/* $Id$ */
// Copyright (C) 2003, International Business Machines
// Corporation and others. All Rights Reserved.
// This code is licensed under the terms of the Eclipse Public License (EPL).
#ifndef ClpNetworkMatrix_H
#define ClpNetworkMatrix_H
#include "CoinPragma.hpp"
#include "ClpMatrixBase.hpp"
/** This implements a simple network matrix as derived from ClpMatrixBase.
If you want more sophisticated version then you could inherit from this.
Also you might want to allow networks with gain */
class ClpNetworkMatrix : public ClpMatrixBase {
public:
/**@name Useful methods */
//@{
/// Return a complete CoinPackedMatrix
virtual CoinPackedMatrix *getPackedMatrix() const;
/** Whether the packed matrix is column major ordered or not. */
virtual bool isColOrdered() const
{
return true;
}
/** Number of entries in the packed matrix. */
virtual CoinBigIndex getNumElements() const
{
return 2 * numberColumns_;
}
/** Number of columns. */
virtual int getNumCols() const
{
return numberColumns_;
}
/** Number of rows. */
virtual int getNumRows() const
{
return numberRows_;
}
/** A vector containing the elements in the packed matrix. Note that there
might be gaps in this list, entries that do not belong to any
major-dimension vector. To get the actual elements one should look at
this vector together with vectorStarts and vectorLengths. */
virtual const double *getElements() const;
/** A vector containing the minor indices of the elements in the packed
matrix. Note that there might be gaps in this list, entries that do not
belong to any major-dimension vector. To get the actual elements one
should look at this vector together with vectorStarts and
vectorLengths. */
virtual const int *getIndices() const
{
return indices_;
}
virtual const CoinBigIndex *getVectorStarts() const;
/** The lengths of the major-dimension vectors. */
virtual const int *getVectorLengths() const;
/** Delete the columns whose indices are listed in indDel. */
virtual void deleteCols(const int numDel, const int *indDel);
/** Delete the rows whose indices are listed in indDel. */
virtual void deleteRows(const int numDel, const int *indDel);
/// Append Columns
virtual void appendCols(int number, const CoinPackedVectorBase *const *columns);
/// Append Rows
virtual void appendRows(int number, const CoinPackedVectorBase *const *rows);
#ifndef SLIM_CLP
/** Append a set of rows/columns to the end of the matrix. Returns number of errors
i.e. if any of the new rows/columns contain an index that's larger than the
number of columns-1/rows-1 (if numberOther>0) or duplicates
If 0 then rows, 1 if columns */
virtual int appendMatrix(int number, int type,
const CoinBigIndex *starts, const int *index,
const double *element, int numberOther = -1);
#endif
/** Returns a new matrix in reverse order without gaps */
virtual ClpMatrixBase *reverseOrderedCopy() const;
/// Returns number of elements in column part of basis
virtual int countBasis(
const int *whichColumn,
int &numberColumnBasic);
/// Fills in column part of basis
virtual void fillBasis(ClpSimplex *model,
const int *whichColumn,
int &numberColumnBasic,
int *row, int *start,
int *rowCount, int *columnCount,
CoinFactorizationDouble *element);
/** Given positive integer weights for each row fills in sum of weights
for each column (and slack).
Returns weights vector
*/
virtual CoinBigIndex *dubiousWeights(const ClpSimplex *model, int *inputWeights) const;
/** Returns largest and smallest elements of both signs.
Largest refers to largest absolute value.
*/
virtual void rangeOfElements(double &smallestNegative, double &largestNegative,
double &smallestPositive, double &largestPositive);
/** Unpacks a column into an CoinIndexedvector
*/
virtual void unpack(const ClpSimplex *model, CoinIndexedVector *rowArray,
int column) const;
/** Unpacks a column into an CoinIndexedvector
** in packed format
Note that model is NOT const. Bounds and objective could
be modified if doing column generation (just for this variable) */
virtual void unpackPacked(ClpSimplex *model,
CoinIndexedVector *rowArray,
int column) const;
/** Adds multiple of a column into an CoinIndexedvector
You can use quickAdd to add to vector */
virtual void add(const ClpSimplex *model, CoinIndexedVector *rowArray,
int column, double multiplier) const;
/** Adds multiple of a column into an array */
virtual void add(const ClpSimplex *model, double *array,
int column, double multiplier) const;
/// Allow any parts of a created CoinMatrix to be deleted
virtual void releasePackedMatrix() const;
/// Says whether it can do partial pricing
virtual bool canDoPartialPricing() const;
/// Partial pricing
virtual void partialPricing(ClpSimplex *model, double start, double end,
int &bestSequence, int &numberWanted);
//@}
/**@name Matrix times vector methods */
//@{
/** Return y + A * scalar *x in y.
@pre x must be of size numColumns()
@pre y must be of size numRows() */
virtual void times(double scalar,
const double *x, double *y) const;
/// And for scaling
virtual void times(double scalar,
const double *x, double *y,
const double *rowScale,
const double *columnScale) const;
/** Return y + x * scalar * A in y.
@pre x must be of size numRows()
@pre y must be of size numColumns() */
virtual void transposeTimes(double scalar,
const double *x, double *y) const;
/// And for scaling
virtual void transposeTimes(double scalar,
const double *x, double *y,
const double *rowScale,
const double *columnScale, double *spare = NULL) const;
/** Return x * scalar * A + y in z.
Can use y as temporary array (will be empty at end)
Note - If x packed mode - then z packed mode
Squashes small elements and knows about ClpSimplex */
virtual void transposeTimes(const ClpSimplex *model, double scalar,
const CoinIndexedVector *x,
CoinIndexedVector *y,
CoinIndexedVector *z) const;
/** Return x *A in z but
just for indices in y.
Note - z always packed mode */
virtual void subsetTransposeTimes(const ClpSimplex *model,
const CoinIndexedVector *x,
const CoinIndexedVector *y,
CoinIndexedVector *z) const;
//@}
/**@name Other */
//@{
/// Return true if really network, false if has slacks
inline bool trueNetwork() const
{
return trueNetwork_;
}
//@}
/**@name Constructors, destructor */
//@{
/** Default constructor. */
ClpNetworkMatrix();
/** Constructor from two arrays */
ClpNetworkMatrix(int numberColumns, const int *head,
const int *tail);
/** Destructor */
virtual ~ClpNetworkMatrix();
//@}
/**@name Copy method */
//@{
/** The copy constructor. */
ClpNetworkMatrix(const ClpNetworkMatrix &);
/** The copy constructor from an CoinNetworkMatrix. */
ClpNetworkMatrix(const CoinPackedMatrix &);
ClpNetworkMatrix &operator=(const ClpNetworkMatrix &);
/// Clone
virtual ClpMatrixBase *clone() const;
/** Subset constructor (without gaps). Duplicates are allowed
and order is as given */
ClpNetworkMatrix(const ClpNetworkMatrix &wholeModel,
int numberRows, const int *whichRows,
int numberColumns, const int *whichColumns);
/** Subset clone (without gaps). Duplicates are allowed
and order is as given */
virtual ClpMatrixBase *subsetClone(
int numberRows, const int *whichRows,
int numberColumns, const int *whichColumns) const;
//@}
protected:
/**@name Data members
The data members are protected to allow access for derived classes. */
//@{
/// For fake CoinPackedMatrix
mutable CoinPackedMatrix *matrix_;
mutable int *lengths_;
/// Data -1, then +1 rows in pairs (row==-1 if one entry)
int *indices_;
/// Number of rows
int numberRows_;
/// Number of columns
int numberColumns_;
/// True if all entries have two elements
bool trueNetwork_;
//@}
};
#endif
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