From 3baeb11a8fbcfcdbc31976d421f17b85503b3ecd Mon Sep 17 00:00:00 2001 From: WuKong Date: Fri, 4 Sep 2015 09:25:34 +0200 Subject: init attribute-based encryption Change-Id: Iba1a3d722110abf747a0fba366f3ebc911d25b25 --- moon-abe/pbc-0.5.14/ecc/d_param.c | 1258 +++++++++++++++++++++++++++++++++++++ 1 file changed, 1258 insertions(+) create mode 100644 moon-abe/pbc-0.5.14/ecc/d_param.c (limited to 'moon-abe/pbc-0.5.14/ecc/d_param.c') diff --git a/moon-abe/pbc-0.5.14/ecc/d_param.c b/moon-abe/pbc-0.5.14/ecc/d_param.c new file mode 100644 index 00000000..8b7d6ac5 --- /dev/null +++ b/moon-abe/pbc-0.5.14/ecc/d_param.c @@ -0,0 +1,1258 @@ +// Type D pairings, aka MNT curves. + +#include +#include +#include // for intptr_t +#include +#include +#include +#include "pbc_utils.h" +#include "pbc_field.h" +#include "pbc_poly.h" +#include "pbc_hilbert.h" +#include "pbc_fp.h" +#include "pbc_fieldquadratic.h" +#include "pbc_mnt.h" +#include "pbc_curve.h" +#include "pbc_param.h" +#include "pbc_pairing.h" +#include "pbc_memory.h" +#include "pbc_d_param.h" +#include "ecc/param.h" + +struct d_param_s { + mpz_t q; // curve defined over F_q + mpz_t n; // has order n (= q - t + 1) in F_q + mpz_t h; // h * r = n, r is prime + mpz_t r; + mpz_t a, b; // curve equation is y^2 = x^3 + ax + b + int k; // embedding degree + mpz_t nk; // order of curve over F_q^k + mpz_t hk; // hk * r^2 = nk + mpz_t *coeff; // coefficients of polynomial used to extend F_q by k/2 + mpz_t nqr; // a quadratic nonresidue in F_q^d that lies in F_q +}; + +typedef struct d_param_s d_param_t[1]; +typedef struct d_param_s *d_param_ptr; + +// Per-pairing data. +typedef struct { + field_t Fq, Fqx, Fqd, Fqk; // The fields F_q, F_q[x], F_q^d, F_q^k. + field_t Eq, Etwist; // The curves E(F_q) and E'(F_q^d). + // Let v be the quadratic nonresidue used to construct F_q^k from F_q^d, + // namely Fqk = Fqd[sqrt(v)]. + element_t nqrinv, nqrinv2; // The constants v^-1 and v^-2. + mpz_t tateexp; // The Tate exponent, + // to standardize coset representatives. + int k; // The embedding degree, usually 6. + // Let x be the element used to build Fqd from Fq, i.e. Fqd = Fq[x]. + element_t xpowq, xpowq2; // x^q and x^{2q} in F_q^d. +} *pptr; + +static void d_clear(void *data) { + d_param_ptr param = data; + int d = param->k / 2; + int i; + mpz_clear(param->q); + mpz_clear(param->n); + mpz_clear(param->h); + mpz_clear(param->r); + mpz_clear(param->a); + mpz_clear(param->b); + mpz_clear(param->nk); + mpz_clear(param->hk); + mpz_clear(param->nqr); + for (i=0; icoeff[i]); + } + pbc_free(param->coeff); + pbc_free(data); +} + +static void d_out_str(FILE *stream, void *data) { + d_param_ptr p = data; + int d = p->k / 2; + int i; + char s[8]; + param_out_type(stream, "d"); + param_out_mpz(stream, "q", p->q); + param_out_mpz(stream, "n", p->n); + param_out_mpz(stream, "h", p->h); + param_out_mpz(stream, "r", p->r); + param_out_mpz(stream, "a", p->a); + param_out_mpz(stream, "b", p->b); + param_out_int(stream, "k", p->k); + param_out_mpz(stream, "nk", p->nk); + param_out_mpz(stream, "hk", p->hk); + for (i=0; icoeff[i]); + } + param_out_mpz(stream, "nqr", p->nqr); +} + +// Define l = aX + bY + c where a, b, c are in Fq. +// Compute e0 = l(Q) specialized for the case when Q has the form +// (Qx, Qy * sqrt(v)) where Qx, Qy are in Fqd and v is the quadratic nonresidue +// used to construct the quadratic field extension Fqk of Fqd. +static inline void d_miller_evalfn(element_t e0, + element_t a, element_t b, element_t c, element_t Qx, element_t Qy) { + element_ptr re_out = element_x(e0); + element_ptr im_out = element_y(e0); + + int i; + int d = polymod_field_degree(re_out->field); + for (i = 0; i < d; i++) { + element_mul(element_item(re_out, i), element_item(Qx, i), a); + element_mul(element_item(im_out, i), element_item(Qy, i), b); + } + element_add(element_item(re_out, 0), element_item(re_out, 0), c); +} + +// Miller's algorithm, assuming we can ignore the denominator. We can do this +// with careful group selection when the embedding degree is even. See thesis. +// This version uses projective coordinates, which don't seem much faster. +static void cc_miller_no_denom_proj(element_t res, mpz_t q, element_t P, + element_ptr Qx, element_ptr Qy) { + int m; + element_t v; + element_t Z; + element_t a, b, c; + element_t t0, t1; + element_ptr t2 = a, t3 = b, t4 = c; + element_t e0; + element_t z, z2; + element_ptr Zx, Zy; + const element_ptr curve_a = curve_a_coeff(P); + const element_ptr Px = curve_x_coord(P); + const element_ptr Py = curve_y_coord(P); + + #define proj_double() { \ + /* t0 = 3x^2 + (curve_a) z^4 */ \ + element_square(t0, Zx); \ + /* element_mul_si(t0, t0, 3); */ \ + element_double(t1, t0); \ + element_add(t0, t0, t1); \ + element_square(t1, z2); \ + element_mul(t1, t1, curve_a); \ + element_add(t0, t0, t1); \ + \ + /* z_out = 2 y z */ \ + element_mul(z, Zy, z); \ + /* element_mul_si(z, z, 2); */ \ + element_double(z, z); \ + element_square(z2, z); \ + \ + /* t1 = 4 x y^2 */ \ + element_square(t2, Zy); \ + element_mul(t1, Zx, t2); \ + /* element_mul_si(t1, t1, 4); */ \ + element_double(t1, t1); \ + element_double(t1, t1); \ + \ + /* x_out = t0^2 - 2 t1 */ \ + /* element_mul_si(t3, t1, 2); */ \ + element_double(t3, t1); \ + element_square(Zx, t0); \ + element_sub(Zx, Zx, t3); \ + \ + /* t2 = 8y^4 */ \ + element_square(t2, t2); \ + /* element_mul_si(t2, t2, 8); */ \ + element_double(t2, t2); \ + element_double(t2, t2); \ + element_double(t2, t2); \ + \ + /* y_out = t0(t1 - x_out) - t2 */ \ + element_sub(t1, t1, Zx); \ + element_mul(t0, t0, t1); \ + element_sub(Zy, t0, t2); \ + } + + #define proj_mixin() { \ + /* t2 = Px z^2 */ \ + element_mul(t2, z2, Px); \ + \ + /* t3 = Zx - t2 */ \ + element_sub(t3, Zx, t2); \ + \ + /* t0 = Py z^3 */ \ + element_mul(t0, z2, Py); \ + element_mul(t0, t0, z); \ + \ + /* t1 = Zy - t0 */ \ + element_sub(t1, Zy, t0); \ + \ + /* e7 = Zx + t2, use t2 to double for e7 */ \ + element_add(t2, Zx, t2); \ + \ + /* e8 = Zy + t0, use t0 to double for e8 */ \ + element_add(t0, Zy, t0); \ + \ + /* z = z t3 */ \ + element_mul(z, z, t3); \ + element_square(z2, z); \ + \ + /* Zx = t1^2 - e7 t3^2 */ \ + /* t3 now holds t3^3, */ \ + /* t4 holds e7 t3^2. */ \ + element_square(t4, t3); \ + element_mul(t3, t4, t3); \ + element_square(Zx, t1); \ + element_mul(t4, t2, t4); \ + element_sub(Zx, Zx, t4); \ + \ + /* t4 = e7 t3^2 - 2 Zx */ \ + element_sub(t4, t4, Zx); \ + element_sub(t4, t4, Zx); \ + \ + /* Zy = (t4 t1 - e8 t3^3)/2 */ \ + element_mul(t4, t4, t1); \ + element_mul(t0, t0, t3); \ + element_sub(t4, t4, t0); \ + element_halve(Zy, t4); \ + } + + #define do_tangent() { \ + /* a = -(3x^2 + cca z^4) */ \ + /* b = 2 y z^3 */ \ + /* c = -(2 y^2 + x a) */ \ + /* a = z^2 a */ \ + element_square(a, z2); \ + element_mul(a, a, curve_a); \ + element_square(b, Zx); \ + /* element_mul_si(b, b, 3); */ \ + element_double(t0, b); \ + element_add(b, b, t0); \ + element_add(a, a, b); \ + element_neg(a, a); \ + \ + element_mul(b, z, z2); \ + element_mul(b, b, Zy); \ + element_mul_si(b, b, 2); \ + \ + element_mul(c, Zx, a); \ + element_mul(a, a, z2); \ + element_square(t0, Zy); \ + element_mul_si(t0, t0, 2); \ + element_add(c, c, t0); \ + element_neg(c, c); \ + \ + d_miller_evalfn(e0, a, b, c, Qx, Qy); \ + element_mul(v, v, e0); \ + } + + #define do_line() { \ + /* a = -(Py z^3 - Zy) */ \ + /* b = Px z^3 - Zx z */ \ + /* c = Zx z Py - Zy Px; */ \ + \ + element_mul(t0, Zx, z); \ + element_mul(t1, z2, z); \ + \ + element_mul(a, Py, t1); \ + element_sub(a, Zy, a); \ + \ + element_mul(b, Px, t1); \ + element_sub(b, b, t0); \ + \ + element_mul(t0, t0, Py); \ + element_mul(c, Zy, Px); \ + element_sub(c, t0, c); \ + \ + d_miller_evalfn(e0, a, b, c, Qx, Qy); \ + element_mul(v, v, e0); \ + } + + element_init(a, Px->field); + element_init(b, a->field); + element_init(c, a->field); + element_init(t0, a->field); + element_init(t1, a->field); + element_init(e0, res->field); + element_init(z, a->field); + element_init(z2, a->field); + element_set1(z); + element_set1(z2); + + element_init(v, res->field); + element_init(Z, P->field); + + element_set(Z, P); + Zx = curve_x_coord(Z); + Zy = curve_x_coord(Z); + + element_set1(v); + m = mpz_sizeinbase(q, 2) - 2; + + for(;;) { + do_tangent(); + if (!m) break; + proj_double(); + if (mpz_tstbit(q, m)) { + do_line(); + proj_mixin(); + } + m--; + element_square(v, v); + } + + element_set(res, v); + + element_clear(v); + element_clear(Z); + element_clear(a); + element_clear(b); + element_clear(c); + element_clear(t0); + element_clear(t1); + element_clear(e0); + element_clear(z); + element_clear(z2); + #undef proj_double + #undef proj_mixin + #undef do_tangent + #undef do_line +} + +// Same as above, but with affine coordinates. +static void cc_miller_no_denom_affine(element_t res, mpz_t q, element_t P, + element_ptr Qx, element_ptr Qy) { + int m; + element_t v; + element_t Z; + element_t a, b, c; + element_t t0; + element_t e0; + const element_ptr cca = curve_a_coeff(P); + const element_ptr Px = curve_x_coord(P); + const element_ptr Py = curve_y_coord(P); + element_ptr Zx, Zy; + + /* TODO: when exactly is this not needed? + void do_vertical() { + mapbase(e0, Z->x); + element_sub(e0, Qx, e0); + element_mul(v, v, e0); + } + */ + + #define do_tangent() { \ + /* a = -(3 Zx^2 + cc->a) */ \ + /* b = 2 * Zy */ \ + /* c = -(2 Zy^2 + a Zx); */ \ + \ + element_square(a, Zx); \ + element_mul_si(a, a, 3); \ + element_add(a, a, cca); \ + element_neg(a, a); \ + \ + element_add(b, Zy, Zy); \ + \ + element_mul(t0, b, Zy); \ + element_mul(c, a, Zx); \ + element_add(c, c, t0); \ + element_neg(c, c); \ + \ + d_miller_evalfn(e0, a, b, c, Qx, Qy); \ + element_mul(v, v, e0); \ + } + + #define do_line() { \ + /* a = -(B.y - A.y) / (B.x - A.x); */ \ + /* b = 1; */ \ + /* c = -(A.y + a * A.x); */ \ + /* but we multiply by B.x - A.x to avoid division. */ \ + \ + element_sub(b, Px, Zx); \ + element_sub(a, Zy, Py); \ + element_mul(t0, b, Zy); \ + element_mul(c, a, Zx); \ + element_add(c, c, t0); \ + element_neg(c, c); \ + \ + d_miller_evalfn(e0, a, b, c, Qx, Qy); \ + element_mul(v, v, e0); \ + } + + element_init(a, Px->field); + element_init(b, a->field); + element_init(c, a->field); + element_init(t0, a->field); + element_init(e0, res->field); + + element_init(v, res->field); + element_init(Z, P->field); + + element_set(Z, P); + Zx = curve_x_coord(Z); + Zy = curve_y_coord(Z); + + element_set1(v); + m = mpz_sizeinbase(q, 2) - 2; + + for(;;) { + do_tangent(); + + if (!m) break; + + element_double(Z, Z); + if (mpz_tstbit(q, m)) { + do_line(); + element_add(Z, Z, P); + } + m--; + element_square(v, v); + } + + element_set(res, v); + + element_clear(v); + element_clear(Z); + element_clear(a); + element_clear(b); + element_clear(c); + element_clear(t0); + element_clear(e0); + #undef do_tangent + #undef do_line +} + +static void (*cc_miller_no_denom_fn)(element_t res, mpz_t q, element_t P, + element_ptr Qx, element_ptr Qy); + +static void d_pairing_option_set(pairing_t pairing, char *key, char *value) { + UNUSED_VAR(pairing); + if (!strcmp(key, "method")) { + if (!strcmp(value, "miller")) { + cc_miller_no_denom_fn = cc_miller_no_denom_proj; + } else if (!strcmp(value, "miller-affine")) { + cc_miller_no_denom_fn = cc_miller_no_denom_affine; + } + } +} + +// Requires cofactor is even. TODO: This seems to contradict a comment below. +// Requires in != out. +// Mangles in. +static void lucas_even(element_ptr out, element_ptr in, mpz_t cofactor) { + if (element_is1(in)) { + element_set(out, in); + return; + } + element_t temp; + element_init_same_as(temp, out); + element_ptr in0 = element_x(in); + element_ptr in1 = element_y(in); + element_ptr v0 = element_x(out); + element_ptr v1 = element_y(out); + element_ptr t0 = element_x(temp); + element_ptr t1 = element_y(temp); + int j; + + element_set_si(t0, 2); + element_double(t1, in0); + + element_set(v0, t0); + element_set(v1, t1); + + j = mpz_sizeinbase(cofactor, 2) - 1; + for (;;) { + if (!j) { + element_mul(v1, v0, v1); + element_sub(v1, v1, t1); + element_square(v0, v0); + element_sub(v0, v0, t0); + break; + } + if (mpz_tstbit(cofactor, j)) { + element_mul(v0, v0, v1); + element_sub(v0, v0, t1); + element_square(v1, v1); + element_sub(v1, v1, t0); + } else { + element_mul(v1, v0, v1); + element_sub(v1, v1, t1); + element_square(v0, v0); + element_sub(v0, v0, t0); + } + j--; + } + + // Assume cofactor = (q^2 - q + 1) / r is odd + // thus v1 = V_k, v0 = V_{k-1} + // U = (P v1 - 2 v0) / (P^2 - 4) + + element_double(v0, v0); + element_mul(in0, t1, v1); + element_sub(in0, in0, v0); + + element_square(t1, t1); + element_sub(t1, t1, t0); + element_sub(t1, t1, t0); + + element_halve(v0, v1); + element_div(v1, in0, t1); + element_mul(v1, v1, in1); + + element_clear(temp); +} + +// The final powering, where we standardize the coset representative. +static void cc_tatepower(element_ptr out, element_ptr in, pairing_t pairing) { + pptr p = pairing->data; + #define qpower(sign) { \ + polymod_const_mul(e2, inre[1], p->xpowq); \ + element_set(e0re, e2); \ + polymod_const_mul(e2, inre[2], p->xpowq2); \ + element_add(e0re, e0re, e2); \ + element_add(e0re0, e0re0, inre[0]); \ + \ + if (sign > 0) { \ + polymod_const_mul(e2, inim[1], p->xpowq); \ + element_set(e0im, e2); \ + polymod_const_mul(e2, inim[2], p->xpowq2); \ + element_add(e0im, e0im, e2); \ + element_add(e0im0, e0im0, inim[0]); \ + } else { \ + polymod_const_mul(e2, inim[1], p->xpowq); \ + element_neg(e0im, e2); \ + polymod_const_mul(e2, inim[2], p->xpowq2); \ + element_sub(e0im, e0im, e2); \ + element_sub(e0im0, e0im0, inim[0]); \ + } \ + } + if (p->k == 6) { + // See thesis, section 6.9, "The Final Powering", which gives a formula + // for the first step of the final powering when Fq6 has been implemented + // as a quadratic extension on top of a cubic extension. + element_t e0, e2, e3; + element_init(e0, p->Fqk); + element_init(e2, p->Fqd); + element_init(e3, p->Fqk); + element_ptr e0re = element_x(e0); + element_ptr e0im = element_y(e0); + element_ptr e0re0 = ((element_t *) e0re->data)[0]; + element_ptr e0im0 = ((element_t *) e0im->data)[0]; + element_t *inre = element_x(in)->data; + element_t *inim = element_y(in)->data; + // Expressions in the formula are similar, hence the following function. + qpower(1); + element_set(e3, e0); + element_set(e0re, element_x(in)); + element_neg(e0im, element_y(in)); + element_mul(e3, e3, e0); + qpower(-1); + element_mul(e0, e0, in); + element_invert(e0, e0); + element_mul(in, e3, e0); + + element_set(e0, in); + // We use Lucas sequences to complete the final powering. + lucas_even(out, e0, pairing->phikonr); + + element_clear(e0); + element_clear(e2); + element_clear(e3); + } else { + element_pow_mpz(out, in, p->tateexp); + } + #undef qpower +} + +static void cc_finalpow(element_t e) { + cc_tatepower(e->data, e->data, e->field->pairing); +} + +static void cc_pairing(element_ptr out, element_ptr in1, element_ptr in2, + pairing_t pairing) { + element_ptr Qbase = in2; + element_t Qx, Qy; + pptr p = pairing->data; + + element_init(Qx, p->Fqd); + element_init(Qy, p->Fqd); + // Twist: (x, y) --> (v^-1 x, v^-(3/2) y) + // where v is the quadratic nonresidue used to construct the twist. + element_mul(Qx, curve_x_coord(Qbase), p->nqrinv); + // v^-3/2 = v^-2 * v^1/2 + element_mul(Qy, curve_y_coord(Qbase), p->nqrinv2); + cc_miller_no_denom_fn(out, pairing->r, in1, Qx, Qy); + cc_tatepower(out, out, pairing); + element_clear(Qx); + element_clear(Qy); +} + + +//do many millers at one time with affine coordinates. +static void cc_millers_no_denom_affine(element_t res, mpz_t q, element_t P[], + element_t Qx[], element_t Qy[], int n_prod) { + int m, i; + element_t v; + element_t a, b, c; + element_t t0; + element_t e0; + const element_ptr cca = curve_a_coeff(P[0]); + element_ptr Px, Py; + element_t* Z = pbc_malloc(sizeof(element_t)*n_prod); + element_ptr Zx, Zy; + + /* TODO: when exactly is this not needed? + void do_vertical() { + mapbase(e0, Z->x); + element_sub(e0, Qx, e0); + element_mul(v, v, e0); + } + */ + + #define do_tangents() { \ + /* a = -(3 Zx^2 + cc->a) */ \ + /* b = 2 * Zy */ \ + /* c = -(2 Zy^2 + a Zx); */ \ + for(i=0; ifield); + element_init(b, a->field); + element_init(c, a->field); + element_init(t0, a->field); + element_init(e0, res->field); + + element_init(v, res->field); + for(i=0; ifield); + element_set(Z[i], P[i]); + } + + element_set1(v); + m = mpz_sizeinbase(q, 2) - 2; + + for(;;) { + do_tangents(); + + if (!m) break; + element_multi_double(Z, Z, n_prod); //Z_i=Z_i+Z_i for all i. + + if (mpz_tstbit(q, m)) { + do_lines(); + element_multi_add(Z, Z, P, n_prod); //Z_i=Z_i+P_i for all i. + } + m--; + element_square(v, v); + } + + element_set(res, v); + + element_clear(v); + for(i=0; idata; + int i; + for(i=0; iFqd); + element_init(Qy[i], p->Fqd); + Qbase = in2[i]; + // Twist: (x, y) --> (v^-1 x, v^-(3/2) y) + // where v is the quadratic nonresidue used to construct the twist. + element_mul(Qx[i], curve_x_coord(Qbase), p->nqrinv); + // v^-3/2 = v^-2 * v^1/2 + element_mul(Qy[i], curve_y_coord(Qbase), p->nqrinv2); + } + cc_millers_no_denom_affine(out, pairing->r, in1, Qx, Qy, n_prod); + cc_tatepower(out, out, pairing); + + for(i=0; idata; + + element_init(cx, p->Fqd); + element_init(cy, p->Fqd); + element_init(dx, p->Fqd); + element_init(dy, p->Fqd); + + element_init(t0, p->Fqk); + element_init(t1, p->Fqk); + element_init(t2, p->Fqk); + // Twist: (x, y) --> (v^-1 x, v^-(3/2) y) + // where v is the quadratic nonresidue used to construct the twist. + element_mul(cx, curve_x_coord(c), p->nqrinv); + element_mul(dx, curve_x_coord(d), p->nqrinv); + // v^-3/2 = v^-2 * v^1/2 + element_mul(cy, curve_y_coord(c), p->nqrinv2); + element_mul(dy, curve_y_coord(d), p->nqrinv2); + + cc_miller_no_denom_fn(t0, pairing->r, a, dx, dy); + cc_miller_no_denom_fn(t1, pairing->r, b, cx, cy); + cc_tatepower(t0, t0, pairing); + cc_tatepower(t1, t1, pairing); + element_mul(t2, t0, t1); + if (element_is1(t2)) res = 1; // We were given g, g^x, h, h^-x. + else { + // Cheaply check the other case. + element_invert(t1, t1); + element_mul(t2, t0, t1); + if (element_is1(t2)) res = 1; // We were given g, g^x, h, h^x. + } + element_clear(cx); + element_clear(cy); + element_clear(dx); + element_clear(dy); + element_clear(t0); + element_clear(t1); + element_clear(t2); + return res; +} + +struct pp_coeff_s { + element_t a; + element_t b; + element_t c; +}; +typedef struct pp_coeff_s pp_coeff_t[1]; +typedef struct pp_coeff_s *pp_coeff_ptr; + +static void d_pairing_pp_init(pairing_pp_t p, element_ptr in1, pairing_t pairing) { + element_ptr P = in1; + const element_ptr Px = curve_x_coord(P); + const element_ptr Py = curve_y_coord(P); + element_t Z; + int m; + pptr info = pairing->data; + element_t t0; + element_t a, b, c; + field_ptr Fq = info->Fq; + pp_coeff_t *coeff; + mpz_ptr q = pairing->r; + pp_coeff_ptr pp; + const element_ptr cca = curve_a_coeff(P); + element_ptr Zx; + element_ptr Zy; + + #define store_abc() { \ + element_init(pp->a, Fq); \ + element_init(pp->b, Fq); \ + element_init(pp->c, Fq); \ + element_set(pp->a, a); \ + element_set(pp->b, b); \ + element_set(pp->c, c); \ + pp++; \ + } + + #define do_tangent() { \ + /* a = -slope_tangent(Z.x, Z.y); */ \ + /* b = 1; */ \ + /* c = -(Z.y + a * Z.x); */ \ + /* but we multiply by 2*Z.y to avoid division. */ \ + \ + /* a = -Zx * (3 Zx + twicea_2) - a_4; */ \ + /* Common curves: a2 = 0 (and cc->a is a_4), so */ \ + /* a = -(3 Zx^2 + cc->a) */ \ + /* b = 2 * Zy */ \ + /* c = -(2 Zy^2 + a Zx); */ \ + \ + element_square(a, Zx); \ + element_double(t0, a); \ + element_add(a, a, t0); \ + element_add(a, a, cca); \ + element_neg(a, a); \ + \ + element_add(b, Zy, Zy); \ + \ + element_mul(t0, b, Zy); \ + element_mul(c, a, Zx); \ + element_add(c, c, t0); \ + element_neg(c, c); \ + \ + store_abc(); \ + } + + #define do_line() { \ + /* a = -(B.y - A.y) / (B.x - A.x); */ \ + /* b = 1; */ \ + /* c = -(A.y + a * A.x); */ \ + /* but we'll multiply by B.x - A.x to avoid division */ \ + \ + element_sub(b, Px, Zx); \ + element_sub(a, Zy, Py); \ + element_mul(t0, b, Zy); \ + element_mul(c, a, Zx); \ + element_add(c, c, t0); \ + element_neg(c, c); \ + \ + store_abc(); \ + } + + element_init(Z, P->field); + element_set(Z, P); + Zx = curve_x_coord(Z); + Zy = curve_y_coord(Z); + + element_init(t0, Fq); + element_init(a, Fq); + element_init(b, Fq); + element_init(c, Fq); + + m = mpz_sizeinbase(q, 2) - 2; + p->data = pbc_malloc(sizeof(pp_coeff_t) * 2 * m); + coeff = (pp_coeff_t *) p->data; + pp = coeff[0]; + + for(;;) { + do_tangent(); + + if (!m) break; + + element_double(Z, Z); + if (mpz_tstbit(q, m)) { + do_line(); + element_add(Z, Z, P); + } + m--; + } + + element_clear(t0); + element_clear(a); + element_clear(b); + element_clear(c); + element_clear(Z); + #undef store_abc + #undef do_tangent + #undef do_line +} + +static void d_pairing_pp_clear(pairing_pp_t p) { + // TODO: Better to store a sentinel value in p->data? + mpz_ptr q = p->pairing->r; + int m = mpz_sizeinbase(q, 2) + mpz_popcount(q) - 3; + int i; + pp_coeff_t *coeff = (pp_coeff_t *) p->data; + pp_coeff_ptr pp; + for (i=0; ia); + element_clear(pp->b); + element_clear(pp->c); + } + pbc_free(p->data); +} + +static void d_pairing_pp_apply(element_ptr out, element_ptr in2, + pairing_pp_t p) { + mpz_ptr q = p->pairing->r; + pptr info = p->pairing->data; + int m = mpz_sizeinbase(q, 2) - 2; + pp_coeff_t *coeff = (pp_coeff_t *) p->data; + pp_coeff_ptr pp = coeff[0]; + element_ptr Qbase = in2; + element_t e0; + element_t Qx, Qy; + element_t v; + element_init_same_as(e0, out); + element_init_same_as(v, out); + element_init(Qx, info->Fqd); + element_init(Qy, info->Fqd); + + // Twist: (x, y) --> (v^-1 x, v^-(3/2) y) + // where v is the quadratic nonresidue used to construct the twist + element_mul(Qx, curve_x_coord(Qbase), info->nqrinv); + // v^-3/2 = v^-2 * v^1/2 + element_mul(Qy, curve_y_coord(Qbase), info->nqrinv2); + + element_set1(out); + for(;;) { + d_miller_evalfn(e0, pp->a, pp->b, pp->c, Qx, Qy); + element_mul(out, out, e0); + pp++; + + if (!m) break; + + if (mpz_tstbit(q, m)) { + d_miller_evalfn(e0, pp->a, pp->b, pp->c, Qx, Qy); + element_mul(out, out, e0); + pp++; + } + m--; + element_square(out, out); + } + cc_tatepower(out, out, p->pairing); + + element_clear(e0); + element_clear(Qx); + element_clear(Qy); + element_clear(v); +} + +static void d_pairing_clear(pairing_t pairing) { + field_clear(pairing->GT); + pptr p = pairing->data; + + if (p->k == 6) { + element_clear(p->xpowq); + element_clear(p->xpowq2); + mpz_clear(pairing->phikonr); + } else { + mpz_clear(p->tateexp); + } + + field_clear(p->Etwist); + field_clear(p->Eq); + element_clear(p->nqrinv); + element_clear(p->nqrinv2); + field_clear(p->Fqk); + field_clear(p->Fqd); + field_clear(p->Fqx); + field_clear(p->Fq); + field_clear(pairing->Zr); + mpz_clear(pairing->r); + pbc_free(p); +} + +static void d_init_pairing(pairing_ptr pairing, void *data) { + d_param_ptr param = data; + pptr p; + element_t a, b; + element_t irred; + int d = param->k / 2; + int i; + + if (param->k % 2) pbc_die("k must be even"); + + mpz_init(pairing->r); + mpz_set(pairing->r, param->r); + field_init_fp(pairing->Zr, pairing->r); + pairing->map = cc_pairing; + pairing->prod_pairings = cc_pairings_affine; + pairing->is_almost_coddh = cc_is_almost_coddh; + + p = pairing->data = pbc_malloc(sizeof(*p)); + field_init_fp(p->Fq, param->q); + element_init(a, p->Fq); + element_init(b, p->Fq); + element_set_mpz(a, param->a); + element_set_mpz(b, param->b); + field_init_curve_ab(p->Eq, a, b, pairing->r, param->h); + + field_init_poly(p->Fqx, p->Fq); + element_init(irred, p->Fqx); + poly_set_coeff1(irred, d); + for (i = 0; i < d; i++) { + element_set_mpz(element_item(irred, i), param->coeff[i]); + } + + field_init_polymod(p->Fqd, irred); + element_clear(irred); + + p->Fqd->nqr = pbc_malloc(sizeof(element_t)); + element_init(p->Fqd->nqr, p->Fqd); + element_set_mpz(((element_t *) p->Fqd->nqr->data)[0], param->nqr); + + field_init_quadratic(p->Fqk, p->Fqd); + + // Compute constants involved in the final powering. + if (param->k == 6) { + mpz_ptr q = param->q; + mpz_ptr z = pairing->phikonr; + mpz_init(z); + mpz_mul(z, q, q); + mpz_sub(z, z, q); + mpz_add_ui(z, z, 1); + mpz_divexact(z, z, pairing->r); + + element_ptr e = p->xpowq; + element_init(e, p->Fqd); + element_set1(((element_t *) e->data)[1]); + element_pow_mpz(e, e, q); + + element_init(p->xpowq2, p->Fqd); + element_square(p->xpowq2, e); + } else { + mpz_init(p->tateexp); + mpz_sub_ui(p->tateexp, p->Fqk->order, 1); + mpz_divexact(p->tateexp, p->tateexp, pairing->r); + } + + field_init_curve_ab_map(p->Etwist, p->Eq, element_field_to_polymod, p->Fqd, pairing->r, NULL); + field_reinit_curve_twist(p->Etwist); + + mpz_t ndonr; + mpz_init(ndonr); + // ndonr temporarily holds the trace. + mpz_sub(ndonr, param->q, param->n); + mpz_add_ui(ndonr, ndonr, 1); + // Negate it because we want the trace of the twist. + mpz_neg(ndonr, ndonr); + pbc_mpz_curve_order_extn(ndonr, param->q, ndonr, d); + mpz_divexact(ndonr, ndonr, param->r); + field_curve_set_quotient_cmp(p->Etwist, ndonr); + mpz_clear(ndonr); + + element_init(p->nqrinv, p->Fqd); + element_invert(p->nqrinv, field_get_nqr(p->Fqd)); + element_init(p->nqrinv2, p->Fqd); + element_square(p->nqrinv2, p->nqrinv); + + pairing->G1 = p->Eq; + pairing->G2 = p->Etwist; + + p->k = param->k; + pairing_GT_init(pairing, p->Fqk); + pairing->finalpow = cc_finalpow; + + // By default use affine coordinates. + cc_miller_no_denom_fn = cc_miller_no_denom_affine; + pairing->option_set = d_pairing_option_set; + pairing->pp_init = d_pairing_pp_init; + pairing->pp_clear = d_pairing_pp_clear; + pairing->pp_apply = d_pairing_pp_apply; + + pairing->clear_func = d_pairing_clear; + + element_clear(a); + element_clear(b); +} + +// Computes a curve and sets fp to the field it is defined over using the +// complex multiplication method, where cm holds the appropriate information +// (e.g. discriminant, field order). +static void compute_cm_curve(d_param_ptr param, pbc_cm_ptr cm) { + element_t hp, root; + field_t fp, fpx; + field_t cc; + + field_init_fp(fp, cm->q); + field_init_poly(fpx, fp); + element_init(hp, fpx); + + mpz_t *coefflist; + int n = pbc_hilbert(&coefflist, cm->D); + + // Temporarily set the coefficient of x^{n-1} to 1 so hp has degree n - 1, + // allowing us to use poly_coeff(). + poly_set_coeff1(hp, n - 1); + int i; + for (i = 0; i < n; i++) { + element_set_mpz(element_item(hp, i), coefflist[i]); + } + pbc_hilbert_free(coefflist, n); + + // TODO: Remove x = 0, 1728 roots. + // TODO: What if there are no roots? + //printf("hp "); + //element_out_str(stdout, 0, hp); + //printf("\n"); + + element_init(root, fp); + poly_findroot(root, hp); + //printf("root = "); + //element_out_str(stdout, 0, root); + //printf("\n"); + element_clear(hp); + field_clear(fpx); + + // The root is the j-invariant of the desired curve. + field_init_curve_j(cc, root, cm->n, NULL); + element_clear(root); + + // We may need to twist it. + { + // Pick a random point P and twist the curve if it has the wrong order. + element_t P; + element_init(P, cc); + element_random(P); + element_mul_mpz(P, P, cm->n); + if (!element_is0(P)) field_reinit_curve_twist(cc); + element_clear(P); + } + + mpz_set(param->q, cm->q); + mpz_set(param->n, cm->n); + mpz_set(param->h, cm->h); + mpz_set(param->r, cm->r); + element_to_mpz(param->a, curve_field_a_coeff(cc)); + element_to_mpz(param->b, curve_field_b_coeff(cc)); + param->k = cm->k; + { + mpz_t z; + mpz_init(z); + // Compute order of curve in F_q^k. + // n = q - t + 1 hence t = q - n + 1 + mpz_sub(z, param->q, param->n); + mpz_add_ui(z, z, 1); + pbc_mpz_trace_n(z, param->q, z, param->k); + mpz_pow_ui(param->nk, param->q, param->k); + mpz_sub_ui(z, z, 1); + mpz_sub(param->nk, param->nk, z); + mpz_mul(z, param->r, param->r); + mpz_divexact(param->hk, param->nk, z); + mpz_clear(z); + } + field_clear(cc); + field_clear(fp); +} + +static void d_param_init(pbc_param_ptr p) { + static pbc_param_interface_t interface = {{ + d_clear, + d_init_pairing, + d_out_str, + }}; + p->api = interface; + d_param_ptr param = p->data = pbc_malloc(sizeof(*param)); + mpz_init(param->q); + mpz_init(param->n); + mpz_init(param->h); + mpz_init(param->r); + mpz_init(param->a); + mpz_init(param->b); + mpz_init(param->nk); + mpz_init(param->hk); + param->k = 0; + param->coeff = NULL; + mpz_init(param->nqr); +} + +// Public interface: + +int pbc_param_init_d(pbc_param_ptr par, struct symtab_s *tab) { + d_param_init(par); + d_param_ptr p = par->data; + char s[80]; + int i, d; + + int err = 0; + err += lookup_mpz(p->q, tab, "q"); + err += lookup_mpz(p->n, tab, "n"); + err += lookup_mpz(p->h, tab, "h"); + err += lookup_mpz(p->r, tab, "r"); + err += lookup_mpz(p->a, tab, "a"); + err += lookup_mpz(p->b, tab, "b"); + err += lookup_int(&p->k, tab, "k"); + err += lookup_mpz(p->nk, tab, "nk"); + err += lookup_mpz(p->hk, tab, "hk"); + err += lookup_mpz(p->nqr, tab, "nqr"); + + d = p->k / 2; + p->coeff = pbc_realloc(p->coeff, sizeof(mpz_t) * d); + for (i=0; icoeff[i]); + err += lookup_mpz(p->coeff[i], tab, s); + } + return err; +} + +void pbc_param_init_d_gen(pbc_param_ptr p, pbc_cm_ptr cm) { + d_param_init(p); + d_param_ptr param = p->data; + field_t Fq, Fqx, Fqd; + element_t irred, nqr; + int d = cm->k / 2; + int i; + + compute_cm_curve(param, cm); + + field_init_fp(Fq, param->q); + field_init_poly(Fqx, Fq); + element_init(irred, Fqx); + do { + poly_random_monic(irred, d); + } while (!poly_is_irred(irred)); + field_init_polymod(Fqd, irred); + + // Find a quadratic nonresidue of Fqd lying in Fq. + element_init(nqr, Fqd); + do { + element_random(((element_t *) nqr->data)[0]); + } while (element_is_sqr(nqr)); + + param->coeff = pbc_realloc(param->coeff, sizeof(mpz_t) * d); + + for (i=0; icoeff[i]); + element_to_mpz(param->coeff[i], element_item(irred, i)); + } + element_to_mpz(param->nqr, ((element_t *) nqr->data)[0]); + + element_clear(nqr); + element_clear(irred); + + field_clear(Fqx); + field_clear(Fqd); + field_clear(Fq); +} -- cgit 1.2.3-korg