crypto/bn/bn_div.c - third_party/openssl - Git at Google

 /*
  * Copyright 1995-2022 The OpenSSL Project Authors. All Rights Reserved.
  *
  * Licensed under the Apache License 2.0 (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
  */

 #include <assert.h>
 #include <openssl/bn.h>
 #include "internal/cryptlib.h"
 #include "bn_local.h"

 /* The old slow way */
 #if 0
 int BN_div(BIGNUM *dv, BIGNUM *rem, const BIGNUM *m, const BIGNUM *d,
            BN_CTX *ctx)
 {
     int i, nm, nd;
     int ret = 0;
     BIGNUM *D;

     bn_check_top(m);
     bn_check_top(d);
     if (BN_is_zero(d)) {
         ERR_raise(ERR_LIB_BN, BN_R_DIV_BY_ZERO);
         return 0;
     }

     if (BN_ucmp(m, d) < 0) {
         if (rem != NULL) {
             if (BN_copy(rem, m) == NULL)
                 return 0;
         }
         if (dv != NULL)
             BN_zero(dv);
         return 1;
     }

     BN_CTX_start(ctx);
     D = BN_CTX_get(ctx);
     if (dv == NULL)
         dv = BN_CTX_get(ctx);
     if (rem == NULL)
         rem = BN_CTX_get(ctx);
     if (D == NULL || dv == NULL || rem == NULL)
         goto end;

     nd = BN_num_bits(d);
     nm = BN_num_bits(m);
     if (BN_copy(D, d) == NULL)
         goto end;
     if (BN_copy(rem, m) == NULL)
         goto end;

     /*
      * The next 2 are needed so we can do a dv->d[0]|=1 later since
      * BN_lshift1 will only work once there is a value :-)
      */
     BN_zero(dv);
     if (bn_wexpand(dv, 1) == NULL)
         goto end;
     dv->top = 1;

     if (!BN_lshift(D, D, nm - nd))
         goto end;
     for (i = nm - nd; i >= 0; i--) {
         if (!BN_lshift1(dv, dv))
             goto end;
         if (BN_ucmp(rem, D) >= 0) {
             dv->d[0] |= 1;
             if (!BN_usub(rem, rem, D))
                 goto end;
         }
 /* CAN IMPROVE (and have now :=) */
         if (!BN_rshift1(D, D))
             goto end;
     }
     rem->neg = BN_is_zero(rem) ? 0 : m->neg;
     dv->neg = m->neg ^ d->neg;
     ret = 1;
  end:
     BN_CTX_end(ctx);
     return ret;
 }

 #else

 # if defined(BN_DIV3W)
 BN_ULONG bn_div_3_words(const BN_ULONG *m, BN_ULONG d1, BN_ULONG d0);
 # elif 0
 /*
  * This is #if-ed away, because it's a reference for assembly implementations,
  * where it can and should be made constant-time. But if you want to test it,
  * just replace 0 with 1.
  */
 #  if BN_BITS2 == 64 && defined(__SIZEOF_INT128__) && __SIZEOF_INT128__==16
 #   undef BN_ULLONG
 #   define BN_ULLONG uint128_t
 #   define BN_LLONG
 #  endif

 #  ifdef BN_LLONG
 #   define BN_DIV3W
 /*
  * Interface is somewhat quirky, |m| is pointer to most significant limb,
  * and less significant limb is referred at |m[-1]|. This means that caller
  * is responsible for ensuring that |m[-1]| is valid. Second condition that
  * has to be met is that |d0|'s most significant bit has to be set. Or in
  * other words divisor has to be "bit-aligned to the left." bn_div_fixed_top
  * does all this. The subroutine considers four limbs, two of which are
  * "overlapping," hence the name...
  */
 static BN_ULONG bn_div_3_words(const BN_ULONG *m, BN_ULONG d1, BN_ULONG d0)
 {
     BN_ULLONG R = ((BN_ULLONG)m[0] << BN_BITS2) | m[-1];
     BN_ULLONG D = ((BN_ULLONG)d0 << BN_BITS2) | d1;
     BN_ULONG Q = 0, mask;
     int i;

     for (i = 0; i < BN_BITS2; i++) {
         Q <<= 1;
         if (R >= D) {
             Q |= 1;
             R -= D;
         }
         D >>= 1;
     }

     mask = 0 - (Q >> (BN_BITS2 - 1));   /* does it overflow? */

     Q <<= 1;
     Q |= (R >= D);

     return (Q | mask) & BN_MASK2;
 }
 #  endif
 # endif

 static int bn_left_align(BIGNUM *num)
 {
     BN_ULONG *d = num->d, n, m, rmask;
     int top = num->top;
     int rshift = BN_num_bits_word(d[top - 1]), lshift, i;

     lshift = BN_BITS2 - rshift;
     rshift %= BN_BITS2;            /* say no to undefined behaviour */
     rmask = (BN_ULONG)0 - rshift;  /* rmask = 0 - (rshift != 0) */
     rmask |= rmask >> 8;

     for (i = 0, m = 0; i < top; i++) {
         n = d[i];
         d[i] = ((n << lshift) | m) & BN_MASK2;
         m = (n >> rshift) & rmask;
     }

     return lshift;
 }

 # if !defined(OPENSSL_NO_ASM) && !defined(OPENSSL_NO_INLINE_ASM) \
     && !defined(PEDANTIC) && !defined(BN_DIV3W)
 #  if defined(__GNUC__) && __GNUC__>=2
 #   if defined(__i386) || defined (__i386__)
    /*-
     * There were two reasons for implementing this template:
     * - GNU C generates a call to a function (__udivdi3 to be exact)
     *   in reply to ((((BN_ULLONG)n0)<<BN_BITS2)|n1)/d0 (I fail to
     *   understand why...);
     * - divl doesn't only calculate quotient, but also leaves
     *   remainder in %edx which we can definitely use here:-)
     */
 #    undef bn_div_words
 #    define bn_div_words(n0,n1,d0)                \
         ({  asm volatile (                      \
                 "divl   %4"                     \
                 : "=a"(q), "=d"(rem)            \
                 : "a"(n1), "d"(n0), "r"(d0)     \
                 : "cc");                        \
             q;                                  \
         })
 #    define REMAINDER_IS_ALREADY_CALCULATED
 #   elif defined(__x86_64) && defined(SIXTY_FOUR_BIT_LONG)
    /*
     * Same story here, but it's 128-bit by 64-bit division. Wow!
     */
 #    undef bn_div_words
 #    define bn_div_words(n0,n1,d0)                \
         ({  asm volatile (                      \
                 "divq   %4"                     \
                 : "=a"(q), "=d"(rem)            \
                 : "a"(n1), "d"(n0), "r"(d0)     \
                 : "cc");                        \
             q;                                  \
         })
 #    define REMAINDER_IS_ALREADY_CALCULATED
 #   endif                       /* __<cpu> */
 #  endif                        /* __GNUC__ */
 # endif                         /* OPENSSL_NO_ASM */

 /*-
  * BN_div computes  dv := num / divisor, rounding towards
  * zero, and sets up rm  such that  dv*divisor + rm = num  holds.
  * Thus:
  *     dv->neg == num->neg ^ divisor->neg  (unless the result is zero)
  *     rm->neg == num->neg                 (unless the remainder is zero)
  * If 'dv' or 'rm' is NULL, the respective value is not returned.
  */
 int BN_div(BIGNUM *dv, BIGNUM *rm, const BIGNUM *num, const BIGNUM *divisor,
            BN_CTX *ctx)
 {
     int ret;

     if (BN_is_zero(divisor)) {
         ERR_raise(ERR_LIB_BN, BN_R_DIV_BY_ZERO);
         return 0;
     }

     /*
      * Invalid zero-padding would have particularly bad consequences so don't
      * just rely on bn_check_top() here (bn_check_top() works only for
      * BN_DEBUG builds)
      */
     if (divisor->d[divisor->top - 1] == 0) {
         ERR_raise(ERR_LIB_BN, BN_R_NOT_INITIALIZED);
         return 0;
     }

     ret = bn_div_fixed_top(dv, rm, num, divisor, ctx);

     if (ret) {
         if (dv != NULL)
             bn_correct_top(dv);
         if (rm != NULL)
             bn_correct_top(rm);
     }

     return ret;
 }

 /*
  * It's argued that *length* of *significant* part of divisor is public.
  * Even if it's private modulus that is. Again, *length* is assumed
  * public, but not *value*. Former is likely to be pre-defined by
  * algorithm with bit granularity, though below subroutine is invariant
  * of limb length. Thanks to this assumption we can require that |divisor|
  * may not be zero-padded, yet claim this subroutine "constant-time"(*).
  * This is because zero-padded dividend, |num|, is tolerated, so that
  * caller can pass dividend of public length(*), but with smaller amount
  * of significant limbs. This naturally means that quotient, |dv|, would
  * contain correspongly less significant limbs as well, and will be zero-
  * padded accordingly. Returned remainder, |rm|, will have same bit length
  * as divisor, also zero-padded if needed. These actually leave sign bits
  * in ambiguous state. In sense that we try to avoid negative zeros, while
  * zero-padded zeros would retain sign.
  *
  * (*) "Constant-time-ness" has two pre-conditions:
  *
  *     - availability of constant-time bn_div_3_words;
  *     - dividend is at least as "wide" as divisor, limb-wise, zero-padded
  *       if so required, which shouldn't be a privacy problem, because
  *       divisor's length is considered public;
  */
 int bn_div_fixed_top(BIGNUM *dv, BIGNUM *rm, const BIGNUM *num,
                      const BIGNUM *divisor, BN_CTX *ctx)
 {
     int norm_shift, i, j, loop;
     BIGNUM *tmp, *snum, *sdiv, *res;
     BN_ULONG *resp, *wnum, *wnumtop;
     BN_ULONG d0, d1;
     int num_n, div_n, num_neg;

     assert(divisor->top > 0 && divisor->d[divisor->top - 1] != 0);

     bn_check_top(num);
     bn_check_top(divisor);
     bn_check_top(dv);
     bn_check_top(rm);

     BN_CTX_start(ctx);
     res = (dv == NULL) ? BN_CTX_get(ctx) : dv;
     tmp = BN_CTX_get(ctx);
     snum = BN_CTX_get(ctx);
     sdiv = BN_CTX_get(ctx);
     if (sdiv == NULL)
         goto err;

     /* First we normalise the numbers */
     if (!BN_copy(sdiv, divisor))
         goto err;
     norm_shift = bn_left_align(sdiv);
     sdiv->neg = 0;
     /*
      * Note that bn_lshift_fixed_top's output is always one limb longer
      * than input, even when norm_shift is zero. This means that amount of
      * inner loop iterations is invariant of dividend value, and that one
      * doesn't need to compare dividend and divisor if they were originally
      * of the same bit length.
      */
     if (!(bn_lshift_fixed_top(snum, num, norm_shift)))
         goto err;

     div_n = sdiv->top;
     num_n = snum->top;

     if (num_n <= div_n) {
         /* caller didn't pad dividend -> no constant-time guarantee... */
         if (bn_wexpand(snum, div_n + 1) == NULL)
             goto err;
         memset(&(snum->d[num_n]), 0, (div_n - num_n + 1) * sizeof(BN_ULONG));
         snum->top = num_n = div_n + 1;
     }

     loop = num_n - div_n;
     /*
      * Lets setup a 'window' into snum This is the part that corresponds to
      * the current 'area' being divided
      */
     wnum = &(snum->d[loop]);
     wnumtop = &(snum->d[num_n - 1]);

     /* Get the top 2 words of sdiv */
     d0 = sdiv->d[div_n - 1];
     d1 = (div_n == 1) ? 0 : sdiv->d[div_n - 2];

     /* Setup quotient */
     if (!bn_wexpand(res, loop))
         goto err;
     num_neg = num->neg;
     res->neg = (num_neg ^ divisor->neg);
     res->top = loop;
     res->flags |= BN_FLG_FIXED_TOP;
     resp = &(res->d[loop]);

     /* space for temp */
     if (!bn_wexpand(tmp, (div_n + 1)))
         goto err;

     for (i = 0; i < loop; i++, wnumtop--) {
         BN_ULONG q, l0;
         /*
          * the first part of the loop uses the top two words of snum and sdiv
          * to calculate a BN_ULONG q such that | wnum - sdiv * q | < sdiv
          */
 # if defined(BN_DIV3W)
         q = bn_div_3_words(wnumtop, d1, d0);
 # else
         BN_ULONG n0, n1, rem = 0;

         n0 = wnumtop[0];
         n1 = wnumtop[-1];
         if (n0 == d0)
             q = BN_MASK2;
         else {                  /* n0 < d0 */
             BN_ULONG n2 = (wnumtop == wnum) ? 0 : wnumtop[-2];
 #  ifdef BN_LLONG
             BN_ULLONG t2;

 #   if defined(BN_LLONG) && defined(BN_DIV2W) && !defined(bn_div_words)
             q = (BN_ULONG)(((((BN_ULLONG) n0) << BN_BITS2) | n1) / d0);
 #   else
             q = bn_div_words(n0, n1, d0);
 #   endif

 #   ifndef REMAINDER_IS_ALREADY_CALCULATED
             /*
              * rem doesn't have to be BN_ULLONG. The least we
              * know it's less that d0, isn't it?
              */
             rem = (n1 - q * d0) & BN_MASK2;
 #   endif
             t2 = (BN_ULLONG) d1 *q;

             for (;;) {
                 if (t2 <= ((((BN_ULLONG) rem) << BN_BITS2) | n2))
                     break;
                 q--;
                 rem += d0;
                 if (rem < d0)
                     break;      /* don't let rem overflow */
                 t2 -= d1;
             }
 #  else                         /* !BN_LLONG */
             BN_ULONG t2l, t2h;

             q = bn_div_words(n0, n1, d0);
 #   ifndef REMAINDER_IS_ALREADY_CALCULATED
             rem = (n1 - q * d0) & BN_MASK2;
 #   endif

 #   if defined(BN_UMULT_LOHI)
             BN_UMULT_LOHI(t2l, t2h, d1, q);
 #   elif defined(BN_UMULT_HIGH)
             t2l = d1 * q;
             t2h = BN_UMULT_HIGH(d1, q);
 #   else
             {
                 BN_ULONG ql, qh;
                 t2l = LBITS(d1);
                 t2h = HBITS(d1);
                 ql = LBITS(q);
                 qh = HBITS(q);
                 mul64(t2l, t2h, ql, qh); /* t2=(BN_ULLONG)d1*q; */
             }
 #   endif

             for (;;) {
                 if ((t2h < rem) || ((t2h == rem) && (t2l <= n2)))
                     break;
                 q--;
                 rem += d0;
                 if (rem < d0)
                     break;      /* don't let rem overflow */
                 if (t2l < d1)
                     t2h--;
                 t2l -= d1;
             }
 #  endif                        /* !BN_LLONG */
         }
 # endif                         /* !BN_DIV3W */

         l0 = bn_mul_words(tmp->d, sdiv->d, div_n, q);
         tmp->d[div_n] = l0;
         wnum--;
         /*
          * ignore top values of the bignums just sub the two BN_ULONG arrays
          * with bn_sub_words
          */
         l0 = bn_sub_words(wnum, wnum, tmp->d, div_n + 1);
         q -= l0;
         /*
          * Note: As we have considered only the leading two BN_ULONGs in
          * the calculation of q, sdiv * q might be greater than wnum (but
          * then (q-1) * sdiv is less or equal than wnum)
          */
         for (l0 = 0 - l0, j = 0; j < div_n; j++)
             tmp->d[j] = sdiv->d[j] & l0;
         l0 = bn_add_words(wnum, wnum, tmp->d, div_n);
         (*wnumtop) += l0;
         assert((*wnumtop) == 0);

         /* store part of the result */
         *--resp = q;
     }
     /* snum holds remainder, it's as wide as divisor */
     snum->neg = num_neg;
     snum->top = div_n;
     snum->flags |= BN_FLG_FIXED_TOP;

     if (rm != NULL && bn_rshift_fixed_top(rm, snum, norm_shift) == 0)
         goto err;

     BN_CTX_end(ctx);
     return 1;
  err:
     bn_check_top(rm);
     BN_CTX_end(ctx);
     return 0;
 }
 #endif
	/*
	* Copyright 1995-2022 The OpenSSL Project Authors. All Rights Reserved.
	*
	* Licensed under the Apache License 2.0 (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
	*/

	#include <assert.h>
	#include <openssl/bn.h>
	#include "internal/cryptlib.h"
	#include "bn_local.h"

	/* The old slow way */
	#if 0
	int BN_div(BIGNUM dv, BIGNUM rem, const BIGNUM m, const BIGNUM d,
	BN_CTX *ctx)
	{
	int i, nm, nd;
	int ret = 0;
	BIGNUM *D;

	bn_check_top(m);
	bn_check_top(d);
	if (BN_is_zero(d)) {
	ERR_raise(ERR_LIB_BN, BN_R_DIV_BY_ZERO);
	return 0;
	}

	if (BN_ucmp(m, d) < 0) {
	if (rem != NULL) {
	if (BN_copy(rem, m) == NULL)
	return 0;
	}
	if (dv != NULL)
	BN_zero(dv);
	return 1;
	}

	BN_CTX_start(ctx);
	D = BN_CTX_get(ctx);
	if (dv == NULL)
	dv = BN_CTX_get(ctx);
	if (rem == NULL)
	rem = BN_CTX_get(ctx);
	if (D == NULL \|\| dv == NULL \|\| rem == NULL)
	goto end;

	nd = BN_num_bits(d);
	nm = BN_num_bits(m);
	if (BN_copy(D, d) == NULL)
	goto end;
	if (BN_copy(rem, m) == NULL)
	goto end;

	/*
	* The next 2 are needed so we can do a dv->d[0]\|=1 later since
	* BN_lshift1 will only work once there is a value :-)
	*/
	BN_zero(dv);
	if (bn_wexpand(dv, 1) == NULL)
	goto end;
	dv->top = 1;

	if (!BN_lshift(D, D, nm - nd))
	goto end;
	for (i = nm - nd; i >= 0; i--) {
	if (!BN_lshift1(dv, dv))
	goto end;
	if (BN_ucmp(rem, D) >= 0) {
	dv->d[0] \|= 1;
	if (!BN_usub(rem, rem, D))
	goto end;
	}
	/* CAN IMPROVE (and have now :=) */
	if (!BN_rshift1(D, D))
	goto end;
	}
	rem->neg = BN_is_zero(rem) ? 0 : m->neg;
	dv->neg = m->neg ^ d->neg;
	ret = 1;
	end:
	BN_CTX_end(ctx);
	return ret;
	}

	#else

	# if defined(BN_DIV3W)
	BN_ULONG bn_div_3_words(const BN_ULONG *m, BN_ULONG d1, BN_ULONG d0);
	# elif 0
	/*
	* This is #if-ed away, because it's a reference for assembly implementations,
	* where it can and should be made constant-time. But if you want to test it,
	* just replace 0 with 1.
	*/
	# if BN_BITS2 == 64 && defined(__SIZEOF_INT128__) && __SIZEOF_INT128__==16
	# undef BN_ULLONG
	# define BN_ULLONG uint128_t
	# define BN_LLONG
	# endif

	# ifdef BN_LLONG
	# define BN_DIV3W
	/*
	* Interface is somewhat quirky, \|m\| is pointer to most significant limb,
	* and less significant limb is referred at \|m[-1]\|. This means that caller
	* is responsible for ensuring that \|m[-1]\| is valid. Second condition that
	* has to be met is that \|d0\|'s most significant bit has to be set. Or in
	* other words divisor has to be "bit-aligned to the left." bn_div_fixed_top
	* does all this. The subroutine considers four limbs, two of which are
	* "overlapping," hence the name...
	*/
	static BN_ULONG bn_div_3_words(const BN_ULONG *m, BN_ULONG d1, BN_ULONG d0)
	{
	BN_ULLONG R = ((BN_ULLONG)m[0] << BN_BITS2) \| m[-1];
	BN_ULLONG D = ((BN_ULLONG)d0 << BN_BITS2) \| d1;
	BN_ULONG Q = 0, mask;
	int i;

	for (i = 0; i < BN_BITS2; i++) {
	Q <<= 1;
	if (R >= D) {
	Q \|= 1;
	R -= D;
	}
	D >>= 1;
	}

	mask = 0 - (Q >> (BN_BITS2 - 1)); /* does it overflow? */

	Q <<= 1;
	Q \|= (R >= D);

	return (Q \| mask) & BN_MASK2;
	}
	# endif
	# endif

	static int bn_left_align(BIGNUM *num)
	{
	BN_ULONG *d = num->d, n, m, rmask;
	int top = num->top;
	int rshift = BN_num_bits_word(d[top - 1]), lshift, i;

	lshift = BN_BITS2 - rshift;
	rshift %= BN_BITS2; /* say no to undefined behaviour */
	rmask = (BN_ULONG)0 - rshift; /* rmask = 0 - (rshift != 0) */
	rmask \|= rmask >> 8;

	for (i = 0, m = 0; i < top; i++) {
	n = d[i];
	d[i] = ((n << lshift) \| m) & BN_MASK2;
	m = (n >> rshift) & rmask;
	}

	return lshift;
	}

	# if !defined(OPENSSL_NO_ASM) && !defined(OPENSSL_NO_INLINE_ASM) \
	&& !defined(PEDANTIC) && !defined(BN_DIV3W)
	# if defined(__GNUC__) && __GNUC__>=2
	# if defined(__i386) \|\| defined (__i386__)
	/*-
	* There were two reasons for implementing this template:
	* - GNU C generates a call to a function (__udivdi3 to be exact)
	* in reply to ((((BN_ULLONG)n0)<<BN_BITS2)\|n1)/d0 (I fail to
	* understand why...);
	* - divl doesn't only calculate quotient, but also leaves
	* remainder in %edx which we can definitely use here:-)
	*/
	# undef bn_div_words
	# define bn_div_words(n0,n1,d0) \
	({ asm volatile ( \
	"divl %4" \
	: "=a"(q), "=d"(rem) \
	: "a"(n1), "d"(n0), "r"(d0) \
	: "cc"); \
	q; \
	})
	# define REMAINDER_IS_ALREADY_CALCULATED
	# elif defined(__x86_64) && defined(SIXTY_FOUR_BIT_LONG)
	/*
	* Same story here, but it's 128-bit by 64-bit division. Wow!
	*/
	# undef bn_div_words
	# define bn_div_words(n0,n1,d0) \
	({ asm volatile ( \
	"divq %4" \
	: "=a"(q), "=d"(rem) \
	: "a"(n1), "d"(n0), "r"(d0) \
	: "cc"); \
	q; \
	})
	# define REMAINDER_IS_ALREADY_CALCULATED
	# endif /* __<cpu> */
	# endif /* __GNUC__ */
	# endif /* OPENSSL_NO_ASM */

	/*-
	* BN_div computes dv := num / divisor, rounding towards
	* zero, and sets up rm such that dv*divisor + rm = num holds.
	* Thus:
	* dv->neg == num->neg ^ divisor->neg (unless the result is zero)
	* rm->neg == num->neg (unless the remainder is zero)
	* If 'dv' or 'rm' is NULL, the respective value is not returned.
	*/
	int BN_div(BIGNUM dv, BIGNUM rm, const BIGNUM num, const BIGNUM divisor,
	BN_CTX *ctx)
	{
	int ret;

	if (BN_is_zero(divisor)) {
	ERR_raise(ERR_LIB_BN, BN_R_DIV_BY_ZERO);
	return 0;
	}

	/*
	* Invalid zero-padding would have particularly bad consequences so don't
	* just rely on bn_check_top() here (bn_check_top() works only for
	* BN_DEBUG builds)
	*/
	if (divisor->d[divisor->top - 1] == 0) {
	ERR_raise(ERR_LIB_BN, BN_R_NOT_INITIALIZED);
	return 0;
	}

	ret = bn_div_fixed_top(dv, rm, num, divisor, ctx);

	if (ret) {
	if (dv != NULL)
	bn_correct_top(dv);
	if (rm != NULL)
	bn_correct_top(rm);
	}

	return ret;
	}

	/*
	* It's argued that length of significant part of divisor is public.
	* Even if it's private modulus that is. Again, length is assumed
	* public, but not value. Former is likely to be pre-defined by
	* algorithm with bit granularity, though below subroutine is invariant
	* of limb length. Thanks to this assumption we can require that \|divisor\|
	* may not be zero-padded, yet claim this subroutine "constant-time"(*).
	* This is because zero-padded dividend, \|num\|, is tolerated, so that
	* caller can pass dividend of public length(*), but with smaller amount
	* of significant limbs. This naturally means that quotient, \|dv\|, would
	* contain correspongly less significant limbs as well, and will be zero-
	* padded accordingly. Returned remainder, \|rm\|, will have same bit length
	* as divisor, also zero-padded if needed. These actually leave sign bits
	* in ambiguous state. In sense that we try to avoid negative zeros, while
	* zero-padded zeros would retain sign.
	*
	* (*) "Constant-time-ness" has two pre-conditions:
	*
	* - availability of constant-time bn_div_3_words;
	* - dividend is at least as "wide" as divisor, limb-wise, zero-padded
	* if so required, which shouldn't be a privacy problem, because
	* divisor's length is considered public;
	*/
	int bn_div_fixed_top(BIGNUM dv, BIGNUM rm, const BIGNUM *num,
	const BIGNUM divisor, BN_CTX ctx)
	{
	int norm_shift, i, j, loop;
	BIGNUM tmp, snum, sdiv, res;
	BN_ULONG resp, wnum, *wnumtop;
	BN_ULONG d0, d1;
	int num_n, div_n, num_neg;

	assert(divisor->top > 0 && divisor->d[divisor->top - 1] != 0);

	bn_check_top(num);
	bn_check_top(divisor);
	bn_check_top(dv);
	bn_check_top(rm);

	BN_CTX_start(ctx);
	res = (dv == NULL) ? BN_CTX_get(ctx) : dv;
	tmp = BN_CTX_get(ctx);
	snum = BN_CTX_get(ctx);
	sdiv = BN_CTX_get(ctx);
	if (sdiv == NULL)
	goto err;

	/* First we normalise the numbers */
	if (!BN_copy(sdiv, divisor))
	goto err;
	norm_shift = bn_left_align(sdiv);
	sdiv->neg = 0;
	/*
	* Note that bn_lshift_fixed_top's output is always one limb longer
	* than input, even when norm_shift is zero. This means that amount of
	* inner loop iterations is invariant of dividend value, and that one
	* doesn't need to compare dividend and divisor if they were originally
	* of the same bit length.
	*/
	if (!(bn_lshift_fixed_top(snum, num, norm_shift)))
	goto err;

	div_n = sdiv->top;
	num_n = snum->top;

	if (num_n <= div_n) {
	/* caller didn't pad dividend -> no constant-time guarantee... */
	if (bn_wexpand(snum, div_n + 1) == NULL)
	goto err;
	memset(&(snum->d[num_n]), 0, (div_n - num_n + 1) * sizeof(BN_ULONG));
	snum->top = num_n = div_n + 1;
	}

	loop = num_n - div_n;
	/*
	* Lets setup a 'window' into snum This is the part that corresponds to
	* the current 'area' being divided
	*/
	wnum = &(snum->d[loop]);
	wnumtop = &(snum->d[num_n - 1]);

	/* Get the top 2 words of sdiv */
	d0 = sdiv->d[div_n - 1];
	d1 = (div_n == 1) ? 0 : sdiv->d[div_n - 2];

	/* Setup quotient */
	if (!bn_wexpand(res, loop))
	goto err;
	num_neg = num->neg;
	res->neg = (num_neg ^ divisor->neg);
	res->top = loop;
	res->flags \|= BN_FLG_FIXED_TOP;
	resp = &(res->d[loop]);

	/* space for temp */
	if (!bn_wexpand(tmp, (div_n + 1)))
	goto err;

	for (i = 0; i < loop; i++, wnumtop--) {
	BN_ULONG q, l0;
	/*
	* the first part of the loop uses the top two words of snum and sdiv
	* to calculate a BN_ULONG q such that \| wnum - sdiv * q \| < sdiv
	*/
	# if defined(BN_DIV3W)
	q = bn_div_3_words(wnumtop, d1, d0);
	# else
	BN_ULONG n0, n1, rem = 0;

	n0 = wnumtop[0];
	n1 = wnumtop[-1];
	if (n0 == d0)
	q = BN_MASK2;
	else { /* n0 < d0 */
	BN_ULONG n2 = (wnumtop == wnum) ? 0 : wnumtop[-2];
	# ifdef BN_LLONG
	BN_ULLONG t2;

	# if defined(BN_LLONG) && defined(BN_DIV2W) && !defined(bn_div_words)
	q = (BN_ULONG)(((((BN_ULLONG) n0) << BN_BITS2) \| n1) / d0);
	# else
	q = bn_div_words(n0, n1, d0);
	# endif

	# ifndef REMAINDER_IS_ALREADY_CALCULATED
	/*
	* rem doesn't have to be BN_ULLONG. The least we
	* know it's less that d0, isn't it?
	*/
	rem = (n1 - q * d0) & BN_MASK2;
	# endif
	t2 = (BN_ULLONG) d1 *q;

	for (;;) {
	if (t2 <= ((((BN_ULLONG) rem) << BN_BITS2) \| n2))
	break;
	q--;
	rem += d0;
	if (rem < d0)
	break; /* don't let rem overflow */
	t2 -= d1;
	}
	# else /* !BN_LLONG */
	BN_ULONG t2l, t2h;

	q = bn_div_words(n0, n1, d0);
	# ifndef REMAINDER_IS_ALREADY_CALCULATED
	rem = (n1 - q * d0) & BN_MASK2;
	# endif

	# if defined(BN_UMULT_LOHI)
	BN_UMULT_LOHI(t2l, t2h, d1, q);
	# elif defined(BN_UMULT_HIGH)
	t2l = d1 * q;
	t2h = BN_UMULT_HIGH(d1, q);
	# else
	{
	BN_ULONG ql, qh;
	t2l = LBITS(d1);
	t2h = HBITS(d1);
	ql = LBITS(q);
	qh = HBITS(q);
	mul64(t2l, t2h, ql, qh); /* t2=(BN_ULLONG)d1q; /
	}
	# endif

	for (;;) {
	if ((t2h < rem) \|\| ((t2h == rem) && (t2l <= n2)))
	break;
	q--;
	rem += d0;
	if (rem < d0)
	break; /* don't let rem overflow */
	if (t2l < d1)
	t2h--;
	t2l -= d1;
	}
	# endif /* !BN_LLONG */
	}
	# endif /* !BN_DIV3W */

	l0 = bn_mul_words(tmp->d, sdiv->d, div_n, q);
	tmp->d[div_n] = l0;
	wnum--;
	/*
	* ignore top values of the bignums just sub the two BN_ULONG arrays
	* with bn_sub_words
	*/
	l0 = bn_sub_words(wnum, wnum, tmp->d, div_n + 1);
	q -= l0;
	/*
	* Note: As we have considered only the leading two BN_ULONGs in
	* the calculation of q, sdiv * q might be greater than wnum (but
	* then (q-1) * sdiv is less or equal than wnum)
	*/
	for (l0 = 0 - l0, j = 0; j < div_n; j++)
	tmp->d[j] = sdiv->d[j] & l0;
	l0 = bn_add_words(wnum, wnum, tmp->d, div_n);
	(*wnumtop) += l0;
	assert((*wnumtop) == 0);

	/* store part of the result */
	*--resp = q;
	}
	/* snum holds remainder, it's as wide as divisor */
	snum->neg = num_neg;
	snum->top = div_n;
	snum->flags \|= BN_FLG_FIXED_TOP;

	if (rm != NULL && bn_rshift_fixed_top(rm, snum, norm_shift) == 0)
	goto err;

	BN_CTX_end(ctx);
	return 1;
	err:
	bn_check_top(rm);
	BN_CTX_end(ctx);
	return 0;
	}
	#endif