vector-sized-1.0.4.0: Size tagged vectors

Safe HaskellNone
LanguageHaskell2010

Data.Vector.Mutable.Sized

Contents

Description

This module re-exports the functionality in Sized specialized to Mutable

Functions returning a vector determine the size from the type context unless they have a ' suffix in which case they take an explicit Proxy argument.

Functions where the resultant vector size is not know until compile time are not exported.

Synopsis

Documentation

type MVector = MVector MVector Source #

Vector specialized to use Mutable

Accessors

Length information

length :: forall n s a. KnownNat n => MVector n s a -> Int Source #

O(1) Yield the length of the mutable vector as an Int.

length' :: forall n s a. MVector n s a -> Proxy n Source #

O(1) Yield the length of the mutable vector as a Proxy.

null :: forall n s a. KnownNat n => MVector n s a -> Bool Source #

O(1) Check whether the mutable vector is empty

Extracting subvectors

slice Source #

Arguments

:: (KnownNat i, KnownNat n) 
=> p i

starting index

-> MVector ((i + n) + k) s a 
-> MVector n s a 

O(1) Yield a slice of the mutable vector without copying it with an inferred length argument.

slice' Source #

Arguments

:: (KnownNat i, KnownNat n) 
=> p i

starting index

-> p n

length

-> MVector ((i + n) + k) s a 
-> MVector n s a 

O(1) Yield a slice of the mutable vector without copying it with an explicit length argument.

init :: forall n s a. MVector (n + 1) s a -> MVector n s a Source #

O(1) Yield all but the last element of a non-empty mutable vector without copying.

tail :: forall n s a. MVector (1 + n) s a -> MVector n s a Source #

O(1) Yield all but the first element of a non-empty mutable vector without copying.

take :: forall n k s a. KnownNat n => MVector (n + k) s a -> MVector n s a Source #

O(1) Yield the first n elements. The resultant vector always contains this many elements. The length of the resultant vector is inferred from the type.

take' :: forall n k s a p. KnownNat n => p n -> MVector (n + k) s a -> MVector n s a Source #

O(1) Yield the first n elements. The resultant vector always contains this many elements. The length of the resultant vector is given explicitly as a Proxy argument.

drop :: forall n k s a. KnownNat n => MVector (n + k) s a -> MVector k s a Source #

O(1) Yield all but the the first n elements. The given vector must contain at least this many elements The length of the resultant vector is inferred from the type.

drop' :: forall n k s a p. KnownNat n => p n -> MVector (n + k) s a -> MVector k s a Source #

O(1) Yield all but the the first n elements. The given vector must contain at least this many elements The length of the resultant vector is givel explicitly as a Proxy argument.

splitAt :: forall n m s a. KnownNat n => MVector (n + m) s a -> (MVector n s a, MVector m s a) Source #

O(1) Yield the first n elements paired with the remainder without copying. The lengths of the resultant vector are inferred from the type.

splitAt' :: forall n m s a p. KnownNat n => p n -> MVector (n + m) s a -> (MVector n s a, MVector m s a) Source #

O(1) Yield the first n elements paired with the remainder without copying. The length of the first resultant vector is passed explicitly as a Proxy argument.

Overlaps

overlaps :: forall n k s a. MVector n s a -> MVector k s a -> Bool Source #

O(1) Yield all but the the first n elements. The given vector must contain at least this many elements The length of the resultant vector is inferred from the type.

Construction

Initialisation

new :: forall n m a. (KnownNat n, PrimMonad m) => m (MVector n (PrimState m) a) Source #

Create a mutable vector where the length is inferred from the type.

unsafeNew :: forall n m a. (KnownNat n, PrimMonad m) => m (MVector n (PrimState m) a) Source #

Create a mutable vector where the length is inferred from the type. The memory is not initialized.

replicate :: forall n m a. (KnownNat n, PrimMonad m) => a -> m (MVector n (PrimState m) a) Source #

Create a mutable vector where the length is inferred from the type and fill it with an initial value.

replicate' :: forall n m a p. (KnownNat n, PrimMonad m) => p n -> a -> m (MVector n (PrimState m) a) Source #

Create a mutable vector where the length is given explicitly as a Proxy argument and fill it with an initial value.

replicateM :: forall n m a. (KnownNat n, PrimMonad m) => m a -> m (MVector n (PrimState m) a) Source #

Create a mutable vector where the length is inferred from the type and fill it with values produced by repeatedly executing the monadic action.

replicateM' :: forall n m a p. (KnownNat n, PrimMonad m) => p n -> m a -> m (MVector n (PrimState m) a) Source #

Create a mutable vector where the length is given explicitly as a Proxy argument and fill it with values produced by repeatedly executing the monadic action.

clone :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> m (MVector n (PrimState m) a) Source #

Create a copy of a mutable vector.

Growing

grow :: forall n k m a p. (KnownNat k, PrimMonad m) => p k -> MVector n (PrimState m) a -> m (MVector (n + k) (PrimState m) a) Source #

Grow a mutable vector by an amount given explicitly as a Proxy argument.

growFront :: forall n k m a p. (KnownNat k, PrimMonad m) => p k -> MVector n (PrimState m) a -> m (MVector (n + k) (PrimState m) a) Source #

Grow a mutable vector (from the front) by an amount given explicitly as a Proxy argument.

Restricting memory usage

clear :: PrimMonad m => MVector n (PrimState m) a -> m () Source #

Reset all elements of the vector to some undefined value, clearing all references to external objects.

Accessing individual elements

read :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Finite n -> m a Source #

O(1) Yield the element at a given type-safe position using Finite.

read' :: forall n k a m p. (KnownNat k, PrimMonad m) => MVector ((n + k) + 1) (PrimState m) a -> p k -> m a Source #

O(1) Yield the element at a given type-safe position using Proxy.

write :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Finite n -> a -> m () Source #

O(1) Replace the element at a given type-safe position using Finite.

write' :: forall n k a m p. (KnownNat k, PrimMonad m) => MVector ((n + k) + 1) (PrimState m) a -> p k -> a -> m () Source #

O(1) Replace the element at a given type-safe position using Proxy.

modify :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> (a -> a) -> Finite n -> m () Source #

O(1) Modify the element at a given type-safe position using Finite.

modify' :: forall n k a m p. (KnownNat k, PrimMonad m) => MVector ((n + k) + 1) (PrimState m) a -> (a -> a) -> p k -> m () Source #

O(1) Modify the element at a given type-safe position using Proxy.

swap :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Finite n -> Finite n -> m () Source #

O(1) Swap the elements at a given type-safe position using Finites.

exchange :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Finite n -> a -> m a Source #

O(1) Replace the element at a given type-safe position and return the old element, using Finite.

exchange' :: forall n k a m p. (KnownNat k, PrimMonad m) => MVector ((n + k) + 1) (PrimState m) a -> p k -> a -> m a Source #

O(1) Replace the element at a given type-safe position and return the old element, using Finite.

unsafeRead :: forall n a m. PrimMonad m => MVector n (PrimState m) a -> Int -> m a Source #

O(1) Yield the element at a given Int position without bounds checking.

unsafeWrite :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Int -> a -> m () Source #

O(1) Replace the element at a given Int position without bounds checking.

unsafeModify :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> (a -> a) -> Int -> m () Source #

O(1) Modify the element at a given Int position without bounds checking.

unsafeSwap :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Int -> Int -> m () Source #

O(1) Swap the elements at a given Int position without bounds checking.

unsafeExchange :: forall n m a. PrimMonad m => MVector n (PrimState m) a -> Int -> a -> m a Source #

O(1) Replace the element at a given Int position and return the old element. No bounds checks are performed.

Modifying vectors

nextPermutation :: forall n e m. (Ord e, PrimMonad m) => MVector n (PrimState m) e -> m Bool Source #

Compute the next (lexicographically) permutation of a given vector in-place. Returns False when the input is the last permutation.

Filling and copying

set :: PrimMonad m => MVector n (PrimState m) a -> a -> m () Source #

Set all elements of the vector to the given value.

copy Source #

Arguments

:: PrimMonad m 
=> MVector n (PrimState m) a

target

-> MVector n (PrimState m) a

source

-> m () 

Copy a vector. The two vectors may not overlap.

move Source #

Arguments

:: PrimMonad m 
=> MVector n (PrimState m) a

target

-> MVector n (PrimState m) a

source

-> m () 

Move the contents of a vector. If the two vectors do not overlap, this is equivalent to copy. Otherwise, the copying is performed as if the source vector were copied to a temporary vector and then the temporary vector was copied to the target vector.

unsafeCopy Source #

Arguments

:: PrimMonad m 
=> MVector n (PrimState m) a

target

-> MVector n (PrimState m) a

source

-> m () 

Copy a vector. The two vectors may not overlap. This is not checked.

Conversions

Unsized Mutable Vectors

toSized :: forall n a s. KnownNat n => MVector s a -> Maybe (MVector n s a) Source #

Convert a MVector into a MVector if it has the correct size, otherwise return Nothing.

Note that this does no copying; the returned MVector is a reference to the exact same vector in memory as the given one, and any modifications to it are also reflected in the given MVector.

withSized :: forall s a r. MVector s a -> (forall n. KnownNat n => MVector n s a -> r) -> r Source #

Takes a MVector and returns a continuation providing a MVector with a size parameter n that is determined at runtime based on the length of the input vector.

Essentially converts a MVector into a MVector with the correct size parameter n.

Note that this does no copying; the returned MVector is a reference to the exact same vector in memory as the given one, and any modifications to it are also reflected in the given MVector.

fromSized :: MVector n s a -> MVector s a Source #

Convert a MVector into a MVector.

Note that this does no copying; the returned MVector is a reference to the exact same vector in memory as the given one, and any modifications to it are also reflected in the given MVector.