parted-1.8.7/libparted/cs/natmath.c - nest-learning-thermostat/5.1.1/parted - Git at Google

 /*
     libparted - a library for manipulating disk partitions
     Copyright (C) 2000, 2007 Free Software Foundation, Inc.

     This program is free software; you can redistribute it and/or modify
     it under the terms of 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.

     This program 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 a copy of the GNU General Public License
     along with this program; if not, write to the Free Software
     Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
 */

 /**
  * \file natmath.c
  */

 /**
  * \addtogroup PedAlignment
  *
  * \brief Alignment constraint model.
  *
  * This part of libparted models alignment constraints.
  *
  * @{
  */

 #include <config.h>
 #include <stdlib.h>
 #include <parted/parted.h>
 #include <parted/debug.h>
 #include <parted/natmath.h>

 /* Arrrghhh!  Why doesn't C have tuples? */
 typedef struct {
 	PedSector	gcd;		/* "converges" to the gcd */
 	PedSector	x;
 	PedSector	y;
 } EuclidTriple;

 static const PedAlignment _any = {
 	offset:		0,
 	grain_size:	1
 };

 const PedAlignment* ped_alignment_any = &_any;
 const PedAlignment* ped_alignment_none = NULL;

 /* This function returns "a mod b", the way C should have done it!
  * Mathematicians prefer -3 mod 4 to be 3.  Reason: division by N
  * is all about adding or subtracting N, and we like our remainders
  * to be between 0 and N - 1.
  */
 PedSector
 abs_mod (PedSector a, PedSector b)
 {
 	if (a < 0)
 		return a % b + b;
 	else
 		return a % b;
 }

 /* Rounds a number down to the closest number that is a multiple of
  * grain_size.
  */
 PedSector
 ped_round_down_to (PedSector sector, PedSector grain_size)
 {
 	return sector - abs_mod (sector, grain_size);
 }

 inline PedSector
 ped_div_round_up (PedSector numerator, PedSector divisor)
 {
                 return (numerator + divisor - 1) / divisor;
 }

 inline PedSector
 ped_div_round_to_nearest (PedSector numerator, PedSector divisor)
 {
                 return (numerator + divisor/2) / divisor;
 }

 /* Rounds a number up to the closest number that is a multiple of
  * grain_size.
  */
 PedSector
 ped_round_up_to (PedSector sector, PedSector grain_size)
 {
 	if (sector % grain_size)
 		return ped_round_down_to (sector, grain_size) + grain_size;
 	else
 		return sector;
 }

 /* Rounds a number to the closest number that is a multiple of grain_size. */
 PedSector
 ped_round_to_nearest (PedSector sector, PedSector grain_size)
 {
 	if (sector % grain_size > grain_size/2)
 		return ped_round_up_to (sector, grain_size);
 	else
 		return ped_round_down_to (sector, grain_size);
 }

 /* This function returns the largest number that divides both a and b.
  * It uses the ancient Euclidean algorithm.
  */
 PedSector
 ped_greatest_common_divisor (PedSector a, PedSector b)
 {
 	PED_ASSERT (a >= 0, return 0);
 	PED_ASSERT (b >= 0, return 0);

 	/* Put the arguments in the "right" format.  (Recursive calls made by
 	 * this function are always in the right format.)
 	 */
 	if (b > a)
 		return ped_greatest_common_divisor (b, a);

 	if (b)
 		return ped_greatest_common_divisor (b, a % b);
 	else
 		return a;
 }

 /**
  * Initialize a preallocated piece of memory for an alignment object
  * (used by PedConstraint).
  *
  * The object will represent all sectors \e s for which the equation
  * <tt>s = offset + X * grain_size</tt> holds.
  */
 int
 ped_alignment_init (PedAlignment* align, PedSector offset, PedSector grain_size)
 {
 	PED_ASSERT (align != NULL, return 0);

 	if (grain_size < 0)
 		return 0;

 	if (grain_size)
 		align->offset = abs_mod (offset, grain_size);
 	else
 		align->offset = offset;
 	align->grain_size = grain_size;

 	return 1;
 }

 /**
  * Return an alignment object (used by PedConstraint), representing all
  * PedSector's that are of the form <tt>offset + X * grain_size</tt>.
  */
 PedAlignment*
 ped_alignment_new (PedSector offset, PedSector grain_size)
 {
 	PedAlignment*	align;

 	align = (PedAlignment*) ped_malloc (sizeof (PedAlignment));
 	if (!align)
 		goto error;

 	if (!ped_alignment_init (align, offset, grain_size))
 		goto error_free_align;

 	return align;

 error_free_align:
 	ped_free (align);
 error:
 	return NULL;
 }

 /**
  * Free up memory associated with \p align.
  */
 void
 ped_alignment_destroy (PedAlignment* align)
 {
 	if (align)
 		ped_free (align);
 }

 /**
  * Return a duplicate of \p align.
  */
 PedAlignment*
 ped_alignment_duplicate (const PedAlignment* align)
 {
 	if (!align)
 		return NULL;
 	return ped_alignment_new (align->offset, align->grain_size);
 }

 /* the extended Euclid algorithm.
  *
  * input:
  * 	a and b, a > b
  *
  * output:
  * 	gcd, x and y, such that:
  *
  * 	gcd = greatest common divisor of a and b
  * 	gcd = x*a + y*b
  */
 EuclidTriple
 extended_euclid (int a, int b)
 {
 	EuclidTriple	result;
 	EuclidTriple	tmp;

 	if (b == 0) {
 		result.gcd = a;
 		result.x = 1;
 		result.y = 0;
 		return result;
 	}

 	tmp = extended_euclid (b, a % b);
 	result.gcd = tmp.gcd;
 	result.x = tmp.y;
 	result.y = tmp.x - (a/b) * tmp.y;
 	return result;
 }

 /**
  * This function computes a PedAlignment object that describes the
  * intersection of two alignments.  That is, a sector satisfies the
  * new alignment object if and only if it satisfies both of the original
  * ones.  (See ped_alignment_is_aligned() for the meaning of "satisfies")
  *
  * Apart from the trivial cases (where one or both of the alignment objects
  * constraints have no sectors that satisfy them), this is what we're trying to
  * do:
  *  - two input constraints: \p a and \p b.
  *  - the new grain_size is going to be the lowest common multiple of
  *  \p a->grain_size and \p b->grain_size
  *  - hard part - solve the simultaneous equations, for offset, where offset,
  *  X and Y are variables.  (Note: offset can be obtained from either X or Y,
  *  by substituing into either equation)
  *
  * \code
  *  	offset = \p a->offset + X * \p a->grain_size		(1)
  *  	offset = \p b->offset + Y * \p b->grain_size		(2)
  * \endcode
  *
  * or, abbreviated:
  *
  * \code
  *  	o = Ao + X*Ag		(1)
  *  	o = Bo + Y*Bg		(2)
  *
  *  =>	Ao + X*Ag    = Bo + Y*Bg     (1) = (2)
  *  	X*Ag - Y*Bg  = Bo - Ao  (3)
  * \endcode
  *
  * As it turns out, there only exists a solution if (Bo - Ao) is a multiple
  * of the GCD of Ag and Bg.  Reason: all linear combinations of Ag and Bg are
  * multiples of the GCD.
  *
  * Proof:
  *
  * \code
  *	A * Ag + B * Bg
  *	= A * (\p a * gcd) + B * (\p b * gcd)
  *	= gcd * (A * \p a + B * \p b)
  * \endcode
  *
  * gcd is a factor of the linear combination.  QED
  *
  * Anyway, \p a * Ag + \p b * Bg = gcd can be solved (for \p a, \p b and gcd)
  * with Euclid's extended algorithm.  Then, we just multiply through by
  * (Bo - Ao) / gcd to get (3).
  *
  * i.e.
  * \code
  * 	A * Ag + B * Bg				= gcd
  * 	A*(Bo-Ao)/gcd * Ag + B(Bo-Ao)/gcd * Bg	= gcd * (Bo-Ao)/gcd
  * 	X*Ag - Y*Bg				= Bo - Ao		(3)
  *
  * 	X = A*(Bo-Ao)/gcd
  * 	Y = - B*(Bo-Ao)/gcd
  * \endcode
  *
  * then:
  * \code
  *  	o = Ao + X*Ag			(1)
  *	  = Ao + A*(Bo-Ao)/gcd*Ag
  *  	o = Bo + Y*Bg			(2)
  *	  = Bo - B*(Bo-Ao)/gcd*Ag
  * \endcode
  *
  * Thanks go to Nathan Hurst (njh@hawthorn.csse.monash.edu.au) for figuring
  * this algorithm out :-)
  *
  * \note Returned \c NULL is a valid PedAlignment object, and can be used
 	for ped_alignment_*() function.
  *
  * \return a PedAlignment on success, \c NULL on failure
  */
 PedAlignment*
 ped_alignment_intersect (const PedAlignment* a, const PedAlignment* b)
 {
 	PedSector	new_grain_size;
 	PedSector	new_offset;
 	PedSector	delta_on_gcd;
 	EuclidTriple	gcd_factors;


 	if (!a || !b)
 		return NULL;

         /*PED_DEBUG (0x10, "intersecting alignments (%d,%d) and (%d,%d)",
                         a->offset, a->grain_size, b->offset, b->grain_size);
         */

 	if (a->grain_size < b->grain_size) {
 		const PedAlignment*	tmp;
 	        tmp = a; a = b; b = tmp;
 	}

 	/* weird/trivial case: where the solution space for "a" or "b" is
 	 * either empty or contains exactly one solution
 	 */
 	if (a->grain_size == 0 && b->grain_size == 0) {
 		if (a->offset == b->offset)
 			return ped_alignment_duplicate (a);
 		else
 			return NULL;
 	}

 	/* general case */
 	gcd_factors = extended_euclid (a->grain_size, b->grain_size);

 	delta_on_gcd = (b->offset - a->offset) / gcd_factors.gcd;
 	new_offset = a->offset + gcd_factors.x * delta_on_gcd * a->grain_size;
 	new_grain_size = a->grain_size * b->grain_size / gcd_factors.gcd;

 	/* inconsistency => no solution */
 	if (new_offset
 	    != b->offset - gcd_factors.y * delta_on_gcd * b->grain_size)
 		return NULL;

 	return ped_alignment_new (new_offset, new_grain_size);
 }

 /* This function returns the sector closest to "sector" that lies inside
  * geom and satisfies the alignment constraint.
  */
 static PedSector
 _closest_inside_geometry (const PedAlignment* align, const PedGeometry* geom,
 			  PedSector sector)
 {
 	PED_ASSERT (align != NULL, return -1);

 	if (!align->grain_size) {
 		if (ped_alignment_is_aligned (align, geom, sector)
 		    && (!geom || ped_geometry_test_sector_inside (geom,
 				    				  sector)))
 			return sector;
 		else
 			return -1;
 	}

 	if (sector < geom->start)
 		sector += ped_round_up_to (geom->start - sector,
 					   align->grain_size);
 	if (sector > geom->end)
 		sector -= ped_round_up_to (sector - geom->end,
 					   align->grain_size);

 	if (!ped_geometry_test_sector_inside (geom, sector))
 		return -1;
 	return sector;
 }

 /**
  * This function returns the closest sector to \p sector that lies inside
  * \p geom that satisfies the given alignment constraint \p align.  It prefers
  * sectors that are beyond \p sector (are not smaller than \p sector),
  * but does not guarantee that this.
  *
  * \return a PedSector on success, \c -1 on failure
  */
 PedSector
 ped_alignment_align_up (const PedAlignment* align, const PedGeometry* geom,
 			PedSector sector)
 {
 	PedSector	result;

 	PED_ASSERT (align != NULL, return -1);

 	if (!align->grain_size)
 		result = align->offset;
 	else
 		result = ped_round_up_to (sector - align->offset,
 			       		  align->grain_size)
 			 + align->offset;

 	if (geom)
 		result = _closest_inside_geometry (align, geom, result);
 	return result;
 }

 /**
  * This function returns the closest sector to \p sector that lies inside
  * \p geom that satisfies the given alignment constraint \p align.  It prefers
  * sectors that are before \p sector (are not larger than \p sector),
  * but does not guarantee that this.
  *
  * \return a PedSector on success, \c -1 on failure
  */
 PedSector
 ped_alignment_align_down (const PedAlignment* align, const PedGeometry* geom,
 			  PedSector sector)
 {
 	PedSector	result;

 	PED_ASSERT (align != NULL, return -1);

 	if (!align->grain_size)
 		result = align->offset;
 	else
 		result = ped_round_down_to (sector - align->offset,
 			      		    align->grain_size)
 			 + align->offset;

 	if (geom)
 		result = _closest_inside_geometry (align, geom, result);
 	return result;
 }

 /* Returns either a or b, depending on which is closest to "sector". */
 static PedSector
 closest (PedSector sector, PedSector a, PedSector b)
 {
 	if (a == -1)
 		return b;
 	if (b == -1)
 		return a;

 	if (abs (sector - a) < abs (sector - b))
 		return a;
 	else
 		return b;
 }

 /**
  * This function returns the sector that is closest to \p sector,
  * satisfies the \p align constraint and lies inside \p geom.
  *
  * \return a PedSector on success, \c -1 on failure
  */
 PedSector
 ped_alignment_align_nearest (const PedAlignment* align, const PedGeometry* geom,
 			     PedSector sector)
 {
 	PED_ASSERT (align != NULL, return -1);

 	return closest (sector, ped_alignment_align_up (align, geom, sector),
 			ped_alignment_align_down (align, geom, sector));
 }

 /**
  * This function returns 1 if \p sector satisfies the alignment
  * constraint \p align and lies inside \p geom.
  *
  * \return \c 1 on success, \c 0 on failure
  */
 int
 ped_alignment_is_aligned (const PedAlignment* align, const PedGeometry* geom,
 			  PedSector sector)
 {
 	if (!align)
 		return 0;

 	if (geom && !ped_geometry_test_sector_inside (geom, sector))
 		return 0;

 	if (align->grain_size)
 		return (sector - align->offset) % align->grain_size == 0;
 	else
 		return sector == align->offset;
 }

 /**
  * @}
  */
	/*
	libparted - a library for manipulating disk partitions
	Copyright (C) 2000, 2007 Free Software Foundation, Inc.

	This program is free software; you can redistribute it and/or modify
	it under the terms of 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.

	This program 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 a copy of the GNU General Public License
	along with this program; if not, write to the Free Software
	Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
	*/

	/**
	* \file natmath.c
	*/

	/**
	* \addtogroup PedAlignment
	*
	* \brief Alignment constraint model.
	*
	* This part of libparted models alignment constraints.
	*
	* @{
	*/

	#include <config.h>
	#include <stdlib.h>
	#include <parted/parted.h>
	#include <parted/debug.h>
	#include <parted/natmath.h>

	/* Arrrghhh! Why doesn't C have tuples? */
	typedef struct {
	PedSector gcd; /* "converges" to the gcd */
	PedSector x;
	PedSector y;
	} EuclidTriple;

	static const PedAlignment _any = {
	offset: 0,
	grain_size: 1
	};

	const PedAlignment* ped_alignment_any = &_any;
	const PedAlignment* ped_alignment_none = NULL;

	/* This function returns "a mod b", the way C should have done it!
	* Mathematicians prefer -3 mod 4 to be 3. Reason: division by N
	* is all about adding or subtracting N, and we like our remainders
	* to be between 0 and N - 1.
	*/
	PedSector
	abs_mod (PedSector a, PedSector b)
	{
	if (a < 0)
	return a % b + b;
	else
	return a % b;
	}

	/* Rounds a number down to the closest number that is a multiple of
	* grain_size.
	*/
	PedSector
	ped_round_down_to (PedSector sector, PedSector grain_size)
	{
	return sector - abs_mod (sector, grain_size);
	}

	inline PedSector
	ped_div_round_up (PedSector numerator, PedSector divisor)
	{
	return (numerator + divisor - 1) / divisor;
	}

	inline PedSector
	ped_div_round_to_nearest (PedSector numerator, PedSector divisor)
	{
	return (numerator + divisor/2) / divisor;
	}

	/* Rounds a number up to the closest number that is a multiple of
	* grain_size.
	*/
	PedSector
	ped_round_up_to (PedSector sector, PedSector grain_size)
	{
	if (sector % grain_size)
	return ped_round_down_to (sector, grain_size) + grain_size;
	else
	return sector;
	}

	/* Rounds a number to the closest number that is a multiple of grain_size. */
	PedSector
	ped_round_to_nearest (PedSector sector, PedSector grain_size)
	{
	if (sector % grain_size > grain_size/2)
	return ped_round_up_to (sector, grain_size);
	else
	return ped_round_down_to (sector, grain_size);
	}

	/* This function returns the largest number that divides both a and b.
	* It uses the ancient Euclidean algorithm.
	*/
	PedSector
	ped_greatest_common_divisor (PedSector a, PedSector b)
	{
	PED_ASSERT (a >= 0, return 0);
	PED_ASSERT (b >= 0, return 0);

	/* Put the arguments in the "right" format. (Recursive calls made by
	* this function are always in the right format.)
	*/
	if (b > a)
	return ped_greatest_common_divisor (b, a);

	if (b)
	return ped_greatest_common_divisor (b, a % b);
	else
	return a;
	}

	/**
	* Initialize a preallocated piece of memory for an alignment object
	* (used by PedConstraint).
	*
	* The object will represent all sectors \e s for which the equation
	* <tt>s = offset + X * grain_size</tt> holds.
	*/
	int
	ped_alignment_init (PedAlignment* align, PedSector offset, PedSector grain_size)
	{
	PED_ASSERT (align != NULL, return 0);

	if (grain_size < 0)
	return 0;

	if (grain_size)
	align->offset = abs_mod (offset, grain_size);
	else
	align->offset = offset;
	align->grain_size = grain_size;

	return 1;
	}

	/**
	* Return an alignment object (used by PedConstraint), representing all
	* PedSector's that are of the form <tt>offset + X * grain_size</tt>.
	*/
	PedAlignment*
	ped_alignment_new (PedSector offset, PedSector grain_size)
	{
	PedAlignment* align;

	align = (PedAlignment*) ped_malloc (sizeof (PedAlignment));
	if (!align)
	goto error;

	if (!ped_alignment_init (align, offset, grain_size))
	goto error_free_align;

	return align;

	error_free_align:
	ped_free (align);
	error:
	return NULL;
	}

	/**
	* Free up memory associated with \p align.
	*/
	void
	ped_alignment_destroy (PedAlignment* align)
	{
	if (align)
	ped_free (align);
	}

	/**
	* Return a duplicate of \p align.
	*/
	PedAlignment*
	ped_alignment_duplicate (const PedAlignment* align)
	{
	if (!align)
	return NULL;
	return ped_alignment_new (align->offset, align->grain_size);
	}

	/* the extended Euclid algorithm.
	*
	* input:
	* a and b, a > b
	*
	* output:
	* gcd, x and y, such that:
	*
	* gcd = greatest common divisor of a and b
	* gcd = xa + yb
	*/
	EuclidTriple
	extended_euclid (int a, int b)
	{
	EuclidTriple result;
	EuclidTriple tmp;

	if (b == 0) {
	result.gcd = a;
	result.x = 1;
	result.y = 0;
	return result;
	}

	tmp = extended_euclid (b, a % b);
	result.gcd = tmp.gcd;
	result.x = tmp.y;
	result.y = tmp.x - (a/b) * tmp.y;
	return result;
	}

	/**
	* This function computes a PedAlignment object that describes the
	* intersection of two alignments. That is, a sector satisfies the
	* new alignment object if and only if it satisfies both of the original
	* ones. (See ped_alignment_is_aligned() for the meaning of "satisfies")
	*
	* Apart from the trivial cases (where one or both of the alignment objects
	* constraints have no sectors that satisfy them), this is what we're trying to
	* do:
	* - two input constraints: \p a and \p b.
	* - the new grain_size is going to be the lowest common multiple of
	* \p a->grain_size and \p b->grain_size
	* - hard part - solve the simultaneous equations, for offset, where offset,
	* X and Y are variables. (Note: offset can be obtained from either X or Y,
	* by substituing into either equation)
	*
	* \code
	* offset = \p a->offset + X * \p a->grain_size (1)
	* offset = \p b->offset + Y * \p b->grain_size (2)
	* \endcode
	*
	* or, abbreviated:
	*
	* \code
	* o = Ao + X*Ag (1)
	* o = Bo + Y*Bg (2)
	*
	* => Ao + XAg = Bo + YBg (1) = (2)
	* XAg - YBg = Bo - Ao (3)
	* \endcode
	*
	* As it turns out, there only exists a solution if (Bo - Ao) is a multiple
	* of the GCD of Ag and Bg. Reason: all linear combinations of Ag and Bg are
	* multiples of the GCD.
	*
	* Proof:
	*
	* \code
	* A * Ag + B * Bg
	* = A * (\p a * gcd) + B * (\p b * gcd)
	* = gcd * (A * \p a + B * \p b)
	* \endcode
	*
	* gcd is a factor of the linear combination. QED
	*
	* Anyway, \p a * Ag + \p b * Bg = gcd can be solved (for \p a, \p b and gcd)
	* with Euclid's extended algorithm. Then, we just multiply through by
	* (Bo - Ao) / gcd to get (3).
	*
	* i.e.
	* \code
	* A * Ag + B * Bg = gcd
	* A(Bo-Ao)/gcd Ag + B(Bo-Ao)/gcd * Bg = gcd * (Bo-Ao)/gcd
	* XAg - YBg = Bo - Ao (3)
	*
	* X = A*(Bo-Ao)/gcd
	* Y = - B*(Bo-Ao)/gcd
	* \endcode
	*
	* then:
	* \code
	* o = Ao + X*Ag (1)
	* = Ao + A(Bo-Ao)/gcdAg
	* o = Bo + Y*Bg (2)
	* = Bo - B(Bo-Ao)/gcdAg
	* \endcode
	*
	* Thanks go to Nathan Hurst (njh@hawthorn.csse.monash.edu.au) for figuring
	* this algorithm out :-)
	*
	* \note Returned \c NULL is a valid PedAlignment object, and can be used
	for ped_alignment_*() function.
	*
	* \return a PedAlignment on success, \c NULL on failure
	*/
	PedAlignment*
	ped_alignment_intersect (const PedAlignment* a, const PedAlignment* b)
	{
	PedSector new_grain_size;
	PedSector new_offset;
	PedSector delta_on_gcd;
	EuclidTriple gcd_factors;


	if (!a \|\| !b)
	return NULL;

	/*PED_DEBUG (0x10, "intersecting alignments (%d,%d) and (%d,%d)",
	a->offset, a->grain_size, b->offset, b->grain_size);
	*/

	if (a->grain_size < b->grain_size) {
	const PedAlignment* tmp;
	tmp = a; a = b; b = tmp;
	}

	/* weird/trivial case: where the solution space for "a" or "b" is
	* either empty or contains exactly one solution
	*/
	if (a->grain_size == 0 && b->grain_size == 0) {
	if (a->offset == b->offset)
	return ped_alignment_duplicate (a);
	else
	return NULL;
	}

	/* general case */
	gcd_factors = extended_euclid (a->grain_size, b->grain_size);

	delta_on_gcd = (b->offset - a->offset) / gcd_factors.gcd;
	new_offset = a->offset + gcd_factors.x * delta_on_gcd * a->grain_size;
	new_grain_size = a->grain_size * b->grain_size / gcd_factors.gcd;

	/* inconsistency => no solution */
	if (new_offset
	!= b->offset - gcd_factors.y * delta_on_gcd * b->grain_size)
	return NULL;

	return ped_alignment_new (new_offset, new_grain_size);
	}

	/* This function returns the sector closest to "sector" that lies inside
	* geom and satisfies the alignment constraint.
	*/
	static PedSector
	_closest_inside_geometry (const PedAlignment* align, const PedGeometry* geom,
	PedSector sector)
	{
	PED_ASSERT (align != NULL, return -1);

	if (!align->grain_size) {
	if (ped_alignment_is_aligned (align, geom, sector)
	&& (!geom \|\| ped_geometry_test_sector_inside (geom,
	sector)))
	return sector;
	else
	return -1;
	}

	if (sector < geom->start)
	sector += ped_round_up_to (geom->start - sector,
	align->grain_size);
	if (sector > geom->end)
	sector -= ped_round_up_to (sector - geom->end,
	align->grain_size);

	if (!ped_geometry_test_sector_inside (geom, sector))
	return -1;
	return sector;
	}

	/**
	* This function returns the closest sector to \p sector that lies inside
	* \p geom that satisfies the given alignment constraint \p align. It prefers
	* sectors that are beyond \p sector (are not smaller than \p sector),
	* but does not guarantee that this.
	*
	* \return a PedSector on success, \c -1 on failure
	*/
	PedSector
	ped_alignment_align_up (const PedAlignment* align, const PedGeometry* geom,
	PedSector sector)
	{
	PedSector result;

	PED_ASSERT (align != NULL, return -1);

	if (!align->grain_size)
	result = align->offset;
	else
	result = ped_round_up_to (sector - align->offset,
	align->grain_size)
	+ align->offset;

	if (geom)
	result = _closest_inside_geometry (align, geom, result);
	return result;
	}

	/**
	* This function returns the closest sector to \p sector that lies inside
	* \p geom that satisfies the given alignment constraint \p align. It prefers
	* sectors that are before \p sector (are not larger than \p sector),
	* but does not guarantee that this.
	*
	* \return a PedSector on success, \c -1 on failure
	*/
	PedSector
	ped_alignment_align_down (const PedAlignment* align, const PedGeometry* geom,
	PedSector sector)
	{
	PedSector result;

	PED_ASSERT (align != NULL, return -1);

	if (!align->grain_size)
	result = align->offset;
	else
	result = ped_round_down_to (sector - align->offset,
	align->grain_size)
	+ align->offset;

	if (geom)
	result = _closest_inside_geometry (align, geom, result);
	return result;
	}

	/* Returns either a or b, depending on which is closest to "sector". */
	static PedSector
	closest (PedSector sector, PedSector a, PedSector b)
	{
	if (a == -1)
	return b;
	if (b == -1)
	return a;

	if (abs (sector - a) < abs (sector - b))
	return a;
	else
	return b;
	}

	/**
	* This function returns the sector that is closest to \p sector,
	* satisfies the \p align constraint and lies inside \p geom.
	*
	* \return a PedSector on success, \c -1 on failure
	*/
	PedSector
	ped_alignment_align_nearest (const PedAlignment* align, const PedGeometry* geom,
	PedSector sector)
	{
	PED_ASSERT (align != NULL, return -1);

	return closest (sector, ped_alignment_align_up (align, geom, sector),
	ped_alignment_align_down (align, geom, sector));
	}

	/**
	* This function returns 1 if \p sector satisfies the alignment
	* constraint \p align and lies inside \p geom.
	*
	* \return \c 1 on success, \c 0 on failure
	*/
	int
	ped_alignment_is_aligned (const PedAlignment* align, const PedGeometry* geom,
	PedSector sector)
	{
	if (!align)
	return 0;

	if (geom && !ped_geometry_test_sector_inside (geom, sector))
	return 0;

	if (align->grain_size)
	return (sector - align->offset) % align->grain_size == 0;
	else
	return sector == align->offset;
	}

	/**
	* @}
	*/