# Difference between revisions of "Library for vectors"

From HaskellWiki

(Small thing for playing with vectors.) |
m (Added vmag_sqr) |
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Line 15: | Line 15: | ||

vdot :: Vector v => v -> v -> Scalar |
vdot :: Vector v => v -> v -> Scalar |
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vdot v0 v1 = vfold (+) 0 $ vzip (*) v0 v1 |
vdot v0 v1 = vfold (+) 0 $ vzip (*) v0 v1 |
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+ | |||

+ | vmag_sqr :: Vector v => v -> Scalar |
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+ | vmag_sqr v = v `vdot` v |
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vmag :: Vector v => v -> Scalar |
vmag :: Vector v => v -> Scalar |
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− | vmag |
+ | vmag = sqrt . vmag_sqr |

vscale :: Vector v => Scalar -> v -> v |
vscale :: Vector v => Scalar -> v -> v |

## Latest revision as of 14:10, 18 April 2007

Most people just use `(Int,Int)`

or similar for a 2-vector. However, if you find yourself wanting to do lots of vector arithmetic, that becomes annoying quite quickly. Below is what I use; feel free to adapt it to your needs.

```
module Vector where
type Scalar = Double
class Vector v where
vmap :: (Scalar -> Scalar) -> v -> v
vzip :: (Scalar -> Scalar -> Scalar) -> v -> v -> v
vfold :: (x -> Scalar -> x) -> x -> v -> x
vdot :: Vector v => v -> v -> Scalar
vdot v0 v1 = vfold (+) 0 $ vzip (*) v0 v1
vmag_sqr :: Vector v => v -> Scalar
vmag_sqr v = v `vdot` v
vmag :: Vector v => v -> Scalar
vmag = sqrt . vmag_sqr
vscale :: Vector v => Scalar -> v -> v
vscale s = vmap (s*)
vunit :: Vector v => v -> v
vunit v =
if vmag v == 0
then v
else vscale (1 / vmag v) v
data Vector2 = Vector2 {v2x, v2y :: Scalar} deriving (Eq)
instance Show Vector2 where
show (Vector2 x y) = "<" ++ (show x) ++ ", " ++ (show y) ++ ">"
instance Vector Vector2 where
vmap f (Vector2 x y) = Vector2 (f x) (f y)
vfold f i (Vector2 x y) = (i `f` x) `f` y
vzip f (Vector2 x0 y0) (Vector2 x1 y1) = Vector2 (f x0 x1) (f y0 y1)
instance Num Vector2 where
(+) = vzip (+)
(-) = vzip (-)
(*) = vzip (*)
negate = vmap negate
fromInteger s = Vector2 (fromInteger s) (fromInteger s)
instance Fractional Vector2 where
(/) = vzip (/)
fromDouble s = Vector2 s s
data Vector3 = Vector3 {v3x, v3y, v3z :: Scalar} deriving (Eq)
instance Show Vector3 where
show (Vector3 x y z) = "<" ++ (show x) ++ ", " ++ (show y) ++ ", " ++ (show z) ++ ">"
instance Vector Vector3 where
vmap f (Vector3 x y z) = Vector3 (f x) (f y) (f z)
vfold f i (Vector3 x y z) = ((i `f` x) `f` y) `f` z
vzip f (Vector3 x0 y0 z0) (Vector3 x1 y1 z1) = Vector3 (f x0 x1) (f y0 y1) (f z0 z1)
instance Num Vector3 where
(+) = vzip (+)
(-) = vzip (-)
(*) = vzip (*)
negate = vmap negate
fromInteger s = Vector3 (fromInteger s) (fromInteger s) (fromInteger s)
instance Fractional Vector3 where
(/) = vzip (/)
fromDouble s = Vector3 s s s
v3cross (Vector3 x0 y0 z0) (Vector3 x1 y1 z1) = Vector3 (y0*z1 - y1*z0) (x0*z1 - x1*z0) (x0*y1 - x1*y0)
```

PS. If anybody knows a way to make every instance of `Vector`

automatically become an instance of `Num`

, etc., let me know!