double-complex precision
[Sparse linear systems]

Functions

magma_int_t magma_zbaiter (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_queue_t queue)
 Solves a system of linear equations A * x = b via the block asynchronous iteration method on GPU.
magma_int_t magma_zbicgstab (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a general matrix.
magma_int_t magma_zbicgstab_merge (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a general matrix.
magma_int_t magma_zbicgstab_merge2 (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a general matrix.
magma_int_t magma_zfgmres (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_z_preconditioner *precond_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a complex sparse matrix stored in the GPU memory.
magma_int_t magma_ziterref (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_z_preconditioner *precond_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a complex Hermitian N-by-N positive definite matrix A.
magma_int_t magma_zjacobi (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a complex Hermitian N-by-N positive definite matrix A.
magma_int_t magma_zjacobidomainoverlap (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a complex Hermitian N-by-N positive definite matrix A.
magma_int_t magma_zpbicgstab (magma_z_matrix A, magma_z_matrix b, magma_z_matrix *x, magma_z_solver_par *solver_par, magma_z_preconditioner *precond_par, magma_queue_t queue)
 Solves a system of linear equations A * X = B where A is a complex N-by-N general matrix.

Function Documentation

magma_int_t magma_zbaiter ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * x = b via the block asynchronous iteration method on GPU.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zbicgstab ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a general matrix.

This is a GPU implementation of the Biconjugate Gradient Stabilized method.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zbicgstab_merge ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a general matrix.

This is a GPU implementation of the Biconjugate Gradient Stabilized method. The difference to magma_zbicgstab is that we use specifically designed kernels merging multiple operations into one kernel.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zbicgstab_merge2 ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a general matrix.

This is a GPU implementation of the Biconjugate Gradient Stabilized method. The difference to magma_zbicgstab is that we use specifically designed kernels merging multiple operations into one kernel.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zfgmres ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_z_preconditioner *  precond_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a complex sparse matrix stored in the GPU memory.

X and B are complex vectors stored on the GPU memory. This is a GPU implementation of the right-preconditioned flexible GMRES.

Parameters:
[in] A magma_z_matrix descriptor for matrix A
[in] b magma_z_matrix RHS b vector
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] precond_par magma_z_preconditioner* preconditioner
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_ziterref ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_z_preconditioner *  precond_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a complex Hermitian N-by-N positive definite matrix A.

This is a GPU implementation of the Iterative Refinement method. The inner solver is passed via the preconditioner argument.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in,out] precond_par magma_z_preconditioner* inner solver
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zjacobi ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a complex Hermitian N-by-N positive definite matrix A.

This is a GPU implementation of the Jacobi method.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zjacobidomainoverlap ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a complex Hermitian N-by-N positive definite matrix A.

This is a GPU implementation of the Jacobi method allowing for domain overlap.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] queue magma_queue_t Queue to execute in.
magma_int_t magma_zpbicgstab ( magma_z_matrix  A,
magma_z_matrix  b,
magma_z_matrix *  x,
magma_z_solver_par *  solver_par,
magma_z_preconditioner *  precond_par,
magma_queue_t  queue 
)

Solves a system of linear equations A * X = B where A is a complex N-by-N general matrix.

This is a GPU implementation of the preconditioned Biconjugate Gradient Stabelized method.

Parameters:
[in] A magma_z_matrix input matrix A
[in] b magma_z_matrix RHS b
[in,out] x magma_z_matrix* solution approximation
[in,out] solver_par magma_z_solver_par* solver parameters
[in] precond_par magma_z_preconditioner* preconditioner parameters
[in] queue magma_queue_t Queue to execute in.

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