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(* *)
(* Menhir *)
(* *)
(* François Pottier, Inria Paris *)
(* Yann Régis-Gianas, PPS, Université Paris Diderot *)
(* *)
(* Copyright Inria. All rights reserved. This file is distributed under the *)
(* terms of the GNU General Public License version 2, as described in the *)
(* file LICENSE. *)
(* *)
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(** This module implements a simple and efficient union/find algorithm.
See Robert E. Tarjan, ``Efficiency of a Good But Not Linear Set
Union Algorithm'', JACM 22(2), 1975. *)
(** The abstraction defined by this module is a set of points,
partitioned into equivalence classes. With each equivalence class,
a piece of information, of abstract type ['a], is associated; we
call it a descriptor.
A point is implemented as a cell, whose (mutable) contents consist
of a single link to either information about the equivalence class,
or another point. Thus, points form a graph, which must be acyclic,
and whose connected components are the equivalence classes. In
every equivalence class, exactly one point has no outgoing edge,
and carries information about the class instead. It is the class's
representative element.
Information about a class consists of an integer weight (the number
of elements in the class) and of the class's descriptor. *)
type 'a point = {
mutable link: 'a link
}
and 'a link =
| Info of 'a info
| Link of 'a point
and 'a info = {
mutable weight: int;
mutable descriptor: 'a
}
(** [fresh desc] creates a fresh point and returns it. It forms an
equivalence class of its own, whose descriptor is [desc]. *)
let fresh desc = {
link = Info { weight = 1; descriptor = desc }
}
(** [repr point] returns the representative element of [point]'s
equivalence class. It is found by starting at [point] and following
the links. For efficiency, the function performs path compression
at the same time. *)
let rec repr point =
match point.link with
| Link point' ->
let point'' = repr point' in
if point'' != point' then
(* [point''] is [point']'s representative element. Because we
just invoked [repr point'], [point'.link] must be [Link
point'']. We write this value into [point.link], thus
performing path compression. Note that this function never
performs memory allocation. *)
point.link <- point'.link;
point''
| Info _ ->
point
(** [get point] returns the descriptor associated with [point]'s
equivalence class. *)
let rec get point =
(* By not calling [repr] immediately, we optimize the common cases
where the path starting at [point] has length 0 or 1, at the
expense of the general case. *)
match point.link with
| Info info
| Link { link = Info info } ->
info.descriptor
| Link { link = Link _ } ->
get (repr point)
let rec set point v =
match point.link with
| Info info
| Link { link = Info info } ->
info.descriptor <- v
| Link { link = Link _ } ->
set (repr point) v
(** [union point1 point2] merges the equivalence classes associated
with [point1] and [point2] into a single class whose descriptor is
that originally associated with [point2]. It does nothing if [point1]
and [point2] already are in the same class.
The weights are used to determine whether [point1] should be made
to point to [point2], or vice-versa. By making the representative
of the smaller class point to that of the larger class, we
guarantee that paths remain of logarithmic length (not accounting
for path compression, which makes them yet smaller). *)
let union point1 point2 =
let point1 = repr point1
and point2 = repr point2 in
if point1 != point2 then
match point1.link, point2.link with
| Info info1, Info info2 ->
let weight1 = info1.weight
and weight2 = info2.weight in
if weight1 >= weight2 then begin
point2.link <- Link point1;
info1.weight <- weight1 + weight2;
info1.descriptor <- info2.descriptor
end
else begin
point1.link <- Link point2;
info2.weight <- weight1 + weight2
end
| _, _ ->
assert false (* [repr] guarantees that [link] matches [Info _]. *)
(** [equivalent point1 point2] tells whether [point1] and [point2]
belong to the same equivalence class. *)
let equivalent point1 point2 =
repr point1 == repr point2