lib/math/rational.c - linux/kernel/git/torvalds/linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * rational fractions
  *
  * Copyright (C) 2009 emlix GmbH, Oskar Schirmer <oskar@scara.com>
  * Copyright (C) 2019 Trent Piepho <tpiepho@gmail.com>
  *
  * helper functions when coping with rational numbers
  */

 #include <linux/rational.h>
 #include <linux/compiler.h>
 #include <linux/export.h>
 #include <linux/kernel.h>

 /*
  * calculate best rational approximation for a given fraction
  * taking into account restricted register size, e.g. to find
  * appropriate values for a pll with 5 bit denominator and
  * 8 bit numerator register fields, trying to set up with a
  * frequency ratio of 3.1415, one would say:
  *
  * rational_best_approximation(31415, 10000,
  *		(1 << 8) - 1, (1 << 5) - 1, &n, &d);
  *
  * you may look at given_numerator as a fixed point number,
  * with the fractional part size described in given_denominator.
  *
  * for theoretical background, see:
  * http://en.wikipedia.org/wiki/Continued_fraction
  */

 void rational_best_approximation(
 	unsigned long given_numerator, unsigned long given_denominator,
 	unsigned long max_numerator, unsigned long max_denominator,
 	unsigned long *best_numerator, unsigned long *best_denominator)
 {
 	/* n/d is the starting rational, which is continually
 	 * decreased each iteration using the Euclidean algorithm.
 	 *
 	 * dp is the value of d from the prior iteration.
 	 *
 	 * n2/d2, n1/d1, and n0/d0 are our successively more accurate
 	 * approximations of the rational.  They are, respectively,
 	 * the current, previous, and two prior iterations of it.
 	 *
 	 * a is current term of the continued fraction.
 	 */
 	unsigned long n, d, n0, d0, n1, d1, n2, d2;
 	n = given_numerator;
 	d = given_denominator;
 	n0 = d1 = 0;
 	n1 = d0 = 1;

 	for (;;) {
 		unsigned long dp, a;

 		if (d == 0)
 			break;
 		/* Find next term in continued fraction, 'a', via
 		 * Euclidean algorithm.
 		 */
 		dp = d;
 		a = n / d;
 		d = n % d;
 		n = dp;

 		/* Calculate the current rational approximation (aka
 		 * convergent), n2/d2, using the term just found and
 		 * the two prior approximations.
 		 */
 		n2 = n0 + a * n1;
 		d2 = d0 + a * d1;

 		/* If the current convergent exceeds the maxes, then
 		 * return either the previous convergent or the
 		 * largest semi-convergent, the final term of which is
 		 * found below as 't'.
 		 */
 		if ((n2 > max_numerator) || (d2 > max_denominator)) {
 			unsigned long t = min((max_numerator - n0) / n1,
 					      (max_denominator - d0) / d1);

 			/* This tests if the semi-convergent is closer
 			 * than the previous convergent.
 			 */
 			if (2u * t > a || (2u * t == a && d0 * dp > d1 * d)) {
 				n1 = n0 + t * n1;
 				d1 = d0 + t * d1;
 			}
 			break;
 		}
 		n0 = n1;
 		n1 = n2;
 		d0 = d1;
 		d1 = d2;
 	}
 	*best_numerator = n1;
 	*best_denominator = d1;
 }

 EXPORT_SYMBOL(rational_best_approximation);
	// SPDX-License-Identifier: GPL-2.0
	/*
	* rational fractions
	*
	* Copyright (C) 2009 emlix GmbH, Oskar Schirmer <oskar@scara.com>
	* Copyright (C) 2019 Trent Piepho <tpiepho@gmail.com>
	*
	* helper functions when coping with rational numbers
	*/

	#include <linux/rational.h>
	#include <linux/compiler.h>
	#include <linux/export.h>
	#include <linux/kernel.h>

	/*
	* calculate best rational approximation for a given fraction
	* taking into account restricted register size, e.g. to find
	* appropriate values for a pll with 5 bit denominator and
	* 8 bit numerator register fields, trying to set up with a
	* frequency ratio of 3.1415, one would say:
	*
	* rational_best_approximation(31415, 10000,
	* (1 << 8) - 1, (1 << 5) - 1, &n, &d);
	*
	* you may look at given_numerator as a fixed point number,
	* with the fractional part size described in given_denominator.
	*
	* for theoretical background, see:
	* http://en.wikipedia.org/wiki/Continued_fraction
	*/

	void rational_best_approximation(
	unsigned long given_numerator, unsigned long given_denominator,
	unsigned long max_numerator, unsigned long max_denominator,
	unsigned long best_numerator, unsigned long best_denominator)
	{
	/* n/d is the starting rational, which is continually
	* decreased each iteration using the Euclidean algorithm.
	*
	* dp is the value of d from the prior iteration.
	*
	* n2/d2, n1/d1, and n0/d0 are our successively more accurate
	* approximations of the rational. They are, respectively,
	* the current, previous, and two prior iterations of it.
	*
	* a is current term of the continued fraction.
	*/
	unsigned long n, d, n0, d0, n1, d1, n2, d2;
	n = given_numerator;
	d = given_denominator;
	n0 = d1 = 0;
	n1 = d0 = 1;

	for (;;) {
	unsigned long dp, a;

	if (d == 0)
	break;
	/* Find next term in continued fraction, 'a', via
	* Euclidean algorithm.
	*/
	dp = d;
	a = n / d;
	d = n % d;
	n = dp;

	/* Calculate the current rational approximation (aka
	* convergent), n2/d2, using the term just found and
	* the two prior approximations.
	*/
	n2 = n0 + a * n1;
	d2 = d0 + a * d1;

	/* If the current convergent exceeds the maxes, then
	* return either the previous convergent or the
	* largest semi-convergent, the final term of which is
	* found below as 't'.
	*/
	if ((n2 > max_numerator) \|\| (d2 > max_denominator)) {
	unsigned long t = min((max_numerator - n0) / n1,
	(max_denominator - d0) / d1);

	/* This tests if the semi-convergent is closer
	* than the previous convergent.
	*/
	if (2u * t > a \|\| (2u * t == a && d0 * dp > d1 * d)) {
	n1 = n0 + t * n1;
	d1 = d0 + t * d1;
	}
	break;
	}
	n0 = n1;
	n1 = n2;
	d0 = d1;
	d1 = d2;
	}
	*best_numerator = n1;
	*best_denominator = d1;
	}

	EXPORT_SYMBOL(rational_best_approximation);