Przeglądaj źródła

Starting to refactor tests against A&B

master
Pete Shadbolt 8 lat temu
rodzic
commit
4124405697
6 zmienionych plików z 144 dodań i 162 usunięć
  1. +5
    -5
      tests/mock.py
  2. +0
    -83
      tests/old/test_against_circuit_model.py
  3. +0
    -44
      tests/old/test_circuit_model_against_chp.py
  4. +0
    -30
      tests/old/test_cphase_against_anders.py
  5. +138
    -0
      tests/test_against_anders_and_briegel.py
  6. +1
    -0
      tests/test_clifford.py

+ 5
- 5
tests/mock.py Wyświetl plik

@@ -116,15 +116,15 @@ def circuit_to_state(Base, n, circuit):
g.act_circuit(circuit)
return g

def test_circuit(circuit):
def test_circuit(circuit, n):
""" Check that two classes exhibit the same behaviour for a given circuit """
a = circuit_to_state(ABPWrapper, 10, circuit)
b = circuit_to_state(AndersWrapper, 10, circuit)
a = circuit_to_state(ABPWrapper, n, circuit)
b = circuit_to_state(AndersWrapper, n, circuit)
assert a == b


if __name__ == '__main__':
for i in range(1000):
test_circuit(random_graph_circuit(10))
test_circuit(random_stabilizer_circuit(10))
test_circuit(random_graph_circuit(10), 10)
test_circuit(random_stabilizer_circuit(10), 10)


+ 0
- 83
tests/old/test_against_circuit_model.py Wyświetl plik

@@ -1,83 +0,0 @@
from abp import GraphState
from abp import CircuitModel
from abp import clifford
import numpy as np
import random
from tqdm import tqdm
from config import *

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 = random.randint(0, 23)
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


+ 0
- 44
tests/old/test_circuit_model_against_chp.py Wyświetl plik

@@ -1,44 +0,0 @@
import chp
from abp import qi
import numpy as np

n = 5

def get_chp_state():
""" Convert CHP to CircuitModel """
output = qi.CircuitModel(n)
ket = chp.get_ket()
nonzero = np.sqrt(len(ket))
output.state[0, 0]=0
for key, phase in ket.items():
output.state[key] = np.exp(1j*phase*np.pi/2)/nonzero
return output


def bell_test():
chp.init(n)
chp.act_hadamard(0)
chp.act_cnot(0, 1)

psi = qi.CircuitModel(n)
psi.act_hadamard(0)
psi.act_cnot(0, 1)
assert psi == get_chp_state()

def random_test():
chp.init(n)
psi = qi.CircuitModel(n)
for i in range(1000):
if np.random.rand()>.5:
a = np.random.randint(0, n-1)
chp.act_hadamard(a)
psi.act_hadamard(a)
else:
a, b = np.random.randint(0, n-1, 2)
if a!=b:
chp.act_cnot(a, b)
psi.act_cnot(a, b)
assert psi == get_chp_state()




+ 0
- 30
tests/old/test_cphase_against_anders.py Wyświetl plik

@@ -1,30 +0,0 @@
import json
import numpy as np
import sys
import os
import itertools as it
from string import maketrans
from abp import clifford, qi, anders_cz, build_tables

def test_cz_table():
""" Does our clifford code work with anders & briegel's table? """
state_table = build_tables.get_state_table(clifford.unitaries)
ab_cz_table = anders_cz.cz_table

rows = it.product([0, 1], it.combinations_with_replacement(range(24), 2))
for bond, (c1, c2) in rows:

# Pick the input state
input_state = state_table[bond, c1, c2]

# Go and compute the output
computed_output = np.dot(qi.cz, input_state)
computed_output = qi.normalize_global_phase(computed_output)

# Now look up the answer in the table
bondp, c1p, c2p = ab_cz_table[bond, c1, c2]
table_output = state_table[bondp, c1p, c2p]

assert np.allclose(computed_output, table_output)



+ 138
- 0
tests/test_against_anders_and_briegel.py Wyświetl plik

@@ -0,0 +1,138 @@
from abp import GraphState, CircuitModel, clifford
from anders_briegel import graphsim
import numpy as np
from tqdm import tqdm
import itertools as it
import mock

REPEATS = 100

def test_hadamard():
""" Test hadamards """
a = graphsim.GraphRegister(1)
b = GraphState()
b.add_node(0)

assert_equal(a, b)
a.hadamard(0)
b.act_hadamard(0)
assert_equal(a, b)
a.hadamard(0)
b.act_hadamard(0)
assert_equal(a, b)


def test_local_rotations():
""" Test local rotations """
a = graphsim.GraphRegister(1)
b = GraphState()
b.add_node(0)
assert_equal(a, b)

for i in range(1000):
j = random.randint(0, 23)
a.local_op(0, graphsim.LocCliffOp(j))
b.act_local_rotation(0, j)
assert_equal(a, b)


def test_times_table():
""" Test times table """
for i, j in it.product(range(24), range(24)):
a = graphsim.GraphRegister(1)
b = GraphState([0])
a.local_op(0, graphsim.LocCliffOp(i))
a.local_op(0, graphsim.LocCliffOp(j))
b.act_local_rotation(0, i)
b.act_local_rotation(0, j)
assert_equal(a, b)


def test_cz_table(N=10):
""" Test the CZ table """

for i, j in it.product(range(24), range(24)):
circuit = [(0, i), (1, j), ((0, 1), "cz")]
mock.test_circuit(circuit, 2)

#for i in range(24):
#for j in range(24):

#a = graphsim.GraphRegister(2)
#b = GraphState()
#b.add_nodes([0, 1])

#a.local_op(0, graphsim.LocCliffOp(10))
#b.act_local_rotation(0, 10)

#a.cphase(0, 1)
#b.act_cz(0, 1)

#a.local_op(0, graphsim.LocCliffOp(i))
#b.act_local_rotation(0, i)
#a.local_op(1, graphsim.LocCliffOp(j))
#b.act_local_rotation(1, j)

#a.cphase(0, 1)
#b.act_cz(0, 1)

#assert_equal(a, b)


def test_with_cphase_gates_hadamard_only(N=10):
""" Hadamrds and CPHASEs, deterministic """

a = graphsim.GraphRegister(N)
b = GraphState()

for i in range(N):
a.hadamard(i)
b.add_node(i)
b.act_hadamard(i)

for i in range(N-1):
a.cphase(i, i+1)
b.act_cz(i, i+1)

assert_equal(a, b)

def test_cz_hadamard(N=10):
""" Test CZs and Hadamards at random """

clifford.use_old_cz()

a = graphsim.GraphRegister(N)
b = GraphState(range(N))
for i in tqdm(range(REPEATS), desc="Testing CZ and Hadamard against A&B"):
if random.random()>0.5:
j = random.randint(0, N-1)
a.hadamard(j)
b.act_hadamard(j)
else:
q = random.randint(0, N-2)
a.cphase(q, q+1)
b.act_cz(q, q+1)
assert_equal(a, b)



def test_all(N=9):
""" Test everything"""

clifford.use_old_cz()

a = graphsim.GraphRegister(N)
b = GraphState(range(N))
for i in tqdm(range(REPEATS), desc="Testing all gates against Anders and Briegel"):
if random.random()>0.5:
j = random.randint(0, N-1)
u = random.randint(0, 23)
a.local_op(j, graphsim.LocCliffOp(u))
b.act_local_rotation(j, u)
else:
q = random.randint(0, N-2)
a.cphase(q, q+1)
b.act_cz(q, q+1)
assert_equal(a, b, str(i))



+ 1
- 0
tests/test_clifford.py Wyświetl plik

@@ -113,3 +113,4 @@ def test_cz_table():
table_output = state_table[bondp, c1p, c2p]

assert np.allclose(computed_output, table_output)


Ładowanie…
Anuluj
Zapisz