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AffineProofs.v
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AffineProofs.v
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Require Export Crypto.Spec.CompleteEdwardsCurve.
Require Import Crypto.Algebra.Hierarchy Crypto.Algebra.ScalarMult Crypto.Util.Decidable.
Require Import Coq.Logic.Eqdep_dec.
Require Import Coq.Classes.Morphisms.
Require Import Coq.Relations.Relation_Definitions.
Require Import Crypto.Util.Tuple Crypto.Util.Notations.
Require Import Crypto.Util.Tactics.UniquePose.
Require Import Crypto.Util.Tactics.DestructHead.
Require Import Crypto.Util.Tactics.BreakMatch.
Require Import Crypto.Util.Tactics.SetoidSubst.
Require Export Crypto.Util.FixCoqMistakes.
Module E.
Import Group Ring Field CompleteEdwardsCurve.E.
Notation onCurve_zero := Pre.onCurve_zero.
Notation denominator_nonzero := Pre.denominator_nonzero.
Notation denominator_nonzero_x := Pre.denominator_nonzero_x.
Notation denominator_nonzero_y := Pre.denominator_nonzero_y.
Notation onCurve_add := Pre.onCurve_add.
Section CompleteEdwardsCurveTheorems.
Context {F Feq Fzero Fone Fopp Fadd Fsub Fmul Finv Fdiv}
{field:@field F Feq Fzero Fone Fopp Fadd Fsub Fmul Finv Fdiv}
{char_ge_3 : @Ring.char_ge F Feq Fzero Fone Fopp Fadd Fsub Fmul (BinNat.N.succ_pos BinNat.N.two)}
{Feq_dec:DecidableRel Feq}.
Local Infix "=" := Feq : type_scope. Local Notation "a <> b" := (not (a = b)) : type_scope.
Local Notation "0" := Fzero. Local Notation "1" := Fone.
Local Infix "+" := Fadd. Local Infix "*" := Fmul.
Local Infix "-" := Fsub. Local Infix "/" := Fdiv.
Local Notation "x ^ 2" := (x*x).
Context {a d: F}
{nonzero_a : a <> 0}
{square_a : exists sqrt_a, sqrt_a^2 = a}
{nonsquare_d : forall x, x^2 <> d}.
Local Notation onCurve x y := (a*x^2 + y^2 = 1 + d*x^2*y^2) (only parsing).
Local Notation point := (@E.point F Feq Fone Fadd Fmul a d).
Local Notation eq := (@E.eq F Feq Fone Fadd Fmul a d).
Local Notation zero := (E.zero(nonzero_a:=nonzero_a)(d:=d)).
Local Notation add := (E.add(nonzero_a:=nonzero_a)(square_a:=square_a)(nonsquare_d:=nonsquare_d)).
Local Notation mul := (E.mul(nonzero_a:=nonzero_a)(square_a:=square_a)(nonsquare_d:=nonsquare_d)).
Program Definition opp (P:point) : point := (Fopp (fst P), (snd P)).
Next Obligation. match goal with P : point |- _ => destruct P as [ [??]?] end; cbv; fsatz. Qed.
Ltac t_step :=
match goal with
| _ => solve [trivial | exact _ ]
| _ => intro
| |- Equivalence _ => split
| |- commutative_group => split | |- group => split | |- monoid => split
| |- is_associative => split | |- is_commutative => split
| |- is_left_inverse => split | |- is_right_inverse => split
| |- is_left_identity => split | |- is_right_identity => split
| _ => progress destruct_head' @E.point
| _ => progress destruct_head' prod
| _ => progress destruct_head' and
| |- context[E.add ?P ?Q] =>
unique pose proof (Pre.denominator_nonzero_x _ nonzero_a square_a _ nonsquare_d _ _ (proj2_sig P) _ _ (proj2_sig Q));
unique pose proof (Pre.denominator_nonzero_y _ nonzero_a square_a _ nonsquare_d _ _ (proj2_sig P) _ _ (proj2_sig Q))
| _ => progress cbv [opp E.zero E.eq E.add E.coordinates proj1_sig fieldwise fieldwise'] in *
(* [_gather_nonzeros] must run before [fst_pair] or [simpl] but after splitting E.eq and unfolding [E.add] *)
| |- _ /\ _ => split | |- _ <-> _ => split
end.
Ltac t := repeat t_step; fsatz.
Global Instance associative_add : is_associative(eq:=E.eq)(op:=add).
Proof using Type.
(* [nsatz_compute] for a denominator runs out of 6GB of stack space *)
(* COQBUG: https://coq.inria.fr/bugs/show_bug.cgi?id=5359 *)
Add Field _field : (Algebra.Field.field_theory_for_stdlib_tactic (T:=F)).
Import Field_tac.
repeat t_step; (field_simplify_eq; [IntegralDomain.nsatz|]); repeat split; trivial.
{ intro. eapply H3. field_simplify_eq; repeat split; trivial. IntegralDomain.nsatz. }
{ intro. eapply H. field_simplify_eq; repeat split; trivial. IntegralDomain.nsatz. }
{ intro. eapply H4. field_simplify_eq; repeat split; trivial. IntegralDomain.nsatz. }
{ intro. eapply H0. field_simplify_eq; repeat split; trivial. IntegralDomain.nsatz. }
Qed.
Global Instance edwards_curve_commutative_group : commutative_group (eq:=eq)(op:=add)(id:=zero)(inv:=opp).
Proof using Type. t. Qed.
Global Instance Proper_coordinates : Proper (eq==>fieldwise (n:=2) Feq) coordinates. Proof using Type. repeat t_step. Qed.
Global Instance Proper_mul : Proper (Logic.eq==>eq==>eq) mul.
Proof using Type.
intros n n'; repeat intro; subst n'.
induction n; (reflexivity || eapply (_:Proper (eq==>eq==>eq) add); eauto).
Qed.
Section PointCompression.
Local Notation "x ^ 2" := (x*x).
Lemma solve_correct x y : onCurve x y <-> (x^2 = (y^2-1) / (d*y^2-a)).
Proof using Feq_dec field nonsquare_d nonzero_a square_a. destruct square_a as [sqrt_a]; pose proof (nonsquare_d (sqrt_a/y));
split; intros; fsatz. Qed.
(* TODO: move *)
Definition exist_option {A} (P : A -> Prop) (x : option A)
: match x with Some v => P v | None => True end -> option { a : A | P a }.
destruct x; intros; [apply Some | apply None]; eauto. Defined.
Lemma exist_option_Some {A} P (x:option A) pf s
(H:Logic.eq (exist_option P x pf) (Some s))
: Logic.eq x (Some (proj1_sig s)).
Proof using Type. destruct x, s; cbv [exist_option proj1_sig] in *; congruence. Qed.
Lemma exist_option_None {A} P (x:option A) pf
(H:Logic.eq (exist_option P x pf) None)
: Logic.eq x None.
Proof using Type. destruct x; cbv [exist_option proj1_sig] in *; congruence. Qed.
Context
{sqrt_div:F -> F -> option F}
{sqrt_Some: forall u v r, Logic.eq (sqrt_div u v) (Some r) -> r^2 = u/v}
{sqrt_None: forall u v, Logic.eq (sqrt_div u v) None -> forall r, r^2 <> u/v}
{parity:F -> bool} {Proper_parity: Proper (Feq ==> Logic.eq) parity}
{parity_opp: forall x, x <> 0 -> Logic.eq (parity (Fopp x)) (negb (parity x)) }.
Definition compress (P:point) : (bool*F) :=
let (x, y) := coordinates P in pair (parity x) y.
Definition set_sign r p : option F :=
if dec (Logic.eq (parity r) p)
then Some r
else
let r' := Fopp r in
if dec (Logic.eq (parity r') p)
then Some r'
else None.
Lemma set_sign_None r p s (H:Logic.eq (set_sign r p) (Some s))
: s^2 = r^2 /\ Logic.eq (parity s) p.
Proof using Feq_dec field nonzero_a.
repeat match goal with
| _ => progress subst
| _ => progress cbv [set_sign] in *
| _ => progress break_match_hyps
| _ => progress Option.inversion_option
| _ => split
| _ => solve [ trivial | fsatz ]
end.
Qed.
Lemma set_sign_Some r p (H:Logic.eq (set_sign r p) None)
: forall s, s^2 = r^2 -> not (Logic.eq (parity s) p).
repeat match goal with
| _ => progress intros
| _ => progress subst
| _ => progress cbv [set_sign] in *
| _ => progress break_match_hyps
| _ => progress Option.inversion_option
end.
destruct (dec (r = 0)).
{ assert (s = 0) by Nsatz.nsatz_power 2%nat.
setoid_subst_rel Feq; trivial. }
{ progress rewrite parity_opp in * by assumption.
destruct (parity r), p; cbv [negb] in *; congruence. }
Qed.
Local Ltac t'_step :=
match goal with
| _ => progress subst
| _ => progress destruct_head' @E.point
| _ => progress destruct_head' and
| _ => progress break_match
| _ => progress break_match_hyps
| _ => progress Option.inversion_option
| _ => progress Prod.inversion_prod
| H:_ |- _ => unique pose proof (sqrt_Some _ _ _ H); clear H
| H:_ |- _ => unique pose proof (sqrt_None _ _ H); clear H
| H:_ |- _ => unique pose proof (set_sign_None _ _ _ H); clear H
| H:_ |- _ => unique pose proof (set_sign_Some _ _ H); clear H
| H:_ |- _ => unique pose proof (exist_option_Some _ _ _ _ H); clear H
| H:_ |- _ => unique pose proof (exist_option_None _ _ _ H); clear H
| _ => solve [trivial | eapply solve_correct; fsatz]
end.
Local Ltac t' := repeat t'_step.
Program Definition decompress (b:bool*F) : option point :=
exist_option _
match b return option (F*F) with
(p, y) =>
match sqrt_div (y^2 - 1) (d*y^2 - a) return option (F*F) with
| None => None
| Some r =>
match set_sign r p return option (F*F) with
| Some x => Some (x, y)
| None => None
end
end
end _.
Next Obligation. t'. Qed.
Lemma decompress_Some b P (H:Logic.eq (decompress b) (Some P))
: Logic.eq (compress P) b.
Proof using Type. cbv [compress decompress] in *; t'. Qed.
Lemma decompress_None b (H:Logic.eq (decompress b) None)
: forall P, not (Logic.eq (compress P) b).
Proof.
cbv [compress decompress exist_option coordinates] in *; intros.
t'.
{ intro.
match goal with
| [ H0 : _ |- False ]
=> apply (H0 f); [t'|congruence]; clear H0
end.
rewrite solve_correct in y; Nsatz.nsatz_power 2%nat. }
{ intro. Prod.inversion_prod; subst.
rewrite solve_correct in y.
eapply H. eapply y. }
Qed.
End PointCompression.
End CompleteEdwardsCurveTheorems.
Section Homomorphism.
Context {F Feq Fzero Fone Fopp Fadd Fsub Fmul Finv Fdiv}
{field:@field F Feq Fzero Fone Fopp Fadd Fsub Fmul Finv Fdiv}
{Fchar_ge_3 : @Ring.char_ge F Feq Fzero Fone Fopp Fadd Fsub Fmul (BinNat.N.succ_pos BinNat.N.two)}
{Feq_dec:DecidableRel Feq}.
Context {Fa Fd: F}
{nonzero_a : not (Feq Fa Fzero)}
{square_a : exists sqrt_a, Feq (Fmul sqrt_a sqrt_a) Fa}
{nonsquare_d : forall x, not (Feq (Fmul x x) Fd)}.
Context {K Keq Kzero Kone Kopp Kadd Ksub Kmul Kinv Kdiv}
{fieldK: @Algebra.Hierarchy.field K Keq Kzero Kone Kopp Kadd Ksub Kmul Kinv Kdiv}
{Keq_dec:DecidableRel Keq}.
Context {FtoK:F->K} {HFtoK:@Ring.is_homomorphism F Feq Fone Fadd Fmul
K Keq Kone Kadd Kmul FtoK}.
Context {KtoF:K->F} {HKtoF:@Ring.is_homomorphism K Keq Kone Kadd Kmul
F Feq Fone Fadd Fmul KtoF}.
Context {HisoF:forall x, Feq (KtoF (FtoK x)) x}.
Context {Ka} {Ha:Keq (FtoK Fa) Ka} {Kd} {Hd:Keq (FtoK Fd) Kd}.
Lemma nonzero_Ka : ~ Keq Ka Kzero.
Proof using Feq_dec HFtoK HKtoF Ha HisoF Keq_dec field fieldK nonzero_a.
rewrite <-Ha.
Ring.pull_homomorphism FtoK.
intro X.
eapply (Monoid.is_homomorphism_phi_proper(phi:=KtoF)) in X.
rewrite 2HisoF in X.
auto.
Qed.
Lemma square_Ka : exists sqrt_a, Keq (Kmul sqrt_a sqrt_a) Ka.
Proof using Feq_dec HFtoK Ha Keq_dec field fieldK square_a.
destruct square_a as [sqrt_a]. exists (FtoK sqrt_a).
Ring.pull_homomorphism FtoK. rewrite <-Ha.
eapply Monoid.is_homomorphism_phi_proper; assumption.
Qed.
Lemma nonsquare_Kd : forall x, not (Keq (Kmul x x) Kd).
Proof using Feq_dec HKtoF Hd HisoF Keq_dec field fieldK nonsquare_d.
intros x X. apply (nonsquare_d (KtoF x)).
Ring.pull_homomorphism KtoF. rewrite X. rewrite <-Hd, HisoF.
reflexivity.
Qed.
(* TODO: character respects isomorphism *)
Global Instance Kchar_ge_2 :
@char_ge K Keq Kzero Kone Kopp Kadd Ksub Kmul (BinNat.N.succ_pos BinNat.N.two).
Proof.
intros p Hp X; apply (Fchar_ge_3 p Hp).
eapply Monoid.is_homomorphism_phi_proper in X.
rewrite (homomorphism_zero(zero:=Fzero)(phi:=KtoF)) in X.
etransitivity; [|eexact X]; clear X.
rewrite (of_Z_absorbs_homomorphism(phi:=KtoF)).
reflexivity.
Qed.
Local Notation Fpoint := (@E.point F Feq Fone Fadd Fmul Fa Fd).
Local Notation Kpoint := (@E.point K Keq Kone Kadd Kmul Ka Kd).
Local Notation FzeroP := (E.zero(nonzero_a:=nonzero_a)(d:=Fd)).
Local Notation KzeroP := (E.zero(nonzero_a:=nonzero_Ka)(d:=Kd)).
Local Notation FaddP := (E.add(nonzero_a:=nonzero_a)(square_a:=square_a)(nonsquare_d:=nonsquare_d)).
Local Notation KaddP := (E.add(nonzero_a:=nonzero_Ka)(square_a:=square_Ka)(nonsquare_d:=nonsquare_Kd)).
Obligation Tactic := idtac.
Program Definition point_phi (P:Fpoint) : Kpoint := exist _ (
let (x, y) := coordinates P in (FtoK x, FtoK y)) _.
Next Obligation.
destruct P as [ [? ?] ?]; cbv.
rewrite <-!Ha, <-!Hd; pull_homomorphism FtoK.
eapply Monoid.is_homomorphism_phi_proper; assumption.
Qed.
Lemma Proper_point_phi : Proper (eq==>eq) point_phi.
Proof using Type.
intros P Q H.
destruct P as [ [? ?] ?], Q as [ [? ?] ?], H as [Hl Hr]; cbv.
rewrite !Hl, !Hr. split; reflexivity.
Qed.
Lemma lift_ismorphism : @Monoid.is_homomorphism Fpoint eq FaddP
Kpoint eq KaddP point_phi.
Proof using Type.
repeat match goal with
| |- _ => intro
| |- Monoid.is_homomorphism => split
| _ => progress destruct_head' @E.point
| _ => progress destruct_head' prod
| _ => progress destruct_head' and
| |- context[E.add ?P ?Q] =>
unique pose proof (Pre.denominator_nonzero_x _ nonzero_a square_a _ nonsquare_d _ _ (proj2_sig P) _ _ (proj2_sig Q));
unique pose proof (Pre.denominator_nonzero_y _ nonzero_a square_a _ nonsquare_d _ _ (proj2_sig P) _ _ (proj2_sig Q))
| _ => progress cbv [eq add point_phi coordinates] in *
| |- _ /\ _ => split
| _ => rewrite !(homomorphism_div(phi:=FtoK)) by assumption
| _ => rewrite !Ha
| _ => rewrite !Hd
| _ => Ring.push_homomorphism FtoK
| |- _ ?x ?x => reflexivity
| _ => eapply Monoid.is_homomorphism_phi_proper; assumption
end.
Qed.
End Homomorphism.
End E.