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shapely_tools.py
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shapely_tools.py
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"""
library with functions to edit and perform spatial analysis on vector data.
build around shapely and fiona libraries
Created on 2016-July-16
@author: Dirk Eilander (dirk.eilander@deltares.nl)
# build on library from https://github.com/ojdo/python-tools/blob/master/shapelytools.py
"""
from shapely.geometry import (box, LineString, MultiLineString, MultiPoint,
Point, Polygon, MultiPolygon, shape)
import shapely.ops
import math
import numpy as np
from fiona import collection
# I/O
def read_geometries(fn, bbox=None):
"""
reads to shapely geometries to features using fiona collection
feature = dict('geometry': <shapely geometry>, 'properties': <dict with properties>
"""
with collection(fn, "r") as c:
ft_list = []
c = c.items(bbox=bbox)
for ft in c:
if ft[1]['geometry'] is not None:
ft_list.append(shape(ft[1]['geometry']))
return ft_list
# simplify, reduce and merge geometries methods
def prune_short_lines(lines, min_length, return_index=False):
"""Remove lines from a LineString DataFrame shorter than min_length.
Deletes all lines from a list of LineStrings or a MultiLineString
that have a total length of less than min_length. Vertices of touching
lines are contracted towards the centroid of the removed line.
Args:
lines: list of LineStrings or a MultiLineString
min_length: minimum length of a single LineString to be preserved
Returns:
the pruned list of lines
"""
pruned_lines = [line for line in lines] # converts MultiLineString to list
index = []
for i, line in enumerate(pruned_lines):
if line.length < min_length:
for n in neighbors(pruned_lines, line):
contact_point = line.intersection(pruned_lines[n])
pruned_lines[n] = bend_towards(pruned_lines[n],
where=contact_point,
to=line.centroid)
else:
index.append(i)
lines_out = [line for i, line in enumerate(pruned_lines) if i in index]
if return_index:
return lines_out, index
else:
return lines_out
def linemerge(linestrings_or_multilinestrings, return_index=False):
""" Merge list of LineStrings and/or MultiLineStrings.
Given a list of LineStrings and possibly MultiLineStrings, merge all of
them to a single MultiLineString.
Args:
list of LineStrings and/or MultiLineStrings
Returns:
a merged LineString or MultiLineString
"""
lines = []
for i, line in enumerate(linestrings_or_multilinestrings):
if isinstance(line, MultiLineString):
# line is a multilinestring, so append its components
lines.extend(line)
else:
# line is a line, so simply append it
lines.append(line)
lines_merged = shapely.ops.linemerge(lines)
if not return_index:
return lines_merged
else:
index = index_spatial_join(lines_merged, lines, function='contains')
return lines_merged, index
def extend_lines_min_length(lines, min_length=100, tolerance=1e-7):
"""lines with length smaller than min_length are extended along the neighboring line
neighboring lines are found within a distance of tolerance to its endpoints
"""
lines_out = []
for ind, of in enumerate(lines):
if of.length < min_length:
other = [line for i, line in enumerate(lines) if i != ind]
neighbor = [line for line in other if line.distance(of.boundary) < tolerance]
# go with shortest neighbor if more than one
if not len(neighbor) == 0:
nb = neighbor[0]
res_len = min_length - of.length
# construct new lines
if nb.distance(of.boundary[0]) < tolerance:
# cut line from end
nb_short, _ = cut_line(LineString(reversed(list(nb.coords))), res_len)
of = LineString(list(nb_short.coords) + list(of.coords)[1:])
elif nb.distance(of.boundary[1]) < tolerance:
# cut line
nb_short, _ = cut_line(nb, res_len)
of = LineString(list(of.coords)[:-1] + list(nb_short.coords))
lines_out.append(of)
return lines_out
def polygon_union(polygons, return_index=False):
"""returns simplified union of polygons without holes"""
# remove 'holes' in polygon
polygons_out = []
for ob in polygons:
if isinstance(ob, MultiPolygon):
for g in ob.geoms:
pol = Polygon(list(Polygon(g).exterior.coords))
polygons_out.append(pol)
elif isinstance(ob, Polygon):
pol = Polygon(list(ob.exterior.coords))
polygons_out.append(pol)
# merge polygons
polygons_union = shapely.ops.cascaded_union(polygons_out)
# return polygons_union
if not return_index:
return polygons_union
else:
index = index_spatial_join(polygons_union, polygons, function='contains')
return polygons_union, index
def one_linestring_per_intersection(lines, return_index=False):
""" Move line endpoints to intersections of line segments.
Given a list of touching or possibly intersecting LineStrings, return a
list LineStrings that have their endpoints at all crossings and
intersecting points and ONLY there.
Args:
a list of LineStrings or a MultiLineString
Returns:
a list of LineStrings
"""
lines_merged = shapely.ops.linemerge(lines)
# intersecting multiline with its bounding box somehow triggers a first
bounding_box = box(*lines_merged.bounds)
# perform linemerge (one linestring between each crossing only)
# if this fails, write function to perform this on a bbox-grid and then
# merge the result
lines_merged = lines_merged.intersection(bounding_box)
lines_merged = shapely.ops.linemerge(lines_merged)
if not return_index:
return lines_merged
else:
index = index_spatial_join(lines_merged, lines, function='contains')
return lines_merged, index
def reduce_line2singlevertex(lines, tolerance=None, return_index=False):
"""simplifies a line to a single vertex
returns a Tuple with the simplified line and the max error made
if a value for tolerance is set, lines with an error larger than tolerance are removed"""
lines_out = [LineString((line.coords[0], line.coords[-1])) for line in lines]
max_dist = [max([Point(p).distance(l2) for p in l1.coords]) for l1, l2 in zip(lines, lines_out)]
if tolerance is not None:
check = [d <= tolerance for d in max_dist]
lines_out = [l for l, c in zip(lines_out, check) if c]
max_dist = [l for l, c in zip(max_dist, check) if c]
if not return_index:
return lines_out, max_dist
else:
index = [i for i, d in enumerate(max_dist) if d <= tolerance]
return lines_out, max_dist, index
# neighborhood methods
def nearest_neighbor_within(others, point, max_distance):
"""Find nearest point among others up to a maximum distance.
Args:
others: a list of Points or a MultiPoint
point: a Point
max_distance: maximum distance to search for the nearest neighbor
Returns:
A shapely Point if one is within max_distance, None otherwise
"""
search_region = point.buffer(max_distance)
interesting_points = search_region.intersection(MultiPoint(others))
if not interesting_points:
closest_point = None
elif isinstance(interesting_points, Point):
closest_point = interesting_points
else:
distances = [point.distance(ip) for ip in interesting_points
if point.distance(ip) > 0]
closest_point = interesting_points[distances.index(min(distances))]
return closest_point
def closest_object(geometries, point):
"""Find the nearest geometry among a list, measured from fixed point.
Args:
geometries: a list of shapely geometry objects
point: a shapely Point
Returns:
Tuple (geom, min_dist, min_index) of the geometry with minimum distance
to point, its distance min_dist and the list index of geom, so that
geom = geometries[min_index].
"""
min_dist, min_index = min((point.distance(geom), k)
for (k, geom) in enumerate(geometries))
return geometries[min_index], min_dist, min_index
# snapping methods
def snap_endings(lines, max_dist):
"""Snap endpoints of lines together if they are at most max_dist apart.
Args:
lines: a list of LineStrings or a MultiLineString
max_dist: maximum distance two endpoints may be joined together
"""
# initialize snapped lines with list of original lines
# snapping points is a MultiPoint object of all vertices
snapped_lines = [line for line in lines]
snapping_points = vertices_from_lines(snapped_lines)
# isolated endpoints are going to snap to the closest vertex
isolated_endpoints = find_isolated_endpoints(snapped_lines)
# only move isolated endpoints, one by one
for endpoint in isolated_endpoints:
# find all vertices within a radius of max_distance as possible
target = nearest_neighbor_within(snapping_points, endpoint,
max_dist)
# do nothing if no target point to snap to is found
if not target:
continue
# find the LineString to modify within snapped_lines and update it
for i, snapped_line in enumerate(snapped_lines):
if endpoint.touches(snapped_line):
snapped_lines[i] = bend_towards(snapped_line, where=endpoint,
to=target)
break
# also update the corresponding snapping_points
for i, snapping_point in enumerate(snapping_points):
if endpoint.equals(snapping_point):
snapping_points[i] = target
break
# post-processing: remove any resulting lines of length 0
snapped_lines = [s for s in snapped_lines if s.length > 0]
return snapped_lines
def snap_lines(lines, max_dist, tolerance=1e-7, return_index=False):
"""Snap lines together if the endpoint of one line is at most max_dist apart from the another line.
The line to which the endpoint is snapped will be split at the intersection
Args:
lines: a list of LineStrings or a MultiLineString
max_dist: maximum distance two endpoints may be joined together
"""
lines_out = []
split_points = []
for i1, line in enumerate(lines):
other = [x for i, x in enumerate(lines) if i1 != i]
start, end = Point(line.coords[0]), Point(line.coords[-1])
# find closest geometry to start point
nn_geom, dist, _ = closest_object(other, start)
# calculate intersection if within max_distance
if dist <= max_dist:
new_pnt = project_point_to_object(start, nn_geom, max_dist=max_dist)
# if intersection not at line end-points split line
if nn_geom.boundary.distance(new_pnt) > tolerance:
split_points.append(new_pnt)
# add node to vertex if not connected and within max distance
if (dist > 0) & (dist <= max_dist):
line = LineString([(new_pnt.x, new_pnt.y)] + list(line.coords)) # add node to start
# find closest geometry tp end point
nn_geom, dist, _ = closest_object(other, end)
# calculate intersection if within max_distance
if dist <= max_dist:
new_pnt = project_point_to_object(end, nn_geom, max_dist=max_dist)
# if intersection not at line end-points split line
if nn_geom.boundary.distance(new_pnt) > tolerance:
split_points.append(new_pnt)
# add node to vertex if not connected and within max distance
if (dist > 0) & (dist <= max_dist):
line = LineString(list(line.coords) + [(new_pnt.x, new_pnt.y)]) # add node to end
lines_out.append(line)
# post-process split lines if no node at intersection
if not return_index:
return remove_redundant_nodes(split_lines_points(lines_out, split_points))
else:
lines, index = split_lines_points(lines_out, split_points, return_index=return_index)
lines = remove_redundant_nodes(lines, tolerance)
return lines, index
def snap_points2geometries(points, geometries, max_dist, return_index=False):
""""""
out_list = []
index = []
# input list of point geometries
if isinstance(points[0], Point):
for i, p in enumerate(points):
line_snap = closest_object(geometries, p)[0] # find closest objects and snap to line
pnt_snap = project_point_to_object(p, line_snap, max_dist=max_dist)
if pnt_snap is not None:
out_list.append(pnt_snap)
index.append(i)
if not return_index:
return out_list
else:
return out_list, index
def project_point_to_line(point, line_start, line_end):
"""Find nearest point on a straight line, measured from given point.
Args:
point: a shapely Point object
line_start: the line starting point as a shapely Point
line_end: the line end point as a shapely Point
Returns:
a shapely Point that lies on the straight line closest to point
Source: http://gis.stackexchange.com/a/438/19627
"""
line_magnitude = line_start.distance(line_end)
u = ((point.x - line_start.x) * (line_end.x - line_start.x) +
(point.y - line_start.y) * (line_end.y - line_start.y)) \
/ (line_magnitude ** 2)
# closest point does not fall within the line segment,
# take the shorter distance to an endpoint
if u < 0.00001 or u > 1:
ix = point.distance(line_start)
iy = point.distance(line_end)
if ix > iy:
return line_end
else:
return line_start
else:
ix = line_start.x + u * (line_end.x - line_start.x)
iy = line_start.y + u * (line_end.y - line_start.y)
return Point([ix, iy])
def project_point_to_object(point, geometry, max_dist=float("inf")):
"""Find nearest point in geometry, measured from given point.
Args:
point: a shapely Point
geometry: a shapely geometry object (LineString, Polygon)
Returns:
a shapely Point that lies on geometry closest to point
"""
nearest_point = None
min_dist = float("inf")
if isinstance(geometry, Polygon):
for seg_start, seg_end in pairs(list(geometry.exterior.coords)):
line_start = Point(seg_start)
line_end = Point(seg_end)
intersection_point = project_point_to_line(point, line_start, line_end)
cur_dist = point.distance(intersection_point)
if (cur_dist < min_dist) & (cur_dist < max_dist):
min_dist = cur_dist
nearest_point = intersection_point
elif isinstance(geometry, LineString):
for seg_start, seg_end in pairs(list(geometry.coords)):
line_start = Point(seg_start)
line_end = Point(seg_end)
intersection_point = project_point_to_line(point, line_start, line_end)
cur_dist = point.distance(intersection_point)
if (cur_dist < min_dist) & (cur_dist < max_dist):
min_dist = cur_dist
nearest_point = intersection_point
else:
raise NotImplementedError("project_point_to_object not implemented for"+
" geometry type '" + geometry.type + "'.")
return nearest_point
def bend_towards(line, where, to):
"""Move the point where along a line to the point at location to.
Args:
line: a LineString
where: a point ON the line (not necessarily a vertex)
to: a point NOT on the line where the nearest vertex will be moved to
Returns:
the modified (bent) line
"""
if not line.contains(where) and not line.touches(where):
raise ValueError('line does not contain the point where.')
coords = line.coords[:]
# easy case: where is (within numeric precision) a vertex of line
for k, vertex in enumerate(coords):
if where.almost_equals(Point(vertex)):
# move coordinates of the vertex to destination
coords[k] = to.coords[0]
return LineString(coords)
# hard case: where lies between vertices of line, so
# find nearest vertex and move that one to point to
_, min_k = min((where.distance(Point(vertex)), k)
for k, vertex in enumerate(coords))
coords[min_k] = to.coords[0]
return LineString(coords)
# split geometries methods
def split_lines_point(lines, point, tolerance=1e-3, return_index=False):
"""Split line at a given point
Args:
lines: a list of shapely LineStrings or a MultiLineString
point: shapely Point
tolerance: required to check if segment intersects with line
Returns:
a list of LineStrings
"""
# find line which intersects with point, but not with start of end point
idx = [i for i, line in enumerate(lines) if
(line.distance(point) <= tolerance) & (line.boundary.distance(point) > tolerance)]
if len(idx) == 0:
raise Warning('line does not intersect with point with given tolerance.')
elif len(idx) > 1:
raise Warning('more than one line within given tolerance')
else:
idx = idx[0]
lines_out = [line for i, line in enumerate(lines) if i != idx]
index = [i for i, line in enumerate(lines) if i != idx] + [idx, idx]
# for intersecting line, find intersecting segment and split line
coords = list(lines[idx].coords)
segments = [LineString(s) for s in pairs(coords)]
n = len(segments)
for i, segment in enumerate(segments):
# find intersecting segment
if segment.distance(point) <= tolerance:
# split line at vertex if within tolerance
if Point(coords[i]).distance(point) <= tolerance:
lines_out.append(LineString(coords[:i+1]))
lines_out.append(LineString(coords[i:]))
break
# split line at point
else:
lines_out.append(LineString(coords[:i+1] + [(point.x, point.y)]))
lines_out.append(LineString([(point.x, point.y)] + coords[i+1:]))
break
if not return_index:
return lines_out
else:
return lines_out, index
def add_node(lines, point, tolerance=1e-3):
"""Split line at a given point
Args:
lines: a list of shapely LineStrings or a MultiLineString
point: shapely Point
tolerance: required to check if segment intersects with line
Returns:
a list of LineStrings
"""
# find line which intersects with point, but not with start of end point
idx = [i for i, line in enumerate(lines) if
(line.distance(point) <= tolerance) & (line.boundary.distance(point) > tolerance)]
if len(idx) == 0:
raise Warning('line does not intersect with point with given tolerance.')
elif len(idx) > 1:
raise Warning('more than one line within given tolerance')
else:
idx = idx[0]
# for intersecting line, find intersecting segment and split line
coords = list(lines[idx].coords)
segments = [LineString(s) for s in pairs(coords)]
n = len(segments)
for i, segment in enumerate(segments):
# find intersecting segment
if segment.distance(point) <= tolerance:
# break if at point at existing node (do nothing)
if Point(coords[i]).distance(point) <= tolerance:
break
# otherwise et node
else:
lines[idx] = LineString(coords[:i+1] + [(point.x, point.y)] + coords[i+1:])
break
return lines
def add_nodes(lines, point_list, tolerance=1e-3):
"""split lines at list of points, see split_lines_point for more information"""
if isinstance(point_list, Point):
point_list = [point_list]
for point in point_list:
lines = add_node(lines, point, tolerance)
return lines
def split_lines_points(lines, point_list, tolerance=1e-3, return_index=False):
"""split lines at list of points, see split_lines_point for more information"""
if isinstance(point_list, Point):
point_list = [point_list]
index = range(len(lines))
if not return_index:
for point in point_list:
lines = split_lines_point(lines, point, tolerance)
return lines
else:
for point in point_list:
lines, idx0 = split_lines_point(lines, point, tolerance, return_index)
index = [index[i] for i in idx0]
return lines, index
def split_lines_angle(lines, split_angle=90, return_index=False):
"""Split line at vertex if angle smaller than 'split_angle'
Args:
lines: a list of shapely LineStrings or a MultiLineString
split_angle: max angle between two segments
Returns:
a list of LineStrings
"""
lines_out = []
index = []
# loop through lines
for ind, line in enumerate(lines):
# check if line has only single segment
if len(list(line.coords)) == 2:
lines_out.append(line)
index.append(ind)
else:
angles, points = segment_angles(line)
idx = np.where(np.array(angles) <= split_angle)[0]
line = [line]
if len(idx) >= 1:
for i in idx:
line = split_lines_point(line, Point(points[i]))
lines_out += line
for l in line:
index.append(ind)
if not return_index:
return lines_out
else:
return lines_out, index
def cut_line(line, distance):
"""Cuts a line in two at a distance from its starting point"""
coords = list(line.coords)
for i, p in enumerate(coords):
pd = line.project(Point(p))
if pd == distance:
return LineString(coords[:i+1]), LineString(coords[i:])
elif pd > distance:
cp = line.interpolate(distance)
return LineString(coords[:i] + [(cp.x, cp.y)]), LineString([(cp.x, cp.y)] + coords[i:])
elif line.length < distance:
return line, LineString() # return empty LineString so that output is always consistent
def explode_lines(lines, length, min_length, equal_length=False, remove_too_small=False, return_index=False):
"""explodes a LineString in to many Linestring with given length.
If final part of line is smaller than min_length it is merged with previous
Args:
lines: a list of shapely LineStrings or a MultiLineString
length: length of new lines
min_length: minimal length of last part of a line
Returns:
a list of LineStrings
"""
lines_out = []
index = []
if equal_length:
for line in lines:
n = max(1.0, round(line.length/float(length)))
length2 = line.length/n
else:
length2 = length
for i, line in enumerate(lines):
# lines shorter than length
if line.length <= length2:
# shorter than min_length
if remove_too_small and (line.length < min_length):
continue
# between min_length and length or remove_too_small == False
else:
lines_out.append(line)
index.append(i)
# lines longer than length
else:
l = line
while (min_length+length) <= l.length:
l1, l = cut_line(l, length2)
lines_out.append(l1)
index.append(i)
# if l.length/2. >= min_length:
# l1, l = cut_line(l, l.length/2.)
# lines_out.append(l1)
# index.append(i)
lines_out.append(l)
index.append(i)
if not return_index:
return lines_out
else:
return lines_out, index
def explode_polygons(polygons, return_index=False):
"""returns main line features that make up the polygons"""
lines_out = []
index = []
if isinstance(polygons, Polygon):
polygons = [polygons]
for i, l in enumerate(polygons):
# get inner lines
for p in l.interiors:
lines_out.append(LineString(p.coords))
index.append(i)
# get outer lines
lines_out.append(LineString(l.exterior.coords))
index.append(i)
if not return_index:
return lines_out
else:
return lines_out, index
# clip geometries methods
def clip_lines_with_polygon(lines, polygon, tolerance=1e-3, within=True, return_index=False):
"""clip lines based on polygon outline"""
# Multipolygon to list of polygons
# if isinstance(polygon, MultiPolygon):
# raise ValueError("function works with tyype polygon only")
# get boundaries of polygon
boundaries = explode_polygons(polygon)
# find intersection points of boundaries and lines and split lines based on it
intersection_points = line_intersections(boundaries, lines)
lines_split, index = split_lines_points(lines, intersection_points, tolerance=tolerance, return_index=True)
# select lines that are contained by polygon
polygon_buffer = polygon.buffer(0.05) # small buffer to allow for use 'within' function
if within:
lines_clip = [line for line in lines_split if line.within(polygon_buffer)]
index = [i for i, line in zip(index, lines_split) if line.within(polygon_buffer)]
else:
lines_clip = [line for line in lines_split if not line.within(polygon_buffer)]
index = [i for i, line in zip(index, lines_split) if not line.within(polygon_buffer)]
if not return_index:
return lines_clip
else:
return lines_clip, index
def offset_and_clip(lines, offset_dist=30, buffer_dist=29.9, side='both', join_style=2):
"""offset lines, but clip where these lines are within buffer distance of other lines"""
# calc buffer around lines
cbuffer = polygon_union([c.buffer(buffer_dist, join_style=join_style) for c in lines])
if side == 'both':
sides = ['left', 'right']
else:
sides = [side]
lines_out = []
for s in sides:
# offset canal lines
offset_lines = [c.parallel_offset(offset_dist, s, join_style=join_style) for c in lines]
#clip lines outside canal buffer
lines_out.append(clip_lines_with_polygon(offset_lines, cbuffer, within=False))
if side == 'both':
return lines_out[0], lines_out[1]
else:
return lines_out[0]
# utils
def perpendicular_line(l1, length):
"""Create a new Line perpendicular to this linear entity which passes
through the point `p`.
"""
dx = l1.coords[1][0] - l1.coords[0][0]
dy = l1.coords[1][1] - l1.coords[0][1]
p = Point(l1.coords[0][0] + 0.5*dx, l1.coords[0][1] + 0.5*dy)
x, y = p.coords[0][0], p.coords[0][1]
if (dy == 0) or (dx == 0):
a = length / l1.length
l2 = LineString([(x - 0.5*a*dy, y - 0.5*a*dx),
(x + 0.5*a*dy, y + 0.5*a*dx)])
else:
s = -dx/dy
a = ((length * 0.5)**2 / (1 + s**2))**0.5
l2 = LineString([(x + a, y + s*a),
(x - a, y - s*a)])
return l2
def pairs(lst):
"""Iterate over a list in overlapping pairs.
Args:
lst: an iterable/list
Returns:
Yields a pair of consecutive elements (lst[k], lst[k+1]) of lst. Last
call yields (lst[-2], lst[-1]).
Example:
lst = [4, 7, 11, 2]
pairs(lst) yields (4, 7), (7, 11), (11, 2)
Source:
http://stackoverflow.com/questions/1257413/1257446#1257446
"""
i = iter(lst)
prev = next(i)
for item in i:
yield prev, item
prev = item
def neighbors(lines, of):
"""Find the indices in a list of LineStrings that touch a given LineString.
Args:
lines: list of LineStrings in which to search for neighbors
of: the LineString which must be touched
Returns:
list of indices, so that all lines[indices] touch the LineString of
"""
return [k for k, line in enumerate(lines) if line.touches(of)]
def endpoints_from_lines(lines):
"""Return list of terminal points from list of LineStrings."""
all_points = []
for line in lines:
for i in [0, -1]: # start and end point
all_points.append(line.coords[i])
unique_points = set(all_points)
return [Point(p) for p in unique_points]
def vertices_from_lines(lines):
"""Return list of unique vertices from list of LineStrings."""
vertices = []
for line in lines:
vertices.extend(list(line.coords))
return [Point(p) for p in set(vertices)]
def find_isolated_endpoints(lines):
"""Find endpoints of lines that don't touch another line.
Args:
lines: a list of LineStrings or a MultiLineString
Returns:
A list of line end Points that don't touch any other line of lines
"""
isolated_endpoints = []
for i, line in enumerate(lines):
other_lines = lines[:i] + lines[i+1:]
for q in [0, -1]:
endpoint = Point(line.coords[q])
if any(endpoint.touches(another_line)
for another_line in other_lines):
continue
else:
isolated_endpoints.append(endpoint)
return isolated_endpoints
def line_intersections(lines1, lines2=None):
""" creates list with points of line intersections
:param lines1: MultiLineString or list of lines
:param lines2: MultiLineString or list of lines, if None find intersections amongst lines1
:return: list with shapely points of intersection
"""
points = []
for i1, l1 in enumerate(lines1):
if lines2 is None:
lines3 = [x for i, x in enumerate(lines1) if i != i1]
else:
lines3 = lines2
for l3 in lines3:
pnt = l1.intersection(l3)
if not pnt.is_empty:
if isinstance(pnt, MultiPoint):
for g in pnt.geoms:
points.append(Point(g))
else:
points.append(pnt)
return points
def segment_angles(line):
"""calculate angles between all segments of a line
:param line: a shapely LineStrings
:return: a list angles and points
"""
# make pairs of segment coordinates
segmentpairs = list(pairs([s for s in pairs(line.coords)]))
# find coordinates of vertices between two segments
points = [np.array(cs[0][1]) for cs in segmentpairs]
# calculate vectors by transformation of middle point to (0,0) coordinates
vectors = [(np.array(cs[0][0])-p0, np.array(cs[1][1])-p0)
for cs, p0 in zip(segmentpairs, points)]
# calculate angle between vectors
angles = [angle(v[0], v[1]) for v in vectors]
return angles, points
def remove_redundant_nodes(lines, tolerance=1e-7):
"""remove vertices with length smaller than tolerance"""
lines_out = []
for line in lines:
coords = line.coords
l_segments = np.array([Point(s[0]).distance(Point(s[1])) for s in pairs(coords)])
idx = np.where(l_segments < tolerance)[0]
lines_out.append(LineString([c for i, c in enumerate(coords) if i not in idx]))
return lines_out
def angle(v1, v2):
"""return angle between vector v1 and vector v2"""
return math.atan2(np.abs(np.cross(v1, v2)), np.dot(v1, v2))/math.pi*180
def index_spatial_join(geometries, geometries_sample, function='within'):
"""find index to map attributes from geometries_sample to geometries based on geospatial relation
:param geometries: geometries to be updated
:param geometries_sample: feature list property values from
:param function: string with name of shapely binary predicates to define spatial relation,
options are: 'within', 'contains', 'crosses', 'disjoint', 'equals', 'intersects', 'touches'
see: http://toblerity.org/shapely/manual.html#binary-predicates
:return: updated feature list
"""
index = []
func_list = ['within', 'contains', 'crosses', 'disjoint', 'equals', 'intersects', 'touches']
if isinstance(geometries, (Point, LineString, Polygon)):
geometries = [geometries]
if function in func_list:
# set function to define spatial relation
spatial_relate = eval('lambda x, y: x.'+function+'(y)')
for geom in geometries:
# find feature in sample list that matches spatial relation
index.append(np.where([spatial_relate(geom, geom_sample) for geom_sample in geometries_sample])[0].tolist())
elif function is 'NN':
for geom in geometries:
# TODO: check if this also works for other than point objects
# TODO: build in max distance check
index.append(closest_object(geometries_sample, geom)[2]) # find nearest object from list
else:
raise ValueError("unknown spatial relation function, choose from: {:s}".format(', '.join(func_list)))
return index