def createMLCP_fromFile():
mlcp=N.MLCP()
N.mixedLinearComplementarity_newFromFilename(mlcp, os.path.join(working_dir, "data/diodeBridge_mlcp.dat"))
zsol =np.array([ 9.85185185e-01, 9.85185185e-01, -0.00000000e+00,
9.85185185e-04, 0.00000000e+00, 0.00000000e+00,
9.85185185e-04])
return (mlcp, zsol)
[ 0. ],
[ 0. ],
[ 0. ],
[ 0. ]])
mlcp=N.MLCP(3,M,q)
def test_mlcp_enum_large():
SO=N.SolverOptions(mlcp,N.SICONOS_MLCP_ENUM)
N.mlcp_driver_init(mlcp, SO)
info = N.mlcp_enum(mlcp, z, w, SO)
N.mlcp_driver_reset(mlcp, SO)
print("z = ", z)
print("w = ", w)
assert (np.linalg.norm(z-zsol) <= ztol)
assert not info
#mlcp =0
mlcp=N.MLCP()
N.mixedLinearComplementarity_newFromFilename(mlcp,"data/diodeBridge_mlcp.dat")
#N.mixedLinearComplementarity_display(mlcp)
def test_mlcp_enum_large_fromfile():
SO=N.SolverOptions(mlcp,N.SICONOS_MLCP_ENUM)
N.mlcp_driver_init(mlcp, SO)
info = N.mlcp_enum(mlcp, z, w, SO)
N.mlcp_driver_reset(mlcp, SO)
print("z = ", z)
print("w = ", w)
assert (linalg.norm(z-zsol) <= ztol)
assert not info
