def road_ends_in_intersection_city(self):
"""
When using smooth geometries, the original intersection point (0,0) does
not exist anymore as a place for the roads to intersect (it should be
replaced by an arc or similar). Since s2 dies on (0,0) the road geometry
has to be extended to touch the new s1 geometry.
__--- (50,30)
(-50,0) ------- + ---
|
|
(0,-50)
"""
city = City("Road ends in intersection")
s1 = Street.from_control_points([Point(-50, 0), Point(0, 0), Point(50, 30)])
s1.name = "s1"
s2 = Street.from_control_points([Point(0, -50), Point(0, 0)])
s2.name = "s2"
city.add_intersection_at(Point(0, 0))
city.add_road(s1)
city.add_road(s2)
return city
def Y_intersection_one_to_many_city(self):
"""
(0,100)
|
|
+
/ \
/ \
(-100,-100) (100,-100)
"""
city = City("Y intersection - One to many")
s1 = Street.from_control_points([Point(0, 100), Point(0, 0)])
s1.name = "s1"
s2 = Street.from_control_points([Point(0, 0), Point(-100, -100)])
s2.name = "s2"
s3 = Street.from_control_points([Point(0, 0), Point(100, -100)])
s3.name = "s3"
city.add_intersection_at(Point(0, 0))
city.add_road(s1)
city.add_road(s2)
city.add_road(s3)
return city
def trunk_from_street_city(self):
"""
---<---
+---<---
--->--+
"""
city = City("Trunk from street")
trunk = Trunk.from_control_points([
Point(0, 0),
Point(50, 0)
])
trunk.name = "t1"
street = Street.from_control_points([
Point(100, 0),
Point(50, 0)
])
street.name = "s1"
city.add_road(trunk)
city.add_road(street)
city.add_intersection_at(Point(50, 0))
return city
def simple_street_city(self):
city = City("Single street")
street = Street.from_control_points([
Point(0, 0),
Point(100, 0),
Point(200, 0)
])
street.name = "s1"
city.add_road(street)
return city
def two_non_collinear_segments_less_than_border_city(self):
"""
(-10,0) -- (0,0) -- (10,2) -- (20,4)
"""
city = City("Non collinear segments - Less than border")
s1 = Street.from_control_points([Point(-10, 0), Point(0, 0), Point(4, 2), Point(20, 7)])
s1.name = "s1"
city.add_road(s1)
return city
def non_collinear_segments_city(self):
"""
(-100,0) -- (0,0) -- (100,30)
"""
city = City("Non collinear segments - Standard")
s1 = Street.from_control_points([Point(-100, 0), Point(0, 0), Point(100, 30)])
s1.name = "s1"
city.add_road(s1)
return city
def test_trim_redundant_nodes_on_multiple_collinear_segments_with_one_intersection(
self):
"""Two collinear segments, where the midpoint is an intersection.
The middle point should not be removed, as that would remove the intersection"""
city = City()
city.add_intersection_at(Point(100, 0))
city.add_road(
Road.from_control_points([Point(100, 100),
Point(100, 0)]))
points = [
Point(0, 0),
Point(10, 0),
Point(20, 0),
Point(50, 0),
Point(100, 0),
Point(110, 0),
Point(150, 0),
Point(200, 0)
]
road = Road.from_control_points(points)
city.add_road(road)
before_trim_expected_nodes = [
RoadSimpleNode(Point(0, 0)),
RoadSimpleNode(Point(10, 0)),
RoadSimpleNode(Point(20, 0)),
RoadSimpleNode(Point(50, 0)),
RoadIntersectionNode(Point(100, 0)),
RoadSimpleNode(Point(110, 0)),
RoadSimpleNode(Point(150, 0)),
RoadSimpleNode(Point(200, 0))
]
self.assertEqual(road.nodes(), before_trim_expected_nodes)
road.trim_redundant_nodes()
after_trim_expected_nodes = [
RoadSimpleNode(Point(0, 0)),
RoadIntersectionNode(Point(100, 0)),
RoadSimpleNode(Point(200, 0))
]
self.assertEqual(road.nodes(), after_trim_expected_nodes)
def L_intersection_city(self):
"""
(0,100)
|
+ -- (100,0)
"""
city = City("L intersection")
s1 = Street.from_control_points([Point(0, 100), Point(0, 0)])
s1.name = "s1"
s2 = Street.from_control_points([Point(0, 0), Point(100, 0)])
s2.name = "s2"
city.add_intersection_at(Point(0, 0))
city.add_road(s1)
city.add_road(s2)
return city
def S_road_city(self):
"""
(50,12) *------- (100, 12)
|
|
(0, 0) ---* (50,0)
"""
city = City("S road")
s1 = Street.from_control_points([
Point(0, 0),
Point(50, 0),
Point(50, 15),
Point(100, 15)
])
s1.name = "s1"
city.add_road(s1)
return city
def T_intersection_out_city(self):
"""
(-100,0) -- + -- (100,0)
|
(0,-100)
"""
city = City("T intersection out")
s1 = Street.from_control_points([Point(-100, 0), Point(0, 0), Point(100, 0)])
s1.name = "s1"
s2 = Street.from_control_points([Point(0, 0), Point(0, -100)])
s2.name = "s2"
city.add_intersection_at(Point(0, 0))
city.add_road(s1)
city.add_road(s2)
return city
def collinear_streets_city(self):
"""
--->---+--->---
"""
city = City("Collinear streets")
s1 = Street.from_control_points([
Point(0, 0),
Point(50, 0)
])
s1.name = "s1"
s2 = Street.from_control_points([
Point(50, 0),
Point(100, 0)
])
s2.name = "s2"
city.add_road(s1)
city.add_road(s2)
city.add_intersection_at(Point(50, 0))
return city
def broken_intersection_on_two_lanes_city(self):
"""
(10,50)
|
| __--- (50,20)
(-50,0) ------- + ---
|
|
(0,-50)
"""
city = City("Broken intersection - Two lanes")
s1 = Street.from_control_points([Point(-50, 0), Point(0, 0), Point(50, 20)])
s1.name = "s1"
s2 = Street.from_control_points([Point(0, -50), Point(0, 0), Point(10, 50)])
s2.name = "s2"
city.add_intersection_at(Point(0, 0))
city.add_road(s1)
city.add_road(s2)
return city
def test_sample_city(self):
city = City()
city.add_road(
Street.from_control_points(
[Point(-100, 0), Point(0, 0),
Point(100, 0)]))
city.add_road(
Street.from_control_points(
[Point(0, 100), Point(0, 0),
Point(0, -100)]))
city.add_intersection_at(Point(0, 0))
city.add_road(
Street.from_control_points([
Point(-10, 200),
Point(0, 200),
Point(10, 220),
Point(20, 270)
]))
stats = CityStatistics(city)
values = stats.run()
self.assertEquals(values['roads_count'], 3)
self.assertEquals(values['lanes_count'], 3)
self.assertEquals(values['buildings_count'], 0)
self.assertEquals(values['blocks_count'], 0)
self.assertEquals(values['polyline_waypoints_count'], 12)
self.assertEquals(values['polyline_intersections_count'], 4)
self.assertEquals(values['average_polyline_intersections'], 4.0 / 3.0)
self.assertEquals(values['average_polyline_waypoints'], 12.0 / 3.0)
self.assertEquals(values['lines_and_arcs_waypoints_count'], 14)
self.assertEquals(values['lines_and_arcs_intersections_count'], 4)
self.assertEquals(values['average_lines_and_arcs_intersections'],
4.0 / 3.0)
self.assertEquals(values['average_lines_and_arcs_waypoints'],
14.0 / 3.0)
