ocaml/stdlib/baltree.mli

78 lines
4.3 KiB
OCaml

(* Basic balanced binary trees *)
(* This module implements balanced ordered binary trees.
All operations over binary trees are applicative (no side-effects).
The [set] and [List.map] modules are based on this module.
This modules gives a more direct access to the internals of the
binary tree implementation than the [set] and [List.map] abstractions,
but is more delicate to use and not as safe. For advanced users only. *)
type 'a t = Empty | Node of 'a t * 'a * 'a t * int
(* The type of trees containing elements of type ['a].
[Empty] is the empty tree (containing no elements). *)
type 'a contents = Nothing | Something of 'a
(* Used with the functions [modify] and [List.split], to represent
the presence or the absence of an element in a tree. *)
val add: ('a -> int) -> 'a -> 'a t -> 'a t
(* [add f x t] inserts the element [x] into the tree [t].
[f] is an ordering function: [f y] must return [0] if
[x] and [y] are equal (or equivalent), a negative integer if
[x] is smaller than [y], and a positive integer if [x] is
greater than [y]. The tree [t] is returned unchanged if
it already contains an element equivalent to [x] (that is,
an element [y] such that [f y] is [0]).
The ordering [f] must be consistent with the orderings used
to build [t] with [add], [remove], [modify] or [List.split]
operations. *)
val contains: ('a -> int) -> 'a t -> bool
(* [contains f t] checks whether [t] contains an element
satisfying [f], that is, an element [x] such
that [f x] is [0]. [f] is an ordering function with the same
constraints as for [add]. It can be coarser (identify more
elements) than the orderings used to build [t], but must be
consistent with them. *)
val find: ('a -> int) -> 'a t -> 'a
(* Same as [contains], except that [find f t] returns the element [x]
such that [f x] is [0], or raises [Not_found] if none has been
found. *)
val remove: ('a -> int) -> 'a t -> 'a t
(* [remove f t] removes one element [x] of [t] such that [f x] is [0].
[f] is an ordering function with the same constraints as for [add].
[t] is returned unchanged if it does not contain any element
satisfying [f]. If several elements of [t] satisfy [f],
only one is removed. *)
val modify: ('a -> int) -> ('a contents -> 'a contents) -> 'a t -> 'a t
(* General insertion/modification/deletion function.
[modify f g t] searchs [t] for an element [x] satisfying the
ordering function [f]. If one is found, [g] is applied to
[Something x]; if [g] returns [Nothing], the element [x]
is removed; if [g] returns [Something y], the element [y]
replaces [x] in the tree. (It is assumed that [x] and [y]
are equivalent, in particular, that [f y] is [0].)
If the tree does not contain any [x] satisfying [f],
[g] is applied to [Nothing]; if it returns [Nothing],
the tree is returned unchanged; if it returns [Something x],
the element [x] is inserted in the tree. (It is assumed that
[f x] is [0].) The functions [add] and [remove] are special cases
of [modify], slightly more efficient. *)
val split: ('a -> int) -> 'a t -> 'a t * 'a contents * 'a t
(* [split f t] returns a triple [(less, elt, greater)] where
[less] is a tree containing all elements [x] of [t] such that
[f x] is negative, [greater] is a tree containing all
elements [x] of [t] such that [f x] is positive, and [elt]
is [Something x] if [t] contains an element [x] such that
[f x] is [0], and [Nothing] otherwise. *)
val compare: ('a -> 'a -> int) -> 'a t -> 'a t -> int
(* Compare two trees. The first argument [f] is a comparison function
over the tree elements: [f e1 e2] is zero if the elements [e1] and
[e2] are equal, negative if [e1] is smaller than [e2],
and positive if [e1] is greater than [e2]. [compare f t1 t2]
compares the fringes of [t1] and [t2] by lexicographic extension
of [f]. *)
(*--*)
val join: 'a t -> 'a -> 'a t -> 'a t
val concat: 'a t -> 'a t -> 'a t