def test_dump_values(self):
qregs = new_qregs(4)
cregs = new_references(4)
circuit = [I(qreg) for qreg in qregs]
sim = qgate.simulator.py()
sim.run(circuit)
qgate.dump(sim.values, file=self.file)
def test_dump_qubits(self):
qregs = new_qregs(4)
circuit = [H(qreg) for qreg in qregs]
sim = qgate.simulator.py()
sim.run(circuit)
qgate.dump(sim.qubits.states, file=self.file)
qgate.dump(sim.qubits.prob, file=self.file)
def test_observation_list_repr(self):
qregs = new_qregs(4)
cregs = new_references(4)
circuit = [
[H(qreg) for qreg in qregs],
measure(cregs[0], qregs[0]),
measure(cregs[2], qregs[2]),
measure(cregs[3], qregs[3]),
]
sim = qgate.simulator.py()
obslist = sim.sample(circuit, cregs, 128)
qgate.dump(obslist, file=self.file)
print(obslist.__repr__(), file=self.file)
def run(caption, circuit, refs = None) :
prefs = { qgate.prefs.circuit_prep: qgate.prefs.dynamic }
# sim = qgate.simulator.py(**prefs)
sim = qgate.simulator.cpu(**prefs)
# sim = qgate.simulator.cuda(**prefs)
sim.run(circuit)
print(caption)
qgate.dump(sim.qubits)
qgate.dump(sim.qubits.prob)
if refs is not None :
print('observation: {}'.format(sim.obs(refs)))
print()
sim.terminate()
def run(circuit, caption) :
sim = qgate.simulator.cuda(dtype=np.float32, isolate_circuits = False)
n_lanes_per_device = -1
device_ids = []
if this.mgpu :
n_lanes_per_device = this.n_qubits - 1
device_ids = [ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 ]
sim.run(circuit)
print(caption)
states = sim.qubits.get_states()
qgate.dump(sim.values)
print()
sim.terminate()
def run(circuit, caption):
prefs = {'isolate_circuits': True}
# sim = qgate.simulator.py(**prefs)
sim = qgate.simulator.cpu(**prefs)
# sim = qgate.simulator.cuda(**prefs)
sim.run(circuit)
print(caption)
qgate.dump(sim.qubits, qgate.simulator.prob)
qgate.dump(sim.qubits)
qgate.dump(sim.values)
print()
sim.terminate()
# allocating qubit register
qregs = new_qregs(2)
q0, q1 = qregs[0], qregs[1]
# building a quantum circuit.
circuit = [[H(qreg) for qreg in qregs],
H(q1),
ctrl(q0).X(q1),
H(q1), [H(qreg) for qreg in qregs], [X(qreg) for qreg in qregs],
H(q1),
ctrl(q0).X(q1),
H(q1), [X(qreg) for qreg in qregs], [H(qreg) for qreg in qregs]]
# measure
refs = new_references(2)
circuit += [measure(refs[0], qregs[0]), measure(refs[1], qregs[1])]
sim = qgate.simulator.py()
sim.run(circuit)
results = sim.values.get(refs)
print('Results\n' '(q0, q1) = ({}, {})'.format(results[0], results[1]))
print('\ndump results:')
qgate.dump(sim.values)
print('\ndump state vector:')
qgate.dump(sim.qubits)
sim.terminate()
circuit = [
X(q[0]), # x q[0]
X(q[2]), # x q[2];
barrier(q), # barrier q;
H(q[0]), # h q[0];
ctrl(q[1]).U1(math.pi / 2.)(q[0]), # cu1(pi/2) q[1],q[0];
H(q[1]), # h q[1];
ctrl(q[2]).U1(math.pi / 4.)(q[0]), # cu1(pi/4) q[2],q[0];
ctrl(q[2]).U1(math.pi / 2.)(q[1]), # cu1(pi/2) q[2],q[1];
H(q[2]), # h q[2];
ctrl(q[3]).U1(math.pi / 8.)(q[0]), # cu1(pi/8) q[3],q[0];
ctrl(q[3]).U1(math.pi / 4.)(q[1]), # cu1(pi/4) q[3],q[1];
ctrl(q[3]).U1(math.pi / 2.)(q[2]), # cu1(pi/2) q[3],q[2];
H(q[3]), # h q[3];
]
sim = qgate.simulator.py()
sim.run(circuit)
print('\nqubit states')
qgate.dump(sim.qubits)
print('\nprobability')
qgate.dump(sim.qubits.prob)
sim.run([measure(_c, _q) for _c, _q in zip(c, q)]) # measure q -> c;
obs = sim.obs(c)
print('\nobservation: {}\n'.format(repr(obs)))
sim.terminate()
# Glover's algorithm
# allocating qubit register
qregs = new_qregs(2)
q0, q1 = qregs[0], qregs[1]
# building a quantum circuit.
circuit = [[H(qreg) for qreg in qregs],
H(q1),
ctrl(q0).X(q1),
H(q1), [H(qreg) for qreg in qregs], [X(qreg) for qreg in qregs],
H(q1),
ctrl(q0).X(q1),
H(q1), [X(qreg) for qreg in qregs], [H(qreg) for qreg in qregs]]
# measure
refs = new_references(2)
circuit += [measure(refs[0], qregs[0]), measure(refs[1], qregs[1])]
sim = qgate.simulator.py()
sim.run(circuit)
obs = sim.obs(refs)
print('observation\n' '(c0, c1) = ({}, {})'.format(obs(refs[0]), obs(refs[1])))
print(obs)
print('\ndump state vector:')
qgate.dump(sim.qubits)
sim.terminate()
def test_dump_circuit(self):
qreg0, qreg1 = new_qregs(2)
circuit = [
I(qreg0),
H(qreg0),
S(qreg0),
T(qreg0),
X(qreg0),
Y(qreg0),
Z(qreg0),
Rx(0.)(qreg0),
Ry(0.)(qreg0),
Rz(0.)(qreg0),
U1(0.)(qreg0),
U2(0., 0.)(qreg0),
U3(0., 0., 0.)(qreg0),
Expii(0.)(qreg0),
Expiz(0.)(qreg0),
SH(qreg0),
Swap(qreg0, qreg1),
barrier(qreg0, qreg1)
]
circuit += [
I.Adj(qreg0),
H.Adj(qreg0),
S.Adj(qreg0),
T.Adj(qreg0),
X.Adj(qreg0),
Y.Adj(qreg0),
Z.Adj(qreg0),
Rx(0.).Adj(qreg0),
Ry(0.).Adj(qreg0),
Rz(0.).Adj(qreg0),
U1(0.).Adj(qreg0),
U2(0., 0.).Adj(qreg0),
U3(0., 0., 0.).Adj(qreg0),
Expii(0.).Adj(qreg0),
Expiz(0.).Adj(qreg0),
SH.Adj(qreg0),
Swap(qreg0, qreg1),
barrier(qreg0, qreg1)
]
circuit += [
ctrl(qreg0).I(qreg1),
ctrl(qreg0).H(qreg1),
ctrl(qreg0).S(qreg1),
ctrl(qreg0).T(qreg1),
ctrl(qreg0).X(qreg1),
ctrl(qreg0).Y(qreg1),
ctrl(qreg0).Z(qreg1),
ctrl(qreg0).Rx(0.)(qreg1),
ctrl(qreg0).Ry(0.)(qreg1),
ctrl(qreg0).Rz(0.)(qreg1),
ctrl(qreg0).U1(0.)(qreg1),
ctrl(qreg0).U2(0., 0.)(qreg1),
ctrl(qreg0).U3(0., 0., 0.)(qreg1),
ctrl(qreg0).Expii(0.)(qreg1),
ctrl(qreg0).Expiz(0.)(qreg1),
ctrl(qreg0).SH(qreg1)
]
circuit += [
ctrl(qreg0).I.Adj(qreg1),
ctrl(qreg0).H.Adj(qreg1),
ctrl(qreg0).S.Adj(qreg1),
ctrl(qreg0).T.Adj(qreg1),
ctrl(qreg0).X.Adj(qreg1),
ctrl(qreg0).Y.Adj(qreg1),
ctrl(qreg0).Z.Adj(qreg1),
ctrl(qreg0).Rx(0.).Adj(qreg1),
ctrl(qreg0).Ry(0.).Adj(qreg1),
ctrl(qreg0).Rz(0.).Adj(qreg1),
ctrl(qreg0).U1(0.).Adj(qreg1),
ctrl(qreg0).U2(0., 0.).Adj(qreg1),
ctrl(qreg0).U3(0., 0., 0.).Adj(qreg1),
ctrl(qreg0).Expii(0.).Adj(qreg1),
ctrl(qreg0).Expiz(0.).Adj(qreg1),
ctrl(qreg0).SH(qreg1)
]
ref = new_reference()
circuit += [measure(ref, qreg0)]
qgate.dump(circuit, file=self.file)
# qregs for iqft.
bits = new_qregs(n_bits)
# initialize
ops = [H(qreg) for qreg in bits]
# set phase in the target qreg.
# Ui = Expii(pi * theta * 2^i), U1, U2, U4, U8 ...
for idx, ctrlreg in enumerate(bits):
theta = 2 * math.pi * v_in * (1 << idx)
ops.append(ctrl(ctrlreg).Expii(theta)(target))
# iqft gate sequence
ops += iqft(bits)
# dump circuit
qgate.dump(ops)
# run simulator
sim = qgate.simulator.cpu()
sim.run(ops)
#sim.qubits.set_ordering(reversed(bits))
#qgate.dump(sim.qubits.prob)
# creating sampling pool
pool = sim.qubits.create_sampling_pool(bits)
# sample 1024 times.
obs = pool.sample(1024)
# creating histgram
hist = obs.histgram()
#print(hist)
