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Require Crypto.WeierstrassCurve.Pre.
Module W.
Section WeierstrassCurves.
(* Short Weierstrass curves with addition laws. References:
* <https://hyperelliptic.org/EFD/g1p/auto-shortw.html>
* <https://cr.yp.to/talks/2007.06.07/slides.pdf>
* See also:
* <http://cs.ucsb.edu/~koc/ccs130h/2013/EllipticHyperelliptic-CohenFrey.pdf> (page 79)
*)
Context {F Feq Fzero Fone Fopp Fadd Fsub Fmul Finv Fdiv} {field:@Algebra.field F Feq Fzero Fone Fopp Fadd Fsub Fmul Finv Fdiv} {Feq_dec:Decidable.DecidableRel Feq} {char_gt_2:@Ring.char_gt F Feq Fzero Fone Fopp Fadd Fsub Fmul (BinNat.N.succ_pos (BinNat.N.two))}.
Local Infix "=" := Feq : type_scope. Local Notation "a <> b" := (not (a = b)) : type_scope.
Local Notation "x =? y" := (Decidable.dec (Feq x y)) (at level 70, no associativity) : type_scope.
Local Notation "x =? y" := (Sumbool.bool_of_sumbool (Decidable.dec (Feq x y))) : bool_scope.
Local Infix "+" := Fadd. Local Infix "*" := Fmul.
Local Infix "-" := Fsub. Local Infix "/" := Fdiv.
Local Notation "- x" := (Fopp x).
Local Notation "x ^ 2" := (x*x) (at level 30). Local Notation "x ^ 3" := (x*x^2) (at level 30).
Local Notation "'∞'" := unit : type_scope.
Local Notation "'∞'" := (inr tt) : core_scope.
Local Notation "( x , y )" := (inl (pair x y)).
Local Open Scope core_scope.
Context {a b: F}.
Definition point := { P | match P with
| (x, y) => y^2 = x^3 + a*x + b
| ∞ => True
end }.
Definition coordinates (P:point) : (F*F + ∞) := proj1_sig P.
Definition eq (P1 P2:point) :=
match coordinates P1, coordinates P2 with
| (x1, y1), (x2, y2) => x1 = x2 /\ y1 = y2
| ∞, ∞ => True
| _, _ => False
end.
Program Definition zero : point := ∞.
Local Notation "0" := Fzero. Local Notation "1" := Fone.
Local Notation "2" := (1+1). Local Notation "3" := (1+2).
Program Definition add (P1 P2:point) : point := exist _
(match coordinates P1, coordinates P2 return _ with
| (x1, y1), (x2, y2) =>
if x1 =? x2
then
if y2 =? -y1
then ∞
else let k := (3*x1^2+a)/(2*y1) in
let x3 := k^2-x1-x1 in
let y3 := k*(x1-x3)-y1 in
(x3, y3)
else let k := (y2-y1)/(x2-x1) in
let x3 := k^2-x1-x2 in
let y3 := k*(x1-x3)-y1 in
(x3, y3)
| ∞, ∞ => ∞
| ∞, _ => coordinates P2
| _, ∞ => coordinates P1
end) _.
Next Obligation. exact (Pre.add_onCurve _ _ (proj2_sig _) (proj2_sig _)). Qed.
Fixpoint mul (n:nat) (P : point) : point :=
match n with
| O => zero
| S n' => add P (mul n' P)
end.
End WeierstrassCurves.
End W.
Delimit Scope W_scope with W.
Infix "+" := W.add : W_scope.
Infix "*" := W.mul : W_scope.
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