Abstract

Utility functions for arrays.

Synopsis

open import "/prelude/zip"
val length [n] 't : [n]t -> i64
val null [n] 't : [n]t -> bool
val head [n] 't : (x: [n]t) -> t
val last [n] 't : (x: [n]t) -> t
val tail [n] 't : (x: [n]t) -> ?[n₃].[n₃]t
val init [n] 't : (x: [n]t) -> ?[n₅].[n₅]t
val take [n] 't : (i: i64) -> (x: [n]t) -> [i]t
val drop [n] 't : (i: i64) -> (x: [n]t) -> ?[n₂].[n₂]t
val split [n] 't : (i: i64) -> (xs: [n]t) -> ([i]t, []t)
val reverse [n] 't : (x: [n]t) -> [n]t
val ++ [n] [m] 't : (xs: [n]t) -> (ys: [m]t) -> *[]t
val concat [n] [m] 't : (xs: [n]t) -> (ys: [m]t) -> *[]t
val concat_to [n] [m] 't : (k: i64) -> (xs: [n]t) -> (ys: [m]t) -> *[k]t
val rotate [n] 't : (r: i64) -> (xs: [n]t) -> [n]t
val iota : (n: i64) -> *[n]i64
val indices [n] 't : [n]t -> *[n]i64
val replicate 't : (n: i64) -> (x: t) -> *[n]t
val copy 't : (a: t) -> *t
val flatten [n] [m] 't : (xs: [n][m]t) -> []t
val flatten_to [n] [m] 't : (l: i64) -> (xs: [n][m]t) -> [l]t
val flatten_3d [n] [m] [l] 't : (xs: [n][m][l]t) -> []t
val flatten_4d [n] [m] [l] [k] 't : (xs: [n][m][l][k]t) -> []t
val unflatten [p] 't : (n: i64) -> (m: i64) -> (xs: [p]t) -> [n][m]t
val unflatten_3d [p] 't : (n: i64) -> (m: i64) -> (l: i64) -> (xs: [p]t) -> [n][m][l]t
val unflatten_4d [p] 't : (n: i64) -> (m: i64) -> (l: i64) -> (k: i64) -> (xs: [p]t) -> [n][m][l][k]t
val transpose [n] [m] 't : (a: [n][m]t) -> [m][n]t
val and [n] : (xs: [n]bool) -> bool
val or [n] : (xs: [n]bool) -> bool
val foldl [n] 'a 'b : (f: a -> b -> a) -> (acc: a) -> (bs: [n]b) -> a
val foldr [n] 'a 'b : (f: b -> a -> a) -> (acc: a) -> (bs: [n]b) -> a
val tabulate 'a : (n: i64) -> (f: i64 -> a) -> *[n]a
val tabulate_2d 'a : (n: i64) -> (m: i64) -> (f: i64 -> i64 -> a) -> *[n][m]a
val tabulate_3d 'a : (n: i64) -> (m: i64) -> (o: i64) -> (f: i64 -> i64 -> i64 -> a) -> *[n][m][o]a

Description

val length [n] 't: [n]t -> i64

The size of the outer dimension of an array.

Complexity: O(1).

val null [n] 't: [n]t -> bool

Is the array empty?

Complexity: O(1).

val head [n] 't: (x: [n]t) -> t

The first element of the array.

Complexity: O(1).

val last [n] 't: (x: [n]t) -> t

The last element of the array.

Complexity: O(1).

val tail [n] 't: (x: [n]t) -> ?[n₃].[n₃]t

Everything but the first element of the array.

Complexity: O(1).

val init [n] 't: (x: [n]t) -> ?[n₅].[n₅]t

Everything but the last element of the array.

Complexity: O(1).

val take [n] 't: (i: i64) -> (x: [n]t) -> [i]t

Take some number of elements from the head of the array.

Complexity: O(1).

val drop [n] 't: (i: i64) -> (x: [n]t) -> ?[n₂].[n₂]t

Remove some number of elements from the head of the array.

Complexity: O(1).

val split [n] 't: (i: i64) -> (xs: [n]t) -> ([i]t, []t)

Split an array at a given position.

Complexity: O(1).

val reverse [n] 't: (x: [n]t) -> [n]t

Return the elements of the array in reverse order.

Complexity: O(1).

val ++ [n] [m] 't: (xs: [n]t) -> (ys: [m]t) -> *[]t

Concatenate two arrays. Warning: never try to perform a reduction with this operator; it will not work.

Work: O(n).

Span: O(1).

val concat [n] [m] 't: (xs: [n]t) -> (ys: [m]t) -> *[]t

An old-fashioned way of saying ++.

val concat_to [n] [m] 't: (k: i64) -> (xs: [n]t) -> (ys: [m]t) -> *[k]t

Concatenation where the result has a predetermined size. If the provided size is wrong, the function will fail with a run-time error.

val rotate [n] 't: (r: i64) -> (xs: [n]t) -> [n]t

Rotate an array some number of elements to the left. A negative rotation amount is also supported.

For example, if b==rotate r a, then b[x] = a[x+r].

Complexity: O(1).

val iota: (n: i64) -> *[n]i64

Construct an array of consecutive integers of the given length, starting at 0.

Work: O(n).

Span: O(1).

val indices [n] 't: [n]t -> *[n]i64

Construct an array comprising valid indexes into some other array, starting at 0.

Work: O(n).

Span: O(1).

val replicate 't: (n: i64) -> (x: t) -> *[n]t

Construct an array of the given length containing the given value.

Work: O(n).

Span: O(1).

val copy 't: (a: t) -> *t

Copy a value. The result will not alias anything.

Work: O(n).

Span: O(1).

val flatten [n] [m] 't: (xs: [n][m]t) -> []t

Combines the outer two dimensions of an array.

Complexity: O(1).

val flatten_to [n] [m] 't: (l: i64) -> (xs: [n][m]t) -> [l]t

Like flatten, but where the final size is known. Fails at runtime if the provided size is wrong.

val flatten_3d [n] [m] [l] 't: (xs: [n][m][l]t) -> []t

Like flatten, but on the outer three dimensions of an array.

val flatten_4d [n] [m] [l] [k] 't: (xs: [n][m][l][k]t) -> []t

Like flatten, but on the outer four dimensions of an array.

val unflatten [p] 't: (n: i64) -> (m: i64) -> (xs: [p]t) -> [n][m]t

Splits the outer dimension of an array in two.

Complexity: O(1).

val unflatten_3d [p] 't: (n: i64) -> (m: i64) -> (l: i64) -> (xs: [p]t) -> [n][m][l]t

Like unflatten, but produces three dimensions.

val unflatten_4d [p] 't: (n: i64) -> (m: i64) -> (l: i64) -> (k: i64) -> (xs: [p]t) -> [n][m][l][k]t

Like unflatten, but produces four dimensions.

val transpose [n] [m] 't: (a: [n][m]t) -> [m][n]t

Transpose an array.

Complexity: O(1).

val and [n]: (xs: [n]bool) -> bool

True if all of the input elements are true. Produces true on an empty array.

Work: O(n).

Span: O(log(n)).

val or [n]: (xs: [n]bool) -> bool

True if any of the input elements are true. Produces false on an empty array.

Work: O(n).

Span: O(log(n)).

val foldl [n] 'a 'b: (f: a -> b -> a) -> (acc: a) -> (bs: [n]b) -> a

Perform a sequential left-fold of an array.

Work: O(n ✕ W(f))).

Span: O(n ✕ S(f)).

val foldr [n] 'a 'b: (f: b -> a -> a) -> (acc: a) -> (bs: [n]b) -> a

Perform a sequential right-fold of an array.

Work: O(n ✕ W(f))).

Span: O(n ✕ S(f)).

val tabulate 'a: (n: i64) -> (f: i64 -> a) -> *[n]a

Create a value for each point in a one-dimensional index space.

Work: O(n ✕ W(f))

Span: O(S(f))

val tabulate_2d 'a: (n: i64) -> (m: i64) -> (f: i64 -> i64 -> a) -> *[n][m]a

Create a value for each point in a two-dimensional index space.

Work: O(n ✕ W(f))

Span: O(S(f))

val tabulate_3d 'a: (n: i64) -> (m: i64) -> (o: i64) -> (f: i64 -> i64 -> i64 -> a) -> *[n][m][o]a

Create a value for each point in a three-dimensional index space.

Work: O(n ✕ W(f))

Span: O(S(f))