def test_contains(self):
for rdggs in [WGS84_003, WGS84_003_RADIANS]:
# A cell should contain its nucleus, but not my test point p.
# Assume that nucleus() and vertices() work.
for suid in [[N, 3, 1], [P, 5, 7, 5, 1, 3], [S, 0]]:
c = Cell(rdggs, suid)
w = c.width()
for plane in [True, False]:
nucleus = c.nucleus(plane=plane)
vertices = c.vertices(plane=plane)
p = (max([v[0] for v in vertices]) + 1, vertices[3][1])
self.assertTrue(c.contains(nucleus, plane=plane))
self.assertFalse(c.contains(p, plane=plane))
def test_contains(self):
for rdggs in [WGS84_003, WGS84_003_RADIANS]:
# A cell should contain its nucleus, but not my test point p.
# Assume that nucleus() and vertices() work.
for suid in [[N, 3, 1], [P, 5, 7, 5, 1, 3], [S, 0]]:
c = Cell(rdggs, suid)
w = c.width()
for plane in [True, False]:
nucleus = c.nucleus(plane=plane)
vertices = c.vertices(plane=plane)
p = (max([v[0] for v in vertices]) + 1, vertices[3][1])
self.assertTrue(c.contains(nucleus, plane=plane))
self.assertFalse(c.contains(p, plane=plane))
def test_random_point(self):
# Output should lie in the cell at least.
for E in [WGS84_ASPHERE_RADIANS, WGS84_ELLIPSOID]:
rdggs = RHEALPixDGGS(E)
for plane in [True, False]:
c = Cell(rdggs, [N, 8, 7])
p = c.random_point(plane=plane)
self.assertTrue(c.contains(p, plane=plane)) #------------------------------------------------------------------------------
def test_random_point(self):
# Output should lie in the cell at least.
for E in [WGS84_ASPHERE_RADIANS, WGS84_ELLIPSOID]:
rdggs = RHEALPixDGGS(E)
for plane in [True, False]:
c = Cell(rdggs, [N, 8, 7])
p = c.random_point(plane=plane)
self.assertTrue(
c.contains(p, plane=plane)
) #------------------------------------------------------------------------------