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Still crunching thru tests

master
Pete Shadbolt 8 年之前
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f6f6ccd08d
共有 10 個文件被更改,包括 153 次插入172 次删除
  1. +2
    -1
      tests/mock.py
  2. +0
    -77
      tests/old/test_graph.py
  3. +0
    -24
      tests/old/test_json.py
  4. +0
    -17
      tests/old/test_layout.py
  5. +0
    -24
      tests/old/test_local_complementation.py
  6. +0
    -11
      tests/old/test_normalize_global_phase.py
  7. +0
    -12
      tests/old/test_nxgraphstate.py
  8. +36
    -0
      tests/test_fancy.py
  9. +106
    -2
      tests/test_graphstate.py
  10. +9
    -4
      tests/test_qi.py

+ 2
- 1
tests/mock.py 查看文件

@@ -97,9 +97,10 @@ def named_node_graph():
g.act_circuit((edge, "cz") for edge in edges)
return g


def simple_graph():
""" A simple graph to test with"""
edges = (0, 1), (1, 2), (2, 0), (0, 3), (100, 200)
edges = (0, 1), (1, 2), (2, 0), (0, 3), (100, 200)
g = ABPWrapper([0, 1, 2, 3, 100, 200])
g.act_circuit((i, "hadamard") for i in g.node)
g.act_circuit((edge, "cz") for edge in edges)


+ 0
- 77
tests/old/test_graph.py 查看文件

@@ -1,77 +0,0 @@
from abp import GraphState
from abp import clifford
from demograph import demograph
import time


def test_graph_basic():
""" Test that we can construct graphs, delete edges, whatever """
g = demograph()
assert set(g.adj[0].keys()) == set([1, 2, 3])
g.del_edge(0, 1)
assert set(g.adj[0].keys()) == set([2, 3])
assert g.has_edge(1, 2)
assert not g.has_edge(0, 1)


def test_local_complementation():
""" Test that local complementation works as expected """
g = demograph()
g.local_complementation(0)
assert g.has_edge(0, 1)
assert g.has_edge(0, 2)
assert not g.has_edge(1, 2)
assert g.has_edge(3, 2)
assert g.has_edge(3, 1)

# TODO: test VOP conditions


def test_remove_vop():
""" Test that removing VOPs really works """
g = demograph()
g.remove_vop(0, 1)
assert g.node[0]["vop"] == clifford.by_name["identity"]
g.remove_vop(1, 1)
assert g.node[1]["vop"] == clifford.by_name["identity"]
g.remove_vop(2, 1)
assert g.node[2]["vop"] == clifford.by_name["identity"]
g.remove_vop(0, 1)
assert g.node[0]["vop"] == clifford.by_name["identity"]


def test_edgelist():
""" Test making edgelists """
g = demograph()
el = g.edgelist()
assert (0, 3) in el
assert (0, 2) in el
assert (100, 200) in el


def test_stress(n = int(1e5)):
""" Testing that making a graph of ten thousand qubits takes less than half a second"""
g = GraphState(range(n+1))
t = time.clock()
for i in xrange(n):
g.add_edge(i, i + 1)
assert time.clock() - t < .5


def test_cz():
""" Test CZ gate """
g = GraphState([0, 1])
g.act_local_rotation(0, clifford.by_name["hadamard"])
g.act_local_rotation(1, clifford.by_name["hadamard"])
g.act_local_rotation(1, clifford.by_name["py"])
assert not g.has_edge(0, 1)
g.act_cz(0, 1)
assert g.has_edge(0, 1)

def test_stabilizer():
""" Test that we can generate stabilizers okay """
g = demograph()
stab = g.to_stabilizer()
#TODO: sux
#assert len(stab.split("\n")) == g.order()


+ 0
- 24
tests/old/test_json.py 查看文件

@@ -1,24 +0,0 @@
from abp import GraphState, fancy
from abp import clifford
from demograph import demograph
import time
import json

def test_json_basic():
""" Test that we can export to JSON """
g = demograph()
js = g.to_json()
assert "adj" in js
assert "node" in js
e = GraphState()

def test_tuple_keys():
""" Test that we can write tuple-ish keys """
g = fancy.GraphState()
g.add_node("string")
g.add_node((1, 2, 3))
g.add_edge((1, 2, 3), "string")
print json.dumps(g.to_json(True))




+ 0
- 17
tests/old/test_layout.py 查看文件

@@ -1,17 +0,0 @@
from demograph import demograph

#TODO

def _test_nx_convert():
g = demograph()
n = g.to_networkx()
assert len(g.ngbh) == len(n.edge)
assert len(g.vops) == len(n.node)

def _test_layout():
g = demograph()
g.layout()
assert len(g.meta) == len(g.vops)
assert "pos" in g.meta[0]
assert "x" in g.meta[0]["pos"]


+ 0
- 24
tests/old/test_local_complementation.py 查看文件

@@ -1,24 +0,0 @@
from abp.fancy import GraphState
from abp import qi

def test_local_comp():
""" Test that local complementation works okay """
psi = GraphState()
psi.add_node(0)
psi.add_node(1)
psi.add_node(2)
psi.add_node(3)

for n in psi.node:
psi.act_hadamard(n)

psi.act_cz(0, 1)
psi.act_cz(0, 3)
psi.act_cz(1, 3)
psi.act_cz(1, 2)

before = psi.copy()
psi.local_complementation(1)
assert before.edgelist() != psi.edgelist()
assert before.to_state_vector() == psi.to_state_vector()


+ 0
- 11
tests/old/test_normalize_global_phase.py 查看文件

@@ -1,11 +0,0 @@
from abp import clifford
from abp import qi
import numpy as np

def test_normalize_global_phase():
for i in range(10):
u = qi.pz
phase = np.random.uniform(0, 2*np.pi)
m = np.exp(1j*phase) * u
normalized = qi.normalize_global_phase(m)
assert np.allclose(normalized, u)

+ 0
- 12
tests/old/test_nxgraphstate.py 查看文件

@@ -1,12 +0,0 @@
from abp.graphstate import GraphState
from abp.util import xyz
import networkx as nx

def simple_test():
g = GraphState()
g.add_node(0, position = xyz(10, 0, 0))
g.add_node(1, position = xyz(1, 0, 0))
g.act_hadamard(0)
g.act_hadamard(1)
g.act_cz(0, 1)


+ 36
- 0
tests/test_fancy.py 查看文件

@@ -0,0 +1,36 @@
import json
import networkx as nx
from abp import GraphState, fancy
from abp import clifford
from abp.util import xyz
from mock import simple_graph

def test_json_basic():
""" Test that we can export to JSON """
g = simple_graph()
js = g.to_json()
assert "adj" in js
assert "node" in js

def test_tuple_keys():
""" Test that we can use tuple-ish keys """
g = fancy.GraphState()
g.add_node("string")
g.add_node((1, 2, 3))
g.add_edge((1, 2, 3), "string")
json.dumps(g.to_json(True))

def networkx_test():
""" Test that fancy graph states really behave like networkx graphs """
g = fancy.GraphState()
g.add_node(0, position = xyz(10, 0, 0))
g.add_node(1, position = xyz(1, 0, 0))
g.act_hadamard(0)
g.act_hadamard(1)
g.act_cz(0, 1)
g.copy()

# TODO: more tests here!




+ 106
- 2
tests/test_graphstate.py 查看文件

@@ -1,7 +1,12 @@
from abp import GraphState
from abp import GraphState, CircuitModel, clifford
from abp import clifford
from mock import simple_graph
import time
import random
import numpy as np
from tqdm import tqdm

REPEATS = 100
DEPTH = 100


def test_graph_basic():
@@ -51,6 +56,7 @@ def test_edgelist():

def test_stress(n = int(1e5)):
""" Testing that making a graph of ten thousand qubits takes less than half a second"""
import time
g = GraphState(range(n+1))
t = time.clock()
for i in xrange(n):
@@ -74,3 +80,101 @@ def test_stabilizer():
stab = g.to_stabilizer()
#TODO

def test_local_complementation():
""" Test that local complementation works okay """
psi = GraphState()
psi.add_node(0)
psi.add_node(1)
psi.add_node(2)
psi.add_node(3)

for n in psi.node:
psi.act_hadamard(n)

psi.act_cz(0, 1)
psi.act_cz(0, 3)
psi.act_cz(1, 3)
psi.act_cz(1, 2)

old_edges = psi.edgelist()
old_state = psi.to_state_vector()
psi.local_complementation(1)
assert old_edges != psi.edgelist()
assert old_state == psi.to_state_vector()

def test_single_qubit():
""" A multi qubit test with Hadamards only"""
for repeat in tqdm(range(REPEATS), desc="Testing against circuit model"):
g = GraphState([0])
c = CircuitModel(1)

for i in range(100):
op = np.random.choice(range(24))
g.act_local_rotation(0, op)
c.act_local_rotation(0, clifford.unitaries[op])

assert g.to_state_vector() == c


def test_hadamard_only_multiqubit(n=6):
""" A multi qubit test with Hadamards only"""
for repeat in tqdm(range(REPEATS), desc="Testing against circuit model"):
g = GraphState(range(n))
c = CircuitModel(n)

for i in range(n):
g.act_hadamard(i)
c.act_hadamard(i)

assert g.to_state_vector() == c

for i in range(100):
a, b = np.random.choice(range(n), 2, False)
g.act_cz(a, b)
c.act_cz(a, b)

assert g.to_state_vector() == c


def test_all_multiqubit(n=4):
""" A multi qubit test with arbitrary local rotations """
g = GraphState(range(n))
c = CircuitModel(n)
for i in range(10):
qubit = np.random.randint(0, n - 1)
rotation = np.random.randint(0, 24 - 1)
g.act_local_rotation(qubit, rotation)
c.act_local_rotation(qubit, clifford.unitaries[rotation])

assert g.to_state_vector() == c

for repeat in tqdm(range(REPEATS), desc="Testing against circuit model"):
a, b = np.random.choice(range(n), 2, False)
g.act_cz(a, b)
c.act_cz(a, b)
assert np.allclose(np.sum(np.abs(c.state) ** 2), 1)
assert np.allclose(
np.sum(np.abs(g.to_state_vector().state) ** 2), 1)

assert g.to_state_vector() == c

assert g.to_state_vector() == c

def test_all(n=8):
""" A multi qubit test with arbitrary local rotations """
g = GraphState(range(n))
c = CircuitModel(n)
for repeat in tqdm(xrange(REPEATS), "Testing against circuit model"):
for step in xrange(DEPTH):
if random.random()>0.5:
qubit = np.random.randint(0, n - 1)
rotation = np.random.randint(0, 24 - 1)
g.act_local_rotation(qubit, rotation)
c.act_local_rotation(qubit, clifford.unitaries[rotation])
else:
a, b = np.random.choice(range(n), 2, False)
g.act_cz(a, b)
c.act_cz(a, b)
assert g.to_state_vector() == c



+ 9
- 4
tests/test_qi.py 查看文件

@@ -92,13 +92,9 @@ def test_dumbness():
a = qi.CircuitModel(1)
b = qi.CircuitModel(1)
assert a == b

a.act_local_rotation(0, qi.px)

assert not (a == b)

a.act_local_rotation(0, qi.px)

assert (a == b)


@@ -111,3 +107,12 @@ def test_to_state_vector_single_qubit():
g.act_local_rotation(1, "hadamard")
g.act_cz(0, 1)
assert np.allclose(g.to_state_vector().state, qi.bond)

def test_normalize_global_phase():
""" We should be able to see that two states are equivalent up to a global phase """
for i in range(10):
u = qi.pz
phase = np.random.uniform(0, 2*np.pi)
m = np.exp(1j*phase) * u
normalized = qi.normalize_global_phase(m)
assert np.allclose(normalized, u)

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