Exemplo n.º 1
0
def test_approx_cli(args):
    settings = make_test_approx_parser().parse_args(args=args)

    from . import geometry, particles
    from pwkit import cgs
    from pwkit.astutil import D2R
    from pwkit.ndshow_gtk3 import cycle, view

    particles = particles.ParticleDistribution.load(settings.particles_path)
    distrib = geometry.GriddedDistribution(particles, cgs.rjup)
    soln = distrib.test_approx(
        settings.mlat * D2R,
        settings.mlon * D2R,
        settings.L,
    )

    def patchlog(a):
        pos = (a > 0)
        mn = a[pos].min()
        a[~pos] = 0.01 * mn
        return np.log10(a)

    cycle(
        [patchlog(soln.data), patchlog(soln.mdata)],
        descs = ['Data', 'Model'],
    )

    view(soln.resids, title='Residuals')
Exemplo n.º 2
0
def main():
    import omega as om
    from pwkit.ndshow_gtk3 import cycle, view

    ###xg, yg, grid1 = calculate_dynat(n_pseudo_particles=2048, n_steps=30000)
    ###xg, yg, grid1 = calculate_fixed(n_pseudo_particles=16384, delta_t=0.00001)
    ###xg, yg, grid1 = calculate_debug(n_pseudo_particles=4096, n_steps=10000, delta_t=0.00001)
    ###_, _, grid2 = calculate(delta_t=0.00005)

    y_bins = 40
    y_edges = np.linspace(YMIN, YMAX, y_bins + 1)
    y_centers = 0.5 * (y_edges[1:] + y_edges[:-1])
    yg = y_centers.reshape((-1, 1))

    x_bins = 40
    x_edges = np.linspace(XMIN, XMAX, x_bins + 1)
    x_centers = 0.5 * (x_edges[1:] + x_edges[:-1])
    xg = x_centers.reshape((1, -1))

    rho = np.sqrt(np.log(xg / x0)**2 + np.log(yg / y0)**2) / u0
    exact = ((xg * y0 / (x0 * yg))**(1. / (2 * u0 * D0)) *
             k0(rho * np.sqrt(1 + D0**2 * u0**2) / (np.sqrt(2) * D0)) /
             (2 * np.pi * D0 * u0**2 * np.sqrt(xg * yg * x0 * y0)))

    ###grid1 *= np.percentile(exact, 95) / np.percentile(grid1, 95)

    ###cycle([exact[::-1], grid1[::-1]], yflip=True)

    view(exact[::-1], yflip=True)

    p = om.RectPlot()
    p.addXY(xg, exact[10], 'exact')
    ###p.addXY(xg, grid1[10], 'mine')
    p.show()
Exemplo n.º 3
0
    def view_vk(self, data, log=False, abs=False, **kwargs):
        from pwkit.ndshow_gtk3 import view

        buf = self.vk_to_rect(data)

        if abs:
            buf = np.abs(buf)
        if log:
            buf = np.log10(buf)

        view(buf, **kwargs)
Exemplo n.º 4
0
def view_hdf5_cli(args):
    """XXX: huge code redundancy with "view cube". Whatever."""
    import h5py

    ap = argparse.ArgumentParser(prog='vernon view hdf5', )
    ap.add_argument('-s',
                    dest='stretch',
                    type=str,
                    nargs=1,
                    default=['default'],
                    choices='default sqrt neg'.split(),
                    help='What kind of stretch to use on the data.')
    ap.add_argument(
        '-p',
        dest='outer_plane_number',
        metavar='P',
        type=int,
        help='Isolate the outermost P\'th plane of the cube before viewing.')
    ap.add_argument('-T',
                    dest='transpose',
                    action='store_true',
                    help='Transpose the array before viewing.')
    ap.add_argument(
        '-f',
        dest='y_flip',
        action='store_true',
        help='Render the cube so that the first row is at the bottom.')
    ap.add_argument('FILE', metavar='HDF5-PATH', help='The HDF5 file to load')
    ap.add_argument('ITEMS',
                    nargs='+',
                    metavar='ITEM-NAMES',
                    help='The name of the item within the file to view')

    settings = ap.parse_args(args=args)
    stretch_spec = settings.stretch[0]

    if stretch_spec == 'default':
        stretch = lambda data: data
    elif stretch_spec == 'sqrt':

        def stretch(data):
            neg = (data < 0)
            data[neg] *= -1
            data = np.sqrt(data)
            data[neg] *= -1
            return data
    elif stretch_spec == 'neg':
        stretch = lambda data: (data < 0).astype(np.int)
    else:
        cli.die('unknown stretch specification %r', stretch_spec)

    if settings.y_flip:
        y_slice = slice(None, None, -1)
    else:
        y_slice = slice(None, None)

    def describe(a):
        print('Final shape:', repr(a.shape))
        print('Min/max/med: %.16e  %.16e  %.16e' %
              (np.nanmin(a), np.nanmax(a), np.nanmedian(a)))
        print('# positive / # negative / # nonfinite: %d  %d  %d' %
              ((a > 0).sum(), (a < 0).sum(), (~np.isfinite(a)).sum()))
        return a  # convenience

    arrays = []

    with h5py.File(settings.FILE, 'r') as ds:
        for item in settings.ITEMS:
            a = ds[item][...]
            if settings.outer_plane_number is not None:
                a = a[settings.outer_plane_number]
            arrays.append(a)

    if len(arrays) > 2:
        a = np.stack(arrays)
    else:
        a = arrays[0]

    if settings.transpose:
        a = a.T

    if a.ndim == 2:
        stretched = stretch(describe(a))
        view(stretched[y_slice], yflip=settings.y_flip)
    elif a.ndim == 3:
        stretched = stretch(describe(a))
        cycle(stretched[:, y_slice], yflip=settings.y_flip)
    elif a.ndim == 4:
        print('Shape:', a.shape)
        for i in range(a.shape[0]):
            stretched = stretch(describe(a[i]))
            cycle(stretched[:, y_slice], yflip=settings.y_flip)
    else:
        cli.die('cannot handle %d-dimensional arrays', a.ndim)