def solve_problem(mesh_filename, options, comm):
order_u = options.order_u
order_p = options.order_p
rank, size = comm.Get_rank(), comm.Get_size()
output('rank', rank, 'of', size)
stats = Struct()
timer = Timer('solve_timer')
timer.start()
mesh = Mesh.from_file(mesh_filename)
stats.t_read_mesh = timer.stop()
timer.start()
if rank == 0:
cell_tasks = pl.partition_mesh(mesh, size, use_metis=options.metis,
verbose=True)
else:
cell_tasks = None
stats.t_partition_mesh = timer.stop()
output('creating global domain and fields...')
timer.start()
domain = FEDomain('domain', mesh)
omega = domain.create_region('Omega', 'all')
field1 = Field.from_args('fu', nm.float64, mesh.dim, omega,
approx_order=order_u)
field2 = Field.from_args('fp', nm.float64, 1, omega,
approx_order=order_p)
fields = [field1, field2]
stats.t_create_global_fields = timer.stop()
output('...done in', timer.dt)
output('distributing fields...')
timer.start()
distribute = pl.distribute_fields_dofs
lfds, gfds = distribute(fields, cell_tasks,
is_overlap=True,
use_expand_dofs=True,
save_inter_regions=options.save_inter_regions,
output_dir=options.output_dir,
comm=comm, verbose=True)
stats.t_distribute_fields_dofs = timer.stop()
output('...done in', timer.dt)
output('creating local problem...')
timer.start()
cells = lfds[0].cells
omega_gi = Region.from_cells(cells, domain)
omega_gi.finalize()
omega_gi.update_shape()
pb = create_local_problem(omega_gi, [order_u, order_p])
variables = pb.get_variables()
state = State(variables)
state.fill(0.0)
state.apply_ebc()
stats.t_create_local_problem = timer.stop()
output('...done in', timer.dt)
output('allocating global system...')
timer.start()
sizes, drange, pdofs = pl.setup_composite_dofs(lfds, fields, variables,
verbose=True)
pmtx, psol, prhs = pl.create_petsc_system(pb.mtx_a, sizes, pdofs, drange,
is_overlap=True, comm=comm,
verbose=True)
stats.t_allocate_global_system = timer.stop()
output('...done in', timer.dt)
output('creating solver...')
timer.start()
conf = Struct(method='bcgsl', precond='jacobi', sub_precond='none',
i_max=10000, eps_a=1e-50, eps_r=1e-6, eps_d=1e4,
verbose=True)
status = {}
ls = PETScKrylovSolver(conf, comm=comm, mtx=pmtx, status=status)
field_ranges = {}
for ii, variable in enumerate(variables.iter_state(ordered=True)):
field_ranges[variable.name] = lfds[ii].petsc_dofs_range
ls.set_field_split(field_ranges, comm=comm)
ev = PETScParallelEvaluator(pb, pdofs, drange, True,
psol, comm, verbose=True)
nls_status = {}
conf = Struct(method='newtonls',
i_max=5, eps_a=0, eps_r=1e-5, eps_s=0.0,
verbose=True)
nls = PETScNonlinearSolver(conf, pmtx=pmtx, prhs=prhs, comm=comm,
fun=ev.eval_residual,
fun_grad=ev.eval_tangent_matrix,
lin_solver=ls, status=nls_status)
stats.t_create_solver = timer.stop()
output('...done in', timer.dt)
output('solving...')
timer.start()
state = pb.create_state()
state.apply_ebc()
ev.psol_i[...] = state()
ev.gather(psol, ev.psol_i)
psol = nls(psol)
ev.scatter(ev.psol_i, psol)
sol0_i = ev.psol_i[...]
stats.t_solve = timer.stop()
output('...done in', timer.dt)
output('saving solution...')
timer.start()
state.set_full(sol0_i)
out = state.create_output_dict()
filename = os.path.join(options.output_dir, 'sol_%02d.h5' % comm.rank)
pb.domain.mesh.write(filename, io='auto', out=out)
gather_to_zero = pl.create_gather_to_zero(psol)
psol_full = gather_to_zero(psol)
if comm.rank == 0:
sol = psol_full[...].copy()
u = FieldVariable('u', 'parameter', field1,
primary_var_name='(set-to-None)')
remap = gfds[0].id_map
ug = sol[remap]
p = FieldVariable('p', 'parameter', field2,
primary_var_name='(set-to-None)')
remap = gfds[1].id_map
pg = sol[remap]
if (((order_u == 1) and (order_p == 1))
or (options.linearization == 'strip')):
out = u.create_output(ug)
out.update(p.create_output(pg))
filename = os.path.join(options.output_dir, 'sol.h5')
mesh.write(filename, io='auto', out=out)
else:
out = u.create_output(ug, linearization=Struct(kind='adaptive',
min_level=0,
max_level=order_u,
eps=1e-3))
filename = os.path.join(options.output_dir, 'sol_u.h5')
out['u'].mesh.write(filename, io='auto', out=out)
out = p.create_output(pg, linearization=Struct(kind='adaptive',
min_level=0,
max_level=order_p,
eps=1e-3))
filename = os.path.join(options.output_dir, 'sol_p.h5')
out['p'].mesh.write(filename, io='auto', out=out)
stats.t_save_solution = timer.stop()
output('...done in', timer.dt)
stats.t_total = timer.total
stats.n_dof = sizes[1]
stats.n_dof_local = sizes[0]
stats.n_cell = omega.shape.n_cell
stats.n_cell_local = omega_gi.shape.n_cell
return stats
def solve_problem(mesh_filename, options, comm):
order = options.order
rank, size = comm.Get_rank(), comm.Get_size()
output('rank', rank, 'of', size)
mesh = Mesh.from_file(mesh_filename)
if rank == 0:
cell_tasks = pl.partition_mesh(mesh, size, use_metis=options.metis,
verbose=True)
else:
cell_tasks = None
domain = FEDomain('domain', mesh)
omega = domain.create_region('Omega', 'all')
field = Field.from_args('fu', nm.float64, 1, omega, approx_order=order)
output('distributing field %s...' % field.name)
tt = time.clock()
distribute = pl.distribute_fields_dofs
lfds, gfds = distribute([field], cell_tasks,
is_overlap=True,
save_inter_regions=options.save_inter_regions,
output_dir=options.output_dir,
comm=comm, verbose=True)
lfd = lfds[0]
output('...done in', time.clock() - tt)
if rank == 0:
dof_maps = gfds[0].dof_maps
id_map = gfds[0].id_map
if options.verify:
verify_save_dof_maps(field, cell_tasks,
dof_maps, id_map, options, verbose=True)
if options.plot:
ppd.plot_partitioning([None, None], field, cell_tasks, gfds[0],
options.output_dir, size)
output('creating local problem...')
tt = time.clock()
omega_gi = Region.from_cells(lfd.cells, field.domain)
omega_gi.finalize()
omega_gi.update_shape()
pb = create_local_problem(omega_gi, order)
output('...done in', time.clock() - tt)
variables = pb.get_variables()
eqs = pb.equations
u_i = variables['u_i']
field_i = u_i.field
if options.plot:
ppd.plot_local_dofs([None, None], field, field_i, omega_gi,
options.output_dir, rank)
output('allocating global system...')
tt = time.clock()
sizes, drange = pl.get_sizes(lfd.petsc_dofs_range, field.n_nod, 1)
output('sizes:', sizes)
output('drange:', drange)
pdofs = pl.get_local_ordering(field_i, lfd.petsc_dofs_conn)
output('pdofs:', pdofs)
pmtx, psol, prhs = pl.create_petsc_system(pb.mtx_a, sizes, pdofs, drange,
is_overlap=True, comm=comm,
verbose=True)
output('...done in', time.clock() - tt)
output('evaluating local problem...')
tt = time.clock()
state = State(variables)
state.fill(0.0)
state.apply_ebc()
rhs_i = eqs.eval_residuals(state())
# This must be after pl.create_petsc_system() call!
mtx_i = eqs.eval_tangent_matrices(state(), pb.mtx_a)
output('...done in', time.clock() - tt)
output('assembling global system...')
tt = time.clock()
pl.apply_ebc_to_matrix(mtx_i, u_i.eq_map.eq_ebc)
pl.assemble_rhs_to_petsc(prhs, rhs_i, pdofs, drange, is_overlap=True,
comm=comm, verbose=True)
pl.assemble_mtx_to_petsc(pmtx, mtx_i, pdofs, drange, is_overlap=True,
comm=comm, verbose=True)
output('...done in', time.clock() - tt)
output('creating solver...')
tt = time.clock()
conf = Struct(method='cg', precond='gamg', sub_precond=None,
i_max=10000, eps_a=1e-50, eps_r=1e-5, eps_d=1e4, verbose=True)
status = {}
ls = PETScKrylovSolver(conf, comm=comm, mtx=pmtx, status=status)
output('...done in', time.clock() - tt)
output('solving...')
tt = time.clock()
psol = ls(prhs, psol, conf)
psol_i = pl.create_local_petsc_vector(pdofs)
gather, scatter = pl.create_gather_scatter(pdofs, psol_i, psol, comm=comm)
scatter(psol_i, psol)
sol0_i = state() - psol_i[...]
psol_i[...] = sol0_i
gather(psol, psol_i)
output('...done in', time.clock() - tt)
output('saving solution...')
tt = time.clock()
u_i.set_data(sol0_i)
out = u_i.create_output()
filename = os.path.join(options.output_dir, 'sol_%02d.h5' % comm.rank)
pb.domain.mesh.write(filename, io='auto', out=out)
gather_to_zero = pl.create_gather_to_zero(psol)
psol_full = gather_to_zero(psol)
if comm.rank == 0:
sol = psol_full[...].copy()[id_map]
u = FieldVariable('u', 'parameter', field,
primary_var_name='(set-to-None)')
filename = os.path.join(options.output_dir, 'sol.h5')
if (order == 1) or (options.linearization == 'strip'):
out = u.create_output(sol)
mesh.write(filename, io='auto', out=out)
else:
out = u.create_output(sol, linearization=Struct(kind='adaptive',
min_level=0,
max_level=order,
eps=1e-3))
out['u'].mesh.write(filename, io='auto', out=out)
output('...done in', time.clock() - tt)
if options.show:
plt.show()
def solve_problem(mesh_filename, options, comm):
order_u = options.order_u
order_p = options.order_p
rank, size = comm.Get_rank(), comm.Get_size()
output('rank', rank, 'of', size)
mesh = Mesh.from_file(mesh_filename)
if rank == 0:
cell_tasks = pl.partition_mesh(mesh, size, use_metis=options.metis,
verbose=True)
else:
cell_tasks = None
domain = FEDomain('domain', mesh)
omega = domain.create_region('Omega', 'all')
field1 = Field.from_args('fu', nm.float64, mesh.dim, omega,
approx_order=order_u)
field2 = Field.from_args('fp', nm.float64, 1, omega,
approx_order=order_p)
fields = [field1, field2]
output('distributing fields...')
tt = time.clock()
lfds, gfds = pl.distribute_fields_dofs(fields, cell_tasks,
is_overlap=True,
use_expand_dofs=True,
comm=comm, verbose=True)
output('...done in', time.clock() - tt)
output('creating local problem...')
tt = time.clock()
cells = lfds[0].cells
omega_gi = Region.from_cells(cells, domain)
omega_gi.finalize()
omega_gi.update_shape()
pb = create_local_problem(omega_gi, [order_u, order_p])
variables = pb.get_variables()
state = State(variables)
state.fill(0.0)
state.apply_ebc()
output('...done in', time.clock() - tt)
output('allocating global system...')
tt = time.clock()
sizes, drange, pdofs = pl.setup_composite_dofs(lfds, fields, variables,
verbose=True)
pmtx, psol, prhs = pl.create_petsc_system(pb.mtx_a, sizes, pdofs, drange,
is_overlap=True, comm=comm,
verbose=True)
output('...done in', time.clock() - tt)
output('creating solver...')
tt = time.clock()
conf = Struct(method='bcgsl', precond='jacobi', sub_precond=None,
i_max=10000, eps_a=1e-50, eps_r=1e-6, eps_d=1e4,
verbose=True)
status = {}
ls = PETScKrylovSolver(conf, comm=comm, mtx=pmtx, status=status)
field_ranges = {}
for ii, variable in enumerate(variables.iter_state(ordered=True)):
field_ranges[variable.name] = lfds[ii].petsc_dofs_range
ls.set_field_split(field_ranges, comm=comm)
ev = PETScParallelEvaluator(pb, pdofs, drange, True,
psol, comm, verbose=True)
nls_status = {}
conf = Struct(method='newtonls',
i_max=5, eps_a=0, eps_r=1e-5, eps_s=0.0,
verbose=True)
nls = PETScNonlinearSolver(conf, pmtx=pmtx, prhs=prhs, comm=comm,
fun=ev.eval_residual,
fun_grad=ev.eval_tangent_matrix,
lin_solver=ls, status=nls_status)
output('...done in', time.clock() - tt)
output('solving...')
tt = time.clock()
state = pb.create_state()
state.apply_ebc()
ev.psol_i[...] = state()
ev.gather(psol, ev.psol_i)
psol = nls(psol)
ev.scatter(ev.psol_i, psol)
sol0_i = ev.psol_i[...]
output('...done in', time.clock() - tt)
output('saving solution...')
tt = time.clock()
state.set_full(sol0_i)
out = state.create_output_dict()
filename = os.path.join(options.output_dir, 'sol_%02d.h5' % comm.rank)
pb.domain.mesh.write(filename, io='auto', out=out)
gather_to_zero = pl.create_gather_to_zero(psol)
psol_full = gather_to_zero(psol)
if comm.rank == 0:
sol = psol_full[...].copy()
u = FieldVariable('u', 'parameter', field1,
primary_var_name='(set-to-None)')
remap = gfds[0].id_map
ug = sol[remap]
p = FieldVariable('p', 'parameter', field2,
primary_var_name='(set-to-None)')
remap = gfds[1].id_map
pg = sol[remap]
if (((order_u == 1) and (order_p == 1))
or (options.linearization == 'strip')):
out = u.create_output(ug)
out.update(p.create_output(pg))
filename = os.path.join(options.output_dir, 'sol.h5')
mesh.write(filename, io='auto', out=out)
else:
out = u.create_output(ug, linearization=Struct(kind='adaptive',
min_level=0,
max_level=order_u,
eps=1e-3))
filename = os.path.join(options.output_dir, 'sol_u.h5')
out['u'].mesh.write(filename, io='auto', out=out)
out = p.create_output(pg, linearization=Struct(kind='adaptive',
min_level=0,
max_level=order_p,
eps=1e-3))
filename = os.path.join(options.output_dir, 'sol_p.h5')
out['p'].mesh.write(filename, io='auto', out=out)
output('...done in', time.clock() - tt)
def solve_problem(mesh_filename, options, comm):
order = options.order
rank, size = comm.Get_rank(), comm.Get_size()
output('rank', rank, 'of', size)
mesh = Mesh.from_file(mesh_filename)
if rank == 0:
cell_tasks = pl.partition_mesh(mesh,
size,
use_metis=options.metis,
verbose=True)
else:
cell_tasks = None
output('creating global domain and field...')
tt = time.clock()
domain = FEDomain('domain', mesh)
omega = domain.create_region('Omega', 'all')
field = Field.from_args('fu', nm.float64, 1, omega, approx_order=order)
output('...done in', time.clock() - tt)
output('distributing field %s...' % field.name)
tt = time.clock()
distribute = pl.distribute_fields_dofs
lfds, gfds = distribute([field],
cell_tasks,
is_overlap=True,
save_inter_regions=options.save_inter_regions,
output_dir=options.output_dir,
comm=comm,
verbose=True)
lfd = lfds[0]
output('...done in', time.clock() - tt)
if rank == 0:
dof_maps = gfds[0].dof_maps
id_map = gfds[0].id_map
if options.verify:
verify_save_dof_maps(field,
cell_tasks,
dof_maps,
id_map,
options,
verbose=True)
if options.plot:
ppd.plot_partitioning([None, None], field, cell_tasks, gfds[0],
options.output_dir, size)
output('creating local problem...')
tt = time.clock()
omega_gi = Region.from_cells(lfd.cells, field.domain)
omega_gi.finalize()
omega_gi.update_shape()
pb = create_local_problem(omega_gi, order)
output('...done in', time.clock() - tt)
variables = pb.get_variables()
eqs = pb.equations
u_i = variables['u_i']
field_i = u_i.field
if options.plot:
ppd.plot_local_dofs([None, None], field, field_i, omega_gi,
options.output_dir, rank)
output('allocating global system...')
tt = time.clock()
sizes, drange = pl.get_sizes(lfd.petsc_dofs_range, field.n_nod, 1)
output('sizes:', sizes)
output('drange:', drange)
pdofs = pl.get_local_ordering(field_i, lfd.petsc_dofs_conn)
output('pdofs:', pdofs)
pmtx, psol, prhs = pl.create_petsc_system(pb.mtx_a,
sizes,
pdofs,
drange,
is_overlap=True,
comm=comm,
verbose=True)
output('...done in', time.clock() - tt)
output('evaluating local problem...')
tt = time.clock()
state = State(variables)
state.fill(0.0)
state.apply_ebc()
rhs_i = eqs.eval_residuals(state())
# This must be after pl.create_petsc_system() call!
mtx_i = eqs.eval_tangent_matrices(state(), pb.mtx_a)
output('...done in', time.clock() - tt)
output('assembling global system...')
tt = time.clock()
apply_ebc_to_matrix(mtx_i, u_i.eq_map.eq_ebc)
pl.assemble_rhs_to_petsc(prhs,
rhs_i,
pdofs,
drange,
is_overlap=True,
comm=comm,
verbose=True)
pl.assemble_mtx_to_petsc(pmtx,
mtx_i,
pdofs,
drange,
is_overlap=True,
comm=comm,
verbose=True)
output('...done in', time.clock() - tt)
output('creating solver...')
tt = time.clock()
conf = Struct(method='cg',
precond='gamg',
sub_precond='none',
i_max=10000,
eps_a=1e-50,
eps_r=1e-5,
eps_d=1e4,
verbose=True)
status = {}
ls = PETScKrylovSolver(conf, comm=comm, mtx=pmtx, status=status)
output('...done in', time.clock() - tt)
output('solving...')
tt = time.clock()
psol = ls(prhs, psol)
psol_i = pl.create_local_petsc_vector(pdofs)
gather, scatter = pl.create_gather_scatter(pdofs, psol_i, psol, comm=comm)
scatter(psol_i, psol)
sol0_i = state() - psol_i[...]
psol_i[...] = sol0_i
gather(psol, psol_i)
output('...done in', time.clock() - tt)
output('saving solution...')
tt = time.clock()
u_i.set_data(sol0_i)
out = u_i.create_output()
filename = os.path.join(options.output_dir, 'sol_%02d.h5' % comm.rank)
pb.domain.mesh.write(filename, io='auto', out=out)
gather_to_zero = pl.create_gather_to_zero(psol)
psol_full = gather_to_zero(psol)
if comm.rank == 0:
sol = psol_full[...].copy()[id_map]
u = FieldVariable('u',
'parameter',
field,
primary_var_name='(set-to-None)')
filename = os.path.join(options.output_dir, 'sol.h5')
if (order == 1) or (options.linearization == 'strip'):
out = u.create_output(sol)
mesh.write(filename, io='auto', out=out)
else:
out = u.create_output(sol,
linearization=Struct(kind='adaptive',
min_level=0,
max_level=order,
eps=1e-3))
out['u'].mesh.write(filename, io='auto', out=out)
output('...done in', time.clock() - tt)
if options.show:
plt.show()
