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openpilot is an open source driver assistance system. openpilot performs the functions of Automated Lane Centering and Adaptive Cruise Control for over 200 supported car makes and models.
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openpilot_comma/phonelibs/qpoases/SRC/QProblem.ipp

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/*
* This file is part of qpOASES.
*
* qpOASES -- An Implementation of the Online Active Set Strategy.
* Copyright (C) 2007-2008 by Hans Joachim Ferreau et al. All rights reserved.
*
* qpOASES is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* qpOASES is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with qpOASES; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
*/
/**
* \file SRC/QProblem.ipp
* \author Hans Joachim Ferreau
* \version 1.3embedded
* \date 2007-2008
*
* Implementation of inlined member functions of the QProblem class which
* is able to use the newly developed online active set strategy for
* parametric quadratic programming.
*/
/*****************************************************************************
* P U B L I C *
*****************************************************************************/
/*
* g e t A
*/
inline returnValue QProblem::getA( real_t* const _A ) const
{
int i;
for ( i=0; i<getNV( )*getNC( ); ++i )
_A[i] = A[i];
return SUCCESSFUL_RETURN;
}
/*
* g e t A
*/
inline returnValue QProblem::getA( int number, real_t* const row ) const
{
int nV = getNV( );
if ( ( number >= 0 ) && ( number < getNC( ) ) )
{
for ( int i=0; i<nV; ++i )
row[i] = A[number*NVMAX + i];
return SUCCESSFUL_RETURN;
}
else
return THROWERROR( RET_INDEX_OUT_OF_BOUNDS );
}
/*
* g e t L B A
*/
inline returnValue QProblem::getLBA( real_t* const _lbA ) const
{
int i;
for ( i=0; i<getNC( ); ++i )
_lbA[i] = lbA[i];
return SUCCESSFUL_RETURN;
}
/*
* g e t L B A
*/
inline returnValue QProblem::getLBA( int number, real_t& value ) const
{
if ( ( number >= 0 ) && ( number < getNC( ) ) )
{
value = lbA[number];
return SUCCESSFUL_RETURN;
}
else
return THROWERROR( RET_INDEX_OUT_OF_BOUNDS );
}
/*
* g e t U B A
*/
inline returnValue QProblem::getUBA( real_t* const _ubA ) const
{
int i;
for ( i=0; i<getNC( ); ++i )
_ubA[i] = ubA[i];
return SUCCESSFUL_RETURN;
}
/*
* g e t U B A
*/
inline returnValue QProblem::getUBA( int number, real_t& value ) const
{
if ( ( number >= 0 ) && ( number < getNC( ) ) )
{
value = ubA[number];
return SUCCESSFUL_RETURN;
}
else
return THROWERROR( RET_INDEX_OUT_OF_BOUNDS );
}
/*
* g e t C o n s t r a i n t s
*/
inline returnValue QProblem::getConstraints( Constraints* const _constraints ) const
{
*_constraints = constraints;
return SUCCESSFUL_RETURN;
}
/*
* g e t N C
*/
inline int QProblem::getNC( ) const
{
return constraints.getNC( );
}
/*
* g e t N E C
*/
inline int QProblem::getNEC( ) const
{
return constraints.getNEC( );
}
/*
* g e t N A C
*/
inline int QProblem::getNAC( )
{
return constraints.getNAC( );
}
/*
* g e t N I A C
*/
inline int QProblem::getNIAC( )
{
return constraints.getNIAC( );
}
/*****************************************************************************
* P R O T E C T E D *
*****************************************************************************/
/*
* s e t A
*/
inline returnValue QProblem::setA( const real_t* const A_new )
{
int i, j;
int nV = getNV( );
int nC = getNC( );
/* Set constraint matrix AND update member AX. */
for( j=0; j<nC; ++j )
{
Ax[j] = 0.0;
for( i=0; i<nV; ++i )
{
A[j*NVMAX + i] = A_new[j*nV + i];
Ax[j] += A[j*NVMAX + i] * x[i];
}
}
return SUCCESSFUL_RETURN;
}
/*
* s e t A
*/
inline returnValue QProblem::setA( int number, const real_t* const row )
{
int i;
int nV = getNV( );
/* Set constraint matrix AND update member AX. */
if ( ( number >= 0 ) && ( number < getNC( ) ) )
{
Ax[number] = 0.0;
for( i=0; i<nV; ++i )
{
A[number*NVMAX + i] = row[i];
Ax[number] += A[number*NVMAX + i] * x[i];
}
return SUCCESSFUL_RETURN;
}
else
return THROWERROR( RET_INDEX_OUT_OF_BOUNDS );
}
/*
* s e t L B A
*/
inline returnValue QProblem::setLBA( const real_t* const lbA_new )
{
int i;
int nC = getNC();
for( i=0; i<nC; ++i )
lbA[i] = lbA_new[i];
return SUCCESSFUL_RETURN;
}
/*
* s e t L B A
*/
inline returnValue QProblem::setLBA( int number, real_t value )
{
if ( ( number >= 0 ) && ( number < getNC( ) ) )
{
lbA[number] = value;
return SUCCESSFUL_RETURN;
}
else
return THROWERROR( RET_INDEX_OUT_OF_BOUNDS );
}
/*
* s e t U B A
*/
inline returnValue QProblem::setUBA( const real_t* const ubA_new )
{
int i;
int nC = getNC();
for( i=0; i<nC; ++i )
ubA[i] = ubA_new[i];
return SUCCESSFUL_RETURN;
}
/*
* s e t U B A
*/
inline returnValue QProblem::setUBA( int number, real_t value )
{
if ( ( number >= 0 ) && ( number < getNC( ) ) )
{
ubA[number] = value;
return SUCCESSFUL_RETURN;
}
else
return THROWERROR( RET_INDEX_OUT_OF_BOUNDS );
}
/*
* end of file
*/