crypto/fipsmodule/ec/p256-x86_64.c - boringssl.git - Git at Google

 /*
  * Copyright 2014-2016 The OpenSSL Project Authors. All Rights Reserved.
  * Copyright (c) 2014, Intel Corporation. All Rights Reserved.
  *
  * Licensed under the OpenSSL license (the "License").  You may not use
  * this file except in compliance with the License.  You can obtain a copy
  * in the file LICENSE in the source distribution or at
  * https://www.openssl.org/source/license.html
  *
  * Originally written by Shay Gueron (1, 2), and Vlad Krasnov (1)
  * (1) Intel Corporation, Israel Development Center, Haifa, Israel
  * (2) University of Haifa, Israel
  *
  * Reference:
  * S.Gueron and V.Krasnov, "Fast Prime Field Elliptic Curve Cryptography with
  *                          256 Bit Primes"
  */

 #include <openssl/ec.h>

 #include <assert.h>
 #include <stdint.h>
 #include <string.h>

 #include <openssl/bn.h>
 #include <openssl/cpu.h>
 #include <openssl/crypto.h>
 #include <openssl/err.h>

 #include "../bn/internal.h"
 #include "../delocate.h"
 #include "../../internal.h"
 #include "internal.h"
 #include "p256-x86_64.h"


 #if !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86_64) && \
     !defined(OPENSSL_SMALL)

 typedef P256_POINT_AFFINE PRECOMP256_ROW[64];

 // One converted into the Montgomery domain
 static const BN_ULONG ONE[P256_LIMBS] = {
     TOBN(0x00000000, 0x00000001), TOBN(0xffffffff, 0x00000000),
     TOBN(0xffffffff, 0xffffffff), TOBN(0x00000000, 0xfffffffe),
 };

 // Precomputed tables for the default generator
 #include "p256-x86_64-table.h"

 // Recode window to a signed digit, see |ec_GFp_nistp_recode_scalar_bits| in
 // util.c for details
 static crypto_word_t booth_recode_w5(crypto_word_t in) {
   crypto_word_t s, d;

   s = ~((in >> 5) - 1);
   d = (1 << 6) - in - 1;
   d = (d & s) | (in & ~s);
   d = (d >> 1) + (d & 1);

   return (d << 1) + (s & 1);
 }

 static crypto_word_t booth_recode_w7(crypto_word_t in) {
   crypto_word_t s, d;

   s = ~((in >> 7) - 1);
   d = (1 << 8) - in - 1;
   d = (d & s) | (in & ~s);
   d = (d >> 1) + (d & 1);

   return (d << 1) + (s & 1);
 }

 // copy_conditional copies |src| to |dst| if |move| is one and leaves it as-is
 // if |move| is zero.
 //
 // WARNING: this breaks the usual convention of constant-time functions
 // returning masks.
 static void copy_conditional(BN_ULONG dst[P256_LIMBS],
                              const BN_ULONG src[P256_LIMBS], BN_ULONG move) {
   BN_ULONG mask1 = ((BN_ULONG)0) - move;
   BN_ULONG mask2 = ~mask1;

   dst[0] = (src[0] & mask1) ^ (dst[0] & mask2);
   dst[1] = (src[1] & mask1) ^ (dst[1] & mask2);
   dst[2] = (src[2] & mask1) ^ (dst[2] & mask2);
   dst[3] = (src[3] & mask1) ^ (dst[3] & mask2);
   if (P256_LIMBS == 8) {
     dst[4] = (src[4] & mask1) ^ (dst[4] & mask2);
     dst[5] = (src[5] & mask1) ^ (dst[5] & mask2);
     dst[6] = (src[6] & mask1) ^ (dst[6] & mask2);
     dst[7] = (src[7] & mask1) ^ (dst[7] & mask2);
   }
 }

 // is_not_zero returns one iff in != 0 and zero otherwise.
 //
 // WARNING: this breaks the usual convention of constant-time functions
 // returning masks.
 //
 // (define-fun is_not_zero ((in (_ BitVec 64))) (_ BitVec 64)
 //   (bvlshr (bvor in (bvsub #x0000000000000000 in)) #x000000000000003f)
 // )
 //
 // (declare-fun x () (_ BitVec 64))
 //
 // (assert (and (= x #x0000000000000000) (= (is_not_zero x) #x0000000000000001)))
 // (check-sat)
 //
 // (assert (and (not (= x #x0000000000000000)) (= (is_not_zero x) #x0000000000000000)))
 // (check-sat)
 //
 static BN_ULONG is_not_zero(BN_ULONG in) {
   in |= (0 - in);
   in >>= BN_BITS2 - 1;
   return in;
 }

 // ecp_nistz256_mod_inverse_sqr_mont sets |r| to (|in| * 2^-256)^-2 * 2^256 mod
 // p. That is, |r| is the modular inverse square of |in| for input and output in
 // the Montgomery domain.
 static void ecp_nistz256_mod_inverse_sqr_mont(BN_ULONG r[P256_LIMBS],
                                               const BN_ULONG in[P256_LIMBS]) {
   // This implements the addition chain described in
   // https://briansmith.org/ecc-inversion-addition-chains-01#p256_field_inversion
   BN_ULONG x2[P256_LIMBS], x3[P256_LIMBS], x6[P256_LIMBS], x12[P256_LIMBS],
       x15[P256_LIMBS], x30[P256_LIMBS], x32[P256_LIMBS];
   ecp_nistz256_sqr_mont(x2, in);      // 2^2 - 2^1
   ecp_nistz256_mul_mont(x2, x2, in);  // 2^2 - 2^0

   ecp_nistz256_sqr_mont(x3, x2);      // 2^3 - 2^1
   ecp_nistz256_mul_mont(x3, x3, in);  // 2^3 - 2^0

   ecp_nistz256_sqr_mont(x6, x3);
   for (int i = 1; i < 3; i++) {
     ecp_nistz256_sqr_mont(x6, x6);
   }                                   // 2^6 - 2^3
   ecp_nistz256_mul_mont(x6, x6, x3);  // 2^6 - 2^0

   ecp_nistz256_sqr_mont(x12, x6);
   for (int i = 1; i < 6; i++) {
     ecp_nistz256_sqr_mont(x12, x12);
   }                                     // 2^12 - 2^6
   ecp_nistz256_mul_mont(x12, x12, x6);  // 2^12 - 2^0

   ecp_nistz256_sqr_mont(x15, x12);
   for (int i = 1; i < 3; i++) {
     ecp_nistz256_sqr_mont(x15, x15);
   }                                     // 2^15 - 2^3
   ecp_nistz256_mul_mont(x15, x15, x3);  // 2^15 - 2^0

   ecp_nistz256_sqr_mont(x30, x15);
   for (int i = 1; i < 15; i++) {
     ecp_nistz256_sqr_mont(x30, x30);
   }                                      // 2^30 - 2^15
   ecp_nistz256_mul_mont(x30, x30, x15);  // 2^30 - 2^0

   ecp_nistz256_sqr_mont(x32, x30);
   ecp_nistz256_sqr_mont(x32, x32);      // 2^32 - 2^2
   ecp_nistz256_mul_mont(x32, x32, x2);  // 2^32 - 2^0

   BN_ULONG ret[P256_LIMBS];
   ecp_nistz256_sqr_mont(ret, x32);
   for (int i = 1; i < 31 + 1; i++) {
     ecp_nistz256_sqr_mont(ret, ret);
   }                                     // 2^64 - 2^32
   ecp_nistz256_mul_mont(ret, ret, in);  // 2^64 - 2^32 + 2^0

   for (int i = 0; i < 96 + 32; i++) {
     ecp_nistz256_sqr_mont(ret, ret);
   }                                      // 2^192 - 2^160 + 2^128
   ecp_nistz256_mul_mont(ret, ret, x32);  // 2^192 - 2^160 + 2^128 + 2^32 - 2^0

   for (int i = 0; i < 32; i++) {
     ecp_nistz256_sqr_mont(ret, ret);
   }                                      // 2^224 - 2^192 + 2^160 + 2^64 - 2^32
   ecp_nistz256_mul_mont(ret, ret, x32);  // 2^224 - 2^192 + 2^160 + 2^64 - 2^0

   for (int i = 0; i < 30; i++) {
     ecp_nistz256_sqr_mont(ret, ret);
   }                                      // 2^254 - 2^222 + 2^190 + 2^94 - 2^30
   ecp_nistz256_mul_mont(ret, ret, x30);  // 2^254 - 2^222 + 2^190 + 2^94 - 2^0

   ecp_nistz256_sqr_mont(ret, ret);
   ecp_nistz256_sqr_mont(r, ret);  // 2^256 - 2^224 + 2^192 + 2^96 - 2^2
 }

 // r = p * p_scalar
 static void ecp_nistz256_windowed_mul(const EC_GROUP *group, P256_POINT *r,
                                       const EC_RAW_POINT *p,
                                       const EC_SCALAR *p_scalar) {
   assert(p != NULL);
   assert(p_scalar != NULL);
   assert(group->field.width == P256_LIMBS);

   static const size_t kWindowSize = 5;
   static const crypto_word_t kMask = (1 << (5 /* kWindowSize */ + 1)) - 1;

   // A |P256_POINT| is (3 * 32) = 96 bytes, and the 64-byte alignment should
   // add no more than 63 bytes of overhead. Thus, |table| should require
   // ~1599 ((96 * 16) + 63) bytes of stack space.
   alignas(64) P256_POINT table[16];
   uint8_t p_str[33];
   OPENSSL_memcpy(p_str, p_scalar->bytes, 32);
   p_str[32] = 0;

   // table[0] is implicitly (0,0,0) (the point at infinity), therefore it is
   // not stored. All other values are actually stored with an offset of -1 in
   // table.
   P256_POINT *row = table;
   assert(group->field.width == P256_LIMBS);
   OPENSSL_memcpy(row[1 - 1].X, p->X.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(row[1 - 1].Y, p->Y.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(row[1 - 1].Z, p->Z.words, P256_LIMBS * sizeof(BN_ULONG));

   ecp_nistz256_point_double(&row[2 - 1], &row[1 - 1]);
   ecp_nistz256_point_add(&row[3 - 1], &row[2 - 1], &row[1 - 1]);
   ecp_nistz256_point_double(&row[4 - 1], &row[2 - 1]);
   ecp_nistz256_point_double(&row[6 - 1], &row[3 - 1]);
   ecp_nistz256_point_double(&row[8 - 1], &row[4 - 1]);
   ecp_nistz256_point_double(&row[12 - 1], &row[6 - 1]);
   ecp_nistz256_point_add(&row[5 - 1], &row[4 - 1], &row[1 - 1]);
   ecp_nistz256_point_add(&row[7 - 1], &row[6 - 1], &row[1 - 1]);
   ecp_nistz256_point_add(&row[9 - 1], &row[8 - 1], &row[1 - 1]);
   ecp_nistz256_point_add(&row[13 - 1], &row[12 - 1], &row[1 - 1]);
   ecp_nistz256_point_double(&row[14 - 1], &row[7 - 1]);
   ecp_nistz256_point_double(&row[10 - 1], &row[5 - 1]);
   ecp_nistz256_point_add(&row[15 - 1], &row[14 - 1], &row[1 - 1]);
   ecp_nistz256_point_add(&row[11 - 1], &row[10 - 1], &row[1 - 1]);
   ecp_nistz256_point_double(&row[16 - 1], &row[8 - 1]);

   BN_ULONG tmp[P256_LIMBS];
   alignas(32) P256_POINT h;
   size_t index = 255;
   crypto_word_t wvalue = p_str[(index - 1) / 8];
   wvalue = (wvalue >> ((index - 1) % 8)) & kMask;

   ecp_nistz256_select_w5(r, table, booth_recode_w5(wvalue) >> 1);

   while (index >= 5) {
     if (index != 255) {
       size_t off = (index - 1) / 8;

       wvalue = (crypto_word_t)p_str[off] | (crypto_word_t)p_str[off + 1] << 8;
       wvalue = (wvalue >> ((index - 1) % 8)) & kMask;

       wvalue = booth_recode_w5(wvalue);

       ecp_nistz256_select_w5(&h, table, wvalue >> 1);

       ecp_nistz256_neg(tmp, h.Y);
       copy_conditional(h.Y, tmp, (wvalue & 1));

       ecp_nistz256_point_add(r, r, &h);
     }

     index -= kWindowSize;

     ecp_nistz256_point_double(r, r);
     ecp_nistz256_point_double(r, r);
     ecp_nistz256_point_double(r, r);
     ecp_nistz256_point_double(r, r);
     ecp_nistz256_point_double(r, r);
   }

   // Final window
   wvalue = p_str[0];
   wvalue = (wvalue << 1) & kMask;

   wvalue = booth_recode_w5(wvalue);

   ecp_nistz256_select_w5(&h, table, wvalue >> 1);

   ecp_nistz256_neg(tmp, h.Y);
   copy_conditional(h.Y, tmp, wvalue & 1);

   ecp_nistz256_point_add(r, r, &h);
 }

 typedef union {
   P256_POINT p;
   P256_POINT_AFFINE a;
 } p256_point_union_t;

 static crypto_word_t calc_first_wvalue(size_t *index, const uint8_t p_str[33]) {
   static const size_t kWindowSize = 7;
   static const crypto_word_t kMask = (1 << (7 /* kWindowSize */ + 1)) - 1;
   *index = kWindowSize;

   crypto_word_t wvalue = (p_str[0] << 1) & kMask;
   return booth_recode_w7(wvalue);
 }

 static crypto_word_t calc_wvalue(size_t *index, const uint8_t p_str[33]) {
   static const size_t kWindowSize = 7;
   static const crypto_word_t kMask = (1 << (7 /* kWindowSize */ + 1)) - 1;

   const size_t off = (*index - 1) / 8;
   crypto_word_t wvalue =
       (crypto_word_t)p_str[off] | (crypto_word_t)p_str[off + 1] << 8;
   wvalue = (wvalue >> ((*index - 1) % 8)) & kMask;
   *index += kWindowSize;

   return booth_recode_w7(wvalue);
 }

 static void ecp_nistz256_point_mul(const EC_GROUP *group, EC_RAW_POINT *r,
                                    const EC_RAW_POINT *p,
                                    const EC_SCALAR *scalar) {
   alignas(32) P256_POINT out;
   ecp_nistz256_windowed_mul(group, &out, p, scalar);

   assert(group->field.width == P256_LIMBS);
   OPENSSL_memcpy(r->X.words, out.X, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Y.words, out.Y, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Z.words, out.Z, P256_LIMBS * sizeof(BN_ULONG));
 }

 static void ecp_nistz256_point_mul_base(const EC_GROUP *group, EC_RAW_POINT *r,
                                         const EC_SCALAR *scalar) {
   alignas(32) p256_point_union_t t, p;

   uint8_t p_str[33];
   OPENSSL_memcpy(p_str, scalar->bytes, 32);
   p_str[32] = 0;

   // First window
   size_t index = 0;
   crypto_word_t wvalue = calc_first_wvalue(&index, p_str);

   ecp_nistz256_select_w7(&p.a, ecp_nistz256_precomputed[0], wvalue >> 1);
   ecp_nistz256_neg(p.p.Z, p.p.Y);
   copy_conditional(p.p.Y, p.p.Z, wvalue & 1);

   // Convert |p| from affine to Jacobian coordinates. We set Z to zero if |p|
   // is infinity and |ONE| otherwise. |p| was computed from the table, so it
   // is infinity iff |wvalue >> 1| is zero.
   OPENSSL_memset(p.p.Z, 0, sizeof(p.p.Z));
   copy_conditional(p.p.Z, ONE, is_not_zero(wvalue >> 1));

   for (int i = 1; i < 37; i++) {
     wvalue = calc_wvalue(&index, p_str);

     ecp_nistz256_select_w7(&t.a, ecp_nistz256_precomputed[i], wvalue >> 1);

     ecp_nistz256_neg(t.p.Z, t.a.Y);
     copy_conditional(t.a.Y, t.p.Z, wvalue & 1);

     // Note |ecp_nistz256_point_add_affine| does not work if |p.p| and |t.a|
     // are the same non-infinity point.
     ecp_nistz256_point_add_affine(&p.p, &p.p, &t.a);
   }

   assert(group->field.width == P256_LIMBS);
   OPENSSL_memcpy(r->X.words, p.p.X, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Y.words, p.p.Y, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Z.words, p.p.Z, P256_LIMBS * sizeof(BN_ULONG));
 }

 static void ecp_nistz256_points_mul_public(const EC_GROUP *group,
                                            EC_RAW_POINT *r,
                                            const EC_SCALAR *g_scalar,
                                            const EC_RAW_POINT *p_,
                                            const EC_SCALAR *p_scalar) {
   assert(p_ != NULL && p_scalar != NULL && g_scalar != NULL);

   alignas(32) p256_point_union_t t, p;
   uint8_t p_str[33];
   OPENSSL_memcpy(p_str, g_scalar->bytes, 32);
   p_str[32] = 0;

   // First window
   size_t index = 0;
   size_t wvalue = calc_first_wvalue(&index, p_str);

   // Convert |p| from affine to Jacobian coordinates. We set Z to zero if |p|
   // is infinity and |ONE| otherwise. |p| was computed from the table, so it
   // is infinity iff |wvalue >> 1| is zero.
   if ((wvalue >> 1) != 0) {
     OPENSSL_memcpy(&p.a, &ecp_nistz256_precomputed[0][(wvalue >> 1) - 1],
                    sizeof(p.a));
     OPENSSL_memcpy(&p.p.Z, ONE, sizeof(p.p.Z));
   } else {
     OPENSSL_memset(&p.a, 0, sizeof(p.a));
     OPENSSL_memset(p.p.Z, 0, sizeof(p.p.Z));
   }

   if ((wvalue & 1) == 1) {
     ecp_nistz256_neg(p.p.Y, p.p.Y);
   }

   for (int i = 1; i < 37; i++) {
     wvalue = calc_wvalue(&index, p_str);

     if ((wvalue >> 1) == 0) {
       continue;
     }

     OPENSSL_memcpy(&t.a, &ecp_nistz256_precomputed[i][(wvalue >> 1) - 1],
                    sizeof(p.a));

     if ((wvalue & 1) == 1) {
       ecp_nistz256_neg(t.a.Y, t.a.Y);
     }

     // Note |ecp_nistz256_point_add_affine| does not work if |p.p| and |t.a|
     // are the same non-infinity point, so it is important that we compute the
     // |g_scalar| term before the |p_scalar| term.
     ecp_nistz256_point_add_affine(&p.p, &p.p, &t.a);
   }

   ecp_nistz256_windowed_mul(group, &t.p, p_, p_scalar);
   ecp_nistz256_point_add(&p.p, &p.p, &t.p);

   assert(group->field.width == P256_LIMBS);
   OPENSSL_memcpy(r->X.words, p.p.X, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Y.words, p.p.Y, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Z.words, p.p.Z, P256_LIMBS * sizeof(BN_ULONG));
 }

 static int ecp_nistz256_get_affine(const EC_GROUP *group,
                                    const EC_RAW_POINT *point, EC_FELEM *x,
                                    EC_FELEM *y) {
   if (ec_GFp_simple_is_at_infinity(group, point)) {
     OPENSSL_PUT_ERROR(EC, EC_R_POINT_AT_INFINITY);
     return 0;
   }

   BN_ULONG z_inv2[P256_LIMBS];
   assert(group->field.width == P256_LIMBS);
   ecp_nistz256_mod_inverse_sqr_mont(z_inv2, point->Z.words);

   if (x != NULL) {
     ecp_nistz256_mul_mont(x->words, z_inv2, point->X.words);
   }

   if (y != NULL) {
     ecp_nistz256_sqr_mont(z_inv2, z_inv2);                            // z^-4
     ecp_nistz256_mul_mont(y->words, point->Y.words, point->Z.words);  // y * z
     ecp_nistz256_mul_mont(y->words, y->words, z_inv2);  // y * z^-3
   }

   return 1;
 }

 static void ecp_nistz256_add(const EC_GROUP *group, EC_RAW_POINT *r,
                              const EC_RAW_POINT *a_, const EC_RAW_POINT *b_) {
   P256_POINT a, b;
   OPENSSL_memcpy(a.X, a_->X.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(a.Y, a_->Y.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(a.Z, a_->Z.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(b.X, b_->X.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(b.Y, b_->Y.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(b.Z, b_->Z.words, P256_LIMBS * sizeof(BN_ULONG));
   ecp_nistz256_point_add(&a, &a, &b);
   OPENSSL_memcpy(r->X.words, a.X, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Y.words, a.Y, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Z.words, a.Z, P256_LIMBS * sizeof(BN_ULONG));
 }

 static void ecp_nistz256_dbl(const EC_GROUP *group, EC_RAW_POINT *r,
                              const EC_RAW_POINT *a_) {
   P256_POINT a;
   OPENSSL_memcpy(a.X, a_->X.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(a.Y, a_->Y.words, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(a.Z, a_->Z.words, P256_LIMBS * sizeof(BN_ULONG));
   ecp_nistz256_point_double(&a, &a);
   OPENSSL_memcpy(r->X.words, a.X, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Y.words, a.Y, P256_LIMBS * sizeof(BN_ULONG));
   OPENSSL_memcpy(r->Z.words, a.Z, P256_LIMBS * sizeof(BN_ULONG));
 }

 static void ecp_nistz256_inv0_mod_ord(const EC_GROUP *group, EC_SCALAR *out,
                                       const EC_SCALAR *in) {
   // table[i] stores a power of |in| corresponding to the matching enum value.
   enum {
     // The following indices specify the power in binary.
     i_1 = 0,
     i_10,
     i_11,
     i_101,
     i_111,
     i_1010,
     i_1111,
     i_10101,
     i_101010,
     i_101111,
     // The following indices specify 2^N-1, or N ones in a row.
     i_x6,
     i_x8,
     i_x16,
     i_x32
   };
   BN_ULONG table[15][P256_LIMBS];

   // https://briansmith.org/ecc-inversion-addition-chains-01#p256_scalar_inversion
   //
   // Even though this code path spares 12 squarings, 4.5%, and 13
   // multiplications, 25%, the overall sign operation is not that much faster,
   // not more that 2%. Most of the performance of this function comes from the
   // scalar operations.

   // Pre-calculate powers.
   OPENSSL_memcpy(table[i_1], in->words, P256_LIMBS * sizeof(BN_ULONG));

   ecp_nistz256_ord_sqr_mont(table[i_10], table[i_1], 1);

   ecp_nistz256_ord_mul_mont(table[i_11], table[i_1], table[i_10]);

   ecp_nistz256_ord_mul_mont(table[i_101], table[i_11], table[i_10]);

   ecp_nistz256_ord_mul_mont(table[i_111], table[i_101], table[i_10]);

   ecp_nistz256_ord_sqr_mont(table[i_1010], table[i_101], 1);

   ecp_nistz256_ord_mul_mont(table[i_1111], table[i_1010], table[i_101]);

   ecp_nistz256_ord_sqr_mont(table[i_10101], table[i_1010], 1);
   ecp_nistz256_ord_mul_mont(table[i_10101], table[i_10101], table[i_1]);

   ecp_nistz256_ord_sqr_mont(table[i_101010], table[i_10101], 1);

   ecp_nistz256_ord_mul_mont(table[i_101111], table[i_101010], table[i_101]);

   ecp_nistz256_ord_mul_mont(table[i_x6], table[i_101010], table[i_10101]);

   ecp_nistz256_ord_sqr_mont(table[i_x8], table[i_x6], 2);
   ecp_nistz256_ord_mul_mont(table[i_x8], table[i_x8], table[i_11]);

   ecp_nistz256_ord_sqr_mont(table[i_x16], table[i_x8], 8);
   ecp_nistz256_ord_mul_mont(table[i_x16], table[i_x16], table[i_x8]);

   ecp_nistz256_ord_sqr_mont(table[i_x32], table[i_x16], 16);
   ecp_nistz256_ord_mul_mont(table[i_x32], table[i_x32], table[i_x16]);

   // Compute |in| raised to the order-2.
   ecp_nistz256_ord_sqr_mont(out->words, table[i_x32], 64);
   ecp_nistz256_ord_mul_mont(out->words, out->words, table[i_x32]);
   static const struct {
     uint8_t p, i;
   } kChain[27] = {{32, i_x32},    {6, i_101111}, {5, i_111},    {4, i_11},
                   {5, i_1111},    {5, i_10101},  {4, i_101},    {3, i_101},
                   {3, i_101},     {5, i_111},    {9, i_101111}, {6, i_1111},
                   {2, i_1},       {5, i_1},      {6, i_1111},   {5, i_111},
                   {4, i_111},     {5, i_111},    {5, i_101},    {3, i_11},
                   {10, i_101111}, {2, i_11},     {5, i_11},     {5, i_11},
                   {3, i_1},       {7, i_10101},  {6, i_1111}};
   for (size_t i = 0; i < OPENSSL_ARRAY_SIZE(kChain); i++) {
     ecp_nistz256_ord_sqr_mont(out->words, out->words, kChain[i].p);
     ecp_nistz256_ord_mul_mont(out->words, out->words, table[kChain[i].i]);
   }
 }

 static int ecp_nistz256_scalar_to_montgomery_inv_vartime(const EC_GROUP *group,
                                                  EC_SCALAR *out,
                                                  const EC_SCALAR *in) {
   if ((OPENSSL_ia32cap_get()[1] & (1 << 28)) == 0) {
     // No AVX support; fallback to generic code.
     return ec_simple_scalar_to_montgomery_inv_vartime(group, out, in);
   }

   assert(group->order.width == P256_LIMBS);
   if (!beeu_mod_inverse_vartime(out->words, in->words, group->order.d)) {
     return 0;
   }

   // The result should be returned in the Montgomery domain.
   ec_scalar_to_montgomery(group, out, out);
   return 1;
 }

 static int ecp_nistz256_cmp_x_coordinate(const EC_GROUP *group,
                                          const EC_RAW_POINT *p,
                                          const EC_SCALAR *r) {
   if (ec_GFp_simple_is_at_infinity(group, p)) {
     return 0;
   }

   assert(group->order.width == P256_LIMBS);
   assert(group->field.width == P256_LIMBS);

   // We wish to compare X/Z^2 with r. This is equivalent to comparing X with
   // r*Z^2. Note that X and Z are represented in Montgomery form, while r is
   // not.
   BN_ULONG r_Z2[P256_LIMBS], Z2_mont[P256_LIMBS], X[P256_LIMBS];
   ecp_nistz256_mul_mont(Z2_mont, p->Z.words, p->Z.words);
   ecp_nistz256_mul_mont(r_Z2, r->words, Z2_mont);
   ecp_nistz256_from_mont(X, p->X.words);

   if (OPENSSL_memcmp(r_Z2, X, sizeof(r_Z2)) == 0) {
     return 1;
   }

   // During signing the x coefficient is reduced modulo the group order.
   // Therefore there is a small possibility, less than 1/2^128, that group_order
   // < p.x < P. in that case we need not only to compare against |r| but also to
   // compare against r+group_order.
   if (bn_less_than_words(r->words, group->field_minus_order.words,
                          P256_LIMBS)) {
     // We can ignore the carry because: r + group_order < p < 2^256.
     bn_add_words(r_Z2, r->words, group->order.d, P256_LIMBS);
     ecp_nistz256_mul_mont(r_Z2, r_Z2, Z2_mont);
     if (OPENSSL_memcmp(r_Z2, X, sizeof(r_Z2)) == 0) {
       return 1;
     }
   }

   return 0;
 }

 DEFINE_METHOD_FUNCTION(EC_METHOD, EC_GFp_nistz256_method) {
   out->group_init = ec_GFp_mont_group_init;
   out->group_finish = ec_GFp_mont_group_finish;
   out->group_set_curve = ec_GFp_mont_group_set_curve;
   out->point_get_affine_coordinates = ecp_nistz256_get_affine;
   out->add = ecp_nistz256_add;
   out->dbl = ecp_nistz256_dbl;
   out->mul = ecp_nistz256_point_mul;
   out->mul_base = ecp_nistz256_point_mul_base;
   out->mul_public = ecp_nistz256_points_mul_public;
   out->felem_mul = ec_GFp_mont_felem_mul;
   out->felem_sqr = ec_GFp_mont_felem_sqr;
   out->felem_to_bytes = ec_GFp_mont_felem_to_bytes;
   out->felem_from_bytes = ec_GFp_mont_felem_from_bytes;
   out->scalar_inv0_montgomery = ecp_nistz256_inv0_mod_ord;
   out->scalar_to_montgomery_inv_vartime =
       ecp_nistz256_scalar_to_montgomery_inv_vartime;
   out->cmp_x_coordinate = ecp_nistz256_cmp_x_coordinate;
 }

 #endif /* !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86_64) && \
           !defined(OPENSSL_SMALL) */
	/*
	* Copyright 2014-2016 The OpenSSL Project Authors. All Rights Reserved.
	* Copyright (c) 2014, Intel Corporation. All Rights Reserved.
	*
	* Licensed under the OpenSSL license (the "License"). You may not use
	* this file except in compliance with the License. You can obtain a copy
	* in the file LICENSE in the source distribution or at
	* https://www.openssl.org/source/license.html
	*
	* Originally written by Shay Gueron (1, 2), and Vlad Krasnov (1)
	* (1) Intel Corporation, Israel Development Center, Haifa, Israel
	* (2) University of Haifa, Israel
	*
	* Reference:
	* S.Gueron and V.Krasnov, "Fast Prime Field Elliptic Curve Cryptography with
	* 256 Bit Primes"
	*/

	#include <openssl/ec.h>

	#include <assert.h>
	#include <stdint.h>
	#include <string.h>

	#include <openssl/bn.h>
	#include <openssl/cpu.h>
	#include <openssl/crypto.h>
	#include <openssl/err.h>

	#include "../bn/internal.h"
	#include "../delocate.h"
	#include "../../internal.h"
	#include "internal.h"
	#include "p256-x86_64.h"


	#if !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86_64) && \
	!defined(OPENSSL_SMALL)

	typedef P256_POINT_AFFINE PRECOMP256_ROW[64];

	// One converted into the Montgomery domain
	static const BN_ULONG ONE[P256_LIMBS] = {
	TOBN(0x00000000, 0x00000001), TOBN(0xffffffff, 0x00000000),
	TOBN(0xffffffff, 0xffffffff), TOBN(0x00000000, 0xfffffffe),
	};

	// Precomputed tables for the default generator
	#include "p256-x86_64-table.h"

	// Recode window to a signed digit, see \|ec_GFp_nistp_recode_scalar_bits\| in
	// util.c for details
	static crypto_word_t booth_recode_w5(crypto_word_t in) {
	crypto_word_t s, d;

	s = ~((in >> 5) - 1);
	d = (1 << 6) - in - 1;
	d = (d & s) \| (in & ~s);
	d = (d >> 1) + (d & 1);

	return (d << 1) + (s & 1);
	}

	static crypto_word_t booth_recode_w7(crypto_word_t in) {
	crypto_word_t s, d;

	s = ~((in >> 7) - 1);
	d = (1 << 8) - in - 1;
	d = (d & s) \| (in & ~s);
	d = (d >> 1) + (d & 1);

	return (d << 1) + (s & 1);
	}

	// copy_conditional copies \|src\| to \|dst\| if \|move\| is one and leaves it as-is
	// if \|move\| is zero.
	//
	// WARNING: this breaks the usual convention of constant-time functions
	// returning masks.
	static void copy_conditional(BN_ULONG dst[P256_LIMBS],
	const BN_ULONG src[P256_LIMBS], BN_ULONG move) {
	BN_ULONG mask1 = ((BN_ULONG)0) - move;
	BN_ULONG mask2 = ~mask1;

	dst[0] = (src[0] & mask1) ^ (dst[0] & mask2);
	dst[1] = (src[1] & mask1) ^ (dst[1] & mask2);
	dst[2] = (src[2] & mask1) ^ (dst[2] & mask2);
	dst[3] = (src[3] & mask1) ^ (dst[3] & mask2);
	if (P256_LIMBS == 8) {
	dst[4] = (src[4] & mask1) ^ (dst[4] & mask2);
	dst[5] = (src[5] & mask1) ^ (dst[5] & mask2);
	dst[6] = (src[6] & mask1) ^ (dst[6] & mask2);
	dst[7] = (src[7] & mask1) ^ (dst[7] & mask2);
	}
	}

	// is_not_zero returns one iff in != 0 and zero otherwise.
	//
	// WARNING: this breaks the usual convention of constant-time functions
	// returning masks.
	//
	// (define-fun is_not_zero ((in (_ BitVec 64))) (_ BitVec 64)
	// (bvlshr (bvor in (bvsub #x0000000000000000 in)) #x000000000000003f)
	// )
	//
	// (declare-fun x () (_ BitVec 64))
	//
	// (assert (and (= x #x0000000000000000) (= (is_not_zero x) #x0000000000000001)))
	// (check-sat)
	//
	// (assert (and (not (= x #x0000000000000000)) (= (is_not_zero x) #x0000000000000000)))
	// (check-sat)
	//
	static BN_ULONG is_not_zero(BN_ULONG in) {
	in \|= (0 - in);
	in >>= BN_BITS2 - 1;
	return in;
	}

	// ecp_nistz256_mod_inverse_sqr_mont sets \|r\| to (\|in\| * 2^-256)^-2 * 2^256 mod
	// p. That is, \|r\| is the modular inverse square of \|in\| for input and output in
	// the Montgomery domain.
	static void ecp_nistz256_mod_inverse_sqr_mont(BN_ULONG r[P256_LIMBS],
	const BN_ULONG in[P256_LIMBS]) {
	// This implements the addition chain described in
	// https://briansmith.org/ecc-inversion-addition-chains-01#p256_field_inversion
	BN_ULONG x2[P256_LIMBS], x3[P256_LIMBS], x6[P256_LIMBS], x12[P256_LIMBS],
	x15[P256_LIMBS], x30[P256_LIMBS], x32[P256_LIMBS];
	ecp_nistz256_sqr_mont(x2, in); // 2^2 - 2^1
	ecp_nistz256_mul_mont(x2, x2, in); // 2^2 - 2^0

	ecp_nistz256_sqr_mont(x3, x2); // 2^3 - 2^1
	ecp_nistz256_mul_mont(x3, x3, in); // 2^3 - 2^0

	ecp_nistz256_sqr_mont(x6, x3);
	for (int i = 1; i < 3; i++) {
	ecp_nistz256_sqr_mont(x6, x6);
	} // 2^6 - 2^3
	ecp_nistz256_mul_mont(x6, x6, x3); // 2^6 - 2^0

	ecp_nistz256_sqr_mont(x12, x6);
	for (int i = 1; i < 6; i++) {
	ecp_nistz256_sqr_mont(x12, x12);
	} // 2^12 - 2^6
	ecp_nistz256_mul_mont(x12, x12, x6); // 2^12 - 2^0

	ecp_nistz256_sqr_mont(x15, x12);
	for (int i = 1; i < 3; i++) {
	ecp_nistz256_sqr_mont(x15, x15);
	} // 2^15 - 2^3
	ecp_nistz256_mul_mont(x15, x15, x3); // 2^15 - 2^0

	ecp_nistz256_sqr_mont(x30, x15);
	for (int i = 1; i < 15; i++) {
	ecp_nistz256_sqr_mont(x30, x30);
	} // 2^30 - 2^15
	ecp_nistz256_mul_mont(x30, x30, x15); // 2^30 - 2^0

	ecp_nistz256_sqr_mont(x32, x30);
	ecp_nistz256_sqr_mont(x32, x32); // 2^32 - 2^2
	ecp_nistz256_mul_mont(x32, x32, x2); // 2^32 - 2^0

	BN_ULONG ret[P256_LIMBS];
	ecp_nistz256_sqr_mont(ret, x32);
	for (int i = 1; i < 31 + 1; i++) {
	ecp_nistz256_sqr_mont(ret, ret);
	} // 2^64 - 2^32
	ecp_nistz256_mul_mont(ret, ret, in); // 2^64 - 2^32 + 2^0

	for (int i = 0; i < 96 + 32; i++) {
	ecp_nistz256_sqr_mont(ret, ret);
	} // 2^192 - 2^160 + 2^128
	ecp_nistz256_mul_mont(ret, ret, x32); // 2^192 - 2^160 + 2^128 + 2^32 - 2^0

	for (int i = 0; i < 32; i++) {
	ecp_nistz256_sqr_mont(ret, ret);
	} // 2^224 - 2^192 + 2^160 + 2^64 - 2^32
	ecp_nistz256_mul_mont(ret, ret, x32); // 2^224 - 2^192 + 2^160 + 2^64 - 2^0

	for (int i = 0; i < 30; i++) {
	ecp_nistz256_sqr_mont(ret, ret);
	} // 2^254 - 2^222 + 2^190 + 2^94 - 2^30
	ecp_nistz256_mul_mont(ret, ret, x30); // 2^254 - 2^222 + 2^190 + 2^94 - 2^0

	ecp_nistz256_sqr_mont(ret, ret);
	ecp_nistz256_sqr_mont(r, ret); // 2^256 - 2^224 + 2^192 + 2^96 - 2^2
	}

	// r = p * p_scalar
	static void ecp_nistz256_windowed_mul(const EC_GROUP group, P256_POINT r,
	const EC_RAW_POINT *p,
	const EC_SCALAR *p_scalar) {
	assert(p != NULL);
	assert(p_scalar != NULL);
	assert(group->field.width == P256_LIMBS);

	static const size_t kWindowSize = 5;
	static const crypto_word_t kMask = (1 << (5 /* kWindowSize */ + 1)) - 1;

	// A \|P256_POINT\| is (3 * 32) = 96 bytes, and the 64-byte alignment should
	// add no more than 63 bytes of overhead. Thus, \|table\| should require
	// ~1599 ((96 * 16) + 63) bytes of stack space.
	alignas(64) P256_POINT table[16];
	uint8_t p_str[33];
	OPENSSL_memcpy(p_str, p_scalar->bytes, 32);
	p_str[32] = 0;

	// table[0] is implicitly (0,0,0) (the point at infinity), therefore it is
	// not stored. All other values are actually stored with an offset of -1 in
	// table.
	P256_POINT *row = table;
	assert(group->field.width == P256_LIMBS);
	OPENSSL_memcpy(row[1 - 1].X, p->X.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(row[1 - 1].Y, p->Y.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(row[1 - 1].Z, p->Z.words, P256_LIMBS * sizeof(BN_ULONG));

	ecp_nistz256_point_double(&row[2 - 1], &row[1 - 1]);
	ecp_nistz256_point_add(&row[3 - 1], &row[2 - 1], &row[1 - 1]);
	ecp_nistz256_point_double(&row[4 - 1], &row[2 - 1]);
	ecp_nistz256_point_double(&row[6 - 1], &row[3 - 1]);
	ecp_nistz256_point_double(&row[8 - 1], &row[4 - 1]);
	ecp_nistz256_point_double(&row[12 - 1], &row[6 - 1]);
	ecp_nistz256_point_add(&row[5 - 1], &row[4 - 1], &row[1 - 1]);
	ecp_nistz256_point_add(&row[7 - 1], &row[6 - 1], &row[1 - 1]);
	ecp_nistz256_point_add(&row[9 - 1], &row[8 - 1], &row[1 - 1]);
	ecp_nistz256_point_add(&row[13 - 1], &row[12 - 1], &row[1 - 1]);
	ecp_nistz256_point_double(&row[14 - 1], &row[7 - 1]);
	ecp_nistz256_point_double(&row[10 - 1], &row[5 - 1]);
	ecp_nistz256_point_add(&row[15 - 1], &row[14 - 1], &row[1 - 1]);
	ecp_nistz256_point_add(&row[11 - 1], &row[10 - 1], &row[1 - 1]);
	ecp_nistz256_point_double(&row[16 - 1], &row[8 - 1]);

	BN_ULONG tmp[P256_LIMBS];
	alignas(32) P256_POINT h;
	size_t index = 255;
	crypto_word_t wvalue = p_str[(index - 1) / 8];
	wvalue = (wvalue >> ((index - 1) % 8)) & kMask;

	ecp_nistz256_select_w5(r, table, booth_recode_w5(wvalue) >> 1);

	while (index >= 5) {
	if (index != 255) {
	size_t off = (index - 1) / 8;

	wvalue = (crypto_word_t)p_str[off] \| (crypto_word_t)p_str[off + 1] << 8;
	wvalue = (wvalue >> ((index - 1) % 8)) & kMask;

	wvalue = booth_recode_w5(wvalue);

	ecp_nistz256_select_w5(&h, table, wvalue >> 1);

	ecp_nistz256_neg(tmp, h.Y);
	copy_conditional(h.Y, tmp, (wvalue & 1));

	ecp_nistz256_point_add(r, r, &h);
	}

	index -= kWindowSize;

	ecp_nistz256_point_double(r, r);
	ecp_nistz256_point_double(r, r);
	ecp_nistz256_point_double(r, r);
	ecp_nistz256_point_double(r, r);
	ecp_nistz256_point_double(r, r);
	}

	// Final window
	wvalue = p_str[0];
	wvalue = (wvalue << 1) & kMask;

	wvalue = booth_recode_w5(wvalue);

	ecp_nistz256_select_w5(&h, table, wvalue >> 1);

	ecp_nistz256_neg(tmp, h.Y);
	copy_conditional(h.Y, tmp, wvalue & 1);

	ecp_nistz256_point_add(r, r, &h);
	}

	typedef union {
	P256_POINT p;
	P256_POINT_AFFINE a;
	} p256_point_union_t;

	static crypto_word_t calc_first_wvalue(size_t *index, const uint8_t p_str[33]) {
	static const size_t kWindowSize = 7;
	static const crypto_word_t kMask = (1 << (7 /* kWindowSize */ + 1)) - 1;
	*index = kWindowSize;

	crypto_word_t wvalue = (p_str[0] << 1) & kMask;
	return booth_recode_w7(wvalue);
	}

	static crypto_word_t calc_wvalue(size_t *index, const uint8_t p_str[33]) {
	static const size_t kWindowSize = 7;
	static const crypto_word_t kMask = (1 << (7 /* kWindowSize */ + 1)) - 1;

	const size_t off = (*index - 1) / 8;
	crypto_word_t wvalue =
	(crypto_word_t)p_str[off] \| (crypto_word_t)p_str[off + 1] << 8;
	wvalue = (wvalue >> ((*index - 1) % 8)) & kMask;
	*index += kWindowSize;

	return booth_recode_w7(wvalue);
	}

	static void ecp_nistz256_point_mul(const EC_GROUP group, EC_RAW_POINT r,
	const EC_RAW_POINT *p,
	const EC_SCALAR *scalar) {
	alignas(32) P256_POINT out;
	ecp_nistz256_windowed_mul(group, &out, p, scalar);

	assert(group->field.width == P256_LIMBS);
	OPENSSL_memcpy(r->X.words, out.X, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Y.words, out.Y, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Z.words, out.Z, P256_LIMBS * sizeof(BN_ULONG));
	}

	static void ecp_nistz256_point_mul_base(const EC_GROUP group, EC_RAW_POINT r,
	const EC_SCALAR *scalar) {
	alignas(32) p256_point_union_t t, p;

	uint8_t p_str[33];
	OPENSSL_memcpy(p_str, scalar->bytes, 32);
	p_str[32] = 0;

	// First window
	size_t index = 0;
	crypto_word_t wvalue = calc_first_wvalue(&index, p_str);

	ecp_nistz256_select_w7(&p.a, ecp_nistz256_precomputed[0], wvalue >> 1);
	ecp_nistz256_neg(p.p.Z, p.p.Y);
	copy_conditional(p.p.Y, p.p.Z, wvalue & 1);

	// Convert \|p\| from affine to Jacobian coordinates. We set Z to zero if \|p\|
	// is infinity and \|ONE\| otherwise. \|p\| was computed from the table, so it
	// is infinity iff \|wvalue >> 1\| is zero.
	OPENSSL_memset(p.p.Z, 0, sizeof(p.p.Z));
	copy_conditional(p.p.Z, ONE, is_not_zero(wvalue >> 1));

	for (int i = 1; i < 37; i++) {
	wvalue = calc_wvalue(&index, p_str);

	ecp_nistz256_select_w7(&t.a, ecp_nistz256_precomputed[i], wvalue >> 1);

	ecp_nistz256_neg(t.p.Z, t.a.Y);
	copy_conditional(t.a.Y, t.p.Z, wvalue & 1);

	// Note \|ecp_nistz256_point_add_affine\| does not work if \|p.p\| and \|t.a\|
	// are the same non-infinity point.
	ecp_nistz256_point_add_affine(&p.p, &p.p, &t.a);
	}

	assert(group->field.width == P256_LIMBS);
	OPENSSL_memcpy(r->X.words, p.p.X, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Y.words, p.p.Y, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Z.words, p.p.Z, P256_LIMBS * sizeof(BN_ULONG));
	}

	static void ecp_nistz256_points_mul_public(const EC_GROUP *group,
	EC_RAW_POINT *r,
	const EC_SCALAR *g_scalar,
	const EC_RAW_POINT *p_,
	const EC_SCALAR *p_scalar) {
	assert(p_ != NULL && p_scalar != NULL && g_scalar != NULL);

	alignas(32) p256_point_union_t t, p;
	uint8_t p_str[33];
	OPENSSL_memcpy(p_str, g_scalar->bytes, 32);
	p_str[32] = 0;

	// First window
	size_t index = 0;
	size_t wvalue = calc_first_wvalue(&index, p_str);

	// Convert \|p\| from affine to Jacobian coordinates. We set Z to zero if \|p\|
	// is infinity and \|ONE\| otherwise. \|p\| was computed from the table, so it
	// is infinity iff \|wvalue >> 1\| is zero.
	if ((wvalue >> 1) != 0) {
	OPENSSL_memcpy(&p.a, &ecp_nistz256_precomputed[0][(wvalue >> 1) - 1],
	sizeof(p.a));
	OPENSSL_memcpy(&p.p.Z, ONE, sizeof(p.p.Z));
	} else {
	OPENSSL_memset(&p.a, 0, sizeof(p.a));
	OPENSSL_memset(p.p.Z, 0, sizeof(p.p.Z));
	}

	if ((wvalue & 1) == 1) {
	ecp_nistz256_neg(p.p.Y, p.p.Y);
	}

	for (int i = 1; i < 37; i++) {
	wvalue = calc_wvalue(&index, p_str);

	if ((wvalue >> 1) == 0) {
	continue;
	}

	OPENSSL_memcpy(&t.a, &ecp_nistz256_precomputed[i][(wvalue >> 1) - 1],
	sizeof(p.a));

	if ((wvalue & 1) == 1) {
	ecp_nistz256_neg(t.a.Y, t.a.Y);
	}

	// Note \|ecp_nistz256_point_add_affine\| does not work if \|p.p\| and \|t.a\|
	// are the same non-infinity point, so it is important that we compute the
	// \|g_scalar\| term before the \|p_scalar\| term.
	ecp_nistz256_point_add_affine(&p.p, &p.p, &t.a);
	}

	ecp_nistz256_windowed_mul(group, &t.p, p_, p_scalar);
	ecp_nistz256_point_add(&p.p, &p.p, &t.p);

	assert(group->field.width == P256_LIMBS);
	OPENSSL_memcpy(r->X.words, p.p.X, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Y.words, p.p.Y, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Z.words, p.p.Z, P256_LIMBS * sizeof(BN_ULONG));
	}

	static int ecp_nistz256_get_affine(const EC_GROUP *group,
	const EC_RAW_POINT point, EC_FELEM x,
	EC_FELEM *y) {
	if (ec_GFp_simple_is_at_infinity(group, point)) {
	OPENSSL_PUT_ERROR(EC, EC_R_POINT_AT_INFINITY);
	return 0;
	}

	BN_ULONG z_inv2[P256_LIMBS];
	assert(group->field.width == P256_LIMBS);
	ecp_nistz256_mod_inverse_sqr_mont(z_inv2, point->Z.words);

	if (x != NULL) {
	ecp_nistz256_mul_mont(x->words, z_inv2, point->X.words);
	}

	if (y != NULL) {
	ecp_nistz256_sqr_mont(z_inv2, z_inv2); // z^-4
	ecp_nistz256_mul_mont(y->words, point->Y.words, point->Z.words); // y * z
	ecp_nistz256_mul_mont(y->words, y->words, z_inv2); // y * z^-3
	}

	return 1;
	}

	static void ecp_nistz256_add(const EC_GROUP group, EC_RAW_POINT r,
	const EC_RAW_POINT a_, const EC_RAW_POINT b_) {
	P256_POINT a, b;
	OPENSSL_memcpy(a.X, a_->X.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(a.Y, a_->Y.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(a.Z, a_->Z.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(b.X, b_->X.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(b.Y, b_->Y.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(b.Z, b_->Z.words, P256_LIMBS * sizeof(BN_ULONG));
	ecp_nistz256_point_add(&a, &a, &b);
	OPENSSL_memcpy(r->X.words, a.X, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Y.words, a.Y, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Z.words, a.Z, P256_LIMBS * sizeof(BN_ULONG));
	}

	static void ecp_nistz256_dbl(const EC_GROUP group, EC_RAW_POINT r,
	const EC_RAW_POINT *a_) {
	P256_POINT a;
	OPENSSL_memcpy(a.X, a_->X.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(a.Y, a_->Y.words, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(a.Z, a_->Z.words, P256_LIMBS * sizeof(BN_ULONG));
	ecp_nistz256_point_double(&a, &a);
	OPENSSL_memcpy(r->X.words, a.X, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Y.words, a.Y, P256_LIMBS * sizeof(BN_ULONG));
	OPENSSL_memcpy(r->Z.words, a.Z, P256_LIMBS * sizeof(BN_ULONG));
	}

	static void ecp_nistz256_inv0_mod_ord(const EC_GROUP group, EC_SCALAR out,
	const EC_SCALAR *in) {
	// table[i] stores a power of \|in\| corresponding to the matching enum value.
	enum {
	// The following indices specify the power in binary.
	i_1 = 0,
	i_10,
	i_11,
	i_101,
	i_111,
	i_1010,
	i_1111,
	i_10101,
	i_101010,
	i_101111,
	// The following indices specify 2^N-1, or N ones in a row.
	i_x6,
	i_x8,
	i_x16,
	i_x32
	};
	BN_ULONG table[15][P256_LIMBS];

	// https://briansmith.org/ecc-inversion-addition-chains-01#p256_scalar_inversion
	//
	// Even though this code path spares 12 squarings, 4.5%, and 13
	// multiplications, 25%, the overall sign operation is not that much faster,
	// not more that 2%. Most of the performance of this function comes from the
	// scalar operations.

	// Pre-calculate powers.
	OPENSSL_memcpy(table[i_1], in->words, P256_LIMBS * sizeof(BN_ULONG));

	ecp_nistz256_ord_sqr_mont(table[i_10], table[i_1], 1);

	ecp_nistz256_ord_mul_mont(table[i_11], table[i_1], table[i_10]);

	ecp_nistz256_ord_mul_mont(table[i_101], table[i_11], table[i_10]);

	ecp_nistz256_ord_mul_mont(table[i_111], table[i_101], table[i_10]);

	ecp_nistz256_ord_sqr_mont(table[i_1010], table[i_101], 1);

	ecp_nistz256_ord_mul_mont(table[i_1111], table[i_1010], table[i_101]);

	ecp_nistz256_ord_sqr_mont(table[i_10101], table[i_1010], 1);
	ecp_nistz256_ord_mul_mont(table[i_10101], table[i_10101], table[i_1]);

	ecp_nistz256_ord_sqr_mont(table[i_101010], table[i_10101], 1);

	ecp_nistz256_ord_mul_mont(table[i_101111], table[i_101010], table[i_101]);

	ecp_nistz256_ord_mul_mont(table[i_x6], table[i_101010], table[i_10101]);

	ecp_nistz256_ord_sqr_mont(table[i_x8], table[i_x6], 2);
	ecp_nistz256_ord_mul_mont(table[i_x8], table[i_x8], table[i_11]);

	ecp_nistz256_ord_sqr_mont(table[i_x16], table[i_x8], 8);
	ecp_nistz256_ord_mul_mont(table[i_x16], table[i_x16], table[i_x8]);

	ecp_nistz256_ord_sqr_mont(table[i_x32], table[i_x16], 16);
	ecp_nistz256_ord_mul_mont(table[i_x32], table[i_x32], table[i_x16]);

	// Compute \|in\| raised to the order-2.
	ecp_nistz256_ord_sqr_mont(out->words, table[i_x32], 64);
	ecp_nistz256_ord_mul_mont(out->words, out->words, table[i_x32]);
	static const struct {
	uint8_t p, i;
	} kChain[27] = {{32, i_x32}, {6, i_101111}, {5, i_111}, {4, i_11},
	{5, i_1111}, {5, i_10101}, {4, i_101}, {3, i_101},
	{3, i_101}, {5, i_111}, {9, i_101111}, {6, i_1111},
	{2, i_1}, {5, i_1}, {6, i_1111}, {5, i_111},
	{4, i_111}, {5, i_111}, {5, i_101}, {3, i_11},
	{10, i_101111}, {2, i_11}, {5, i_11}, {5, i_11},
	{3, i_1}, {7, i_10101}, {6, i_1111}};
	for (size_t i = 0; i < OPENSSL_ARRAY_SIZE(kChain); i++) {
	ecp_nistz256_ord_sqr_mont(out->words, out->words, kChain[i].p);
	ecp_nistz256_ord_mul_mont(out->words, out->words, table[kChain[i].i]);
	}
	}

	static int ecp_nistz256_scalar_to_montgomery_inv_vartime(const EC_GROUP *group,
	EC_SCALAR *out,
	const EC_SCALAR *in) {
	if ((OPENSSL_ia32cap_get()[1] & (1 << 28)) == 0) {
	// No AVX support; fallback to generic code.
	return ec_simple_scalar_to_montgomery_inv_vartime(group, out, in);
	}

	assert(group->order.width == P256_LIMBS);
	if (!beeu_mod_inverse_vartime(out->words, in->words, group->order.d)) {
	return 0;
	}

	// The result should be returned in the Montgomery domain.
	ec_scalar_to_montgomery(group, out, out);
	return 1;
	}

	static int ecp_nistz256_cmp_x_coordinate(const EC_GROUP *group,
	const EC_RAW_POINT *p,
	const EC_SCALAR *r) {
	if (ec_GFp_simple_is_at_infinity(group, p)) {
	return 0;
	}

	assert(group->order.width == P256_LIMBS);
	assert(group->field.width == P256_LIMBS);

	// We wish to compare X/Z^2 with r. This is equivalent to comparing X with
	// r*Z^2. Note that X and Z are represented in Montgomery form, while r is
	// not.
	BN_ULONG r_Z2[P256_LIMBS], Z2_mont[P256_LIMBS], X[P256_LIMBS];
	ecp_nistz256_mul_mont(Z2_mont, p->Z.words, p->Z.words);
	ecp_nistz256_mul_mont(r_Z2, r->words, Z2_mont);
	ecp_nistz256_from_mont(X, p->X.words);

	if (OPENSSL_memcmp(r_Z2, X, sizeof(r_Z2)) == 0) {
	return 1;
	}

	// During signing the x coefficient is reduced modulo the group order.
	// Therefore there is a small possibility, less than 1/2^128, that group_order
	// < p.x < P. in that case we need not only to compare against \|r\| but also to
	// compare against r+group_order.
	if (bn_less_than_words(r->words, group->field_minus_order.words,
	P256_LIMBS)) {
	// We can ignore the carry because: r + group_order < p < 2^256.
	bn_add_words(r_Z2, r->words, group->order.d, P256_LIMBS);
	ecp_nistz256_mul_mont(r_Z2, r_Z2, Z2_mont);
	if (OPENSSL_memcmp(r_Z2, X, sizeof(r_Z2)) == 0) {
	return 1;
	}
	}

	return 0;
	}

	DEFINE_METHOD_FUNCTION(EC_METHOD, EC_GFp_nistz256_method) {
	out->group_init = ec_GFp_mont_group_init;
	out->group_finish = ec_GFp_mont_group_finish;
	out->group_set_curve = ec_GFp_mont_group_set_curve;
	out->point_get_affine_coordinates = ecp_nistz256_get_affine;
	out->add = ecp_nistz256_add;
	out->dbl = ecp_nistz256_dbl;
	out->mul = ecp_nistz256_point_mul;
	out->mul_base = ecp_nistz256_point_mul_base;
	out->mul_public = ecp_nistz256_points_mul_public;
	out->felem_mul = ec_GFp_mont_felem_mul;
	out->felem_sqr = ec_GFp_mont_felem_sqr;
	out->felem_to_bytes = ec_GFp_mont_felem_to_bytes;
	out->felem_from_bytes = ec_GFp_mont_felem_from_bytes;
	out->scalar_inv0_montgomery = ecp_nistz256_inv0_mod_ord;
	out->scalar_to_montgomery_inv_vartime =
	ecp_nistz256_scalar_to_montgomery_inv_vartime;
	out->cmp_x_coordinate = ecp_nistz256_cmp_x_coordinate;
	}

	#endif /* !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86_64) && \
	!defined(OPENSSL_SMALL) */