def test_base_solver_init(self):
solver = pybamm.BaseSolver(rtol=1e-2, atol=1e-4)
self.assertEqual(solver.rtol, 1e-2)
self.assertEqual(solver.atol, 1e-4)
solver.rtol = 1e-5
self.assertEqual(solver.rtol, 1e-5)
solver.rtol = 1e-7
self.assertEqual(solver.rtol, 1e-7)
# max_steps deprecated
with self.assertRaisesRegex(ValueError, "max_steps has been deprecated"):
pybamm.BaseSolver(max_steps=10)
def test_root_method_init(self):
solver = pybamm.BaseSolver(root_method="casadi")
self.assertIsInstance(solver.root_method, pybamm.CasadiAlgebraicSolver)
solver = pybamm.BaseSolver(root_method="lm")
self.assertIsInstance(solver.root_method, pybamm.AlgebraicSolver)
self.assertEqual(solver.root_method.method, "lm")
root_solver = pybamm.AlgebraicSolver()
solver = pybamm.BaseSolver(root_method=root_solver)
self.assertEqual(solver.root_method, root_solver)
with self.assertRaisesRegex(pybamm.SolverError,
"Root method must be an algebraic solver"):
pybamm.BaseSolver(root_method=pybamm.ScipySolver())
def test_step_or_solve_empty_model(self):
model = pybamm.BaseModel()
solver = pybamm.BaseSolver()
with self.assertRaisesRegex(pybamm.ModelError, "Cannot step empty model"):
solver.step(None, model, None)
with self.assertRaisesRegex(pybamm.ModelError, "Cannot solve empty model"):
solver.solve(model, None)
def test_nonmonotonic_teval(self):
solver = pybamm.BaseSolver(rtol=1e-2, atol=1e-4)
model = pybamm.BaseModel()
a = pybamm.Scalar(0)
model.rhs = {a: a}
with self.assertRaisesRegex(pybamm.SolverError,
"t_eval must increase monotonically"):
solver.solve(model, np.array([1, 2, 3, 2]))
def test_base_solver_init(self):
solver = pybamm.BaseSolver(rtol=1e-2, atol=1e-4)
self.assertEqual(solver.rtol, 1e-2)
self.assertEqual(solver.atol, 1e-4)
solver.rtol = 1e-5
self.assertEqual(solver.rtol, 1e-5)
solver.rtol = 1e-7
self.assertEqual(solver.rtol, 1e-7)
def test_time_too_short(self):
solver = pybamm.BaseSolver()
model = pybamm.BaseModel()
v = pybamm.StateVector(slice(0, 1))
model.rhs = {v: v}
with self.assertRaisesRegex(
pybamm.SolverError,
"It looks like t_eval might be dimensionless"):
solver.solve(model, np.linspace(0, 0.1))
def test_block_symbolic_inputs(self):
solver = pybamm.BaseSolver(rtol=1e-2, atol=1e-4)
model = pybamm.BaseModel()
a = pybamm.Scalar(0)
p = pybamm.InputParameter("p")
model.rhs = {a: a * p}
with self.assertRaisesRegex(
pybamm.SolverError, "Only CasadiAlgebraicSolver can have symbolic inputs"
):
solver.solve(model, np.array([1, 2, 3]))
def test_t_eval_none(self):
model = pybamm.BaseModel()
v = pybamm.Variable("v")
model.rhs = {v: 1}
model.initial_conditions = {v: 1}
disc = pybamm.Discretisation()
disc.process_model(model)
solver = pybamm.BaseSolver()
with self.assertRaisesRegex(ValueError, "t_eval cannot be None"):
solver.solve(model, None)
def test_timescale_input_fail(self):
# Make sure timescale can't depend on inputs
model = pybamm.BaseModel()
v = pybamm.Variable("v")
model.rhs = {v: -1}
model.initial_conditions = {v: 1}
a = pybamm.InputParameter("a")
model.timescale = a
solver = pybamm.BaseSolver()
with self.assertRaisesRegex(pybamm.SolverError, "The model timescale"):
solver.set_up(model, inputs={"a": 10})
def test_fail_consistent_initial_conditions(self):
class Model:
def __init__(self):
self.y0 = np.array([2])
self.rhs = {}
self.jac_algebraic_eval = None
self.timescale_eval = 1
t = casadi.MX.sym("t")
y = casadi.MX.sym("y")
p = casadi.MX.sym("p")
self.casadi_algebraic = casadi.Function(
"alg", [t, y, p], [self.algebraic_eval(t, y, p)]
)
self.convert_to_format = "casadi"
def rhs_eval(self, t, y, inputs):
return np.array([])
def algebraic_eval(self, t, y, inputs):
# algebraic equation has no root
return y ** 2 + 1
solver = pybamm.BaseSolver(root_method="hybr")
with self.assertRaisesRegex(
pybamm.SolverError,
"Could not find acceptable solution: The iteration is not making",
):
solver.calculate_consistent_state(Model())
solver = pybamm.BaseSolver(root_method="lm")
with self.assertRaisesRegex(
pybamm.SolverError, "Could not find acceptable solution: solver terminated"
):
solver.calculate_consistent_state(Model())
# with casadi
solver = pybamm.BaseSolver(root_method="casadi")
with self.assertRaisesRegex(
pybamm.SolverError, "Could not find acceptable solution: .../casadi"
):
solver.calculate_consistent_state(Model())
def test_fail_consistent_initial_conditions(self):
class Model:
def __init__(self):
self.concatenated_initial_conditions = np.array([2])
self.jac_algebraic_eval = None
self.timescale = 1
t = casadi.MX.sym("t")
y = casadi.MX.sym("y")
u = casadi.MX.sym("u")
self.casadi_algebraic = casadi.Function(
"alg", [t, y, u], [self.algebraic_eval(t, y)])
def rhs_eval(self, t, y):
return np.array([])
def algebraic_eval(self, t, y):
# algebraic equation has no root
return y**2 + 1
solver = pybamm.BaseSolver(root_method="hybr")
with self.assertRaisesRegex(
pybamm.SolverError,
"Could not find consistent initial conditions: The iteration is not making",
):
solver.calculate_consistent_state(Model())
solver = pybamm.BaseSolver(root_method="lm")
with self.assertRaisesRegex(
pybamm.SolverError,
"Could not find consistent initial conditions: solver terminated",
):
solver.calculate_consistent_state(Model())
# with casadi
solver = pybamm.BaseSolver(root_method="casadi")
with self.assertRaisesRegex(
pybamm.SolverError,
"Could not find consistent initial conditions: .../casadi",
):
solver.calculate_consistent_state(Model())
def test_base_solver_init(self):
solver = pybamm.BaseSolver(rtol=1e-2, atol=1e-4)
self.assertEqual(solver.rtol, 1e-2)
self.assertEqual(solver.atol, 1e-4)
solver.rtol = 1e-5
self.assertEqual(solver.rtol, 1e-5)
solver.rtol = 1e-7
self.assertEqual(solver.rtol, 1e-7)
with self.assertRaises(NotImplementedError):
solver.compute_solution(None, None)
with self.assertRaises(NotImplementedError):
solver.set_up(None)
def test_convert_to_casadi_format(self):
# Make sure model is converted to casadi format
model = pybamm.BaseModel()
v = pybamm.Variable("v")
model.rhs = {v: -1}
model.initial_conditions = {v: 1}
model.convert_to_format = "python"
disc = pybamm.Discretisation()
disc.process_model(model)
solver = pybamm.BaseSolver(root_method="casadi")
pybamm.set_logging_level("ERROR")
solver.set_up(model, {})
self.assertEqual(model.convert_to_format, "casadi")
pybamm.set_logging_level("WARNING")
def test_discretise_model(self):
# Make sure 0D model is automatically discretised
model = pybamm.BaseModel()
v = pybamm.Variable("v")
model.rhs = {v: -1}
model.initial_conditions = {v: 1}
solver = pybamm.BaseSolver()
self.assertFalse(model.is_discretised)
solver.set_up(model, {})
self.assertTrue(model.is_discretised)
# 1D model cannot be automatically discretised
model = pybamm.BaseModel()
v = pybamm.Variable("v", domain="line")
model.rhs = {v: -1}
model.initial_conditions = {v: 1}
with self.assertRaisesRegex(pybamm.DiscretisationError,
"Cannot automatically discretise model"):
solver.set_up(model, {})
def test_set_defaults(self):
sim = pybamm.Simulation(pybamm.lithium_ion.SPM())
model_options = {"thermal": "x-full"}
submesh_types = {
"Negative particle":
pybamm.MeshGenerator(pybamm.Exponential1DSubMesh)
}
solver = pybamm.BaseSolver()
quick_plot_vars = ["Negative particle surface concentration"]
sim.specs(
model_options=model_options,
submesh_types=submesh_types,
solver=solver,
quick_plot_vars=quick_plot_vars,
)
sim.set_defaults()
self.assertEqual(sim.model_options["thermal"], "x-full")
self.assertEqual(sim.submesh_types["negative particle"].submesh_type,
pybamm.Uniform1DSubMesh)
self.assertEqual(sim.quick_plot_vars, None)
self.assertIsInstance(sim.solver, pybamm.ScipySolver)
def test_find_consistent_initial_conditions(self):
# Simple system: a single algebraic equation
class ScalarModel:
def __init__(self):
self.y0 = np.array([2])
self.rhs = {}
self.jac_algebraic_eval = None
self.timescale_eval = 1
t = casadi.MX.sym("t")
y = casadi.MX.sym("y")
p = casadi.MX.sym("p")
self.casadi_algebraic = casadi.Function(
"alg", [t, y, p], [self.algebraic_eval(t, y, p)]
)
self.convert_to_format = "casadi"
def rhs_eval(self, t, y, inputs):
return np.array([])
def algebraic_eval(self, t, y, inputs):
return y + 2
solver = pybamm.BaseSolver(root_method="lm")
model = ScalarModel()
init_cond = solver.calculate_consistent_state(model)
np.testing.assert_array_equal(init_cond, -2)
# with casadi
solver_with_casadi = pybamm.BaseSolver(root_method="casadi", root_tol=1e-12)
model = ScalarModel()
init_cond = solver_with_casadi.calculate_consistent_state(model)
np.testing.assert_array_equal(init_cond, -2)
# More complicated system
vec = np.array([0.0, 1.0, 1.5, 2.0])
class VectorModel:
def __init__(self):
self.y0 = np.zeros_like(vec)
self.rhs = {"test": "test"}
self.concatenated_rhs = np.array([1])
self.jac_algebraic_eval = None
self.timescale_eval = 1
t = casadi.MX.sym("t")
y = casadi.MX.sym("y", vec.size)
p = casadi.MX.sym("p")
self.casadi_algebraic = casadi.Function(
"alg", [t, y, p], [self.algebraic_eval(t, y, p)]
)
self.convert_to_format = "casadi"
def rhs_eval(self, t, y, inputs):
return y[0:1]
def algebraic_eval(self, t, y, inputs):
return (y[1:] - vec[1:]) ** 2
model = VectorModel()
init_cond = solver.calculate_consistent_state(model)
np.testing.assert_array_almost_equal(init_cond, vec)
# with casadi
init_cond = solver_with_casadi.calculate_consistent_state(model)
np.testing.assert_array_almost_equal(init_cond, vec)
# With jacobian
def jac_dense(t, y, inputs):
return 2 * np.hstack([np.zeros((3, 1)), np.diag(y[1:] - vec[1:])])
model.jac_algebraic_eval = jac_dense
init_cond = solver.calculate_consistent_state(model)
np.testing.assert_array_almost_equal(init_cond, vec)
# With sparse jacobian
def jac_sparse(t, y, inputs):
return 2 * csr_matrix(
np.hstack([np.zeros((3, 1)), np.diag(y[1:] - vec[1:])])
)
model.jac_algebraic_eval = jac_sparse
init_cond = solver.calculate_consistent_state(model)
np.testing.assert_array_almost_equal(init_cond, vec)
