Vehicle-Anti-Theft-Face-Rec.../venv/Lib/site-packages/skimage/measure/tests/test_marching_cubes.py

import numpy as np
from skimage.draw import ellipsoid, ellipsoid_stats
from skimage.measure import marching_cubes, mesh_surface_area
from skimage._shared import testing
from skimage._shared.testing import assert_array_equal
import pytest

def test_marching_cubes_isotropic():
    ellipsoid_isotropic = ellipsoid(6, 10, 16, levelset=True)
    _, surf = ellipsoid_stats(6, 10, 16)

    # Classic
    verts, faces = marching_cubes(ellipsoid_isotropic, 0., method='_lorensen')
    surf_calc = mesh_surface_area(verts, faces)
    # Test within 1% tolerance for isotropic. Will always underestimate.
    assert surf > surf_calc and surf_calc > surf * 0.99

    # Lewiner
    verts, faces = marching_cubes(ellipsoid_isotropic, 0.)[:2]
    surf_calc = mesh_surface_area(verts, faces)
    # Test within 1% tolerance for isotropic. Will always underestimate.
    assert surf > surf_calc and surf_calc > surf * 0.99


def test_marching_cubes_anisotropic():
    # test spacing as numpy array (and not just tuple)
    spacing = np.array([1., 10 / 6., 16 / 6.])
    ellipsoid_anisotropic = ellipsoid(6, 10, 16, spacing=spacing,
                                      levelset=True)
    _, surf = ellipsoid_stats(6, 10, 16)

    # Classic
    verts, faces = marching_cubes(ellipsoid_anisotropic, 0.,
                                  spacing=spacing, method='_lorensen')
    surf_calc = mesh_surface_area(verts, faces)
    # Test within 1.5% tolerance for anisotropic. Will always underestimate.
    assert surf > surf_calc and surf_calc > surf * 0.985

    # Lewiner
    verts, faces = marching_cubes(ellipsoid_anisotropic, 0.,
                                  spacing=spacing)[:2]
    surf_calc = mesh_surface_area(verts, faces)
    # Test within 1.5% tolerance for anisotropic. Will always underestimate.
    assert surf > surf_calc and surf_calc > surf * 0.985

    # Test marching cube with mask
    with pytest.raises(ValueError):
        verts, faces = marching_cubes(
            ellipsoid_anisotropic, 0., spacing=spacing,
            mask=np.array([]))[:2]

    # Test spacing together with allow_degenerate=False
    marching_cubes(ellipsoid_anisotropic, 0, spacing=spacing,
                   allow_degenerate=False)


def test_invalid_input():
    # Classic
    with testing.raises(ValueError):
        marching_cubes(np.zeros((2, 2, 1)), 0, method='_lorensen')
    with testing.raises(ValueError):
        marching_cubes(np.zeros((2, 2, 1)), 1, method='_lorensen')
    with testing.raises(ValueError):
        marching_cubes(np.ones((3, 3, 3)), 1, spacing=(1, 2), method='_lorensen')
    with testing.raises(ValueError):
        marching_cubes(np.zeros((20, 20)), 0, method='_lorensen')

    # Lewiner
    with testing.raises(ValueError):
        marching_cubes(np.zeros((2, 2, 1)), 0)
    with testing.raises(ValueError):
        marching_cubes(np.zeros((2, 2, 1)), 1)
    with testing.raises(ValueError):
        marching_cubes(np.ones((3, 3, 3)), 1, spacing=(1, 2))
    with testing.raises(ValueError):
        marching_cubes(np.zeros((20, 20)), 0)


def test_both_algs_same_result_ellipse():
    # Performing this test on data that does not have ambiguities

    sphere_small = ellipsoid(1, 1, 1, levelset=True)

    vertices1, faces1 = marching_cubes(sphere_small, 0, method='_lorensen')[:2]
    vertices2, faces2 = marching_cubes(sphere_small, 0,
                                       allow_degenerate=False)[:2]
    vertices3, faces3 = marching_cubes(sphere_small, 0,
                                       allow_degenerate=False,
                                       method='lorensen')[:2]

    # Order is different, best we can do is test equal shape and same
    # vertices present
    assert _same_mesh(vertices1, faces1, vertices2, faces2)
    assert _same_mesh(vertices1, faces1, vertices3, faces3)


def _same_mesh(vertices1, faces1, vertices2, faces2, tol=1e-10):
    """ Compare two meshes, using a certain tolerance and invariant to
    the order of the faces.
    """
    # Unwind vertices
    triangles1 = vertices1[np.array(faces1)]
    triangles2 = vertices2[np.array(faces2)]
    # Sort vertices within each triangle
    triang1 = [np.concatenate(sorted(t, key=lambda x:tuple(x)))
               for t in triangles1]
    triang2 = [np.concatenate(sorted(t, key=lambda x:tuple(x)))
               for t in triangles2]
    # Sort the resulting 9-element "tuples"
    triang1 = np.array(sorted([tuple(x) for x in triang1]))
    triang2 = np.array(sorted([tuple(x) for x in triang2]))
    return (triang1.shape == triang2.shape and
            np.allclose(triang1, triang2, 0, tol))


def test_both_algs_same_result_donut():
    # Performing this test on data that does not have ambiguities
    n = 48
    a, b = 2.5/n, -1.25

    vol = np.empty((n, n, n), 'float32')
    for iz in range(vol.shape[0]):
        for iy in range(vol.shape[1]):
            for ix in range(vol.shape[2]):
                # Double-torii formula by Thomas Lewiner
                z, y, x = float(iz)*a+b, float(iy)*a+b, float(ix)*a+b
                vol[iz,iy,ix] = ( (
                    (8*x)**2 + (8*y-2)**2 + (8*z)**2 + 16 - 1.85*1.85 ) * ( (8*x)**2 +
                    (8*y-2)**2 + (8*z)**2 + 16 - 1.85*1.85 ) - 64 * ( (8*x)**2 + (8*y-2)**2 )
                    ) * ( ( (8*x)**2 + ((8*y-2)+4)*((8*y-2)+4) + (8*z)**2 + 16 - 1.85*1.85 )
                    * ( (8*x)**2 + ((8*y-2)+4)*((8*y-2)+4) + (8*z)**2 + 16 - 1.85*1.85 ) -
                    64 * ( ((8*y-2)+4)*((8*y-2)+4) + (8*z)**2
                    ) ) + 1025

    vertices1, faces1 = marching_cubes(vol, 0, method='_lorensen')[:2]
    vertices2, faces2 = marching_cubes(vol, 0)[:2]
    vertices3, faces3 = marching_cubes(vol, 0, method='lorensen')[:2]

    # Old and new alg are different
    assert not _same_mesh(vertices1, faces1, vertices2, faces2)
    # New classic and new Lewiner are different
    assert not _same_mesh(vertices2, faces2, vertices3, faces3)
    # Would have been nice if old and new classic would have been the same
    # assert _same_mesh(vertices1, faces1, vertices3, faces3, 5)


def test_masked_marching_cubes():

    ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)
    mask = np.ones_like(ellipsoid_scalar, dtype=bool)
    mask[:10, :, :] = False
    mask[:, :, 20:] = False
    ver, faces, _, _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)
    area = mesh_surface_area(ver, faces)

    np.testing.assert_allclose(area, 299.56878662109375, rtol=.01)


def test_masked_marching_cubes_empty():
    ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)
    mask = np.array([])
    with pytest.raises(ValueError):
        _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)


def test_masked_marching_cubes_old_lewiner():
    ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)
    mask = np.array([])
    with pytest.raises(NotImplementedError):
        _ = marching_cubes(ellipsoid_scalar, 0, mask=mask, method='_lorensen')


def test_masked_marching_cubes_all_true():
    ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)
    mask = np.ones_like(ellipsoid_scalar, dtype=bool)
    ver_m, faces_m, _, _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)
    ver, faces, _, _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)
    np.testing.assert_allclose(ver_m, ver, rtol=.00001)
    np.testing.assert_allclose(faces_m, faces, rtol=.00001)
Fixed database typo and removed unnecessary class identifier. 2020-10-14 14:10:37 +00:00			`import numpy as np`
			`from skimage.draw import ellipsoid, ellipsoid_stats`
			`from skimage.measure import marching_cubes, mesh_surface_area`
			`from skimage._shared import testing`
			`from skimage._shared.testing import assert_array_equal`
			`import pytest`

			`def test_marching_cubes_isotropic():`
			`ellipsoid_isotropic = ellipsoid(6, 10, 16, levelset=True)`
			`_, surf = ellipsoid_stats(6, 10, 16)`

			`# Classic`
			`verts, faces = marching_cubes(ellipsoid_isotropic, 0., method='_lorensen')`
			`surf_calc = mesh_surface_area(verts, faces)`
			`# Test within 1% tolerance for isotropic. Will always underestimate.`
			`assert surf > surf_calc and surf_calc > surf * 0.99`

			`# Lewiner`
			`verts, faces = marching_cubes(ellipsoid_isotropic, 0.)[:2]`
			`surf_calc = mesh_surface_area(verts, faces)`
			`# Test within 1% tolerance for isotropic. Will always underestimate.`
			`assert surf > surf_calc and surf_calc > surf * 0.99`


			`def test_marching_cubes_anisotropic():`
			`# test spacing as numpy array (and not just tuple)`
			`spacing = np.array([1., 10 / 6., 16 / 6.])`
			`ellipsoid_anisotropic = ellipsoid(6, 10, 16, spacing=spacing,`
			`levelset=True)`
			`_, surf = ellipsoid_stats(6, 10, 16)`

			`# Classic`
			`verts, faces = marching_cubes(ellipsoid_anisotropic, 0.,`
			`spacing=spacing, method='_lorensen')`
			`surf_calc = mesh_surface_area(verts, faces)`
			`# Test within 1.5% tolerance for anisotropic. Will always underestimate.`
			`assert surf > surf_calc and surf_calc > surf * 0.985`

			`# Lewiner`
			`verts, faces = marching_cubes(ellipsoid_anisotropic, 0.,`
			`spacing=spacing)[:2]`
			`surf_calc = mesh_surface_area(verts, faces)`
			`# Test within 1.5% tolerance for anisotropic. Will always underestimate.`
			`assert surf > surf_calc and surf_calc > surf * 0.985`

			`# Test marching cube with mask`
			`with pytest.raises(ValueError):`
			`verts, faces = marching_cubes(`
			`ellipsoid_anisotropic, 0., spacing=spacing,`
			`mask=np.array([]))[:2]`

			`# Test spacing together with allow_degenerate=False`
			`marching_cubes(ellipsoid_anisotropic, 0, spacing=spacing,`
			`allow_degenerate=False)`


			`def test_invalid_input():`
			`# Classic`
			`with testing.raises(ValueError):`
			`marching_cubes(np.zeros((2, 2, 1)), 0, method='_lorensen')`
			`with testing.raises(ValueError):`
			`marching_cubes(np.zeros((2, 2, 1)), 1, method='_lorensen')`
			`with testing.raises(ValueError):`
			`marching_cubes(np.ones((3, 3, 3)), 1, spacing=(1, 2), method='_lorensen')`
			`with testing.raises(ValueError):`
			`marching_cubes(np.zeros((20, 20)), 0, method='_lorensen')`

			`# Lewiner`
			`with testing.raises(ValueError):`
			`marching_cubes(np.zeros((2, 2, 1)), 0)`
			`with testing.raises(ValueError):`
			`marching_cubes(np.zeros((2, 2, 1)), 1)`
			`with testing.raises(ValueError):`
			`marching_cubes(np.ones((3, 3, 3)), 1, spacing=(1, 2))`
			`with testing.raises(ValueError):`
			`marching_cubes(np.zeros((20, 20)), 0)`


			`def test_both_algs_same_result_ellipse():`
			`# Performing this test on data that does not have ambiguities`

			`sphere_small = ellipsoid(1, 1, 1, levelset=True)`

			`vertices1, faces1 = marching_cubes(sphere_small, 0, method='_lorensen')[:2]`
			`vertices2, faces2 = marching_cubes(sphere_small, 0,`
			`allow_degenerate=False)[:2]`
			`vertices3, faces3 = marching_cubes(sphere_small, 0,`
			`allow_degenerate=False,`
			`method='lorensen')[:2]`

			`# Order is different, best we can do is test equal shape and same`
			`# vertices present`
			`assert _same_mesh(vertices1, faces1, vertices2, faces2)`
			`assert _same_mesh(vertices1, faces1, vertices3, faces3)`


			`def _same_mesh(vertices1, faces1, vertices2, faces2, tol=1e-10):`
			`""" Compare two meshes, using a certain tolerance and invariant to`
			`the order of the faces.`
			`"""`
			`# Unwind vertices`
			`triangles1 = vertices1[np.array(faces1)]`
			`triangles2 = vertices2[np.array(faces2)]`
			`# Sort vertices within each triangle`
			`triang1 = [np.concatenate(sorted(t, key=lambda x:tuple(x)))`
			`for t in triangles1]`
			`triang2 = [np.concatenate(sorted(t, key=lambda x:tuple(x)))`
			`for t in triangles2]`
			`# Sort the resulting 9-element "tuples"`
			`triang1 = np.array(sorted([tuple(x) for x in triang1]))`
			`triang2 = np.array(sorted([tuple(x) for x in triang2]))`
			`return (triang1.shape == triang2.shape and`
			`np.allclose(triang1, triang2, 0, tol))`


			`def test_both_algs_same_result_donut():`
			`# Performing this test on data that does not have ambiguities`
			`n = 48`
			`a, b = 2.5/n, -1.25`

			`vol = np.empty((n, n, n), 'float32')`
			`for iz in range(vol.shape[0]):`
			`for iy in range(vol.shape[1]):`
			`for ix in range(vol.shape[2]):`
			`# Double-torii formula by Thomas Lewiner`
			`z, y, x = float(iz)a+b, float(iy)a+b, float(ix)*a+b`
			`vol[iz,iy,ix] = ( (`
			`(8x)2 + (8y-2)*2 + (8z)*2 + 16 - 1.851.85 ) * ( (8x)*2 +`
			`(8y-2)2 + (8z)*2 + 16 - 1.851.85 ) - 64 * ( (8x)2 + (8y-2)**2 )`
			`) * ( ( (8x)2 + ((8y-2)+4)((8y-2)+4) + (8z)2 + 16 - 1.851.85 )`
			`* ( (8x)2 + ((8y-2)+4)((8y-2)+4) + (8z)2 + 16 - 1.851.85 ) -`
			`64 * ( ((8y-2)+4)((8y-2)+4) + (8z)**2`
			`) ) + 1025`

			`vertices1, faces1 = marching_cubes(vol, 0, method='_lorensen')[:2]`
			`vertices2, faces2 = marching_cubes(vol, 0)[:2]`
			`vertices3, faces3 = marching_cubes(vol, 0, method='lorensen')[:2]`

			`# Old and new alg are different`
			`assert not _same_mesh(vertices1, faces1, vertices2, faces2)`
			`# New classic and new Lewiner are different`
			`assert not _same_mesh(vertices2, faces2, vertices3, faces3)`
			`# Would have been nice if old and new classic would have been the same`
			`# assert _same_mesh(vertices1, faces1, vertices3, faces3, 5)`


			`def test_masked_marching_cubes():`

			`ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)`
			`mask = np.ones_like(ellipsoid_scalar, dtype=bool)`
			`mask[:10, :, :] = False`
			`mask[:, :, 20:] = False`
			`ver, faces, _, _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)`
			`area = mesh_surface_area(ver, faces)`

			`np.testing.assert_allclose(area, 299.56878662109375, rtol=.01)`


			`def test_masked_marching_cubes_empty():`
			`ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)`
			`mask = np.array([])`
			`with pytest.raises(ValueError):`
			`_ = marching_cubes(ellipsoid_scalar, 0, mask=mask)`


			`def test_masked_marching_cubes_old_lewiner():`
			`ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)`
			`mask = np.array([])`
			`with pytest.raises(NotImplementedError):`
			`_ = marching_cubes(ellipsoid_scalar, 0, mask=mask, method='_lorensen')`


			`def test_masked_marching_cubes_all_true():`
			`ellipsoid_scalar = ellipsoid(6, 10, 16, levelset=True)`
			`mask = np.ones_like(ellipsoid_scalar, dtype=bool)`
			`ver_m, faces_m, _, _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)`
			`ver, faces, _, _ = marching_cubes(ellipsoid_scalar, 0, mask=mask)`
			`np.testing.assert_allclose(ver_m, ver, rtol=.00001)`
			`np.testing.assert_allclose(faces_m, faces, rtol=.00001)`