dragonpilot/third_party/acados/include/qpOASES_e/extras/OQPinterface.h

/*
 *	This file is part of qpOASES.
 *
 *	qpOASES -- An Implementation of the Online Active Set Strategy.
 *	Copyright (C) 2007-2015 by Hans Joachim Ferreau, Andreas Potschka,
 *	Christian Kirches 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 include/qpOASES_e/extras/OQPinterface.h
 *	\author Hans Joachim Ferreau, Andreas Potschka, Christian Kirches
 *	\version 3.1embedded
 *	\date 2007-2015
 *
 *	Declaration of an interface comprising several utility functions
 *	for solving test problems from the Online QP Benchmark Collection
 *	(This collection is no longer maintained, see
 *	http://www.qpOASES.org/onlineQP for a backup).
 */


#ifndef QPOASES_OQPINTERFACE_H
#define QPOASES_OQPINTERFACE_H


#include <qpOASES_e/Utils.h>
#include <qpOASES_e/Options.h>

#include <qpOASES_e/QProblemB.h>
#include <qpOASES_e/QProblem.h>


BEGIN_NAMESPACE_QPOASES

typedef struct {
	QProblem *qp;

	DenseMatrix *H;
	DenseMatrix *A;

	real_t *x;
	real_t *y;
} OQPbenchmark_ws;

int OQPbenchmark_ws_calculateMemorySize( unsigned int nV, unsigned int nC );

char *OQPbenchmark_ws_assignMemory( unsigned int nV, unsigned int nC, OQPbenchmark_ws **mem, void *raw_memory );

OQPbenchmark_ws *OQPbenchmark_ws_createMemory( unsigned int nV, unsigned int nC );

typedef struct {
	QProblemB *qp;

	DenseMatrix *H;

	real_t *x;
	real_t *y;
} OQPbenchmarkB_ws;

int OQPbenchmarkB_ws_calculateMemorySize( unsigned int nV );

char *OQPbenchmarkB_ws_assignMemory( unsigned int nV, OQPbenchmarkB_ws **mem, void *raw_memory );

OQPbenchmarkB_ws *OQPbenchmarkB_ws_createMemory( unsigned int nV );

typedef struct {
	OQPbenchmark_ws *qp_ws;
	OQPbenchmarkB_ws *qpB_ws;

	real_t *H;
	real_t *g;
	real_t *A;
	real_t *lb;
	real_t *ub;
	real_t *lbA;
	real_t *ubA;
} OQPinterface_ws;

int OQPinterface_ws_calculateMemorySize( unsigned int nV, unsigned int nC, unsigned int nQP  );

char *OQPinterface_ws_assignMemory( unsigned int nV, unsigned int nC, unsigned int nQP, OQPinterface_ws **mem, void *raw_memory );

OQPinterface_ws *OQPinterface_ws_createMemory( unsigned int nV, unsigned int nC, unsigned int nQP );

/** Reads dimensions of an Online QP Benchmark problem from file.
 * \return SUCCESSFUL_RETURN \n
		   RET_UNABLE_TO_READ_FILE \n
		   RET_FILEDATA_INCONSISTENT */
returnValue readOQPdimensions(	const char* path,	/**< Full path of the data files (without trailing slash!). */
								int* nQP,			/**< Output: Number of QPs. */
								int* nV,			/**< Output: Number of variables. */
								int* nC,			/**< Output: Number of constraints. */
								int* nEC			/**< Output: Number of equality constraints. */
								);

/** Reads data of an Online QP Benchmark problem from file.
 *  This function allocates the required memory for all data; after successfully calling it,
 *  you have to free this memory yourself!
 * \return SUCCESSFUL_RETURN \n
		   RET_INVALID_ARGUMENTS \n
		   RET_UNABLE_TO_READ_FILE \n
		   RET_FILEDATA_INCONSISTENT */
returnValue readOQPdata(	const char* path,	/**< Full path of the data files (without trailing slash!). */
							int* nQP,			/**< Output: Number of QPs. */
							int* nV,			/**< Output: Number of variables. */
							int* nC,			/**< Output: Number of constraints. */
							int* nEC,			/**< Output: Number of equality constraints. */
							real_t* H,		 	/**< Output: Hessian matrix. */
							real_t* g,		 	/**< Output: Sequence of gradient vectors. */
							real_t* A,		 	/**< Output: Constraint matrix. */
							real_t* lb,			/**< Output: Sequence of lower bound vectors (on variables). */
							real_t* ub,			/**< Output: Sequence of upper bound vectors (on variables). */
							real_t* lbA,		/**< Output: Sequence of lower constraints' bound vectors. */
							real_t* ubA,		/**< Output: Sequence of upper constraints' bound vectors. */
							real_t* xOpt,		/**< Output: Sequence of primal solution vectors
												 *           (not read if a null pointer is passed). */
							real_t* yOpt,		/**< Output: Sequence of dual solution vectors
												 *           (not read if a null pointer is passed). */
							real_t* objOpt		/**< Output: Sequence of optimal objective function values
												 *           (not read if a null pointer is passed). */
							);


/** Solves an Online QP Benchmark problem as specified by the arguments.
 *  The maximum deviations from the given optimal solution as well as the
 *  maximum CPU time to solve each QP are determined.
 * \return SUCCESSFUL_RETURN \n
 		   RET_BENCHMARK_ABORTED */
returnValue solveOQPbenchmark(	int nQP,					/**< Number of QPs. */
								int nV,						/**< Number of variables. */
								int nC,						/**< Number of constraints. */
								int nEC,					/**< Number of equality constraints. */
								real_t* _H,					/**< Hessian matrix. */
								const real_t* const g,		/**< Sequence of gradient vectors. */
								real_t* _A,					/**< Constraint matrix. */
								const real_t* const lb,		/**< Sequence of lower bound vectors (on variables). */
								const real_t* const ub,		/**< Sequence of upper bound vectors (on variables). */
								const real_t* const lbA,	/**< Sequence of lower constraints' bound vectors. */
								const real_t* const ubA,	/**< Sequence of upper constraints' bound vectors. */
								BooleanType isSparse,		/**< Shall convert matrices to sparse format before solution? */
								BooleanType useHotstarts,	/**< Shall QP solution be hotstarted? */
								const Options* options,		/**< QP solver options to be used while solving benchmark problems. */
								int maxAllowedNWSR, 		/**< Maximum number of working set recalculations to be performed. */
								real_t* maxNWSR,			/**< Output: Maximum number of performed working set recalculations. */
								real_t* avgNWSR,			/**< Output: Average number of performed working set recalculations. */
								real_t* maxCPUtime,			/**< Output: Maximum CPU time required for solving each QP. */
								real_t* avgCPUtime,			/**< Output: Average CPU time required for solving each QP. */
								real_t* maxStationarity,	/**< Output: Maximum residual of stationarity condition. */
								real_t* maxFeasibility,		/**< Output: Maximum residual of primal feasibility condition. */
								real_t* maxComplementarity,	/**< Output: Maximum residual of complementarity condition. */
								OQPbenchmark_ws *work	    /**< Workspace. */
								);

/** Solves an Online QP Benchmark problem (without constraints) as specified
 *  by the arguments. The maximum deviations from the given optimal solution
 *  as well as the maximum CPU time to solve each QP are determined.
 * \return SUCCESSFUL_RETURN \n
 		   RET_BENCHMARK_ABORTED */
returnValue solveOQPbenchmarkB(	int nQP,					/**< Number of QPs. */
								int nV,						/**< Number of variables. */
								real_t* _H,					/**< Hessian matrix. */
								const real_t* const g,		/**< Sequence of gradient vectors. */
								const real_t* const lb,		/**< Sequence of lower bound vectors (on variables). */
								const real_t* const ub,		/**< Sequence of upper bound vectors (on variables). */
								BooleanType isSparse,		/**< Shall convert matrices to sparse format before solution? */
								BooleanType useHotstarts,	/**< Shall QP solution be hotstarted? */
								const Options* options,		/**< QP solver options to be used while solving benchmark problems. */
								int maxAllowedNWSR, 		/**< Maximum number of working set recalculations to be performed. */
								real_t* maxNWSR,			/**< Output: Maximum number of performed working set recalculations. */
								real_t* avgNWSR,			/**< Output: Average number of performed working set recalculations. */
								real_t* maxCPUtime,			/**< Output: Maximum CPU time required for solving each QP. */
								real_t* avgCPUtime,			/**< Output: Average CPU time required for solving each QP. */
								real_t* maxStationarity,	/**< Output: Maximum residual of stationarity condition. */
								real_t* maxFeasibility,		/**< Output: Maximum residual of primal feasibility condition. */
								real_t* maxComplementarity,	/**< Output: Maximum residual of complementarity condition. */
								OQPbenchmarkB_ws *work	    /**< Workspace. */
								);


/** Runs an Online QP Benchmark problem and determines the maximum
 *  violation of the KKT optimality conditions as well as the
 *  maximum and average number of iterations and CPU time to solve
 *	each QP.
 *
 * \return SUCCESSFUL_RETURN \n
		   RET_UNABLE_TO_READ_BENCHMARK \n
 		   RET_BENCHMARK_ABORTED */
returnValue runOQPbenchmark(	const char* path,			/**< Full path of the benchmark files (without trailing slash!). */
								BooleanType isSparse,		/**< Shall convert matrices to sparse format before solution? */
								BooleanType useHotstarts,	/**< Shall QP solution be hotstarted? */
								const Options* options,		/**< QP solver options to be used while solving benchmark problems. */
								int maxAllowedNWSR, 		/**< Maximum number of working set recalculations to be performed. */
								real_t* maxNWSR,			/**< Output: Maximum number of performed working set recalculations. */
								real_t* avgNWSR,			/**< Output: Average number of performed working set recalculations. */
								real_t* maxCPUtime,			/**< Output: Maximum CPU time required for solving each QP. */
								real_t* avgCPUtime,			/**< Output: Average CPU time required for solving each QP. */
								real_t* maxStationarity,	/**< Output: Maximum residual of stationarity condition. */
								real_t* maxFeasibility,		/**< Output: Maximum residual of primal feasibility condition. */
								real_t* maxComplementarity,	/**< Output: Maximum residual of complementarity condition. */
								OQPinterface_ws* work       /**< Workspace. */
								);

END_NAMESPACE_QPOASES


#endif	/* QPOASES_OQPINTERFACE_H */


/*
 *	end of file
 */
acados support (#21319) * acados support * add pyextra to python path * x86 libs 4 years ago			`/*`
			`* This file is part of qpOASES.`
			`*`
			`* qpOASES -- An Implementation of the Online Active Set Strategy.`
			`* Copyright (C) 2007-2015 by Hans Joachim Ferreau, Andreas Potschka,`
			`* Christian Kirches 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 include/qpOASES_e/extras/OQPinterface.h`
			`* \author Hans Joachim Ferreau, Andreas Potschka, Christian Kirches`
			`* \version 3.1embedded`
			`* \date 2007-2015`
			`*`
			`* Declaration of an interface comprising several utility functions`
			`* for solving test problems from the Online QP Benchmark Collection`
			`* (This collection is no longer maintained, see`
			`* http://www.qpOASES.org/onlineQP for a backup).`
			`*/`


			`#ifndef QPOASES_OQPINTERFACE_H`
			`#define QPOASES_OQPINTERFACE_H`


			`#include <qpOASES_e/Utils.h>`
			`#include <qpOASES_e/Options.h>`

			`#include <qpOASES_e/QProblemB.h>`
			`#include <qpOASES_e/QProblem.h>`


			`BEGIN_NAMESPACE_QPOASES`

			`typedef struct {`
			`QProblem *qp;`

			`DenseMatrix *H;`
			`DenseMatrix *A;`

			`real_t *x;`
			`real_t *y;`
			`} OQPbenchmark_ws;`

			`int OQPbenchmark_ws_calculateMemorySize( unsigned int nV, unsigned int nC );`

			`char OQPbenchmark_ws_assignMemory( unsigned int nV, unsigned int nC, OQPbenchmark_ws mem, void raw_memory );`

			`OQPbenchmark_ws *OQPbenchmark_ws_createMemory( unsigned int nV, unsigned int nC );`

			`typedef struct {`
			`QProblemB *qp;`

			`DenseMatrix *H;`

			`real_t *x;`
			`real_t *y;`
			`} OQPbenchmarkB_ws;`

			`int OQPbenchmarkB_ws_calculateMemorySize( unsigned int nV );`

			`char OQPbenchmarkB_ws_assignMemory( unsigned int nV, OQPbenchmarkB_ws mem, void raw_memory );`

			`OQPbenchmarkB_ws *OQPbenchmarkB_ws_createMemory( unsigned int nV );`

			`typedef struct {`
			`OQPbenchmark_ws *qp_ws;`
			`OQPbenchmarkB_ws *qpB_ws;`

			`real_t *H;`
			`real_t *g;`
			`real_t *A;`
			`real_t *lb;`
			`real_t *ub;`
			`real_t *lbA;`
			`real_t *ubA;`
			`} OQPinterface_ws;`

			`int OQPinterface_ws_calculateMemorySize( unsigned int nV, unsigned int nC, unsigned int nQP );`

			`char OQPinterface_ws_assignMemory( unsigned int nV, unsigned int nC, unsigned int nQP, OQPinterface_ws mem, void raw_memory );`

			`OQPinterface_ws *OQPinterface_ws_createMemory( unsigned int nV, unsigned int nC, unsigned int nQP );`

			`/** Reads dimensions of an Online QP Benchmark problem from file.`
			`* \return SUCCESSFUL_RETURN \n`
			`RET_UNABLE_TO_READ_FILE \n`
			`RET_FILEDATA_INCONSISTENT */`
			`returnValue readOQPdimensions( const char* path, /*< Full path of the data files (without trailing slash!). /`
			`int* nQP, /*< Output: Number of QPs. /`
			`int* nV, /*< Output: Number of variables. /`
			`int* nC, /*< Output: Number of constraints. /`
			`int* nEC /*< Output: Number of equality constraints. /`
			`);`

			`/** Reads data of an Online QP Benchmark problem from file.`
			`* This function allocates the required memory for all data; after successfully calling it,`
			`* you have to free this memory yourself!`
			`* \return SUCCESSFUL_RETURN \n`
			`RET_INVALID_ARGUMENTS \n`
			`RET_UNABLE_TO_READ_FILE \n`
			`RET_FILEDATA_INCONSISTENT */`
			`returnValue readOQPdata( const char* path, /*< Full path of the data files (without trailing slash!). /`
			`int* nQP, /*< Output: Number of QPs. /`
			`int* nV, /*< Output: Number of variables. /`
			`int* nC, /*< Output: Number of constraints. /`
			`int* nEC, /*< Output: Number of equality constraints. /`
			`real_t* H, /*< Output: Hessian matrix. /`
			`real_t* g, /*< Output: Sequence of gradient vectors. /`
			`real_t* A, /*< Output: Constraint matrix. /`
			`real_t* lb, /*< Output: Sequence of lower bound vectors (on variables). /`
			`real_t* ub, /*< Output: Sequence of upper bound vectors (on variables). /`
			`real_t* lbA, /*< Output: Sequence of lower constraints' bound vectors. /`
			`real_t* ubA, /*< Output: Sequence of upper constraints' bound vectors. /`
			`real_t* xOpt, /**< Output: Sequence of primal solution vectors`
			`* (not read if a null pointer is passed). */`
			`real_t* yOpt, /**< Output: Sequence of dual solution vectors`
			`* (not read if a null pointer is passed). */`
			`real_t* objOpt /**< Output: Sequence of optimal objective function values`
			`* (not read if a null pointer is passed). */`
			`);`


			`/** Solves an Online QP Benchmark problem as specified by the arguments.`
			`* The maximum deviations from the given optimal solution as well as the`
			`* maximum CPU time to solve each QP are determined.`
			`* \return SUCCESSFUL_RETURN \n`
			`RET_BENCHMARK_ABORTED */`
			`returnValue solveOQPbenchmark( int nQP, /*< Number of QPs. /`
			`int nV, /*< Number of variables. /`
			`int nC, /*< Number of constraints. /`
			`int nEC, /*< Number of equality constraints. /`
			`real_t* _H, /*< Hessian matrix. /`
			`const real_t* const g, /*< Sequence of gradient vectors. /`
			`real_t* _A, /*< Constraint matrix. /`
			`const real_t* const lb, /*< Sequence of lower bound vectors (on variables). /`
			`const real_t* const ub, /*< Sequence of upper bound vectors (on variables). /`
			`const real_t* const lbA, /*< Sequence of lower constraints' bound vectors. /`
			`const real_t* const ubA, /*< Sequence of upper constraints' bound vectors. /`
			`BooleanType isSparse, /*< Shall convert matrices to sparse format before solution? /`
			`BooleanType useHotstarts, /*< Shall QP solution be hotstarted? /`
			`const Options* options, /*< QP solver options to be used while solving benchmark problems. /`
			`int maxAllowedNWSR, /*< Maximum number of working set recalculations to be performed. /`
			`real_t* maxNWSR, /*< Output: Maximum number of performed working set recalculations. /`
			`real_t* avgNWSR, /*< Output: Average number of performed working set recalculations. /`
			`real_t* maxCPUtime, /*< Output: Maximum CPU time required for solving each QP. /`
			`real_t* avgCPUtime, /*< Output: Average CPU time required for solving each QP. /`
			`real_t* maxStationarity, /*< Output: Maximum residual of stationarity condition. /`
			`real_t* maxFeasibility, /*< Output: Maximum residual of primal feasibility condition. /`
			`real_t* maxComplementarity, /*< Output: Maximum residual of complementarity condition. /`
			`OQPbenchmark_ws work /< Workspace. /`
			`);`

			`/** Solves an Online QP Benchmark problem (without constraints) as specified`
			`* by the arguments. The maximum deviations from the given optimal solution`
			`* as well as the maximum CPU time to solve each QP are determined.`
			`* \return SUCCESSFUL_RETURN \n`
			`RET_BENCHMARK_ABORTED */`
			`returnValue solveOQPbenchmarkB( int nQP, /*< Number of QPs. /`
			`int nV, /*< Number of variables. /`
			`real_t* _H, /*< Hessian matrix. /`
			`const real_t* const g, /*< Sequence of gradient vectors. /`
			`const real_t* const lb, /*< Sequence of lower bound vectors (on variables). /`
			`const real_t* const ub, /*< Sequence of upper bound vectors (on variables). /`
			`BooleanType isSparse, /*< Shall convert matrices to sparse format before solution? /`
			`BooleanType useHotstarts, /*< Shall QP solution be hotstarted? /`
			`const Options* options, /*< QP solver options to be used while solving benchmark problems. /`
			`int maxAllowedNWSR, /*< Maximum number of working set recalculations to be performed. /`
			`real_t* maxNWSR, /*< Output: Maximum number of performed working set recalculations. /`
			`real_t* avgNWSR, /*< Output: Average number of performed working set recalculations. /`
			`real_t* maxCPUtime, /*< Output: Maximum CPU time required for solving each QP. /`
			`real_t* avgCPUtime, /*< Output: Average CPU time required for solving each QP. /`
			`real_t* maxStationarity, /*< Output: Maximum residual of stationarity condition. /`
			`real_t* maxFeasibility, /*< Output: Maximum residual of primal feasibility condition. /`
			`real_t* maxComplementarity, /*< Output: Maximum residual of complementarity condition. /`
			`OQPbenchmarkB_ws work /< Workspace. /`
			`);`


			`/** Runs an Online QP Benchmark problem and determines the maximum`
			`* violation of the KKT optimality conditions as well as the`
			`* maximum and average number of iterations and CPU time to solve`
			`* each QP.`
			`*`
			`* \return SUCCESSFUL_RETURN \n`
			`RET_UNABLE_TO_READ_BENCHMARK \n`
			`RET_BENCHMARK_ABORTED */`
			`returnValue runOQPbenchmark( const char* path, /*< Full path of the benchmark files (without trailing slash!). /`
			`BooleanType isSparse, /*< Shall convert matrices to sparse format before solution? /`
			`BooleanType useHotstarts, /*< Shall QP solution be hotstarted? /`
			`const Options* options, /*< QP solver options to be used while solving benchmark problems. /`
			`int maxAllowedNWSR, /*< Maximum number of working set recalculations to be performed. /`
			`real_t* maxNWSR, /*< Output: Maximum number of performed working set recalculations. /`
			`real_t* avgNWSR, /*< Output: Average number of performed working set recalculations. /`
			`real_t* maxCPUtime, /*< Output: Maximum CPU time required for solving each QP. /`
			`real_t* avgCPUtime, /*< Output: Average CPU time required for solving each QP. /`
			`real_t* maxStationarity, /*< Output: Maximum residual of stationarity condition. /`
			`real_t* maxFeasibility, /*< Output: Maximum residual of primal feasibility condition. /`
			`real_t* maxComplementarity, /*< Output: Maximum residual of complementarity condition. /`
			`OQPinterface_ws* work /*< Workspace. /`
			`);`

			`END_NAMESPACE_QPOASES`


			`#endif /* QPOASES_OQPINTERFACE_H */`


			`/*`
			`* end of file`
			`*/`