def test_primitive_conversion():
for _ in supported_backends():
assert pg.obj2id("str") == str(hash("str"))
assert pg.sum(pg.to_array([1, 2, 3])) == 6
assert pg.sum(pg.dot(pg.exp(pg.log(pg.to_array([4, 5]))), pg.to_array([2, 2]))) == 18
primitive = pg.to_array([1, 2, 3])
assert id(primitive) == id(pg.to_array(primitive, copy_array=False))
assert id(primitive) != id(pg.to_array(primitive, copy_array=True))
def test_sequential():
graph = next(pg.load_datasets_graph(["graph5"]))
for _ in supported_backends():
prior = pg.to_signal(graph, {"A": 2})
posterior1 = pg.Normalize(pg.PageRank(), "range").rank(prior)
posterior2 = pg.Normalize("range")(pg.PageRank()(prior))
posterior3 = pg.Sequential(pg.PageRank(),
pg.Normalize("range")).rank(prior)
assert pg.sum(pg.abs(posterior1 - posterior2)) < pg.epsilon(
) # TODO: investigate when not exactly zero
assert pg.sum(pg.abs(posterior1 - posterior3)) < pg.epsilon(
) # TODO: investigate when not exactly zero
def test_normalize():
import networkx as nx
graph = next(pg.load_datasets_graph(["graph5"]))
for _ in supported_backends():
assert float(
pg.sum(
pg.Normalize("range").transform(
pg.to_signal(nx.Graph([("A", "B")]), [2, 2])).np)) == 4
r = pg.Normalize(pg.PageRank(), "range").rank(graph)
assert pg.min(r.np) == 0
assert pg.max(r.np) == 1
r = pg.Normalize(pg.PageRank(), "sum").rank(graph)
assert abs(pg.sum(r.np) - 1) < pg.epsilon()
with pytest.raises(Exception):
pg.Normalize(pg.PageRank(), "unknown").rank(graph)
def _transform(self, ranks: pg.GraphSignal, **kwargs):
if ranks.graph not in self.known_ranks or not self.assume_immutability:
with pg.Backend("numpy"):
A = pg.preprocessor(normalization=self.normalization)(
ranks.graph)
D = pg.degrees(
pg.preprocessor(normalization="none")(ranks.graph))
s = pg.sum(
D)**0.5 / 2 if self.sparsity is None else self.sparsity
D = (D / pg.max(D))**self.beta
S = scipy.sparse.random(
self.dims,
A.shape[0],
density=1. / s,
data_rvs=lambda l: np.random.choice([-1, 1], size=l),
format="csc")
S = S @ scipy.sparse.spdiags(D, 0, *A.shape)
self.embeddigns[ranks.graph] = pg.scipy_sparse_to_backend(S.T)
self.known_ranks[ranks.graph] = [
] # we know that the first term is zero and avoid direct embedding comparison
for _ in range(len(self.weights)):
S = S @ A
self.known_ranks[ranks.graph].append(
pg.scipy_sparse_to_backend(S))
ret = 0
on = pg.conv(ranks.np, self.embeddigns[ranks.graph])
for weight, S in zip(self.weights, self.known_ranks[ranks.graph]):
uv = pg.conv(on, S)
ret = ret + weight * uv
return pg.to_signal(ranks, ret)
def test_norm_maintain():
# TODO: investigate that 2.5*epsilon is truly something to be expected
graph = next(pg.load_datasets_graph(["graph5"]))
for _ in supported_backends():
prior = pg.to_signal(graph, {"A": 2})
posterior = pg.MabsMaintain(pg.Normalize(pg.PageRank(),
"range")).rank(prior)
assert abs(pg.sum(pg.abs(posterior.np)) - 2) < 2.5 * pg.epsilon()
def test_separate_and_combine():
for _ in supported_backends():
table = pg.to_primitive([[1, 2, 3], [4, 5, 6]])
cols = pg.separate_cols(table)
assert len(cols) == 3
for col in cols:
assert pg.length(col) == 2
new_table = pg.combine_cols(cols)
assert pg.sum(pg.abs(table - new_table)) == 0
def test_transform():
import math
graph = next(pg.load_datasets_graph(["graph5"]))
for _ in supported_backends():
r1 = pg.Normalize(pg.PageRank(), "sum").rank(graph)
r2 = pg.Transformer(pg.PageRank(), lambda x: x / pg.sum(x)).rank(graph)
assert pg.Mabs(r1)(r2) < pg.epsilon()
r1 = pg.Transformer(math.exp).transform(pg.PageRank()(graph))
r2 = pg.Transformer(pg.PageRank(), pg.exp).rank(graph)
assert pg.Mabs(r1)(r2) < pg.epsilon()
def test_preprocessor_types():
def test_graph():
return next(pg.load_datasets_graph(["graph5"]))
for _ in supported_backends():
from random import random
graph = test_graph()
signal = pg.to_signal(graph, {v: random() for v in graph})
laplacian = pg.preprocessor(normalization="laplacian")(graph)
symmetric = pg.preprocessor(normalization="symmetric")(graph)
assert pg.abs(pg.sum(pg.conv(signal, laplacian) + pg.conv(signal, symmetric) - signal)) <= pg.epsilon()
def rank(self,
graph: pg.GraphSignalGraph = None,
personalization: pg.GraphSignalData = None,
**kwargs):
personalization = pg.to_signal(graph, personalization)
graph = personalization.graph
ranks = self.ranker(personalization)
ret = 0
total_sum = pg.sum(ranks)
accum_sum = 0
for threshold in sorted(ranks.values()):
accum_sum += threshold
if accum_sum > total_sum * 0.1:
break
for i, v in enumerate(ranks):
pg.utils.log(f"{i}/{len(ranks)}")
if ranks[v] >= threshold:
partial = ranks >> pg.Threshold(ranks[v],
inclusive=True) >> self.ranker
ret = partial * ranks[v] + ret
return ret
def test_fastgraph():
for graph_api in [pg.fastgraph, nx]:
graph = next(pg.load_datasets_graph(["graph5"], graph_api=graph_api))
assert graph.has_edge("A", "B")
assert not graph.has_edge("A", "E")
graph.add_edge("A", "E")
assert graph.has_edge("A", "E")
assert graph.has_edge(
"E", "A") # checks that undirected is the default mode
prev_count = graph.number_of_edges()
graph.remove_edge("A", "E")
assert graph.number_of_edges() == prev_count - 1
sparse = graph.to_scipy_sparse_array() if isinstance(
graph, pg.Graph) else nx.to_scipy_sparse_matrix(
graph, weight="weight", dtype=float)
assert pg.sum(sparse) == 14
assert not graph.has_edge("A", "E")
assert not graph.has_edge("E", "A")
graph.add_edge("A", "E")
assert graph.has_edge("A", "E")
graph.add_edge("Y", "Z")
assert graph.has_edge("Y", "Z")
def test_krylov_space():
graph = next(pg.load_datasets_graph(["bigraph"]))
nodes = list(graph)
for _ in supported_backends():
personalization = pg.to_signal(graph, {nodes[0]: 1, nodes[1]: 1})
M = pg.preprocessor(normalization="symmetric")(graph)
krylov_dims = 5
krylov_result = pg.eye(int(krylov_dims))
krylov_base, H = pg.krylov_base(M, personalization.np,
int(krylov_dims))
error_bound = pg.krylov_error_bound(krylov_base, H, M,
personalization.np)
assert pg.sum(pg.krylov2original(0, H, krylov_dims)) == 0
assert error_bound < 0.01
for _ in range(100):
krylov_result = krylov_result @ H
personalization.np = pg.conv(personalization.np, M)
# print(pg.Mabs(personalization.np)(pg.krylov2original(krylov_base, krylov_result, int(krylov_dims))))
assert pg.Mabs(personalization.np)(pg.krylov2original(
krylov_base, krylov_result, int(krylov_dims))) <= error_bound
assert pg.krylov2original(
krylov_base, krylov_result,
int(krylov_dims)).shape == personalization.np.shape
def test_zero_personalization():
assert pg.sum(pg.PageRank()(next(pg.load_datasets_graph(["graph9"])),
{}).np) == 0
def test_signal_direct_operations():
for _ in supported_backends():
graph = nx.DiGraph([(1, 2), (2, 3)])
signal = pg.to_signal(graph, [1., 2., 3.])
assert pg.sum(signal) == 6
assert pg.sum(signal + 1) == 9
assert pg.sum(1 + signal) == 9
assert pg.sum(signal**2) == 14
assert pg.sum(signal - pg.to_signal(graph, [1, 2, 2])) == 1
assert pg.sum(-1 + signal) == 3
assert pg.sum(signal / pg.to_signal(graph, [1., 2., 3.])) == 3
assert pg.sum(3**signal) == 3 + 9 + 27
signal **= 2
assert pg.sum(signal) == 14
signal.np = pg.to_signal(graph, [4, 4, 4])
assert pg.sum(signal) == 12
assert pg.sum(+signal) == 12
assert pg.sum(-signal) == -12
assert pg.sum(-signal / 2) == -6
#assert pg.sum(-signal//2) == -6
assert pg.sum(2 / signal) == 1.5
#assert pg.sum(2//signal) == 0
signal += 1
assert pg.sum(signal) == 15
signal -= 1
assert pg.sum(signal) == 12
signal /= 2
assert pg.sum(signal) == 6
signal /= 2 # //= 2
assert pg.sum(signal) == 3
signal *= 4
assert pg.sum(signal) == 12
with pytest.raises(Exception):
signal + pg.to_signal(graph.copy(), [1., 2., 3.])
