Esempio n. 1
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def starfish_lpot_source(queue, n_arms):
    from meshmode.discretization import Discretization
    from meshmode.discretization.poly_element import (
        InterpolatoryQuadratureSimplexGroupFactory)

    from meshmode.mesh.generation import make_curve_mesh, NArmedStarfish

    mesh = make_curve_mesh(NArmedStarfish(n_arms, 0.8),
                           np.linspace(0, 1, 1 + PANELS_PER_ARM * n_arms),
                           TARGET_ORDER)

    pre_density_discr = Discretization(
        queue.context, mesh,
        InterpolatoryQuadratureSimplexGroupFactory(TARGET_ORDER))

    lpot_kwargs = DEFAULT_LPOT_KWARGS.copy()
    lpot_kwargs.update(target_association_tolerance=0.025,
                       _expansion_stick_out_factor=TCF,
                       fmm_order=FMM_ORDER,
                       qbx_order=QBX_ORDER,
                       fmm_backend="fmmlib")

    from pytential.qbx import QBXLayerPotentialSource
    lpot_source = QBXLayerPotentialSource(pre_density_discr,
                                          OVSMP_FACTOR * TARGET_ORDER,
                                          **lpot_kwargs)

    lpot_source, _ = lpot_source.with_refinement()

    return lpot_source
Esempio n. 2
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def _build_qbx_discr(queue,
        ndim=2,
        nelements=30,
        target_order=7,
        qbx_order=4,
        curve_f=None):

    if curve_f is None:
        curve_f = NArmedStarfish(5, 0.25)

    if ndim == 2:
        mesh = make_curve_mesh(curve_f,
                np.linspace(0, 1, nelements + 1),
                target_order)
    elif ndim == 3:
        mesh = generate_torus(10.0, 2.0, order=target_order)
    else:
        raise ValueError("unsupported ambient dimension")

    from meshmode.discretization import Discretization
    from meshmode.discretization.poly_element import \
            InterpolatoryQuadratureSimplexGroupFactory
    from pytential.qbx import QBXLayerPotentialSource
    density_discr = Discretization(
            queue.context, mesh,
            InterpolatoryQuadratureSimplexGroupFactory(target_order))

    qbx, _ = QBXLayerPotentialSource(density_discr,
            fine_order=4 * target_order,
            qbx_order=qbx_order,
            fmm_order=False).with_refinement()

    return qbx
Esempio n. 3
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def test_get_qbx_center_neighborhood_sizes(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

    from meshmode.discretization import Discretization
    from meshmode.discretization.poly_element import (
            InterpolatoryQuadratureSimplexGroupFactory)

    target_order = 8
    n_arms = 5
    nelements = 50 * n_arms

    mesh = make_curve_mesh(
            NArmedStarfish(n_arms, 0.8),
            np.linspace(0, 1, nelements+1),
            target_order)

    pre_density_discr = Discretization(
            queue.context, mesh,
            InterpolatoryQuadratureSimplexGroupFactory(target_order))

    from pytential.qbx import QBXLayerPotentialSource
    lpot_source, _ = QBXLayerPotentialSource(
            pre_density_discr, 4 * target_order,
            _max_leaf_refine_weight=64,
            target_association_tolerance=1e-3,
            ).with_refinement()


    t_f = 0.9
    
    result_direct = get_qbx_center_neighborhood_sizes_direct(lpot_source, 8/t_f)
    result_aq = get_qbx_center_neighborhood_sizes(lpot_source, 8/t_f)

    assert (result_direct[0] == result_aq[0]).all()
    assert result_direct[1] == result_aq[1]
    assert result_direct[2] == result_aq[2]
Esempio n. 4
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 def curve_fn(self):
     from meshmode.mesh.generation import NArmedStarfish
     return NArmedStarfish(self.narms, self.amplitude)
 def get_mesh(self, nelements, target_order):
     return make_curve_mesh(NArmedStarfish(self.n_arms, self.amplitude),
                            np.linspace(0, 1, nelements + 1), target_order)
Esempio n. 6
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def get_starfish_mesh(n_arms, nelements, target_order):
    return make_curve_mesh(NArmedStarfish(n_arms, 0.8),
                           np.linspace(0, 1, nelements + 1), target_order)
Esempio n. 7
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    error = -np.inf
    for i in range(index_set.nblocks):
        mat_i = index_set.take(mat, i)
        blk_i = index_set.block_take(blk, i)

        error = max(error, la.norm(mat_i - blk_i) / la.norm(mat_i))

    return error


@pytest.mark.skipif(USE_SYMENGINE,
        reason="https://gitlab.tiker.net/inducer/sumpy/issues/25")
@pytest.mark.parametrize("k", [0, 42])
@pytest.mark.parametrize("curve_f", [
    partial(ellipse, 3),
    NArmedStarfish(5, 0.25)])
@pytest.mark.parametrize("lpot_id", [2, 3])
def test_matrix_build(ctx_factory, k, curve_f, lpot_id, visualize=False):
    cl_ctx = ctx_factory()
    queue = cl.CommandQueue(cl_ctx)

    # prevent cache 'splosion
    from sympy.core.cache import clear_cache
    clear_cache()

    target_order = 7
    qbx_order = 4
    nelements = 30
    mesh = make_curve_mesh(curve_f,
            np.linspace(0, 1, nelements + 1),
            target_order)
Esempio n. 8
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                vis = make_visualizer(actx, discr)
                filename = f"test_proxy_geometry_{suffix}_block_{i:04d}.vtu"
                vis.write_vtk_file(filename, [], overwrite=False)
    else:
        raise ValueError


# }}}

PROXY_TEST_CASES = [
    extra.CurveTestCase(name="ellipse",
                        target_order=7,
                        curve_fn=partial(ellipse, 3.0)),
    extra.CurveTestCase(name="starfish",
                        target_order=4,
                        curve_fn=NArmedStarfish(5, 0.25),
                        resolutions=[32]),
    extra.TorusTestCase(target_order=2, resolutions=[0])
]

# {{{ test_partition_points


@pytest.mark.parametrize("tree_kind", ["adaptive", None])
@pytest.mark.parametrize("case", PROXY_TEST_CASES)
def test_partition_points(actx_factory, tree_kind, case, visualize=False):
    """Tests that the points are correctly partitioned."""

    if case.ambient_dim == 3 and tree_kind is None:
        pytest.skip("3d partitioning requires a tree")
Esempio n. 9
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def test_build_matrix_fixed_stage(ctx_factory,
                                  source_discr_stage,
                                  target_discr_stage,
                                  visualize=False):
    """Checks that the block builders match for difference stages."""

    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)
    actx = PyOpenCLArrayContext(queue)

    # prevent cache explosion
    from sympy.core.cache import clear_cache
    clear_cache()

    case = extra.CurveTestCase(
        name="starfish",
        curve_fn=NArmedStarfish(5, 0.25),
        target_order=4,
        resolutions=[32],
        index_sparsity_factor=0.6,
        op_type="scalar",
        tree_kind=None,
    )

    logger.info("\n%s", case)

    # {{{ geometry

    dd = sym.DOFDescriptor(case.name)
    qbx = case.get_layer_potential(actx, case.resolutions[-1],
                                   case.target_order)

    places = GeometryCollection(
        {case.name: qbx},
        auto_where=(dd.copy(discr_stage=source_discr_stage),
                    dd.copy(discr_stage=target_discr_stage)))

    dd = places.auto_source
    density_discr = places.get_discretization(dd.geometry, dd.discr_stage)

    # }}}

    # {{{ symbolic

    if source_discr_stage is target_discr_stage:
        qbx_forced_limit = -1
    else:
        qbx_forced_limit = None

    sym_u, sym_op = case.get_operator(places.ambient_dim, qbx_forced_limit)

    from pytential.symbolic.execution import _prepare_expr
    sym_prep_op = _prepare_expr(places, sym_op)

    # }}}

    # {{{ check

    source_discr = places.get_discretization(case.name, source_discr_stage)
    target_discr = places.get_discretization(case.name, target_discr_stage)

    logger.info("nelements:     %d", density_discr.mesh.nelements)
    logger.info("ndofs:         %d", source_discr.ndofs)
    logger.info("ndofs:         %d", target_discr.ndofs)

    icols = case.get_block_indices(actx, source_discr, matrix_indices=False)
    irows = case.get_block_indices(actx, target_discr, matrix_indices=False)
    index_set = MatrixBlockIndexRanges(actx.context, icols, irows)

    kwargs = dict(
        dep_expr=sym_u,
        other_dep_exprs=[],
        dep_source=places.get_geometry(case.name),
        dep_discr=density_discr,
        places=places,
        context=case.knl_concrete_kwargs,
    )

    # qbx
    from pytential.symbolic import matrix
    mat = matrix.MatrixBuilder(actx, **kwargs)(sym_prep_op)
    blk = matrix.NearFieldBlockBuilder(actx, index_set=index_set,
                                       **kwargs)(sym_prep_op)

    assert mat.shape == (target_discr.ndofs, source_discr.ndofs)
    assert extra.max_block_error(mat, blk, index_set.get(queue)) < 1.0e-14

    # p2p
    mat = matrix.P2PMatrixBuilder(actx, exclude_self=True,
                                  **kwargs)(sym_prep_op)
    blk = matrix.FarFieldBlockBuilder(actx,
                                      index_set=index_set,
                                      exclude_self=True,
                                      **kwargs)(sym_prep_op)

    assert mat.shape == (target_discr.ndofs, source_discr.ndofs)
    assert extra.max_block_error(mat, blk, index_set.get(queue)) < 1.0e-14
Esempio n. 10
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from pyopencl.tools import (  # noqa
    pytest_generate_tests_for_pyopencl as pytest_generate_tests)

import extra_matrix_data as extra
import logging

logger = logging.getLogger(__name__)
logging.basicConfig(level=logging.INFO)


@pytest.mark.skipif(USE_SYMENGINE,
                    reason="https://gitlab.tiker.net/inducer/sumpy/issues/25")
@pytest.mark.parametrize("k", [0, 42])
@pytest.mark.parametrize(
    "curve_fn",
    [partial(ellipse, 3), NArmedStarfish(5, 0.25)])
@pytest.mark.parametrize("op_type", ["scalar_mixed", "vector"])
def test_build_matrix(ctx_factory, k, curve_fn, op_type, visualize=False):
    """Checks that the matrix built with `symbolic.execution.build_matrix`
    gives the same (to tolerance) answer as a direct evaluation.
    """

    cl_ctx = ctx_factory()
    queue = cl.CommandQueue(cl_ctx)
    actx = PyOpenCLArrayContext(queue)

    # prevent cache 'splosion
    from sympy.core.cache import clear_cache
    clear_cache()

    case = extra.CurveTestCase(name="curve",