/usr/include/gecode/int/linear.hh is in libgecode-dev 3.7.1-3.
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/*
* Main authors:
* Christian Schulte <schulte@gecode.org>
* Guido Tack <tack@gecode.org>
* Tias Guns <tias.guns@cs.kuleuven.be>
*
* Copyright:
* Christian Schulte, 2002
* Guido Tack, 2004
* Tias Guns, 2009
*
* Last modified:
* $Date: 2009-12-04 13:57:33 +0100 (Fri, 04 Dec 2009) $ by $Author: schulte $
* $Revision: 10188 $
*
* 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_INT_LINEAR_HH__
#define __GECODE_INT_LINEAR_HH__
#include <gecode/int.hh>
/**
* \namespace Gecode::Int::Linear
* \brief %Linear propagators
*/
namespace Gecode { namespace Int { namespace Linear {
/*
* Binary propagators
*
*/
/**
* \brief Base-class for binary linear propagators
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*/
template<class Val, class A, class B, PropCond pc>
class LinBin : public Propagator {
protected:
/// View of type \a A
A x0;
/// View of type \a B
B x1;
/// Value of type \a Val
Val c;
/// Constructor for cloning \a p
LinBin(Space& home, bool share, LinBin& p);
/// Constructor for rewriting \a p during cloning
LinBin(Space& home, bool share, Propagator& p, A x0, B x1, Val c);
/// Constructor for creation
LinBin(Home home, A x0, B x1, Val c);
public:
/// Cost function (defined as low binary)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief Base-class for reified binary linear propagators
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*/
template<class Val, class A, class B, PropCond pc, class Ctrl>
class ReLinBin : public Propagator {
protected:
/// View of type \a A
A x0;
/// View of type \a B
B x1;
/// Value of type \a Val
Val c;
/// Control view for reification
Ctrl b;
/// Constructor for cloning \a p
ReLinBin(Space& home, bool share, ReLinBin& p);
/// Constructor for creation
ReLinBin(Home home, A x0, B x1, Val c, Ctrl b);
public:
/// Cost function (defined as low binary)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief %Propagator for bounds consistent binary linear equality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B>
class EqBin : public LinBin<Val,A,B,PC_INT_BND> {
protected:
using LinBin<Val,A,B,PC_INT_BND>::x0;
using LinBin<Val,A,B,PC_INT_BND>::x1;
using LinBin<Val,A,B,PC_INT_BND>::c;
/// Constructor for cloning \a p
EqBin(Space& home, bool share, EqBin& p);
/// Constructor for creation
EqBin(Home home, A x0, B x1, Val c);
public:
/// Constructor for rewriting \a p during cloning
EqBin(Space& home, bool share, Propagator& p, A x0, B x1, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$x_0+x_1 = c\f$
static ExecStatus post(Home home, A x0, B x1, Val c);
};
/**
* \brief %Propagator for reified bounds consistent binary linear equality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B, class Ctrl>
class ReEqBin : public ReLinBin<Val,A,B,PC_INT_BND,Ctrl> {
protected:
using ReLinBin<Val,A,B,PC_INT_BND,Ctrl>::x0;
using ReLinBin<Val,A,B,PC_INT_BND,Ctrl>::x1;
using ReLinBin<Val,A,B,PC_INT_BND,Ctrl>::c;
using ReLinBin<Val,A,B,PC_INT_BND,Ctrl>::b;
/// Constructor for cloning \a p
ReEqBin(Space& home, bool share, ReEqBin& p);
/// Constructor for creation
ReEqBin(Home home,A,B,Val,Ctrl);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$(x_0+x_1 = c)\Leftrightarrow b\f$
static ExecStatus post(Home home, A x0, B x1, Val c, Ctrl b);
};
/**
* \brief %Propagator for bounds consistent binary linear disequality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B>
class NqBin : public LinBin<Val,A,B,PC_INT_VAL> {
protected:
using LinBin<Val,A,B,PC_INT_VAL>::x0;
using LinBin<Val,A,B,PC_INT_VAL>::x1;
using LinBin<Val,A,B,PC_INT_VAL>::c;
/// Constructor for cloning \a p
NqBin(Space& home, bool share, NqBin& p);
/// Constructor for creation
NqBin(Home home, A x0, B x1, Val c);
public:
/// Constructor for rewriting \a p during cloning
NqBin(Space& home, bool share, Propagator& p, A x0, B x1, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Cost function (defined as low unary)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Post propagator for \f$x_0+x_1 \neq c\f$
static ExecStatus post(Home home, A x0, B x1, Val c);
};
/**
* \brief %Propagator for bounds consistent binary linear less or equal
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B>
class LqBin : public LinBin<Val,A,B,PC_INT_BND> {
protected:
using LinBin<Val,A,B,PC_INT_BND>::x0;
using LinBin<Val,A,B,PC_INT_BND>::x1;
using LinBin<Val,A,B,PC_INT_BND>::c;
/// Constructor for cloning \a p
LqBin(Space& home, bool share, LqBin& p);
/// Constructor for creation
LqBin(Home home, A x0, B x1, Val c);
public:
/// Constructor for rewriting \a p during cloning
LqBin(Space& home, bool share, Propagator& p, A x0, B x1, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$x_0+x_1 \leq c\f$
static ExecStatus post(Home home, A x0, B x1, Val c);
};
/**
* \brief %Propagator for bounds consistent binary linear greater or equal
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B>
class GqBin : public LinBin<Val,A,B,PC_INT_BND> {
protected:
using LinBin<Val,A,B,PC_INT_BND>::x0;
using LinBin<Val,A,B,PC_INT_BND>::x1;
using LinBin<Val,A,B,PC_INT_BND>::c;
/// Constructor for cloning \a p
GqBin(Space& home, bool share, GqBin& p);
/// Constructor for creation
GqBin(Home home, A x0, B x1, Val c);
public:
/// Constructor for rewriting \a p during cloning
GqBin(Space& home, bool share, Propagator& p, A x0, B x1, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$x_0+x_1 \geq c\f$
static ExecStatus post(Home home, A x0, B x1, Val c);
};
/**
* \brief %Propagator for reified bounds consistent binary linear less or equal
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A and \a B
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B>
class ReLqBin : public ReLinBin<Val,A,B,PC_INT_BND,BoolView> {
protected:
using ReLinBin<Val,A,B,PC_INT_BND,BoolView>::x0;
using ReLinBin<Val,A,B,PC_INT_BND,BoolView>::x1;
using ReLinBin<Val,A,B,PC_INT_BND,BoolView>::c;
using ReLinBin<Val,A,B,PC_INT_BND,BoolView>::b;
/// Constructor for cloning \a p
ReLqBin(Space& home, bool share, ReLqBin& p);
/// Constructor for creation
ReLqBin(Home home, A x0, B x1, Val c, BoolView b);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$(x_0+x_1 \leq c)\Leftrightarrow b\f$
static ExecStatus post(Home home, A x0, B x1, Val c, BoolView b);
};
}}}
#include <gecode/int/linear/int-bin.hpp>
namespace Gecode { namespace Int { namespace Linear {
/*
* Ternary propagators
*
*/
/**
* \brief Base-class for ternary linear propagators
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A, \a B,
* and \a C give the types of the views.
*
* The propagation condition \a pc refers to all three views.
*/
template<class Val, class A, class B, class C, PropCond pc>
class LinTer : public Propagator {
protected:
/// View of type \a A
A x0;
/// View of type \a B
B x1;
/// View of type \a C
C x2;
/// Value of type \a Val
Val c;
/// Constructor for cloning \a p
LinTer(Space& home, bool share, LinTer& p);
/// Constructor for creation
LinTer(Home home, A x0, B x1, C x2, Val c);
/// Constructor for rewriting \a p during cloning
LinTer(Space& home, bool share, Propagator& p, A x0, B x1, C x2, Val c);
public:
/// Cost function (defined as low ternary)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief %Propagator for bounds consistent ternary linear equality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A, \a B,
* and \a C give the types of the views.
*
* The propagation condition \a pc refers to all three views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B, class C>
class EqTer : public LinTer<Val,A,B,C,PC_INT_BND> {
protected:
using LinTer<Val,A,B,C,PC_INT_BND>::x0;
using LinTer<Val,A,B,C,PC_INT_BND>::x1;
using LinTer<Val,A,B,C,PC_INT_BND>::x2;
using LinTer<Val,A,B,C,PC_INT_BND>::c;
/// Constructor for cloning \a p
EqTer(Space& home, bool share, EqTer& p);
/// Constructor for creation
EqTer(Home home, A x0, B x1, C x2, Val c);
public:
/// Constructor for rewriting \a p during cloning
EqTer(Space& home, bool share, Propagator& p, A x0, B x1, C x2, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$x_0+x_1+x_2 = c\f$
static ExecStatus post(Home home, A x0, B x1, C x2, Val c);
};
/**
* \brief %Propagator for bounds consistent ternary linear disquality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A, \a B,
* and \a C give the types of the views.
*
* The propagation condition \a pc refers to all three views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B, class C>
class NqTer : public LinTer<Val,A,B,C,PC_INT_VAL> {
protected:
using LinTer<Val,A,B,C,PC_INT_VAL>::x0;
using LinTer<Val,A,B,C,PC_INT_VAL>::x1;
using LinTer<Val,A,B,C,PC_INT_VAL>::x2;
using LinTer<Val,A,B,C,PC_INT_VAL>::c;
/// Constructor for cloning \a p
NqTer(Space& home, bool share, NqTer& p);
/// Constructor for creation
NqTer(Home home, A x0, B x1, C x2, Val c);
public:
/// Constructor for rewriting \a p during cloning
NqTer(Space& home, bool share, Propagator& p, A x0, B x1, C x2, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$x_0+x_1+x_2 \neq c\f$
static ExecStatus post(Home home, A x0, B x1, C x2, Val c);
};
/**
* \brief %Propagator for bounds consistent ternary linear less or equal
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a A, \a B,
* and \a C give the types of the views.
*
* The propagation condition \a pc refers to all three views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class A, class B, class C>
class LqTer : public LinTer<Val,A,B,C,PC_INT_BND> {
protected:
using LinTer<Val,A,B,C,PC_INT_BND>::x0;
using LinTer<Val,A,B,C,PC_INT_BND>::x1;
using LinTer<Val,A,B,C,PC_INT_BND>::x2;
using LinTer<Val,A,B,C,PC_INT_BND>::c;
/// Constructor for cloning \a p
LqTer(Space& home, bool share, LqTer& p);
/// Constructor for creation
LqTer(Home home, A x0, B x1, C x2, Val c);
public:
/// Constructor for rewriting \a p during cloning
LqTer(Space& home, bool share, Propagator& p, A x0, B x1, C x2, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$x_0+x_1+x_2 \leq c\f$
static ExecStatus post(Home home, A x0, B x1, C x2, Val c);
};
}}}
#include <gecode/int/linear/int-ter.hpp>
namespace Gecode { namespace Int { namespace Linear {
/*
* n-ary propagators
*
*/
/**
* \brief Base-class for n-ary linear propagators
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. Positive views are of
* type \a P whereas negative views are of type \a N.
*
* The propagation condition \a pc refers to all views.
*/
template<class Val, class P, class N, PropCond pc>
class Lin : public Propagator {
protected:
/// Array of positive views
ViewArray<P> x;
/// Array of negative views
ViewArray<N> y;
/// Constant value
Val c;
/// Constructor for cloning \a p
Lin(Space& home, bool share, Lin<Val,P,N,pc>& p);
/// Constructor for creation
Lin(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
public:
/// Cost function (defined as low linear)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief Base-class for reified n-ary linear propagators
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. Positive views are of
* type \a P whereas negative views are of type \a N.
*
* The propagation condition \a pc refers to all views.
*/
template<class Val, class P, class N, PropCond pc, class Ctrl>
class ReLin : public Lin<Val,P,N,pc> {
protected:
/// Control view for reification
Ctrl b;
/// Constructor for cloning \a p
ReLin(Space& home, bool share, ReLin& p);
/// Constructor for creation
ReLin(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c, Ctrl b);
public:
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief Compute bounds information for positive views
*
* \relates Lin
*/
template<class Val, class View>
void bounds_p(ModEventDelta med, ViewArray<View>& x,
Val& c, Val& sl, Val& su);
/**
* \brief Compute bounds information for negative views
*
* \relates Lin
*/
template<class Val, class View>
void bounds_n(ModEventDelta med, ViewArray<View>& y,
Val& c, Val& sl, Val& su);
/**
* \brief %Propagator for bounds consistent n-ary linear equality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a P and \a N
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class P, class N>
class Eq : public Lin<Val,P,N,PC_INT_BND> {
protected:
using Lin<Val,P,N,PC_INT_BND>::x;
using Lin<Val,P,N,PC_INT_BND>::y;
using Lin<Val,P,N,PC_INT_BND>::c;
/// Constructor for cloning \a p
Eq(Space& home, bool share, Eq& p);
public:
/// Constructor for creation
Eq(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i-\sum_{i=0}^{|y|-1}y_i=c\f$
static ExecStatus
post(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
};
/**
* \brief %Propagator for domain consistent n-ary linear equality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a View
* give the type of the view.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class View>
class DomEq
: public Lin<Val,View,View,PC_INT_DOM> {
protected:
using Lin<Val,View,View,PC_INT_DOM>::x;
using Lin<Val,View,View,PC_INT_DOM>::y;
using Lin<Val,View,View,PC_INT_DOM>::c;
/// Constructor for cloning \a p
DomEq(Space& home, bool share, DomEq& p);
public:
/// Constructor for creation
DomEq(Home home, ViewArray<View>& x, ViewArray<View>& y, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/**
* \brief Cost function
*
* If in stage for bounds propagation, the cost is
* low linear. Otherwise it is high crazy.
*/
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i-\sum_{i=0}^{|y|-1}y_i=c\f$
static ExecStatus
post(Home home, ViewArray<View>& x, ViewArray<View>& y, Val c);
};
/**
* \brief %Propagator for reified bounds consistent n-ary linear equality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a P and \a N
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class P, class N, class Ctrl>
class ReEq : public ReLin<Val,P,N,PC_INT_BND,Ctrl> {
protected:
using ReLin<Val,P,N,PC_INT_BND,Ctrl>::x;
using ReLin<Val,P,N,PC_INT_BND,Ctrl>::y;
using ReLin<Val,P,N,PC_INT_BND,Ctrl>::c;
using ReLin<Val,P,N,PC_INT_BND,Ctrl>::b;
/// Constructor for cloning \a p
ReEq(Space& home, bool share, ReEq& p);
public:
/// Constructor for creation
ReEq(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c, Ctrl b);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\left(\sum_{i=0}^{|x|-1}x_i-\sum_{i=0}^{|y|-1}y_i=c\right)\Leftrightarrow b\f$
static ExecStatus
post(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c, Ctrl b);
};
/**
* \brief %Propagator for bounds consistent n-ary linear disequality
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a P and \a N
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class P, class N>
class Nq : public Lin<Val,P,N,PC_INT_VAL> {
protected:
using Lin<Val,P,N,PC_INT_VAL>::x;
using Lin<Val,P,N,PC_INT_VAL>::y;
using Lin<Val,P,N,PC_INT_VAL>::c;
/// Constructor for cloning \a p
Nq(Space& home, bool share, Nq& p);
public:
/// Constructor for creation
Nq(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i-\sum_{i=0}^{|y|-1}y_i\neq c\f$
static ExecStatus
post(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
};
/**
* \brief %Propagator for bounds consistent n-ary linear less or equal
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a P and \a N
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class P, class N>
class Lq : public Lin<Val,P,N,PC_INT_BND> {
protected:
using Lin<Val,P,N,PC_INT_BND>::x;
using Lin<Val,P,N,PC_INT_BND>::y;
using Lin<Val,P,N,PC_INT_BND>::c;
/// Constructor for cloning \a p
Lq(Space& home, bool share, Lq& p);
public:
/// Constructor for creation
Lq(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i-\sum_{i=0}^{|y|-1}y_i\leq c\f$
static ExecStatus
post(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c);
};
/**
* \brief %Propagator for reified bounds consistent n-ary linear less or equal
*
* The type \a Val can be either \c double or \c int, defining the
* numerical precision during propagation. The types \a P and \a N
* give the types of the views.
*
* The propagation condition \a pc refers to both views.
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class Val, class P, class N>
class ReLq : public ReLin<Val,P,N,PC_INT_BND,BoolView> {
protected:
using ReLin<Val,P,N,PC_INT_BND,BoolView>::x;
using ReLin<Val,P,N,PC_INT_BND,BoolView>::y;
using ReLin<Val,P,N,PC_INT_BND,BoolView>::c;
using ReLin<Val,P,N,PC_INT_BND,BoolView>::b;
/// Constructor for cloning \a p
ReLq(Space& home, bool share, ReLq& p);
public:
/// Constructor for creation
ReLq(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c, BoolView b);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\left(\sum_{i=0}^{|x|-1}x_i-\sum_{i=0}^{|y|-1}y_i\leq c\right)\Leftrightarrow b\f$
static ExecStatus
post(Home home, ViewArray<P>& x, ViewArray<N>& y, Val c, BoolView b);
};
}}}
#include <gecode/int/linear/int-nary.hpp>
#include <gecode/int/linear/int-dom.hpp>
namespace Gecode { namespace Int { namespace Linear {
/*
* Boolean linear propagators
*
*/
/**
* \brief Baseclass for integer Boolean sum
*
*/
template<class VX>
class LinBoolInt : public Propagator {
protected:
/// Council for managing single advisor
Council<Advisor> co;
/// Boolean views
ViewArray<VX> x;
/// Number of active subscriptions
int n_as;
/// Number of views that have or had subscriptions
int n_hs;
/// Righthandside
int c;
/// Normalize by removing unused views
void normalize(void);
/// Constructor for cloning \a p
LinBoolInt(Space& home, bool share, LinBoolInt& p);
/// Constructor for creation
LinBoolInt(Home home, ViewArray<VX>& x, int n_s, int c);
public:
/// Cost function (defined as high unary)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief %Propagator for integer equal to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class VX>
class EqBoolInt : public LinBoolInt<VX> {
protected:
using LinBoolInt<VX>::co;
using LinBoolInt<VX>::x;
using LinBoolInt<VX>::n_as;
using LinBoolInt<VX>::n_hs;
using LinBoolInt<VX>::c;
/// Constructor for cloning \a p
EqBoolInt(Space& home, bool share, EqBoolInt& p);
/// Constructor for creation
EqBoolInt(Home home, ViewArray<VX>& x, int c);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Give advice to propagator
virtual ExecStatus advise(Space& home, Advisor& a, const Delta& d);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i = c\f$
static ExecStatus post(Home home, ViewArray<VX>& x, int c);
};
/**
* \brief %Propagator for integer less or equal to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class VX>
class GqBoolInt : public LinBoolInt<VX> {
protected:
using LinBoolInt<VX>::co;
using LinBoolInt<VX>::x;
using LinBoolInt<VX>::n_as;
using LinBoolInt<VX>::n_hs;
using LinBoolInt<VX>::c;
/// Constructor for cloning \a p
GqBoolInt(Space& home, bool share, GqBoolInt& p);
/// Constructor for creation
GqBoolInt(Home home, ViewArray<VX>& x, int c);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Give advice to propagator
virtual ExecStatus advise(Space& home, Advisor& a, const Delta& d);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i \geq c\f$
static ExecStatus post(Home home, ViewArray<VX>& x, int c);
};
/**
* \brief %Propagator for integer disequal to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class VX>
class NqBoolInt : public BinaryPropagator<VX,PC_INT_VAL> {
protected:
using BinaryPropagator<VX,PC_INT_VAL>::x0;
using BinaryPropagator<VX,PC_INT_VAL>::x1;
/// Views not yet subscribed to
ViewArray<VX> x;
/// Righthandside
int c;
/// Update subscription
bool resubscribe(Space& home, VX& y);
/// Constructor for posting
NqBoolInt(Home home, ViewArray<VX>& b, int c);
/// Constructor for cloning \a p
NqBoolInt(Space& home, bool share, NqBoolInt<VX>& p);
public:
/// Copy propagator during cloning
virtual Actor* copy(Space& home, bool share);
/// Cost function (defined as low linear)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i \neq c\f$
static ExecStatus post(Home home, ViewArray<VX>& b, int c);
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief Baseclass for reified integer Boolean sum
*
*/
template<class VX, class VB>
class ReLinBoolInt : public Propagator {
protected:
/// Council for single advisor
Council<Advisor> co;
/// Views
ViewArray<VX> x;
/// Number of subscriptions
int n_s;
/// Righthandside
int c;
/// Control variable
VB b;
/// Normalize by removing unused views
void normalize(void);
/// Constructor for cloning \a p
ReLinBoolInt(Space& home, bool share, ReLinBoolInt& p);
/// Constructor for creation
ReLinBoolInt(Home home, ViewArray<VX>& x, int c, VB b);
public:
/// Cost function (defined as high unary)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief Traits for Boolean negation view
*/
template<class BV>
class BoolNegTraits {};
/**
* \brief %Propagator for reified integer less or equal to Boolean sum (cardinality)
*
* Requires \code #include "gecode/int/linear.hh" \endcode
* \ingroup FuncIntProp
*/
template<class VX, class VB>
class ReGqBoolInt : public ReLinBoolInt<VX,VB> {
protected:
using ReLinBoolInt<VX,VB>::co;
using ReLinBoolInt<VX,VB>::x;
using ReLinBoolInt<VX,VB>::c;
using ReLinBoolInt<VX,VB>::b;
using ReLinBoolInt<VX,VB>::n_s;
using ReLinBoolInt<VX,VB>::normalize;
/// Constructor for cloning \a p
ReGqBoolInt(Space& home, bool share, ReGqBoolInt& p);
/// Constructor for creation
ReGqBoolInt(Home home, ViewArray<VX>& x, int c, VB b);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Give advice to propagator
virtual ExecStatus advise(Space& home, Advisor& a, const Delta& d);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\left(\sum_{i=0}^{|x|-1}x_i \geq\right) c \Leftrightarrow b\f$
static ExecStatus post(Home home, ViewArray<VX>& x, int c, VB b);
};
/**
* \brief %Propagator for reified integer equal to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class VX, class VB>
class ReEqBoolInt : public ReLinBoolInt<VX,VB> {
protected:
using ReLinBoolInt<VX,VB>::co;
using ReLinBoolInt<VX,VB>::x;
using ReLinBoolInt<VX,VB>::c;
using ReLinBoolInt<VX,VB>::b;
using ReLinBoolInt<VX,VB>::n_s;
using ReLinBoolInt<VX,VB>::normalize;
/// Constructor for cloning \a p
ReEqBoolInt(Space& home, bool share, ReEqBoolInt& p);
/// Constructor for creation
ReEqBoolInt(Home home, ViewArray<VX>& x, int c, VB b);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Give advice to propagator
virtual ExecStatus advise(Space& home, Advisor& a, const Delta& d);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\left(\sum_{i=0}^{|x|-1}x_i = c\right)\Leftrightarrow b\f$
static ExecStatus post(Home home, ViewArray<VX>& x, int c, VB b);
};
}}}
#include <gecode/int/linear/bool-int.hpp>
namespace Gecode { namespace Int { namespace Linear {
/**
* \brief Base-class for Boolean linear propagators
*
*/
template<class XV, class YV>
class LinBoolView : public Propagator {
protected:
/// Boolean views
ViewArray<XV> x;
/// View to compare number of assigned Boolean views to
YV y;
/// Righthandside (constant part from Boolean views assigned to 1)
int c;
/// Constructor for cloning \a p
LinBoolView(Space& home, bool share, LinBoolView& p);
/// Constructor for creation
LinBoolView(Home home, ViewArray<XV>& x, YV y, int c);
public:
/// Cost function (defined as low linear)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief %Propagator for equality to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class XV, class YV>
class EqBoolView : public LinBoolView<XV,YV> {
protected:
using LinBoolView<XV,YV>::x;
using LinBoolView<XV,YV>::y;
using LinBoolView<XV,YV>::c;
/// Constructor for cloning \a p
EqBoolView(Space& home, bool share, EqBoolView& p);
/// Constructor for creation
EqBoolView(Home home, ViewArray<XV>& x, YV y, int c);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i = y+c\f$
static ExecStatus post(Home home, ViewArray<XV>& x, YV y, int c);
};
/**
* \brief %Propagator for disequality to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class XV, class YV>
class NqBoolView : public LinBoolView<XV,YV> {
protected:
using LinBoolView<XV,YV>::x;
using LinBoolView<XV,YV>::y;
using LinBoolView<XV,YV>::c;
/// Constructor for cloning \a p
NqBoolView(Space& home, bool share, NqBoolView& p);
/// Constructor for creation
NqBoolView(Home home, ViewArray<XV>& x, YV y, int c);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i \neq y+c\f$
static ExecStatus post(Home home, ViewArray<XV>& x, YV y, int c);
};
/**
* \brief %Propagator for greater or equal to Boolean sum (cardinality)
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class XV, class YV>
class GqBoolView : public LinBoolView<XV,YV> {
protected:
using LinBoolView<XV,YV>::x;
using LinBoolView<XV,YV>::y;
using LinBoolView<XV,YV>::c;
/// Constructor for cloning \a p
GqBoolView(Space& home, bool share, GqBoolView& p);
/// Constructor for creation
GqBoolView(Home home, ViewArray<XV>& x, YV y, int c);
public:
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator for \f$\sum_{i=0}^{|x|-1}x_i \geq y+c\f$
static ExecStatus post(Home home, ViewArray<XV>& x, YV y, int c);
};
}}}
#include <gecode/int/linear/bool-view.hpp>
namespace Gecode { namespace Int { namespace Linear {
/// Coefficient and Boolean view
class ScaleBool {
public:
/// Integer coefficient
int a;
/// Boolean view
BoolView x;
};
/// Array of scale Boolean views
class ScaleBoolArray {
private:
/// First entry in array
ScaleBool* _fst;
/// One after last entry in array
ScaleBool* _lst;
public:
/// Default constructor
ScaleBoolArray(void);
/// Create array with \a n elements
ScaleBoolArray(Space& home, int n);
/// Subscribe propagator \a p
void subscribe(Space& home, Propagator& p);
/// Cancel propagator \a p
void cancel(Space& home, Propagator& p);
/// Update \a sba during copying
void update(Space& home, bool share, ScaleBoolArray& sba);
/// Return pointer to first element
ScaleBool* fst(void) const;
/// Return pointer after last element
ScaleBool* lst(void) const;
/// Set pointer to first element
void fst(ScaleBool* f);
/// Set pointer after last element
void lst(ScaleBool* l);
/// Test whether array is empty
bool empty(void) const;
/// Return number of elements
int size(void) const;
private:
/// For sorting array in decreasing order of coefficients
class ScaleDec {
public:
bool
operator ()(const ScaleBool& x, const ScaleBool& y);
};
public:
/// Sort array in decreasing order of coefficients
void sort(void);
};
/// Empty array of scale Boolean views
class EmptyScaleBoolArray {
public:
/// Default constructor
EmptyScaleBoolArray(void);
/// Create array with \a n elements
EmptyScaleBoolArray(Space& home, int n);
/// Subscribe propagator \a p
void subscribe(Space& home, Propagator& p);
/// Cancel propagator \a p
void cancel(Space& home, Propagator& p);
/// Update \a sba during copying
void update(Space& home, bool share, EmptyScaleBoolArray& esba);
/// Return pointer to first element
ScaleBool* fst(void) const;
/// Return pointer after last element
ScaleBool* lst(void) const;
/// Set pointer to first element
void fst(ScaleBool* f);
/// Set pointer after last element
void lst(ScaleBool* l);
/// Test whether array is empty
bool empty(void) const;
/// Return number of elements
int size(void) const;
/// Sort array in decreasing order of coefficients
void sort(void);
};
/**
* \brief Base class for linear Boolean constraints with coefficients
*
*/
template<class SBAP, class SBAN, class VX, PropCond pcx>
class LinBoolScale : public Propagator {
protected:
/// Positive Boolean views with coefficients on left-hand side
SBAP p;
/// Negative Boolean views with coefficients on left-hand side
SBAN n;
/// Integer view on right-hand side
VX x;
/// Integer constant on right-hand side
int c;
public:
/// Constructor for creation
LinBoolScale(Home home, SBAP& p, SBAN& n, VX x, int c);
/// Constructor for cloning \a pr
LinBoolScale(Space& home, bool share, Propagator& pr,
SBAP& p, SBAN& n, VX x, int c);
/// Cost function (defined as low linear)
virtual PropCost cost(const Space& home, const ModEventDelta& med) const;
/// Delete propagator and return its size
virtual size_t dispose(Space& home);
};
/**
* \brief %Propagator for equality to Boolean sum with coefficients
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class SBAP, class SBAN, class VX>
class EqBoolScale : public LinBoolScale<SBAP,SBAN,VX,PC_INT_BND> {
protected:
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::p;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::n;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::x;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::c;
public:
/// Constructor for creation
EqBoolScale(Home home, SBAP& p, SBAN& n, VX x, int c);
/// Constructor for cloning \a pr
EqBoolScale(Space& home, bool share, Propagator& pr,
SBAP& p, SBAN& n, VX x, int c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator
static ExecStatus post(Home home, SBAP& p, SBAN& n, VX x, int c);
};
/**
* \brief %Propagator for inequality to Boolean sum with coefficients
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class SBAP, class SBAN, class VX>
class LqBoolScale : public LinBoolScale<SBAP,SBAN,VX,PC_INT_BND> {
protected:
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::p;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::n;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::x;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_BND>::c;
public:
/// Constructor for creation
LqBoolScale(Home home, SBAP& p, SBAN& n, VX x, int c);
/// Constructor for cloning \a pr
LqBoolScale(Space& home, bool share, Propagator& pr,
SBAP& p, SBAN& n, VX x, int c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator
static ExecStatus post(Home home, SBAP& p, SBAN& n, VX x, int c);
};
/**
* \brief %Propagator for disequality to Boolean sum with coefficients
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
template<class SBAP, class SBAN, class VX>
class NqBoolScale : public LinBoolScale<SBAP,SBAN,VX,PC_INT_VAL> {
protected:
using LinBoolScale<SBAP,SBAN,VX,PC_INT_VAL>::p;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_VAL>::n;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_VAL>::x;
using LinBoolScale<SBAP,SBAN,VX,PC_INT_VAL>::c;
public:
/// Constructor for creation
NqBoolScale(Home home, SBAP& p, SBAN& n, VX x, int c);
/// Constructor for cloning \a pr
NqBoolScale(Space& home, bool share, Propagator& pr,
SBAP& p, SBAN& n, VX x, int c);
/// Create copy during cloning
virtual Actor* copy(Space& home, bool share);
/// Perform propagation
virtual ExecStatus propagate(Space& home, const ModEventDelta& med);
/// Post propagator
static ExecStatus post(Home home, SBAP& p, SBAN& n, VX x, int c);
};
}}}
#include <gecode/int/linear/bool-scale.hpp>
namespace Gecode { namespace Int { namespace Linear {
/**
* \brief Class for describing linear term \f$a\cdot x\f$
*
*/
template<class View>
class Term {
public:
/// Coefficient
int a;
/// View
View x;
};
/** \brief Estimate lower and upper bounds
*
* Estimates the boundaries for a linear expression
* \f$\sum_{i=0}^{n-1}t_i + c\f$. If the boundaries exceed
* the limits as defined in Limits::Int, these boundaries
* are returned.
*
* \param t array of linear terms
* \param n size of array
* \param c constant
* \param l lower bound
* \param u upper bound
*
*/
template<class View>
void estimate(Term<View>* t, int n, int c,
int& l, int& u);
/** \brief Normalize linear integer constraints
*
* \param t array of linear terms
* \param n size of array
* \param t_p array of linear terms over integers with positive coefficients
* \param n_p number of postive terms
* \param t_n array of linear terms over integers with negative coefficients
* \param n_n number of negative terms
*
* Replaces all negative coefficients by positive coefficients.
*
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
*
* Returns true, if all coefficients are unit coefficients
*/
template<class View>
bool normalize(Term<View>* t, int &n,
Term<View>* &t_p, int &n_p,
Term<View>* &t_n, int &n_n);
/**
* \brief Post propagator for linear constraint over integers
* \param home current space
* \param t array of linear terms over integers
* \param n size of array
* \param r type of relation
* \param c result of linear constraint
*
* All variants for linear constraints share the following properties:
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
* - Assume linear terms for the constraint
* \f$\sum_{i=0}^{|x|-1}a_i\cdot x_i\sim_r c\f$.
* If \f$|c|+\sum_{i=0}^{|x|-1}a_i\cdot x_i\f$ exceeds the limits
* for doubles as defined in Limits::Int, an exception of
* type Int::NumericalOverflow is thrown.
* - In all other cases, the created propagators are accurate (that
* is, they will not silently overflow during propagation).
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
GECODE_INT_EXPORT void
post(Home home, Term<IntView>* t, int n, IntRelType r, int c,
IntConLevel=ICL_DEF);
/**
* \brief Post reified propagator for linear constraint
* \param home current space
* \param t array of linear terms
* \param n size of array
* \param r type of relation
* \param c result of linear constraint
* \param b Boolean control view
*
* All variants for linear constraints share the following properties:
* - Only bounds consistency is supported.
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
* - Assume linear terms for the constraint
* \f$\sum_{i=0}^{|x|-1}a_i\cdot x_i\sim_r c\f$.
* If \f$|c|+\sum_{i=0}^{|x|-1}a_i\cdot x_i\f$ exceeds the limits
* for doubles as defined in Limits::Int, an exception of
* type Int::NumericalOverflow is thrown.
* - In all other cases, the created propagators are accurate (that
* is, they will not silently overflow during propagation).
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
GECODE_INT_EXPORT void
post(Home home, Term<IntView>* t, int n, IntRelType r, int c, BoolView b,
IntConLevel=ICL_DEF);
/**
* \brief Post propagator for linear constraint over Booleans
* \param home current space
* \param t array of linear terms over Booleans
* \param n size of array
* \param r type of relation
* \param c result of linear constraint
*
* All variants for linear constraints share the following properties:
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
* - Assume linear terms for the constraint
* \f$\sum_{i=0}^{|x|-1}a_i\cdot x_i\sim_r c\f$.
* If \f$|c|+\sum_{i=0}^{|x|-1}a_i\cdot x_i\f$ exceeds the limits
* for integers as defined in Limits::Int, an exception of
* type Int::NumericalOverflow is thrown.
* - In all other cases, the created propagators are accurate (that
* is, they will not silently overflow during propagation).
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
GECODE_INT_EXPORT void
post(Home home, Term<BoolView>* t, int n, IntRelType r, int c,
IntConLevel=ICL_DEF);
/**
* \brief Post propagator for reified linear constraint over Booleans
* \param home current space
* \param t array of linear terms over Booleans
* \param n size of array
* \param r type of relation
* \param c result of linear constraint
* \param b Boolean control varaible
*
* All variants for linear constraints share the following properties:
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
* - Assume linear terms for the constraint
* \f$\sum_{i=0}^{|x|-1}a_i\cdot x_i\sim_r c\f$.
* If \f$|c|+\sum_{i=0}^{|x|-1}a_i\cdot x_i\f$ exceeds the limits
* for integers as defined in Limits::Int, an exception of
* type Int::NumericalOverflow is thrown.
* - In all other cases, the created propagators are accurate (that
* is, they will not silently overflow during propagation).
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
GECODE_INT_EXPORT void
post(Home home, Term<BoolView>* t, int n, IntRelType r, int c, BoolView b,
IntConLevel=ICL_DEF);
/**
* \brief Post propagator for linear constraint over Booleans
* \param home current space
* \param t array of linear terms over Booleans
* \param n size of array
* \param r type of relation
* \param y variable right hand side of linear constraint
* \param c constant right hand side of linear constraint
*
* All variants for linear constraints share the following properties:
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
* - Assume linear terms for the constraint
* \f$\sum_{i=0}^{|x|-1}a_i\cdot x_i\sim_r c\f$.
* If \f$|c|+\sum_{i=0}^{|x|-1}a_i\cdot x_i\f$ exceeds the limits
* for integers as defined in Limits::Int, an exception of
* type Int::NumericalOverflow is thrown.
* - In all other cases, the created propagators are accurate (that
* is, they will not silently overflow during propagation).
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
GECODE_INT_EXPORT void
post(Home home, Term<BoolView>* t, int n, IntRelType r, IntView y, int c=0,
IntConLevel=ICL_DEF);
/**
* \brief Post propagator for reified linear constraint over Booleans
* \param home current space
* \param t array of linear terms over Booleans
* \param n size of array
* \param r type of relation
* \param y variable right hand side of linear constraint
* \param b Boolean control variable
*
* All variants for linear constraints share the following properties:
* - Variables occuring multiply in the term array are replaced
* by a single occurence: for example, \f$ax+bx\f$ becomes
* \f$(a+b)x\f$.
* - If in the above simplification the value for \f$(a+b)\f$ (or for
* \f$a\f$ and \f$b\f$) exceeds the limits for integers as
* defined in Limits::Int, an exception of type
* Int::NumericalOverflow is thrown.
* - Assume linear terms for the constraint
* \f$\sum_{i=0}^{|x|-1}a_i\cdot x_i\sim_r c\f$.
* If \f$|c|+\sum_{i=0}^{|x|-1}a_i\cdot x_i\f$ exceeds the limits
* for integers as defined in Limits::Int, an exception of
* type Int::NumericalOverflow is thrown.
* - In all other cases, the created propagators are accurate (that
* is, they will not silently overflow during propagation).
*
* Requires \code #include <gecode/int/linear.hh> \endcode
* \ingroup FuncIntProp
*/
GECODE_INT_EXPORT void
post(Home home, Term<BoolView>* t, int n, IntRelType r, IntView y,
BoolView b, IntConLevel=ICL_DEF);
}}}
#include <gecode/int/linear/post.hpp>
#endif
// STATISTICS: int-prop
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