s u v)) # tensorDualBasisCandidates :: (SemiInner w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => [(Int, LinearMap s u v ⊗ w)] -> Forest (Int, DualVector (LinearMap s u v ⊗ w)) # symTensorDualBasisCandidates :: [(Int, SymmetricTensor (Scalar (LinearMap s u v)) (LinearMap s u v))] -> Forest (Int, SymmetricTensor (Scalar (LinearMap s u v)) (DualVector (LinearMap s u v))) # symTensorTensorDualBasisCandidates :: (SemiInner w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => [(Int, SymmetricTensor (Scalar (LinearMap s u v)) (LinearMap s u v) ⊗ w)] -> Forest (Int, SymmetricTensor (Scalar (LinearMap s u v)) (LinearMap s u v) +> DualVector w) #
(LSpace u, FiniteDimensional (DualVector u), FiniteDimensional v, (~) * (Scalar u) s, (~) * (Scalar v) s, (~) * (Scalar (DualVector v)) s, Fractional' (Scalar v)) => FiniteDimensional (LinearMap s u v)
Associated Types data SubBasis (LinearMap s u v) :: * # Methods entireBasis :: SubBasis (LinearMap s u v) # enumerateSubBasis :: SubBasis (LinearMap s u v) -> [LinearMap s u v] # subbasisDimension :: SubBasis (LinearMap s u v) -> Int # decomposeLinMap :: (LSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v +> w) -> (SubBasis (LinearMap s u v), DList w) # decomposeLinMapWithin :: (LSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => SubBasis (LinearMap s u v) -> (LinearMap s u v +> w) -> Either (SubBasis (LinearMap s u v), DList w) (DList w) # recomposeSB :: SubBasis (LinearMap s u v) -> [Scalar (LinearMap s u v)] -> (LinearMap s u v, [Scalar (LinearMap s u v)]) # recomposeSBTensor :: (FiniteDimensional w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => SubBasis (LinearMap s u v) -> SubBasis w -> [Scalar (LinearMap s u v)] -> (LinearMap s u v ⊗ w, [Scalar (LinearMap s u v)]) # recomposeLinMap :: (LSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => SubBasis (LinearMap s u v) -> [w] -> (LinearMap s u v +> w, [w]) # recomposeContraLinMap :: (LinearSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v)), Functor f) => (f (Scalar w) -> w) -> f (DualVector (LinearMap s u v)) -> LinearMap s u v +> w # recomposeContraLinMapTensor :: (FiniteDimensional u, LinearSpace w, (* ~ Scalar u) (Scalar (LinearMap s u v)), (* ~ Scalar w) (Scalar (LinearMap s u v)), Functor f) => (f (Scalar w) -> w) -> f (LinearMap s u v +> DualVector u) -> (LinearMap s u v ⊗ u) +> w # uncanonicallyFromDual :: DualVector (LinearMap s u v) -+> LinearMap s u v # uncanonicallyToDual :: LinearMap s u v -+> DualVector (LinearMap s u v) #
(LinearSpace u, TensorSpace v, (~) * (Scalar u) s, (~) * (Scalar v) s) => TensorSpace (LinearMap s u v)
Associated Types type TensorProduct (LinearMap s u v) w :: * # Methods scalarSpaceWitness :: ScalarSpaceWitness (LinearMap s u v) # linearManifoldWitness :: LinearManifoldWitness (LinearMap s u v) # zeroTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => LinearMap s u v ⊗ w # toFlatTensor :: LinearMap s u v -+> (LinearMap s u v ⊗ Scalar (LinearMap s u v)) # fromFlatTensor :: (LinearMap s u v ⊗ Scalar (LinearMap s u v)) -+> LinearMap s u v # addTensors :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ w) -> (LinearMap s u v ⊗ w) -> LinearMap s u v ⊗ w # subtractTensors :: (TensorSpace (LinearMap s u v), TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ w) -> (LinearMap s u v ⊗ w) -> LinearMap s u v ⊗ w # scaleTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => Bilinear (Scalar (LinearMap s u v)) (LinearMap s u v ⊗ w) (LinearMap s u v ⊗ w) # negateTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ w) -+> (LinearMap s u v ⊗ w) # tensorProduct :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => Bilinear (LinearMap s u v) w (LinearMap s u v ⊗ w) # tensorProducts :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => [(LinearMap s u v, w)] -> LinearMap s u v ⊗ w # transposeTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ w) -+> (w ⊗ LinearMap s u v) # fmapTensor :: (TensorSpace w, TensorSpace x, (* ~ Scalar w) (Scalar (LinearMap s u v)), (* ~ Scalar x) (Scalar (LinearMap s u v))) => Bilinear (w -+> x) (LinearMap s u v ⊗ w) (LinearMap s u v ⊗ x) # fzipTensorWith :: (TensorSpace u, TensorSpace w, TensorSpace x, (* ~ Scalar u) (Scalar (LinearMap s u v)), (* ~ Scalar w) (Scalar (LinearMap s u v)), (* ~ Scalar x) (Scalar (LinearMap s u v))) => Bilinear ((w, x) -+> u) (LinearMap s u v ⊗ w, LinearMap s u v ⊗ x) (LinearMap s u v ⊗ u) # coerceFmapTensorProduct :: Functor p => p (LinearMap s u v) -> Coercion * a b -> Coercion * (TensorProduct (LinearMap s u v) a) (TensorProduct (LinearMap s u v) b) # wellDefinedVector :: LinearMap s u v -> Maybe (LinearMap s u v) # wellDefinedTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ w) -> Maybe (LinearMap s u v ⊗ w) #
(LinearSpace u, LinearSpace v, (~) * (Scalar u) s, (~) * (Scalar v) s) => LinearSpace (LinearMap s u v)
Associated Types type DualVector (LinearMap s u v) :: * # Methods dualSpaceWitness :: DualSpaceWitness (LinearMap s u v) # linearId :: LinearMap s u v +> LinearMap s u v # idTensor :: LinearMap s u v ⊗ DualVector (LinearMap s u v) # sampleLinearFunction :: (TensorSpace w, (* ~ Scalar (LinearMap s u v)) (Scalar w)) => (LinearMap s u v -+> w) -+> (LinearMap s u v +> w) # toLinearForm :: DualVector (LinearMap s u v) -+> (LinearMap s u v +> Scalar (LinearMap s u v)) # fromLinearForm :: (LinearMap s u v +> Scalar (LinearMap s u v)) -+> DualVector (LinearMap s u v) # coerceDoubleDual :: Coercion * (LinearMap s u v) (DualVector (DualVector (LinearMap s u v))) # trace :: (LinearMap s u v +> LinearMap s u v) -+> Scalar (LinearMap s u v) # contractTensorMap :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v +> (LinearMap s u v ⊗ w)) -+> w # contractMapTensor :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ (LinearMap s u v +> w)) -+> w # contractTensorFn :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v -+> (LinearMap s u v ⊗ w)) -+> w # contractLinearMapAgainst :: (LinearSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => Bilinear (LinearMap s u v +> w) (w -+> LinearMap s u v) (Scalar (LinearMap s u v)) # applyDualVector :: Bilinear (DualVector (LinearMap s u v)) (LinearMap s u v) (Scalar (LinearMap s u v)) # applyLinear :: (TensorSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => Bilinear (LinearMap s u v +> w) (LinearMap s u v) w # composeLinear :: (LinearSpace w, TensorSpace x, (* ~ Scalar w) (Scalar (LinearMap s u v)), (* ~ Scalar x) (Scalar (LinearMap s u v))) => Bilinear (w +> x) (LinearMap s u v +> w) (LinearMap s u v +> x) # tensorId :: (LinearSpace w, (* ~ Scalar w) (Scalar (LinearMap s u v))) => (LinearMap s u v ⊗ w) +> (LinearMap s u v ⊗ w) # applyTensorFunctional :: (LinearSpace u, (* ~ Scalar u) (Scalar (LinearMap s u v))) => Bilinear (DualVector (LinearMap s u v ⊗ u)) (LinearMap s u v ⊗ u) (Scalar (LinearMap s u v)) # applyTensorLinMap :: (LinearSpace u, TensorSpace w, (* ~ Scalar u) (Scalar (LinearMap s u v)), (* ~ Scalar w) (Scalar (LinearMap s u v))) => Bilinear ((LinearMap s u v ⊗ u) +> w) (LinearMap s u v ⊗ u) w #
(LinearSpace v, TensorSpace w, (~) * (Scalar v) s, (~) * (Scalar w) s) => Semimanifold (LinearMap s v w)
Associated Types type Needle (LinearMap s v w) :: * # type Interior (LinearMap s v w) :: * # Methods (.+~^) :: Interior (LinearMap s v w) -> Needle (LinearMap s v w) -> LinearMap s v w # fromInterior :: Interior (LinearMap s v w) -> LinearMap s v w # toInterior :: LinearMap s v w -> Maybe (Interior (LinearMap s v w)) # translateP :: Tagged * (LinearMap s v w) (Interior (LinearMap s v w) -> Needle (LinearMap s v w) -> Interior (LinearMap s v w)) # (.-~^) :: Interior (LinearMap s v w) -> Needle (LinearMap s v w) -> LinearMap s v w # semimanifoldWitness :: SemimanifoldWitness (LinearMap s v w) #
(LinearSpace v, TensorSpace w, (~) * (Scalar v) s, (~) * (Scalar w) s) => PseudoAffine (LinearMap s v w)
Methods (.-~.) :: LinearMap s v w -> LinearMap s v w -> Maybe (Needle (LinearMap s v w)) # (.-~!) :: LinearMap s v w -> LinearMap s v w -> Needle (LinearMap s v w) # pseudoAffineWitness :: PseudoAffineWitness (LinearMap s v w) #
(LinearSpace v, (~) * (Scalar v) s, TensorSpace w, (~) * (Scalar w) s) => Atlas (LinearMap s v w) Source #
Associated Types type ChartIndex (LinearMap s v w) :: * Source # Methods chartReferencePoint :: ChartIndex (LinearMap s v w) -> LinearMap s v w Source # interiorChartReferencePoint :: Functor p => p (LinearMap s v w) -> ChartIndex (LinearMap s v w) -> Interior (LinearMap s v w) Source # lookupAtlas :: LinearMap s v w -> ChartIndex (LinearMap s v w) Source #
(LinearSpace v, (~) * (Scalar v) ℝ, TensorSpace w, (~) * (Scalar w) ℝ) => Geodesic (LinearMap ℝ v w) Source #
Methods geodesicBetween :: LinearMap ℝ v w -> LinearMap ℝ v w -> Maybe (D¹ -> LinearMap ℝ v w) Source # geodesicWitness :: GeodesicWitness (LinearMap ℝ v w) Source # middleBetween :: LinearMap ℝ v w -> LinearMap ℝ v w -> Maybe (LinearMap ℝ v w) Source #
(HilbertSpace v, SemiInner v, FiniteDimensional v, LtdErrorShow v, (~) * (Scalar v) ℝ) => LtdErrorShow (LinearMap ℝ v (ℝ, ℝ)) Source #
Methods ltdErrorShowWitness :: LtdErrorShowWitness (LinearMap ℝ v (ℝ, ℝ)) showsPrecShade'_errorLtdC :: Int -> Shade' (LinearMap ℝ v (ℝ, ℝ)) -> ShowS prettyShowsPrecShade :: Int -> Shade (LinearMap ℝ v (ℝ, ℝ)) -> ShowS prettyShowsPrecShade' :: Int -> Shade' (LinearMap ℝ v (ℝ, ℝ)) -> ShowS Source #
(HilbertSpace v, SemiInner v, FiniteDimensional v, LtdErrorShow v, (~) * (Scalar v) ℝ) => LtdErrorShow (LinearMap ℝ v ℝ) Source #
Methods ltdErrorShowWitness :: LtdErrorShowWitness (LinearMap ℝ v ℝ) showsPrecShade'_errorLtdC :: Int -> Shade' (LinearMap ℝ v ℝ) -> ShowS prettyShowsPrecShade :: Int -> Shade (LinearMap ℝ v ℝ) -> ShowS prettyShowsPrecShade' :: Int -> Shade' (LinearMap ℝ v ℝ) -> ShowS Source #
(SimpleSpace a, SimpleSpace b, Refinable a, Refinable b, (~) * (Scalar a) ℝ, (~) * (Scalar b) ℝ, (~) * (Scalar (DualVector a)) ℝ, (~) * (Scalar (DualVector b)) ℝ, (~) * (Scalar (DualVector (DualVector a))) ℝ, (~) * (Scalar (DualVector (DualVector b))) ℝ) => Refinable (LinearMap ℝ a b) Source #
Methods debugView :: Maybe (DebugView (LinearMap ℝ a b)) subShade' :: Shade' (LinearMap ℝ a b) -> Shade' (LinearMap ℝ a b) -> Bool Source # refineShade' :: Shade' (LinearMap ℝ a b) -> Shade' (LinearMap ℝ a b) -> Maybe (Shade' (LinearMap ℝ a b)) Source # convolveMetric :: Functor p => p (LinearMap ℝ a b) -> Metric (LinearMap ℝ a b) -> Metric (LinearMap ℝ a b) -> Metric (LinearMap ℝ a b) Source # convolveShade' :: Shade' (LinearMap ℝ a b) -> Shade' (Needle (LinearMap ℝ a b)) -> Shade' (LinearMap ℝ a b) Source #
type UnitObject (LinearMap s)
type UnitObject (LinearMap s) = ZeroDim s
type Object (LinearMap s) v
type Object (LinearMap s) v = (LinearSpace v, (~) * (Scalar v) s)
type PairObjects (LinearMap s) a b
type PairObjects (LinearMap s) a b = ()
type Scalar (LinearMap s v w)
type Scalar (LinearMap s v w) = s
type Diff (LinearMap s u v)
type Diff (LinearMap s u v) = LinearMap s u v
data SubBasis (LinearMap s u v)
data SubBasis (LinearMap s u v) = LinMapBasis ~(SubBasis (DualVector u)) ~(SubBasis v)
type DualVector (LinearMap s u v)
type DualVector (LinearMap s u v) = Tensor s u (DualVector v)
type Interior (LinearMap s v w)
type Interior (LinearMap s v w) = LinearMap s v w
type Needle (LinearMap s v w)
type Needle (LinearMap s v w) = LinearMap s v w
type ChartIndex (LinearMap s v w) Source #
type ChartIndex (LinearMap s v w) = ()
type TensorProduct (LinearMap s u v) w
type TensorProduct (LinearMap s u v) w = TensorProduct (DualVector u) (Tensor s v w)

type LocalLinear x y = LinearMap (Scalar (Needle x)) (Needle x) (Needle y) Source #

Misc

type StiefelScalar s = (RealFloat s, Unbox s) Source #

Orphan instances

(LinearSpace v, FiniteFreeSpace v, FiniteFreeSpace (DualVector v), StiefelScalar (Scalar v)) => Semimanifold (Stiefel1 v) Source #
Associated Types type Needle (Stiefel1 v) :: * # type Interior (Stiefel1 v) :: * # Methods (.+~^) :: Interior (Stiefel1 v) -> Needle (Stiefel1 v) -> Stiefel1 v # fromInterior :: Interior (Stiefel1 v) -> Stiefel1 v # toInterior :: Stiefel1 v -> Maybe (Interior (Stiefel1 v)) # translateP :: Tagged * (Stiefel1 v) (Interior (Stiefel1 v) -> Needle (Stiefel1 v) -> Interior (Stiefel1 v)) # (.-~^) :: Interior (Stiefel1 v) -> Needle (Stiefel1 v) -> Stiefel1 v # semimanifoldWitness :: SemimanifoldWitness (Stiefel1 v) #
(LinearSpace v, FiniteFreeSpace v, FiniteFreeSpace (DualVector v), StiefelScalar (Scalar v)) => PseudoAffine (Stiefel1 v) Source #
Methods (.-~.) :: Stiefel1 v -> Stiefel1 v -> Maybe (Needle (Stiefel1 v)) # (.-~!) :: Stiefel1 v -> Stiefel1 v -> Needle (Stiefel1 v) # pseudoAffineWitness :: PseudoAffineWitness (Stiefel1 v) #