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Require Import BinInt BinNat ZArith Znumtheory NArith.
Require Import Eqdep_dec.
Require Export Coq.Classes.Morphisms Setoid.
Require Export Ring_theory Field_theory Field_tac.
Require Export Crypto.Galois.Galois.
Set Implicit Arguments.
Unset Strict Implicits.
Module GaloisTheory (M: Modulus).
Module G := Galois M.
Export M G.
(* Notations *)
Delimit Scope GF_scope with GF.
Notation "1" := GFone : GF_scope.
Notation "0" := GFzero : GF_scope.
Infix "+" := GFplus : GF_scope.
Infix "-" := GFminus : GF_scope.
Infix "*" := GFmult : GF_scope.
Infix "/" := GFdiv : GF_scope.
Infix "^" := GFexp : GF_scope.
(* Basic Properties *)
(* Fails iff the input term does some arithmetic with mod'd values. *)
Ltac notFancy E :=
match E with
| - (_ mod _) => idtac
| context[_ mod _] => fail 1
| _ => idtac
end.
Lemma Zplus_neg : forall n m, n + -m = n - m.
Proof.
auto.
Qed.
Lemma Zmod_eq : forall a b n, a = b -> a mod n = b mod n.
Proof.
intros; rewrite H; trivial.
Qed.
(* Remove redundant [mod] operations from the conclusion. *)
Ltac demod :=
repeat match goal with
| [ |- context[(?x mod _ + _) mod _] ] =>
notFancy x; rewrite (Zplus_mod_idemp_l x)
| [ |- context[(_ + ?y mod _) mod _] ] =>
notFancy y; rewrite (Zplus_mod_idemp_r y)
| [ |- context[(?x mod _ - _) mod _] ] =>
notFancy x; rewrite (Zminus_mod_idemp_l x)
| [ |- context[(_ - ?y mod _) mod _] ] =>
notFancy y; rewrite (Zminus_mod_idemp_r _ y)
| [ |- context[(?x mod _ * _) mod _] ] =>
notFancy x; rewrite (Zmult_mod_idemp_l x)
| [ |- context[(_ * (?y mod _)) mod _] ] =>
notFancy y; rewrite (Zmult_mod_idemp_r y)
| [ |- context[(?x mod _) mod _] ] =>
notFancy x; rewrite (Zmod_mod x)
| _ => rewrite Zplus_neg in * || rewrite Z.sub_diag in *
end.
(* Remove exists under equals: we do this a lot *)
Ltac eq_remove_proofs := match goal with
| [ |- ?a = ?b ] =>
assert (Q := gf_eq a b);
simpl in *; apply Q; clear Q
end.
(* General big hammer for proving Galois arithmetic facts *)
Ltac galois := intros; apply gf_eq; simpl;
repeat match goal with
| [ x : GF |- _ ] => destruct x
end; simpl in *; autorewrite with core;
intuition; demod; try solve [ f_equal; intuition ].
Lemma modmatch_eta : forall n,
match n with
| 0 => 0
| Z.pos y' => Z.pos y'
| Z.neg y' => Z.neg y'
end = n.
Proof.
destruct n; auto.
Qed.
Hint Rewrite Zmod_mod modmatch_eta.
(* Ring Theory*)
Ltac compat := repeat intro; subst; trivial.
Instance GFplus_compat : Proper (eq==>eq==>eq) GFplus.
Proof.
compat.
Qed.
Instance GFminus_compat : Proper (eq==>eq==>eq) GFminus.
Proof.
compat.
Qed.
Instance GFmult_compat : Proper (eq==>eq==>eq) GFmult.
Proof.
compat.
Qed.
Instance GFopp_compat : Proper (eq==>eq) GFopp.
Proof.
compat.
Qed.
Definition GFring_theory : ring_theory GFzero GFone GFplus GFmult GFminus GFopp eq.
Proof.
constructor; galois.
Qed.
(* Power theory *)
Local Open Scope GF_scope.
Lemma GFexp'_doubling : forall q r0, GFexp' (r0 * r0) q = GFexp' r0 q * GFexp' r0 q.
Proof.
induction q; simpl; intuition.
rewrite (IHq (r0 * r0)); generalize (GFexp' (r0 * r0) q); intro.
galois.
apply Zmod_eq; ring.
Qed.
Lemma GFexp'_correct : forall r p, GFexp' r p = pow_pos GFmult r p.
Proof.
induction p; simpl; intuition;
rewrite GFexp'_doubling; congruence.
Qed.
Hint Immediate GFexp'_correct.
Lemma GFexp_correct : forall r n,
r^n = pow_N 1 GFmult r n.
Proof.
induction n; simpl; intuition.
Qed.
Lemma GFexp_correct' : forall r n,
r^id n = pow_N 1 GFmult r n.
Proof.
apply GFexp_correct.
Qed.
Hint Immediate GFexp_correct'.
Lemma GFpower_theory : power_theory GFone GFmult eq id GFexp.
Proof.
constructor; auto.
Qed.
(* Ring properties *)
Ltac GFexp_tac t := Ncst t.
Lemma GFdecidable : forall (x y: GF), Zeq_bool x y = true -> x = y.
Proof.
intros; galois.
apply Zeq_is_eq_bool.
trivial.
Qed.
Lemma GFcomplete : forall (x y: GF), x = y -> Zeq_bool x y = true.
Proof.
intros.
apply Zeq_is_eq_bool.
galois.
Qed.
(* Division Theory *)
Definition inject(x: Z): GF.
exists (x mod modulus).
abstract (demod; trivial).
Defined.
Lemma inject_distr_add : forall (m n : Z),
inject (m + n) = inject m + inject n.
Proof.
galois.
Qed.
Lemma inject_distr_sub : forall (m n : Z),
inject (m - n) = inject m - inject n.
Proof.
galois.
Qed.
Lemma inject_distr_mul : forall (m n : Z),
inject (m * n) = inject m * inject n.
Proof.
galois.
Qed.
Lemma inject_eq : forall (x : GF), inject x = x.
Proof.
galois.
Qed.
Lemma inject_mod_eq : forall x, inject x = inject (x mod modulus).
Proof.
galois.
Qed.
Definition GFquotrem(a b: GF): GF * GF :=
match (Z.quotrem a b) with
| (q, r) => (inject q, inject r)
end.
Lemma GFdiv_theory : div_theory eq GFplus GFmult (@id _) GFquotrem.
Proof.
constructor; intros; unfold GFquotrem.
replace (Z.quotrem a b) with (Z.quot a b, Z.rem a b);
try (unfold Z.quot, Z.rem; rewrite <- surjective_pairing; trivial).
eq_remove_proofs; demod;
rewrite <- (Z.quot_rem' a b);
destruct a; simpl; trivial.
Qed.
(* Now add the ring with all modifiers *)
Add Ring GFring0 : GFring_theory
(power_tac GFpower_theory [GFexp_tac]).
(* Field Theory*)
Lemma GFexp'_pred' : forall x p,
GFexp' p (Pos.succ x) = GFexp' p x * p.
Proof.
induction x; simpl; intuition; try ring.
rewrite IHx; ring.
Qed.
Lemma GFexp'_pred : forall x p,
p <> 0
-> x <> 1%positive
-> GFexp' p x = GFexp' p (Pos.pred x) * p.
Proof.
intros; rewrite <- (Pos.succ_pred x) at 1; auto using GFexp'_pred'.
Qed.
Lemma GFexp_pred : forall p x,
p <> 0
-> x <> 0%N
-> p^x = p^N.pred x * p.
Proof.
destruct x; simpl; intuition.
destruct (Pos.eq_dec p0 1); subst; simpl; try ring.
rewrite GFexp'_pred by auto.
destruct p0; intuition.
Qed.
Lemma GF_multiplicative_inverse : forall p,
p <> 0
-> GFinv p * p = 1.
Proof.
unfold GFinv; destruct totient as [ ? [ ] ]; simpl.
intros.
rewrite <- GFexp_pred; auto using N.gt_lt, N.lt_neq.
intro; subst.
eapply N.lt_irrefl; eauto using N.gt_lt.
Qed.
Instance GFinv_compat : Proper (eq==>eq) GFinv.
Proof.
compat.
Qed.
Instance GFdiv_compat : Proper (eq==>eq==>eq) GFdiv.
Proof.
compat.
Qed.
Hint Immediate GF_multiplicative_inverse GFring_theory.
Local Hint Extern 1 False => discriminate.
Definition GFfield_theory : field_theory GFzero GFone GFplus GFmult GFminus GFopp GFdiv GFinv eq.
Proof.
constructor; auto.
Qed.
End GaloisTheory.
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