From a0cfa4f118023d35b767a999d5a2ac4b082857b4 Mon Sep 17 00:00:00 2001
From: Samuel Mimram <smimram@debian.org>
Date: Fri, 25 Jul 2008 15:12:53 +0200
Subject: Imported Upstream version 8.2~beta3+dfsg

---
 theories/ZArith/ZOdiv_def.v | 136 ++++++++++++++++++++++++++++++++++++++++++++
 1 file changed, 136 insertions(+)
 create mode 100644 theories/ZArith/ZOdiv_def.v

(limited to 'theories/ZArith/ZOdiv_def.v')

diff --git a/theories/ZArith/ZOdiv_def.v b/theories/ZArith/ZOdiv_def.v
new file mode 100644
index 00000000..2c84765e
--- /dev/null
+++ b/theories/ZArith/ZOdiv_def.v
@@ -0,0 +1,136 @@
+(************************************************************************)
+(*  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        *)
+(************************************************************************)
+
+
+Require Import BinPos BinNat Nnat ZArith_base.
+
+Open Scope Z_scope.
+
+Definition NPgeb (a:N)(b:positive) :=
+  match a with
+   | N0 => false
+   | Npos na => match Pcompare na b Eq with Lt => false | _ => true end
+  end.
+
+Fixpoint Pdiv_eucl (a b:positive) {struct a} : N * N :=
+  match a with
+    | xH => 
+       match b with xH => (1, 0)%N | _ => (0, 1)%N end
+    | xO a' =>
+       let (q, r) := Pdiv_eucl a' b in
+       let r' := (2 * r)%N in
+        if (NPgeb r' b) then (2 * q + 1, (Nminus r'  (Npos b)))%N
+        else  (2 * q, r')%N
+    | xI a' =>
+       let (q, r) := Pdiv_eucl a' b in
+       let r' := (2 * r + 1)%N in
+        if (NPgeb r' b) then (2 * q + 1, (Nminus r' (Npos b)))%N
+        else  (2 * q, r')%N
+  end.
+
+Definition ZOdiv_eucl (a b:Z) : Z * Z := 
+  match a, b with
+   | Z0,  _ => (Z0, Z0)
+   | _, Z0  => (Z0, a)
+   | Zpos na, Zpos nb => 
+         let (nq, nr) := Pdiv_eucl na nb in 
+         (Z_of_N nq, Z_of_N nr)
+   | Zneg na, Zpos nb => 
+         let (nq, nr) := Pdiv_eucl na nb in 
+         (Zopp (Z_of_N nq), Zopp (Z_of_N nr))
+   | Zpos na, Zneg nb => 
+         let (nq, nr) := Pdiv_eucl na nb in 
+         (Zopp (Z_of_N nq), Z_of_N nr)
+   | Zneg na, Zneg nb => 
+         let (nq, nr) := Pdiv_eucl na nb in 
+         (Z_of_N nq, Zopp (Z_of_N nr))
+  end.
+
+Definition ZOdiv a b := fst (ZOdiv_eucl a b).
+Definition ZOmod a b := snd (ZOdiv_eucl a b).
+
+
+Definition Ndiv_eucl (a b:N) : N * N := 
+  match a, b with
+   | N0,  _ => (N0, N0)
+   | _, N0  => (N0, a)
+   | Npos na, Npos nb => Pdiv_eucl na nb
+  end.
+
+Definition Ndiv a b := fst (Ndiv_eucl a b).
+Definition Nmod a b := snd (Ndiv_eucl a b).
+
+
+(* Proofs of specifications for these euclidean divisions. *)
+
+Theorem NPgeb_correct: forall (a:N)(b:positive), 
+  if NPgeb a b then a = (Nminus a (Npos b) + Npos b)%N else True.
+Proof.
+  destruct a; intros; simpl; auto.
+  generalize (Pcompare_Eq_eq p b).
+  case_eq (Pcompare p b Eq); intros; auto.
+  rewrite H0; auto. 
+  now rewrite Pminus_mask_diag.
+  destruct (Pminus_mask_Gt p b H) as [d [H2 [H3 _]]].
+  rewrite H2. rewrite <- H3.
+  simpl; f_equal; apply Pplus_comm.
+Qed.
+
+Hint Rewrite Z_of_N_plus Z_of_N_mult Z_of_N_minus Zmult_1_l Zmult_assoc
+ Zmult_plus_distr_l Zmult_plus_distr_r : zdiv. 
+Hint Rewrite <- Zplus_assoc : zdiv. 
+
+Theorem Pdiv_eucl_correct: forall a b,
+  let (q,r) := Pdiv_eucl a b in 
+  Zpos a = Z_of_N q * Zpos b + Z_of_N r.
+Proof.
+  induction a; cbv beta iota delta [Pdiv_eucl]; fold Pdiv_eucl; cbv zeta.
+  intros b; generalize (IHa b); case Pdiv_eucl.
+    intros q1 r1 Hq1.
+     generalize (NPgeb_correct (2 * r1 + 1) b); case NPgeb; intros H.
+     set (u := Nminus (2 * r1 + 1) (Npos b)) in * |- *.
+     assert (HH: Z_of_N u = (Z_of_N (2 * r1 + 1) - Zpos b)%Z).
+        rewrite H; autorewrite with zdiv; simpl.
+        rewrite Zplus_comm, Zminus_plus; trivial.
+     rewrite HH; autorewrite with zdiv; simpl Z_of_N.
+     rewrite Zpos_xI, Hq1.
+     autorewrite with zdiv; f_equal; rewrite Zplus_minus; trivial.
+     rewrite Zpos_xI, Hq1; autorewrite with zdiv; auto.
+  intros b; generalize (IHa b); case Pdiv_eucl.
+    intros q1 r1 Hq1.
+     generalize (NPgeb_correct (2 * r1) b); case NPgeb; intros H.
+     set (u := Nminus (2 * r1) (Npos b)) in * |- *.
+     assert (HH: Z_of_N u = (Z_of_N (2 * r1) - Zpos b)%Z).
+        rewrite H; autorewrite with zdiv; simpl.
+        rewrite Zplus_comm, Zminus_plus; trivial.
+     rewrite HH; autorewrite with zdiv; simpl Z_of_N.
+     rewrite Zpos_xO, Hq1.
+     autorewrite with zdiv; f_equal; rewrite Zplus_minus; trivial.
+     rewrite Zpos_xO, Hq1; autorewrite with zdiv; auto.
+  destruct b; auto.
+Qed.
+
+Theorem ZOdiv_eucl_correct: forall a b,
+  let (q,r) := ZOdiv_eucl a b in a = q * b + r.
+Proof.
+  destruct a; destruct b; simpl; auto;
+  generalize (Pdiv_eucl_correct p p0); case Pdiv_eucl; auto; intros;
+  try change (Zneg p) with (Zopp (Zpos p)); rewrite H.
+    destruct n; auto.
+  repeat (rewrite Zopp_plus_distr || rewrite Zopp_mult_distr_l); trivial.
+  repeat (rewrite Zopp_plus_distr || rewrite Zopp_mult_distr_r); trivial.
+Qed.
+
+Theorem Ndiv_eucl_correct: forall a b,
+  let (q,r) := Ndiv_eucl a b in a = (q * b + r)%N.
+Proof.
+  destruct a; destruct b; simpl; auto;
+  generalize (Pdiv_eucl_correct p p0); case Pdiv_eucl; auto; intros;
+  destruct n; destruct n0; simpl; simpl in H; try discriminate;
+  injection H; intros; subst; trivial.
+Qed.
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