Ejemplo n.º 1
0
    def __init__(self, topoconfig: TopoConfig, grid: Gridlines, dtype: str):
        dtype = DummyDtype.validator(dtype)
        dem, _ = read_cf(topoconfig.file, [topoconfig.key])

        # copy to a nplike.ndarray
        vert = nplike.array(dem[topoconfig.key][:])

        # see if we need to do interpolation
        try:
            interp = not (nplike.allclose(grid.x.vert, nplike.array(dem["x"]))
                          and nplike.allclose(grid.y.vert,
                                              nplike.array(dem["y"])))
        except ValueError:  # assume thie excpetion means a shape mismatch
            interp = True

        # unfortunately, we need to do interpolation in such a situation
        if interp:
            interpolator = RectBivariateSpline(dem["x"], dem["y"], vert.T)
            vert = nplike.array(interpolator(
                grid.x.vert, grid.y.vert).T)  # it uses vanilla numpy

        # cast to desired float type
        vert = vert.astype(dtype)

        # topography elevation at cell centers through linear interpolation
        cntr = vert[:-1, :-1] + vert[:-1, 1:] + vert[1:, :-1] + vert[1:, 1:]
        cntr /= 4

        # topography elevation at cell faces' midpoints through linear interpolation
        xface = (vert[:-1, :] + vert[1:, :]) / 2.
        yface = (vert[:, :-1] + vert[:, 1:]) / 2.

        # gradient at cell centers through central difference; here allows nonuniform grids
        # this function does not assume constant cell sizes, so we re-calculate dx, dy
        # the `delta`s in grid.x and y are constants (current solver only supports uniform grid)
        xgrad = (xface[:, 1:] - xface[:, :-1]) / (grid.x.vert[1:] -
                                                  grid.x.vert[:-1])[None, :]
        ygrad = (yface[1:, :] - yface[:-1, :]) / (grid.y.vert[1:] -
                                                  grid.y.vert[:-1])[:, None]

        # initialize DataModel and let pydantic validates data
        super().__init__(nx=grid.x.n,
                         ny=grid.y.n,
                         dtype=dtype,
                         vert=vert,
                         cntr=cntr,
                         xface=xface,
                         yface=yface,
                         xgrad=xgrad,
                         ygrad=ygrad)
Ejemplo n.º 2
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def minmod_slope_x_one_comp(q: nplike.ndarray, dx: float, ngh: int,
                            theta: float, tol: float):
    """Minmod slope in x direction for only one conservative quantity.

    Arguments
    ---------
    q : nplike.ndarray
        (ny+2*ngh, nx+2*ngh) array of a conservative quantity.
    dx : float
        Cell size in x-direction. Assume an uniform grid.
    ngh : int
        Number of ghost cell layers outside each boundary.
    theta: float
        Parameter to controll oscillation and dispassion. 1 <= theta <= 2.
    tol : float
        To control how small can be treat as zero.

    Returns
    -------
    slpx : nplike.ndarray
        (ny, nx+2) array of the slopes in x-direction, including one ghost layer at west and east.
    """
    # pylint: disable=invalid-name

    cells = slice(ngh, -ngh)  # non-ghost cells, length ny or nx
    i = slice(ngh - 1, q.shape[1] - ngh +
              1)  # i = one ghost outside each bound; length nx+2
    ip1 = slice(ngh, q.shape[1] - ngh + 2)  # i + 1; length nx+2
    im1 = slice(ngh - 2, q.shape[1] - ngh)  # i - 1; length nx+2

    denominator = q[cells, ip1] - q[cells,
                                    i]  # q_{j, i+1} - q_{j, i} for all j
    zeros = nplike.nonzero(
        nplike.logical_and(denominator > -tol, denominator < tol))

    with nplike.errstate(divide="ignore", invalid="ignore"):
        slpx = (q[cells, i] - q[cells, im1]) / denominator

    slpx[zeros] = 0.  # where q_{j, i+1} - q_{j, i} = 0

    slpx = nplike.maximum(
        nplike.minimum(nplike.minimum(theta * slpx, (1. + slpx) / 2.),
                       nplike.array(theta)), nplike.array(0.))

    slpx *= denominator
    slpx /= dx

    return slpx
Ejemplo n.º 3
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def get_local_speed(states: States, gravity: float) -> States:
    """Calculate local speeds on the two sides of cell faces.

    Arguments
    ---------
    states : torchswe.utils.data.States
    gravity : float
        Gravity in m / s^2.

    Returns
    -------
    states : torchswe.utils.data.States
        The same object as the input. Changed inplace. Returning it just for coding style.
    """

    # faces normal to x-direction
    sqrt_gh_plus = nplike.sqrt(gravity * states.face.x.plus.h)
    sqrt_gh_minus = nplike.sqrt(gravity * states.face.x.minus.h)

    # for convenience
    zero = nplike.array(0.)

    states.face.x.plus.a = nplike.maximum(
        nplike.maximum(states.face.x.plus.u + sqrt_gh_plus,
                       states.face.x.minus.u + sqrt_gh_minus), zero)

    states.face.x.minus.a = nplike.minimum(
        nplike.minimum(states.face.x.plus.u - sqrt_gh_plus,
                       states.face.x.minus.u - sqrt_gh_minus), zero)

    # faces normal to y-direction
    sqrt_gh_plus = nplike.sqrt(gravity * states.face.y.plus.h)
    sqrt_gh_minus = nplike.sqrt(gravity * states.face.y.minus.h)

    states.face.y.plus.a = nplike.maximum(
        nplike.maximum(states.face.y.plus.v + sqrt_gh_plus,
                       states.face.y.minus.v + sqrt_gh_minus), zero)

    states.face.y.minus.a = nplike.minimum(
        nplike.minimum(states.face.y.plus.v - sqrt_gh_plus,
                       states.face.y.minus.v - sqrt_gh_minus), zero)

    return states
Ejemplo n.º 4
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def create_ic(comm, ic_config, grid, topo, dtype):
    """Create initial conditions.

    When the x_cntr and y_cntr have different resolutions from the x and y in the NetCDF file, an
    bi-cubic spline interpolation will take place.

    Arguments
    ---------
    comm : mpi4py.MPI.Comm
        The communicator.
    ic_config : torchswe.utils.config.ICConfig
    grid : torchswe.utils.data.Gridlines
    topo : torchswe.utils.data.Topography
    dtype : str; either "float32" or "float64"

    Returns
    -------
    torchswe.utils.data.WHUHVModel
    """

    # special case: constant I.C.
    if ic_config.values is not None:
        return _WHUHVModel(nx=grid.x.n,
                           ny=grid.y.n,
                           dtype=dtype,
                           w=_nplike.maximum(
                               topo.cntr, _nplike.array(ic_config.values[0])),
                           hu=_nplike.full(topo.cntr.shape,
                                           ic_config.values[1],
                                           dtype=topo.dtype),
                           hv=_nplike.full(topo.cntr.shape,
                                           ic_config.values[2],
                                           dtype=topo.dtype))

    # otherwise, read data from a NetCDF file
    icdata, _ = _ncread(
        ic_config.file,
        ic_config.keys,
        [grid.x.cntr[0], grid.x.cntr[-1], grid.y.cntr[0], grid.y.cntr[-1]],
        parallel=True,
        comm=comm)

    # see if we need to do interpolation
    try:
        interp = not (_nplike.allclose(grid.x.cntr, icdata["x"])
                      and _nplike.allclose(grid.y.cntr, icdata["y"]))
    except ValueError:  # assume thie excpetion means a shape mismatch
        interp = True

    # unfortunately, we need to do interpolation in such a situation
    if interp:
        _logger.warning("Grids do not match. Doing spline interpolation.")
        w = _nplike.array(
            _interpolate(icdata["x"], icdata["y"], icdata[ic_config.keys[0]].T,
                         grid.x.cntr, grid.y.cntr).T)

        hu = _nplike.array(
            _interpolate(icdata["x"], icdata["y"], icdata[ic_config.keys[1]].T,
                         grid.x.cntr, grid.y.cntr).T)

        hv = _nplike.array(
            _interpolate(icdata["x"], icdata["y"], icdata[ic_config.keys[2]].T,
                         grid.x.cntr, grid.y.cntr).T)
    else:
        w = icdata[ic_config.keys[0]]
        hu = icdata[ic_config.keys[1]]
        hv = icdata[ic_config.keys[2]]

    # make sure the w can not be smaller than topopgraphy elevation
    w = _nplike.maximum(w, topo.cntr)

    return _WHUHVModel(nx=grid.x.n,
                       ny=grid.y.n,
                       dtype=dtype,
                       w=w,
                       hu=hu,
                       hv=hv)
Ejemplo n.º 5
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def get_topography(topofile: Union[str, os.PathLike], key: str,
                   grid_xv: nplike.ndarray, grid_yv: nplike.ndarray,
                   dtype: str):
    """Get a Topography object from a config object.

    Arguments
    ---------
    topofile : str or PathLike
    key : str
    grid_xv, grid_yv : nplike.ndarray
    dtype : str, nplike.float32, nplike.float64

    Returns
    -------
    topo : Topography
    """
    dtype = DummyDtype.validator(dtype)
    assert dtype == grid_xv.dtype
    assert dtype == grid_yv.dtype

    dem, _ = ncread(topofile, [key])

    vert = dem[key]

    # see if we need to do interpolation
    try:
        interp = not (nplike.allclose(grid_xv, dem["x"])
                      and nplike.allclose(grid_yv, dem["y"]))
    except ValueError:  # assume thie excpetion means a shape mismatch
        interp = True

    # unfortunately, we need to do interpolation in such a situation
    if interp:
        logger.warning("Grids do not match. Doing spline interpolation.")
        vert = nplike.array(
            _interpolate(dem["x"], dem["y"], vert.T, grid_xv, grid_yv).T)

    # cast to desired float type
    vert = vert.astype(dtype)

    # topography elevation at cell centers through linear interpolation
    cntr = vert[:-1, :-1] + vert[:-1, 1:] + vert[1:, :-1] + vert[1:, 1:]
    cntr /= 4

    # topography elevation at cell faces' midpoints through linear interpolation
    xface = (vert[:-1, :] + vert[1:, :]) / 2.
    yface = (vert[:, :-1] + vert[:, 1:]) / 2.

    # gradient at cell centers through central difference; here allows nonuniform grids
    # this function does not assume constant cell sizes
    xgrad = (xface[:, 1:] - xface[:, :-1]) / (grid_xv[1:] -
                                              grid_xv[:-1])[None, :]
    ygrad = (yface[1:, :] - yface[:-1, :]) / (grid_yv[1:] - grid_yv[:-1])[:,
                                                                          None]

    # initialize DataModel and let pydantic validates data
    return Topography(nx=len(grid_xv) - 1,
                      ny=len(grid_yv) - 1,
                      dtype=dtype,
                      vert=vert,
                      cntr=cntr,
                      xface=xface,
                      yface=yface,
                      xgrad=xgrad,
                      ygrad=ygrad)
Ejemplo n.º 6
0
 def get_uv(h, hu, hv):
     # pylint: disable=invalid-name
     h4 = nplike.power(h, 4)
     coeff = h * sqrt2 / nplike.sqrt(
         h4 + nplike.maximum(h4, nplike.array(epsilon)))
     return coeff * hu, coeff * hv
Ejemplo n.º 7
0
def create_ic(ic_config, gridlines, topo, dtype):
    """Create initial conditions.

    When the x_cntr and y_cntr have different resolutions from the x and y in the NetCDF file, an
    bi-cubic spline interpolation will take place.

    Arguments
    ---------
    ic_config : torchswe.utils.config.ICConfig
    gridlines : torchswe.utils.data.Gridlines
    topo : torchswe.utils.data.Topography
    dtype : str; either "float32" or "float64"

    Returns
    -------
    torchswe.utils.data.WHUHVModel
    """

    # special case: constant I.C.
    if ic_config.values is not None:
        return WHUHVModel(gridlines.x.n,
                          gridlines.y.n,
                          dtype,
                          w=nplike.maximum(topo.cntr,
                                           nplike.array(ic_config.values[0])),
                          hu=nplike.full(topo.cntr.shape,
                                         ic_config.values[1],
                                         dtype=topo.dtype),
                          hv=nplike.full(topo.cntr.shape,
                                         ic_config.values[2],
                                         dtype=topo.dtype))

    # otherwise, read data from a NetCDF file
    icdata, _ = read_cf(ic_config.file, ic_config.keys)

    # see if we need to do interpolation
    try:
        interp = not (
            nplike.allclose(gridlines.x.cntr, nplike.array(icdata["x"]))
            and nplike.allclose(gridlines.y.cntr, nplike.array(icdata["y"])))
    except ValueError:  # assume thie excpetion means a shape mismatch
        interp = True

    # unfortunately, we need to do interpolation in such a situation
    if interp:
        interpolator = RectBivariateSpline(icdata["x"], icdata["y"],
                                           icdata[ic_config.keys[0]][:].T)
        w = interpolator(gridlines.x.cntr, gridlines.y.cntr).T

        # get an interpolator for conserv_q_ic[1], use the default 3rd order spline
        interpolator = RectBivariateSpline(icdata["x"], icdata["y"],
                                           icdata[ic_config.keys[1]][:].T)
        hu = interpolator(gridlines.x.cntr, gridlines.y.cntr).T

        # get an interpolator for conserv_q_ic[2], use the default 3rd order spline
        interpolator = RectBivariateSpline(icdata["x"], icdata["y"],
                                           icdata[ic_config.keys[2]][:].T)
        hv = interpolator(gridlines.x.cntr, gridlines.y.cntr).T
    else:
        w = nplike.array(icdata[ic_config.keys[0]][:].copy())
        hu = nplike.array(icdata[ic_config.keys[1]][:].copy())
        hv = nplike.array(icdata[ic_config.keys[2]][:].copy())

    # make sure the w can not be smaller than topopgraphy elevation
    w = nplike.maximum(w, topo.cntr)

    return WHUHVModel(gridlines.x.n, gridlines.y.n, dtype, w=w, hu=hu, hv=hv)