crypto/bn/montgomery_inv.c - third_party/boringssl - Git at Google

 /* Copyright 2016 Brian Smith.
  *
  * 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. */

 #include <openssl/bn.h>

 #include <assert.h>

 #include "internal.h"
 #include "../internal.h"


 static uint64_t bn_neg_inv_mod_r_u64(uint64_t n);

 OPENSSL_COMPILE_ASSERT(BN_MONT_CTX_N0_LIMBS == 1 || BN_MONT_CTX_N0_LIMBS == 2,
                        BN_MONT_CTX_N0_LIMBS_VALUE_INVALID);
 OPENSSL_COMPILE_ASSERT(sizeof(uint64_t) ==
                        BN_MONT_CTX_N0_LIMBS * sizeof(BN_ULONG),
                        BN_MONT_CTX_N0_LIMBS_DOES_NOT_MATCH_UINT64_T);

 /* LG_LITTLE_R is log_2(r). */
 #define LG_LITTLE_R (BN_MONT_CTX_N0_LIMBS * BN_BITS2)

 uint64_t bn_mont_n0(const BIGNUM *n) {
   /* These conditions are checked by the caller, |BN_MONT_CTX_set|. */
   assert(!BN_is_zero(n));
   assert(!BN_is_negative(n));
   assert(BN_is_odd(n));

   /* r == 2**(BN_MONT_CTX_N0_LIMBS * BN_BITS2) and LG_LITTLE_R == lg(r). This
    * ensures that we can do integer division by |r| by simply ignoring
    * |BN_MONT_CTX_N0_LIMBS| limbs. Similarly, we can calculate values modulo
    * |r| by just looking at the lowest |BN_MONT_CTX_N0_LIMBS| limbs. This is
    * what makes Montgomery multiplication efficient.
    *
    * As shown in Algorithm 1 of "Fast Prime Field Elliptic Curve Cryptography
    * with 256 Bit Primes" by Shay Gueron and Vlad Krasnov, in the loop of a
    * multi-limb Montgomery multiplication of |a * b (mod n)|, given the
    * unreduced product |t == a * b|, we repeatedly calculate:
    *
    *    t1 := t % r         |t1| is |t|'s lowest limb (see previous paragraph).
    *    t2 := t1*n0*n
    *    t3 := t + t2
    *    t := t3 / r         copy all limbs of |t3| except the lowest to |t|.
    *
    * In the last step, it would only make sense to ignore the lowest limb of
    * |t3| if it were zero. The middle steps ensure that this is the case:
    *
    *                            t3 ==  0 (mod r)
    *                        t + t2 ==  0 (mod r)
    *                   t + t1*n0*n ==  0 (mod r)
    *                       t1*n0*n == -t (mod r)
    *                        t*n0*n == -t (mod r)
    *                          n0*n == -1 (mod r)
    *                            n0 == -1/n (mod r)
    *
    * Thus, in each iteration of the loop, we multiply by the constant factor
    * |n0|, the negative inverse of n (mod r). */

   /* n_mod_r = n % r. As explained above, this is done by taking the lowest
    * |BN_MONT_CTX_N0_LIMBS| limbs of |n|. */
   uint64_t n_mod_r = n->d[0];
 #if BN_MONT_CTX_N0_LIMBS == 2
   if (n->top > 1) {
     n_mod_r |= (uint64_t)n->d[1] << BN_BITS2;
   }
 #endif

   return bn_neg_inv_mod_r_u64(n_mod_r);
 }

 /* bn_neg_inv_r_mod_n_u64 calculates the -1/n mod r; i.e. it calculates |v|
  * such that u*r - v*n == 1. |r| is the constant defined in |bn_mont_n0|. |n|
  * must be odd.
  *
  * This is derived from |xbinGCD| in Henry S. Warren, Jr.'s "Montgomery
  * Multiplication" (http://www.hackersdelight.org/MontgomeryMultiplication.pdf).
  * It is very similar to the MODULAR-INVERSE function in Stephen R. Dussé's and
  * Burton S. Kaliski Jr.'s "A Cryptographic Library for the Motorola DSP56000"
  * (http://link.springer.com/chapter/10.1007%2F3-540-46877-3_21).
  *
  * This is inspired by Joppe W. Bos's "Constant Time Modular Inversion"
  * (http://www.joppebos.com/files/CTInversion.pdf) so that the inversion is
  * constant-time with respect to |n|. We assume uint64_t additions,
  * subtractions, shifts, and bitwise operations are all constant time, which
  * may be a large leap of faith on 32-bit targets. We avoid division and
  * multiplication, which tend to be the most problematic in terms of timing
  * leaks.
  *
  * Most GCD implementations return values such that |u*r + v*n == 1|, so the
  * caller would have to negate the resultant |v| for the purpose of Montgomery
  * multiplication. This implementation does the negation implicitly by doing
  * the computations as a difference instead of a sum. */
 static uint64_t bn_neg_inv_mod_r_u64(uint64_t n) {
   assert(n % 2 == 1);

   /* alpha == 2**(lg r - 1) == r / 2. */
   static const uint64_t alpha = UINT64_C(1) << (LG_LITTLE_R - 1);

   const uint64_t beta = n;

   uint64_t u = 1;
   uint64_t v = 0;

   /* The invariant maintained from here on is:
    * 2**(lg r - i) == u*2*alpha - v*beta. */
   for (size_t i = 0; i < LG_LITTLE_R; ++i) {
 #if BN_BITS2 == 64 && defined(BN_ULLONG)
     assert((BN_ULLONG)(1) << (LG_LITTLE_R - i) ==
            ((BN_ULLONG)u * 2 * alpha) - ((BN_ULLONG)v * beta));
 #endif

     /* Delete a common factor of 2 in u and v if |u| is even. Otherwise, set
      * |u = (u + beta) / 2| and |v = (v / 2) + alpha|. */

     uint64_t u_is_odd = UINT64_C(0) - (u & 1); /* Either 0xff..ff or 0. */

     /* The addition can overflow, so use Dietz's method for it.
      *
      * Dietz calculates (x+y)/2 by (x⊕y)>>1 + x&y. This is valid for all
      * (unsigned) x and y, even when x+y overflows. Evidence for 32-bit values
      * (embedded in 64 bits to so that overflow can be ignored):
      *
      * (declare-fun x () (_ BitVec 64))
      * (declare-fun y () (_ BitVec 64))
      * (assert (let (
      *    (one (_ bv1 64))
      *    (thirtyTwo (_ bv32 64)))
      *    (and
      *      (bvult x (bvshl one thirtyTwo))
      *      (bvult y (bvshl one thirtyTwo))
      *      (not (=
      *        (bvadd (bvlshr (bvxor x y) one) (bvand x y))
      *        (bvlshr (bvadd x y) one)))
      * )))
      * (check-sat) */
     uint64_t beta_if_u_is_odd = beta & u_is_odd; /* Either |beta| or 0. */
     u = ((u ^ beta_if_u_is_odd) >> 1) + (u & beta_if_u_is_odd);

     uint64_t alpha_if_u_is_odd = alpha & u_is_odd; /* Either |alpha| or 0. */
     v = (v >> 1) + alpha_if_u_is_odd;
   }

   /* The invariant now shows that u*r - v*n == 1 since r == 2 * alpha. */
 #if BN_BITS2 == 64 && defined(BN_ULLONG)
   assert(1 == ((BN_ULLONG)u * 2 * alpha) - ((BN_ULLONG)v * beta));
 #endif

   return v;
 }

 /* bn_mod_exp_base_2_vartime calculates r = 2**p (mod n). |p| must be larger
  * than log_2(n); i.e. 2**p must be larger than |n|. |n| must be positive and
  * odd. */
 int bn_mod_exp_base_2_vartime(BIGNUM *r, unsigned p, const BIGNUM *n) {
   assert(!BN_is_zero(n));
   assert(!BN_is_negative(n));
   assert(BN_is_odd(n));

   BN_zero(r);

   unsigned n_bits = BN_num_bits(n);
   assert(n_bits != 0);
   if (n_bits == 1) {
     return 1;
   }

   /* Set |r| to the smallest power of two larger than |n|. */
   assert(p > n_bits);
   if (!BN_set_bit(r, n_bits)) {
     return 0;
   }

   /* Unconditionally reduce |r|. */
   assert(BN_cmp(r, n) > 0);
   if (!BN_usub(r, r, n)) {
     return 0;
   }
   assert(BN_cmp(r, n) < 0);

   for (unsigned i = n_bits; i < p; ++i) {
     /* This is like |BN_mod_lshift1_quick| except using |BN_usub|.
      *
      * TODO: Replace this with the use of a constant-time variant of
      * |BN_mod_lshift1_quick|. */
     if (!BN_lshift1(r, r)) {
       return 0;
     }
     if (BN_cmp(r, n) >= 0) {
       if (!BN_usub(r, r, n)) {
         return 0;
       }
     }
   }

   return 1;
 }
	/* Copyright 2016 Brian Smith.
	*
	* 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. */

	#include <openssl/bn.h>

	#include <assert.h>

	#include "internal.h"
	#include "../internal.h"


	static uint64_t bn_neg_inv_mod_r_u64(uint64_t n);

	OPENSSL_COMPILE_ASSERT(BN_MONT_CTX_N0_LIMBS == 1 \|\| BN_MONT_CTX_N0_LIMBS == 2,
	BN_MONT_CTX_N0_LIMBS_VALUE_INVALID);
	OPENSSL_COMPILE_ASSERT(sizeof(uint64_t) ==
	BN_MONT_CTX_N0_LIMBS * sizeof(BN_ULONG),
	BN_MONT_CTX_N0_LIMBS_DOES_NOT_MATCH_UINT64_T);

	/* LG_LITTLE_R is log_2(r). */
	#define LG_LITTLE_R (BN_MONT_CTX_N0_LIMBS * BN_BITS2)

	uint64_t bn_mont_n0(const BIGNUM *n) {
	/* These conditions are checked by the caller, \|BN_MONT_CTX_set\|. */
	assert(!BN_is_zero(n));
	assert(!BN_is_negative(n));
	assert(BN_is_odd(n));

	/* r == 2*(BN_MONT_CTX_N0_LIMBS BN_BITS2) and LG_LITTLE_R == lg(r). This
	* ensures that we can do integer division by \|r\| by simply ignoring
	* \|BN_MONT_CTX_N0_LIMBS\| limbs. Similarly, we can calculate values modulo
	* \|r\| by just looking at the lowest \|BN_MONT_CTX_N0_LIMBS\| limbs. This is
	* what makes Montgomery multiplication efficient.
	*
	* As shown in Algorithm 1 of "Fast Prime Field Elliptic Curve Cryptography
	* with 256 Bit Primes" by Shay Gueron and Vlad Krasnov, in the loop of a
	* multi-limb Montgomery multiplication of \|a * b (mod n)\|, given the
	* unreduced product \|t == a * b\|, we repeatedly calculate:
	*
	* t1 := t % r \|t1\| is \|t\|'s lowest limb (see previous paragraph).
	* t2 := t1n0n
	* t3 := t + t2
	* t := t3 / r copy all limbs of \|t3\| except the lowest to \|t\|.
	*
	* In the last step, it would only make sense to ignore the lowest limb of
	* \|t3\| if it were zero. The middle steps ensure that this is the case:
	*
	* t3 == 0 (mod r)
	* t + t2 == 0 (mod r)
	* t + t1n0n == 0 (mod r)
	* t1n0n == -t (mod r)
	* tn0n == -t (mod r)
	* n0*n == -1 (mod r)
	* n0 == -1/n (mod r)
	*
	* Thus, in each iteration of the loop, we multiply by the constant factor
	* \|n0\|, the negative inverse of n (mod r). */

	/* n_mod_r = n % r. As explained above, this is done by taking the lowest
	* \|BN_MONT_CTX_N0_LIMBS\| limbs of \|n\|. */
	uint64_t n_mod_r = n->d[0];
	#if BN_MONT_CTX_N0_LIMBS == 2
	if (n->top > 1) {
	n_mod_r \|= (uint64_t)n->d[1] << BN_BITS2;
	}
	#endif

	return bn_neg_inv_mod_r_u64(n_mod_r);
	}

	/* bn_neg_inv_r_mod_n_u64 calculates the -1/n mod r; i.e. it calculates \|v\|
	* such that ur - vn == 1. \|r\| is the constant defined in \|bn_mont_n0\|. \|n\|
	* must be odd.
	*
	* This is derived from \|xbinGCD\| in Henry S. Warren, Jr.'s "Montgomery
	* Multiplication" (http://www.hackersdelight.org/MontgomeryMultiplication.pdf).
	* It is very similar to the MODULAR-INVERSE function in Stephen R. Dussé's and
	* Burton S. Kaliski Jr.'s "A Cryptographic Library for the Motorola DSP56000"
	* (http://link.springer.com/chapter/10.1007%2F3-540-46877-3_21).
	*
	* This is inspired by Joppe W. Bos's "Constant Time Modular Inversion"
	* (http://www.joppebos.com/files/CTInversion.pdf) so that the inversion is
	* constant-time with respect to \|n\|. We assume uint64_t additions,
	* subtractions, shifts, and bitwise operations are all constant time, which
	* may be a large leap of faith on 32-bit targets. We avoid division and
	* multiplication, which tend to be the most problematic in terms of timing
	* leaks.
	*
	* Most GCD implementations return values such that \|ur + vn == 1\|, so the
	* caller would have to negate the resultant \|v\| for the purpose of Montgomery
	* multiplication. This implementation does the negation implicitly by doing
	* the computations as a difference instead of a sum. */
	static uint64_t bn_neg_inv_mod_r_u64(uint64_t n) {
	assert(n % 2 == 1);

	/* alpha == 2*(lg r - 1) == r / 2. /
	static const uint64_t alpha = UINT64_C(1) << (LG_LITTLE_R - 1);

	const uint64_t beta = n;

	uint64_t u = 1;
	uint64_t v = 0;

	/* The invariant maintained from here on is:
	* 2*(lg r - i) == u2alpha - vbeta. */
	for (size_t i = 0; i < LG_LITTLE_R; ++i) {
	#if BN_BITS2 == 64 && defined(BN_ULLONG)
	assert((BN_ULLONG)(1) << (LG_LITTLE_R - i) ==
	((BN_ULLONG)u * 2 * alpha) - ((BN_ULLONG)v * beta));
	#endif

	/* Delete a common factor of 2 in u and v if \|u\| is even. Otherwise, set
	* \|u = (u + beta) / 2\| and \|v = (v / 2) + alpha\|. */

	uint64_t u_is_odd = UINT64_C(0) - (u & 1); /* Either 0xff..ff or 0. */

	/* The addition can overflow, so use Dietz's method for it.
	*
	* Dietz calculates (x+y)/2 by (x⊕y)>>1 + x&y. This is valid for all
	* (unsigned) x and y, even when x+y overflows. Evidence for 32-bit values
	* (embedded in 64 bits to so that overflow can be ignored):
	*
	* (declare-fun x () (_ BitVec 64))
	* (declare-fun y () (_ BitVec 64))
	* (assert (let (
	* (one (_ bv1 64))
	* (thirtyTwo (_ bv32 64)))
	* (and
	* (bvult x (bvshl one thirtyTwo))
	* (bvult y (bvshl one thirtyTwo))
	* (not (=
	* (bvadd (bvlshr (bvxor x y) one) (bvand x y))
	* (bvlshr (bvadd x y) one)))
	* )))
	* (check-sat) */
	uint64_t beta_if_u_is_odd = beta & u_is_odd; /* Either \|beta\| or 0. */
	u = ((u ^ beta_if_u_is_odd) >> 1) + (u & beta_if_u_is_odd);

	uint64_t alpha_if_u_is_odd = alpha & u_is_odd; /* Either \|alpha\| or 0. */
	v = (v >> 1) + alpha_if_u_is_odd;
	}

	/* The invariant now shows that ur - vn == 1 since r == 2 * alpha. */
	#if BN_BITS2 == 64 && defined(BN_ULLONG)
	assert(1 == ((BN_ULLONG)u * 2 * alpha) - ((BN_ULLONG)v * beta));
	#endif

	return v;
	}

	/* bn_mod_exp_base_2_vartime calculates r = 2**p (mod n). \|p\| must be larger
	* than log_2(n); i.e. 2**p must be larger than \|n\|. \|n\| must be positive and
	* odd. */
	int bn_mod_exp_base_2_vartime(BIGNUM r, unsigned p, const BIGNUM n) {
	assert(!BN_is_zero(n));
	assert(!BN_is_negative(n));
	assert(BN_is_odd(n));

	BN_zero(r);

	unsigned n_bits = BN_num_bits(n);
	assert(n_bits != 0);
	if (n_bits == 1) {
	return 1;
	}

	/* Set \|r\| to the smallest power of two larger than \|n\|. */
	assert(p > n_bits);
	if (!BN_set_bit(r, n_bits)) {
	return 0;
	}

	/* Unconditionally reduce \|r\|. */
	assert(BN_cmp(r, n) > 0);
	if (!BN_usub(r, r, n)) {
	return 0;
	}
	assert(BN_cmp(r, n) < 0);

	for (unsigned i = n_bits; i < p; ++i) {
	/* This is like \|BN_mod_lshift1_quick\| except using \|BN_usub\|.
	*
	* TODO: Replace this with the use of a constant-time variant of
	* \|BN_mod_lshift1_quick\|. */
	if (!BN_lshift1(r, r)) {
	return 0;
	}
	if (BN_cmp(r, n) >= 0) {
	if (!BN_usub(r, r, n)) {
	return 0;
	}
	}
	}

	return 1;
	}