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

 /*
     libparted - a library for manipulating disk partitions
     Copyright (C) 2000, 2001, 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
 */

 /**
  * \addtogroup PedConstraint
  *
  * \brief Constraint solver interface.
  *
  * Constraints are used to communicate restrictions on operations Constraints
  * are restrictions on the location and alignment of the start and end of a
  * partition, and the minimum and maximum size.
  *
  * Constraints are closed under intersection (for the proof see the source
  * code).  For background information see the Chinese Remainder Theorem.
  *
  * This interface consists of construction constraints, finding the intersection
  * of constraints, and finding solutions to constraints.
  *
  * The constraint solver allows you to specify constraints on where a partition
  * or file system (or any PedGeometry) may be placed/resized/etc. For example,
  * you might want to make sure that a file system is at least 10 Gb, or that it
  * starts at the beginning of new cylinder.
  *
  * The constraint solver in this file unifies solver in geom.c (which allows you
  * to specify constraints on ranges) and natmath.c (which allows you to specify
  * alignment constraints).
  *
  * @{
  */

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

 /**
  * Initializes a pre-allocated piece of memory to contain a constraint
  * with the supplied default values.
  *
  * \return \c 0 on failure.
  */
 int
 ped_constraint_init (
 	PedConstraint* constraint,
 	const PedAlignment* start_align,
 	const PedAlignment* end_align,
 	const PedGeometry* start_range,
 	const PedGeometry* end_range,
 	PedSector min_size,
 	PedSector max_size)
 {
 	PED_ASSERT (constraint != NULL, return 0);
 	PED_ASSERT (start_range != NULL, return 0);
 	PED_ASSERT (end_range != NULL, return 0);
 	PED_ASSERT (min_size > 0, return 0);
 	PED_ASSERT (max_size > 0, return 0);

 	constraint->start_align = ped_alignment_duplicate (start_align);
 	constraint->end_align = ped_alignment_duplicate (end_align);
 	constraint->start_range = ped_geometry_duplicate (start_range);
 	constraint->end_range = ped_geometry_duplicate (end_range);
 	constraint->min_size = min_size;
 	constraint->max_size = max_size;

 	return 1;
 }

 /**
  * Convenience wrapper for ped_constraint_init().
  *
  * Allocates a new piece of memory and initializes the constraint.
  *
  * \return \c NULL on failure.
  */
 PedConstraint*
 ped_constraint_new (
 	const PedAlignment* start_align,
 	const PedAlignment* end_align,
 	const PedGeometry* start_range,
 	const PedGeometry* end_range,
 	PedSector min_size,
 	PedSector max_size)
 {
 	PedConstraint*	constraint;

 	constraint = (PedConstraint*) ped_malloc (sizeof (PedConstraint));
 	if (!constraint)
 		goto error;
 	if (!ped_constraint_init (constraint, start_align, end_align,
 			          start_range, end_range, min_size, max_size))
 		goto error_free_constraint;
 	return constraint;

 error_free_constraint:
 	ped_free (constraint);
 error:
 	return NULL;
 }

 /**
  * Return a constraint that requires a region to be entirely contained inside
  * \p max, and to entirely contain \p min.
  *
  * \return \c NULL on failure.
  */
 PedConstraint*
 ped_constraint_new_from_min_max (
 	const PedGeometry* min,
 	const PedGeometry* max)
 {
 	PedGeometry	start_range;
 	PedGeometry	end_range;

 	PED_ASSERT (min != NULL, return NULL);
 	PED_ASSERT (max != NULL, return NULL);
 	PED_ASSERT (ped_geometry_test_inside (max, min), return NULL);

 	ped_geometry_init (&start_range, min->dev, max->start,
 			   min->start - max->start + 1);
 	ped_geometry_init (&end_range, min->dev, min->end,
 			   max->end - min->end + 1);

 	return ped_constraint_new (
 			ped_alignment_any, ped_alignment_any,
 			&start_range, &end_range,
 			min->length, max->length);
 }

 /**
  * Return a constraint that requires a region to entirely contain \p min.
  *
  * \return \c NULL on failure.
  */
 PedConstraint*
 ped_constraint_new_from_min (const PedGeometry* min)
 {
 	PedGeometry	full_dev;

 	PED_ASSERT (min != NULL, return NULL);

 	ped_geometry_init (&full_dev, min->dev, 0, min->dev->length);
 	return ped_constraint_new_from_min_max (min, &full_dev);
 }

 /**
  * Return a constraint that requires a region to be entirely contained inside
  * \p max.
  *
  * \return \c NULL on failure.
  */
 PedConstraint*
 ped_constraint_new_from_max (const PedGeometry* max)
 {
 	PED_ASSERT (max != NULL, return NULL);

 	return ped_constraint_new (
 			ped_alignment_any, ped_alignment_any,
 			max, max, 1, max->length);
 }

 /**
  * Duplicate a constraint.
  *
  * \return \c NULL on failure.
  */
 PedConstraint*
 ped_constraint_duplicate (const PedConstraint* constraint)
 {
 	PED_ASSERT (constraint != NULL, return NULL);

 	return ped_constraint_new (
 		constraint->start_align,
 		constraint->end_align,
 		constraint->start_range,
 		constraint->end_range,
 		constraint->min_size,
 		constraint->max_size);
 }

 /**
  * Return a constraint that requires a region to satisfy both \p a and \p b.
  *
  * Moreover, any region satisfying \p a and \p b will also satisfy the returned
  * constraint.
  *
  * \return \c NULL if no solution could be found (note that \c NULL is a valid
  *         PedConstraint).
  */
 PedConstraint*
 ped_constraint_intersect (const PedConstraint* a, const PedConstraint* b)
 {
 	PedAlignment*	start_align;
 	PedAlignment*	end_align;
 	PedGeometry*	start_range;
 	PedGeometry*	end_range;
 	PedSector	min_size;
 	PedSector	max_size;
 	PedConstraint*	constraint;

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

 	start_align = ped_alignment_intersect (a->start_align, b->start_align);
 	if (!start_align)
 		goto empty;
 	end_align = ped_alignment_intersect (a->end_align, b->end_align);
 	if (!end_align)
 		goto empty_destroy_start_align;
 	start_range = ped_geometry_intersect (a->start_range, b->start_range);
 	if (!start_range)
 		goto empty_destroy_end_align;
 	end_range = ped_geometry_intersect (a->end_range, b->end_range);
 	if (!end_range)
 		goto empty_destroy_start_range;
 	min_size = PED_MAX (a->min_size, b->min_size);
 	max_size = PED_MIN (a->max_size, b->max_size);

 	constraint = ped_constraint_new (
 			start_align, end_align, start_range, end_range,
 			min_size, max_size);
 	if (!constraint)
 		goto empty_destroy_end_range;

 	ped_alignment_destroy (start_align);
 	ped_alignment_destroy (end_align);
 	ped_geometry_destroy (start_range);
 	ped_geometry_destroy (end_range);
 	return constraint;

 empty_destroy_end_range:
 	ped_geometry_destroy (end_range);
 empty_destroy_start_range:
 	ped_geometry_destroy (start_range);
 empty_destroy_end_align:
 	ped_alignment_destroy (end_align);
 empty_destroy_start_align:
 	ped_alignment_destroy (start_align);
 empty:
 	return NULL;
 }

 /**
  * Release the memory allocated for a PedConstraint constructed with
  * ped_constraint_init().
  */
 void
 ped_constraint_done (PedConstraint* constraint)
 {
 	PED_ASSERT (constraint != NULL, return);

 	ped_alignment_destroy (constraint->start_align);
 	ped_alignment_destroy (constraint->end_align);
 	ped_geometry_destroy (constraint->start_range);
 	ped_geometry_destroy (constraint->end_range);
 }

 /**
  * Release the memory allocated for a PedConstraint constructed with
  * ped_constraint_new().
  */
 void
 ped_constraint_destroy (PedConstraint* constraint)
 {
 	if (constraint) {
 		ped_constraint_done (constraint);
 		ped_free (constraint);
 	}
 }

 /*
  * Return the region within which the start must lie
  * in order to satisfy a constriant.  It takes into account
  * constraint->start_range, constraint->min_size and constraint->max_size.
  * All sectors in this range that also satisfy alignment requirements have
  * an end, such that the (start, end) satisfy the constraint.
  */
 static PedGeometry*
 _constraint_get_canonical_start_range (const PedConstraint* constraint)
 {
 	PedSector	first_end_soln;
 	PedSector	last_end_soln;
 	PedSector	min_start;
 	PedSector	max_start;
 	PedGeometry	start_min_max_range;

 	if (constraint->min_size > constraint->max_size)
 		return NULL;

 	first_end_soln = ped_alignment_align_down (
 			constraint->end_align, constraint->end_range,
 			constraint->end_range->start);
 	last_end_soln = ped_alignment_align_up (
 			constraint->end_align, constraint->end_range,
 			constraint->end_range->end);
 	if (first_end_soln == -1 || last_end_soln == -1
 	    || first_end_soln > last_end_soln
 	    || last_end_soln < constraint->min_size)
 		return NULL;

 	min_start = first_end_soln - constraint->max_size + 1;
 	if (min_start < 0)
 		min_start = 0;
 	max_start = last_end_soln - constraint->min_size + 1;
 	if (max_start < 0)
 		return NULL;

 	ped_geometry_init (
 		&start_min_max_range, constraint->start_range->dev,
 		min_start, max_start - min_start + 1);

 	return ped_geometry_intersect (&start_min_max_range,
 				       constraint->start_range);
 }

 /*
  * Return the nearest start that will have at least one other end that
  * together satisfy the constraint.
  */
 static PedSector
 _constraint_get_nearest_start_soln (const PedConstraint* constraint,
 				    PedSector start)
 {
 	PedGeometry*	start_range;
 	PedSector	result;

 	start_range = _constraint_get_canonical_start_range (constraint);
 	if (!start_range)
 		return -1;
 	result = ped_alignment_align_nearest (
 			constraint->start_align, start_range, start);
 	ped_geometry_destroy (start_range);
 	return result;
 }

 /*
  * Given a constraint and a start ("half of the solution"), find the
  * range of all possible ends, such that all (start, end) are solutions
  * to constraint (subject to additional alignment requirements).
  */
 static PedGeometry*
 _constraint_get_end_range (const PedConstraint* constraint, PedSector start)
 {
 	PedDevice*	dev = constraint->end_range->dev;
 	PedSector	first_min_max_end;
 	PedSector	last_min_max_end;
 	PedGeometry	end_min_max_range;

 	if (start + constraint->min_size - 1 > dev->length - 1)
 		return NULL;

 	first_min_max_end = start + constraint->min_size - 1;
 	last_min_max_end = start + constraint->max_size - 1;
 	if (last_min_max_end > dev->length - 1)
 		last_min_max_end = dev->length - 1;

 	ped_geometry_init (&end_min_max_range, dev,
 			   first_min_max_end,
 			   last_min_max_end - first_min_max_end + 1);

 	return ped_geometry_intersect (&end_min_max_range,
 		       		       constraint->end_range);
 }

 /*
  * Given "constraint" and "start", find the end that is nearest to
  * "end", such that ("start", the end) together form a solution to
  * "constraint".
  */
 static PedSector
 _constraint_get_nearest_end_soln (const PedConstraint* constraint,
 				  PedSector start, PedSector end)
 {
 	PedGeometry*	end_range;
 	PedSector	result;

 	end_range = _constraint_get_end_range (constraint, start);
 	if (!end_range)
 		return -1;

 	result = ped_alignment_align_nearest (constraint->end_align, end_range,
 		       			      end);
 	ped_geometry_destroy (end_range);
 	return result;
 }

 /**
  * Return the nearest region to \p geom that satisfy a \p constraint.
  *
  * Note that "nearest" is somewhat ambiguous.  This function makes
  * no guarantees about how this ambiguity is resovled.
  *
  * \return PedGeometry, or NULL when a \p constrain cannot be satisfied
  */
 PedGeometry*
 ped_constraint_solve_nearest (
 	const PedConstraint* constraint, const PedGeometry* geom)
 {
 	PedSector	start;
 	PedSector	end;
 	PedGeometry*	result;

 	if (constraint == NULL)
 		return NULL;

 	PED_ASSERT (geom != NULL, return NULL);
 	PED_ASSERT (constraint->start_range->dev == geom->dev, return NULL);

 	start = _constraint_get_nearest_start_soln (constraint, geom->start);
 	if (start == -1)
 		return NULL;
 	end = _constraint_get_nearest_end_soln (constraint, start, geom->end);
 	if (end == -1)
 		return NULL;

 	result = ped_geometry_new (geom->dev, start, end - start + 1);
 	if (!result)
 		return NULL;
 	PED_ASSERT (ped_constraint_is_solution (constraint, result),
 		    return NULL);
 	return result;
 }

 /**
  * Find the largest region that satisfies a constraint.
  *
  * There might be more than one solution.  This function makes no
  * guarantees about which solution it will choose in this case.
  */
 PedGeometry*
 ped_constraint_solve_max (const PedConstraint* constraint)
 {
 	PedDevice*	dev;
 	PedGeometry	full_dev;

 	if (!constraint)
 		return NULL;
 	dev = constraint->start_range->dev;
 	ped_geometry_init (&full_dev, dev, 0, dev->length - 1);
 	return ped_constraint_solve_nearest (constraint, &full_dev);
 }

 /**
  * Check whether \p geom satisfies the given constraint.
  *
  * \return \c 1 if it does.
  **/
 int
 ped_constraint_is_solution (const PedConstraint* constraint,
 	       		    const PedGeometry* geom)
 {
 	PED_ASSERT (constraint != NULL, return 0);
 	PED_ASSERT (geom != NULL, return 0);

 	if (!ped_alignment_is_aligned (constraint->start_align, NULL,
 				       geom->start))
 		return 0;
 	if (!ped_alignment_is_aligned (constraint->end_align, NULL, geom->end))
 		return 0;
 	if (!ped_geometry_test_sector_inside (constraint->start_range,
 					      geom->start))
 		return 0;
 	if (!ped_geometry_test_sector_inside (constraint->end_range, geom->end))
 		return 0;
 	if (geom->length < constraint->min_size)
 		return 0;
 	if (geom->length > constraint->max_size)
 		return 0;
 	return 1;
 }

 /**
  * Return a constraint that any region on the given device will satisfy.
  */
 PedConstraint*
 ped_constraint_any (const PedDevice* dev)
 {
 	PedGeometry	full_dev;

 	if (!ped_geometry_init (&full_dev, dev, 0, dev->length))
 		return NULL;

 	return ped_constraint_new (
 			ped_alignment_any,
 		       	ped_alignment_any,
 			&full_dev,
 			&full_dev,
 		       	1,
 			dev->length);
 }

 /**
  * Return a constraint that only the given region will satisfy.
  */
 PedConstraint*
 ped_constraint_exact (const PedGeometry* geom)
 {
 	PedAlignment	start_align;
 	PedAlignment	end_align;
 	PedGeometry	start_sector;
 	PedGeometry	end_sector;

 	ped_alignment_init (&start_align, geom->start, 0);
 	ped_alignment_init (&end_align, geom->end, 0);
 	ped_geometry_init (&start_sector, geom->dev, geom->start, 1);
 	ped_geometry_init (&end_sector, geom->dev, geom->end, 1);

 	return ped_constraint_new (&start_align, &end_align,
 				   &start_sector, &end_sector, 1,
 				   geom->dev->length);
 }

 /**
  * @}
  */
	/*
	libparted - a library for manipulating disk partitions
	Copyright (C) 2000, 2001, 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
	*/

	/**
	* \addtogroup PedConstraint
	*
	* \brief Constraint solver interface.
	*
	* Constraints are used to communicate restrictions on operations Constraints
	* are restrictions on the location and alignment of the start and end of a
	* partition, and the minimum and maximum size.
	*
	* Constraints are closed under intersection (for the proof see the source
	* code). For background information see the Chinese Remainder Theorem.
	*
	* This interface consists of construction constraints, finding the intersection
	* of constraints, and finding solutions to constraints.
	*
	* The constraint solver allows you to specify constraints on where a partition
	* or file system (or any PedGeometry) may be placed/resized/etc. For example,
	* you might want to make sure that a file system is at least 10 Gb, or that it
	* starts at the beginning of new cylinder.
	*
	* The constraint solver in this file unifies solver in geom.c (which allows you
	* to specify constraints on ranges) and natmath.c (which allows you to specify
	* alignment constraints).
	*
	* @{
	*/

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

	/**
	* Initializes a pre-allocated piece of memory to contain a constraint
	* with the supplied default values.
	*
	* \return \c 0 on failure.
	*/
	int
	ped_constraint_init (
	PedConstraint* constraint,
	const PedAlignment* start_align,
	const PedAlignment* end_align,
	const PedGeometry* start_range,
	const PedGeometry* end_range,
	PedSector min_size,
	PedSector max_size)
	{
	PED_ASSERT (constraint != NULL, return 0);
	PED_ASSERT (start_range != NULL, return 0);
	PED_ASSERT (end_range != NULL, return 0);
	PED_ASSERT (min_size > 0, return 0);
	PED_ASSERT (max_size > 0, return 0);

	constraint->start_align = ped_alignment_duplicate (start_align);
	constraint->end_align = ped_alignment_duplicate (end_align);
	constraint->start_range = ped_geometry_duplicate (start_range);
	constraint->end_range = ped_geometry_duplicate (end_range);
	constraint->min_size = min_size;
	constraint->max_size = max_size;

	return 1;
	}

	/**
	* Convenience wrapper for ped_constraint_init().
	*
	* Allocates a new piece of memory and initializes the constraint.
	*
	* \return \c NULL on failure.
	*/
	PedConstraint*
	ped_constraint_new (
	const PedAlignment* start_align,
	const PedAlignment* end_align,
	const PedGeometry* start_range,
	const PedGeometry* end_range,
	PedSector min_size,
	PedSector max_size)
	{
	PedConstraint* constraint;

	constraint = (PedConstraint*) ped_malloc (sizeof (PedConstraint));
	if (!constraint)
	goto error;
	if (!ped_constraint_init (constraint, start_align, end_align,
	start_range, end_range, min_size, max_size))
	goto error_free_constraint;
	return constraint;

	error_free_constraint:
	ped_free (constraint);
	error:
	return NULL;
	}

	/**
	* Return a constraint that requires a region to be entirely contained inside
	* \p max, and to entirely contain \p min.
	*
	* \return \c NULL on failure.
	*/
	PedConstraint*
	ped_constraint_new_from_min_max (
	const PedGeometry* min,
	const PedGeometry* max)
	{
	PedGeometry start_range;
	PedGeometry end_range;

	PED_ASSERT (min != NULL, return NULL);
	PED_ASSERT (max != NULL, return NULL);
	PED_ASSERT (ped_geometry_test_inside (max, min), return NULL);

	ped_geometry_init (&start_range, min->dev, max->start,
	min->start - max->start + 1);
	ped_geometry_init (&end_range, min->dev, min->end,
	max->end - min->end + 1);

	return ped_constraint_new (
	ped_alignment_any, ped_alignment_any,
	&start_range, &end_range,
	min->length, max->length);
	}

	/**
	* Return a constraint that requires a region to entirely contain \p min.
	*
	* \return \c NULL on failure.
	*/
	PedConstraint*
	ped_constraint_new_from_min (const PedGeometry* min)
	{
	PedGeometry full_dev;

	PED_ASSERT (min != NULL, return NULL);

	ped_geometry_init (&full_dev, min->dev, 0, min->dev->length);
	return ped_constraint_new_from_min_max (min, &full_dev);
	}

	/**
	* Return a constraint that requires a region to be entirely contained inside
	* \p max.
	*
	* \return \c NULL on failure.
	*/
	PedConstraint*
	ped_constraint_new_from_max (const PedGeometry* max)
	{
	PED_ASSERT (max != NULL, return NULL);

	return ped_constraint_new (
	ped_alignment_any, ped_alignment_any,
	max, max, 1, max->length);
	}

	/**
	* Duplicate a constraint.
	*
	* \return \c NULL on failure.
	*/
	PedConstraint*
	ped_constraint_duplicate (const PedConstraint* constraint)
	{
	PED_ASSERT (constraint != NULL, return NULL);

	return ped_constraint_new (
	constraint->start_align,
	constraint->end_align,
	constraint->start_range,
	constraint->end_range,
	constraint->min_size,
	constraint->max_size);
	}

	/**
	* Return a constraint that requires a region to satisfy both \p a and \p b.
	*
	* Moreover, any region satisfying \p a and \p b will also satisfy the returned
	* constraint.
	*
	* \return \c NULL if no solution could be found (note that \c NULL is a valid
	* PedConstraint).
	*/
	PedConstraint*
	ped_constraint_intersect (const PedConstraint* a, const PedConstraint* b)
	{
	PedAlignment* start_align;
	PedAlignment* end_align;
	PedGeometry* start_range;
	PedGeometry* end_range;
	PedSector min_size;
	PedSector max_size;
	PedConstraint* constraint;

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

	start_align = ped_alignment_intersect (a->start_align, b->start_align);
	if (!start_align)
	goto empty;
	end_align = ped_alignment_intersect (a->end_align, b->end_align);
	if (!end_align)
	goto empty_destroy_start_align;
	start_range = ped_geometry_intersect (a->start_range, b->start_range);
	if (!start_range)
	goto empty_destroy_end_align;
	end_range = ped_geometry_intersect (a->end_range, b->end_range);
	if (!end_range)
	goto empty_destroy_start_range;
	min_size = PED_MAX (a->min_size, b->min_size);
	max_size = PED_MIN (a->max_size, b->max_size);

	constraint = ped_constraint_new (
	start_align, end_align, start_range, end_range,
	min_size, max_size);
	if (!constraint)
	goto empty_destroy_end_range;

	ped_alignment_destroy (start_align);
	ped_alignment_destroy (end_align);
	ped_geometry_destroy (start_range);
	ped_geometry_destroy (end_range);
	return constraint;

	empty_destroy_end_range:
	ped_geometry_destroy (end_range);
	empty_destroy_start_range:
	ped_geometry_destroy (start_range);
	empty_destroy_end_align:
	ped_alignment_destroy (end_align);
	empty_destroy_start_align:
	ped_alignment_destroy (start_align);
	empty:
	return NULL;
	}

	/**
	* Release the memory allocated for a PedConstraint constructed with
	* ped_constraint_init().
	*/
	void
	ped_constraint_done (PedConstraint* constraint)
	{
	PED_ASSERT (constraint != NULL, return);

	ped_alignment_destroy (constraint->start_align);
	ped_alignment_destroy (constraint->end_align);
	ped_geometry_destroy (constraint->start_range);
	ped_geometry_destroy (constraint->end_range);
	}

	/**
	* Release the memory allocated for a PedConstraint constructed with
	* ped_constraint_new().
	*/
	void
	ped_constraint_destroy (PedConstraint* constraint)
	{
	if (constraint) {
	ped_constraint_done (constraint);
	ped_free (constraint);
	}
	}

	/*
	* Return the region within which the start must lie
	* in order to satisfy a constriant. It takes into account
	* constraint->start_range, constraint->min_size and constraint->max_size.
	* All sectors in this range that also satisfy alignment requirements have
	* an end, such that the (start, end) satisfy the constraint.
	*/
	static PedGeometry*
	_constraint_get_canonical_start_range (const PedConstraint* constraint)
	{
	PedSector first_end_soln;
	PedSector last_end_soln;
	PedSector min_start;
	PedSector max_start;
	PedGeometry start_min_max_range;

	if (constraint->min_size > constraint->max_size)
	return NULL;

	first_end_soln = ped_alignment_align_down (
	constraint->end_align, constraint->end_range,
	constraint->end_range->start);
	last_end_soln = ped_alignment_align_up (
	constraint->end_align, constraint->end_range,
	constraint->end_range->end);
	if (first_end_soln == -1 \|\| last_end_soln == -1
	\|\| first_end_soln > last_end_soln
	\|\| last_end_soln < constraint->min_size)
	return NULL;

	min_start = first_end_soln - constraint->max_size + 1;
	if (min_start < 0)
	min_start = 0;
	max_start = last_end_soln - constraint->min_size + 1;
	if (max_start < 0)
	return NULL;

	ped_geometry_init (
	&start_min_max_range, constraint->start_range->dev,
	min_start, max_start - min_start + 1);

	return ped_geometry_intersect (&start_min_max_range,
	constraint->start_range);
	}

	/*
	* Return the nearest start that will have at least one other end that
	* together satisfy the constraint.
	*/
	static PedSector
	_constraint_get_nearest_start_soln (const PedConstraint* constraint,
	PedSector start)
	{
	PedGeometry* start_range;
	PedSector result;

	start_range = _constraint_get_canonical_start_range (constraint);
	if (!start_range)
	return -1;
	result = ped_alignment_align_nearest (
	constraint->start_align, start_range, start);
	ped_geometry_destroy (start_range);
	return result;
	}

	/*
	* Given a constraint and a start ("half of the solution"), find the
	* range of all possible ends, such that all (start, end) are solutions
	* to constraint (subject to additional alignment requirements).
	*/
	static PedGeometry*
	_constraint_get_end_range (const PedConstraint* constraint, PedSector start)
	{
	PedDevice* dev = constraint->end_range->dev;
	PedSector first_min_max_end;
	PedSector last_min_max_end;
	PedGeometry end_min_max_range;

	if (start + constraint->min_size - 1 > dev->length - 1)
	return NULL;

	first_min_max_end = start + constraint->min_size - 1;
	last_min_max_end = start + constraint->max_size - 1;
	if (last_min_max_end > dev->length - 1)
	last_min_max_end = dev->length - 1;

	ped_geometry_init (&end_min_max_range, dev,
	first_min_max_end,
	last_min_max_end - first_min_max_end + 1);

	return ped_geometry_intersect (&end_min_max_range,
	constraint->end_range);
	}

	/*
	* Given "constraint" and "start", find the end that is nearest to
	* "end", such that ("start", the end) together form a solution to
	* "constraint".
	*/
	static PedSector
	_constraint_get_nearest_end_soln (const PedConstraint* constraint,
	PedSector start, PedSector end)
	{
	PedGeometry* end_range;
	PedSector result;

	end_range = _constraint_get_end_range (constraint, start);
	if (!end_range)
	return -1;

	result = ped_alignment_align_nearest (constraint->end_align, end_range,
	end);
	ped_geometry_destroy (end_range);
	return result;
	}

	/**
	* Return the nearest region to \p geom that satisfy a \p constraint.
	*
	* Note that "nearest" is somewhat ambiguous. This function makes
	* no guarantees about how this ambiguity is resovled.
	*
	* \return PedGeometry, or NULL when a \p constrain cannot be satisfied
	*/
	PedGeometry*
	ped_constraint_solve_nearest (
	const PedConstraint* constraint, const PedGeometry* geom)
	{
	PedSector start;
	PedSector end;
	PedGeometry* result;

	if (constraint == NULL)
	return NULL;

	PED_ASSERT (geom != NULL, return NULL);
	PED_ASSERT (constraint->start_range->dev == geom->dev, return NULL);

	start = _constraint_get_nearest_start_soln (constraint, geom->start);
	if (start == -1)
	return NULL;
	end = _constraint_get_nearest_end_soln (constraint, start, geom->end);
	if (end == -1)
	return NULL;

	result = ped_geometry_new (geom->dev, start, end - start + 1);
	if (!result)
	return NULL;
	PED_ASSERT (ped_constraint_is_solution (constraint, result),
	return NULL);
	return result;
	}

	/**
	* Find the largest region that satisfies a constraint.
	*
	* There might be more than one solution. This function makes no
	* guarantees about which solution it will choose in this case.
	*/
	PedGeometry*
	ped_constraint_solve_max (const PedConstraint* constraint)
	{
	PedDevice* dev;
	PedGeometry full_dev;

	if (!constraint)
	return NULL;
	dev = constraint->start_range->dev;
	ped_geometry_init (&full_dev, dev, 0, dev->length - 1);
	return ped_constraint_solve_nearest (constraint, &full_dev);
	}

	/**
	* Check whether \p geom satisfies the given constraint.
	*
	* \return \c 1 if it does.
	**/
	int
	ped_constraint_is_solution (const PedConstraint* constraint,
	const PedGeometry* geom)
	{
	PED_ASSERT (constraint != NULL, return 0);
	PED_ASSERT (geom != NULL, return 0);

	if (!ped_alignment_is_aligned (constraint->start_align, NULL,
	geom->start))
	return 0;
	if (!ped_alignment_is_aligned (constraint->end_align, NULL, geom->end))
	return 0;
	if (!ped_geometry_test_sector_inside (constraint->start_range,
	geom->start))
	return 0;
	if (!ped_geometry_test_sector_inside (constraint->end_range, geom->end))
	return 0;
	if (geom->length < constraint->min_size)
	return 0;
	if (geom->length > constraint->max_size)
	return 0;
	return 1;
	}

	/**
	* Return a constraint that any region on the given device will satisfy.
	*/
	PedConstraint*
	ped_constraint_any (const PedDevice* dev)
	{
	PedGeometry full_dev;

	if (!ped_geometry_init (&full_dev, dev, 0, dev->length))
	return NULL;

	return ped_constraint_new (
	ped_alignment_any,
	ped_alignment_any,
	&full_dev,
	&full_dev,
	1,
	dev->length);
	}

	/**
	* Return a constraint that only the given region will satisfy.
	*/
	PedConstraint*
	ped_constraint_exact (const PedGeometry* geom)
	{
	PedAlignment start_align;
	PedAlignment end_align;
	PedGeometry start_sector;
	PedGeometry end_sector;

	ped_alignment_init (&start_align, geom->start, 0);
	ped_alignment_init (&end_align, geom->end, 0);
	ped_geometry_init (&start_sector, geom->dev, geom->start, 1);
	ped_geometry_init (&end_sector, geom->dev, geom->end, 1);

	return ped_constraint_new (&start_align, &end_align,
	&start_sector, &end_sector, 1,
	geom->dev->length);
	}

	/**
	* @}
	*/