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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2014 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
Require Import Setoid Morphisms BinPos BinNat.
Set Implicit Arguments.
Module RingSyntax.
Reserved Notation "x ?=! y" (at level 70, no associativity).
Reserved Notation "x +! y " (at level 50, left associativity).
Reserved Notation "x -! y" (at level 50, left associativity).
Reserved Notation "x *! y" (at level 40, left associativity).
Reserved Notation "-! x" (at level 35, right associativity).
Reserved Notation "[ x ]" (at level 0).
Reserved Notation "x ?== y" (at level 70, no associativity).
Reserved Notation "x -- y" (at level 50, left associativity).
Reserved Notation "x ** y" (at level 40, left associativity).
Reserved Notation "-- x" (at level 35, right associativity).
Reserved Notation "x == y" (at level 70, no associativity).
End RingSyntax.
Import RingSyntax.
Section Power.
Variable R:Type.
Variable rI : R.
Variable rmul : R -> R -> R.
Variable req : R -> R -> Prop.
Variable Rsth : Equivalence req.
Infix "*" := rmul.
Infix "==" := req.
Hypothesis mul_ext : Proper (req ==> req ==> req) rmul.
Hypothesis mul_assoc : forall x y z, x * (y * z) == (x * y) * z.
Fixpoint pow_pos (x:R) (i:positive) : R :=
match i with
| xH => x
| xO i => let p := pow_pos x i in p * p
| xI i => let p := pow_pos x i in x * (p * p)
end.
Lemma pow_pos_swap x j : pow_pos x j * x == x * pow_pos x j.
Proof.
induction j; simpl; rewrite <- ?mul_assoc.
- f_equiv. now do 2 (rewrite IHj, mul_assoc).
- now do 2 (rewrite IHj, mul_assoc).
- reflexivity.
Qed.
Lemma pow_pos_succ x j :
pow_pos x (Pos.succ j) == x * pow_pos x j.
Proof.
induction j; simpl; try reflexivity.
rewrite IHj, <- mul_assoc; f_equiv.
now rewrite mul_assoc, pow_pos_swap, mul_assoc.
Qed.
Lemma pow_pos_add x i j :
pow_pos x (i + j) == pow_pos x i * pow_pos x j.
Proof.
induction i using Pos.peano_ind.
- now rewrite Pos.add_1_l, pow_pos_succ.
- now rewrite Pos.add_succ_l, !pow_pos_succ, IHi, mul_assoc.
Qed.
Definition pow_N (x:R) (p:N) :=
match p with
| N0 => rI
| Npos p => pow_pos x p
end.
Definition id_phi_N (x:N) : N := x.
Lemma pow_N_pow_N x n : pow_N x (id_phi_N n) == pow_N x n.
Proof.
reflexivity.
Qed.
End Power.
Section DEFINITIONS.
Variable R : Type.
Variable (rO rI : R) (radd rmul rsub: R->R->R) (ropp : R -> R).
Variable req : R -> R -> Prop.
Notation "0" := rO. Notation "1" := rI.
Infix "==" := req. Infix "+" := radd. Infix "*" := rmul.
Infix "-" := rsub. Notation "- x" := (ropp x).
(** Semi Ring *)
Record semi_ring_theory : Prop := mk_srt {
SRadd_0_l : forall n, 0 + n == n;
SRadd_comm : forall n m, n + m == m + n ;
SRadd_assoc : forall n m p, n + (m + p) == (n + m) + p;
SRmul_1_l : forall n, 1*n == n;
SRmul_0_l : forall n, 0*n == 0;
SRmul_comm : forall n m, n*m == m*n;
SRmul_assoc : forall n m p, n*(m*p) == (n*m)*p;
SRdistr_l : forall n m p, (n + m)*p == n*p + m*p
}.
(** Almost Ring *)
(*Almost ring are no ring : Ropp_def is missing **)
Record almost_ring_theory : Prop := mk_art {
ARadd_0_l : forall x, 0 + x == x;
ARadd_comm : forall x y, x + y == y + x;
ARadd_assoc : forall x y z, x + (y + z) == (x + y) + z;
ARmul_1_l : forall x, 1 * x == x;
ARmul_0_l : forall x, 0 * x == 0;
ARmul_comm : forall x y, x * y == y * x;
ARmul_assoc : forall x y z, x * (y * z) == (x * y) * z;
ARdistr_l : forall x y z, (x + y) * z == (x * z) + (y * z);
ARopp_mul_l : forall x y, -(x * y) == -x * y;
ARopp_add : forall x y, -(x + y) == -x + -y;
ARsub_def : forall x y, x - y == x + -y
}.
(** Ring *)
Record ring_theory : Prop := mk_rt {
Radd_0_l : forall x, 0 + x == x;
Radd_comm : forall x y, x + y == y + x;
Radd_assoc : forall x y z, x + (y + z) == (x + y) + z;
Rmul_1_l : forall x, 1 * x == x;
Rmul_comm : forall x y, x * y == y * x;
Rmul_assoc : forall x y z, x * (y * z) == (x * y) * z;
Rdistr_l : forall x y z, (x + y) * z == (x * z) + (y * z);
Rsub_def : forall x y, x - y == x + -y;
Ropp_def : forall x, x + (- x) == 0
}.
(** Equality is extensional *)
Record sring_eq_ext : Prop := mk_seqe {
(* SRing operators are compatible with equality *)
SRadd_ext : Proper (req ==> req ==> req) radd;
SRmul_ext : Proper (req ==> req ==> req) rmul
}.
Record ring_eq_ext : Prop := mk_reqe {
(* Ring operators are compatible with equality *)
Radd_ext : Proper (req ==> req ==> req) radd;
Rmul_ext : Proper (req ==> req ==> req) rmul;
Ropp_ext : Proper (req ==> req) ropp
}.
(** Interpretation morphisms definition*)
Section MORPHISM.
Variable C:Type.
Variable (cO cI : C) (cadd cmul csub : C->C->C) (copp : C->C).
Variable ceqb : C->C->bool.
(* [phi] est un morphisme de [C] dans [R] *)
Variable phi : C -> R.
Infix "+!" := cadd. Infix "-!" := csub.
Infix "*!" := cmul. Notation "-! x" := (copp x).
Infix "?=!" := ceqb. Notation "[ x ]" := (phi x).
(*for semi rings*)
Record semi_morph : Prop := mkRmorph {
Smorph0 : [cO] == 0;
Smorph1 : [cI] == 1;
Smorph_add : forall x y, [x +! y] == [x]+[y];
Smorph_mul : forall x y, [x *! y] == [x]*[y];
Smorph_eq : forall x y, x?=!y = true -> [x] == [y]
}.
(* for rings*)
Record ring_morph : Prop := mkmorph {
morph0 : [cO] == 0;
morph1 : [cI] == 1;
morph_add : forall x y, [x +! y] == [x]+[y];
morph_sub : forall x y, [x -! y] == [x]-[y];
morph_mul : forall x y, [x *! y] == [x]*[y];
morph_opp : forall x, [-!x] == -[x];
morph_eq : forall x y, x?=!y = true -> [x] == [y]
}.
Section SIGN.
Variable get_sign : C -> option C.
Record sign_theory : Prop := mksign_th {
sign_spec : forall c c', get_sign c = Some c' -> c ?=! -! c' = true
}.
End SIGN.
Definition get_sign_None (c:C) := @None C.
Lemma get_sign_None_th : sign_theory get_sign_None.
Proof. constructor;intros;discriminate. Qed.
Section DIV.
Variable cdiv: C -> C -> C*C.
Record div_theory : Prop := mkdiv_th {
div_eucl_th : forall a b, let (q,r) := cdiv a b in [a] == [b *! q +! r]
}.
End DIV.
End MORPHISM.
(** Identity is a morphism *)
Variable Rsth : Equivalence req.
Variable reqb : R->R->bool.
Hypothesis morph_req : forall x y, (reqb x y) = true -> x == y.
Definition IDphi (x:R) := x.
Lemma IDmorph : ring_morph rO rI radd rmul rsub ropp reqb IDphi.
Proof.
now apply (mkmorph rO rI radd rmul rsub ropp reqb IDphi).
Qed.
(** Specification of the power function *)
Section POWER.
Variable Cpow : Type.
Variable Cp_phi : N -> Cpow.
Variable rpow : R -> Cpow -> R.
Record power_theory : Prop := mkpow_th {
rpow_pow_N : forall r n, req (rpow r (Cp_phi n)) (pow_N rI rmul r n)
}.
End POWER.
Definition pow_N_th :=
mkpow_th id_phi_N (pow_N rI rmul) (pow_N_pow_N rI rmul Rsth).
End DEFINITIONS.
Section ALMOST_RING.
Variable R : Type.
Variable (rO rI : R) (radd rmul rsub: R->R->R) (ropp : R -> R).
Variable req : R -> R -> Prop.
Notation "0" := rO. Notation "1" := rI.
Infix "==" := req. Infix "+" := radd. Infix "* " := rmul.
Infix "-" := rsub. Notation "- x" := (ropp x).
(** Leibniz equality leads to a setoid theory and is extensional*)
Lemma Eqsth : Equivalence (@eq R).
Proof. exact eq_equivalence. Qed.
Lemma Eq_s_ext : sring_eq_ext radd rmul (@eq R).
Proof. constructor;solve_proper. Qed.
Lemma Eq_ext : ring_eq_ext radd rmul ropp (@eq R).
Proof. constructor;solve_proper. Qed.
Variable Rsth : Equivalence req.
Section SEMI_RING.
Variable SReqe : sring_eq_ext radd rmul req.
Add Morphism radd : radd_ext1. exact (SRadd_ext SReqe). Qed.
Add Morphism rmul : rmul_ext1. exact (SRmul_ext SReqe). Qed.
Variable SRth : semi_ring_theory 0 1 radd rmul req.
(** Every semi ring can be seen as an almost ring, by taking :
-x = x and x - y = x + y *)
Definition SRopp (x:R) := x. Notation "- x" := (SRopp x).
Definition SRsub x y := x + -y. Notation "x - y " := (SRsub x y).
Lemma SRopp_ext : forall x y, x == y -> -x == -y.
Proof. intros x y H; exact H. Qed.
Lemma SReqe_Reqe : ring_eq_ext radd rmul SRopp req.
Proof.
constructor.
- exact (SRadd_ext SReqe).
- exact (SRmul_ext SReqe).
- exact SRopp_ext.
Qed.
Lemma SRopp_mul_l : forall x y, -(x * y) == -x * y.
Proof. reflexivity. Qed.
Lemma SRopp_add : forall x y, -(x + y) == -x + -y.
Proof. reflexivity. Qed.
Lemma SRsub_def : forall x y, x - y == x + -y.
Proof. reflexivity. Qed.
Lemma SRth_ARth : almost_ring_theory 0 1 radd rmul SRsub SRopp req.
Proof (mk_art 0 1 radd rmul SRsub SRopp req
(SRadd_0_l SRth) (SRadd_comm SRth) (SRadd_assoc SRth)
(SRmul_1_l SRth) (SRmul_0_l SRth)
(SRmul_comm SRth) (SRmul_assoc SRth) (SRdistr_l SRth)
SRopp_mul_l SRopp_add SRsub_def).
(** Identity morphism for semi-ring equipped with their almost-ring structure*)
Variable reqb : R->R->bool.
Hypothesis morph_req : forall x y, (reqb x y) = true -> x == y.
Definition SRIDmorph : ring_morph 0 1 radd rmul SRsub SRopp req
0 1 radd rmul SRsub SRopp reqb (@IDphi R).
Proof.
now apply mkmorph.
Qed.
(* a semi_morph can be extended to a ring_morph for the almost_ring derived
from a semi_ring, provided the ring is a setoid (we only need
reflexivity) *)
Variable C : Type.
Variable (cO cI : C) (cadd cmul: C->C->C).
Variable (ceqb : C -> C -> bool).
Variable phi : C -> R.
Variable Smorph : semi_morph rO rI radd rmul req cO cI cadd cmul ceqb phi.
Lemma SRmorph_Rmorph :
ring_morph rO rI radd rmul SRsub SRopp req
cO cI cadd cmul cadd (fun x => x) ceqb phi.
Proof.
case Smorph; now constructor.
Qed.
End SEMI_RING.
Variable Reqe : ring_eq_ext radd rmul ropp req.
Add Morphism radd : radd_ext2. exact (Radd_ext Reqe). Qed.
Add Morphism rmul : rmul_ext2. exact (Rmul_ext Reqe). Qed.
Add Morphism ropp : ropp_ext2. exact (Ropp_ext Reqe). Qed.
Section RING.
Variable Rth : ring_theory 0 1 radd rmul rsub ropp req.
(** Rings are almost rings*)
Lemma Rmul_0_l x : 0 * x == 0.
Proof.
setoid_replace (0*x) with ((0+1)*x + -x).
now rewrite (Radd_0_l Rth), (Rmul_1_l Rth), (Ropp_def Rth).
rewrite (Rdistr_l Rth), (Rmul_1_l Rth).
rewrite <- (Radd_assoc Rth), (Ropp_def Rth).
now rewrite (Radd_comm Rth), (Radd_0_l Rth).
Qed.
Lemma Ropp_mul_l x y : -(x * y) == -x * y.
Proof.
rewrite <-(Radd_0_l Rth (- x * y)).
rewrite (Radd_comm Rth), <-(Ropp_def Rth (x*y)).
rewrite (Radd_assoc Rth), <- (Rdistr_l Rth).
rewrite (Rth.(Radd_comm) (-x)), (Ropp_def Rth).
now rewrite Rmul_0_l, (Radd_0_l Rth).
Qed.
Lemma Ropp_add x y : -(x + y) == -x + -y.
Proof.
rewrite <- ((Radd_0_l Rth) (-(x+y))).
rewrite <- ((Ropp_def Rth) x).
rewrite <- ((Radd_0_l Rth) (x + - x + - (x + y))).
rewrite <- ((Ropp_def Rth) y).
rewrite ((Radd_comm Rth) x).
rewrite ((Radd_comm Rth) y).
rewrite <- ((Radd_assoc Rth) (-y)).
rewrite <- ((Radd_assoc Rth) (- x)).
rewrite ((Radd_assoc Rth) y).
rewrite ((Radd_comm Rth) y).
rewrite <- ((Radd_assoc Rth) (- x)).
rewrite ((Radd_assoc Rth) y).
rewrite ((Radd_comm Rth) y), (Ropp_def Rth).
rewrite ((Radd_comm Rth) (-x) 0), (Radd_0_l Rth).
now apply (Radd_comm Rth).
Qed.
Lemma Ropp_opp x : - -x == x.
Proof.
rewrite <- (Radd_0_l Rth (- -x)).
rewrite <- (Ropp_def Rth x).
rewrite <- (Radd_assoc Rth), (Ropp_def Rth).
rewrite ((Radd_comm Rth) x); now apply (Radd_0_l Rth).
Qed.
Lemma Rth_ARth : almost_ring_theory 0 1 radd rmul rsub ropp req.
Proof
(mk_art 0 1 radd rmul rsub ropp req (Radd_0_l Rth) (Radd_comm Rth) (Radd_assoc Rth)
(Rmul_1_l Rth) Rmul_0_l (Rmul_comm Rth) (Rmul_assoc Rth) (Rdistr_l Rth)
Ropp_mul_l Ropp_add (Rsub_def Rth)).
(** Every semi morphism between two rings is a morphism*)
Variable C : Type.
Variable (cO cI : C) (cadd cmul csub: C->C->C) (copp : C -> C).
Variable (ceq : C -> C -> Prop) (ceqb : C -> C -> bool).
Variable phi : C -> R.
Infix "+!" := cadd. Infix "*!" := cmul.
Infix "-!" := csub. Notation "-! x" := (copp x).
Notation "?=!" := ceqb. Notation "[ x ]" := (phi x).
Variable Csth : Equivalence ceq.
Variable Ceqe : ring_eq_ext cadd cmul copp ceq.
Add Setoid C ceq Csth as C_setoid.
Add Morphism cadd : cadd_ext. exact (Radd_ext Ceqe). Qed.
Add Morphism cmul : cmul_ext. exact (Rmul_ext Ceqe). Qed.
Add Morphism copp : copp_ext. exact (Ropp_ext Ceqe). Qed.
Variable Cth : ring_theory cO cI cadd cmul csub copp ceq.
Variable Smorph : semi_morph 0 1 radd rmul req cO cI cadd cmul ceqb phi.
Variable phi_ext : forall x y, ceq x y -> [x] == [y].
Add Morphism phi : phi_ext1. exact phi_ext. Qed.
Lemma Smorph_opp x : [-!x] == -[x].
Proof.
rewrite <- (Rth.(Radd_0_l) [-!x]).
rewrite <- ((Ropp_def Rth) [x]).
rewrite ((Radd_comm Rth) [x]).
rewrite <- (Radd_assoc Rth).
rewrite <- (Smorph_add Smorph).
rewrite (Ropp_def Cth).
rewrite (Smorph0 Smorph).
rewrite (Radd_comm Rth (-[x])).
now apply (Radd_0_l Rth).
Qed.
Lemma Smorph_sub x y : [x -! y] == [x] - [y].
Proof.
rewrite (Rsub_def Cth), (Rsub_def Rth).
now rewrite (Smorph_add Smorph), Smorph_opp.
Qed.
Lemma Smorph_morph :
ring_morph 0 1 radd rmul rsub ropp req
cO cI cadd cmul csub copp ceqb phi.
Proof
(mkmorph 0 1 radd rmul rsub ropp req cO cI cadd cmul csub copp ceqb phi
(Smorph0 Smorph) (Smorph1 Smorph)
(Smorph_add Smorph) Smorph_sub (Smorph_mul Smorph) Smorph_opp
(Smorph_eq Smorph)).
End RING.
(** Useful lemmas on almost ring *)
Variable ARth : almost_ring_theory 0 1 radd rmul rsub ropp req.
Lemma ARth_SRth : semi_ring_theory 0 1 radd rmul req.
Proof.
elim ARth; intros.
constructor; trivial.
Qed.
Instance ARsub_ext : Proper (req ==> req ==> req) rsub.
Proof.
intros x1 x2 Ex y1 y2 Ey.
now rewrite !(ARsub_def ARth), Ex, Ey.
Qed.
Ltac mrewrite :=
repeat first
[ rewrite (ARadd_0_l ARth)
| rewrite <- ((ARadd_comm ARth) 0)
| rewrite (ARmul_1_l ARth)
| rewrite <- ((ARmul_comm ARth) 1)
| rewrite (ARmul_0_l ARth)
| rewrite <- ((ARmul_comm ARth) 0)
| rewrite (ARdistr_l ARth)
| reflexivity
| match goal with
| |- context [?z * (?x + ?y)] => rewrite ((ARmul_comm ARth) z (x+y))
end].
Lemma ARadd_0_r x : x + 0 == x.
Proof. mrewrite. Qed.
Lemma ARmul_1_r x : x * 1 == x.
Proof. mrewrite. Qed.
Lemma ARmul_0_r x : x * 0 == 0.
Proof. mrewrite. Qed.
Lemma ARdistr_r x y z : z * (x + y) == z*x + z*y.
Proof.
mrewrite. now rewrite !(ARth.(ARmul_comm) z).
Qed.
Lemma ARadd_assoc1 x y z : (x + y) + z == (y + z) + x.
Proof.
now rewrite <-(ARth.(ARadd_assoc) x), (ARth.(ARadd_comm) x).
Qed.
Lemma ARadd_assoc2 x y z : (y + x) + z == (y + z) + x.
Proof.
now rewrite <- !(ARadd_assoc ARth), ((ARadd_comm ARth) x).
Qed.
Lemma ARmul_assoc1 x y z : (x * y) * z == (y * z) * x.
Proof.
now rewrite <- ((ARmul_assoc ARth) x), ((ARmul_comm ARth) x).
Qed.
Lemma ARmul_assoc2 x y z : (y * x) * z == (y * z) * x.
Proof.
now rewrite <- !(ARmul_assoc ARth), ((ARmul_comm ARth) x).
Qed.
Lemma ARopp_mul_r x y : - (x * y) == x * -y.
Proof.
rewrite ((ARmul_comm ARth) x y), (ARopp_mul_l ARth).
now apply (ARmul_comm ARth).
Qed.
Lemma ARopp_zero : -0 == 0.
Proof.
now rewrite <- (ARmul_0_r 0), (ARopp_mul_l ARth), !ARmul_0_r.
Qed.
End ALMOST_RING.
Section AddRing.
(* Variable R : Type.
Variable (rO rI : R) (radd rmul rsub: R->R->R) (ropp : R -> R).
Variable req : R -> R -> Prop. *)
Inductive ring_kind : Type :=
| Abstract
| Computational
(R:Type)
(req : R -> R -> Prop)
(reqb : R -> R -> bool)
(_ : forall x y, (reqb x y) = true -> req x y)
| Morphism
(R : Type)
(rO rI : R) (radd rmul rsub: R->R->R) (ropp : R -> R)
(req : R -> R -> Prop)
(C : Type)
(cO cI : C) (cadd cmul csub : C->C->C) (copp : C->C)
(ceqb : C->C->bool)
phi
(_ : ring_morph rO rI radd rmul rsub ropp req
cO cI cadd cmul csub copp ceqb phi).
End AddRing.
(** Some simplification tactics*)
Ltac gen_reflexivity Rsth := apply (Seq_refl _ _ Rsth).
Ltac gen_srewrite Rsth Reqe ARth :=
repeat first
[ gen_reflexivity Rsth
| progress rewrite (ARopp_zero Rsth Reqe ARth)
| rewrite (ARadd_0_l ARth)
| rewrite (ARadd_0_r Rsth ARth)
| rewrite (ARmul_1_l ARth)
| rewrite (ARmul_1_r Rsth ARth)
| rewrite (ARmul_0_l ARth)
| rewrite (ARmul_0_r Rsth ARth)
| rewrite (ARdistr_l ARth)
| rewrite (ARdistr_r Rsth Reqe ARth)
| rewrite (ARadd_assoc ARth)
| rewrite (ARmul_assoc ARth)
| progress rewrite (ARopp_add ARth)
| progress rewrite (ARsub_def ARth)
| progress rewrite <- (ARopp_mul_l ARth)
| progress rewrite <- (ARopp_mul_r Rsth Reqe ARth) ].
Ltac gen_srewrite_sr Rsth Reqe ARth :=
repeat first
[ gen_reflexivity Rsth
| progress rewrite (ARopp_zero Rsth Reqe ARth)
| rewrite (ARadd_0_l ARth)
| rewrite (ARadd_0_r Rsth ARth)
| rewrite (ARmul_1_l ARth)
| rewrite (ARmul_1_r Rsth ARth)
| rewrite (ARmul_0_l ARth)
| rewrite (ARmul_0_r Rsth ARth)
| rewrite (ARdistr_l ARth)
| rewrite (ARdistr_r Rsth Reqe ARth)
| rewrite (ARadd_assoc ARth)
| rewrite (ARmul_assoc ARth) ].
Ltac gen_add_push add Rsth Reqe ARth x :=
repeat (match goal with
| |- context [add (add ?y x) ?z] =>
progress rewrite (ARadd_assoc2 Rsth Reqe ARth x y z)
| |- context [add (add x ?y) ?z] =>
progress rewrite (ARadd_assoc1 Rsth ARth x y z)
| |- context [(add x ?y)] =>
progress rewrite (ARadd_comm ARth x y)
end).
Ltac gen_mul_push mul Rsth Reqe ARth x :=
repeat (match goal with
| |- context [mul (mul ?y x) ?z] =>
progress rewrite (ARmul_assoc2 Rsth Reqe ARth x y z)
| |- context [mul (mul x ?y) ?z] =>
progress rewrite (ARmul_assoc1 Rsth ARth x y z)
| |- context [(mul x ?y)] =>
progress rewrite (ARmul_comm ARth x y)
end).
|