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ecc.h
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ecc.h
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#ifndef PUTTY_ECC_H
#define PUTTY_ECC_H
/*
* Arithmetic functions for the various kinds of elliptic curves used
* by PuTTY's public-key cryptography.
*
* All of these elliptic curves are over the finite field whose order
* is a large prime p. (Elliptic curves over a field of order 2^n are
* also known, but PuTTY currently has no need of them.)
*/
/* ----------------------------------------------------------------------
* Weierstrass curves (or rather, 'short form' Weierstrass curves).
*
* A curve in this form is defined by two parameters a,b, and the
* non-identity points on the curve are represented by (x,y) (the
* 'affine coordinates') such that y^2 = x^3 + ax + b.
*
* The identity element of the curve's group is an additional 'point
* at infinity', which is considered to be the third point on the
* intersection of the curve with any vertical line. Hence, the
* inverse of the point (x,y) is (x,-y).
*/
/*
* Create and destroy Weierstrass curve data structures. The mandatory
* parameters to the constructor are the prime modulus p, and the
* curve parameters a,b.
*
* 'nonsquare_mod_p' is an optional extra parameter, only needed by
* ecc_edwards_point_new_from_y which has to take a modular square
* root. You can pass it as NULL if you don't need that function.
*/
WeierstrassCurve *ecc_weierstrass_curve(
mp_int *p, mp_int *a, mp_int *b, mp_int *nonsquare_mod_p);
void ecc_weierstrass_curve_free(WeierstrassCurve *);
/*
* Create points on a Weierstrass curve, given the curve.
*
* point_new_identity returns the special identity point.
* point_new(x,y) returns the non-identity point with the given affine
* coordinates.
*
* point_new_from_x constructs a non-identity point given only the
* x-coordinate, by using the curve equation to work out what y has to
* be. Of course the equation only tells you y^2, so it only
* determines y up to sign; the parameter desired_y_parity controls
* which of the two values of y you get, by saying whether you'd like
* its minimal non-negative residue mod p to be even or odd. (Of
* course, since p itself is odd, exactly one of y and p-y is odd.)
* This function has to take a modular square root, so it will only
* work if you passed in a non-square mod p when constructing the
* curve.
*/
WeierstrassPoint *ecc_weierstrass_point_new_identity(WeierstrassCurve *curve);
WeierstrassPoint *ecc_weierstrass_point_new(
WeierstrassCurve *curve, mp_int *x, mp_int *y);
WeierstrassPoint *ecc_weierstrass_point_new_from_x(
WeierstrassCurve *curve, mp_int *x, unsigned desired_y_parity);
/* Memory management: copy and free points. */
void ecc_weierstrass_point_copy_into(
WeierstrassPoint *dest, WeierstrassPoint *src);
WeierstrassPoint *ecc_weierstrass_point_copy(WeierstrassPoint *wc);
void ecc_weierstrass_point_free(WeierstrassPoint *point);
/* Check whether a point is actually on the curve. */
unsigned ecc_weierstrass_point_valid(WeierstrassPoint *);
/*
* Add two points and return their sum. This function is fully
* general: it should do the right thing if the two inputs are the
* same, or if either (or both) of the input points is the identity,
* or if the two input points are inverses so the output is the
* identity. However, it pays for that generality by being slower than
* the special-purpose functions below..
*/
WeierstrassPoint *ecc_weierstrass_add_general(
WeierstrassPoint *, WeierstrassPoint *);
/*
* Fast but less general arithmetic functions: add two points on the
* condition that they are not equal and neither is the identity, and
* add a point to itself.
*/
WeierstrassPoint *ecc_weierstrass_add(WeierstrassPoint *, WeierstrassPoint *);
WeierstrassPoint *ecc_weierstrass_double(WeierstrassPoint *);
/*
* Compute an integer multiple of a point. Not guaranteed to work
* unless the integer argument is less than the order of the point in
* the group (because it won't cope if an identity element shows up in
* any intermediate product).
*/
WeierstrassPoint *ecc_weierstrass_multiply(WeierstrassPoint *, mp_int *);
/*
* Query functions to get the value of a point back out. is_identity
* tells you whether the point is the identity; if it isn't, then
* get_affine will retrieve one or both of its affine coordinates.
* (You can pass NULL as either output pointer, if you don't need that
* coordinate as output.)
*/
unsigned ecc_weierstrass_is_identity(WeierstrassPoint *wp);
void ecc_weierstrass_get_affine(WeierstrassPoint *wp, mp_int **x, mp_int **y);
/* ----------------------------------------------------------------------
* Montgomery curves.
*
* A curve in this form is defined by two parameters a,b, and the
* curve equation is by^2 = x^3 + ax^2 + x.
*
* As with Weierstrass curves, there's an additional point at infinity
* that is the identity element, and the inverse of (x,y) is (x,-y).
*
* However, we don't actually work with full (x,y) pairs. We just
* store the x-coordinate (so what we're really representing is not a
* specific point on the curve but a two-point set {P,-P}). This means
* you can't quite do point addition, because if you're given {P,-P}
* and {Q,-Q} as input, you can work out a pair of x-coordinates that
* are those of P-Q and P+Q, but you don't know which is which.
*
* Instead, the basic operation is 'differential addition', in which
* you are given three parameters P, Q and P-Q and you return P+Q. (As
* well as disambiguating which of the possible answers you want, that
* extra input also enables a fast formulae for computing it. This
* fast formula is more or less why Montgomery curves are useful in
* the first place.)
*
* Doubling a point is still possible to do unambiguously, so you can
* still compute an integer multiple of P if you start by making 2P
* and then doing a series of differential additions.
*/
/*
* Create and destroy Montgomery curve data structures.
*/
MontgomeryCurve *ecc_montgomery_curve(mp_int *p, mp_int *a, mp_int *b);
void ecc_montgomery_curve_free(MontgomeryCurve *);
/*
* Create, copy and free points on the curve. We don't need to
* explicitly represent the identity for this application.
*/
MontgomeryPoint *ecc_montgomery_point_new(MontgomeryCurve *mc, mp_int *x);
void ecc_montgomery_point_copy_into(
MontgomeryPoint *dest, MontgomeryPoint *src);
MontgomeryPoint *ecc_montgomery_point_copy(MontgomeryPoint *orig);
void ecc_montgomery_point_free(MontgomeryPoint *mp);
/*
* Basic arithmetic routines: differential addition and point-
* doubling. Each of these assumes that no special cases come up - no
* input or output point should be the identity, and in diff_add, P
* and Q shouldn't be the same.
*/
MontgomeryPoint *ecc_montgomery_diff_add(
MontgomeryPoint *P, MontgomeryPoint *Q, MontgomeryPoint *PminusQ);
MontgomeryPoint *ecc_montgomery_double(MontgomeryPoint *P);
/*
* Compute an integer multiple of a point.
*/
MontgomeryPoint *ecc_montgomery_multiply(MontgomeryPoint *, mp_int *);
/*
* Return the affine x-coordinate of a point.
*/
void ecc_montgomery_get_affine(MontgomeryPoint *mp, mp_int **x);
/*
* Test whether a point is the curve identity.
*/
unsigned ecc_montgomery_is_identity(MontgomeryPoint *mp);
/* ----------------------------------------------------------------------
* Twisted Edwards curves.
*
* A curve in this form is defined by two parameters d,a, and the
* curve equation is a x^2 + y^2 = 1 + d x^2 y^2.
*
* Apparently if you ask a proper algebraic geometer they'll tell you
* that this is technically not an actual elliptic curve. Certainly it
* doesn't work quite the same way as the other kinds: in this form,
* there is no need for a point at infinity, because the identity
* element is represented by the affine coordinates (0,1). And you
* invert a point by negating its x rather than y coordinate: the
* inverse of (x,y) is (-x,y).
*
* The usefulness of this representation is that the addition formula
* is 'strongly unified', meaning that the same formula works for any
* input and output points, without needing special cases for the
* identity or for doubling.
*/
/*
* Create and destroy Edwards curve data structures.
*
* Similarly to ecc_weierstrass_curve, you don't have to provide
* nonsquare_mod_p if you don't need ecc_edwards_point_new_from_y.
*/
EdwardsCurve *ecc_edwards_curve(
mp_int *p, mp_int *d, mp_int *a, mp_int *nonsquare_mod_p);
void ecc_edwards_curve_free(EdwardsCurve *);
/*
* Create points.
*
* There's no need to have a separate function to create the identity
* point, because you can just pass x=0 and y=1 to the usual function.
*
* Similarly to the Weierstrass curve, ecc_edwards_point_new_from_y
* creates a point given only its y-coordinate and the desired parity
* of its x-coordinate, and you can only call it if you provided the
* optional nonsquare_mod_p argument when creating the curve.
*/
EdwardsPoint *ecc_edwards_point_new(
EdwardsCurve *curve, mp_int *x, mp_int *y);
EdwardsPoint *ecc_edwards_point_new_from_y(
EdwardsCurve *curve, mp_int *y, unsigned desired_x_parity);
/* Copy and free points. */
void ecc_edwards_point_copy_into(EdwardsPoint *dest, EdwardsPoint *src);
EdwardsPoint *ecc_edwards_point_copy(EdwardsPoint *ec);
void ecc_edwards_point_free(EdwardsPoint *point);
/*
* Arithmetic: add two points, and calculate an integer multiple of a
* point.
*/
EdwardsPoint *ecc_edwards_add(EdwardsPoint *, EdwardsPoint *);
EdwardsPoint *ecc_edwards_multiply(EdwardsPoint *, mp_int *);
/*
* Query functions: compare two points for equality, and return the
* affine coordinates of a point.
*/
unsigned ecc_edwards_eq(EdwardsPoint *, EdwardsPoint *);
void ecc_edwards_get_affine(EdwardsPoint *wp, mp_int **x, mp_int **y);
#endif /* PUTTY_ECC_H */