Module Stdlib.Seq

Sequences.

A sequence of type 'a Seq.t can be thought of as a delayed list, that is, a list whose elements are computed only when they are demanded by a consumer. This allows sequences to be produced and transformed lazily (one element at a time) rather than eagerly (all elements at once). This also allows constructing conceptually infinite sequences.

The type 'a Seq.t is defined as a synonym for unit -> 'a Seq.node. This is a function type: therefore, it is opaque. The consumer can query a sequence in order to request the next element (if there is one), but cannot otherwise inspect the sequence in any way.

Because it is opaque, the type 'a Seq.t does not reveal whether a sequence is:

It also does not reveal whether the elements of the sequence are:

It is up to the programmer to keep these distinctions in mind so as to understand the time and space requirements of sequences.

For the sake of simplicity, most of the documentation that follows is written under the implicit assumption that the sequences at hand are persistent. We normally do not point out when or how many times each function is invoked, because that would be too verbose. For instance, in the description of map, we write: "if xs is the sequence x0; x1; ... then map f xs is the sequence f x0; f x1; ...". If we wished to be more explicit, we could point out that the transformation takes place on demand: that is, the elements of map f xs are computed only when they are demanded. In other words, the definition let ys = map f xs terminates immediately and does not invoke f. The function call f x0 takes place only when the first element of ys is demanded, via the function call ys(). Furthermore, calling ys() twice causes f x0 to be called twice as well. If one wishes for f to be applied at most once to each element of xs, even in scenarios where ys is queried more than once, then one should use let ys = memoize (map f xs).

As a general rule, the functions that build sequences, such as map, filter, scan, take, etc., produce sequences whose elements are computed only on demand. The functions that eagerly consume sequences, such as is_empty, find, length, iter, fold_left, etc., are the functions that force computation to take place.

When possible, we recommend using sequences rather than dispensers (functions of type unit -> 'a option that produce elements upon demand). Whereas sequences can be persistent or ephemeral, dispensers are always ephemeral, and are typically more difficult to work with than sequences. Two conversion functions, to_dispenser and of_dispenser, are provided.

type t('a) = unit => node('a);

A sequence xs of type 'a t is a delayed list of elements of type 'a. Such a sequence is queried by performing a function application xs(). This function application returns a node, allowing the caller to determine whether the sequence is empty or nonempty, and in the latter case, to obtain its head and tail.

and node(+'a) =
  1. | Nil
  2. | Cons('a, t('a))
;

A node is either Nil, which means that the sequence is empty, or Cons (x, xs), which means that x is the first element of the sequence and that xs is the remainder of the sequence.

Consuming sequences

The functions in this section consume their argument, a sequence, either partially or completely:

Similarly, among the functions that consume two sequences, one can distinguish two groups:

The functions that consume two sequences can be applied to two sequences of distinct lengths: in that case, the excess elements in the longer sequence are ignored. (It may be the case that one excess element is demanded, even though this element is not used.)

None of the functions in this section is lazy. These functions are consumers: they force some computation to take place.

let is_empty: t('a) => bool;

is_empty xs determines whether the sequence xs is empty.

It is recommended that the sequence xs be persistent. Indeed, is_empty xs demands the head of the sequence xs, so, if xs is ephemeral, it may be the case that xs cannot be used any more after this call has taken place.

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let uncons: t('a) => option(('a, t('a)));

If xs is empty, then uncons xs is None.

If xs is nonempty, then uncons xs is Some (x, ys) where x is the head of the sequence and ys its tail.

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let length: t('a) => int;

length xs is the length of the sequence xs.

The sequence xs must be finite.

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let iter: ('a => unit) => t('a) => unit;

iter f xs invokes f x successively for every element x of the sequence xs, from left to right.

It terminates only if the sequence xs is finite.

let fold_left: ('acc => 'a => 'acc) => 'acc => t('a) => 'acc;

fold_left f _ xs invokes f _ x successively for every element x of the sequence xs, from left to right.

An accumulator of type 'a is threaded through the calls to f.

It terminates only if the sequence xs is finite.

let iteri: (int => 'a => unit) => t('a) => unit;

iteri f xs invokes f i x successively for every element x located at index i in the sequence xs.

It terminates only if the sequence xs is finite.

iteri f xs is equivalent to iter (fun (i, x) -> f i x) (zip (ints 0) xs).

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let fold_lefti: ('acc => int => 'a => 'acc) => 'acc => t('a) => 'acc;

fold_lefti f _ xs invokes f _ i x successively for every element x located at index i of the sequence xs.

An accumulator of type 'b is threaded through the calls to f.

It terminates only if the sequence xs is finite.

fold_lefti f accu xs is equivalent to fold_left (fun accu (i, x) -> f accu i x) accu (zip (ints 0) xs).

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let for_all: ('a => bool) => t('a) => bool;

for_all p xs determines whether all elements x of the sequence xs satisfy p x.

The sequence xs must be finite.

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let exists: ('a => bool) => t('a) => bool;

exists xs p determines whether at least one element x of the sequence xs satisfies p x.

The sequence xs must be finite.

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let find: ('a => bool) => t('a) => option('a);

find p xs returns Some x, where x is the first element of the sequence xs that satisfies p x, if there is such an element.

It returns None if there is no such element.

The sequence xs must be finite.

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let find_index: ('a => bool) => t('a) => option(int);

find_index p xs returns Some i, where i is the index of the first element of the sequence xs that satisfies p x, if there is such an element.

It returns None if there is no such element.

The sequence xs must be finite.

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let find_map: ('a => option('b)) => t('a) => option('b);

find_map f xs returns Some y, where x is the first element of the sequence xs such that f x = Some _, if there is such an element, and where y is defined by f x = Some y.

It returns None if there is no such element.

The sequence xs must be finite.

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let find_mapi: (int => 'a => option('b)) => t('a) => option('b);

Same as find_map, but the predicate is applied to the index of the element as first argument (counting from 0), and the element itself as second argument.

The sequence xs must be finite.

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let iter2: ('a => 'b => unit) => t('a) => t('b) => unit;

iter2 f xs ys invokes f x y successively for every pair (x, y) of elements drawn synchronously from the sequences xs and ys.

If the sequences xs and ys have different lengths, then iteration stops as soon as one sequence is exhausted; the excess elements in the other sequence are ignored.

Iteration terminates only if at least one of the sequences xs and ys is finite.

iter2 f xs ys is equivalent to iter (fun (x, y) -> f x y) (zip xs ys).

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let fold_left2: ('acc => 'a => 'b => 'acc) => 'acc => t('a) => t('b) => 'acc;

fold_left2 f _ xs ys invokes f _ x y successively for every pair (x, y) of elements drawn synchronously from the sequences xs and ys.

An accumulator of type 'a is threaded through the calls to f.

If the sequences xs and ys have different lengths, then iteration stops as soon as one sequence is exhausted; the excess elements in the other sequence are ignored.

Iteration terminates only if at least one of the sequences xs and ys is finite.

fold_left2 f accu xs ys is equivalent to fold_left (fun accu (x, y) -> f accu x y) (zip xs ys).

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let for_all2: ('a => 'b => bool) => t('a) => t('b) => bool;

for_all2 p xs ys determines whether all pairs (x, y) of elements drawn synchronously from the sequences xs and ys satisfy p x y.

If the sequences xs and ys have different lengths, then iteration stops as soon as one sequence is exhausted; the excess elements in the other sequence are ignored. In particular, if xs or ys is empty, then for_all2 p xs ys is true. This is where for_all2 and equal differ: equal eq xs ys can be true only if xs and ys have the same length.

At least one of the sequences xs and ys must be finite.

for_all2 p xs ys is equivalent to for_all (fun b -> b) (map2 p xs ys).

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let exists2: ('a => 'b => bool) => t('a) => t('b) => bool;

exists2 p xs ys determines whether some pair (x, y) of elements drawn synchronously from the sequences xs and ys satisfies p x y.

If the sequences xs and ys have different lengths, then iteration must stop as soon as one sequence is exhausted; the excess elements in the other sequence are ignored.

At least one of the sequences xs and ys must be finite.

exists2 p xs ys is equivalent to exists (fun b -> b) (map2 p xs ys).

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let equal: ('a => 'b => bool) => t('a) => t('b) => bool;

Provided the function eq defines an equality on elements, equal eq xs ys determines whether the sequences xs and ys are pointwise equal.

At least one of the sequences xs and ys must be finite.

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let compare: ('a => 'b => int) => t('a) => t('b) => int;

Provided the function cmp defines a preorder on elements, compare cmp xs ys compares the sequences xs and ys according to the lexicographic preorder.

For more details on comparison functions, see Array.sort.

At least one of the sequences xs and ys must be finite.

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Constructing sequences

The functions in this section are lazy: that is, they return sequences whose elements are computed only when demanded.

let empty: t('a);

empty is the empty sequence. It has no elements. Its length is 0.

let return: 'a => t('a);

return x is the sequence whose sole element is x. Its length is 1.

let cons: 'a => t('a) => t('a);

cons x xs is the sequence that begins with the element x, followed with the sequence xs.

Writing cons (f()) xs causes the function call f() to take place immediately. For this call to be delayed until the sequence is queried, one must instead write (fun () -> Cons(f(), xs)).

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let init: int => (int => 'a) => t('a);

init n f is the sequence f 0; f 1; ...; f (n-1).

n must be nonnegative.

If desired, the infinite sequence f 0; f 1; ... can be defined as map f (ints 0).

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let unfold: ('b => option(('a, 'b))) => 'b => t('a);

unfold constructs a sequence out of a step function and an initial state.

If f u is None then unfold f u is the empty sequence. If f u is Some (x, u') then unfold f u is the nonempty sequence cons x (unfold f u').

For example, unfold (function [] -> None | h :: t -> Some (h, t)) l is equivalent to List.to_seq l.

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let repeat: 'a => t('a);

repeat x is the infinite sequence where the element x is repeated indefinitely.

repeat x is equivalent to cycle (return x).

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let forever: (unit => 'a) => t('a);

forever f is an infinite sequence where every element is produced (on demand) by the function call f().

For instance, forever Random.bool is an infinite sequence of random bits.

forever f is equivalent to map f (repeat ()).

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let cycle: t('a) => t('a);

cycle xs is the infinite sequence that consists of an infinite number of repetitions of the sequence xs.

If xs is an empty sequence, then cycle xs is empty as well.

Consuming (a prefix of) the sequence cycle xs once can cause the sequence xs to be consumed more than once. Therefore, xs must be persistent.

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let iterate: ('a => 'a) => 'a => t('a);

iterate f x is the infinite sequence whose elements are x, f x, f (f x), and so on.

In other words, it is the orbit of the function f, starting at x.

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Transforming sequences

The functions in this section are lazy: that is, they return sequences whose elements are computed only when demanded.

let map: ('a => 'b) => t('a) => t('b);

map f xs is the image of the sequence xs through the transformation f.

If xs is the sequence x0; x1; ... then map f xs is the sequence f x0; f x1; ....

let mapi: (int => 'a => 'b) => t('a) => t('b);

mapi is analogous to map, but applies the function f to an index and an element.

mapi f xs is equivalent to map2 f (ints 0) xs.

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let filter: ('a => bool) => t('a) => t('a);

filter p xs is the sequence of the elements x of xs that satisfy p x.

In other words, filter p xs is the sequence xs, deprived of the elements x such that p x is false.

let filter_map: ('a => option('b)) => t('a) => t('b);

filter_map f xs is the sequence of the elements y such that f x = Some y, where x ranges over xs.

filter_map f xs is equivalent to map Option.get (filter Option.is_some (map f xs)).

let scan: ('b => 'a => 'b) => 'b => t('a) => t('b);

If xs is a sequence [x0; x1; x2; ...], then scan f a0 xs is a sequence of accumulators [a0; a1; a2; ...] where a1 is f a0 x0, a2 is f a1 x1, and so on.

Thus, scan f a0 xs is conceptually related to fold_left f a0 xs. However, instead of performing an eager iteration and immediately returning the final accumulator, it returns a sequence of accumulators.

For instance, scan (+) 0 transforms a sequence of integers into the sequence of its partial sums.

If xs has length n then scan f a0 xs has length n+1.

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let take: int => t('a) => t('a);

take n xs is the sequence of the first n elements of xs.

If xs has fewer than n elements, then take n xs is equivalent to xs.

n must be nonnegative.

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let drop: int => t('a) => t('a);

drop n xs is the sequence xs, deprived of its first n elements.

If xs has fewer than n elements, then drop n xs is empty.

n must be nonnegative.

drop is lazy: the first n+1 elements of the sequence xs are demanded only when the first element of drop n xs is demanded. For this reason, drop 1 xs is not equivalent to tail xs, which queries xs immediately.

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let take_while: ('a => bool) => t('a) => t('a);

take_while p xs is the longest prefix of the sequence xs where every element x satisfies p x.

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let drop_while: ('a => bool) => t('a) => t('a);

drop_while p xs is the sequence xs, deprived of the prefix take_while p xs.

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let group: ('a => 'a => bool) => t('a) => t(t('a));

Provided the function eq defines an equality on elements, group eq xs is the sequence of the maximal runs of adjacent duplicate elements of the sequence xs.

Every element of group eq xs is a nonempty sequence of equal elements.

The concatenation concat (group eq xs) is equal to xs.

Consuming group eq xs, and consuming the sequences that it contains, can cause xs to be consumed more than once. Therefore, xs must be persistent.

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let memoize: t('a) => t('a);

The sequence memoize xs has the same elements as the sequence xs.

Regardless of whether xs is ephemeral or persistent, memoize xs is persistent: even if it is queried several times, xs is queried at most once.

The construction of the sequence memoize xs internally relies on suspensions provided by the module Lazy. These suspensions are not thread-safe. Therefore, the sequence memoize xs must not be queried by multiple threads concurrently.

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exception Forced_twice;

This exception is raised when a sequence returned by once (or a suffix of it) is queried more than once.

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let once: t('a) => t('a);

The sequence once xs has the same elements as the sequence xs.

Regardless of whether xs is ephemeral or persistent, once xs is an ephemeral sequence: it can be queried at most once. If it (or a suffix of it) is queried more than once, then the exception Forced_twice is raised. This can be useful, while debugging or testing, to ensure that a sequence is consumed at most once.

  • raises Forced_twice

    if once xs, or a suffix of it, is queried more than once.

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let transpose: t(t('a)) => t(t('a));

If xss is a matrix (a sequence of rows), then transpose xss is the sequence of the columns of the matrix xss.

The rows of the matrix xss are not required to have the same length.

The matrix xss is not required to be finite (in either direction).

The matrix xss must be persistent.

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Combining sequences

let append: t('a) => t('a) => t('a);

append xs ys is the concatenation of the sequences xs and ys.

Its elements are the elements of xs, followed by the elements of ys.

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let concat: t(t('a)) => t('a);

If xss is a sequence of sequences, then concat xss is its concatenation.

If xss is the sequence xs0; xs1; ... then concat xss is the sequence xs0 @ xs1 @ ....

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let flat_map: ('a => t('b)) => t('a) => t('b);

flat_map f xs is equivalent to concat (map f xs).

let concat_map: ('a => t('b)) => t('a) => t('b);

concat_map f xs is equivalent to concat (map f xs).

concat_map is an alias for flat_map.

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let zip: t('a) => t('b) => t(('a, 'b));

zip xs ys is the sequence of pairs (x, y) drawn synchronously from the sequences xs and ys.

If the sequences xs and ys have different lengths, then the sequence ends as soon as one sequence is exhausted; the excess elements in the other sequence are ignored.

zip xs ys is equivalent to map2 (fun a b -> (a, b)) xs ys.

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let map2: ('a => 'b => 'c) => t('a) => t('b) => t('c);

map2 f xs ys is the sequence of the elements f x y, where the pairs (x, y) are drawn synchronously from the sequences xs and ys.

If the sequences xs and ys have different lengths, then the sequence ends as soon as one sequence is exhausted; the excess elements in the other sequence are ignored.

map2 f xs ys is equivalent to map (fun (x, y) -> f x y) (zip xs ys).

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let interleave: t('a) => t('a) => t('a);

interleave xs ys is the sequence that begins with the first element of xs, continues with the first element of ys, and so on.

When one of the sequences xs and ys is exhausted, interleave xs ys continues with the rest of the other sequence.

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let sorted_merge: ('a => 'a => int) => t('a) => t('a) => t('a);

If the sequences xs and ys are sorted according to the total preorder cmp, then sorted_merge cmp xs ys is the sorted sequence obtained by merging the sequences xs and ys.

For more details on comparison functions, see Array.sort.

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let product: t('a) => t('b) => t(('a, 'b));

product xs ys is the Cartesian product of the sequences xs and ys.

For every element x of xs and for every element y of ys, the pair (x, y) appears once as an element of product xs ys.

The order in which the pairs appear is unspecified.

The sequences xs and ys are not required to be finite.

The sequences xs and ys must be persistent.

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let map_product: ('a => 'b => 'c) => t('a) => t('b) => t('c);

The sequence map_product f xs ys is the image through f of the Cartesian product of the sequences xs and ys.

For every element x of xs and for every element y of ys, the element f x y appears once as an element of map_product f xs ys.

The order in which these elements appear is unspecified.

The sequences xs and ys are not required to be finite.

The sequences xs and ys must be persistent.

map_product f xs ys is equivalent to map (fun (x, y) -> f x y) (product xs ys).

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Splitting a sequence into two sequences

let unzip: t(('a, 'b)) => (t('a), t('b));

unzip transforms a sequence of pairs into a pair of sequences.

unzip xs is equivalent to (map fst xs, map snd xs).

Querying either of the sequences returned by unzip xs causes xs to be queried. Therefore, querying both of them causes xs to be queried twice. Thus, xs must be persistent and cheap. If that is not the case, use unzip (memoize xs).

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let split: t(('a, 'b)) => (t('a), t('b));

split is an alias for unzip.

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let partition_map: ('a => Either.t('b, 'c)) => t('a) => (t('b), t('c));

partition_map f xs returns a pair of sequences (ys, zs), where:

  • ys is the sequence of the elements y such that f x = Left y, where x ranges over xs;
  • zs is the sequence of the elements z such that f x = Right z, where x ranges over xs.

partition_map f xs is equivalent to a pair of filter_map Either.find_left (map f xs) and filter_map Either.find_right (map f xs).

Querying either of the sequences returned by partition_map f xs causes xs to be queried. Therefore, querying both of them causes xs to be queried twice. Thus, xs must be persistent and cheap. If that is not the case, use partition_map f (memoize xs).

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let partition: ('a => bool) => t('a) => (t('a), t('a));

partition p xs returns a pair of the subsequence of the elements of xs that satisfy p and the subsequence of the elements of xs that do not satisfy p.

partition p xs is equivalent to filter p xs, filter (fun x -> not (p x)) xs.

Consuming both of the sequences returned by partition p xs causes xs to be consumed twice and causes the function f to be applied twice to each element of the list. Therefore, f should be pure and cheap. Furthermore, xs should be persistent and cheap. If that is not the case, use partition p (memoize xs).

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Converting between sequences and dispensers

A dispenser is a representation of a sequence as a function of type unit -> 'a option. Every time this function is invoked, it returns the next element of the sequence. When there are no more elements, it returns None. A dispenser has mutable internal state, therefore is ephemeral: the sequence that it represents can be consumed at most once.

let of_dispenser: (unit => option('a)) => t('a);

of_dispenser it is the sequence of the elements produced by the dispenser it. It is an ephemeral sequence: it can be consumed at most once. If a persistent sequence is needed, use memoize (of_dispenser it).

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let to_dispenser: t('a) => unit => option('a);

to_dispenser xs is a fresh dispenser on the sequence xs.

This dispenser has mutable internal state, which is not protected by a lock; so, it must not be used by several threads concurrently.

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Sequences of integers

let ints: int => t(int);

ints i is the infinite sequence of the integers beginning at i and counting up.

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