File: //lib/python3/dist-packages/networkx/algorithms/operators/tests/test_product.py
import pytest
import networkx as nx
from networkx.utils import edges_equal
def test_tensor_product_raises():
with pytest.raises(nx.NetworkXError):
P = nx.tensor_product(nx.DiGraph(), nx.Graph())
def test_tensor_product_null():
null = nx.null_graph()
empty10 = nx.empty_graph(10)
K3 = nx.complete_graph(3)
K10 = nx.complete_graph(10)
P3 = nx.path_graph(3)
P10 = nx.path_graph(10)
# null graph
G = nx.tensor_product(null, null)
assert nx.is_isomorphic(G, null)
# null_graph X anything = null_graph and v.v.
G = nx.tensor_product(null, empty10)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(null, K3)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(null, K10)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(null, P3)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(null, P10)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(empty10, null)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(K3, null)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(K10, null)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(P3, null)
assert nx.is_isomorphic(G, null)
G = nx.tensor_product(P10, null)
assert nx.is_isomorphic(G, null)
def test_tensor_product_size():
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
K5 = nx.complete_graph(5)
G = nx.tensor_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.tensor_product(K3, K5)
assert nx.number_of_nodes(G) == 3 * 5
def test_tensor_product_combinations():
# basic smoke test, more realistic tests would be useful
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
G = nx.tensor_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.tensor_product(P5, nx.MultiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
G = nx.tensor_product(nx.MultiGraph(P5), K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.tensor_product(nx.MultiGraph(P5), nx.MultiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
G = nx.tensor_product(nx.DiGraph(P5), nx.DiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
def test_tensor_product_classic_result():
K2 = nx.complete_graph(2)
G = nx.petersen_graph()
G = nx.tensor_product(G, K2)
assert nx.is_isomorphic(G, nx.desargues_graph())
G = nx.cycle_graph(5)
G = nx.tensor_product(G, K2)
assert nx.is_isomorphic(G, nx.cycle_graph(10))
G = nx.tetrahedral_graph()
G = nx.tensor_product(G, K2)
assert nx.is_isomorphic(G, nx.cubical_graph())
def test_tensor_product_random():
G = nx.erdos_renyi_graph(10, 2 / 10.0)
H = nx.erdos_renyi_graph(10, 2 / 10.0)
GH = nx.tensor_product(G, H)
for (u_G, u_H) in GH.nodes():
for (v_G, v_H) in GH.nodes():
if H.has_edge(u_H, v_H) and G.has_edge(u_G, v_G):
assert GH.has_edge((u_G, u_H), (v_G, v_H))
else:
assert not GH.has_edge((u_G, u_H), (v_G, v_H))
def test_cartesian_product_multigraph():
G = nx.MultiGraph()
G.add_edge(1, 2, key=0)
G.add_edge(1, 2, key=1)
H = nx.MultiGraph()
H.add_edge(3, 4, key=0)
H.add_edge(3, 4, key=1)
GH = nx.cartesian_product(G, H)
assert set(GH) == {(1, 3), (2, 3), (2, 4), (1, 4)}
assert {(frozenset([u, v]), k) for u, v, k in GH.edges(keys=True)} == {
(frozenset([u, v]), k)
for u, v, k in [
((1, 3), (2, 3), 0),
((1, 3), (2, 3), 1),
((1, 3), (1, 4), 0),
((1, 3), (1, 4), 1),
((2, 3), (2, 4), 0),
((2, 3), (2, 4), 1),
((2, 4), (1, 4), 0),
((2, 4), (1, 4), 1),
]
}
def test_cartesian_product_raises():
with pytest.raises(nx.NetworkXError):
P = nx.cartesian_product(nx.DiGraph(), nx.Graph())
def test_cartesian_product_null():
null = nx.null_graph()
empty10 = nx.empty_graph(10)
K3 = nx.complete_graph(3)
K10 = nx.complete_graph(10)
P3 = nx.path_graph(3)
P10 = nx.path_graph(10)
# null graph
G = nx.cartesian_product(null, null)
assert nx.is_isomorphic(G, null)
# null_graph X anything = null_graph and v.v.
G = nx.cartesian_product(null, empty10)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(null, K3)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(null, K10)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(null, P3)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(null, P10)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(empty10, null)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(K3, null)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(K10, null)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(P3, null)
assert nx.is_isomorphic(G, null)
G = nx.cartesian_product(P10, null)
assert nx.is_isomorphic(G, null)
def test_cartesian_product_size():
# order(GXH)=order(G)*order(H)
K5 = nx.complete_graph(5)
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
G = nx.cartesian_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
assert nx.number_of_edges(G) == nx.number_of_edges(P5) * nx.number_of_nodes(
K3
) + nx.number_of_edges(K3) * nx.number_of_nodes(P5)
G = nx.cartesian_product(K3, K5)
assert nx.number_of_nodes(G) == 3 * 5
assert nx.number_of_edges(G) == nx.number_of_edges(K5) * nx.number_of_nodes(
K3
) + nx.number_of_edges(K3) * nx.number_of_nodes(K5)
def test_cartesian_product_classic():
# test some classic product graphs
P2 = nx.path_graph(2)
P3 = nx.path_graph(3)
# cube = 2-path X 2-path
G = nx.cartesian_product(P2, P2)
G = nx.cartesian_product(P2, G)
assert nx.is_isomorphic(G, nx.cubical_graph())
# 3x3 grid
G = nx.cartesian_product(P3, P3)
assert nx.is_isomorphic(G, nx.grid_2d_graph(3, 3))
def test_cartesian_product_random():
G = nx.erdos_renyi_graph(10, 2 / 10.0)
H = nx.erdos_renyi_graph(10, 2 / 10.0)
GH = nx.cartesian_product(G, H)
for (u_G, u_H) in GH.nodes():
for (v_G, v_H) in GH.nodes():
if (u_G == v_G and H.has_edge(u_H, v_H)) or (
u_H == v_H and G.has_edge(u_G, v_G)
):
assert GH.has_edge((u_G, u_H), (v_G, v_H))
else:
assert not GH.has_edge((u_G, u_H), (v_G, v_H))
def test_lexicographic_product_raises():
with pytest.raises(nx.NetworkXError):
P = nx.lexicographic_product(nx.DiGraph(), nx.Graph())
def test_lexicographic_product_null():
null = nx.null_graph()
empty10 = nx.empty_graph(10)
K3 = nx.complete_graph(3)
K10 = nx.complete_graph(10)
P3 = nx.path_graph(3)
P10 = nx.path_graph(10)
# null graph
G = nx.lexicographic_product(null, null)
assert nx.is_isomorphic(G, null)
# null_graph X anything = null_graph and v.v.
G = nx.lexicographic_product(null, empty10)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(null, K3)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(null, K10)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(null, P3)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(null, P10)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(empty10, null)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(K3, null)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(K10, null)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(P3, null)
assert nx.is_isomorphic(G, null)
G = nx.lexicographic_product(P10, null)
assert nx.is_isomorphic(G, null)
def test_lexicographic_product_size():
K5 = nx.complete_graph(5)
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
G = nx.lexicographic_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.lexicographic_product(K3, K5)
assert nx.number_of_nodes(G) == 3 * 5
def test_lexicographic_product_combinations():
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
G = nx.lexicographic_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.lexicographic_product(nx.MultiGraph(P5), K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.lexicographic_product(P5, nx.MultiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
G = nx.lexicographic_product(nx.MultiGraph(P5), nx.MultiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
# No classic easily found classic results for lexicographic product
def test_lexicographic_product_random():
G = nx.erdos_renyi_graph(10, 2 / 10.0)
H = nx.erdos_renyi_graph(10, 2 / 10.0)
GH = nx.lexicographic_product(G, H)
for (u_G, u_H) in GH.nodes():
for (v_G, v_H) in GH.nodes():
if G.has_edge(u_G, v_G) or (u_G == v_G and H.has_edge(u_H, v_H)):
assert GH.has_edge((u_G, u_H), (v_G, v_H))
else:
assert not GH.has_edge((u_G, u_H), (v_G, v_H))
def test_strong_product_raises():
with pytest.raises(nx.NetworkXError):
P = nx.strong_product(nx.DiGraph(), nx.Graph())
def test_strong_product_null():
null = nx.null_graph()
empty10 = nx.empty_graph(10)
K3 = nx.complete_graph(3)
K10 = nx.complete_graph(10)
P3 = nx.path_graph(3)
P10 = nx.path_graph(10)
# null graph
G = nx.strong_product(null, null)
assert nx.is_isomorphic(G, null)
# null_graph X anything = null_graph and v.v.
G = nx.strong_product(null, empty10)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(null, K3)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(null, K10)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(null, P3)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(null, P10)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(empty10, null)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(K3, null)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(K10, null)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(P3, null)
assert nx.is_isomorphic(G, null)
G = nx.strong_product(P10, null)
assert nx.is_isomorphic(G, null)
def test_strong_product_size():
K5 = nx.complete_graph(5)
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
G = nx.strong_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.strong_product(K3, K5)
assert nx.number_of_nodes(G) == 3 * 5
def test_strong_product_combinations():
P5 = nx.path_graph(5)
K3 = nx.complete_graph(3)
G = nx.strong_product(P5, K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.strong_product(nx.MultiGraph(P5), K3)
assert nx.number_of_nodes(G) == 5 * 3
G = nx.strong_product(P5, nx.MultiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
G = nx.strong_product(nx.MultiGraph(P5), nx.MultiGraph(K3))
assert nx.number_of_nodes(G) == 5 * 3
# No classic easily found classic results for strong product
def test_strong_product_random():
G = nx.erdos_renyi_graph(10, 2 / 10.0)
H = nx.erdos_renyi_graph(10, 2 / 10.0)
GH = nx.strong_product(G, H)
for (u_G, u_H) in GH.nodes():
for (v_G, v_H) in GH.nodes():
if (
(u_G == v_G and H.has_edge(u_H, v_H))
or (u_H == v_H and G.has_edge(u_G, v_G))
or (G.has_edge(u_G, v_G) and H.has_edge(u_H, v_H))
):
assert GH.has_edge((u_G, u_H), (v_G, v_H))
else:
assert not GH.has_edge((u_G, u_H), (v_G, v_H))
def test_graph_power_raises():
with pytest.raises(nx.NetworkXNotImplemented):
nx.power(nx.MultiDiGraph(), 2)
def test_graph_power():
# wikipedia example for graph power
G = nx.cycle_graph(7)
G.add_edge(6, 7)
G.add_edge(7, 8)
G.add_edge(8, 9)
G.add_edge(9, 2)
H = nx.power(G, 2)
assert edges_equal(
list(H.edges()),
[
(0, 1),
(0, 2),
(0, 5),
(0, 6),
(0, 7),
(1, 9),
(1, 2),
(1, 3),
(1, 6),
(2, 3),
(2, 4),
(2, 8),
(2, 9),
(3, 4),
(3, 5),
(3, 9),
(4, 5),
(4, 6),
(5, 6),
(5, 7),
(6, 7),
(6, 8),
(7, 8),
(7, 9),
(8, 9),
],
)
def test_graph_power_negative():
with pytest.raises(ValueError):
nx.power(nx.Graph(), -1)
def test_rooted_product_raises():
with pytest.raises(nx.NetworkXError):
nx.rooted_product(nx.Graph(), nx.path_graph(2), 10)
def test_rooted_product():
G = nx.cycle_graph(5)
H = nx.Graph()
H.add_edges_from([("a", "b"), ("b", "c"), ("b", "d")])
R = nx.rooted_product(G, H, "a")
assert len(R) == len(G) * len(H)
assert R.size() == G.size() + len(G) * H.size()