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(* *)
(* Ocamlgraph: a generic graph library for OCaml *)
(* Copyright (C) 2004-2010 *)
(* Sylvain Conchon, Jean-Christophe Filliatre and Julien Signoles *)
(* *)
(* This software is free software; you can redistribute it and/or *)
(* modify it under the terms of the GNU Library General Public *)
(* License version 2.1, with the special exception on linking *)
(* described in file LICENSE. *)
(* *)
(* This software is distributed in the hope that it will be useful, *)
(* but WITHOUT ANY WARRANTY; without even the implied warranty of *)
(* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. *)
(* *)
(**************************************************************************)
(** Imperative Graph Implementations. *)
open Sig
(** Signature of imperative graphs. *)
module type S = sig
(** <b>Edges may be labeled or not</b>:
- Unlabeled: there is no label on edges
- Labeled: you have to provide a label implementation as a functor
parameter.
<b>Vertices may be concrete or abstract</b>:
- Concrete: type of vertex labels and type of vertices are identified.
- Abstract: type of vertices is abstract (in particular it is not equal
to type of vertex labels
<b>How to choose between concrete and abstract vertices for my graph
implementation</b>?
Usually, if you fall into one of the following cases, use abstract
vertices:
- you cannot provide efficient comparison/hash functions for vertices; or
- you wish to get two different vertices with the same label.
In other cases, it is certainly easier to use concrete vertices. *)
(** Imperative Unlabeled Graphs. *)
module Concrete (V: COMPARABLE) :
Sig.I with type V.t = V.t and type V.label = V.t and type E.t = V.t * V.t
and type E.label = unit
(** Abstract Imperative Unlabeled Graphs. *)
module Abstract(V: ANY_TYPE) :
Sig.IM with type V.label = V.t and type E.label = unit
(** Imperative Labeled Graphs. *)
module ConcreteLabeled (V: COMPARABLE)(E: ORDERED_TYPE_DFT) :
Sig.I with type V.t = V.t and type V.label = V.t
and type E.t = V.t * E.t * V.t and type E.label = E.t
(** Abstract Imperative Labeled Graphs. *)
module AbstractLabeled (V: ANY_TYPE)(E: ORDERED_TYPE_DFT) :
Sig.IM with type V.label = V.t and type E.label = E.t
end
(** Imperative Directed Graphs. *)
module Digraph : sig
include S
(** {2 Bidirectional graphs}
Bidirectional graphs use more memory space (at worse the double) that
standard concrete directional graphs. But accessing predecessors is in
O(1) amortized instead of O(max(|V|,|E|)) and removing a vertex is in
O(D*ln(D)) instead of O(|V|*ln(D)). D is the maximal degree of the
graph. *)
(** Imperative Unlabeled, bidirectional graph. *)
module ConcreteBidirectional (V: COMPARABLE) :
Sig.I with type V.t = V.t and type V.label = V.t and type E.t = V.t * V.t
and type E.label = unit
(** Imperative Labeled and bidirectional graph. *)
module ConcreteBidirectionalLabeled(V:COMPARABLE)(E:ORDERED_TYPE_DFT) :
Sig.I with type V.t = V.t and type V.label = V.t
and type E.t = V.t * E.t * V.t and type E.label = E.t
end
(** Imperative Undirected Graphs. *)
module Graph : S
(** Imperative graphs implemented as adjacency matrices. *)
module Matrix : sig
module type S = sig
(** Vertices are integers in [0..n-1].
A vertex label is the vertex itself.
Edges are unlabeled. *)
include Sig.I with type V.t = int and type V.label = int
and type E.t = int * int
(** Creation. graphs are not resizeable: size is given at creation time.
Thus [make] must be used instead of [create]. *)
val make : int -> t
(** Note: [add_vertex] and [remove_vertex] have no effect.
[clear] only removes edges, not vertices. *)
end
module Digraph : S
(** Imperative Directed Graphs implemented with adjacency matrices. *)
module Graph : S
(** Imperative Undirected Graphs implemented with adjacency matrices. *)
end
(****
(** Faster implementations for abstract (un)labeled (di)graphs
when vertices are _not shared_ between different graphs.
This means that, when using the following implementations, two different
graphs (created with two calls to [create]) must have disjoint sets of
vertices. *)
module UV : sig
(** directed graphs *)
module Digraph : sig
module Abstract(V: ANY_TYPE) :
Sig.IM with type V.label = V.t and type E.label = unit
module AbstractLabeled (V: ANY_TYPE)(E: ORDERED_TYPE_DFT) :
Sig.IM with type V.label = V.t and type E.label = E.t
end
(** undirected graphs *)
module Graph : sig
module Abstract(V: ANY_TYPE) :
Sig.IM with type V.label = V.t and type E.label = unit
module AbstractLabeled (V: ANY_TYPE)(E: ORDERED_TYPE_DFT) :
Sig.IM with type V.label = V.t and type E.label = E.t
end
end
****)
(*
Local Variables:
compile-command: "make -C .."
End:
*)
|