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|
(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \VV/ *************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(***********************************************************************)
(* $Id: FSetInterface.v 10616 2008-03-04 17:33:35Z letouzey $ *)
(** * Finite set library *)
(** Set interfaces, inspired by the one of Ocaml. When compared with
Ocaml, the main differences are:
- the lack of [iter] function, useless since Coq is purely functional
- the use of [option] types instead of [Not_found] exceptions
- the use of [nat] instead of [int] for the [cardinal] function
Several variants of the set interfaces are available:
- [WSfun] : functorial signature for weak sets, non-dependent style
- [WS] : self-contained version of [WSfun]
- [Sfun] : functorial signature for ordered sets, non-dependent style
- [S] : self-contained version of [Sfun]
- [Sdep] : analog of [S] written using dependent style
If unsure, [S] is probably what you're looking for: other signatures
are subsets of it, apart from [Sdep] which is isomorphic to [S] (see
[FSetBridge]).
*)
Require Export Bool OrderedType DecidableType.
Set Implicit Arguments.
Unset Strict Implicit.
(** * Non-dependent signatures
The following signatures presents sets as purely informative
programs together with axioms *)
(** ** Functorial signature for weak sets
Weak sets are sets without ordering on base elements, only
a decidable equality. *)
Module Type WSfun (E : EqualityType).
(** The module E of base objects is meant to be a [DecidableType]
(and used to be so). But requiring only an [EqualityType] here
allows subtyping between weak and ordered sets *)
Definition elt := E.t.
Parameter t : Type. (** the abstract type of sets *)
(** Logical predicates *)
Parameter In : elt -> t -> Prop.
Definition Equal s s' := forall a : elt, In a s <-> In a s'.
Definition Subset s s' := forall a : elt, In a s -> In a s'.
Definition Empty s := forall a : elt, ~ In a s.
Definition For_all (P : elt -> Prop) s := forall x, In x s -> P x.
Definition Exists (P : elt -> Prop) s := exists x, In x s /\ P x.
Notation "s [=] t" := (Equal s t) (at level 70, no associativity).
Notation "s [<=] t" := (Subset s t) (at level 70, no associativity).
Parameter empty : t.
(** The empty set. *)
Parameter is_empty : t -> bool.
(** Test whether a set is empty or not. *)
Parameter mem : elt -> t -> bool.
(** [mem x s] tests whether [x] belongs to the set [s]. *)
Parameter 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. *)
Parameter singleton : elt -> t.
(** [singleton x] returns the one-element set containing only [x]. *)
Parameter 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. *)
Parameter union : t -> t -> t.
(** Set union. *)
Parameter inter : t -> t -> t.
(** Set intersection. *)
Parameter diff : t -> t -> t.
(** Set difference. *)
Definition eq : t -> t -> Prop := Equal.
(** In order to have the subtyping WS < S between weak and ordered
sets, we do not require here an [eq_dec]. This interface is hence
not compatible with [DecidableType], but only with [EqualityType],
so in general it may not possible to form weak sets of weak sets.
Some particular implementations may allow this nonetheless, in
particular [FSetWeakList.Make]. *)
Parameter equal : t -> t -> bool.
(** [equal s1 s2] tests whether the sets [s1] and [s2] are
equal, that is, contain equal elements. *)
Parameter subset : t -> t -> bool.
(** [subset s1 s2] tests whether the set [s1] is a subset of
the set [s2]. *)
Parameter fold : forall A : Type, (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].
The order in which elements of [s] are presented to [f] is
unspecified. *)
Parameter for_all : (elt -> bool) -> t -> bool.
(** [for_all p s] checks if all elements of the set
satisfy the predicate [p]. *)
Parameter exists_ : (elt -> bool) -> t -> bool.
(** [exists p s] checks if at least one element of
the set satisfies the predicate [p]. *)
Parameter filter : (elt -> bool) -> t -> t.
(** [filter p s] returns the set of all elements in [s]
that satisfy predicate [p]. *)
Parameter 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]. *)
Parameter cardinal : t -> nat.
(** Return the number of elements of a set. *)
Parameter elements : t -> list elt.
(** Return the list of all elements of the given set, in any order. *)
Parameter choose : t -> option elt.
(** Return one element of the given set, or [None] if
the set is empty. Which element is chosen is unspecified.
Equal sets could return different elements. *)
Section Spec.
Variable s s' s'': t.
Variable x y : elt.
(** Specification of [In] *)
Parameter In_1 : E.eq x y -> In x s -> In y s.
(** Specification of [eq] *)
Parameter eq_refl : eq s s.
Parameter eq_sym : eq s s' -> eq s' s.
Parameter eq_trans : eq s s' -> eq s' s'' -> eq s s''.
(** Specification of [mem] *)
Parameter mem_1 : In x s -> mem x s = true.
Parameter mem_2 : mem x s = true -> In x s.
(** Specification of [equal] *)
Parameter equal_1 : Equal s s' -> equal s s' = true.
Parameter equal_2 : equal s s' = true -> Equal s s'.
(** Specification of [subset] *)
Parameter subset_1 : Subset s s' -> subset s s' = true.
Parameter subset_2 : subset s s' = true -> Subset s s'.
(** Specification of [empty] *)
Parameter empty_1 : Empty empty.
(** Specification of [is_empty] *)
Parameter is_empty_1 : Empty s -> is_empty s = true.
Parameter is_empty_2 : is_empty s = true -> Empty s.
(** Specification of [add] *)
Parameter add_1 : E.eq x y -> In y (add x s).
Parameter add_2 : In y s -> In y (add x s).
Parameter add_3 : ~ E.eq x y -> In y (add x s) -> In y s.
(** Specification of [remove] *)
Parameter remove_1 : E.eq x y -> ~ In y (remove x s).
Parameter remove_2 : ~ E.eq x y -> In y s -> In y (remove x s).
Parameter remove_3 : In y (remove x s) -> In y s.
(** Specification of [singleton] *)
Parameter singleton_1 : In y (singleton x) -> E.eq x y.
Parameter singleton_2 : E.eq x y -> In y (singleton x).
(** Specification of [union] *)
Parameter union_1 : In x (union s s') -> In x s \/ In x s'.
Parameter union_2 : In x s -> In x (union s s').
Parameter union_3 : In x s' -> In x (union s s').
(** Specification of [inter] *)
Parameter inter_1 : In x (inter s s') -> In x s.
Parameter inter_2 : In x (inter s s') -> In x s'.
Parameter inter_3 : In x s -> In x s' -> In x (inter s s').
(** Specification of [diff] *)
Parameter diff_1 : In x (diff s s') -> In x s.
Parameter diff_2 : In x (diff s s') -> ~ In x s'.
Parameter diff_3 : In x s -> ~ In x s' -> In x (diff s s').
(** Specification of [fold] *)
Parameter fold_1 : forall (A : Type) (i : A) (f : elt -> A -> A),
fold f s i = fold_left (fun a e => f e a) (elements s) i.
(** Specification of [cardinal] *)
Parameter cardinal_1 : cardinal s = length (elements s).
Section Filter.
Variable f : elt -> bool.
(** Specification of [filter] *)
Parameter filter_1 : compat_bool E.eq f -> In x (filter f s) -> In x s.
Parameter filter_2 : compat_bool E.eq f -> In x (filter f s) -> f x = true.
Parameter filter_3 :
compat_bool E.eq f -> In x s -> f x = true -> In x (filter f s).
(** Specification of [for_all] *)
Parameter for_all_1 :
compat_bool E.eq f ->
For_all (fun x => f x = true) s -> for_all f s = true.
Parameter for_all_2 :
compat_bool E.eq f ->
for_all f s = true -> For_all (fun x => f x = true) s.
(** Specification of [exists] *)
Parameter exists_1 :
compat_bool E.eq f ->
Exists (fun x => f x = true) s -> exists_ f s = true.
Parameter exists_2 :
compat_bool E.eq f ->
exists_ f s = true -> Exists (fun x => f x = true) s.
(** Specification of [partition] *)
Parameter partition_1 :
compat_bool E.eq f -> Equal (fst (partition f s)) (filter f s).
Parameter partition_2 :
compat_bool E.eq f ->
Equal (snd (partition f s)) (filter (fun x => negb (f x)) s).
End Filter.
(** Specification of [elements] *)
Parameter elements_1 : In x s -> InA E.eq x (elements s).
Parameter elements_2 : InA E.eq x (elements s) -> In x s.
(** When compared with ordered sets, here comes the only
property that is really weaker: *)
Parameter elements_3w : NoDupA E.eq (elements s).
(** Specification of [choose] *)
Parameter choose_1 : choose s = Some x -> In x s.
Parameter choose_2 : choose s = None -> Empty s.
End Spec.
Hint Resolve mem_1 equal_1 subset_1 empty_1
is_empty_1 choose_1 choose_2 add_1 add_2 remove_1
remove_2 singleton_2 union_1 union_2 union_3
inter_3 diff_3 fold_1 filter_3 for_all_1 exists_1
partition_1 partition_2 elements_1 elements_3w
: set.
Hint Immediate In_1 mem_2 equal_2 subset_2 is_empty_2 add_3
remove_3 singleton_1 inter_1 inter_2 diff_1 diff_2
filter_1 filter_2 for_all_2 exists_2 elements_2
: set.
End WSfun.
(** ** Static signature for weak sets
Similar to the functorial signature [SW], except that the
module [E] of base elements is incorporated in the signature. *)
Module Type WS.
Declare Module E : EqualityType.
Include Type WSfun E.
End WS.
(** ** Functorial signature for sets on ordered elements
Based on [WSfun], plus ordering on sets and [min_elt] and [max_elt]
and some stronger specifications for other functions. *)
Module Type Sfun (E : OrderedType).
Include Type WSfun E.
Parameter lt : t -> t -> Prop.
Parameter compare : forall s s' : t, Compare lt eq s s'.
(** Total ordering between sets. Can be used as the ordering function
for doing sets of sets. *)
Parameter min_elt : t -> option elt.
(** Return the smallest element of the given set
(with respect to the [E.compare] ordering),
or [None] if the set is empty. *)
Parameter max_elt : t -> option elt.
(** Same as [min_elt], but returns the largest element of the
given set. *)
Section Spec.
Variable s s' s'' : t.
Variable x y : elt.
(** Specification of [lt] *)
Parameter lt_trans : lt s s' -> lt s' s'' -> lt s s''.
Parameter lt_not_eq : lt s s' -> ~ eq s s'.
(** Additional specification of [elements] *)
Parameter elements_3 : sort E.lt (elements s).
(** Remark: since [fold] is specified via [elements], this stronger
specification of [elements] has an indirect impact on [fold],
which can now be proved to receive elements in increasing order.
*)
(** Specification of [min_elt] *)
Parameter min_elt_1 : min_elt s = Some x -> In x s.
Parameter min_elt_2 : min_elt s = Some x -> In y s -> ~ E.lt y x.
Parameter min_elt_3 : min_elt s = None -> Empty s.
(** Specification of [max_elt] *)
Parameter max_elt_1 : max_elt s = Some x -> In x s.
Parameter max_elt_2 : max_elt s = Some x -> In y s -> ~ E.lt x y.
Parameter max_elt_3 : max_elt s = None -> Empty s.
(** Additional specification of [choose] *)
Parameter choose_3 : choose s = Some x -> choose s' = Some y ->
Equal s s' -> E.eq x y.
End Spec.
Hint Resolve elements_3 : set.
Hint Immediate
min_elt_1 min_elt_2 min_elt_3 max_elt_1 max_elt_2 max_elt_3 : set.
End Sfun.
(** ** Static signature for sets on ordered elements
Similar to the functorial signature [Sfun], except that the
module [E] of base elements is incorporated in the signature. *)
Module Type S.
Declare Module E : OrderedType.
Include Type Sfun E.
End S.
(** ** Some subtyping tests
<<
WSfun ---> WS
| |
| |
V V
Sfun ---> S
Module S_WS (M : S) <: SW := M.
Module Sfun_WSfun (E:OrderedType)(M : Sfun E) <: WSfun E := M.
Module S_Sfun (E:OrderedType)(M : S with Module E:=E) <: Sfun E := M.
Module WS_WSfun (E:EqualityType)(M : WS with Module E:=E) <: WSfun E := M.
>>
*)
(** * Dependent signature
Signature [Sdep] presents ordered sets using dependent types *)
Module Type Sdep.
Declare Module E : OrderedType.
Definition elt := E.t.
Parameter t : Type.
Parameter In : elt -> t -> Prop.
Definition Equal s s' := forall a : elt, In a s <-> In a s'.
Definition Subset s s' := forall a : elt, In a s -> In a s'.
Definition Add x s s' := forall y, In y s' <-> E.eq x y \/ In y s.
Definition Empty s := forall a : elt, ~ In a s.
Definition For_all (P : elt -> Prop) s := forall x, In x s -> P x.
Definition Exists (P : elt -> Prop) s := exists x, In x s /\ P x.
Notation "s [=] t" := (Equal s t) (at level 70, no associativity).
Definition eq : t -> t -> Prop := Equal.
Parameter lt : t -> t -> Prop.
Parameter compare : forall s s' : t, Compare lt eq s s'.
Parameter eq_refl : forall s : t, eq s s.
Parameter eq_sym : forall s s' : t, eq s s' -> eq s' s.
Parameter eq_trans : forall s s' s'' : t, eq s s' -> eq s' s'' -> eq s s''.
Parameter lt_trans : forall s s' s'' : t, lt s s' -> lt s' s'' -> lt s s''.
Parameter lt_not_eq : forall s s' : t, lt s s' -> ~ eq s s'.
Parameter eq_In : forall (s : t) (x y : elt), E.eq x y -> In x s -> In y s.
Parameter empty : {s : t | Empty s}.
Parameter is_empty : forall s : t, {Empty s} + {~ Empty s}.
Parameter mem : forall (x : elt) (s : t), {In x s} + {~ In x s}.
Parameter add : forall (x : elt) (s : t), {s' : t | Add x s s'}.
Parameter
singleton : forall x : elt, {s : t | forall y : elt, In y s <-> E.eq x y}.
Parameter
remove :
forall (x : elt) (s : t),
{s' : t | forall y : elt, In y s' <-> ~ E.eq x y /\ In y s}.
Parameter
union :
forall s s' : t,
{s'' : t | forall x : elt, In x s'' <-> In x s \/ In x s'}.
Parameter
inter :
forall s s' : t,
{s'' : t | forall x : elt, In x s'' <-> In x s /\ In x s'}.
Parameter
diff :
forall s s' : t,
{s'' : t | forall x : elt, In x s'' <-> In x s /\ ~ In x s'}.
Parameter equal : forall s s' : t, {s[=]s'} + {~ s[=]s'}.
Parameter subset : forall s s' : t, {Subset s s'} + {~ Subset s s'}.
Parameter
filter :
forall (P : elt -> Prop) (Pdec : forall x : elt, {P x} + {~ P x})
(s : t),
{s' : t | compat_P E.eq P -> forall x : elt, In x s' <-> In x s /\ P x}.
Parameter
for_all :
forall (P : elt -> Prop) (Pdec : forall x : elt, {P x} + {~ P x})
(s : t),
{compat_P E.eq P -> For_all P s} + {compat_P E.eq P -> ~ For_all P s}.
Parameter
exists_ :
forall (P : elt -> Prop) (Pdec : forall x : elt, {P x} + {~ P x})
(s : t),
{compat_P E.eq P -> Exists P s} + {compat_P E.eq P -> ~ Exists P s}.
Parameter
partition :
forall (P : elt -> Prop) (Pdec : forall x : elt, {P x} + {~ P x})
(s : t),
{partition : t * t |
let (s1, s2) := partition in
compat_P E.eq P ->
For_all P s1 /\
For_all (fun x => ~ P x) s2 /\
(forall x : elt, In x s <-> In x s1 \/ In x s2)}.
Parameter
elements :
forall s : t,
{l : list elt |
sort E.lt l /\ (forall x : elt, In x s <-> InA E.eq x l)}.
Parameter
fold :
forall (A : Type) (f : elt -> A -> A) (s : t) (i : A),
{r : A | let (l,_) := elements s in
r = fold_left (fun a e => f e a) l i}.
Parameter
cardinal :
forall s : t,
{r : nat | let (l,_) := elements s in r = length l }.
Parameter
min_elt :
forall s : t,
{x : elt | In x s /\ For_all (fun y => ~ E.lt y x) s} + {Empty s}.
Parameter
max_elt :
forall s : t,
{x : elt | In x s /\ For_all (fun y => ~ E.lt x y) s} + {Empty s}.
Parameter choose : forall s : t, {x : elt | In x s} + {Empty s}.
(** The [choose_3] specification of [S] cannot be packed
in the dependent version of [choose], so we leave it separate. *)
Parameter choose_equal : forall s s', Equal s s' ->
match choose s, choose s' with
| inleft (exist x _), inleft (exist x' _) => E.eq x x'
| inright _, inright _ => True
| _, _ => False
end.
End Sdep.
|