Modules/_decimal/libmpdec/basearith.h - platform/external/python/cpython3 - Git at Google

 /*
  * Copyright (c) 2008-2020 Stefan Krah. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  *
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS "AS IS" AND
  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */


 #ifndef LIBMPDEC_BASEARITH_H_
 #define LIBMPDEC_BASEARITH_H_


 #include "mpdecimal.h"
 #include "typearith.h"


 /* Internal header file: all symbols have local scope in the DSO */
 MPD_PRAGMA(MPD_HIDE_SYMBOLS_START)


 mpd_uint_t _mpd_baseadd(mpd_uint_t *w, const mpd_uint_t *u, const mpd_uint_t *v,
                         mpd_size_t m, mpd_size_t n);
 void _mpd_baseaddto(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n);
 mpd_uint_t _mpd_shortadd(mpd_uint_t *w, mpd_size_t m, mpd_uint_t v);
 mpd_uint_t _mpd_shortadd_b(mpd_uint_t *w, mpd_size_t m, mpd_uint_t v,
                            mpd_uint_t b);
 mpd_uint_t _mpd_baseincr(mpd_uint_t *u, mpd_size_t n);
 void _mpd_basesub(mpd_uint_t *w, const mpd_uint_t *u, const mpd_uint_t *v,
                   mpd_size_t m, mpd_size_t n);
 void _mpd_basesubfrom(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n);
 void _mpd_basemul(mpd_uint_t *w, const mpd_uint_t *u, const mpd_uint_t *v,
                   mpd_size_t m, mpd_size_t n);
 void _mpd_shortmul(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n,
                    mpd_uint_t v);
 mpd_uint_t _mpd_shortmul_c(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n,
                            mpd_uint_t v);
 mpd_uint_t _mpd_shortmul_b(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n,
                            mpd_uint_t v, mpd_uint_t b);
 mpd_uint_t _mpd_shortdiv(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n,
                          mpd_uint_t v);
 mpd_uint_t _mpd_shortdiv_b(mpd_uint_t *w, const mpd_uint_t *u, mpd_size_t n,
                            mpd_uint_t v, mpd_uint_t b);
 int _mpd_basedivmod(mpd_uint_t *q, mpd_uint_t *r, const mpd_uint_t *uconst,
                     const mpd_uint_t *vconst, mpd_size_t nplusm, mpd_size_t n);
 void _mpd_baseshiftl(mpd_uint_t *dest, mpd_uint_t *src, mpd_size_t n,
                      mpd_size_t m, mpd_size_t shift);
 mpd_uint_t _mpd_baseshiftr(mpd_uint_t *dest, mpd_uint_t *src, mpd_size_t slen,
                            mpd_size_t shift);


 #ifdef CONFIG_64
 extern const mpd_uint_t mprime_rdx;

 /*
  * Algorithm from: Division by Invariant Integers using Multiplication,
  * T. Granlund and P. L. Montgomery, Proceedings of the SIGPLAN '94
  * Conference on Programming Language Design and Implementation.
  *
  * http://gmplib.org/~tege/divcnst-pldi94.pdf
  *
  * Variables from the paper and their translations (See section 8):
  *
  *  N := 64
  *  d := MPD_RADIX
  *  l := 64
  *  m' := floor((2**(64+64) - 1)/MPD_RADIX) - 2**64
  *
  * Since N-l == 0:
  *
  *  dnorm := d
  *  n2 := hi
  *  n10 := lo
  *
  * ACL2 proof: mpd-div-words-r-correct
  */
 static inline void
 _mpd_div_words_r(mpd_uint_t *q, mpd_uint_t *r, mpd_uint_t hi, mpd_uint_t lo)
 {
     mpd_uint_t n_adj, h, l, t;
     mpd_uint_t n1_neg;

     /* n1_neg = if lo >= 2**63 then MPD_UINT_MAX else 0 */
     n1_neg = (lo & (1ULL<<63)) ? MPD_UINT_MAX : 0;
     /* n_adj = if lo >= 2**63 then lo+MPD_RADIX else lo */
     n_adj = lo + (n1_neg & MPD_RADIX);

     /* (h, l) = if lo >= 2**63 then m'*(hi+1) else m'*hi */
     _mpd_mul_words(&h, &l, mprime_rdx, hi-n1_neg);
     l = l + n_adj;
     if (l < n_adj) h++;
     t = h + hi;
     /* At this point t == qest, with q == qest or q == qest+1:
      *   1) 0 <= 2**64*hi + lo - qest*MPD_RADIX < 2*MPD_RADIX
      */

     /* t = 2**64-1 - qest = 2**64 - (qest+1) */
     t = MPD_UINT_MAX - t;

     /* (h, l) = 2**64*MPD_RADIX - (qest+1)*MPD_RADIX */
     _mpd_mul_words(&h, &l, t, MPD_RADIX);
     l = l + lo;
     if (l < lo) h++;
     h += hi;
     h -= MPD_RADIX;
     /* (h, l) = 2**64*hi + lo - (qest+1)*MPD_RADIX (mod 2**128)
      * Case q == qest+1:
      *     a) h == 0, l == r
      *     b) q := h - t == qest+1
      *     c) r := l
      * Case q == qest:
      *     a) h == MPD_UINT_MAX, l == 2**64-(MPD_RADIX-r)
      *     b) q := h - t == qest
      *     c) r := l + MPD_RADIX = r
      */

     *q = (h - t);
     *r = l + (MPD_RADIX & h);
 }
 #else
 static inline void
 _mpd_div_words_r(mpd_uint_t *q, mpd_uint_t *r, mpd_uint_t hi, mpd_uint_t lo)
 {
     _mpd_div_words(q, r, hi, lo, MPD_RADIX);
 }
 #endif


 /* Multiply two single base MPD_RADIX words, store result in array w[2]. */
 static inline void
 _mpd_singlemul(mpd_uint_t w[2], mpd_uint_t u, mpd_uint_t v)
 {
     mpd_uint_t hi, lo;

     _mpd_mul_words(&hi, &lo, u, v);
     _mpd_div_words_r(&w[1], &w[0], hi, lo);
 }

 /* Multiply u (len 2) and v (len m, 1 <= m <= 2). */
 static inline void
 _mpd_mul_2_le2(mpd_uint_t w[4], mpd_uint_t u[2], mpd_uint_t v[2], mpd_ssize_t m)
 {
     mpd_uint_t hi, lo;

     _mpd_mul_words(&hi, &lo, u[0], v[0]);
     _mpd_div_words_r(&w[1], &w[0], hi, lo);

     _mpd_mul_words(&hi, &lo, u[1], v[0]);
     lo = w[1] + lo;
     if (lo < w[1]) hi++;
     _mpd_div_words_r(&w[2], &w[1], hi, lo);
     if (m == 1) return;

     _mpd_mul_words(&hi, &lo, u[0], v[1]);
     lo = w[1] + lo;
     if (lo < w[1]) hi++;
     _mpd_div_words_r(&w[3], &w[1], hi, lo);

     _mpd_mul_words(&hi, &lo, u[1], v[1]);
     lo = w[2] + lo;
     if (lo < w[2]) hi++;
     lo = w[3] + lo;
     if (lo < w[3]) hi++;
     _mpd_div_words_r(&w[3], &w[2], hi, lo);
 }


 /*
  * Test if all words from data[len-1] to data[0] are zero. If len is 0, nothing
  * is tested and the coefficient is regarded as "all zero".
  */
 static inline int
 _mpd_isallzero(const mpd_uint_t *data, mpd_ssize_t len)
 {
     while (--len >= 0) {
         if (data[len] != 0) return 0;
     }
     return 1;
 }

 /*
  * Test if all full words from data[len-1] to data[0] are MPD_RADIX-1
  * (all nines). Return true if len == 0.
  */
 static inline int
 _mpd_isallnine(const mpd_uint_t *data, mpd_ssize_t len)
 {
     while (--len >= 0) {
         if (data[len] != MPD_RADIX-1) return 0;
     }
     return 1;
 }


 MPD_PRAGMA(MPD_HIDE_SYMBOLS_END) /* restore previous scope rules */


 #endif /* LIBMPDEC_BASEARITH_H_ */
	/*
	* Copyright (c) 2008-2020 Stefan Krah. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	*
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	*
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS "AS IS" AND
	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
	* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
	* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
	* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/


	#ifndef LIBMPDEC_BASEARITH_H_
	#define LIBMPDEC_BASEARITH_H_


	#include "mpdecimal.h"
	#include "typearith.h"


	/* Internal header file: all symbols have local scope in the DSO */
	MPD_PRAGMA(MPD_HIDE_SYMBOLS_START)


	mpd_uint_t _mpd_baseadd(mpd_uint_t w, const mpd_uint_t u, const mpd_uint_t *v,
	mpd_size_t m, mpd_size_t n);
	void _mpd_baseaddto(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n);
	mpd_uint_t _mpd_shortadd(mpd_uint_t *w, mpd_size_t m, mpd_uint_t v);
	mpd_uint_t _mpd_shortadd_b(mpd_uint_t *w, mpd_size_t m, mpd_uint_t v,
	mpd_uint_t b);
	mpd_uint_t _mpd_baseincr(mpd_uint_t *u, mpd_size_t n);
	void _mpd_basesub(mpd_uint_t w, const mpd_uint_t u, const mpd_uint_t *v,
	mpd_size_t m, mpd_size_t n);
	void _mpd_basesubfrom(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n);
	void _mpd_basemul(mpd_uint_t w, const mpd_uint_t u, const mpd_uint_t *v,
	mpd_size_t m, mpd_size_t n);
	void _mpd_shortmul(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n,
	mpd_uint_t v);
	mpd_uint_t _mpd_shortmul_c(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n,
	mpd_uint_t v);
	mpd_uint_t _mpd_shortmul_b(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n,
	mpd_uint_t v, mpd_uint_t b);
	mpd_uint_t _mpd_shortdiv(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n,
	mpd_uint_t v);
	mpd_uint_t _mpd_shortdiv_b(mpd_uint_t w, const mpd_uint_t u, mpd_size_t n,
	mpd_uint_t v, mpd_uint_t b);
	int _mpd_basedivmod(mpd_uint_t q, mpd_uint_t r, const mpd_uint_t *uconst,
	const mpd_uint_t *vconst, mpd_size_t nplusm, mpd_size_t n);
	void _mpd_baseshiftl(mpd_uint_t dest, mpd_uint_t src, mpd_size_t n,
	mpd_size_t m, mpd_size_t shift);
	mpd_uint_t _mpd_baseshiftr(mpd_uint_t dest, mpd_uint_t src, mpd_size_t slen,
	mpd_size_t shift);



	#ifdef CONFIG_64
	extern const mpd_uint_t mprime_rdx;

	/*
	* Algorithm from: Division by Invariant Integers using Multiplication,
	* T. Granlund and P. L. Montgomery, Proceedings of the SIGPLAN '94
	* Conference on Programming Language Design and Implementation.
	*
	* http://gmplib.org/~tege/divcnst-pldi94.pdf
	*
	* Variables from the paper and their translations (See section 8):
	*
	* N := 64
	* d := MPD_RADIX
	* l := 64
	* m' := floor((2(64+64) - 1)/MPD_RADIX) - 264
	*
	* Since N-l == 0:
	*
	* dnorm := d
	* n2 := hi
	* n10 := lo
	*
	* ACL2 proof: mpd-div-words-r-correct
	*/
	static inline void
	_mpd_div_words_r(mpd_uint_t q, mpd_uint_t r, mpd_uint_t hi, mpd_uint_t lo)
	{
	mpd_uint_t n_adj, h, l, t;
	mpd_uint_t n1_neg;

	/* n1_neg = if lo >= 2*63 then MPD_UINT_MAX else 0 /
	n1_neg = (lo & (1ULL<<63)) ? MPD_UINT_MAX : 0;
	/* n_adj = if lo >= 2*63 then lo+MPD_RADIX else lo /
	n_adj = lo + (n1_neg & MPD_RADIX);

	/* (h, l) = if lo >= 2*63 then m'(hi+1) else m'hi /
	_mpd_mul_words(&h, &l, mprime_rdx, hi-n1_neg);
	l = l + n_adj;
	if (l < n_adj) h++;
	t = h + hi;
	/* At this point t == qest, with q == qest or q == qest+1:
	* 1) 0 <= 2*64hi + lo - qestMPD_RADIX < 2MPD_RADIX
	*/

	/* t = 264-1 - qest = 264 - (qest+1) */
	t = MPD_UINT_MAX - t;

	/* (h, l) = 2*64MPD_RADIX - (qest+1)MPD_RADIX /
	_mpd_mul_words(&h, &l, t, MPD_RADIX);
	l = l + lo;
	if (l < lo) h++;
	h += hi;
	h -= MPD_RADIX;
	/* (h, l) = 2*64hi + lo - (qest+1)MPD_RADIX (mod 2*128)
	* Case q == qest+1:
	* a) h == 0, l == r
	* b) q := h - t == qest+1
	* c) r := l
	* Case q == qest:
	* a) h == MPD_UINT_MAX, l == 2**64-(MPD_RADIX-r)
	* b) q := h - t == qest
	* c) r := l + MPD_RADIX = r
	*/

	*q = (h - t);
	*r = l + (MPD_RADIX & h);
	}
	#else
	static inline void
	_mpd_div_words_r(mpd_uint_t q, mpd_uint_t r, mpd_uint_t hi, mpd_uint_t lo)
	{
	_mpd_div_words(q, r, hi, lo, MPD_RADIX);
	}
	#endif


	/* Multiply two single base MPD_RADIX words, store result in array w[2]. */
	static inline void
	_mpd_singlemul(mpd_uint_t w[2], mpd_uint_t u, mpd_uint_t v)
	{
	mpd_uint_t hi, lo;

	_mpd_mul_words(&hi, &lo, u, v);
	_mpd_div_words_r(&w[1], &w[0], hi, lo);
	}

	/* Multiply u (len 2) and v (len m, 1 <= m <= 2). */
	static inline void
	_mpd_mul_2_le2(mpd_uint_t w[4], mpd_uint_t u[2], mpd_uint_t v[2], mpd_ssize_t m)
	{
	mpd_uint_t hi, lo;

	_mpd_mul_words(&hi, &lo, u[0], v[0]);
	_mpd_div_words_r(&w[1], &w[0], hi, lo);

	_mpd_mul_words(&hi, &lo, u[1], v[0]);
	lo = w[1] + lo;
	if (lo < w[1]) hi++;
	_mpd_div_words_r(&w[2], &w[1], hi, lo);
	if (m == 1) return;

	_mpd_mul_words(&hi, &lo, u[0], v[1]);
	lo = w[1] + lo;
	if (lo < w[1]) hi++;
	_mpd_div_words_r(&w[3], &w[1], hi, lo);

	_mpd_mul_words(&hi, &lo, u[1], v[1]);
	lo = w[2] + lo;
	if (lo < w[2]) hi++;
	lo = w[3] + lo;
	if (lo < w[3]) hi++;
	_mpd_div_words_r(&w[3], &w[2], hi, lo);
	}


	/*
	* Test if all words from data[len-1] to data[0] are zero. If len is 0, nothing
	* is tested and the coefficient is regarded as "all zero".
	*/
	static inline int
	_mpd_isallzero(const mpd_uint_t *data, mpd_ssize_t len)
	{
	while (--len >= 0) {
	if (data[len] != 0) return 0;
	}
	return 1;
	}

	/*
	* Test if all full words from data[len-1] to data[0] are MPD_RADIX-1
	* (all nines). Return true if len == 0.
	*/
	static inline int
	_mpd_isallnine(const mpd_uint_t *data, mpd_ssize_t len)
	{
	while (--len >= 0) {
	if (data[len] != MPD_RADIX-1) return 0;
	}
	return 1;
	}


	MPD_PRAGMA(MPD_HIDE_SYMBOLS_END) /* restore previous scope rules */


	#endif /* LIBMPDEC_BASEARITH_H_ */