def test_split_uniform_empty(self): """Test splitUniform on empty fiber""" empty = Fiber() split = empty.splitUniform(5) # After we split, we need to make sure that we have actually added # another level to the empty fiber self.assertIsInstance(split.getDefault(), Fiber)
def test_split_uniform_below(self): """Test splitUniformBelow""" c0 = [0, 1, 9, 10, 12, 31, 41] p0 = [ 0, 10, 20, 100, 120, 310, 410 ] f0 = Fiber(c0, p0) c1 = [1, 2, 10, 11, 13, 32, 42] p1 = [ 1, 11, 21, 101, 121, 311, 411 ] f1 = Fiber(c1, p1) c = [2, 4] f = Fiber(c, [f0, f1]) f.splitUniformBelow(10, depth=0) f0_split = f0.splitUniform(10) f1_split = f1.splitUniform(10) f_ref = Fiber(c, [f0_split, f1_split]) self.assertEqual(f, f_ref)
def test_split_uniform_then_flatten(self): """Test that flattenRanks() can undo splitUniform""" # # Create the fiber to be split # c = [0, 1, 9, 10, 12, 31, 41] p = [0, 10, 20, 100, 120, 310, 410] f = Fiber(c, p) # # Do the split # coords = 10 split = f.splitUniform(coords) # # Check that flattening after splitting gives us the same answer # self.assertEqual(split.flattenRanks(style="absolute"), f)
def test_split_uniform_relative_then_flatten(self): """Test that flattenRanks can undo splitUniform (relative)""" # # Create the fiber to be split # c = [0, 1, 9, 10, 12, 31, 41] p = [0, 10, 20, 100, 120, 310, 410] f = Fiber(c, p) # # Do the split # coords = 10 split = f.splitUniform(coords, relativeCoords=True) # # Check the split # self.assertEqual(split.flattenRanks(style="relative"), f)
def test_split_uniform_relative(self): """Test splitUniform""" # # Create the fiber to be split # c = [0, 1, 9, 10, 12, 31, 41] p = [0, 10, 20, 100, 120, 310, 410] f = Fiber(c, p) # # Create list of reference fibers after the split # split_ref_coords = [0, 10, 30, 40] css = [[0, 1, 9], [0, 2], [1], [1]] pss = [[0, 10, 20], [100, 120], [310], [410]] split_ref_payloads = [] for (cs, ps) in zip(css, pss): split_ref_payloads.append(Fiber(cs, ps)) # # Do the split # coords = 10 split = f.splitUniform(coords, relativeCoords=True) # # Check the split # for i, (sc, sp) in enumerate(split): self.assertEqual(sc, split_ref_coords[i]) self.assertEqual(sp, split_ref_payloads[i])
from fibertree import Fiber f = Fiber([0, 1, 2, 10, 12, 31, 41], [0, 10, 20, 100, 120, 310, 410]) print("Original fiber\n") f.print() # # Unform coordiate-based split # coords = 10 print("Uniform coordinate split (groups of %s coordinates)\n" % coords) fibers = f.splitUniform(coords) for c, s in fibers: s.print() # # Non-unform coordiate-based split # splits = [0, 12, 31] print(f"NonUniform coordinate split (splits at {splits})\n") fibers = f.splitNonUniform(splits) for c, s in fibers: s.print() # # Equal position-based split