Safe Haskell	None
Language	Haskell2010

Data.Geometry.Vector

Synopsis

module Data.Geometry.Vector.VectorFamily
module Linear.Vector
data C (n :: Nat) = C
class Additive (Diff p) => Affine (p :: * -> *) where
- type Diff (p :: * -> *) :: * -> *
qdA :: (Affine p, Foldable (Diff p), Num a) => p a -> p a -> a
distanceA :: (Floating a, Foldable (Diff p), Affine p) => p a -> p a -> a
dot :: (Metric f, Num a) => f a -> f a -> a
norm :: (Metric f, Floating a) => f a -> a
signorm :: (Metric f, Floating a) => f a -> f a
isScalarMultipleOf :: (Eq r, Fractional r, Arity d) => Vector d r -> Vector d r -> Bool
scalarMultiple :: (Eq r, Fractional r, Arity d) => Vector d r -> Vector d r -> Maybe r
replicate :: Vector v a => a -> v a
imap :: (Vector v a, Vector v b) => (Int -> a -> b) -> v a -> v b

Documentation

module Data.Geometry.Vector.VectorFamily

module Linear.Vector

data C (n :: Nat) Source #

A proxy which can be used for the coordinates.

Constructors

C

Instances

Eq (C n) Source #
Instance details Defined in Data.Geometry.Vector.VectorFixed Methods (==) :: C n -> C n -> Bool # (/=) :: C n -> C n -> Bool #
Ord (C n) Source #
Instance details Defined in Data.Geometry.Vector.VectorFixed Methods compare :: C n -> C n -> Ordering # (<) :: C n -> C n -> Bool # (<=) :: C n -> C n -> Bool # (>) :: C n -> C n -> Bool # (>=) :: C n -> C n -> Bool # max :: C n -> C n -> C n # min :: C n -> C n -> C n #
Read (C n) Source #
Instance details Defined in Data.Geometry.Vector.VectorFixed Methods readsPrec :: Int -> ReadS (C n) # readList :: ReadS [C n] # readPrec :: ReadPrec (C n) # readListPrec :: ReadPrec [C n] #
Show (C n) Source #
Instance details Defined in Data.Geometry.Vector.VectorFixed Methods showsPrec :: Int -> C n -> ShowS # show :: C n -> String # showList :: [C n] -> ShowS #

class Additive (Diff p) => Affine (p :: * -> *) where #

An affine space is roughly a vector space in which we have forgotten or at least pretend to have forgotten the origin.

a .+^ (b .-. a)  =  b@
(a .+^ u) .+^ v  =  a .+^ (u ^+^ v)@
(a .-. b) ^+^ v  =  (a .+^ v) .-. q@

Minimal complete definition

(.-.), (.+^)

Associated Types

type Diff (p :: * -> *) :: * -> * #

Methods

(.-.) :: Num a => p a -> p a -> Diff p a infixl 6 #

Get the difference between two points as a vector offset.

(.+^) :: Num a => p a -> Diff p a -> p a infixl 6 #

Add a vector offset to a point.

(.-^) :: Num a => p a -> Diff p a -> p a infixl 6 #

Subtract a vector offset from a point.

Instances

Affine []
Instance details Defined in Linear.Affine Associated Types type Diff [] :: * -> * # Methods (.-.) :: Num a => [a] -> [a] -> Diff [] a # (.+^) :: Num a => [a] -> Diff [] a -> [a] # (.-^) :: Num a => [a] -> Diff [] a -> [a] #
Affine Maybe
Instance details Defined in Linear.Affine Associated Types type Diff Maybe :: * -> * # Methods (.-.) :: Num a => Maybe a -> Maybe a -> Diff Maybe a # (.+^) :: Num a => Maybe a -> Diff Maybe a -> Maybe a # (.-^) :: Num a => Maybe a -> Diff Maybe a -> Maybe a #
Affine Complex
Instance details Defined in Linear.Affine Associated Types type Diff Complex :: * -> * # Methods (.-.) :: Num a => Complex a -> Complex a -> Diff Complex a # (.+^) :: Num a => Complex a -> Diff Complex a -> Complex a # (.-^) :: Num a => Complex a -> Diff Complex a -> Complex a #
Affine ZipList
Instance details Defined in Linear.Affine Associated Types type Diff ZipList :: * -> * # Methods (.-.) :: Num a => ZipList a -> ZipList a -> Diff ZipList a # (.+^) :: Num a => ZipList a -> Diff ZipList a -> ZipList a # (.-^) :: Num a => ZipList a -> Diff ZipList a -> ZipList a #
Affine Identity
Instance details Defined in Linear.Affine Associated Types type Diff Identity :: * -> * # Methods (.-.) :: Num a => Identity a -> Identity a -> Diff Identity a # (.+^) :: Num a => Identity a -> Diff Identity a -> Identity a # (.-^) :: Num a => Identity a -> Diff Identity a -> Identity a #
Affine IntMap
Instance details Defined in Linear.Affine Associated Types type Diff IntMap :: * -> * # Methods (.-.) :: Num a => IntMap a -> IntMap a -> Diff IntMap a # (.+^) :: Num a => IntMap a -> Diff IntMap a -> IntMap a # (.-^) :: Num a => IntMap a -> Diff IntMap a -> IntMap a #
Affine Vector
Instance details Defined in Linear.Affine Associated Types type Diff Vector :: * -> * # Methods (.-.) :: Num a => Vector a -> Vector a -> Diff Vector a # (.+^) :: Num a => Vector a -> Diff Vector a -> Vector a # (.-^) :: Num a => Vector a -> Diff Vector a -> Vector a #
Affine Plucker
Instance details Defined in Linear.Affine Associated Types type Diff Plucker :: * -> * # Methods (.-.) :: Num a => Plucker a -> Plucker a -> Diff Plucker a # (.+^) :: Num a => Plucker a -> Diff Plucker a -> Plucker a # (.-^) :: Num a => Plucker a -> Diff Plucker a -> Plucker a #
Affine Quaternion
Instance details Defined in Linear.Affine Associated Types type Diff Quaternion :: * -> * # Methods (.-.) :: Num a => Quaternion a -> Quaternion a -> Diff Quaternion a # (.+^) :: Num a => Quaternion a -> Diff Quaternion a -> Quaternion a # (.-^) :: Num a => Quaternion a -> Diff Quaternion a -> Quaternion a #
Affine V0
Instance details Defined in Linear.Affine Associated Types type Diff V0 :: * -> * # Methods (.-.) :: Num a => V0 a -> V0 a -> Diff V0 a # (.+^) :: Num a => V0 a -> Diff V0 a -> V0 a # (.-^) :: Num a => V0 a -> Diff V0 a -> V0 a #
Affine V4
Instance details Defined in Linear.Affine Associated Types type Diff V4 :: * -> * # Methods (.-.) :: Num a => V4 a -> V4 a -> Diff V4 a # (.+^) :: Num a => V4 a -> Diff V4 a -> V4 a # (.-^) :: Num a => V4 a -> Diff V4 a -> V4 a #
Affine V3
Instance details Defined in Linear.Affine Associated Types type Diff V3 :: * -> * # Methods (.-.) :: Num a => V3 a -> V3 a -> Diff V3 a # (.+^) :: Num a => V3 a -> Diff V3 a -> V3 a # (.-^) :: Num a => V3 a -> Diff V3 a -> V3 a #
Affine V2
Instance details Defined in Linear.Affine Associated Types type Diff V2 :: * -> * # Methods (.-.) :: Num a => V2 a -> V2 a -> Diff V2 a # (.+^) :: Num a => V2 a -> Diff V2 a -> V2 a # (.-^) :: Num a => V2 a -> Diff V2 a -> V2 a #
Affine V1
Instance details Defined in Linear.Affine Associated Types type Diff V1 :: * -> * # Methods (.-.) :: Num a => V1 a -> V1 a -> Diff V1 a # (.+^) :: Num a => V1 a -> Diff V1 a -> V1 a # (.-^) :: Num a => V1 a -> Diff V1 a -> V1 a #
(Eq k, Hashable k) => Affine (HashMap k)
Instance details Defined in Linear.Affine Associated Types type Diff (HashMap k) :: * -> * # Methods (.-.) :: Num a => HashMap k a -> HashMap k a -> Diff (HashMap k) a # (.+^) :: Num a => HashMap k a -> Diff (HashMap k) a -> HashMap k a # (.-^) :: Num a => HashMap k a -> Diff (HashMap k) a -> HashMap k a #
Ord k => Affine (Map k)
Instance details Defined in Linear.Affine Associated Types type Diff (Map k) :: * -> * # Methods (.-.) :: Num a => Map k a -> Map k a -> Diff (Map k) a # (.+^) :: Num a => Map k a -> Diff (Map k) a -> Map k a # (.-^) :: Num a => Map k a -> Diff (Map k) a -> Map k a #
Additive f => Affine (Point f)
Instance details Defined in Linear.Affine Associated Types type Diff (Point f) :: * -> * # Methods (.-.) :: Num a => Point f a -> Point f a -> Diff (Point f) a # (.+^) :: Num a => Point f a -> Diff (Point f) a -> Point f a # (.-^) :: Num a => Point f a -> Diff (Point f) a -> Point f a #
Arity d => Affine (Vector d) #
Instance details Defined in Data.Geometry.Vector.VectorFixed Associated Types type Diff (Vector d) :: * -> * # Methods (.-.) :: Num a => Vector d a -> Vector d a -> Diff (Vector d) a # (.+^) :: Num a => Vector d a -> Diff (Vector d) a -> Vector d a # (.-^) :: Num a => Vector d a -> Diff (Vector d) a -> Vector d a #
ImplicitArity d => Affine (VectorFamily d) #
Instance details Defined in Data.Geometry.Vector.VectorFamilyPeano Associated Types type Diff (VectorFamily d) :: * -> * # Methods (.-.) :: Num a => VectorFamily d a -> VectorFamily d a -> Diff (VectorFamily d) a # (.+^) :: Num a => VectorFamily d a -> Diff (VectorFamily d) a -> VectorFamily d a # (.-^) :: Num a => VectorFamily d a -> Diff (VectorFamily d) a -> VectorFamily d a #
Arity d => Affine (Vector d) #
Instance details Defined in Data.Geometry.Vector.VectorFamily Associated Types type Diff (Vector d) :: * -> * # Methods (.-.) :: Num a => Vector d a -> Vector d a -> Diff (Vector d) a # (.+^) :: Num a => Vector d a -> Diff (Vector d) a -> Vector d a # (.-^) :: Num a => Vector d a -> Diff (Vector d) a -> Vector d a #
Arity d => Affine (Point d) #
Instance details Defined in Data.Geometry.Point Associated Types type Diff (Point d) :: * -> * # Methods (.-.) :: Num a => Point d a -> Point d a -> Diff (Point d) a # (.+^) :: Num a => Point d a -> Diff (Point d) a -> Point d a # (.-^) :: Num a => Point d a -> Diff (Point d) a -> Point d a #
Dim n => Affine (V n)
Instance details Defined in Linear.Affine Associated Types type Diff (V n) :: * -> * # Methods (.-.) :: Num a => V n a -> V n a -> Diff (V n) a # (.+^) :: Num a => V n a -> Diff (V n) a -> V n a # (.-^) :: Num a => V n a -> Diff (V n) a -> V n a #
Affine ((->) b :: * -> *)
Instance details Defined in Linear.Affine Associated Types type Diff ((->) b) :: * -> * # Methods (.-.) :: Num a => (b -> a) -> (b -> a) -> Diff ((->) b) a # (.+^) :: Num a => (b -> a) -> Diff ((->) b) a -> b -> a # (.-^) :: Num a => (b -> a) -> Diff ((->) b) a -> b -> a #

qdA :: (Affine p, Foldable (Diff p), Num a) => p a -> p a -> a #

Compute the quadrance of the difference (the square of the distance)

distanceA :: (Floating a, Foldable (Diff p), Affine p) => p a -> p a -> a #

Distance between two points in an affine space

dot :: (Metric f, Num a) => f a -> f a -> a #

Compute the inner product of two vectors or (equivalently) convert a vector f a into a covector f a -> a.

>>> V2 1 2 `dot` V2 3 4
11

norm :: (Metric f, Floating a) => f a -> a #

Compute the norm of a vector in a metric space

signorm :: (Metric f, Floating a) => f a -> f a #

Convert a non-zero vector to unit vector.

isScalarMultipleOf :: (Eq r, Fractional r, Arity d) => Vector d r -> Vector d r -> Bool Source #

Test if v is a scalar multiple of u.

>>> Vector2 1 1 `isScalarMultipleOf` Vector2 10 10
True
>>> Vector2 1 1 `isScalarMultipleOf` Vector2 10 1
False
>>> Vector2 1 1 `isScalarMultipleOf` Vector2 11.1 11.1
True
>>> Vector2 1 1 `isScalarMultipleOf` Vector2 11.1 11.2
False
>>> Vector2 2 1 `isScalarMultipleOf` Vector2 11.1 11.2
False
>>> Vector2 2 1 `isScalarMultipleOf` Vector2 4 2
True
>>> Vector2 2 1 `isScalarMultipleOf` Vector2 4 0
False

scalarMultiple :: (Eq r, Fractional r, Arity d) => Vector d r -> Vector d r -> Maybe r Source #

Get the scalar labmda s.t. v = lambda * u (if it exists)

replicate :: Vector v a => a -> v a #

Replicate value n times.

Examples:

>>> import Data.Vector.Fixed.Boxed (Vec2)
>>> replicate 1 :: Vec2 Int
fromList [1,1]

>>> replicate 2 :: (Double,Double,Double)
(2.0,2.0,2.0)

>>> import Data.Vector.Fixed.Boxed (Vec4)
>>> replicate "foo" :: Vec4 String
fromList ["foo","foo","foo","foo"]

imap :: (Vector v a, Vector v b) => (Int -> a -> b) -> v a -> v b #

Apply function to every element of the vector and its index.