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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       *)
(***********************************************************************)

(* $Id$ *)

Require Export Bool.

Set Implicit Arguments.

Section Theory_of_semi_rings.

Variable A : Type.
Variable Aplus : A -> A -> A.
Variable Amult : A -> A -> A.
Variable Aone : A.
Variable Azero : A.
(* There is also a "weakly decidable" equality on A. That means 
  that if (A_eq x y)=true then x=y but x=y can arise when 
  (A_eq x y)=false. On an abstract ring the function [x,y:A]false
  is a good choice. The proof of A_eq_prop is in this case easy. *)
Variable Aeq : A -> A -> bool.

Infix 4 "+" Aplus V8only 40 (left associativity).
Infix 4 "*" Amult V8only 30 (left associativity).
Notation "0" := Azero.
Notation "1" := Aone.

Record Semi_Ring_Theory : Prop :=
{ SR_plus_sym  : (n,m:A) n + m == m + n;
  SR_plus_assoc : (n,m,p:A) n + (m + p) == (n + m) + p;
  SR_mult_sym : (n,m:A) n*m == m*n;
  SR_mult_assoc : (n,m,p:A) n*(m*p) == (n*m)*p;
  SR_plus_zero_left :(n:A) 0 + n == n;
  SR_mult_one_left : (n:A) 1*n == n;
  SR_mult_zero_left : (n:A) 0*n == 0;
  SR_distr_left   : (n,m,p:A) (n + m)*p == n*p + m*p;
  SR_plus_reg_left : (n,m,p:A) n + m == n + p -> m==p;
  SR_eq_prop : (x,y:A) (Is_true (Aeq x y)) -> x==y
}.

Variable T : Semi_Ring_Theory.

Local plus_sym  := (SR_plus_sym T).
Local plus_assoc := (SR_plus_assoc T).
Local mult_sym  := ( SR_mult_sym T).
Local mult_assoc := (SR_mult_assoc T).
Local plus_zero_left := (SR_plus_zero_left T).
Local mult_one_left := (SR_mult_one_left T). 
Local mult_zero_left := (SR_mult_zero_left T).
Local distr_left := (SR_distr_left T).
Local plus_reg_left := (SR_plus_reg_left T).

Hints Resolve  plus_sym plus_assoc mult_sym mult_assoc
  plus_zero_left mult_one_left mult_zero_left distr_left
  plus_reg_left.

(* Lemmas whose form is x=y are also provided in form y=x because Auto does
  not symmetry *) 
Lemma SR_mult_assoc2 : (n,m,p:A) (n * m) * p == n * (m * p).
Symmetry; EAuto. Qed.

Lemma SR_plus_assoc2 : (n,m,p:A) (n + m) + p == n + (m + p).
Symmetry; EAuto. Qed.

Lemma SR_plus_zero_left2 : (n:A) n == 0 + n.
Symmetry; EAuto. Qed.

Lemma SR_mult_one_left2 : (n:A) n == 1*n.
Symmetry; EAuto. Qed.

Lemma SR_mult_zero_left2 : (n:A) 0 == 0*n.
Symmetry; EAuto. Qed.

Lemma SR_distr_left2 : (n,m,p:A) n*p + m*p  == (n + m)*p.
Symmetry; EAuto. Qed.

Lemma SR_plus_permute : (n,m,p:A) n + (m + p) == m + (n + p).
Intros.
Rewrite -> plus_assoc.
Elim (plus_sym m n).
Rewrite <- plus_assoc.
Reflexivity.
Qed.

Lemma SR_mult_permute : (n,m,p:A) n*(m*p) == m*(n*p).
Intros.
Rewrite -> mult_assoc.
Elim (mult_sym m n).
Rewrite <- mult_assoc.
Reflexivity.
Qed.

Hints Resolve SR_plus_permute SR_mult_permute.

Lemma SR_distr_right : (n,m,p:A) n*(m + p) == (n*m) + (n*p).
Intros.
Repeat Rewrite -> (mult_sym n).
EAuto.
Qed.

Lemma SR_distr_right2 : (n,m,p:A) (n*m) + (n*p) == n*(m + p).
Symmetry; Apply SR_distr_right. Qed.

Lemma SR_mult_zero_right : (n:A) n*0 == 0.
Intro; Rewrite mult_sym; EAuto.
Qed.

Lemma SR_mult_zero_right2 : (n:A) 0 == n*0.
Intro; Rewrite mult_sym; EAuto.
Qed.

Lemma SR_plus_zero_right :(n:A) n + 0 == n.
Intro; Rewrite plus_sym; EAuto.
Qed.
Lemma SR_plus_zero_right2 :(n:A) n == n + 0.
Intro; Rewrite plus_sym; EAuto.
Qed.

Lemma SR_mult_one_right : (n:A) n*1 == n.
Intro; Elim mult_sym; Auto.
Qed.

Lemma SR_mult_one_right2 : (n:A) n == n*1.
Intro; Elim mult_sym; Auto.
Qed.

Lemma SR_plus_reg_right : (n,m,p:A) m + n == p + n -> m==p.
Intros n m p; Rewrite (plus_sym m n); Rewrite (plus_sym p n); EAuto.
Qed.

End Theory_of_semi_rings.

Section Theory_of_rings.

Variable A : Type.

Variable Aplus : A -> A -> A.
Variable Amult : A -> A -> A.
Variable Aone : A.
Variable Azero : A.
Variable Aopp : A -> A.
Variable Aeq : A -> A -> bool.

Infix 4 "+" Aplus V8only 40 (left associativity).
Infix 4 "*" Amult V8only 30 (left associativity).
Notation "0" := Azero.
Notation "1" := Aone.
Notation "- 0" := (Aopp Azero) (at level 0)
  V8only (at level 40, left associativity).
Notation "- 1" := (Aopp Aone) (at level 0)
  V8only (at level 40, left associativity).
Notation "- x" := (Aopp x) (at level 0)
  V8only (at level 40, left associativity).

Record Ring_Theory : Prop :=
{ Th_plus_sym  : (n,m:A) n + m == m + n;
  Th_plus_assoc : (n,m,p:A) n + (m + p) == (n + m) + p;
  Th_mult_sym : (n,m:A) n*m == m*n;
  Th_mult_assoc : (n,m,p:A) n*(m*p) == (n*m)*p;
  Th_plus_zero_left :(n:A) 0 + n == n;
  Th_mult_one_left : (n:A) 1*n == n;
  Th_opp_def : (n:A) n + (-n) == 0;
  Th_distr_left : (n,m,p:A) (n + m)*p == n*p + m*p;
  Th_eq_prop : (x,y:A) (Is_true (Aeq x y)) -> x==y
}.

Variable T : Ring_Theory.

Local plus_sym  := (Th_plus_sym T).
Local plus_assoc := (Th_plus_assoc T).
Local mult_sym  := ( Th_mult_sym T).
Local mult_assoc := (Th_mult_assoc T).
Local plus_zero_left := (Th_plus_zero_left T).
Local mult_one_left := (Th_mult_one_left T). 
Local opp_def := (Th_opp_def T).
Local distr_left := (Th_distr_left T).

Hints Resolve plus_sym plus_assoc mult_sym mult_assoc
  plus_zero_left mult_one_left opp_def distr_left.

(* Lemmas whose form is x=y are also provided in form y=x because Auto does
  not symmetry *) 
Lemma Th_mult_assoc2 : (n,m,p:A) (n * m) * p == n * (m * p).
Symmetry; EAuto. Qed.

Lemma Th_plus_assoc2 : (n,m,p:A) (n + m) + p == n + (m + p).
Symmetry; EAuto. Qed.

Lemma Th_plus_zero_left2 : (n:A) n == 0 + n.
Symmetry; EAuto. Qed.

Lemma Th_mult_one_left2 : (n:A) n == 1*n.
Symmetry; EAuto. Qed.

Lemma Th_distr_left2 : (n,m,p:A) n*p + m*p  == (n + m)*p.
Symmetry; EAuto. Qed.

Lemma Th_opp_def2 : (n:A) 0 == n + (-n).
Symmetry; EAuto. Qed.

Lemma Th_plus_permute : (n,m,p:A) n + (m + p) == m + (n + p).
Intros.
Rewrite -> plus_assoc.
Elim (plus_sym m n).
Rewrite <- plus_assoc.
Reflexivity.
Qed.

Lemma Th_mult_permute : (n,m,p:A) n*(m*p) == m*(n*p).
Intros.
Rewrite -> mult_assoc.
Elim (mult_sym m n).
Rewrite <- mult_assoc.
Reflexivity.
Qed.

Hints Resolve Th_plus_permute Th_mult_permute.

Lemma aux1 : (a:A) a + a == a -> a == 0.
Intros.
Generalize (opp_def a).
Pattern 1 a.
Rewrite <- H.
Rewrite <- plus_assoc.
Rewrite -> opp_def.
Elim plus_sym.
Rewrite plus_zero_left.
Trivial.
Qed.

Lemma Th_mult_zero_left :(n:A) 0*n == 0.
Intros.
Apply aux1.
Rewrite <- distr_left.
Rewrite plus_zero_left.
Reflexivity.
Qed.
Hints Resolve Th_mult_zero_left.

Lemma Th_mult_zero_left2 : (n:A) 0 == 0*n.
Symmetry; EAuto. Qed.

Lemma aux2 : (x,y,z:A) x+y==0 -> x+z==0 -> y==z.
Intros.
Rewrite <- (plus_zero_left y).
Elim H0.
Elim plus_assoc.
Elim (plus_sym y z).
Rewrite -> plus_assoc.
Rewrite -> H.
Rewrite plus_zero_left.
Reflexivity.
Qed.

Lemma Th_opp_mult_left : (x,y:A) -(x*y) == (-x)*y.
Intros.
Apply (aux2 1!x*y);
[ Apply opp_def
| Rewrite <- distr_left;
  Rewrite -> opp_def;
  Auto].
Qed.
Hints Resolve Th_opp_mult_left.

Lemma Th_opp_mult_left2 : (x,y:A) (-x)*y == -(x*y).
Symmetry; EAuto. Qed.

Lemma Th_mult_zero_right : (n:A) n*0 == 0.
Intro; Elim mult_sym; EAuto.
Qed.

Lemma Th_mult_zero_right2 : (n:A) 0 == n*0.
Intro; Elim mult_sym; EAuto.
Qed.

Lemma Th_plus_zero_right :(n:A) n + 0 == n.
Intro; Rewrite plus_sym; EAuto.
Qed.

Lemma Th_plus_zero_right2 :(n:A) n == n + 0.
Intro; Rewrite plus_sym; EAuto.
Qed.

Lemma Th_mult_one_right : (n:A) n*1 == n.
Intro;Elim mult_sym; EAuto.
Qed.

Lemma Th_mult_one_right2  : (n:A) n == n*1.
Intro;Elim mult_sym; EAuto.
Qed.

Lemma Th_opp_mult_right : (x,y:A) -(x*y) == x*(-y).
Intros; Do 2 Rewrite -> (mult_sym x); Auto.
Qed.

Lemma Th_opp_mult_right2 : (x,y:A) x*(-y) == -(x*y).
Intros; Do 2 Rewrite -> (mult_sym x); Auto.
Qed.

Lemma Th_plus_opp_opp : (x,y:A) (-x) + (-y) == -(x+y).
Intros.
Apply (aux2 1! x + y);
[ Elim plus_assoc;
  Rewrite -> (Th_plus_permute y (-x)); Rewrite -> plus_assoc;
  Rewrite -> opp_def;  Rewrite plus_zero_left; Auto
| Auto ].
Qed.

Lemma Th_plus_permute_opp: (n,m,p:A) (-m)+(n+p) == n+((-m)+p).
EAuto. Qed.

Lemma Th_opp_opp : (n:A) -(-n) == n.
Intro; Apply (aux2 1! -n); 
  [ Auto | Elim plus_sym; Auto ].
Qed.
Hints Resolve Th_opp_opp.

Lemma Th_opp_opp2 : (n:A) n == -(-n).
Symmetry; EAuto. Qed.

Lemma Th_mult_opp_opp : (x,y:A) (-x)*(-y) == x*y.
Intros; Rewrite <- Th_opp_mult_left; Rewrite <- Th_opp_mult_right; Auto.
Qed.

Lemma Th_mult_opp_opp2 : (x,y:A) x*y == (-x)*(-y).
Symmetry; Apply Th_mult_opp_opp. Qed.

Lemma Th_opp_zero : -0 == 0.
Rewrite <- (plus_zero_left (-0)).
Auto. Qed.

Lemma Th_plus_reg_left : (n,m,p:A) n + m == n + p -> m==p.
Intros; Generalize (congr_eqT ? ? [z] (-n)+z ? ? H).
Repeat Rewrite plus_assoc.
Rewrite (plus_sym (-n) n).
Rewrite opp_def.
Repeat Rewrite Th_plus_zero_left; EAuto.
Qed.

Lemma Th_plus_reg_right : (n,m,p:A) m + n == p + n -> m==p.
Intros.
EApply Th_plus_reg_left with n. 
Rewrite (plus_sym n m).
Rewrite (plus_sym n p).
Auto.
Qed.

Lemma Th_distr_right : (n,m,p:A)  n*(m + p) == (n*m) + (n*p).
Intros.
Repeat Rewrite -> (mult_sym n).
EAuto.
Qed.

Lemma Th_distr_right2  : (n,m,p:A) (n*m) + (n*p) == n*(m + p).
Symmetry; Apply Th_distr_right.
Qed.

End Theory_of_rings.

Hints Resolve Th_mult_zero_left Th_plus_reg_left : core.

Unset Implicit Arguments.

Definition Semi_Ring_Theory_of :
  (A:Type)(Aplus : A -> A -> A)(Amult : A -> A -> A)(Aone : A)
  (Azero : A)(Aopp : A -> A)(Aeq : A -> A -> bool)
  (Ring_Theory Aplus Amult Aone Azero Aopp Aeq)
    ->(Semi_Ring_Theory Aplus Amult Aone Azero Aeq).
Intros until 1; Case H.
Split; Intros; Simpl; EAuto.
Defined.

(* Every ring can be viewed as a semi-ring : this property will be used
  in Abstract_polynom. *)
Coercion Semi_Ring_Theory_of : Ring_Theory >-> Semi_Ring_Theory.


Section product_ring.

End product_ring.

Section power_ring.

End power_ring.