# This file was automatically generated by SWIG (http://www.swig.org).
# Version 1.3.40
#
# Do not make changes to this file unless you know what you are doing--modify
# the SWIG interface file instead.
# This file is compatible with both classic and new-style classes.
from sys import version_info
if version_info >= (2,6,0):
def swig_import_helper():
from os.path import dirname
import imp
fp = None
try:
fp, pathname, description = imp.find_module('_amg_core', [dirname(__file__)])
except ImportError:
import _amg_core
return _amg_core
if fp is not None:
try:
_mod = imp.load_module('_amg_core', fp, pathname, description)
finally:
fp.close()
return _mod
_amg_core = swig_import_helper()
del swig_import_helper
else:
import _amg_core
del version_info
try:
_swig_property = property
except NameError:
pass # Python < 2.2 doesn't have 'property'.
def _swig_setattr_nondynamic(self,class_type,name,value,static=1):
if (name == "thisown"): return self.this.own(value)
if (name == "this"):
if type(value).__name__ == 'SwigPyObject':
self.__dict__[name] = value
return
method = class_type.__swig_setmethods__.get(name,None)
if method: return method(self,value)
if (not static) or hasattr(self,name):
self.__dict__[name] = value
else:
raise AttributeError("You cannot add attributes to %s" % self)
def _swig_setattr(self,class_type,name,value):
return _swig_setattr_nondynamic(self,class_type,name,value,0)
def _swig_getattr(self,class_type,name):
if (name == "thisown"): return self.this.own()
method = class_type.__swig_getmethods__.get(name,None)
if method: return method(self)
raise AttributeError(name)
def _swig_repr(self):
try: strthis = "proxy of " + self.this.__repr__()
except: strthis = ""
return "<%s.%s; %s >" % (self.__class__.__module__, self.__class__.__name__, strthis,)
try:
_object = object
_newclass = 1
except AttributeError:
class _object : pass
_newclass = 0
F_NODE = _amg_core.F_NODE
C_NODE = _amg_core.C_NODE
U_NODE = _amg_core.U_NODE
[docs]def cljp_naive_splitting(*args):
"""
cljp_naive_splitting(int n, int Sp, int Sj, int Tp, int Tj, int splitting,
int colorflag)
"""
return _amg_core.cljp_naive_splitting(*args)
[docs]def naive_aggregation(*args):
"""naive_aggregation(int n_row, int Ap, int Aj, int x, int y) -> int"""
return _amg_core.naive_aggregation(*args)
[docs]def standard_aggregation(*args):
"""standard_aggregation(int n_row, int Ap, int Aj, int x, int y) -> int"""
return _amg_core.standard_aggregation(*args)
[docs]def rs_cf_splitting(*args):
"""rs_cf_splitting(int n_nodes, int Sp, int Sj, int Tp, int Tj, int splitting)"""
return _amg_core.rs_cf_splitting(*args)
[docs]def rs_direct_interpolation_pass1(*args):
"""rs_direct_interpolation_pass1(int n_nodes, int Sp, int Sj, int splitting, int Bp)"""
return _amg_core.rs_direct_interpolation_pass1(*args)
[docs]def maximal_independent_set_serial(*args):
"""
maximal_independent_set_serial(int num_rows, int Ap, int Aj, int active, int C, int F,
int x) -> int
"""
return _amg_core.maximal_independent_set_serial(*args)
[docs]def vertex_coloring_mis(*args):
"""vertex_coloring_mis(int num_rows, int Ap, int Aj, int x) -> int"""
return _amg_core.vertex_coloring_mis(*args)
[docs]def vertex_coloring_jones_plassmann(*args):
"""vertex_coloring_jones_plassmann(int num_rows, int Ap, int Aj, int x, double y) -> int"""
return _amg_core.vertex_coloring_jones_plassmann(*args)
[docs]def vertex_coloring_LDF(*args):
"""vertex_coloring_LDF(int num_rows, int Ap, int Aj, int x, double y) -> int"""
return _amg_core.vertex_coloring_LDF(*args)
[docs]def breadth_first_search(*args):
"""breadth_first_search(int Ap, int Aj, int seed, int order, int level)"""
return _amg_core.breadth_first_search(*args)
[docs]def connected_components(*args):
"""connected_components(int num_nodes, int Ap, int Aj, int components) -> int"""
return _amg_core.connected_components(*args)
[docs]def signof(*args):
"""
signof(int a) -> int
signof(float a) -> float
signof(double a) -> double
"""
return _amg_core.signof(*args)
[docs]def conjugate(*args):
"""
conjugate(float x) -> float
conjugate(double x) -> double
conjugate(npy_cfloat_wrapper x) -> npy_cfloat_wrapper
conjugate(npy_cdouble_wrapper x) -> npy_cdouble_wrapper
"""
return _amg_core.conjugate(*args)
[docs]def real(*args):
"""
real(float x) -> float
real(double x) -> double
real(npy_cfloat_wrapper x) -> float
real(npy_cdouble_wrapper x) -> double
"""
return _amg_core.real(*args)
[docs]def imag(*args):
"""
imag(float x) -> float
imag(double x) -> double
imag(npy_cfloat_wrapper x) -> float
imag(npy_cdouble_wrapper x) -> double
"""
return _amg_core.imag(*args)
[docs]def mynorm(*args):
"""
mynorm(float x) -> float
mynorm(double x) -> double
mynorm(npy_cfloat_wrapper x) -> float
mynorm(npy_cdouble_wrapper x) -> double
"""
return _amg_core.mynorm(*args)
[docs]def mynormsq(*args):
"""
mynormsq(float x) -> float
mynormsq(double x) -> double
mynormsq(npy_cfloat_wrapper x) -> float
mynormsq(npy_cdouble_wrapper x) -> double
"""
return _amg_core.mynormsq(*args)
[docs]def zero_real(*args):
"""
zero_real(float x) -> float
zero_real(double x) -> double
zero_real(npy_cfloat_wrapper x) -> npy_cfloat_wrapper
zero_real(npy_cdouble_wrapper x) -> npy_cdouble_wrapper
"""
return _amg_core.zero_real(*args)
[docs]def zero_imag(*args):
"""
zero_imag(float x) -> float
zero_imag(double x) -> double
zero_imag(npy_cfloat_wrapper x) -> npy_cfloat_wrapper
zero_imag(npy_cdouble_wrapper x) -> npy_cdouble_wrapper
"""
return _amg_core.zero_imag(*args)
[docs]def rs_direct_interpolation_pass2(*args):
"""
rs_direct_interpolation_pass2(int n_nodes, int Ap, int Aj, float Ax, int Sp, int Sj,
float Sx, int splitting, int Bp, int Bj,
float Bx)
rs_direct_interpolation_pass2(int n_nodes, int Ap, int Aj, double Ax, int Sp, int Sj,
double Sx, int splitting, int Bp, int Bj,
double Bx)
"""
return _amg_core.rs_direct_interpolation_pass2(*args)
[docs]def satisfy_constraints_helper(*args):
"""
satisfy_constraints_helper(int RowsPerBlock, int ColsPerBlock, int num_block_rows,
int NullDim, float x, float y, float z,
int Sp, int Sj, float Sx)
satisfy_constraints_helper(int RowsPerBlock, int ColsPerBlock, int num_block_rows,
int NullDim, double x, double y, double z,
int Sp, int Sj, double Sx)
satisfy_constraints_helper(int RowsPerBlock, int ColsPerBlock, int num_block_rows,
int NullDim, npy_cfloat_wrapper x, npy_cfloat_wrapper y,
npy_cfloat_wrapper z, int Sp,
int Sj, npy_cfloat_wrapper Sx)
satisfy_constraints_helper(int RowsPerBlock, int ColsPerBlock, int num_block_rows,
int NullDim, npy_cdouble_wrapper x, npy_cdouble_wrapper y,
npy_cdouble_wrapper z, int Sp,
int Sj, npy_cdouble_wrapper Sx)
"""
return _amg_core.satisfy_constraints_helper(*args)
[docs]def calc_BtB(*args):
"""
calc_BtB(int NullDim, int Nnodes, int ColsPerBlock, float b,
int BsqCols, float x, int Sp, int Sj)
calc_BtB(int NullDim, int Nnodes, int ColsPerBlock, double b,
int BsqCols, double x, int Sp, int Sj)
calc_BtB(int NullDim, int Nnodes, int ColsPerBlock, npy_cfloat_wrapper b,
int BsqCols, npy_cfloat_wrapper x,
int Sp, int Sj)
calc_BtB(int NullDim, int Nnodes, int ColsPerBlock, npy_cdouble_wrapper b,
int BsqCols, npy_cdouble_wrapper x,
int Sp, int Sj)
"""
return _amg_core.calc_BtB(*args)
[docs]def incomplete_mat_mult_bsr(*args):
"""
incomplete_mat_mult_bsr(int Ap, int Aj, float Ax, int Bp, int Bj, float Bx,
int Sp, int Sj, float Sx, int n_brow, int n_bcol,
int brow_A, int bcol_A, int bcol_B)
incomplete_mat_mult_bsr(int Ap, int Aj, double Ax, int Bp, int Bj, double Bx,
int Sp, int Sj, double Sx, int n_brow, int n_bcol,
int brow_A, int bcol_A, int bcol_B)
incomplete_mat_mult_bsr(int Ap, int Aj, npy_cfloat_wrapper Ax, int Bp, int Bj,
npy_cfloat_wrapper Bx, int Sp, int Sj, npy_cfloat_wrapper Sx,
int n_brow, int n_bcol,
int brow_A, int bcol_A, int bcol_B)
incomplete_mat_mult_bsr(int Ap, int Aj, npy_cdouble_wrapper Ax, int Bp, int Bj,
npy_cdouble_wrapper Bx, int Sp, int Sj,
npy_cdouble_wrapper Sx, int n_brow, int n_bcol,
int brow_A, int bcol_A, int bcol_B)
"""
return _amg_core.incomplete_mat_mult_bsr(*args)
[docs]def maximum_row_value(*args):
"""
maximum_row_value(int n_row, float x, int Ap, int Aj, float Ax)
maximum_row_value(int n_row, double x, int Ap, int Aj, double Ax)
maximum_row_value(int n_row, npy_cfloat_wrapper x, int Ap, int Aj, npy_cfloat_wrapper Ax)
maximum_row_value(int n_row, npy_cdouble_wrapper x, int Ap, int Aj, npy_cdouble_wrapper Ax)
"""
return _amg_core.maximum_row_value(*args)
[docs]def pinv_array(*args):
"""
pinv_array(float Ax, int m, int n, char TransA)
pinv_array(double Ax, int m, int n, char TransA)
pinv_array(npy_cfloat_wrapper Ax, int m, int n, char TransA)
pinv_array(npy_cdouble_wrapper Ax, int m, int n, char TransA)
"""
return _amg_core.pinv_array(*args)
[docs]def classical_strength_of_connection(*args):
"""
classical_strength_of_connection(int n_row, float theta, int Ap, int Aj, float Ax, int Sp,
int Sj, float Sx)
classical_strength_of_connection(int n_row, double theta, int Ap, int Aj, double Ax,
int Sp, int Sj, double Sx)
classical_strength_of_connection(int n_row, float theta, int Ap, int Aj, npy_cfloat_wrapper Ax,
int Sp, int Sj, npy_cfloat_wrapper Sx)
classical_strength_of_connection(int n_row, double theta, int Ap, int Aj, npy_cdouble_wrapper Ax,
int Sp, int Sj, npy_cdouble_wrapper Sx)
"""
return _amg_core.classical_strength_of_connection(*args)
[docs]def symmetric_strength_of_connection(*args):
"""
symmetric_strength_of_connection(int n_row, float theta, int Ap, int Aj, float Ax, int Sp,
int Sj, float Sx)
symmetric_strength_of_connection(int n_row, double theta, int Ap, int Aj, double Ax,
int Sp, int Sj, double Sx)
symmetric_strength_of_connection(int n_row, float theta, int Ap, int Aj, npy_cfloat_wrapper Ax,
int Sp, int Sj, npy_cfloat_wrapper Sx)
symmetric_strength_of_connection(int n_row, double theta, int Ap, int Aj, npy_cdouble_wrapper Ax,
int Sp, int Sj, npy_cdouble_wrapper Sx)
"""
return _amg_core.symmetric_strength_of_connection(*args)
[docs]def evolution_strength_helper(*args):
"""
evolution_strength_helper(float Sx, int Sp, int Sj, int nrows, float x, float y,
float b, int BDBCols, int NullDim, float tol)
evolution_strength_helper(double Sx, int Sp, int Sj, int nrows, double x, double y,
double b, int BDBCols, int NullDim, double tol)
evolution_strength_helper(npy_cfloat_wrapper Sx, int Sp, int Sj, int nrows, npy_cfloat_wrapper x,
npy_cfloat_wrapper y, npy_cfloat_wrapper b,
int BDBCols, int NullDim,
float tol)
evolution_strength_helper(npy_cdouble_wrapper Sx, int Sp, int Sj, int nrows,
npy_cdouble_wrapper x, npy_cdouble_wrapper y,
npy_cdouble_wrapper b, int BDBCols, int NullDim,
double tol)
"""
return _amg_core.evolution_strength_helper(*args)
[docs]def incomplete_mat_mult_csr(*args):
"""
incomplete_mat_mult_csr(int Ap, int Aj, float Ax, int Bp, int Bj, float Bx,
int Sp, int Sj, float Sx, int num_rows)
incomplete_mat_mult_csr(int Ap, int Aj, double Ax, int Bp, int Bj, double Bx,
int Sp, int Sj, double Sx, int num_rows)
incomplete_mat_mult_csr(int Ap, int Aj, npy_cfloat_wrapper Ax, int Bp, int Bj,
npy_cfloat_wrapper Bx, int Sp, int Sj, npy_cfloat_wrapper Sx,
int num_rows)
incomplete_mat_mult_csr(int Ap, int Aj, npy_cdouble_wrapper Ax, int Bp, int Bj,
npy_cdouble_wrapper Bx, int Sp, int Sj,
npy_cdouble_wrapper Sx, int num_rows)
"""
return _amg_core.incomplete_mat_mult_csr(*args)
[docs]def apply_distance_filter(*args):
"""
apply_distance_filter(int n_row, float epsilon, int Sp, int Sj, float Sx)
apply_distance_filter(int n_row, double epsilon, int Sp, int Sj, double Sx)
"""
return _amg_core.apply_distance_filter(*args)
[docs]def apply_absolute_distance_filter(*args):
"""
apply_absolute_distance_filter(int n_row, float epsilon, int Sp, int Sj, float Sx)
apply_absolute_distance_filter(int n_row, double epsilon, int Sp, int Sj, double Sx)
"""
return _amg_core.apply_absolute_distance_filter(*args)
[docs]def min_blocks(*args):
"""
min_blocks(int n_blocks, int blocksize, float Sx, float Tx)
min_blocks(int n_blocks, int blocksize, double Sx, double Tx)
"""
return _amg_core.min_blocks(*args)
[docs]def bsr_gauss_seidel(*args):
"""
bsr_gauss_seidel(int Ap, int Aj, float Ax, float x, float b, int row_start,
int row_stop, int row_step, int blocksize)
bsr_gauss_seidel(int Ap, int Aj, double Ax, double x, double b, int row_start,
int row_stop, int row_step, int blocksize)
bsr_gauss_seidel(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, int row_start,
int row_stop, int row_step, int blocksize)
bsr_gauss_seidel(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, int row_start,
int row_stop, int row_step, int blocksize)
"""
return _amg_core.bsr_gauss_seidel(*args)
[docs]def bsr_jacobi(*args):
"""
bsr_jacobi(int Ap, int Aj, float Ax, float x, float b, float temp,
int row_start, int row_stop, int row_step,
int blocksize, float omega)
bsr_jacobi(int Ap, int Aj, double Ax, double x, double b, double temp,
int row_start, int row_stop, int row_step,
int blocksize, double omega)
bsr_jacobi(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, npy_cfloat_wrapper temp,
int row_start, int row_stop, int row_step,
int blocksize, npy_cfloat_wrapper omega)
bsr_jacobi(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, npy_cdouble_wrapper temp,
int row_start, int row_stop,
int row_step, int blocksize, npy_cdouble_wrapper omega)
"""
return _amg_core.bsr_jacobi(*args)
[docs]def gauss_seidel(*args):
"""
gauss_seidel(int Ap, int Aj, float Ax, float x, float b, int row_start,
int row_stop, int row_step)
gauss_seidel(int Ap, int Aj, double Ax, double x, double b, int row_start,
int row_stop, int row_step)
gauss_seidel(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, int row_start,
int row_stop, int row_step)
gauss_seidel(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, int row_start,
int row_stop, int row_step)
"""
return _amg_core.gauss_seidel(*args)
[docs]def jacobi(*args):
"""
jacobi(int Ap, int Aj, float Ax, float x, float b, float temp,
int row_start, int row_stop, int row_step,
float omega)
jacobi(int Ap, int Aj, double Ax, double x, double b, double temp,
int row_start, int row_stop, int row_step,
double omega)
jacobi(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, npy_cfloat_wrapper temp,
int row_start, int row_stop, int row_step,
npy_cfloat_wrapper omega)
jacobi(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, npy_cdouble_wrapper temp,
int row_start, int row_stop,
int row_step, npy_cdouble_wrapper omega)
"""
return _amg_core.jacobi(*args)
[docs]def block_jacobi(*args):
"""
block_jacobi(int Ap, int Aj, float Ax, float x, float b, float Tx,
float temp, int row_start, int row_stop, int row_step,
float omega, int blocksize)
block_jacobi(int Ap, int Aj, double Ax, double x, double b, double Tx,
double temp, int row_start, int row_stop,
int row_step, double omega, int blocksize)
block_jacobi(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, npy_cfloat_wrapper Tx,
npy_cfloat_wrapper temp, int row_start,
int row_stop, int row_step, npy_cfloat_wrapper omega,
int blocksize)
block_jacobi(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, npy_cdouble_wrapper Tx,
npy_cdouble_wrapper temp, int row_start,
int row_stop, int row_step, npy_cdouble_wrapper omega,
int blocksize)
"""
return _amg_core.block_jacobi(*args)
[docs]def block_gauss_seidel(*args):
"""
block_gauss_seidel(int Ap, int Aj, float Ax, float x, float b, float Tx,
int row_start, int row_stop, int row_step,
int blocksize)
block_gauss_seidel(int Ap, int Aj, double Ax, double x, double b, double Tx,
int row_start, int row_stop, int row_step,
int blocksize)
block_gauss_seidel(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, npy_cfloat_wrapper Tx,
int row_start, int row_stop, int row_step,
int blocksize)
block_gauss_seidel(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, npy_cdouble_wrapper Tx,
int row_start, int row_stop, int row_step,
int blocksize)
"""
return _amg_core.block_gauss_seidel(*args)
[docs]def gauss_seidel_indexed(*args):
"""
gauss_seidel_indexed(int Ap, int Aj, float Ax, float x, float b, int Id,
int row_start, int row_stop, int row_step)
gauss_seidel_indexed(int Ap, int Aj, double Ax, double x, double b, int Id,
int row_start, int row_stop, int row_step)
gauss_seidel_indexed(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, int Id, int row_start,
int row_stop, int row_step)
gauss_seidel_indexed(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, int Id, int row_start,
int row_stop, int row_step)
"""
return _amg_core.gauss_seidel_indexed(*args)
[docs]def jacobi_ne(*args):
"""
jacobi_ne(int Ap, int Aj, float Ax, float x, float b, float Tx,
float temp, int row_start, int row_stop, int row_step,
float omega)
jacobi_ne(int Ap, int Aj, double Ax, double x, double b, double Tx,
double temp, int row_start, int row_stop,
int row_step, double omega)
jacobi_ne(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, npy_cfloat_wrapper Tx,
npy_cfloat_wrapper temp, int row_start,
int row_stop, int row_step, npy_cfloat_wrapper omega)
jacobi_ne(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, npy_cdouble_wrapper Tx,
npy_cdouble_wrapper temp, int row_start,
int row_stop, int row_step, npy_cdouble_wrapper omega)
"""
return _amg_core.jacobi_ne(*args)
[docs]def gauss_seidel_ne(*args):
"""
gauss_seidel_ne(int Ap, int Aj, float Ax, float x, float b, int row_start,
int row_stop, int row_step, float Tx,
float omega)
gauss_seidel_ne(int Ap, int Aj, double Ax, double x, double b, int row_start,
int row_stop, int row_step, double Tx,
double omega)
gauss_seidel_ne(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, int row_start,
int row_stop, int row_step, npy_cfloat_wrapper Tx,
float omega)
gauss_seidel_ne(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, int row_start,
int row_stop, int row_step, npy_cdouble_wrapper Tx,
double omega)
"""
return _amg_core.gauss_seidel_ne(*args)
[docs]def gauss_seidel_nr(*args):
"""
gauss_seidel_nr(int Ap, int Aj, float Ax, float x, float z, int col_start,
int col_stop, int col_step, float Tx,
float omega)
gauss_seidel_nr(int Ap, int Aj, double Ax, double x, double z, int col_start,
int col_stop, int col_step, double Tx,
double omega)
gauss_seidel_nr(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper z, int col_start,
int col_stop, int col_step, npy_cfloat_wrapper Tx,
float omega)
gauss_seidel_nr(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper z, int col_start,
int col_stop, int col_step, npy_cdouble_wrapper Tx,
double omega)
"""
return _amg_core.gauss_seidel_nr(*args)
[docs]def overlapping_schwarz_csr(*args):
"""
overlapping_schwarz_csr(int Ap, int Aj, float Ax, float x, float b, float Tx,
int Tp, int Sj, int Sp, int nsdomains, int nrows,
int row_start, int row_stop, int row_step)
overlapping_schwarz_csr(int Ap, int Aj, double Ax, double x, double b, double Tx,
int Tp, int Sj, int Sp, int nsdomains,
int nrows, int row_start, int row_stop, int row_step)
overlapping_schwarz_csr(int Ap, int Aj, npy_cfloat_wrapper Ax, npy_cfloat_wrapper x,
npy_cfloat_wrapper b, npy_cfloat_wrapper Tx,
int Tp, int Sj, int Sp, int nsdomains,
int nrows, int row_start, int row_stop, int row_step)
overlapping_schwarz_csr(int Ap, int Aj, npy_cdouble_wrapper Ax, npy_cdouble_wrapper x,
npy_cdouble_wrapper b, npy_cdouble_wrapper Tx,
int Tp, int Sj, int Sp, int nsdomains,
int nrows, int row_start, int row_stop,
int row_step)
"""
return _amg_core.overlapping_schwarz_csr(*args)
[docs]def apply_householders(*args):
"""
apply_householders(float z, float B, int n, int start, int stop, int step)
apply_householders(double z, double B, int n, int start, int stop, int step)
apply_householders(npy_cfloat_wrapper z, npy_cfloat_wrapper B, int n,
int start, int stop, int step)
apply_householders(npy_cdouble_wrapper z, npy_cdouble_wrapper B, int n,
int start, int stop, int step)
"""
return _amg_core.apply_householders(*args)
[docs]def householder_hornerscheme(*args):
"""
householder_hornerscheme(float z, float B, float y, int n, int start, int stop,
int step)
householder_hornerscheme(double z, double B, double y, int n, int start, int stop,
int step)
householder_hornerscheme(npy_cfloat_wrapper z, npy_cfloat_wrapper B, npy_cfloat_wrapper y,
int n, int start, int stop, int step)
householder_hornerscheme(npy_cdouble_wrapper z, npy_cdouble_wrapper B, npy_cdouble_wrapper y,
int n, int start, int stop,
int step)
"""
return _amg_core.householder_hornerscheme(*args)
[docs]def apply_givens(*args):
"""
apply_givens(float B, float x, int n, int nrot)
apply_givens(double B, double x, int n, int nrot)
apply_givens(npy_cfloat_wrapper B, npy_cfloat_wrapper x, int n,
int nrot)
apply_givens(npy_cdouble_wrapper B, npy_cdouble_wrapper x, int n,
int nrot)
"""
return _amg_core.apply_givens(*args)
[docs]def maximal_independent_set_parallel(*args):
"""
maximal_independent_set_parallel(int num_rows, int Ap, int Aj, int active, int C, int F,
int x, double y, int max_iters = -1) -> int
maximal_independent_set_parallel(int num_rows, int Ap, int Aj, int active, int C, int F,
int x, double y) -> int
"""
return _amg_core.maximal_independent_set_parallel(*args)
[docs]def maximal_independent_set_k_parallel(*args):
"""
maximal_independent_set_k_parallel(int num_rows, int Ap, int Aj, int k, int x, double y,
int max_iters = -1)
maximal_independent_set_k_parallel(int num_rows, int Ap, int Aj, int k, int x, double y)
"""
return _amg_core.maximal_independent_set_k_parallel(*args)
[docs]def bellman_ford(*args):
"""
bellman_ford(int num_rows, int Ap, int Aj, int Ax, int x, int y)
bellman_ford(int num_rows, int Ap, int Aj, float Ax, float x, int y)
bellman_ford(int num_rows, int Ap, int Aj, double Ax, double x,
int y)
"""
return _amg_core.bellman_ford(*args)
[docs]def lloyd_cluster(*args):
"""
lloyd_cluster(int num_rows, int Ap, int Aj, int Ax, int num_seeds,
int x, int y, int z)
lloyd_cluster(int num_rows, int Ap, int Aj, float Ax, int num_seeds,
float x, int y, int z)
lloyd_cluster(int num_rows, int Ap, int Aj, double Ax, int num_seeds,
double x, int y, int z)
"""
return _amg_core.lloyd_cluster(*args)
[docs]def fit_candidates(*args):
"""
fit_candidates(int n_row, int n_col, int K1, int K2, int Ap, int Ai,
float Ax, float B, float R, float tol)
fit_candidates(int n_row, int n_col, int K1, int K2, int Ap, int Ai,
double Ax, double B, double R, double tol)
fit_candidates(int n_row, int n_col, int K1, int K2, int Ap, int Ai,
npy_cfloat_wrapper Ax, npy_cfloat_wrapper B,
npy_cfloat_wrapper R, float tol)
fit_candidates(int n_row, int n_col, int K1, int K2, int Ap, int Ai,
npy_cdouble_wrapper Ax, npy_cdouble_wrapper B,
npy_cdouble_wrapper R, double tol)
"""
return _amg_core.fit_candidates(*args)