def all_bell_states(self, q, ix):
Gates.H(q, 0)
if ix >= 2:
Gates.X(q, 1)
Gates.CNOT(q, 0, 1)
if ix % 2 == 1:
Gates.Z(q, 0)
def mZX(q, ix, iy):
Gates.H(q, iy)
Gates.CNOT(q, iy, ix)
m = Measurement.measure(q, ix)
Gates.CNOT(q, iy, ix)
Gates.H(q, iy)
print m, q
def mZZ(q, ix, iy):
Gates.CNOT(q, iy, ix)
print q
m = Measurement.measure(q, ix)
print m, q
Gates.CNOT(q, iy, ix)
print m, q
def controlled_x(self, q, rnd):
Gates.Z(q, 0)
if Measurement.rr_measurement(q, [PauliZ(), PauliX()], [0, 1],
rnd) == -1:
Gates.Z(q, 1)
Gates.H(q, 1)
Gates.Z(q, 0)
def bell_state(self, q, index):
assert q.length == 2
Gates.H(q, 0)
Gates.CNOT(q, 0, 1)
if index % 2 == 1:
Gates.Z(q, 1)
if index >= 2:
Gates.X(q, 1)
def test_103_check_plus_minus(self):
q = Qubits(1)
Gates.H(q, 0)
assert self.check_plus_minus(q) == True
q = Qubits(1)
Gates.X(q, 0)
Gates.H(q, 0)
assert self.check_plus_minus(q) == False
def check_bell(self, q):
Gates.CNOT(q, 0, 1)
Gates.H(q, 0)
m = Measurement.measure(q, 0)
mm = Measurement.measure(q, 1)
i = 0 if m == 1 else 1
ii = 0 if mm == 1 else 1
return i + 2 * ii
def check_state(self, q):
Gates.H(q, 0)
Gates.H(q, 1)
m = Measurement.measure(q, 0)
mm = Measurement.measure(q, 1)
ii = 0 if m == 1 else 1
i = 0 if mm == 1 else 1
return i + 2 * ii
def oracle(self, qs):
assert qs.length == (len(self.b) + 1), "incorrect qubit length"
for ix, b in enumerate(self.b):
if b:
Gates.CNOT(qs, ix, qs.length - 1)
else:
Gates.X(qs, ix)
Gates.CNOT(qs, ix, qs.length - 1)
Gates.X(qs, ix)
def superposition_bitstrings(self, q, bits1, bits2):
ix, bitsa, bitsb = self.__find_one_zero(bits1, bits2)
Gates.H(q, ix)
for ii in range(0, len(bits1)):
if ix == ii:
continue
if bitsb[ii]:
Gates.X(q, ii)
Gates.CNOT(q, ix, ii)
if bitsa[ii]:
Gates.CNOT(q, ix, ii)
def check_bva(self, n, oracle):
q = Qubits(n + 1)
Gates.X(q, n)
for ix in xrange(n + 1):
Gates.H(q, ix)
oracle(q)
for ix in xrange(n):
Gates.H(q, ix)
r = [True] * n
for ix in xrange(n):
m = Measurement.measure(q, ix)
if m == -1:
Gates.X(q, ix)
r[ix] = (m != 1)
return r
def test_teleportation(self): q = Qubits(3) alice = 0 bob = 1 message = 2 Gates.H(q, message) # entangle alice with bob Gates.H(q, alice) Gates.CNOT(q, alice, bob) # entangle message with alice print Gates.CNOT(q, message, alice) print Gates.H(q, message) am = Measurement.measure(q, alice) mm = Measurement.measure(q, message) print am == -1, mm == -1, q
def test_phase_flip(self):
q = Qubits(1)
self.phase_flip(q)
self.assert_signs(q, [(0, 1)])
Gates.X(q, 0)
self.phase_flip(q)
self.assert_signs(q, [(1, I)])
def test_add_CNOT_remove(self):
q = Qubits.random_qubits(2)
qq = q.clone()
q.add_qubit()
Gates.CNOT(q, 1, 0)
q.remove_qubit()
self.assert_qubits(q, qq)
def oracle(self, qs):
assert qs.length == (len(self.b) + 1), "incorrect qubit length"
assert self.called == False, "can only call oracle once"
for ix, b in enumerate(self.b):
if b:
Gates.CNOT(qs, ix, qs.length - 1)
self.called = True
def test_102_reset_qubit(self):
q = Qubits(1)
self.reset_qubit(q)
self.assert_signs(q, [(0, 1)])
q = Qubits(1)
Gates.X(q, 0)
self.reset_qubit(q)
self.assert_signs(q, [(0, 1)])
def test_phase_change(self):
aaa = symbols('aaa')
q = Qubits(1)
self.phase_change(q, aaa)
self.assert_signs(q, [(0, 1)])
Gates.X(q, 0)
self.phase_change(q, aaa)
self.assert_signs(q, [(1, exp(I * aaa))])
def test_fredkin_gate(self):
q = Qubits(3)
Gates.X(q, 0)
Gates.X(q, 1)
self.fredkin_gate(q)
self.assert_signs(q, [(5, 1)])
q = Qubits(3)
Gates.X(q, 0)
Gates.X(q, 2)
self.fredkin_gate(q)
self.assert_signs(q, [(6, 1)])
for x in [True, False]:
for y in [True, False]:
for z in [True, False]:
if x and (y ^ z):
continue
q = Qubits(3)
if x:
Gates.X(q, 0)
if y:
Gates.X(q, 1)
if z:
Gates.X(q, 2)
self.fredkin_gate(q)
self.assert_signs(q, q.monomials())
def test_amplitude_change(self):
q = Qubits(1)
self.amplitude_change(q, pi / 3)
self.assert_signs(q, [(0, half), (1, half * sqrt(3))])
q = Qubits(1)
Gates.X(q, 0)
self.amplitude_change(q, pi / 3)
self.assert_signs(q, [(0, -half * sqrt(3)), (1, half)])
def test_two_qubit_gate(self):
q = Qubits(2)
Gates().H(q, 0)
self.two_qubit_gate(q)
self.assert_signs(q, [(0, 1), (3, 1)])
q = Qubits(2)
self.two_qubit_gate(q)
self.assert_signs(q, [(0, 1)])
def test_toffoli_gate(self):
for x in [True, False]:
for y in [True, False]:
for z in [True, False]:
q = Qubits(3)
m = 0
if x:
Gates.X(q, 0)
m = m + 4
if y:
Gates.X(q, 1)
m = m + 2
if z:
Gates.X(q, 2)
if x and y:
if not z:
m = m + 1
elif z:
m = m + 1
self.toffoli_gate(q)
self.assert_signs(q, [(m, 1)])
def test_two_qubit_gate_3(self):
q = Qubits(2)
# Assert that |01> -> |10>
Gates.X(q, 1)
self.two_qubit_gate_3(q)
self.assert_signs(q, [(2, 1)])
# Assert that |10> -> |01>
self.two_qubit_gate_3(q)
self.assert_signs(q, [(1, 1)])
# Assert that |00> -> |00>
q = Qubits(2)
self.two_qubit_gate_3(q)
self.assert_signs(q, [(0, 1)])
# Assert that |11> -> |11>
Gates.X(q, 0)
Gates.X(q, 1)
self.assert_signs(q, [(3, 1)])
self.two_qubit_gate_3(q)
self.assert_signs(q, [(3, 1)])
def check_state(self, q, rnd):
l = q.length
if l % 2 == 1:
m = Measurement.rr_measure(q, l - 1, rnd)
if m == -1:
m = Measurement.measure(q, 0)
if m == 1:
return 1
if m == -1:
return 0
return
l = l - 1
for ix in xrange(1, l):
Gates.CNOT(q, ix, 0)
for ix in xrange(1, l):
Gates.CNOT(q, 0, ix)
# if l % 2 == 1:
# Gates.H(q, 0)
m = Measurement.measure(q, 0)
if m == -1:
return 1
else:
return 0
def test_06_controlled_x(self):
"""// Task 6. Controlled X gate with |0⟩ target
// Input: Two unentangled qubits (stored in an array of length 2).
// The first qubit will be in state |ψ⟩ = α |0⟩ + β |1⟩, the second - in state |0⟩
// (this can be written as two-qubit state (α|0⟩ + β|1⟩) ⊕ |0⟩).
// Goal: Change the two-qubit state to α |00⟩ + β |11⟩ using only single-qubit gates and joint measurements.
// Do not use two-qubit gates.
// You do not need to allocate extra qubits."""
for _ in range(20):
for rnd in [0.1, 0.9]:
a, b = self.random_unit_vector(2)
q = Qubits.create(2, [(0, a), (2, b)])
qq = q.clone()
Gates.CNOT(qq, 0, 1)
self.controlled_x(q, rnd)
self.assert_qubits(q, qq)
def w_state(self, q):
Gates.X(q, 0)
power = 1
while power < q.length:
oldpower = power
power = power * 2
Gates.H(q, power - 1)
for ix in range(oldpower - 1):
index = oldpower + ix
Gates.CCNOT(q, ix, power - 1, index)
Gates.CNOT(q, index, ix)
Gates.CNOT(q, index, power - 1)
Gates.CNOT(q, power - 1, oldpower - 1)
return q
def controlled_x_general(self, q):
# Gates.CNOT(q, 0, 1)
items = [0.1, 0.9]
r1, r2, r3 = choice(items), choice(items), choice(items)
bad = [[0.1, 0.9, 0.9], [0.9, 0.9, 0.1]]
if [r1, r2, r3] in bad:
r1, r2, r3 = [0.1, 0.1, 0.1]
print r1, r2, r3
q.add_qubit()
#print "before measurement", q
p1 = self.copy_qubit(q, 1, 0, r1)
#print "after measurement", q
Gates.H(q, 0)
Gates.H(q, 2)
p2 = Measurement.rr_measurement(q, [PauliZ(), PauliZ()], [0, 2], r2)
Gates.H(q, 0)
Gates.H(q, 2)
if p2 == -1:
Gates.Z(q, 1)
if p1 != Measurement.rr_measurement(q, [PauliZ()], [0], r3):
Gates.X(q, 2)
#print "after CNOT", q
q.remove_qubit()
def copy_qubit(self, q, source, target, r):
Gates.H(q, target)
return Measurement.rr_measurement(q, [PauliZ(), PauliZ()],
[target, source], r)
def generate_superposition(self, qs):
for ix in range(qs.length):
Gates.H(qs, ix)
def ghz_state(self, q):
l = q.length
Gates.H(q, 0)
for ix in xrange(1, l):
Gates.CNOT(q, 0, ix)
def plus_minus_state(self, q, sign):
assert q.length == 1
if sign < 0:
Gates.X(q, 0)
Gates.H(q, 0)
