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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 *)
(***********************************************************************)
(*i $Id$ i*)
Require Le.
Require Lt.
Section Between.
Variables P,Q : nat -> Prop.
Inductive between [k:nat] : nat -> Prop
:= bet_emp : (between k k)
| bet_S : (l:nat)(between k l)->(P l)->(between k (S l)).
Hint constr_between : arith v62 := Constructors between.
Lemma bet_eq : (k,l:nat)(l=k)->(between k l).
Proof.
NewInduction 1; Auto with arith.
Qed.
Hints Resolve bet_eq : arith v62.
Lemma between_le : (k,l:nat)(between k l)->(le k l).
Proof.
NewInduction 1; Auto with arith.
Qed.
Hints Immediate between_le : arith v62.
Lemma between_Sk_l : (k,l:nat)(between k l)->(le (S k) l)->(between (S k) l).
Proof.
NewInduction 1.
Intros; Absurd (le (S k) k); Auto with arith.
Induction H; Auto with arith.
Qed.
Hints Resolve between_Sk_l : arith v62.
Lemma between_restr :
(k,l,m:nat)(le k l)->(le l m)->(between k m)->(between l m).
Proof.
NewInduction 1; Auto with arith.
Qed.
Inductive exists [k:nat] : nat -> Prop
:= exists_S : (l:nat)(exists k l)->(exists k (S l))
| exists_le: (l:nat)(le k l)->(Q l)->(exists k (S l)).
Hint constr_exists : arith v62 := Constructors exists.
Lemma exists_le_S : (k,l:nat)(exists k l)->(le (S k) l).
Proof.
NewInduction 1; Auto with arith.
Qed.
Lemma exists_lt : (k,l:nat)(exists k l)->(lt k l).
Proof exists_le_S.
Hints Immediate exists_le_S exists_lt : arith v62.
Lemma exists_S_le : (k,l:nat)(exists k (S l))->(le k l).
Proof.
Intros; Apply le_S_n; Auto with arith.
Qed.
Hints Immediate exists_S_le : arith v62.
Definition in_int := [p,q,r:nat](le p r)/\(lt r q).
Lemma in_int_intro : (p,q,r:nat)(le p r)->(lt r q)->(in_int p q r).
Proof.
Red; Auto with arith.
Qed.
Hints Resolve in_int_intro : arith v62.
Lemma in_int_lt : (p,q,r:nat)(in_int p q r)->(lt p q).
Proof.
NewInduction 1; Intros.
Apply le_lt_trans with r; Auto with arith.
Qed.
Lemma in_int_p_Sq :
(p,q,r:nat)(in_int p (S q) r)->((in_int p q r) \/ <nat>r=q).
Proof.
NewInduction 1; Intros.
Elim (le_lt_or_eq r q); Auto with arith.
Qed.
Lemma in_int_S : (p,q,r:nat)(in_int p q r)->(in_int p (S q) r).
Proof.
NewInduction 1;Auto with arith.
Qed.
Hints Resolve in_int_S : arith v62.
Lemma in_int_Sp_q : (p,q,r:nat)(in_int (S p) q r)->(in_int p q r).
Proof.
NewInduction 1; Auto with arith.
Qed.
Hints Immediate in_int_Sp_q : arith v62.
Lemma between_in_int : (k,l:nat)(between k l)->(r:nat)(in_int k l r)->(P r).
Proof.
NewInduction 1; Intros.
Absurd (lt k k); Auto with arith.
Apply in_int_lt with r; Auto with arith.
Elim (in_int_p_Sq k l r); Intros; Auto with arith.
Rewrite H2; Trivial with arith.
Qed.
Lemma in_int_between :
(k,l:nat)(le k l)->((r:nat)(in_int k l r)->(P r))->(between k l).
Proof.
NewInduction 1; Auto with arith.
Qed.
Lemma exists_in_int :
(k,l:nat)(exists k l)->(EX m:nat | (in_int k l m) & (Q m)).
Proof.
NewInduction 1.
Case IHexists; Intros p inp Qp; Exists p; Auto with arith.
Exists l; Auto with arith.
Qed.
Lemma in_int_exists : (k,l,r:nat)(in_int k l r)->(Q r)->(exists k l).
Proof.
NewDestruct 1; Intros.
Elim H0; Auto with arith.
Qed.
Lemma between_or_exists :
(k,l:nat)(le k l)->((n:nat)(in_int k l n)->((P n)\/(Q n)))
->((between k l)\/(exists k l)).
Proof.
NewInduction 1; Intros; Auto with arith.
Elim IHle; Intro; Auto with arith.
Elim (H0 m); Auto with arith.
Qed.
Lemma between_not_exists : (k,l:nat)(between k l)->
((n:nat)(in_int k l n) -> (P n) -> ~(Q n))
-> ~(exists k l).
Proof.
NewInduction 1; Red; Intros.
Absurd (lt k k); Auto with arith.
Absurd (Q l); Auto with arith.
Elim (exists_in_int k (S l)); Auto with arith; Intros l' inl' Ql'.
Replace l with l'; Auto with arith.
Elim inl'; Intros.
Elim (le_lt_or_eq l' l); Auto with arith; Intros.
Absurd (exists k l); Auto with arith.
Apply in_int_exists with l'; Auto with arith.
Qed.
Inductive P_nth [init:nat] : nat->nat->Prop
:= nth_O : (P_nth init init O)
| nth_S : (k,l:nat)(n:nat)(P_nth init k n)->(between (S k) l)
->(Q l)->(P_nth init l (S n)).
Lemma nth_le : (init,l,n:nat)(P_nth init l n)->(le init l).
Proof.
NewInduction 1; Intros; Auto with arith.
Apply le_trans with (S k); Auto with arith.
Qed.
Definition eventually := [n:nat](EX k:nat | (le k n) & (Q k)).
Lemma event_O : (eventually O)->(Q O).
Proof.
NewInduction 1; Intros.
Replace O with x; Auto with arith.
Qed.
End Between.
Hints Resolve nth_O bet_S bet_emp bet_eq between_Sk_l exists_S exists_le
in_int_S in_int_intro : arith v62.
Hints Immediate in_int_Sp_q exists_le_S exists_S_le : arith v62.
|