third_party/gmp/mpn/generic/hgcd.c - RealtimeRoboticsGroup/test - Gitiles

 /* hgcd.c.

    THE FUNCTIONS IN THIS FILE ARE INTERNAL WITH MUTABLE INTERFACES.  IT IS ONLY
    SAFE TO REACH THEM THROUGH DOCUMENTED INTERFACES.  IN FACT, IT IS ALMOST
    GUARANTEED THAT THEY'LL CHANGE OR DISAPPEAR IN A FUTURE GNU MP RELEASE.

 Copyright 2003-2005, 2008, 2011, 2012 Free Software Foundation, Inc.

 This file is part of the GNU MP Library.

 The GNU MP Library is free software; you can redistribute it and/or modify
 it under the terms of either:

   * the GNU Lesser General Public License as published by the Free
     Software Foundation; either version 3 of the License, or (at your
     option) any later version.

 or

   * the GNU General Public License as published by the Free Software
     Foundation; either version 2 of the License, or (at your option) any
     later version.

 or both in parallel, as here.

 The GNU MP Library is distributed in the hope that it will be useful, but
 WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
 or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 for more details.

 You should have received copies of the GNU General Public License and the
 GNU Lesser General Public License along with the GNU MP Library.  If not,
 see https://www.gnu.org/licenses/.  */

 #include "gmp-impl.h"
 #include "longlong.h"


 /* Size analysis for hgcd:

    For the recursive calls, we have n1 <= ceil(n / 2). Then the
    storage need is determined by the storage for the recursive call
    computing M1, and hgcd_matrix_adjust and hgcd_matrix_mul calls that use M1
    (after this, the storage needed for M1 can be recycled).

    Let S(r) denote the required storage. For M1 we need 4 * (ceil(n1/2) + 1)
    = 4 * (ceil(n/4) + 1), for the hgcd_matrix_adjust call, we need n + 2,
    and for the hgcd_matrix_mul, we may need 3 ceil(n/2) + 8. In total,
    4 * ceil(n/4) + 3 ceil(n/2) + 12 <= 10 ceil(n/4) + 12.

    For the recursive call, we need S(n1) = S(ceil(n/2)).

    S(n) <= 10*ceil(n/4) + 12 + S(ceil(n/2))
 	<= 10*(ceil(n/4) + ... + ceil(n/2^(1+k))) + 12k + S(ceil(n/2^k))
 	<= 10*(2 ceil(n/4) + k) + 12k + S(ceil(n/2^k))
 	<= 20 ceil(n/4) + 22k + S(ceil(n/2^k))
 */

 mp_size_t
 mpn_hgcd_itch (mp_size_t n)
 {
   unsigned k;
   int count;
   mp_size_t nscaled;

   if (BELOW_THRESHOLD (n, HGCD_THRESHOLD))
     return n;

   /* Get the recursion depth. */
   nscaled = (n - 1) / (HGCD_THRESHOLD - 1);
   count_leading_zeros (count, nscaled);
   k = GMP_LIMB_BITS - count;

   return 20 * ((n+3) / 4) + 22 * k + HGCD_THRESHOLD;
 }

 /* Reduces a,b until |a-b| fits in n/2 + 1 limbs. Constructs matrix M
    with elements of size at most (n+1)/2 - 1. Returns new size of a,
    b, or zero if no reduction is possible. */

 mp_size_t
 mpn_hgcd (mp_ptr ap, mp_ptr bp, mp_size_t n,
 	  struct hgcd_matrix *M, mp_ptr tp)
 {
   mp_size_t s = n/2 + 1;

   mp_size_t nn;
   int success = 0;

   if (n <= s)
     /* Happens when n <= 2, a fairly uninteresting case but exercised
        by the random inputs of the testsuite. */
     return 0;

   ASSERT ((ap[n-1] | bp[n-1]) > 0);

   ASSERT ((n+1)/2 - 1 < M->alloc);

   if (ABOVE_THRESHOLD (n, HGCD_THRESHOLD))
     {
       mp_size_t n2 = (3*n)/4 + 1;
       mp_size_t p = n/2;

       nn = mpn_hgcd_reduce (M, ap, bp, n, p, tp);
       if (nn)
 	{
 	  n = nn;
 	  success = 1;
 	}

       /* NOTE: It appears this loop never runs more than once (at
 	 least when not recursing to hgcd_appr). */
       while (n > n2)
 	{
 	  /* Needs n + 1 storage */
 	  nn = mpn_hgcd_step (n, ap, bp, s, M, tp);
 	  if (!nn)
 	    return success ? n : 0;

 	  n = nn;
 	  success = 1;
 	}

       if (n > s + 2)
 	{
 	  struct hgcd_matrix M1;
 	  mp_size_t scratch;

 	  p = 2*s - n + 1;
 	  scratch = MPN_HGCD_MATRIX_INIT_ITCH (n-p);

 	  mpn_hgcd_matrix_init(&M1, n - p, tp);

 	  /* FIXME: Should use hgcd_reduce, but that may require more
 	     scratch space, which requires review. */

 	  nn = mpn_hgcd (ap + p, bp + p, n - p, &M1, tp + scratch);
 	  if (nn > 0)
 	    {
 	      /* We always have max(M) > 2^{-(GMP_NUMB_BITS + 1)} max(M1) */
 	      ASSERT (M->n + 2 >= M1.n);

 	      /* Furthermore, assume M ends with a quotient (1, q; 0, 1),
 		 then either q or q + 1 is a correct quotient, and M1 will
 		 start with either (1, 0; 1, 1) or (2, 1; 1, 1). This
 		 rules out the case that the size of M * M1 is much
 		 smaller than the expected M->n + M1->n. */

 	      ASSERT (M->n + M1.n < M->alloc);

 	      /* Needs 2 (p + M->n) <= 2 (2*s - n2 + 1 + n2 - s - 1)
 		 = 2*s <= 2*(floor(n/2) + 1) <= n + 2. */
 	      n = mpn_hgcd_matrix_adjust (&M1, p + nn, ap, bp, p, tp + scratch);

 	      /* We need a bound for of M->n + M1.n. Let n be the original
 		 input size. Then

 		 ceil(n/2) - 1 >= size of product >= M.n + M1.n - 2

 		 and it follows that

 		 M.n + M1.n <= ceil(n/2) + 1

 		 Then 3*(M.n + M1.n) + 5 <= 3 * ceil(n/2) + 8 is the
 		 amount of needed scratch space. */
 	      mpn_hgcd_matrix_mul (M, &M1, tp + scratch);
 	      success = 1;
 	    }
 	}
     }

   for (;;)
     {
       /* Needs s+3 < n */
       nn = mpn_hgcd_step (n, ap, bp, s, M, tp);
       if (!nn)
 	return success ? n : 0;

       n = nn;
       success = 1;
     }
 }
	/* hgcd.c.

	THE FUNCTIONS IN THIS FILE ARE INTERNAL WITH MUTABLE INTERFACES. IT IS ONLY
	SAFE TO REACH THEM THROUGH DOCUMENTED INTERFACES. IN FACT, IT IS ALMOST
	GUARANTEED THAT THEY'LL CHANGE OR DISAPPEAR IN A FUTURE GNU MP RELEASE.

	Copyright 2003-2005, 2008, 2011, 2012 Free Software Foundation, Inc.

	This file is part of the GNU MP Library.

	The GNU MP Library is free software; you can redistribute it and/or modify
	it under the terms of either:

	* the GNU Lesser General Public License as published by the Free
	Software Foundation; either version 3 of the License, or (at your
	option) any later version.

	or

	* the GNU General Public License as published by the Free Software
	Foundation; either version 2 of the License, or (at your option) any
	later version.

	or both in parallel, as here.

	The GNU MP Library is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
	or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	for more details.

	You should have received copies of the GNU General Public License and the
	GNU Lesser General Public License along with the GNU MP Library. If not,
	see https://www.gnu.org/licenses/. */

	#include "gmp-impl.h"
	#include "longlong.h"


	/* Size analysis for hgcd:

	For the recursive calls, we have n1 <= ceil(n / 2). Then the
	storage need is determined by the storage for the recursive call
	computing M1, and hgcd_matrix_adjust and hgcd_matrix_mul calls that use M1
	(after this, the storage needed for M1 can be recycled).

	Let S(r) denote the required storage. For M1 we need 4 * (ceil(n1/2) + 1)
	= 4 * (ceil(n/4) + 1), for the hgcd_matrix_adjust call, we need n + 2,
	and for the hgcd_matrix_mul, we may need 3 ceil(n/2) + 8. In total,
	4 * ceil(n/4) + 3 ceil(n/2) + 12 <= 10 ceil(n/4) + 12.

	For the recursive call, we need S(n1) = S(ceil(n/2)).

	S(n) <= 10*ceil(n/4) + 12 + S(ceil(n/2))
	<= 10*(ceil(n/4) + ... + ceil(n/2^(1+k))) + 12k + S(ceil(n/2^k))
	<= 10*(2 ceil(n/4) + k) + 12k + S(ceil(n/2^k))
	<= 20 ceil(n/4) + 22k + S(ceil(n/2^k))
	*/

	mp_size_t
	mpn_hgcd_itch (mp_size_t n)
	{
	unsigned k;
	int count;
	mp_size_t nscaled;

	if (BELOW_THRESHOLD (n, HGCD_THRESHOLD))
	return n;

	/* Get the recursion depth. */
	nscaled = (n - 1) / (HGCD_THRESHOLD - 1);
	count_leading_zeros (count, nscaled);
	k = GMP_LIMB_BITS - count;

	return 20 * ((n+3) / 4) + 22 * k + HGCD_THRESHOLD;
	}

	/* Reduces a,b until \|a-b\| fits in n/2 + 1 limbs. Constructs matrix M
	with elements of size at most (n+1)/2 - 1. Returns new size of a,
	b, or zero if no reduction is possible. */

	mp_size_t
	mpn_hgcd (mp_ptr ap, mp_ptr bp, mp_size_t n,
	struct hgcd_matrix *M, mp_ptr tp)
	{
	mp_size_t s = n/2 + 1;

	mp_size_t nn;
	int success = 0;

	if (n <= s)
	/* Happens when n <= 2, a fairly uninteresting case but exercised
	by the random inputs of the testsuite. */
	return 0;

	ASSERT ((ap[n-1] \| bp[n-1]) > 0);

	ASSERT ((n+1)/2 - 1 < M->alloc);

	if (ABOVE_THRESHOLD (n, HGCD_THRESHOLD))
	{
	mp_size_t n2 = (3*n)/4 + 1;
	mp_size_t p = n/2;

	nn = mpn_hgcd_reduce (M, ap, bp, n, p, tp);
	if (nn)
	{
	n = nn;
	success = 1;
	}

	/* NOTE: It appears this loop never runs more than once (at
	least when not recursing to hgcd_appr). */
	while (n > n2)
	{
	/* Needs n + 1 storage */
	nn = mpn_hgcd_step (n, ap, bp, s, M, tp);
	if (!nn)
	return success ? n : 0;

	n = nn;
	success = 1;
	}

	if (n > s + 2)
	{
	struct hgcd_matrix M1;
	mp_size_t scratch;

	p = 2*s - n + 1;
	scratch = MPN_HGCD_MATRIX_INIT_ITCH (n-p);

	mpn_hgcd_matrix_init(&M1, n - p, tp);

	/* FIXME: Should use hgcd_reduce, but that may require more
	scratch space, which requires review. */

	nn = mpn_hgcd (ap + p, bp + p, n - p, &M1, tp + scratch);
	if (nn > 0)
	{
	/* We always have max(M) > 2^{-(GMP_NUMB_BITS + 1)} max(M1) */
	ASSERT (M->n + 2 >= M1.n);

	/* Furthermore, assume M ends with a quotient (1, q; 0, 1),
	then either q or q + 1 is a correct quotient, and M1 will
	start with either (1, 0; 1, 1) or (2, 1; 1, 1). This
	rules out the case that the size of M * M1 is much
	smaller than the expected M->n + M1->n. */

	ASSERT (M->n + M1.n < M->alloc);

	/* Needs 2 (p + M->n) <= 2 (2*s - n2 + 1 + n2 - s - 1)
	= 2s <= 2(floor(n/2) + 1) <= n + 2. */
	n = mpn_hgcd_matrix_adjust (&M1, p + nn, ap, bp, p, tp + scratch);

	/* We need a bound for of M->n + M1.n. Let n be the original
	input size. Then

	ceil(n/2) - 1 >= size of product >= M.n + M1.n - 2

	and it follows that

	M.n + M1.n <= ceil(n/2) + 1

	Then 3(M.n + M1.n) + 5 <= 3 ceil(n/2) + 8 is the
	amount of needed scratch space. */
	mpn_hgcd_matrix_mul (M, &M1, tp + scratch);
	success = 1;
	}
	}
	}

	for (;;)
	{
	/* Needs s+3 < n */
	nn = mpn_hgcd_step (n, ap, bp, s, M, tp);
	if (!nn)
	return success ? n : 0;

	n = nn;
	success = 1;
	}
	}