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(**************************************************************************)
(* *)
(* OCaml *)
(* *)
(* Xavier Leroy, projet Cristal, INRIA Rocquencourt *)
(* *)
(* Copyright 1996 Institut National de Recherche en Informatique et *)
(* en Automatique. *)
(* *)
(* All rights reserved. This file is distributed under the terms of *)
(* the GNU Lesser General Public License version 2.1, with the *)
(* special exception on linking described in the file LICENSE. *)
(* *)
(**************************************************************************)
(** Sets over ordered types.
This module implements the set data structure, given a total ordering
function over the set elements. All operations over sets
are purely applicative (no side-effects).
The implementation uses balanced binary trees, and is therefore
reasonably efficient: insertion and membership take time
logarithmic in the size of the set, for instance.
The {!Make} functor constructs implementations for any type, given a
[compare] function.
For instance:
{[
module IntPairs =
struct
type t = int * int
let compare (x0,y0) (x1,y1) =
match Stdlib.compare x0 x1 with
0 -> Stdlib.compare y0 y1
| c -> c
end
module PairsSet = Set.Make(IntPairs)
let m = PairsSet.(empty |> add (2,3) |> add (5,7) |> add (11,13))
]}
This creates a new module [PairsSet], with a new type [PairsSet.t]
of sets of [int * int].
*)
module type OrderedType =
sig
type t
(** The type of the set elements. *)
val compare : t -> t -> int
(** A total ordering function over the set elements.
This is a two-argument function [f] such that
[f e1 e2] is zero if the elements [e1] and [e2] are equal,
[f e1 e2] is strictly negative if [e1] is smaller than [e2],
and [f e1 e2] is strictly positive if [e1] is greater than [e2].
Example: a suitable ordering function is the generic structural
comparison function {!Stdlib.compare}. *)
end
(** Input signature of the functor {!Set.Make}. *)
module type S =
sig
type elt
(** The type of the set elements. *)
type t
(** The type of sets. *)
include Comparer.S with type t := t
val empty: t
(** The empty set. *)
val is_empty: t -> bool
(** Test whether a set is empty or not. *)
val mem: elt -> t -> bool
(** [mem x s] tests whether [x] belongs to the set [s]. *)
val add: elt -> t -> t
(** [add x s] returns a set containing all elements of [s],
plus [x]. If [x] was already in [s], [s] is returned unchanged
(the result of the function is then physically equal to [s]).
@before 4.03 Physical equality was not ensured. *)
val singleton: elt -> t
(** [singleton x] returns the one-element set containing only [x]. *)
val remove: elt -> t -> t
(** [remove x s] returns a set containing all elements of [s],
except [x]. If [x] was not in [s], [s] is returned unchanged
(the result of the function is then physically equal to [s]).
@before 4.03 Physical equality was not ensured. *)
val union: t -> t -> t
(** Set union. *)
val inter: t -> t -> t
(** Set intersection. *)
val disjoint: t -> t -> bool
(** Test if two sets are disjoint.
@since 4.08.0 *)
val diff: t -> t -> t
(** Set difference: [diff s1 s2] contains the elements of [s1]
that are not in [s2]. *)
val compare: t -> t -> int
(** Total ordering between sets. Can be used as the ordering function
for doing sets of sets. *)
module Provide_equal (_ : sig
type t = elt [@@deriving equal]
end) : sig
val equal: t -> t -> bool
(** [equal s1 s2] tests whether the sets [s1] and [s2] are
equal, that is, contain equal elements. *)
end
val subset: t -> t -> bool
(** [subset s1 s2] tests whether the set [s1] is a subset of
the set [s2]. *)
val iter: (elt -> unit) -> t -> unit
(** [iter f s] applies [f] in turn to all elements of [s].
The elements of [s] are presented to [f] in increasing order
with respect to the ordering over the type of the elements. *)
val map: (elt -> elt) -> t -> t
(** [map f s] is the set whose elements are [f a0],[f a1]... [f
aN], where [a0],[a1]...[aN] are the elements of [s].
The elements are passed to [f] in increasing order
with respect to the ordering over the type of the elements.
If no element of [s] is changed by [f], [s] is returned
unchanged. (If each output of [f] is physically equal to its
input, the returned set is physically equal to [s].)
@since 4.04.0 *)
val fold: (elt -> 'a -> 'a) -> t -> 'a -> 'a
(** [fold f s a] computes [(f xN ... (f x2 (f x1 a))...)],
where [x1 ... xN] are the elements of [s], in increasing order. *)
val for_all: (elt -> bool) -> t -> bool
(** [for_all p s] checks if all elements of the set
satisfy the predicate [p]. *)
val exists: (elt -> bool) -> t -> bool
(** [exists p s] checks if at least one element of
the set satisfies the predicate [p]. *)
val filter: (elt -> bool) -> t -> t
(** [filter p s] returns the set of all elements in [s]
that satisfy predicate [p]. If [p] satisfies every element in [s],
[s] is returned unchanged (the result of the function is then
physically equal to [s]).
@before 4.03 Physical equality was not ensured.*)
val filter_map: (elt -> elt option) -> t -> t
(** [filter_map f s] returns the set of all [v] such that
[f x = Some v] for some element [x] of [s].
For example,
{[filter_map (fun n -> if n mod 2 = 0 then Some (n / 2) else None) s]}
is the set of halves of the even elements of [s].
If no element of [s] is changed or dropped by [f] (if
[f x = Some x] for each element [x]), then
[s] is returned unchanged: the result of the function
is then physically equal to [s].
@since 4.11.0
*)
val partition: (elt -> bool) -> t -> t * t
(** [partition p s] returns a pair of sets [(s1, s2)], where
[s1] is the set of all the elements of [s] that satisfy the
predicate [p], and [s2] is the set of all the elements of
[s] that do not satisfy [p]. *)
val cardinal: t -> int
(** Return the number of elements of a set. *)
val elements: t -> elt list
(** Return the list of all elements of the given set.
The returned list is sorted in increasing order with respect
to the ordering [Ord.compare], where [Ord] is the argument
given to {!Set.Make}. *)
val min_elt: t -> elt
(** Return the smallest element of the given set
(with respect to the [Ord.compare] ordering), or raise
[Not_found] if the set is empty. *)
val min_elt_opt: t -> elt option
(** Return the smallest element of the given set
(with respect to the [Ord.compare] ordering), or [None]
if the set is empty.
@since 4.05
*)
val max_elt: t -> elt
(** Same as {!Set.S.min_elt}, but returns the largest element of the
given set. *)
val max_elt_opt: t -> elt option
(** Same as {!Set.S.min_elt_opt}, but returns the largest element of the
given set.
@since 4.05
*)
val choose: t -> elt
(** Return one element of the given set, or raise [Not_found] if
the set is empty. Which element is chosen is unspecified,
but equal elements will be chosen for equal sets. *)
val choose_opt: t -> elt option
(** Return one element of the given set, or [None] if
the set is empty. Which element is chosen is unspecified,
but equal elements will be chosen for equal sets.
@since 4.05
*)
val split: elt -> t -> t * bool * t
(** [split x s] returns a triple [(l, present, r)], where
[l] is the set of elements of [s] that are
strictly less than [x];
[r] is the set of elements of [s] that are
strictly greater than [x];
[present] is [false] if [s] contains no element equal to [x],
or [true] if [s] contains an element equal to [x]. *)
val find: elt -> t -> elt
(** [find x s] returns the element of [s] equal to [x] (according
to [Ord.compare]), or raise [Not_found] if no such element
exists.
@since 4.01.0 *)
val find_opt: elt -> t -> elt option
(** [find_opt x s] returns the element of [s] equal to [x] (according
to [Ord.compare]), or [None] if no such element
exists.
@since 4.05 *)
val find_first: (elt -> bool) -> t -> elt
(** [find_first f s], where [f] is a monotonically increasing function,
returns the lowest element [e] of [s] such that [f e],
or raises [Not_found] if no such element exists.
For example, [find_first (fun e -> Ord.compare e x >= 0) s] will return
the first element [e] of [s] where [Ord.compare e x >= 0] (intuitively:
[e >= x]), or raise [Not_found] if [x] is greater than any element of
[s].
@since 4.05
*)
val find_first_opt: (elt -> bool) -> t -> elt option
(** [find_first_opt f s], where [f] is a monotonically increasing function,
returns an option containing the lowest element [e] of [s] such that
[f e], or [None] if no such element exists.
@since 4.05
*)
val find_last: (elt -> bool) -> t -> elt
(** [find_last f s], where [f] is a monotonically decreasing function,
returns the highest element [e] of [s] such that [f e],
or raises [Not_found] if no such element exists.
@since 4.05
*)
val find_last_opt: (elt -> bool) -> t -> elt option
(** [find_last_opt f s], where [f] is a monotonically decreasing function,
returns an option containing the highest element [e] of [s] such that
[f e], or [None] if no such element exists.
@since 4.05
*)
val of_list: elt list -> t
(** [of_list l] creates a set from a list of elements.
This is usually more efficient than folding [add] over the list,
except perhaps for lists with many duplicated elements.
@since 4.02.0 *)
(** {1 Iterators} *)
val to_seq_from : elt -> t -> elt Seq.t
(** [to_seq_from x s] iterates on a subset of the elements of [s]
in ascending order, from [x] or above.
@since 4.07 *)
val to_seq : t -> elt Seq.t
(** Iterate on the whole set, in ascending order
@since 4.07 *)
val add_seq : elt Seq.t -> t -> t
(** Add the given elements to the set, in order.
@since 4.07 *)
val of_seq : elt Seq.t -> t
(** Build a set from the given bindings
@since 4.07 *)
module Provide_sexp_of (_ : sig
type t = elt [@@deriving sexp_of]
end) : sig
type t [@@deriving sexp_of]
end
with type t := t
module Provide_of_sexp (_ : sig
type t = elt [@@deriving of_sexp]
end) : sig
type t [@@deriving of_sexp]
end
with type t := t
end
(** Output signature of the functor {!Set.Make}. *)
type ('elt, 'cmp) t [@@deriving compare, equal, sexp]
type 'compare_elt compare [@@deriving compare, equal, sexp]
module Make (Ord : Comparer.S) :
S with type elt = Ord.t
with type t = (Ord.t, Ord.compare) t
with type compare = Ord.compare compare
(** Functor building an implementation of the set structure
given a totally ordered type. *)