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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(*i $Id: TheoryList.v 8642 2006-03-17 10:09:02Z notin $ i*)
(** Some programs and results about lists following CAML Manual *)
Require Export List.
Set Implicit Arguments.
Section Lists.
Variable A : Set.
(**********************)
(** The null function *)
(**********************)
Definition Isnil (l:list A) : Prop := nil = l.
Lemma Isnil_nil : Isnil nil.
red in |- *; auto.
Qed.
Hint Resolve Isnil_nil.
Lemma not_Isnil_cons : forall (a:A) (l:list A), ~ Isnil (a :: l).
unfold Isnil in |- *.
intros; discriminate.
Qed.
Hint Resolve Isnil_nil not_Isnil_cons.
Lemma Isnil_dec : forall l:list A, {Isnil l} + {~ Isnil l}.
intro l; case l; auto.
(*
Realizer (fun l => match l with
| nil => true
| _ => false
end).
*)
Qed.
(************************)
(** The Uncons function *)
(************************)
Lemma Uncons :
forall l:list A, {a : A & {m : list A | a :: m = l}} + {Isnil l}.
intro l; case l.
auto.
intros a m; intros; left; exists a; exists m; reflexivity.
(*
Realizer (fun l => match l with
| nil => error
| (cons a m) => value (a,m)
end).
*)
Qed.
(********************************)
(** The head function *)
(********************************)
Lemma Hd :
forall l:list A, {a : A | exists m : list A, a :: m = l} + {Isnil l}.
intro l; case l.
auto.
intros a m; intros; left; exists a; exists m; reflexivity.
(*
Realizer (fun l => match l with
| nil => error
| (cons a m) => value a
end).
*)
Qed.
Lemma Tl :
forall l:list A,
{m : list A | (exists a : A, a :: m = l) \/ Isnil l /\ Isnil m}.
intro l; case l.
exists (nil (A:=A)); auto.
intros a m; intros; exists m; left; exists a; reflexivity.
(*
Realizer (fun l => match l with
| nil => nil
| (cons a m) => m
end).
*)
Qed.
(****************************************)
(** Length of lists *)
(****************************************)
(* length is defined in List *)
Fixpoint Length_l (l:list A) (n:nat) {struct l} : nat :=
match l with
| nil => n
| _ :: m => Length_l m (S n)
end.
(* A tail recursive version *)
Lemma Length_l_pf : forall (l:list A) (n:nat), {m : nat | n + length l = m}.
induction l as [| a m lrec].
intro n; exists n; simpl in |- *; auto.
intro n; elim (lrec (S n)); simpl in |- *; intros.
exists x; transitivity (S (n + length m)); auto.
(*
Realizer Length_l.
*)
Qed.
Lemma Length : forall l:list A, {m : nat | length l = m}.
intro l. apply (Length_l_pf l 0).
(*
Realizer (fun l -> Length_l_pf l O).
*)
Qed.
(*******************************)
(** Members of lists *)
(*******************************)
Inductive In_spec (a:A) : list A -> Prop :=
| in_hd : forall l:list A, In_spec a (a :: l)
| in_tl : forall (l:list A) (b:A), In a l -> In_spec a (b :: l).
Hint Resolve in_hd in_tl.
Hint Unfold In.
Hint Resolve in_cons.
Theorem In_In_spec : forall (a:A) (l:list A), In a l <-> In_spec a l.
split.
elim l;
[ intros; contradiction
| intros; elim H0; [ intros; rewrite H1; auto | auto ] ].
intros; elim H; auto.
Qed.
Inductive AllS (P:A -> Prop) : list A -> Prop :=
| allS_nil : AllS P nil
| allS_cons : forall (a:A) (l:list A), P a -> AllS P l -> AllS P (a :: l).
Hint Resolve allS_nil allS_cons.
Hypothesis eqA_dec : forall a b:A, {a = b} + {a <> b}.
Fixpoint mem (a:A) (l:list A) {struct l} : bool :=
match l with
| nil => false
| b :: m => if eqA_dec a b then true else mem a m
end.
Hint Unfold In.
Lemma Mem : forall (a:A) (l:list A), {In a l} + {AllS (fun b:A => b <> a) l}.
intros a l.
induction l.
auto.
elim (eqA_dec a a0).
auto.
simpl in |- *. elim IHl; auto.
(*
Realizer mem.
*)
Qed.
(*********************************)
(** Index of elements *)
(*********************************)
Require Import Le.
Require Import Lt.
Inductive nth_spec : list A -> nat -> A -> Prop :=
| nth_spec_O : forall (a:A) (l:list A), nth_spec (a :: l) 1 a
| nth_spec_S :
forall (n:nat) (a b:A) (l:list A),
nth_spec l n a -> nth_spec (b :: l) (S n) a.
Hint Resolve nth_spec_O nth_spec_S.
Inductive fst_nth_spec : list A -> nat -> A -> Prop :=
| fst_nth_O : forall (a:A) (l:list A), fst_nth_spec (a :: l) 1 a
| fst_nth_S :
forall (n:nat) (a b:A) (l:list A),
a <> b -> fst_nth_spec l n a -> fst_nth_spec (b :: l) (S n) a.
Hint Resolve fst_nth_O fst_nth_S.
Lemma fst_nth_nth :
forall (l:list A) (n:nat) (a:A), fst_nth_spec l n a -> nth_spec l n a.
induction 1; auto.
Qed.
Hint Immediate fst_nth_nth.
Lemma nth_lt_O : forall (l:list A) (n:nat) (a:A), nth_spec l n a -> 0 < n.
induction 1; auto.
Qed.
Lemma nth_le_length :
forall (l:list A) (n:nat) (a:A), nth_spec l n a -> n <= length l.
induction 1; simpl in |- *; auto with arith.
Qed.
Fixpoint Nth_func (l:list A) (n:nat) {struct l} : Exc A :=
match l, n with
| a :: _, S O => value a
| _ :: l', S (S p) => Nth_func l' (S p)
| _, _ => error
end.
Lemma Nth :
forall (l:list A) (n:nat),
{a : A | nth_spec l n a} + {n = 0 \/ length l < n}.
induction l as [| a l IHl].
intro n; case n; simpl in |- *; auto with arith.
intro n; destruct n as [| [| n1]]; simpl in |- *; auto.
left; exists a; auto.
destruct (IHl (S n1)) as [[b]| o].
left; exists b; auto.
right; destruct o.
absurd (S n1 = 0); auto.
auto with arith.
(*
Realizer Nth_func.
*)
Qed.
Lemma Item :
forall (l:list A) (n:nat), {a : A | nth_spec l (S n) a} + {length l <= n}.
intros l n; case (Nth l (S n)); intro.
case s; intro a; left; exists a; auto.
right; case o; intro.
absurd (S n = 0); auto.
auto with arith.
Qed.
Require Import Minus.
Require Import DecBool.
Fixpoint index_p (a:A) (l:list A) {struct l} : nat -> Exc nat :=
match l with
| nil => fun p => error
| b :: m => fun p => ifdec (eqA_dec a b) (value p) (index_p a m (S p))
end.
Lemma Index_p :
forall (a:A) (l:list A) (p:nat),
{n : nat | fst_nth_spec l (S n - p) a} + {AllS (fun b:A => a <> b) l}.
induction l as [| b m irec].
auto.
intro p.
destruct (eqA_dec a b) as [e| e].
left; exists p.
destruct e; elim minus_Sn_m; trivial; elim minus_n_n; auto with arith.
destruct (irec (S p)) as [[n H]| ].
left; exists n; auto with arith.
elim minus_Sn_m; auto with arith.
apply lt_le_weak; apply lt_O_minus_lt; apply nth_lt_O with m a;
auto with arith.
auto.
Qed.
Lemma Index :
forall (a:A) (l:list A),
{n : nat | fst_nth_spec l n a} + {AllS (fun b:A => a <> b) l}.
intros a l; case (Index_p a l 1); auto.
intros [n P]; left; exists n; auto.
rewrite (minus_n_O n); trivial.
(*
Realizer (fun a l -> Index_p a l (S O)).
*)
Qed.
Section Find_sec.
Variables R P : A -> Prop.
Inductive InR : list A -> Prop :=
| inR_hd : forall (a:A) (l:list A), R a -> InR (a :: l)
| inR_tl : forall (a:A) (l:list A), InR l -> InR (a :: l).
Hint Resolve inR_hd inR_tl.
Definition InR_inv (l:list A) :=
match l with
| nil => False
| b :: m => R b \/ InR m
end.
Lemma InR_INV : forall l:list A, InR l -> InR_inv l.
induction 1; simpl in |- *; auto.
Qed.
Lemma InR_cons_inv : forall (a:A) (l:list A), InR (a :: l) -> R a \/ InR l.
intros a l H; exact (InR_INV H).
Qed.
Lemma InR_or_app : forall l m:list A, InR l \/ InR m -> InR (l ++ m).
intros l m [| ].
induction 1; simpl in |- *; auto.
intro. induction l; simpl in |- *; auto.
Qed.
Lemma InR_app_or : forall l m:list A, InR (l ++ m) -> InR l \/ InR m.
intros l m; elim l; simpl in |- *; auto.
intros b l' Hrec IAc; elim (InR_cons_inv IAc); auto.
intros; elim Hrec; auto.
Qed.
Hypothesis RS_dec : forall a:A, {R a} + {P a}.
Fixpoint find (l:list A) : Exc A :=
match l with
| nil => error
| a :: m => ifdec (RS_dec a) (value a) (find m)
end.
Lemma Find : forall l:list A, {a : A | In a l & R a} + {AllS P l}.
induction l as [| a m [[b H1 H2]| H]]; auto.
left; exists b; auto.
destruct (RS_dec a).
left; exists a; auto.
auto.
(*
Realizer find.
*)
Qed.
Variable B : Set.
Variable T : A -> B -> Prop.
Variable TS_dec : forall a:A, {c : B | T a c} + {P a}.
Fixpoint try_find (l:list A) : Exc B :=
match l with
| nil => error
| a :: l1 =>
match TS_dec a with
| inleft (exist c _) => value c
| inright _ => try_find l1
end
end.
Lemma Try_find :
forall l:list A, {c : B | exists2 a : A, In a l & T a c} + {AllS P l}.
induction l as [| a m [[b H1]| H]].
auto.
left; exists b; destruct H1 as [a' H2 H3]; exists a'; auto.
destruct (TS_dec a) as [[c H1]| ].
left; exists c.
exists a; auto.
auto.
(*
Realizer try_find.
*)
Qed.
End Find_sec.
Section Assoc_sec.
Variable B : Set.
Fixpoint assoc (a:A) (l:list (A * B)) {struct l} :
Exc B :=
match l with
| nil => error
| (a', b) :: m => ifdec (eqA_dec a a') (value b) (assoc a m)
end.
Inductive AllS_assoc (P:A -> Prop) : list (A * B) -> Prop :=
| allS_assoc_nil : AllS_assoc P nil
| allS_assoc_cons :
forall (a:A) (b:B) (l:list (A * B)),
P a -> AllS_assoc P l -> AllS_assoc P ((a, b) :: l).
Hint Resolve allS_assoc_nil allS_assoc_cons.
(* The specification seems too weak: it is enough to return b if the
list has at least an element (a,b); probably the intention is to have
the specification
(a:A)(l:(list A*B)){b:B|(In_spec (a,b) l)}+{(AllS_assoc [a':A]~(a=a') l)}.
*)
Lemma Assoc :
forall (a:A) (l:list (A * B)), B + {AllS_assoc (fun a':A => a <> a') l}.
induction l as [| [a' b] m assrec]. auto.
destruct (eqA_dec a a').
left; exact b.
destruct assrec as [b'| ].
left; exact b'.
right; auto.
(*
Realizer assoc.
*)
Qed.
End Assoc_sec.
End Lists.
Hint Resolve Isnil_nil not_Isnil_cons in_hd in_tl in_cons allS_nil allS_cons:
datatypes.
Hint Immediate fst_nth_nth: datatypes.
|