Library
Module
Module type
Parameter
Class
Class type
Simple and Efficient Iterators.
The iterators are designed to allow easy transfer (mappings) between data structures, without defining n^2
conversions between the n
types. The implementation relies on the assumption that an iterator can be iterated on as many times as needed; this choice allows for high performance of many combinators. However, for transient iterators, the persistent
function is provided, storing elements of a transient iterator in memory; the iterator can then be used several times (See further).
Note that some combinators also return iterators (e.g. group
). The transformation is computed on the fly every time one iterates over the resulting iterator. If a transformation performs heavy computation, persistent
can also be used as intermediate storage.
Most functions are lazy, i.e. they do not actually use their arguments until their result is iterated on. For instance, if one calls map
on an iterator, one gets a new iterator, but nothing else happens until this new iterator is used (by folding or iterating on it).
If an iterator is built from an iteration function that is repeatable (i.e. calling it several times always iterates on the same set of elements, for instance List.iter or Map.iter), then the resulting t
object is also repeatable. For one-time iter functions such as iteration on a file descriptor or a Seq
, the persistent
function can be used to iterate and store elements in a memory structure; the result is an iterator that iterates on the elements of this memory structure, cheaply and repeatably.
An iterator of values of type 'a
. If you give it a function 'a -> unit
it will be applied to every element of the iterator successively.
type +'a iter = 'a t
val from_iter : (('a -> unit) -> unit) -> 'a t
Build an iterator from a iter function
val from_labelled_iter : (f:('a -> unit) -> unit) -> 'a t
Build an iterator from a labelled iter function
val from_fun : (unit -> 'a option) -> 'a t
Call the function repeatedly until it returns None. This iterator is transient, use persistent
if needed!
val empty : 'a t
Empty iterator. It contains no element.
val singleton : 'a -> 'a t
Singleton iterator, with exactly one element.
val doubleton : 'a -> 'a -> 'a t
Iterator with exactly two elements
val init : (int -> 'a) -> 'a t
init f
is the infinite iterator f 0; f 1; f 2; …
.
cons x l
yields x
, then yields from l
. Same as append (singleton x) l
.
Caution: it is advised not to build long iterators out of cons
, because it's inefficient. Each additional cons x i
adds one layer of function call per item traversed in i
.
val repeat : 'a -> 'a t
Infinite iterator of the same element. You may want to look at take
and the likes if you iterate on it.
val iterate : ('a -> 'a) -> 'a -> 'a t
iterate f x
is the infinite iterator x, f(x), f(f(x)), ...
val forever : (unit -> 'b) -> 'b t
Iterator that calls the given function to produce elements. The iterator may be transient (depending on the function), and definitely is infinite. You may want to use take
and persistent
.
Cycle forever through the given iterator. Assume the given iterator can be traversed any amount of times (not transient). This yields an infinite iterator, you should use something like take
not to loop forever.
val unfoldr : ('b -> ('a * 'b) option) -> 'b -> 'a t
unfoldr f b
will apply f
to b
. If it yields Some (x,b')
then x
is returned and unfoldr recurses with b'
.
val iter : ('a -> unit) -> 'a t -> unit
Consume the iterator, passing all its arguments to the function. Basically iter f seq
is just seq f
.
val iteri : (int -> 'a -> unit) -> 'a t -> unit
Iterate on elements and their index in the iterator
val for_each : 'a t -> ('a -> unit) -> unit
Consume the iterator, passing all its arguments to the function. for_each seq f
is the same as iter f seq
, i.e., iter
with arguments reversed.
val for_eachi : 'a t -> (int -> 'a -> unit) -> unit
Iterate on elements and their index in the iterator. for_eachi seq f
is the same as iteri f seq
, i.e., iteri
with arguments reversed.
val fold : ('a -> 'b -> 'a) -> 'a -> 'b t -> 'a
Fold over elements of the iterator, consuming it
val foldi : ('a -> int -> 'b -> 'a) -> 'a -> 'b t -> 'a
Fold over elements of the iterator and their index, consuming it
fold_filter_map f acc l
is a fold_map
-like function, but the function can choose to skip an element by retuning None
.
Map objects two by two. lazily. The last element is kept in the iterator if the count is odd.
val for_all : ('a -> bool) -> 'a t -> bool
Do all elements satisfy the predicate?
val exists : ('a -> bool) -> 'a t -> bool
Exists there some element satisfying the predicate?
val mem : ?eq:('a -> 'a -> bool) -> 'a -> 'a t -> bool
Is the value a member of the iterator?
val find : ('a -> 'b option) -> 'a t -> 'b option
Find the first element on which the function doesn't return None
val find_pred : ('a -> bool) -> 'a t -> 'a option
find_pred p l
finds the first element of l
that satisfies p
, or returns None
if no element satisfies p
val length : 'a t -> int
How long is the iterator? Forces the iterator.
val is_empty : 'a t -> bool
Is the iterator empty? Forces the iterator.
Append two iterators. Iterating on the result is like iterating on the first, then on the second.
Append iterators. Iterating on the result is like iterating on the each iterator of the list in order.
Monadic bind. Intuitively, it applies the function to every element of the initial iterator, and calls concat
. Formerly flatMap
seq_list l
returns all the ways to pick one element in each sub-iterator in l
. Assumes the sub-iterators can be iterated on several times.
seq_list_map f l
maps f
over every element of l
, then calls seq_list
Map with indices, and only keep non-None
elements
val filter_count : ('a -> bool) -> 'a t -> int
Count how many elements satisfy the given predicate
filter_some l
retains only elements of the form Some x
. Same as filter_map (fun x->x)
Iterate on the iterator, storing elements in an efficient internal structure.. The resulting iterator can be iterated on as many times as needed. Note: calling persistent on an already persistent iterator will still make a new copy of the iterator!
Lazy version of persistent
. When calling persistent_lazy s
, a new iterator s'
is immediately returned (without actually consuming s
) in constant time; the first time s'
is iterated on, it also consumes s
and caches its content into a inner data structure that will back s'
for future iterations.
warning: on the first traversal of s'
, if the traversal is interrupted prematurely (take
, etc.) then s'
will not be memorized, and the next call to s'
will traverse s
again.
Sort the iterator. Eager, O(n) ram and O(n ln(n)) time. It iterates on elements of the argument iterator immediately, before it sorts them.
Sort the iterator and remove duplicates. Eager, same as sort
val sorted : ?cmp:('a -> 'a -> int) -> 'a t -> bool
Checks whether the iterator is sorted. Eager, same as sort
.
Group equal consecutive elements. Linear time. Formerly synonym to group
. note: Order of items in each list is unspecified.
Group equal elements, disregarding their order of appearance. precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold. note: Order of items in each list is unspecified.
Map each distinct element to its number of occurrences in the whole seq. Similar to group_by seq |> map (fun l->List.hd l, List.length l)
precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold.
Remove consecutive duplicate elements. Basically this is like fun seq -> map List.hd (group seq)
.
Cartesian product of iterators. When calling product a b
, the caller MUST ensure that b
can be traversed as many times as required (several times), possibly by calling persistent
on it beforehand.
val diagonal_l : 'a list -> ('a * 'a) t
All pairs of distinct positions of the list. diagonal l
will return the iterator of all List.nth i l, List.nth j l
if i < j
.
All pairs of distinct positions of the iterator. Iterates only once on the iterator, which must be finite.
join ~join_row a b
combines every element of a
with every element of b
using join_row
. If join_row
returns None, then the two elements do not combine. Assume that b
allows for multiple iterations.
val join_by :
?eq:'key equal ->
?hash:'key hash ->
('a -> 'key) ->
('b -> 'key) ->
merge:('key -> 'a -> 'b -> 'c option) ->
'a t ->
'b t ->
'c t
join key1 key2 ~merge
is a binary operation that takes two iterators a
and b
, projects their elements resp. with key1
and key2
, and combine values (x,y)
from (a,b)
with the same key
using merge
. If merge
returns None
, the combination of values is discarded. precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold.
val join_all_by :
?eq:'key equal ->
?hash:'key hash ->
('a -> 'key) ->
('b -> 'key) ->
merge:('key -> 'a list -> 'b list -> 'c option) ->
'a t ->
'b t ->
'c t
join_all_by key1 key2 ~merge
is a binary operation that takes two iterators a
and b
, projects their elements resp. with key1
and key2
, and, for each key k
occurring in at least one of them:
l1
of elements of a
that map to k
l2
of elements of b
that map to k
merge k l1 l2
. If merge
returns None
, the combination of values is discarded, otherwise it returns Some c
and c
is inserted in the result.group_join_by key2
associates to every element x
of the first iterator, all the elements y
of the second iterator such that eq x (key y)
. Elements of the first iterators without corresponding values in the second one are mapped to []
precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold.
Intersection of two collections. Each element will occur at most once in the result. Eager. precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold.
Union of two collections. Each element will occur at most once in the result. Eager. precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold.
subset a b
returns true
if all elements of a
belong to b
. Eager. precondition: for any x
and y
, if eq x y
then hash x=hash y
must hold.
val max : ?lt:('a -> 'a -> bool) -> 'a t -> 'a option
Max element of the iterator, using the given comparison function.
val min : ?lt:('a -> 'a -> bool) -> 'a t -> 'a option
Min element of the iterator, using the given comparison function. see max
for more details.
val sum : int t -> int
Sum of elements
val sumf : float t -> float
Sum of elements, using Kahan summation
val head : 'a t -> 'a option
First element, if any, otherwise None
val head_exn : 'a t -> 'a
First element, if any, fails
Take at most n
elements from the iterator. Works on infinite iterators.
Take elements while they satisfy the predicate, then stops iterating. Will work on an infinite iterator s
if the predicate is false for at least one element of s
.
val fold_while : ('a -> 'b -> 'a * [ `Stop | `Continue ]) -> 'a -> 'b t -> 'a
Folds over elements of the iterator, stopping early if the accumulator returns ('a, `Stop)
Reverse the iterator. O(n) memory and time, needs the iterator to be finite. The result is persistent and does not depend on the input being repeatable.
val fold2 : ('c -> 'a -> 'b -> 'c) -> 'c -> ('a * 'b) t -> 'c
val iter2 : ('a -> 'b -> unit) -> ('a * 'b) t -> unit
map2_2 f g seq2
maps each x, y
of seq2 into f x y, g x y
val to_list : 'a t -> 'a list
Convert the iterator into a list. Preserves order of elements. This function is tail-recursive, but consumes 2*n memory. If order doesn't matter to you, consider to_rev_list
.
val to_rev_list : 'a t -> 'a list
Get the list of the reversed iterator (more efficient than to_list
)
val of_list : 'a list -> 'a t
on_list f l
is equivalent to to_list @@ f @@ of_list l
.
val to_array : 'a t -> 'a array
Convert to an array. Currently not very efficient because an intermediate list is used.
val of_array : 'a array -> 'a t
val of_array_i : 'a array -> (int * 'a) t
Elements of the array, with their index
val array_slice : 'a array -> int -> int -> 'a t
array_slice a i j
Iterator of elements whose indexes range from i
to j
val of_opt : 'a option -> 'a t
Iterate on 0 or 1 values.
Convert to a Seq
. Linear in memory and time (a copy is made in memory). This does not work on infinite iterators.
Add elements of the iterator to the hashtable, with Hashtbl.add
Add elements of the iterator to the hashtable, with Hashtbl.replace (erases conflicting bindings)
Build a hashtable from an iterator of key/value pairs
val of_str : string -> char t
val to_str : char t -> string
val concat_str : string t -> string
Concatenate strings together, eagerly. Also see intersperse
to add a separator.
Raised when the user tries to iterate several times on a transient iterator
val of_in_channel : in_channel -> char t
Iterates on characters of the input (can block when one iterates over the iterator). If you need to iterate several times on this iterator, use persistent
.
val int_range : start:int -> stop:int -> int t
Iterator on integers in start...stop
by steps 1. Also see (--)
for an infix version.
val int_range_dec : start:int -> stop:int -> int t
Iterator on decreasing integers in stop...start
by steps -1. See (--^)
for an infix version
val int_range_by : step:int -> int -> int -> int t
int_range_by ~step i j
is the range starting at i
, including j
, where the difference between successive elements is step
. use a negative step
for a decreasing iterator.
val bools : bool t
Iterates on true
and false
Convert the given set to an iterator. The set module must be provided.
Convert the iterator to a set, given the proper set module
One shot iterator using this generator. It must not be traversed twice.
module Set : sig ... end
module Map : sig ... end
val random_int : int -> int t
Infinite iterator of random integers between 0 and the given higher bound (see Random.int)
val random_bool : bool t
Infinite iterator of random bool values
val random_float : float -> float t
val random_array : 'a array -> 'a t
Iterator of choices of an element in the array
val random_list : 'a list -> 'a t
Infinite iterator of random elements of the list. Basically the same as random_array
.
shuffle seq
returns a perfect shuffle of seq
. Uses O(length seq) memory and time. Eager.
shuffle_buffer n seq
returns an iterator of element of seq
in random order. The shuffling is *not* uniform. Uses O(n) memory.
The first n
elements of the iterator are consumed immediately. The rest is consumed lazily.
val sample : int -> 'a t -> 'a array
sample n seq
returns k samples of seq
, with uniform probability. It will consume the iterator and use O(n) memory.
It returns an array of size min (length seq) n
.
Random iterators use Random.int
, Random.float
, Random.bool
, etc., under the hood, so they will respect seeding of the random generator in the usual way. I.e., if you do not initialize the random generator with one of Random.init
, Random.full_init
, or Random.self_init
before calling these functions, they will yield the same values across seperate invocations of your program.
Example:
(* Ensure a fresh random seed each time the program is executed. *)
let () = Random.self_init ()
(* Generate random values. *)
let l = Iter.random_int 1000 |> Iter.take 3 |> Iter.to_list
module Infix : sig ... end
include module type of Infix
val (--) : int -> int -> int t
a -- b
is the range of integers from a
to b
, both included, in increasing order. It will therefore be empty if a > b
.
val (--^) : int -> int -> int t
a --^ b
is the range of integers from b
to a
, both included, in decreasing order (starts from a
). It will therefore be empty if a < b
.
val pp_seq :
?sep:string ->
(Format.formatter -> 'a -> unit) ->
Format.formatter ->
'a t ->
unit
Pretty print an iterator of 'a
, using the given pretty printer to print each elements. An optional separator string can be provided.
val to_string : ?sep:string -> ('a -> string) -> 'a t -> string
Print into a string
module IO : sig ... end
Basic IO