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

 /* Copyright (c) 2014, Intel Corporation.
  *
  * Permission to use, copy, modify, and/or distribute this software for any
  * purpose with or without fee is hereby granted, provided that the above
  * copyright notice and this permission notice appear in all copies.
  *
  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
  * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
  * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
  * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */

 // Developers and authors:
 // Shay Gueron (1, 2), and Vlad Krasnov (1)
 // (1) Intel Corporation, Israel Development Center
 // (2) University of Haifa
 // 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/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 util-64.c for details
 static unsigned booth_recode_w5(unsigned in) {
   unsigned 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 unsigned booth_recode_w7(unsigned in) {
   unsigned 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_mont sets |r| to (|in| * 2^-256)^-1 * 2^256 mod p.
 // That is, |r| is the modular inverse of |in| for input and output in the
 // Montgomery domain.
 static void ecp_nistz256_mod_inverse_mont(BN_ULONG r[P256_LIMBS],
                                           const BN_ULONG in[P256_LIMBS]) {
   /* The poly is ffffffff 00000001 00000000 00000000 00000000 ffffffff ffffffff
      ffffffff
      We use FLT and used poly-2 as exponent */
   BN_ULONG p2[P256_LIMBS];
   BN_ULONG p4[P256_LIMBS];
   BN_ULONG p8[P256_LIMBS];
   BN_ULONG p16[P256_LIMBS];
   BN_ULONG p32[P256_LIMBS];
   BN_ULONG res[P256_LIMBS];
   int i;

   ecp_nistz256_sqr_mont(res, in);
   ecp_nistz256_mul_mont(p2, res, in);  // 3*p

   ecp_nistz256_sqr_mont(res, p2);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_mul_mont(p4, res, p2);  // f*p

   ecp_nistz256_sqr_mont(res, p4);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_mul_mont(p8, res, p4);  // ff*p

   ecp_nistz256_sqr_mont(res, p8);
   for (i = 0; i < 7; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(p16, res, p8);  // ffff*p

   ecp_nistz256_sqr_mont(res, p16);
   for (i = 0; i < 15; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(p32, res, p16);  // ffffffff*p

   ecp_nistz256_sqr_mont(res, p32);
   for (i = 0; i < 31; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(res, res, in);

   for (i = 0; i < 32 * 4; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(res, res, p32);

   for (i = 0; i < 32; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(res, res, p32);

   for (i = 0; i < 16; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(res, res, p16);

   for (i = 0; i < 8; i++) {
     ecp_nistz256_sqr_mont(res, res);
   }
   ecp_nistz256_mul_mont(res, res, p8);

   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_mul_mont(res, res, p4);

   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_mul_mont(res, res, p2);

   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_sqr_mont(res, res);
   ecp_nistz256_mul_mont(r, res, in);
 }

 // ecp_nistz256_bignum_to_field_elem copies the contents of |in| to |out| and
 // returns one if it fits. Otherwise it returns zero.
 static int ecp_nistz256_bignum_to_field_elem(BN_ULONG out[P256_LIMBS],
                                              const BIGNUM *in) {
   if (in->top > P256_LIMBS) {
     return 0;
   }

   OPENSSL_memset(out, 0, sizeof(BN_ULONG) * P256_LIMBS);
   OPENSSL_memcpy(out, in->d, sizeof(BN_ULONG) * in->top);
   return 1;
 }

 // r = p * p_scalar
 static int ecp_nistz256_windowed_mul(const EC_GROUP *group, P256_POINT *r,
                                      const EC_POINT *p,
                                      const EC_SCALAR *p_scalar) {
   assert(p != NULL);
   assert(p_scalar != NULL);

   static const unsigned kWindowSize = 5;
   static const unsigned 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;

   if (!ecp_nistz256_bignum_to_field_elem(row[1 - 1].X, &p->X) ||
       !ecp_nistz256_bignum_to_field_elem(row[1 - 1].Y, &p->Y) ||
       !ecp_nistz256_bignum_to_field_elem(row[1 - 1].Z, &p->Z)) {
     OPENSSL_PUT_ERROR(EC, EC_R_COORDINATES_OUT_OF_RANGE);
     return 0;
   }

   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;
   unsigned index = 255;
   unsigned 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) {
       unsigned off = (index - 1) / 8;

       wvalue = p_str[off] | 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);

   return 1;
 }

 static int ecp_nistz256_points_mul(const EC_GROUP *group, EC_POINT *r,
                                    const EC_SCALAR *g_scalar,
                                    const EC_POINT *p_,
                                    const EC_SCALAR *p_scalar, BN_CTX *ctx) {
   assert((p_ != NULL) == (p_scalar != NULL));

   static const unsigned kWindowSize = 7;
   static const unsigned kMask = (1 << (7 /* kWindowSize */ + 1)) - 1;

   alignas(32) union {
     P256_POINT p;
     P256_POINT_AFFINE a;
   } t, p;

   if (g_scalar != NULL) {
     uint8_t p_str[33];
     OPENSSL_memcpy(p_str, g_scalar->bytes, 32);
     p_str[32] = 0;

     // First window
     unsigned wvalue = (p_str[0] << 1) & kMask;
     unsigned index = kWindowSize;

     wvalue = booth_recode_w7(wvalue);

     const PRECOMP256_ROW *const precomputed_table =
         (const PRECOMP256_ROW *)ecp_nistz256_precomputed;
     ecp_nistz256_select_w7(&p.a, precomputed_table[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++) {
       unsigned off = (index - 1) / 8;
       wvalue = p_str[off] | p_str[off + 1] << 8;
       wvalue = (wvalue >> ((index - 1) % 8)) & kMask;
       index += kWindowSize;

       wvalue = booth_recode_w7(wvalue);

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

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

       ecp_nistz256_point_add_affine(&p.p, &p.p, &t.a);
     }
   }

   const int p_is_infinity = g_scalar == NULL;
   if (p_scalar != NULL) {
     P256_POINT *out = &t.p;
     if (p_is_infinity) {
       out = &p.p;
     }

     if (!ecp_nistz256_windowed_mul(group, out, p_, p_scalar)) {
       return 0;
     }

     if (!p_is_infinity) {
       ecp_nistz256_point_add(&p.p, &p.p, out);
     }
   }

   // Not constant-time, but we're only operating on the public output.
   if (!bn_set_words(&r->X, p.p.X, P256_LIMBS) ||
       !bn_set_words(&r->Y, p.p.Y, P256_LIMBS) ||
       !bn_set_words(&r->Z, p.p.Z, P256_LIMBS)) {
     return 0;
   }

   return 1;
 }

 static int ecp_nistz256_get_affine(const EC_GROUP *group, const EC_POINT *point,
                                    BIGNUM *x, BIGNUM *y, BN_CTX *ctx) {
   BN_ULONG z_inv2[P256_LIMBS];
   BN_ULONG z_inv3[P256_LIMBS];
   BN_ULONG point_x[P256_LIMBS], point_y[P256_LIMBS], point_z[P256_LIMBS];

   if (EC_POINT_is_at_infinity(group, point)) {
     OPENSSL_PUT_ERROR(EC, EC_R_POINT_AT_INFINITY);
     return 0;
   }

   if (!ecp_nistz256_bignum_to_field_elem(point_x, &point->X) ||
       !ecp_nistz256_bignum_to_field_elem(point_y, &point->Y) ||
       !ecp_nistz256_bignum_to_field_elem(point_z, &point->Z)) {
     OPENSSL_PUT_ERROR(EC, EC_R_COORDINATES_OUT_OF_RANGE);
     return 0;
   }

   ecp_nistz256_mod_inverse_mont(z_inv3, point_z);
   ecp_nistz256_sqr_mont(z_inv2, z_inv3);

   // Instead of using |ecp_nistz256_from_mont| to convert the |x| coordinate
   // and then calling |ecp_nistz256_from_mont| again to convert the |y|
   // coordinate below, convert the common factor |z_inv2| once now, saving one
   // reduction.
   ecp_nistz256_from_mont(z_inv2, z_inv2);

   if (x != NULL) {
     BN_ULONG x_aff[P256_LIMBS];
     ecp_nistz256_mul_mont(x_aff, z_inv2, point_x);
     if (!bn_set_words(x, x_aff, P256_LIMBS)) {
       OPENSSL_PUT_ERROR(EC, ERR_R_MALLOC_FAILURE);
       return 0;
     }
   }

   if (y != NULL) {
     BN_ULONG y_aff[P256_LIMBS];
     ecp_nistz256_mul_mont(z_inv3, z_inv3, z_inv2);
     ecp_nistz256_mul_mont(y_aff, z_inv3, point_y);
     if (!bn_set_words(y, y_aff, P256_LIMBS)) {
       OPENSSL_PUT_ERROR(EC, ERR_R_MALLOC_FAILURE);
       return 0;
     }
   }

   return 1;
 }

 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->mul = ecp_nistz256_points_mul;
   out->field_mul = ec_GFp_mont_field_mul;
   out->field_sqr = ec_GFp_mont_field_sqr;
   out->field_encode = ec_GFp_mont_field_encode;
   out->field_decode = ec_GFp_mont_field_decode;
 };

 #endif /* !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86_64) && \
           !defined(OPENSSL_SMALL) */
	/* Copyright (c) 2014, Intel Corporation.
	*
	* Permission to use, copy, modify, and/or distribute this software for any
	* purpose with or without fee is hereby granted, provided that the above
	* copyright notice and this permission notice appear in all copies.
	*
	* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
	* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
	* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
	* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
	* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
	* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */

	// Developers and authors:
	// Shay Gueron (1, 2), and Vlad Krasnov (1)
	// (1) Intel Corporation, Israel Development Center
	// (2) University of Haifa
	// 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/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 util-64.c for details
	static unsigned booth_recode_w5(unsigned in) {
	unsigned 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 unsigned booth_recode_w7(unsigned in) {
	unsigned 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_mont sets \|r\| to (\|in\| * 2^-256)^-1 * 2^256 mod p.
	// That is, \|r\| is the modular inverse of \|in\| for input and output in the
	// Montgomery domain.
	static void ecp_nistz256_mod_inverse_mont(BN_ULONG r[P256_LIMBS],
	const BN_ULONG in[P256_LIMBS]) {
	/* The poly is ffffffff 00000001 00000000 00000000 00000000 ffffffff ffffffff
	ffffffff
	We use FLT and used poly-2 as exponent */
	BN_ULONG p2[P256_LIMBS];
	BN_ULONG p4[P256_LIMBS];
	BN_ULONG p8[P256_LIMBS];
	BN_ULONG p16[P256_LIMBS];
	BN_ULONG p32[P256_LIMBS];
	BN_ULONG res[P256_LIMBS];
	int i;

	ecp_nistz256_sqr_mont(res, in);
	ecp_nistz256_mul_mont(p2, res, in); // 3*p

	ecp_nistz256_sqr_mont(res, p2);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_mul_mont(p4, res, p2); // f*p

	ecp_nistz256_sqr_mont(res, p4);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_mul_mont(p8, res, p4); // ff*p

	ecp_nistz256_sqr_mont(res, p8);
	for (i = 0; i < 7; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(p16, res, p8); // ffff*p

	ecp_nistz256_sqr_mont(res, p16);
	for (i = 0; i < 15; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(p32, res, p16); // ffffffff*p

	ecp_nistz256_sqr_mont(res, p32);
	for (i = 0; i < 31; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(res, res, in);

	for (i = 0; i < 32 * 4; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(res, res, p32);

	for (i = 0; i < 32; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(res, res, p32);

	for (i = 0; i < 16; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(res, res, p16);

	for (i = 0; i < 8; i++) {
	ecp_nistz256_sqr_mont(res, res);
	}
	ecp_nistz256_mul_mont(res, res, p8);

	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_mul_mont(res, res, p4);

	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_mul_mont(res, res, p2);

	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_sqr_mont(res, res);
	ecp_nistz256_mul_mont(r, res, in);
	}

	// ecp_nistz256_bignum_to_field_elem copies the contents of \|in\| to \|out\| and
	// returns one if it fits. Otherwise it returns zero.
	static int ecp_nistz256_bignum_to_field_elem(BN_ULONG out[P256_LIMBS],
	const BIGNUM *in) {
	if (in->top > P256_LIMBS) {
	return 0;
	}

	OPENSSL_memset(out, 0, sizeof(BN_ULONG) * P256_LIMBS);
	OPENSSL_memcpy(out, in->d, sizeof(BN_ULONG) * in->top);
	return 1;
	}

	// r = p * p_scalar
	static int ecp_nistz256_windowed_mul(const EC_GROUP group, P256_POINT r,
	const EC_POINT *p,
	const EC_SCALAR *p_scalar) {
	assert(p != NULL);
	assert(p_scalar != NULL);

	static const unsigned kWindowSize = 5;
	static const unsigned 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;

	if (!ecp_nistz256_bignum_to_field_elem(row[1 - 1].X, &p->X) \|\|
	!ecp_nistz256_bignum_to_field_elem(row[1 - 1].Y, &p->Y) \|\|
	!ecp_nistz256_bignum_to_field_elem(row[1 - 1].Z, &p->Z)) {
	OPENSSL_PUT_ERROR(EC, EC_R_COORDINATES_OUT_OF_RANGE);
	return 0;
	}

	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;
	unsigned index = 255;
	unsigned 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) {
	unsigned off = (index - 1) / 8;

	wvalue = p_str[off] \| 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);

	return 1;
	}

	static int ecp_nistz256_points_mul(const EC_GROUP group, EC_POINT r,
	const EC_SCALAR *g_scalar,
	const EC_POINT *p_,
	const EC_SCALAR p_scalar, BN_CTX ctx) {
	assert((p_ != NULL) == (p_scalar != NULL));

	static const unsigned kWindowSize = 7;
	static const unsigned kMask = (1 << (7 /* kWindowSize */ + 1)) - 1;

	alignas(32) union {
	P256_POINT p;
	P256_POINT_AFFINE a;
	} t, p;

	if (g_scalar != NULL) {
	uint8_t p_str[33];
	OPENSSL_memcpy(p_str, g_scalar->bytes, 32);
	p_str[32] = 0;

	// First window
	unsigned wvalue = (p_str[0] << 1) & kMask;
	unsigned index = kWindowSize;

	wvalue = booth_recode_w7(wvalue);

	const PRECOMP256_ROW *const precomputed_table =
	(const PRECOMP256_ROW *)ecp_nistz256_precomputed;
	ecp_nistz256_select_w7(&p.a, precomputed_table[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++) {
	unsigned off = (index - 1) / 8;
	wvalue = p_str[off] \| p_str[off + 1] << 8;
	wvalue = (wvalue >> ((index - 1) % 8)) & kMask;
	index += kWindowSize;

	wvalue = booth_recode_w7(wvalue);

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

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

	ecp_nistz256_point_add_affine(&p.p, &p.p, &t.a);
	}
	}

	const int p_is_infinity = g_scalar == NULL;
	if (p_scalar != NULL) {
	P256_POINT *out = &t.p;
	if (p_is_infinity) {
	out = &p.p;
	}

	if (!ecp_nistz256_windowed_mul(group, out, p_, p_scalar)) {
	return 0;
	}

	if (!p_is_infinity) {
	ecp_nistz256_point_add(&p.p, &p.p, out);
	}
	}

	// Not constant-time, but we're only operating on the public output.
	if (!bn_set_words(&r->X, p.p.X, P256_LIMBS) \|\|
	!bn_set_words(&r->Y, p.p.Y, P256_LIMBS) \|\|
	!bn_set_words(&r->Z, p.p.Z, P256_LIMBS)) {
	return 0;
	}

	return 1;
	}

	static int ecp_nistz256_get_affine(const EC_GROUP group, const EC_POINT point,
	BIGNUM x, BIGNUM y, BN_CTX *ctx) {
	BN_ULONG z_inv2[P256_LIMBS];
	BN_ULONG z_inv3[P256_LIMBS];
	BN_ULONG point_x[P256_LIMBS], point_y[P256_LIMBS], point_z[P256_LIMBS];

	if (EC_POINT_is_at_infinity(group, point)) {
	OPENSSL_PUT_ERROR(EC, EC_R_POINT_AT_INFINITY);
	return 0;
	}

	if (!ecp_nistz256_bignum_to_field_elem(point_x, &point->X) \|\|
	!ecp_nistz256_bignum_to_field_elem(point_y, &point->Y) \|\|
	!ecp_nistz256_bignum_to_field_elem(point_z, &point->Z)) {
	OPENSSL_PUT_ERROR(EC, EC_R_COORDINATES_OUT_OF_RANGE);
	return 0;
	}

	ecp_nistz256_mod_inverse_mont(z_inv3, point_z);
	ecp_nistz256_sqr_mont(z_inv2, z_inv3);

	// Instead of using \|ecp_nistz256_from_mont\| to convert the \|x\| coordinate
	// and then calling \|ecp_nistz256_from_mont\| again to convert the \|y\|
	// coordinate below, convert the common factor \|z_inv2\| once now, saving one
	// reduction.
	ecp_nistz256_from_mont(z_inv2, z_inv2);

	if (x != NULL) {
	BN_ULONG x_aff[P256_LIMBS];
	ecp_nistz256_mul_mont(x_aff, z_inv2, point_x);
	if (!bn_set_words(x, x_aff, P256_LIMBS)) {
	OPENSSL_PUT_ERROR(EC, ERR_R_MALLOC_FAILURE);
	return 0;
	}
	}

	if (y != NULL) {
	BN_ULONG y_aff[P256_LIMBS];
	ecp_nistz256_mul_mont(z_inv3, z_inv3, z_inv2);
	ecp_nistz256_mul_mont(y_aff, z_inv3, point_y);
	if (!bn_set_words(y, y_aff, P256_LIMBS)) {
	OPENSSL_PUT_ERROR(EC, ERR_R_MALLOC_FAILURE);
	return 0;
	}
	}

	return 1;
	}

	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->mul = ecp_nistz256_points_mul;
	out->field_mul = ec_GFp_mont_field_mul;
	out->field_sqr = ec_GFp_mont_field_sqr;
	out->field_encode = ec_GFp_mont_field_encode;
	out->field_decode = ec_GFp_mont_field_decode;
	};

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