8b7b61b3bd
* Adding Equations, solving typos * improve _code.rst * the team rst and restuctore index.rst * fixing errors --------- Co-authored-by: Dario Coscia <dariocoscia@dhcp-015.eduroam.sissa.it>
123 lines
3.8 KiB
Python
123 lines
3.8 KiB
Python
import torch
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import pytest
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from pina.problem import SpatialProblem
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from pina.operators import laplacian
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from pina import LabelTensor, Condition
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from pina.geometry import CartesianDomain
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from pina.equation.equation import Equation
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from pina.equation.equation_factory import FixedValue
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def laplace_equation(input_, output_):
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force_term = (torch.sin(input_.extract(['x']) * torch.pi) *
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torch.sin(input_.extract(['y']) * torch.pi))
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delta_u = laplacian(output_.extract(['u']), input_)
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return delta_u - force_term
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my_laplace = Equation(laplace_equation)
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in_ = LabelTensor(torch.tensor([[0., 1.]], requires_grad=True), ['x', 'y'])
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out_ = LabelTensor(torch.tensor([[0.]], requires_grad=True), ['u'])
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class Poisson(SpatialProblem):
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output_variables = ['u']
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spatial_domain = CartesianDomain({'x': [0, 1], 'y': [0, 1]})
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conditions = {
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'gamma1':
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Condition(location=CartesianDomain({
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'x': [0, 1],
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'y': 1
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}),
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equation=FixedValue(0.0)),
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'gamma2':
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Condition(location=CartesianDomain({
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'x': [0, 1],
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'y': 0
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}),
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equation=FixedValue(0.0)),
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'gamma3':
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Condition(location=CartesianDomain({
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'x': 1,
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'y': [0, 1]
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}),
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equation=FixedValue(0.0)),
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'gamma4':
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Condition(location=CartesianDomain({
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'x': 0,
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'y': [0, 1]
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}),
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equation=FixedValue(0.0)),
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'D':
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Condition(location=CartesianDomain({
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'x': [0, 1],
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'y': [0, 1]
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}),
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equation=my_laplace),
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'data':
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Condition(input_points=in_, output_points=out_)
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}
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def poisson_sol(self, pts):
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return -(torch.sin(pts.extract(['x']) * torch.pi) *
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torch.sin(pts.extract(['y']) * torch.pi)) / (2 * torch.pi**2)
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truth_solution = poisson_sol
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# make the problem
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poisson_problem = Poisson()
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def test_discretise_domain():
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n = 10
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boundaries = ['gamma1', 'gamma2', 'gamma3', 'gamma4']
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poisson_problem.discretise_domain(n, 'grid', locations=boundaries)
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for b in boundaries:
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assert poisson_problem.input_pts[b].shape[0] == n
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poisson_problem.discretise_domain(n, 'random', locations=boundaries)
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for b in boundaries:
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assert poisson_problem.input_pts[b].shape[0] == n
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poisson_problem.discretise_domain(n, 'grid', locations=['D'])
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assert poisson_problem.input_pts['D'].shape[0] == n**2
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poisson_problem.discretise_domain(n, 'random', locations=['D'])
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assert poisson_problem.input_pts['D'].shape[0] == n
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poisson_problem.discretise_domain(n, 'latin', locations=['D'])
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assert poisson_problem.input_pts['D'].shape[0] == n
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poisson_problem.discretise_domain(n, 'lh', locations=['D'])
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assert poisson_problem.input_pts['D'].shape[0] == n
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def test_sampling_few_variables():
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n = 10
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poisson_problem.discretise_domain(n,
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'grid',
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locations=['D'],
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variables=['x'])
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assert poisson_problem.input_pts['D'].shape[1] == 1
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assert poisson_problem._have_sampled_points['D'] is False
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# def test_sampling_all_args():
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# n = 10
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# poisson_problem.discretise_domain(n, 'grid', locations=['D'])
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# def test_sampling_all_kwargs():
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# n = 10
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# poisson_problem.discretise_domain(n=n, mode='latin', locations=['D'])
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# def test_sampling_dict():
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# n = 10
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# poisson_problem.discretise_domain(
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# {'variables': ['x', 'y'], 'mode': 'grid', 'n': n}, locations=['D'])
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# def test_sampling_mixed_args_kwargs():
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# n = 10
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# with pytest.raises(ValueError):
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# poisson_problem.discretise_domain(n, mode='latin', locations=['D'])
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