204 lines
5.6 KiB
Python
204 lines
5.6 KiB
Python
"""
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sample.py
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------------
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Randomly sample surface and volume of meshes.
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"""
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import numpy as np
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from . import util
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from . import transformations
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def sample_surface(mesh, count):
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"""
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Sample the surface of a mesh, returning the specified
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number of points
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For individual triangle sampling uses this method:
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http://mathworld.wolfram.com/TrianglePointPicking.html
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Parameters
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---------
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mesh : trimesh.Trimesh
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Geometry to sample the surface of
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count : int
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Number of points to return
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Returns
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---------
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samples : (count, 3) float
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Points in space on the surface of mesh
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face_index : (count,) int
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Indices of faces for each sampled point
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"""
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# len(mesh.faces) float, array of the areas
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# of each face of the mesh
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area = mesh.area_faces
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# total area (float)
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area_sum = np.sum(area)
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# cumulative area (len(mesh.faces))
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area_cum = np.cumsum(area)
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face_pick = np.random.random(count) * area_sum
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face_index = np.searchsorted(area_cum, face_pick)
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# pull triangles into the form of an origin + 2 vectors
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tri_origins = mesh.triangles[:, 0]
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tri_vectors = mesh.triangles[:, 1:].copy()
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tri_vectors -= np.tile(tri_origins, (1, 2)).reshape((-1, 2, 3))
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# pull the vectors for the faces we are going to sample from
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tri_origins = tri_origins[face_index]
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tri_vectors = tri_vectors[face_index]
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# randomly generate two 0-1 scalar components to multiply edge vectors by
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random_lengths = np.random.random((len(tri_vectors), 2, 1))
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# points will be distributed on a quadrilateral if we use 2 0-1 samples
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# if the two scalar components sum less than 1.0 the point will be
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# inside the triangle, so we find vectors longer than 1.0 and
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# transform them to be inside the triangle
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random_test = random_lengths.sum(axis=1).reshape(-1) > 1.0
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random_lengths[random_test] -= 1.0
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random_lengths = np.abs(random_lengths)
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# multiply triangle edge vectors by the random lengths and sum
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sample_vector = (tri_vectors * random_lengths).sum(axis=1)
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# finally, offset by the origin to generate
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# (n,3) points in space on the triangle
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samples = sample_vector + tri_origins
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return samples, face_index
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def volume_mesh(mesh, count):
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"""
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Use rejection sampling to produce points randomly
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distributed in the volume of a mesh.
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Parameters
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---------
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mesh : trimesh.Trimesh
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Geometry to sample
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count : int
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Number of points to return
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Returns
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---------
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samples : (n, 3) float
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Points in the volume of the mesh where n <= count
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"""
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points = (np.random.random((count, 3)) * mesh.extents) + mesh.bounds[0]
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contained = mesh.contains(points)
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samples = points[contained][:count]
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return samples
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def volume_rectangular(extents,
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count,
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transform=None):
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"""
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Return random samples inside a rectangular volume,
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useful for sampling inside oriented bounding boxes.
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Parameters
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----------
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extents : (3,) float
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Side lengths of rectangular solid
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count : int
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Number of points to return
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transform : (4, 4) float
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Homogeneous transformation matrix
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Returns
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---------
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samples : (count, 3) float
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Points in requested volume
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"""
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samples = np.random.random((count, 3)) - .5
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samples *= extents
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if transform is not None:
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samples = transformations.transform_points(samples,
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transform)
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return samples
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def sample_surface_even(mesh, count, radius=None):
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"""
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Sample the surface of a mesh, returning samples which are
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VERY approximately evenly spaced. This is accomplished by
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sampling and then rejecting pairs that are too close together.
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Note that since it is using rejection sampling it may return
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fewer points than requested (i.e. n < count). If this is the
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case a log.warning will be emitted.
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Parameters
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---------
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mesh : trimesh.Trimesh
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Geometry to sample the surface of
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count : int
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Number of points to return
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radius : None or float
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Removes samples below this radius
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Returns
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---------
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samples : (n, 3) float
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Points in space on the surface of mesh
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face_index : (n,) int
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Indices of faces for each sampled point
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"""
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from .points import remove_close
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# guess radius from area
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if radius is None:
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radius = np.sqrt(mesh.area / (3 * count))
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# get points on the surface
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points, index = sample_surface(mesh, count * 3)
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# remove the points closer than radius
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points, mask = remove_close(points, radius)
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# we got all the samples we expect
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if len(points) >= count:
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return points[:count], index[mask][:count]
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# warn if we didn't get all the samples we expect
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util.log.warning('only got {}/{} samples!'.format(
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len(points), count))
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return points, index[mask]
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def sample_surface_sphere(count):
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"""
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Correctly pick random points on the surface of a unit sphere
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Uses this method:
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http://mathworld.wolfram.com/SpherePointPicking.html
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Parameters
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----------
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count : int
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Number of points to return
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Returns
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----------
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points : (count, 3) float
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Random points on the surface of a unit sphere
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"""
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# get random values 0.0-1.0
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u, v = np.random.random((2, count))
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# convert to two angles
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theta = np.pi * 2 * u
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phi = np.arccos((2 * v) - 1)
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# convert spherical coordinates to cartesian
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points = util.spherical_to_vector(
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np.column_stack((theta, phi)))
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return points
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