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/*
* Main authors:
* Guido Tack <tack@gecode.org>
* Christian Schulte <schulte@gecode.org>
*
* Contributing authors:
* Gabor Szokoli <szokoli@gecode.org>
*
* Copyright:
* Guido Tack, 2004
* Christian Schulte, 2004
* Gabor Szokoli, 2004
*
* Last modified:
* $Date: 2013-07-23 14:31:03 +0200 (Tue, 23 Jul 2013) $ by $Author: schulte $
* $Revision: 13939 $
*
* This file is part of Gecode, the generic constraint
* development environment:
* http://www.gecode.org
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
* LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
*/
#ifndef __GECODE_SET_HH__
#define __GECODE_SET_HH__
#include <gecode/kernel.hh>
#include <gecode/int.hh>
#include <gecode/iter.hh>
/*
* Configure linking
*
*/
#if !defined(GECODE_STATIC_LIBS) && \
(defined(__CYGWIN__) || defined(__MINGW32__) || defined(_MSC_VER))
#ifdef GECODE_BUILD_SET
#define GECODE_SET_EXPORT __declspec( dllexport )
#else
#define GECODE_SET_EXPORT __declspec( dllimport )
#endif
#else
#ifdef GECODE_GCC_HAS_CLASS_VISIBILITY
#define GECODE_SET_EXPORT __attribute__ ((visibility("default")))
#else
#define GECODE_SET_EXPORT
#endif
#endif
// Configure auto-linking
#ifndef GECODE_BUILD_SET
#define GECODE_LIBRARY_NAME "Set"
#include <gecode/support/auto-link.hpp>
#endif
/**
* \namespace Gecode::Set
* \brief Finite integer sets
*
* The Gecode::Set namespace contains all functionality required
* to program propagators and branchers for finite integer sets.
* In addition, all propagators and branchers for finite integer
* sets provided by %Gecode are contained as nested namespaces.
*
*/
#include <gecode/set/exception.hpp>
namespace Gecode { namespace Set {
/// Numerical limits for set variables
namespace Limits {
/// Largest allowed integer in integer set
const int max = (Gecode::Int::Limits::max / 2) - 1;
/// Smallest allowed integer in integer set
const int min = -max;
/// Maximum cardinality of an integer set
const unsigned int card = max-min+1;
/// Check whether integer \a n is in range, otherwise throw overflow exception with information \a l
void check(int n, const char* l);
/// Check whether unsigned int \a n is in range for cardinality, otherwise throw overflow exception with information \a l
void check(unsigned int n, const char* l);
/// Check whether minimum and maximum of IntSet \a s is in range, otherwise throw overflow exception with information \a l
void check(const IntSet& s, const char* l);
}
}}
#include <gecode/set/limits.hpp>
#include <gecode/set/var-imp.hpp>
namespace Gecode {
namespace Set {
class SetView;
}
/**
* \brief %Set variables
*
* \ingroup TaskModelSetVars
*/
class SetVar : public VarImpVar<Set::SetVarImp> {
friend class SetVarArray;
friend class SetVarArgs;
using VarImpVar<Set::SetVarImp>::x;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVar(void);
/// Initialize from set variable \a y
SetVar(const SetVar& y);
/// Initialize from set view \a y
SetVar(const Set::SetView& y);
/// Initialize variable with empty greatest lower and full least upper bound
GECODE_SET_EXPORT SetVar(Space& home);
/**
* \brief Initialize variable with given bounds and cardinality
*
* The variable is created with
* greatest lower bound \f$\{\mathit{glbMin},\dots,\mathit{glbMax}\}\f$,
* least upper bound \f$\{\mathit{lubMin},\dots,\mathit{lubMax}\}\f$, and
* cardinality minimum \a cardMin and maximum \a cardMax.
* The following exceptions might be thrown:
* - If the bounds are no legal set bounds (between Set::Limits::min
* and Set::Limits::max), an exception of type
* Gecode::Set::OutOfLimits is thrown.
* - If the cardinality is greater than Set::Limits::max_set_size, an
* exception of type Gecode::Set::OutOfLimits is
* thrown.
* - If \a cardMin > \a cardMax, an exception of type
* Gecode::Set::VariableEmptyDomain is thrown.
*/
GECODE_SET_EXPORT
SetVar(Space& home,int glbMin,int glbMax,int lubMin,int lubMax,
unsigned int cardMin = 0,
unsigned int cardMax = Set::Limits::card);
/**
* \brief Initialize variable with given bounds and cardinality
*
* The variable is created with greatest lower bound \a glbD,
* least upper bound \f$\{\mathit{lubMin},\dots,\mathit{lubMax}\}\f$, and
* cardinality minimum \a cardMin and maximum \a cardMax.
* The following exceptions might be thrown:
* - If the bounds are no legal set bounds (between Set::Limits::min
* and Set::Limits::max), an exception of type
* Gecode::Set::OutOfLimits is thrown.
* - If the cardinality is greater than Set::Limits::max_set_size, an
* exception of type Gecode::Set::OutOfLimits is
* thrown.
* - If \a cardMin > \a cardMax, an exception of type
* Gecode::Set::VariableEmptyDomain is thrown.
*/
GECODE_SET_EXPORT
SetVar(Space& home,const IntSet& glbD,int lubMin,int lubMax,
unsigned int cardMin = 0,
unsigned int cardMax = Set::Limits::card);
/**
* \brief Initialize variable with given bounds and cardinality
*
* The variable is created with
* greatest lower bound \f$\{\mathit{glbMin},\dots,\mathit{glbMax}\}\f$,
* least upper bound \a lubD, and
* cardinality minimum \a cardMin and maximum \a cardMax.
* The following exceptions might be thrown:
* - If the bounds are no legal set bounds (between Set::Limits::min
* and Set::Limits::max), an exception of type
* Gecode::Set::OutOfLimits is thrown.
* - If the cardinality is greater than Set::Limits::max_set_size, an
* exception of type Gecode::Set::OutOfLimits is
* thrown.
* - If \a minCard > \a maxCard, an exception of type
* Gecode::Set::VariableEmptyDomain is thrown.
*/
GECODE_SET_EXPORT
SetVar(Space& home,int glbMin,int glbMax,const IntSet& lubD,
unsigned int cardMin = 0,
unsigned int cardMax = Set::Limits::card);
/**
* \brief Initialize variable with given bounds and cardinality
*
* The variable is created with
* greatest lower bound \a glbD,
* least upper bound \a lubD, and
* cardinality minimum \a cardMin and maximum \a cardMax.
* The following exceptions might be thrown:
* - If the bounds are no legal set bounds (between Set::Limits::min
* and Set::Limits::max), an exception of type
* Gecode::Set::OutOfLimits is thrown.
* - If the cardinality is greater than Set::Limits::max_set_size, an
* exception of type Gecode::Set::OutOfLimits is
* thrown.
* - If \a minCard > \a maxCard, an exception of type
* Gecode::Set::VariableEmptyDomain is thrown.
*/
GECODE_SET_EXPORT
SetVar(Space& home,const IntSet& glbD,const IntSet& lubD,
unsigned int cardMin = 0,
unsigned int cardMax = Set::Limits::card);
//@}
/// \name Value access
//@{
/// Return number of elements in the greatest lower bound
unsigned int glbSize(void) const;
/// Return number of elements in the least upper bound
unsigned int lubSize(void) const;
/// Return number of unknown elements (elements in lub but not in glb)
unsigned int unknownSize(void) const;
/// Return cardinality minimum
unsigned int cardMin(void) const;
/// Return cardinality maximum
unsigned int cardMax(void) const;
/// Return minimum element of least upper bound
int lubMin(void) const;
/// Return maximum element of least upper bound
int lubMax(void) const;
/// Return minimum element of greatest lower bound
int glbMin(void) const;
/// Return maximum of greatest lower bound
int glbMax(void) const;
//@}
/// \name Domain tests
//@{
/// Test whether \a i is in greatest lower bound
bool contains(int i) const;
/// Test whether \a i is not in the least upper bound
bool notContains(int i) const;
//@}
};
/**
* \defgroup TaskModelSetIter Range and value iterators for set variables
* \ingroup TaskModelSet
*/
//@{
/// Iterator for the greatest lower bound ranges of a set variable
class SetVarGlbRanges {
private:
Set::GlbRanges<Set::SetVarImp*> iter;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVarGlbRanges(void);
/// Initialize to iterate ranges of variable \a x
SetVarGlbRanges(const SetVar& x);
//@}
/// \name Iteration control
//@{
/// Test whether iterator is still at a range or done
bool operator ()(void) const;
/// Move iterator to next range (if possible)
void operator ++(void);
//@}
/// \name Range access
//@{
/// Return smallest value of range
int min(void) const;
/// Return largest value of range
int max(void) const;
/// Return width of range (distance between minimum and maximum)
unsigned int width(void) const;
//@}
};
/// Iterator for the least upper bound ranges of a set variable
class SetVarLubRanges {
private:
Set::LubRanges<Set::SetVarImp*> iter;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVarLubRanges(void);
/// Initialize to iterate ranges of variable \a x
SetVarLubRanges(const SetVar& x);
//@}
/// \name Iteration control
//@{
/// Test whether iterator is still at a range or done
bool operator ()(void) const;
/// Move iterator to next range (if possible)
void operator ++(void);
//@}
/// \name Range access
//@{
/// Return smallest value of range
int min(void) const;
/// Return largest value of range
int max(void) const;
/// Return width of range (distance between minimum and maximum)
unsigned int width(void) const;
//@}
};
/// Iterator for the unknown ranges of a set variable
class SetVarUnknownRanges {
private:
Set::UnknownRanges<Set::SetVarImp*> iter;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVarUnknownRanges(void);
/// Initialize to iterate ranges of variable \a x
SetVarUnknownRanges(const SetVar& x);
//@}
/// \name Iteration control
//@{
/// Test whether iterator is still at a range or done
bool operator ()(void) const;
/// Move iterator to next range (if possible)
void operator ++(void);
//@}
/// \name Range access
//@{
/// Return smallest value of range
int min(void) const;
/// Return largest value of range
int max(void) const;
/// Return width of range (distance between minimum and maximum)
unsigned int width(void) const;
//@}
};
/// Iterator for the values in the greatest lower bound of a set variable
class SetVarGlbValues {
private:
Iter::Ranges::ToValues<SetVarGlbRanges> iter;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVarGlbValues(void);
/// Initialize to iterate values of variable \a x
SetVarGlbValues(const SetVar& x);
//@}
/// \name Iteration control
//@{
/// Test whether iterator is still at a value or done
bool operator ()(void) const;
/// Move iterator to next value (if possible)
void operator ++(void);
//@}
/// \name Value access
//@{
/// Return current value
int val(void) const;
//@}
};
/// Iterator for the values in the least upper bound of a set variable
class SetVarLubValues {
private:
Iter::Ranges::ToValues<SetVarLubRanges> iter;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVarLubValues(void);
/// Initialize to iterate values of variable \a x
SetVarLubValues(const SetVar& x);
//@}
/// \name Iteration control
//@{
/// Test whether iterator is still at a value or done
bool operator ()(void) const;
/// Move iterator to next value (if possible)
void operator ++(void);
//@}
/// \name Value access
//@{
/// Return current value
int val(void) const;
//@}
};
/// Iterator for the values in the unknown set of a set variable
class SetVarUnknownValues {
private:
Iter::Ranges::ToValues<SetVarUnknownRanges> iter;
public:
/// \name Constructors and initialization
//@{
/// Default constructor
SetVarUnknownValues(void);
/// Initialize to iterate values of variable \a x
SetVarUnknownValues(const SetVar& x);
//@}
/// \name Iteration control
//@{
/// Test whether iterator is still at a value or done
bool operator ()(void) const;
/// Move iterator to next value (if possible)
void operator ++(void);
//@}
/// \name Value access
//@{
/// Return current value
int val(void) const;
//@}
};
//@}
/**
* \brief Print set variable \a x
* \relates Gecode::SetVar
*/
template<class Char, class Traits>
std::basic_ostream<Char,Traits>&
operator <<(std::basic_ostream<Char,Traits>& os, const SetVar& x);
}
#include <gecode/set/view.hpp>
namespace Gecode {
/**
* \defgroup TaskModelSetArgs Argument arrays
*
* Argument arrays are just good enough for passing arguments
* with automatic memory management.
* \ingroup TaskModelSet
*/
//@{
}
#include <gecode/set/array-traits.hpp>
namespace Gecode {
/** \brief Passing set variables
*
* We could have used a simple typedef instead, but doxygen cannot
* resolve some overloading then, leading to unusable documentation for
* important parts of the library. As long as there is no fix for this,
* we will keep this workaround.
*
*/
class SetVarArgs : public VarArgArray<SetVar> {
public:
/// \name Constructors and initialization
//@{
/// Allocate empty array
SetVarArgs(void) {}
/// Allocate array with \a n elements
explicit SetVarArgs(int n) : VarArgArray<SetVar>(n) {}
/// Initialize from variable argument array \a a (copy elements)
SetVarArgs(const SetVarArgs& a) : VarArgArray<SetVar>(a) {}
/// Initialize from variable array \a a (copy elements)
SetVarArgs(const VarArray<SetVar>& a) : VarArgArray<SetVar>(a) {}
/// Initialize from vector \a a
SetVarArgs(const std::vector<SetVar>& a) : VarArgArray<SetVar>(a) {}
/// Initialize from InputIterator \a first and \a last
template<class InputIterator>
SetVarArgs(InputIterator first, InputIterator last)
: VarArgArray<SetVar>(first,last) {}
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArgs(Space& home,int n,int glbMin,int glbMax,
int lubMin,int lubMax,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArgs(Space& home,int n,const IntSet& glb,
int lubMin, int lubMax,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArgs(Space& home,int n,int glbMin,int glbMax,
const IntSet& lub,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArgs(Space& home,int n,
const IntSet& glb,const IntSet& lub,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
//@}
};
//@}
/**
* \defgroup TaskModelSetVarArrays Variable arrays
*
* Variable arrays can store variables. They are typically used
* for storing the variables being part of a solution. However,
* they can also be used for temporary purposes (even though
* memory is not reclaimed until the space it is created for
* is deleted).
* \ingroup TaskModelSet
*/
/**
* \brief %Set variable array
* \ingroup TaskModelSetVarArrays
*/
class SetVarArray : public VarArray<SetVar> {
public:
/// \name Creation and initialization
//@{
/// Default constructor (array of size 0)
SetVarArray(void);
/// Initialize from set variable array \a a (share elements)
SetVarArray(const SetVarArray&);
/// Initialize from set variable argument array \a a (copy elements)
SetVarArray(Space& home, const SetVarArgs&);
/// Allocate array for \a n set variables (variables are uninitialized)
GECODE_SET_EXPORT SetVarArray(Space& home, int n);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArray(Space& home,int n,int glbMin,int glbMax,int lubMin,int lubMax,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArray(Space& home,int n,const IntSet& glb, int lubMin, int lubMax,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArray(Space& home,int n,int glbMin,int glbMax,const IntSet& lub,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
/**
* \brief Create an array of size \a n.
*
* Each variable is initialized with the bounds and cardinality as
* given by the arguments.
*/
GECODE_SET_EXPORT
SetVarArray(Space& home,int n,
const IntSet& glb,const IntSet& lub,
unsigned int minCard = 0,
unsigned int maxCard = Set::Limits::card);
//@}
};
}
#include <gecode/set/array.hpp>
namespace Gecode {
/**
* \brief Common relation types for sets
*
* The total order on sets is defined as the lexicographic
* order on their characteristic functions, e.g.,
* \f$x\leq y\f$ means that either \f$x\f$ is empty or
* the minimal element of the symmetric difference
* \f$x\ominus y\f$ is in \f$y\f$.
*
* \ingroup TaskModelSet
*/
enum SetRelType {
SRT_EQ, ///< Equality (\f$=\f$)
SRT_NQ, ///< Disequality (\f$\neq\f$)
SRT_SUB, ///< Subset (\f$\subseteq\f$)
SRT_SUP, ///< Superset (\f$\supseteq\f$)
SRT_DISJ, ///< Disjoint (\f$\parallel\f$)
SRT_CMPL, ///< Complement
SRT_LQ, ///< Less or equal (\f$\leq\f$)
SRT_LE, ///< Less (\f$<\f$)
SRT_GQ, ///< Greater or equal (\f$\geq\f$)
SRT_GR ///< Greater (\f$>\f$)
};
/**
* \brief Common operations for sets
* \ingroup TaskModelSet
*/
enum SetOpType {
SOT_UNION, ///< Union
SOT_DUNION, ///< Disjoint union
SOT_INTER, ///< %Intersection
SOT_MINUS ///< Difference
};
/**
* \defgroup TaskModelSetDom Domain constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Propagates \f$ x \sim_r \{i\}\f$
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetRelType r, int i);
/// Propagates \f$ x_i \sim_r \{i\}\f$ for all \f$0\leq i<|x|\f$
GECODE_SET_EXPORT void
dom(Home home, const SetVarArgs& x, SetRelType r, int i);
/// Propagates \f$ x \sim_r \{i,\dots,j\}\f$
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetRelType r, int i, int j);
/// Propagates \f$ x \sim_r \{i,\dots,j\}\f$ for all \f$0\leq i<|x|\f$
GECODE_SET_EXPORT void
dom(Home home, const SetVarArgs& x, SetRelType r, int i, int j);
/// Propagates \f$ x \sim_r s\f$
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetRelType r, const IntSet& s);
/// Propagates \f$ x \sim_r s\f$ for all \f$0\leq i<|x|\f$
GECODE_SET_EXPORT void
dom(Home home, const SetVarArgs& x, SetRelType r, const IntSet& s);
/// Propagates \f$ i \leq |s| \leq j \f$
GECODE_SET_EXPORT void
cardinality(Home home, SetVar x, unsigned int i, unsigned int j);
/// Propagates \f$ i \leq |s| \leq j \f$ for all \f$0\leq i<|x|\f$
GECODE_SET_EXPORT void
cardinality(Home home, const SetVarArgs& x, unsigned int i, unsigned int j);
/// Post propagator for \f$ (x \sim_{rt} \{i\}) \equiv r \f$
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetRelType rt, int i, Reify r);
/// Post propagator for \f$ (x \sim_{rt} \{i,\dots,j\}) \equiv r \f$
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetRelType rt, int i, int j, Reify r);
/// Post propagator for \f$ (x \sim_{rt} s) \equiv r \f$
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetRelType rt, const IntSet& s, Reify r);
/// Constrain domain of \a x according to domain of \a d
GECODE_SET_EXPORT void
dom(Home home, SetVar x, SetVar d);
/// Constrain domain of \f$ x_i \f$ according to domain of \f$ d_i \f$ for all \f$0\leq i<|x|\f$
GECODE_SET_EXPORT void
dom(Home home, const SetVarArgs& x, const SetVarArgs& d);
//@}
/**
* \defgroup TaskModelSetRel Relation constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Post propagator for \f$ x \sim_r y\f$
GECODE_SET_EXPORT void
rel(Home home, SetVar x, SetRelType r, SetVar y);
/// Post propagator for \f$ (x \sim_{rt} y) \equiv r\f$
GECODE_SET_EXPORT void
rel(Home home, SetVar x, SetRelType rt, SetVar y, Reify r);
/// Post propagator for \f$ s \sim_r \{x\}\f$
GECODE_SET_EXPORT void
rel(Home home, SetVar s, SetRelType r, IntVar x);
/// Post propagator for \f$ \{x\} \sim_r s\f$
GECODE_SET_EXPORT void
rel(Home home, IntVar x, SetRelType r, SetVar s);
/// Post propagator for \f$ (s \sim_{rt} \{x\}) \equiv r\f$
GECODE_SET_EXPORT void
rel(Home home, SetVar s, SetRelType rt, IntVar x, Reify r);
/// Post propagator for \f$ (\{x\} \sim_{rt} s) \equiv r \f$
GECODE_SET_EXPORT void
rel(Home home, IntVar x, SetRelType rt, SetVar s, Reify r);
/// Post propagator for \f$|s|\geq 1 \land \forall i\in s:\ i \sim_r x\f$
GECODE_SET_EXPORT void
rel(Home home, SetVar s, IntRelType r, IntVar x);
/// Post propagator for \f$|s|\geq 1 \land \forall i\in s:\ x \sim_r i\f$
GECODE_SET_EXPORT void
rel(Home home, IntVar x, IntRelType r, SetVar s);
//@}
/**
* \defgroup TaskModelSetRelOp Set operation/relation constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Post propagator for \f$ (x \diamond_{\mathit{op}} y) \sim_r z \f$
GECODE_SET_EXPORT void
rel(Home home, SetVar x, SetOpType op, SetVar y, SetRelType r, SetVar z);
/// Post propagator for \f$ y = \diamond_{\mathit{op}} x\f$
GECODE_SET_EXPORT void
rel(Home home, SetOpType op, const SetVarArgs& x, SetVar y);
/// Post propagator for \f$ y = \diamond_{\mathit{op}} x \diamond_{\mathit{op}} z\f$
GECODE_SET_EXPORT void
rel(Home home, SetOpType op, const SetVarArgs& x, const IntSet& z, SetVar y);
/// Post propagator for \f$ y = \diamond_{\mathit{op}} x \diamond_{\mathit{op}} z\f$
GECODE_SET_EXPORT void
rel(Home home, SetOpType op, const IntVarArgs& x, const IntSet& z, SetVar y);
/// Post propagator for \f$ y = \diamond_{\mathit{op}} x\f$
GECODE_SET_EXPORT void
rel(Home home, SetOpType op, const IntVarArgs& x, SetVar y);
/// Post propagator for \f$ (x \diamond_{\mathit{op}} y) \sim_r z \f$
GECODE_SET_EXPORT void
rel(Home home, const IntSet& x, SetOpType op, SetVar y,
SetRelType r, SetVar z);
/// Post propagator for \f$ (x \diamond_{\mathit{op}} y) \sim_r z \f$
GECODE_SET_EXPORT void
rel(Home home, SetVar x, SetOpType op, const IntSet& y,
SetRelType r, SetVar z);
/// Post propagator for \f$ (x \diamond_{\mathit{op}} y) \sim_r z \f$
GECODE_SET_EXPORT void
rel(Home home, SetVar x, SetOpType op, SetVar y,
SetRelType r, const IntSet& z);
/// Post propagator for \f$ (x \diamond_{\mathit{op}} y) \sim_r z \f$
GECODE_SET_EXPORT void
rel(Home home, const IntSet& x, SetOpType op, SetVar y, SetRelType r,
const IntSet& z);
/// Post propagator for \f$ (x \diamond_{\mathit{op}} y) \sim_r z \f$
GECODE_SET_EXPORT void
rel(Home home, SetVar x, SetOpType op, const IntSet& y, SetRelType r,
const IntSet& z);
//@}
/**
* \defgroup TaskModelSetConvex Convexity constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Post propagator that propagates that \a x is convex
GECODE_SET_EXPORT void
convex(Home home, SetVar x);
/// Post propagator that propagates that \a y is the convex hull of \a x
GECODE_SET_EXPORT void
convex(Home home, SetVar x, SetVar y);
//@}
/**
* \defgroup TaskModelSetSequence Sequence constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Post propagator for \f$\forall 0\leq i< |x|-1 : \max(x_i)<\min(x_{i+1})\f$
GECODE_SET_EXPORT void
sequence(Home home, const SetVarArgs& x);
/// Post propagator for \f$\forall 0\leq i< |x|-1 : \max(x_i)<\min(x_{i+1})\f$ and \f$ x = \bigcup_{i\in\{0,\dots,n-1\}} y_i \f$
GECODE_SET_EXPORT void
sequence(Home home, const SetVarArgs& y, SetVar x);
//@}
/**
* \defgroup TaskModelSetDistinct Distinctness constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Post propagator for \f$\forall 0\leq i\leq |x| : |x_i|=c\f$ and \f$\forall 0\leq i<j\leq |x| : |x_i\cap x_j|\leq 1\f$
GECODE_SET_EXPORT void
atmostOne(Home home, const SetVarArgs& x, unsigned int c);
//@}
/**
* \defgroup TaskModelSetConnect Connection constraints to integer variables
* \ingroup TaskModelSet
*
*/
//@{
/** \brief Post propagator that propagates that \a x is the
* minimal element of \a s, and that \a s is not empty */
GECODE_SET_EXPORT void
min(Home home, SetVar s, IntVar x);
/** \brief Post propagator that propagates that \a x is not the
* minimal element of \a s */
GECODE_SET_EXPORT void
notMin(Home home, SetVar s, IntVar x);
/** \brief Post reified propagator for \a b iff \a x is the
* minimal element of \a s */
GECODE_SET_EXPORT void
min(Home home, SetVar s, IntVar x, Reify r);
/** \brief Post propagator that propagates that \a x is the
* maximal element of \a s, and that \a s is not empty */
GECODE_SET_EXPORT void
max(Home home, SetVar s, IntVar x);
/** \brief Post propagator that propagates that \a x is not the
* maximal element of \a s */
GECODE_SET_EXPORT void
notMax(Home home, SetVar s, IntVar x);
/** \brief Post reified propagator for \a b iff \a x is the
* maximal element of \a s */
GECODE_SET_EXPORT void
max(Home home, SetVar s, IntVar x, Reify r);
/// Post propagator for \f$ |s|=x \f$
GECODE_SET_EXPORT void
cardinality(Home home, SetVar s, IntVar x);
/**
* \brief Post propagator for \f$y = \mathrm{weight}(x)\f$
*
* The weights are given as pairs of elements and their weight:
* \f$\mathrm{weight}(\mathrm{elements}_i) = \mathrm{weights}_i\f$
*
* The upper bound of \a x is constrained to contain only elements from
* \a elements. The weight of a set is the sum of the weights of its
* elements.
*/
GECODE_SET_EXPORT void
weights(Home home, IntSharedArray elements, IntSharedArray weights,
SetVar x, IntVar y);
//@}
/**
* \defgroup TaskModelSetChannel Channel constraints
* \ingroup TaskModelSet
*
*/
//@{
/// Post propagator for \f$x_i=j \Leftrightarrow i\in y_j\f$
GECODE_SET_EXPORT void
channel(Home home, const IntVarArgs& x,const SetVarArgs& y);
/// Post propagator for \f$\{x_0,\dots,x_{n-1}\}=y\f$ and \f$x_i<x_{i+1}\f$
GECODE_SET_EXPORT void
channelSorted(Home home, const IntVarArgs& x, SetVar y);
/// Post propagator for \f$x_i=1 \Leftrightarrow i\in y\f$
GECODE_SET_EXPORT void
channel(Home home, const BoolVarArgs& x, SetVar y);
/// Post propagator for \f$j\in x_i \Leftrightarrow i\in y_j\f$
GECODE_SET_EXPORT void
channel(Home home, const SetVarArgs& x, const SetVarArgs& y);
//@}
/**
* \defgroup TaskModelSetPrecede Value precedence constraints over set variables
* \ingroup TaskModelSet
*/
/** \brief Post propagator that \a s precedes \a t in \a x
*
* This constraint enforces that if there exists \f$j\f$ such that
* \f$s\notin x_j\land t\in x_j\f$, then there exists \f$i<j\f$ such that
* \f$s\in x_i\land t\notin x_i\f$.
* \ingroup TaskModelSetPrecede
*/
GECODE_SET_EXPORT void
precede(Home home, const SetVarArgs& x, int s, int t);
/** \brief Post propagator that successive values in \a c precede each other in \a x
* \ingroup TaskModelSetPrecede
*/
GECODE_SET_EXPORT void
precede(Home home, const SetVarArgs& x, const IntArgs& c);
/**
* \defgroup TaskModelSetElement Element constraints
* \ingroup TaskModelSet
*
* An element constraint selects zero, one or more elements out of a
* sequence. We write \f$ \langle x_0,\dots, x_{n-1} \rangle \f$ for the
* sequence, and \f$ [y] \f$ for the index variable.
*
* Set element constraints are closely related to the ::element constraint
* on integer variables.
*/
//@{
/**
* \brief Post propagator for \f$ z=\diamond_{\mathit{op}}\langle x_0,\dots,x_{n-1}\rangle[y] \f$
*
* If \a y is the empty set, the usual conventions for set operations apply:
* an empty union is empty, while an empty intersection is the universe,
* which can be given as the optional parameter \a u.
*
* The indices for \a y start at 0.
*/
GECODE_SET_EXPORT void
element(Home home, SetOpType op, const SetVarArgs& x, SetVar y, SetVar z,
const IntSet& u = IntSet(Set::Limits::min,Set::Limits::max));
/**
* \brief Post propagator for \f$ z=\diamond_{\mathit{op}}\langle \{x_0\},\dots,\{x_{n-1}\}\rangle[y] \f$
*
* If \a y is the empty set, the usual conventions for set operations apply:
* an empty union is empty, while an empty intersection is the universe,
* which can be given as the optional parameter \a u.
*
* The indices for \a y start at 0.
*/
GECODE_SET_EXPORT void
element(Home home, SetOpType op, const IntVarArgs& x, SetVar y, SetVar z,
const IntSet& u = IntSet(Set::Limits::min,Set::Limits::max));
/**
* \brief Post propagator for \f$ z=\diamond_{\mathit{op}}\langle x_0,\dots,x_{n-1}\rangle[y] \f$
*
* If \a y is the empty set, the usual conventions for set operations apply:
* an empty union is empty, while an empty intersection is the universe,
* which can be given as the optional parameter \a u.
*
* The indices for \a y start at 0.
*/
GECODE_SET_EXPORT void
element(Home home, SetOpType op, const IntSetArgs& x, SetVar y, SetVar z,
const IntSet& u = IntSet(Set::Limits::min,Set::Limits::max));
/**
* \brief Post propagator for \f$ z=\diamond_{\mathit{op}}\langle \{x_0\},\dots,\{x_{n-1}\}\rangle[y] \f$
*
* If \a y is the empty set, the usual conventions for set operations apply:
* an empty union is empty, while an empty intersection is the universe,
* which can be given as the optional parameter \a u.
*
* The indices for \a y start at 0.
*/
GECODE_SET_EXPORT void
element(Home home, SetOpType op, const IntArgs& x, SetVar y, SetVar z,
const IntSet& u = IntSet(Set::Limits::min,Set::Limits::max));
/**
* \brief Post propagator for \f$ z=\langle x_0,\dots,x_{n-1}\rangle[y] \f$
*
* The indices for \a y start at 0.
*/
GECODE_SET_EXPORT void
element(Home home, const SetVarArgs& x, IntVar y, SetVar z);
/**
* \brief Post propagator for \f$ z=\langle s_0,\dots,s_{n-1}\rangle[y] \f$
*
* The indices for \a y start at 0.
*/
GECODE_SET_EXPORT void
element(Home home, const IntSetArgs& s, IntVar y, SetVar z);
/** \brief Post propagator for \f$ a_{x+w\cdot y}=z\f$
*
* Throws an exception of type Set::ArgumentSizeMismatch, if
* \f$ w\cdot h\neq|a|\f$.
*/
GECODE_SET_EXPORT void
element(Home home, const IntSetArgs& a,
IntVar x, int w, IntVar y, int h, SetVar z);
/** \brief Post propagator for \f$ a_{x+w\cdot y}=z\f$
*
* Throws an exception of type Set::ArgumentSizeMismatch, if
* \f$ w\cdot h\neq|a|\f$.
*/
GECODE_SET_EXPORT void
element(Home home, const SetVarArgs& a,
IntVar x, int w, IntVar y, int h, SetVar z);
//@}
/**
* \defgroup TaskModelSetExec Synchronized execution
* \ingroup TaskModelSet
*
* Synchronized execution executes a function or a static member function
* when a certain event happends.
*
* \ingroup TaskModelSet
*/
//@{
/// Execute \a c when \a x becomes assigned
GECODE_SET_EXPORT void
wait(Home home, SetVar x, void (*c)(Space& home));
/// Execute \a c when all variables in \a x become assigned
GECODE_SET_EXPORT void
wait(Home home, const SetVarArgs& x, void (*c)(Space& home));
//@}
}
namespace Gecode {
/**
* \defgroup TaskModelSetBranch Branching
* \ingroup TaskModelSet
*/
/**
* \brief Branch filter function type for set variables
*
* The variable \a x is considered for selection and \a i refers to the
* variable's position in the original array passed to the brancher.
*
* \ingroup TaskModelSetBranch
*/
typedef bool (*SetBranchFilter)(const Space& home, SetVar x, int i);
/**
* \brief Branch merit function type for set variables
*
* The function must return a merit value for the variable
* \a x.
* The value \a i refers to the variable's position in the original array
* passed to the brancher.
*
* \ingroup TaskModelSetBranch
*/
typedef double (*SetBranchMerit)(const Space& home, SetVar x, int i);
/**
* \brief Branch value function type for set variables
*
* Returns a value for the variable \a x that is to be used in the
* corresponding branch commit function. The integer \a i refers
* to the variable's position in the original array passed to the
* brancher.
*
* \ingroup TaskModelSetBranch
*/
typedef int (*SetBranchVal)(const Space& home, SetVar x, int i);
/**
* \brief Branch commit function type for set variables
*
* The function must post a constraint on the variable \a x which
* corresponds to the alternative \a a. The integer \a i refers
* to the variable's position in the original array passed to the
* brancher. The value \a n is the value
* computed by the corresponding branch value function.
*
* \ingroup TaskModelSetBranch
*/
typedef void (*SetBranchCommit)(Space& home, unsigned int a,
SetVar x, int i, int n);
}
#include <gecode/set/branch/traits.hpp>
namespace Gecode {
/**
* \brief Recording AFC information for set variables
*
* \ingroup TaskModelSetBranch
*/
class SetAFC : public AFC {
public:
/**
* \brief Construct as not yet initialized
*
* The only member functions that can be used on a constructed but not
* yet initialized AFC storage is init or the assignment operator.
*
*/
SetAFC(void);
/// Copy constructor
SetAFC(const SetAFC& a);
/// Assignment operator
SetAFC& operator =(const SetAFC& a);
/// Initialize for set variables \a x with decay factor \a d
SetAFC(Home home, const SetVarArgs& x, double d=1.0);
/**
* \brief Initialize for set variables \a x with decay factor \a d
*
* This member function can only be used once and only if the
* AFC storage has been constructed with the default constructor.
*
*/
void init(Home, const SetVarArgs& x, double d=1.0);
};
}
#include <gecode/set/branch/afc.hpp>
namespace Gecode {
/**
* \brief Recording activities for set variables
*
* \ingroup TaskModelSetBranch
*/
class SetActivity : public Activity {
public:
/**
* \brief Construct as not yet initialized
*
* The only member functions that can be used on a constructed but not
* yet initialized activity storage is init or the assignment operator.
*
*/
SetActivity(void);
/// Copy constructor
SetActivity(const SetActivity& a);
/// Assignment operator
SetActivity& operator =(const SetActivity& a);
/**
* \brief Initialize for set variables \a x with decay factor \a d
*
* If the branch merit function \a bm is different from NULL, the
* activity for each variable is initialized with the merit returned
* by \a bm.
*
*/
GECODE_SET_EXPORT
SetActivity(Home home, const SetVarArgs& x, double d=1.0,
SetBranchMerit bm=NULL);
/**
* \brief Initialize for set variables \a x with decay factor \a d
*
* If the branch merit function \a bm is different from NULL, the
* activity for each variable is initialized with the merit returned
* by \a bm.
*
* This member function can only be used once and only if the
* activity storage has been constructed with the default constructor.
*
*/
GECODE_SET_EXPORT void
init(Home, const SetVarArgs& x, double d=1.0,
SetBranchMerit bm=NULL);
};
}
#include <gecode/set/branch/activity.hpp>
namespace Gecode {
/// Function type for printing branching alternatives for set variables
typedef void (*SetVarValPrint)(const Space &home, const BrancherHandle& bh,
unsigned int a,
SetVar x, int i, const int& n,
std::ostream& o);
}
namespace Gecode {
/**
* \brief Which variable to select for branching
*
* \ingroup TaskModelSetBranch
*/
class SetVarBranch : public VarBranch {
public:
/// Which variable selection
enum Select {
SEL_NONE = 0, ///< First unassigned
SEL_RND, ///< Random (uniform, for tie breaking)
SEL_MERIT_MIN, ///< With least merit
SEL_MERIT_MAX, ///< With highest merit
SEL_DEGREE_MIN, ///< With smallest degree
SEL_DEGREE_MAX, ///< With largest degree
SEL_AFC_MIN, ///< With smallest accumulated failure count
SEL_AFC_MAX, ///< With largest accumulated failure count
SEL_ACTIVITY_MIN, ///< With lowest activity
SEL_ACTIVITY_MAX, ///< With highest activity
SEL_MIN_MIN, ///< With smallest minimum unknown element
SEL_MIN_MAX, ///< With largest minimum unknown element
SEL_MAX_MIN, ///< With smallest maximum unknown element
SEL_MAX_MAX, ///< With largest maximum unknown element
SEL_SIZE_MIN, ///< With smallest unknown set
SEL_SIZE_MAX, ///< With largest unknown set
SEL_DEGREE_SIZE_MIN, ///< With smallest degree divided by domain size
SEL_DEGREE_SIZE_MAX, ///< With largest degree divided by domain size
SEL_AFC_SIZE_MIN, ///< With smallest accumulated failure count divided by domain size
SEL_AFC_SIZE_MAX, ///< With largest accumulated failure count divided by domain size
SEL_ACTIVITY_SIZE_MIN, ///< With smallest activity divided by domain size
SEL_ACTIVITY_SIZE_MAX, ///< With largest activity divided by domain size
};
protected:
/// Which variable to select
Select s;
public:
/// Initialize with strategy SEL_NONE
SetVarBranch(void);
/// Initialize with random number generator \a r
SetVarBranch(Rnd r);
/// Initialize with selection strategy \a s and tie-break limit function \a t
SetVarBranch(Select s, BranchTbl t);
/// Initialize with selection strategy \a s, decay factor \a d, and tie-break limit function \a t
SetVarBranch(Select s, double d, BranchTbl t);
/// Initialize with selection strategy \a s, afc \a a, and tie-break limit function \a t
SetVarBranch(Select s, AFC a, BranchTbl t);
/// Initialize with selection strategy \a s, activity \a a, and tie-break limit function \a t
SetVarBranch(Select s, Activity a, BranchTbl t);
/// Initialize with selection strategy \a s, branch merit function \a mf, and tie-break limit function \a t
SetVarBranch(Select s, VoidFunction mf, BranchTbl t);
/// Return selection strategy
Select select(void) const;
/// Expand decay factor into AFC or activity
void expand(Home home, const SetVarArgs& x);
};
/**
* \defgroup TaskModelSetBranchVar Selecting set variables
* \ingroup TaskModelSetBranch
*/
//@{
/// Select first unassigned variable
SetVarBranch SET_VAR_NONE(void);
/// Select random variable (uniform distribution, for tie breaking)
SetVarBranch SET_VAR_RND(Rnd r);
/// Select variable with least merit according to branch merit function \a bm
SetVarBranch SET_VAR_MERIT_MIN(SetBranchMerit bm, BranchTbl tbl=NULL);
/// Select variable with highest merit according to branch merit function \a bm
SetVarBranch SET_VAR_MERIT_MAX(SetBranchMerit bm, BranchTbl tbl=NULL);
/// Select variable with smallest degree
SetVarBranch SET_VAR_DEGREE_MIN(BranchTbl tbl=NULL);
/// Select variable with largest degree
SetVarBranch SET_VAR_DEGREE_MAX(BranchTbl tbl=NULL);
/// Select variable with smallest accumulated failure count with decay factor \a d
SetVarBranch SET_VAR_AFC_MIN(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with smallest accumulated failure count
SetVarBranch SET_VAR_AFC_MIN(SetAFC a, BranchTbl tbl=NULL);
/// Select variable with largest accumulated failure count with decay factor \a d
SetVarBranch SET_VAR_AFC_MAX(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with largest accumulated failure count
SetVarBranch SET_VAR_AFC_MAX(SetAFC a, BranchTbl tbl=NULL);
/// Select variable with lowest activity with decay factor \a d
SetVarBranch SET_VAR_ACTIVITY_MIN(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with lowest activity
SetVarBranch SET_VAR_ACTIVITY_MIN(SetActivity a, BranchTbl tbl=NULL);
/// Select variable with highest activity with decay factor \a d
SetVarBranch SET_VAR_ACTIVITY_MAX(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with highest activity
SetVarBranch SET_VAR_ACTIVITY_MAX(SetActivity a, BranchTbl tbl=NULL);
/// Select variable with smallest minimum unknown element
SetVarBranch SET_VAR_MIN_MIN(BranchTbl tbl=NULL);
/// Select variable with largest minimum unknown element
SetVarBranch SET_VAR_MIN_MAX(BranchTbl tbl=NULL);
/// Select variable with smallest maximum unknown element
SetVarBranch SET_VAR_MAX_MIN(BranchTbl tbl=NULL);
/// Select variable with largest maximum unknown element
SetVarBranch SET_VAR_MAX_MAX(BranchTbl tbl=NULL);
/// Select variable with smallest unknown set
SetVarBranch SET_VAR_SIZE_MIN(BranchTbl tbl=NULL);
/// Select variable with largest unknown set
SetVarBranch SET_VAR_SIZE_MAX(BranchTbl tbl=NULL);
/// Select variable with smallest degree divided by domain size
SetVarBranch SET_VAR_DEGREE_SIZE_MIN(BranchTbl tbl=NULL);
/// Select variable with largest degree divided by domain size
SetVarBranch SET_VAR_DEGREE_SIZE_MAX(BranchTbl tbl=NULL);
/// Select variable with smallest accumulated failure count divided by domain size with decay factor \a d
SetVarBranch SET_VAR_AFC_SIZE_MIN(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with smallest accumulated failure count divided by domain size
SetVarBranch SET_VAR_AFC_SIZE_MIN(SetAFC a, BranchTbl tbl=NULL);
/// Select variable with largest accumulated failure count divided by domain size with decay factor \a d
SetVarBranch SET_VAR_AFC_SIZE_MAX(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with largest accumulated failure count divided by domain size
SetVarBranch SET_VAR_AFC_SIZE_MAX(SetAFC a, BranchTbl tbl=NULL);
/// Select variable with smallest activity divided by domain size with decay factor \a d
SetVarBranch SET_VAR_ACTIVITY_SIZE_MIN(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with smallest activity divided by domain size
SetVarBranch SET_VAR_ACTIVITY_SIZE_MIN(SetActivity a, BranchTbl tbl=NULL);
/// Select variable with largest activity divided by domain size with decay factor \a d
SetVarBranch SET_VAR_ACTIVITY_SIZE_MAX(double d=1.0, BranchTbl tbl=NULL);
/// Select variable with largest activity divided by domain size
SetVarBranch SET_VAR_ACTIVITY_SIZE_MAX(SetActivity a, BranchTbl tbl=NULL);
//@}
}
#include <gecode/set/branch/var.hpp>
namespace Gecode {
/**
* \brief Which values to select for branching first
*
* \ingroup TaskModelSetBranch
*/
class SetValBranch : public ValBranch {
public:
/// Which value selection
enum Select {
SEL_MIN_INC, ///< Include smallest element
SEL_MIN_EXC, ///< Exclude smallest element
SEL_MED_INC, ///< Include median element (rounding downwards)
SEL_MED_EXC, ///< Exclude median element (rounding downwards)
SEL_MAX_INC, ///< Include largest element
SEL_MAX_EXC, ///< Exclude largest element
SEL_RND_INC, ///< Include random element
SEL_RND_EXC, ///< Exclude random element
SEL_VAL_COMMIT ///< Select value according to user-defined functions
};
protected:
/// Which value to select
Select s;
public:
/// Initialize with selection strategy \a s
SetValBranch(Select s = SEL_MIN_INC);
/// Initialize with random number generator \a r
SetValBranch(Select s, Rnd r);
/// Initialize with value function \a f and commit function \a c
SetValBranch(VoidFunction v, VoidFunction c);
/// Return selection strategy
Select select(void) const;
};
/**
* \defgroup TaskModelSetBranchVal Value selection for set variables
* \ingroup TaskModelSetBranch
*/
//@{
/// Include smallest element
SetValBranch SET_VAL_MIN_INC(void);
/// Exclude smallest element
SetValBranch SET_VAL_MIN_EXC(void);
/// Include median element (rounding downwards)
SetValBranch SET_VAL_MED_INC(void);
/// Exclude median element (rounding downwards)
SetValBranch SET_VAL_MED_EXC(void);
/// Include largest element
SetValBranch SET_VAL_MAX_INC(void);
/// Exclude largest element
SetValBranch SET_VAL_MAX_EXC(void);
/// Include random element
SetValBranch SET_VAL_RND_INC(Rnd r);
/// Exclude random element
SetValBranch SET_VAL_RND_EXC(Rnd r);
/**
* \brief Select value as defined by the value function \a v and commit function \a c
*
* The default commit function posts the constraint that the value \a n
* must be included in the set variable \a x for the first alternative,
* and that \a n must be excluded from \a x otherwise.
*/
SetValBranch SET_VAL(SetBranchVal v, SetBranchCommit c=NULL);
//@}
}
#include <gecode/set/branch/val.hpp>
namespace Gecode {
/**
* \brief Which value to select for assignment
*
* \ingroup TaskModelSetBranch
*/
class SetAssign : public ValBranch {
public:
/// Which value selection
enum Select {
SEL_MIN_INC, ///< Include smallest element
SEL_MIN_EXC, ///< Exclude smallest element
SEL_MED_INC, ///< Include median element (rounding downwards)
SEL_MED_EXC, ///< Exclude median element (rounding downwards)
SEL_MAX_INC, ///< Include largest element
SEL_MAX_EXC, ///< Exclude largest element
SEL_RND_INC, ///< Include random element
SEL_RND_EXC, ///< Exclude random element
SEL_VAL_COMMIT ///< Select value according to user-defined functions
};
protected:
/// Which value to select
Select s;
public:
/// Initialize with selection strategy \a s
SetAssign(Select s = SEL_MIN_INC);
/// Initialize with random number generator \a r
SetAssign(Select s, Rnd r);
/// Initialize with value function \a f and commit function \a c
SetAssign(VoidFunction v, VoidFunction c);
/// Return selection strategy
Select select(void) const;
};
/**
* \defgroup TaskModelSetBranchAssign Assigning set variables
* \ingroup TaskModelSetBranch
*/
//@{
/// Include smallest element
SetAssign SET_ASSIGN_MIN_INC(void);
/// Exclude smallest element
SetAssign SET_ASSIGN_MIN_EXC(void);
/// Include median element (rounding downwards)
SetAssign SET_ASSIGN_MED_INC(void);
/// Exclude median element (rounding downwards)
SetAssign SET_ASSIGN_MED_EXC(void);
/// Include largest element
SetAssign SET_ASSIGN_MAX_INC(void);
/// Exclude largest element
SetAssign SET_ASSIGN_MAX_EXC(void);
/// Include random element
SetAssign SET_ASSIGN_RND_INC(Rnd r);
/// Exclude random element
SetAssign SET_ASSIGN_RND_EXC(Rnd r);
/**
* \brief Select value as defined by the value function \a v and commit function \a c
*
* The default commit function posts the constraint that the value \a n
* must be included in the set variable \a x.
*/
SetAssign SET_ASSIGN(SetBranchVal v, SetBranchCommit c=NULL);
//@}
}
#include <gecode/set/branch/assign.hpp>
namespace Gecode {
/**
* \brief Branch over \a x with variable selection \a vars and value selection \a vals
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
branch(Home home, const SetVarArgs& x,
SetVarBranch vars, SetValBranch vals,
SetBranchFilter bf=NULL,
SetVarValPrint vvp=NULL);
/**
* \brief Branch over \a x with tie-breaking variable selection \a vars and value selection \a vals
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
branch(Home home, const SetVarArgs& x,
TieBreak<SetVarBranch> vars, SetValBranch vals,
SetBranchFilter bf=NULL,
SetVarValPrint vvp=NULL);
/**
* \brief Branch over \a x with value selection \a vals
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
branch(Home home, SetVar x, SetValBranch vals,
SetVarValPrint vvp=NULL);
/**
* \brief Assign all \a x with value selection \a vals
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
assign(Home home, const SetVarArgs& x, SetAssign vals,
SetBranchFilter bf=NULL,
SetVarValPrint vvp=NULL);
/**
* \brief Assign \a x with value selection \a vals
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
assign(Home home, SetVar x, SetAssign vals,
SetVarValPrint vvp=NULL);
}
// LDSB-related declarations.
namespace Gecode {
/// Variables in \a x are interchangeable
GECODE_SET_EXPORT SymmetryHandle VariableSymmetry(const SetVarArgs& x);
/**
* \brief Variable sequences in \a x of size \a ss are interchangeable
*
* The size of \a x must be a multiple of \a ss.
*/
GECODE_SET_EXPORT
SymmetryHandle VariableSequenceSymmetry(const SetVarArgs& x, int ss);
/**
* \brief Branch over \a x with variable selection \a vars and value
* selection \a vals with symmetry breaking
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
branch(Home home, const SetVarArgs& x,
SetVarBranch vars, SetValBranch vals,
const Symmetries& syms,
SetBranchFilter bf=NULL,
SetVarValPrint vvp=NULL);
/**
* \brief Branch over \a x with tie-breaking variable selection \a
* vars and value selection \a vals with symmetry breaking
*
* \ingroup TaskModelSetBranch
*/
GECODE_SET_EXPORT BrancherHandle
branch(Home home, const SetVarArgs& x,
TieBreak<SetVarBranch> vars, SetValBranch vals,
const Symmetries& syms,
SetBranchFilter bf=NULL,
SetVarValPrint vvp=NULL);
}
#endif
// IFDEF: GECODE_HAS_SET_VARS
// STATISTICS: set-post
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