third_party/osqp/docs/contributing/index.rst - RealtimeRoboticsGroup/test - Gitiles

 Contributing
 =============

 OSQP is an open-source project open to any academic or commercial applications.
 Contributions are welcome as `GitHub pull requests <https://help.github.com/articles/creating-a-pull-request/>`_ in any part of the project such as

 * algorithm developments
 * interfaces to other languages
 * compatibility with new architectures
 * linear system solvers interfaces


 .. _interfacing_new_linear_system_solvers :

 Interfacing new linear system solvers
 -------------------------------------
 OSQP is designed to be easily interfaced to new linear system solvers via dynamic library loading.
 To add a linear system solver interface you need to edit the :code:`lin_sys/` directory subfolder :code:`direct/` or :code:`indirect/` depending on the type of solver.
 Create a subdirectory with your solver name with four files:

 * Dynamic library loading: :code:`mysolver_loader.c` and :code:`mysolver_loader.h`.
 * Linear system solution: :code:`mysolver.c` and :code:`mysolver.h`.

 We suggest you to have a look at the `MKL Pardiso solver interface <https://github.com/osqp/osqp/tree/master/lin_sys/direct/pardiso>`_ for more details.

 Dynamic library loading
 ^^^^^^^^^^^^^^^^^^^^^^^
 In this part define the methods to load the shared library and obtain the functions required to solve the linear system.
 The main functions to be exported are :code:`lh_load_mysolver(const char* libname)` and :code:`lh_unload_mysolver()`.
 In addition, the file :code:`mysolver_loader.c` must define static function pointers to the shared library functions to be loaded.

 Linear system solution
 ^^^^^^^^^^^^^^^^^^^^^^
 In this part we define the core of the interface: **linear system solver object**.
 The main functions are the external method

 * :code:`init_linsys_solver_mysolver`: create the instance and perform the setup

 and the internal methods of the object

 * :code:`free_linsys_solver_mysolver`: free the instance
 * :code:`solve_linsys_mysolver`: solve the linear system
 * :code:`update_matrices`: update problem matrices
 * :code:`update_rho_vec`: update :math:`\rho` as a diagonal vector.

 After the initializations these functions are assigned to the internal pointers so that, for an instance :code:`s` they can be called as :code:`s->free`, :code:`s->solve`, :code:`s->update_matrices` and :code:`s->update_rho_vec`.

 The linear system solver object is defined in :code:`mysolver.h` as follows

 .. code:: c

         typedef struct mysolver mysolver_solver;

         struct mysolver {
             // Methods
             enum linsys_solver_type type; // Linear system solver defined in constants.h

             c_int (*solve)(struct mysolver * self, c_float * b);
             void (*free)(struct mysolver * self);
             c_int (*update_matrices)(struct mysolver * self, const csc *P, const csc *A);
             c_int (*update_rho_vec)(struct mysolver * self, const c_float * rho_vec);

             // Attributes
             c_int nthreads; // Number of threads used (required!)

             // Internal attributes of the solver
             ...

             // Internal attributes required for matrix updates
             c_int * Pdiag_idx, Pdiag_n;  ///< index and number of diagonal elements in P
             c_int * PtoKKT, * AtoKKT;    ///< Index of elements from P and A to KKT matrix
             c_int * rhotoKKT;            ///< Index of rho places in KKT matrix
             ...

         };

         // Initialize mysolver solver
         c_int init_linsys_solver_mysolver(mysolver_solver ** s, const csc * P, const csc * A, c_float sigma, c_float * rho_vec, c_int polish);

         // Solve linear system and store result in b
         c_int solve_linsys_mysolver(mysolver_solver * s, c_float * b);

          // Update linear system solver matrices
         c_int update_linsys_solver_matrices_mysolver(mysolver_solver * s, const csc *P, const csc *A);

         // Update rho_vec parameter in linear system solver structure
         c_int update_linsys_solver_rho_vec_mysolver(mysolver_solver * s, const c_float * rho_vec);

         // Free linear system solver
         void free_linsys_solver_mysolver(mysolver_solver * s);


 The function details are coded in the :code:`mysolver.c` file.
	Contributing
	=============

	OSQP is an open-source project open to any academic or commercial applications.
	Contributions are welcome as `GitHub pull requests <https://help.github.com/articles/creating-a-pull-request/>`_ in any part of the project such as

	* algorithm developments
	* interfaces to other languages
	* compatibility with new architectures
	* linear system solvers interfaces


	.. _interfacing_new_linear_system_solvers :

	Interfacing new linear system solvers
	-------------------------------------
	OSQP is designed to be easily interfaced to new linear system solvers via dynamic library loading.
	To add a linear system solver interface you need to edit the :code:`lin_sys/` directory subfolder :code:`direct/` or :code:`indirect/` depending on the type of solver.
	Create a subdirectory with your solver name with four files:

	* Dynamic library loading: :code:`mysolver_loader.c` and :code:`mysolver_loader.h`.
	* Linear system solution: :code:`mysolver.c` and :code:`mysolver.h`.

	We suggest you to have a look at the `MKL Pardiso solver interface <https://github.com/osqp/osqp/tree/master/lin_sys/direct/pardiso>`_ for more details.

	Dynamic library loading
	^^^^^^^^^^^^^^^^^^^^^^^
	In this part define the methods to load the shared library and obtain the functions required to solve the linear system.
	The main functions to be exported are :code:`lh_load_mysolver(const char* libname)` and :code:`lh_unload_mysolver()`.
	In addition, the file :code:`mysolver_loader.c` must define static function pointers to the shared library functions to be loaded.

	Linear system solution
	^^^^^^^^^^^^^^^^^^^^^^
	In this part we define the core of the interface: linear system solver object.
	The main functions are the external method

	* :code:`init_linsys_solver_mysolver`: create the instance and perform the setup

	and the internal methods of the object

	* :code:`free_linsys_solver_mysolver`: free the instance
	* :code:`solve_linsys_mysolver`: solve the linear system
	* :code:`update_matrices`: update problem matrices
	* :code:`update_rho_vec`: update :math:`\rho` as a diagonal vector.

	After the initializations these functions are assigned to the internal pointers so that, for an instance :code:`s` they can be called as :code:`s->free`, :code:`s->solve`, :code:`s->update_matrices` and :code:`s->update_rho_vec`.

	The linear system solver object is defined in :code:`mysolver.h` as follows

	.. code:: c

	typedef struct mysolver mysolver_solver;

	struct mysolver {
	// Methods
	enum linsys_solver_type type; // Linear system solver defined in constants.h

	c_int (solve)(struct mysolver self, c_float * b);
	void (free)(struct mysolver self);
	c_int (update_matrices)(struct mysolver self, const csc P, const csc A);
	c_int (update_rho_vec)(struct mysolver self, const c_float * rho_vec);

	// Attributes
	c_int nthreads; // Number of threads used (required!)

	// Internal attributes of the solver
	...

	// Internal attributes required for matrix updates
	c_int * Pdiag_idx, Pdiag_n; ///< index and number of diagonal elements in P
	c_int * PtoKKT, * AtoKKT; ///< Index of elements from P and A to KKT matrix
	c_int * rhotoKKT; ///< Index of rho places in KKT matrix
	...

	};

	// Initialize mysolver solver
	c_int init_linsys_solver_mysolver(mysolver_solver ** s, const csc * P, const csc * A, c_float sigma, c_float * rho_vec, c_int polish);

	// Solve linear system and store result in b
	c_int solve_linsys_mysolver(mysolver_solver * s, c_float * b);

	// Update linear system solver matrices
	c_int update_linsys_solver_matrices_mysolver(mysolver_solver * s, const csc P, const csc A);

	// Update rho_vec parameter in linear system solver structure
	c_int update_linsys_solver_rho_vec_mysolver(mysolver_solver * s, const c_float * rho_vec);

	// Free linear system solver
	void free_linsys_solver_mysolver(mysolver_solver * s);


	The function details are coded in the :code:`mysolver.c` file.