Exemplo n.º 1
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 def test_construct_from_oplabels(self):
     # Now repeat the read-in with no parallelize, but a list of lists of oplabels
     labels = [[Label('Gi', 'Q0'), Label('Gp', 'Q8')],
               [Label('Gh', 'Q1'), Label('Gp', 'Q12')]]
     c = circuit.Circuit(layer_labels=labels,
                         line_labels=['Q0', 'Q1', 'Q8', 'Q12'])
     self.assertLess(0, c.depth())
Exemplo n.º 2
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 def test_insert_labels_into_layers_with_nonidle_qubits(self):
     # Test inserting a gate when the relevant qubits aren't
     # idling at that layer
     self.c.insert_labels_into_layers([Label('Gx', 'Q0')], 2)
     self.assertEqual(self.c.size(), 9)
     self.assertEqual(self.c.depth(), 6)
     self.assertEqual(self.c[2, 'Q0'], Label('Gx', 'Q0'))
Exemplo n.º 3
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 def test_construction_label_conversion(self):
     # XXX what is tested here that is not covered by other tests?  EGN: this is more of a use case for when this input is a *nested* tuple.
     # Check that parallel operation labels get converted to circuits properly
     opstr = circuit.Circuit(((('Gx', 0), ('Gy', 1)), ('Gcnot', 0, 1)))
     c = circuit.Circuit(layer_labels=opstr, num_lines=2)
     self.assertEqual(c._labels, (Label(
         (('Gx', 0), ('Gy', 1))), Label('Gcnot', (0, 1))))
Exemplo n.º 4
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 def test_insert_labels_into_layers_with_idle_qubits(self):
     # Test inserting a gate when the relevant qubits are
     # idling at that layer -- depth shouldn't increase
     self.c[2, 'Q1'] = Label('Gx', 'Q1')
     self.assertEqual(self.c.size(), 8)
     self.assertEqual(self.c.depth(), 5)
     self.assertEqual(self.c[2, 'Q1'], Label('Gx', 'Q1'))
Exemplo n.º 5
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 def test_construct_from_label_parallelized(self):
     # Do again with parallelization
     labels = [Label('Gi', 'Q0'), Label('Gp', 'Q8')]
     c = circuit.Circuit(layer_labels=labels,
                         line_labels=['Q0', 'Q1', 'Q8'])
     c = c.parallelize()
     self.assertEqual(c.depth(), 1)
     self.assertEqual(c.size(), 2)
Exemplo n.º 6
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    def test_to_pythonstr(self):
        mdl = circuit.Circuit(None, stringrep="Gx^3Gy^2GxGz")

        op_labels = (Label('Gx'), Label('Gy'), Label('Gz'))
        pystr = mdl.to_pythonstr(op_labels)
        self.assertEqual(pystr, "AAABBAC")

        gs2_tup = circuit.Circuit.from_pythonstr(pystr, op_labels)
        self.assertEqual(gs2_tup, tuple(mdl))
Exemplo n.º 7
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 def test_convert_to_quil(self):
     # Check that convert_to_quil runs, doesn't check the output makes sense.
     labels = [
         Label(('Gi', 'Q1')),
         Label(('Gxpi', 'Q1')),
         Label('Gcnot', ('Q1', 'Q2'))
     ]
     c = circuit.Circuit(layer_labels=labels, line_labels=['Q1', 'Q2'])
     s = c.convert_to_quil()
Exemplo n.º 8
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 def test_change_gate_library_missing_gates(self):
     # Change gate library using a dict with some gates missing
     comp = {}
     comp[Label('Gz',
                'Q0')] = circuit.Circuit(layer_labels=[Label('Gx', 'Q0')],
                                         line_labels=['Q0'])
     self.c.change_gate_library(comp, allow_unchanged_gates=True)
     self.assertTrue(Label('Gx', 'Q0')
                     in self.c[0].components)  # c.get_layer(0)
     self.assertTrue(Label('Gy', 'Q1') in self.c[0].components)
Exemplo n.º 9
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 def test_construct_from_label(self):
     # Test initializing a circuit from a non-empty circuit that is a list
     # containing Label objects. Also test that it can have non-integer line_labels
     # and a different identity identifier.
     labels = [Label('Gi', 'Q0'), Label('Gp', 'Q8')]
     c = circuit.Circuit(layer_labels=labels,
                         line_labels=['Q0', 'Q1', 'Q8', 'Q12'])
     # Not parallelized by default, so will be depth 2.
     self.assertEqual(c.depth(), 2)
     self.assertEqual(c.size(), 2)
     self.assertEqual(c.number_of_lines(), 4)
     self.assertEqual(c.line_labels, ('Q0', 'Q1', 'Q8', 'Q12'))
Exemplo n.º 10
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    def test_predicted_error_probability(self):
        # Test the error-probability prediction method
        labels = circuit.Circuit(None, stringrep="[Gx:Q0][Gi:Q0Gi:Q1]")
        c = circuit.Circuit(layer_labels=labels, line_labels=['Q0', 'Q1'])
        infidelity_dict = {}
        infidelity_dict[Label('Gi', 'Q0')] = 0.7
        infidelity_dict[Label('Gi', 'Q1')] = 0.9
        infidelity_dict[Label('Gx', 'Q0')] = 0.8
        infidelity_dict[Label('Gx', 'Q2')] = 0.9

        # TODO fix
        epsilon = c.predicted_error_probability(infidelity_dict)
        self.assertLess(
            abs(epsilon - (1 - (1 - 0.7) * (1 - 0.8) * (1 - 0.9)**2)), 10**-10)
Exemplo n.º 11
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    def test_do_mlgst_alias_model(self):
        aliased_list = [
            Circuit([(x if x != Label("Gx") else Label("GA1")) for x in mdl])
            for mdl in self.lsgstStrings[0]
        ]
        aliased_model = self.mdl_clgst.copy()
        aliased_model.operations['GA1'] = self.mdl_clgst.operations['Gx']
        aliased_model.operations.pop('Gx')

        model = core.do_mlgst(self.ds,
                              aliased_model,
                              aliased_list,
                              minProbClip=1e-4,
                              probClipInterval=(-1e6, 1e6),
                              opLabelAliases={Label('GA1'): Circuit(['Gx'])})
Exemplo n.º 12
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    def test_circuit_layer_by_co2Qgates(self):
        self.skipTest("RB analysis is known to be broken.  Skip tests until it gets fixed.")
        n = self.pspec_1.number_of_qubits
        C01 = Label('Gcnot', ('Q0', 'Q1'))
        C23 = Label('Gcnot', ('Q2', 'Q3'))
        co2Qgates = [[], [C01, C23]]

        layer = sample.circuit_layer_by_co2Qgates(
            self.pspec_1, None, co2Qgates, co2Qgatesprob='uniform',
            twoQprob=1.0, oneQgatenames='all', modelname='clifford'
        )
        self.assertTrue(len(layer) == n or len(layer) == n // 2)

        layer = sample.circuit_layer_by_co2Qgates(
            self.pspec_1, None, co2Qgates, co2Qgatesprob=[0., 1.],
            twoQprob=1.0, oneQgatenames='all', modelname='clifford'
        )
        self.assertEqual(len(layer), n // 2)

        layer = sample.circuit_layer_by_co2Qgates(
            self.pspec_1, None, co2Qgates, co2Qgatesprob=[1., 0.],
            twoQprob=1.0, oneQgatenames=['Gx'], modelname='clifford'
        )
        self.assertEqual(len(layer), n)
        self.assertEqual(layer[0].name, 'Gx')

        co2Qgates = [[], [C23]]
        layer = sample.circuit_layer_by_co2Qgates(
            self.pspec_1, ['Q2', 'Q3'], co2Qgates,
            co2Qgatesprob=[0.25, 0.75], twoQprob=0.5,
            oneQgatenames='all', modelname='clifford'
        )
        # TODO assert correctness

        co2Qgates = [[C01]]
        layer = sample.circuit_layer_by_co2Qgates(
            self.pspec_1, None, co2Qgates, co2Qgatesprob=[1.],
            twoQprob=1.0, oneQgatenames='all', modelname='clifford'
        )
        self.assertEqual(layer[0].name, 'Gcnot')
        self.assertEqual(len(layer), 3)

        # Tests the nested co2Qgates option.
        co2Qgates = [[], [[C01, C23], [C01]]]
        layer = sample.circuit_layer_by_co2Qgates(
            self.pspec_1, None, co2Qgates, co2Qgatesprob='uniform',
            twoQprob=1.0, oneQgatenames='all', modelname='clifford'
        )
Exemplo n.º 13
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    def test_direct_rb_experiment(self):
        self.skipTest("RB analysis is known to be broken.  Skip tests until it gets fixed.")
        lengths = [0, 2, 5]
        circuits_per_length = 2

        # Test DRB experiment with all defaults.
        exp = sample.direct_rb_experiment(self.pspec_2, lengths, circuits_per_length, verbosity=0)
        # TODO assert correctness

        exp = sample.direct_rb_experiment(
            self.pspec_2, lengths, circuits_per_length, subsetQs=[0, 1],
            sampler='pairingQs', cliffordtwirl=False,
            conditionaltwirl=False, citerations=2, partitioned=True,
            verbosity=0
        )
        # TODO assert correctness

        exp = sample.direct_rb_experiment(
            self.pspec_2, lengths, circuits_per_length, subsetQs=[0, 1],
            sampler='co2Qgates',
            samplerargs=[[[], [Label('Gcphase', (0, 1)), ]], [0., 1.]],
            cliffordtwirl=False, conditionaltwirl=False,
            citerations=2, partitioned=True, verbosity=0
        )
        # TODO assert correctness

        exp = sample.direct_rb_experiment(
            self.pspec_2, lengths, circuits_per_length, subsetQs=[0, 1],
            sampler='local', cliffordtwirl=False,
            conditionaltwirl=False, citerations=2, partitioned=True,
            verbosity=0
        )
Exemplo n.º 14
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    def test_simulate(self):
        # TODO optimize
        # Create a pspec, to test the circuit simulator.
        n = 4
        qubit_labels = ['Q' + str(i) for i in range(n)]
        gate_names = ['Gh', 'Gp', 'Gxpi', 'Gpdag', 'Gcnot']  # 'Gi',
        ps = ProcessorSpec(n, gate_names=gate_names, qubit_labels=qubit_labels)

        # Tests the circuit simulator
        c = circuit.Circuit(
            layer_labels=[Label('Gh', 'Q0'),
                          Label('Gcnot', ('Q0', 'Q1'))],
            line_labels=['Q0', 'Q1'])
        out = c.simulate(ps.models['target'])
        self.assertLess(abs(out['00'] - 0.5), 10**-10)
        self.assertLess(abs(out['11'] - 0.5), 10**-10)
Exemplo n.º 15
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 def test_prefix_circuit(self):
     c2 = circuit.Circuit(layer_labels=[Label('Gx', 'Q0')],
                          line_labels=[
                              'Q0',
                          ],
                          editable=True)
     self.c.prefix_circuit(c2)
Exemplo n.º 16
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 def test_append_circuit(self):
     # Test appending
     c2 = circuit.Circuit(layer_labels=[Label('Gx', 'Q0')],
                          line_labels=[
                              'Q0',
                          ],
                          editable=True)
     self.c.append_circuit(c2)
Exemplo n.º 17
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 def test_insert_layer(self):
     # Test layer insertion
     layer = [
         Label('Gx', 'Q1'),
     ]
     self.c.insert_layer(layer, 1)
     self.assertEqual(self.c.size(), 9)
     self.assertEqual(self.c.depth(), 6)
     self.assertEqual(self.c[1], Label('Gx', 'Q1'))
     self.c.insert_layer([], 1)
     self.assertTrue(len(self.c[1, ('Q0', 'Q1')].components) == 0)
     self.assertTrue(len(self.c[1, 'Q0'].components) == 0)
     self.assertFalse(len(self.c[2, 'Q1'].components) == 0)
     self.assertFalse(self.c.is_line_idling('Q1'))
     self.c.append_idling_lines(['Q3'])
     self.assertFalse(self.c.is_line_idling('Q0'))
     self.assertFalse(self.c.is_line_idling('Q1'))
     self.assertTrue(self.c.is_line_idling('Q3'))
Exemplo n.º 18
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 def test_do_iterative_mlgst_circuit_weights_dict(self):
     model = core.do_iterative_mlgst(self.ds,
                                     self.mdl_clgst,
                                     self.lsgstStrings,
                                     minProbClip=1e-4,
                                     probClipInterval=(-1e2, 1e2),
                                     circuitWeightsDict={
                                         (Label('Gx'), ): 2.0
                                     })
Exemplo n.º 19
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 def test_insert_circuit_with_qubit_subset(self):
     # Test inserting a circuit that is on *less* qubits.
     c2 = circuit.Circuit(layer_labels=[Label('Gx', 'Q0')],
                          line_labels=[
                              'Q0',
                          ])
     self.c.insert_circuit(c2, 1)
     self.assertEqual(self.c.line_labels, ('Q0', 'Q1'))
     self.assertEqual(self.c.number_of_lines(), 2)
Exemplo n.º 20
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 def test_delete_layers(self):
     # Test layer deletion
     layer = [
         Label('Gx', 'Q1'),
     ]
     c_copy = self.c.copy()
     c_copy.insert_layer(layer, 1)
     c_copy.delete_layers([1])
     self.assertEqual(self.c, c_copy)
Exemplo n.º 21
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    def test_random_circuit(self):
        self.skipTest("RB analysis is known to be broken.  Skip tests until it gets fixed.")
        C01 = Label('Gcnot', ('Q0', 'Q1'))
        C23 = Label('Gcnot', ('Q2', 'Q3'))
        co2Qgates = [[], [[C01, C23], [C01, ]]]

        circuit = sample.random_circuit(self.pspec_1, length=100, sampler='Qelimination')
        self.assertEqual(circuit.depth(), 100)

        circuit = sample.random_circuit(self.pspec_2, length=100, sampler='Qelimination',
                                        samplerargs=[0.1, ], addlocal=True)
        self.assertEqual(circuit.depth(), 201)
        self.assertLessEqual(len(circuit.get_layer(0)), self.pspec_2.number_of_qubits)

        circuit = sample.random_circuit(self.pspec_1, length=100, sampler='pairingQs')
        # TODO assert correctness

        circuit = sample.random_circuit(
            self.pspec_1, length=10, sampler='pairingQs',
            samplerargs=[0.1, ['Gx', ]]
        )
        # TODO assert correctness

        circuit = sample.random_circuit(self.pspec_1, length=100, sampler='co2Qgates', samplerargs=[co2Qgates])
        # TODO assert correctness

        circuit = sample.random_circuit(
            self.pspec_1, length=100, sampler='co2Qgates',
            samplerargs=[co2Qgates, [0.1, 0.2], 0.1], addlocal=True,
            lsargs=[['Gx', ]]
        )
        self.assertEqual(circuit.depth(), 201)

        circuit = sample.random_circuit(self.pspec_1, length=5, sampler='local')
        self.assertEqual(circuit.depth(), 5)

        circuit = sample.random_circuit(self.pspec_1, length=5, sampler='local', samplerargs=[['Gx']])
        self.assertEqual(circuit[0, 'Q0'].name, 'Gx')
Exemplo n.º 22
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    def test_translate_circuit_list(self):
        orig_list = cc.circuit_list([('Gx', 'Gx'), ('Gx', 'Gy'),
                                     ('Gx', 'Gx', 'Gx'), ('Gy', 'Gy'),
                                     ('Gi', )])

        list0 = cc.translate_circuit_list(orig_list, None)
        self.assertEqual(list0, orig_list)

        list1 = cc.translate_circuit_list(orig_list, {
            Label('Gx'): (Label('Gx2'), ),
            Label('Gy'): (Label('Gy'), )
        })
        expected_list1 = cc.circuit_list([('Gx2', 'Gx2'), ('Gx2', 'Gy'),
                                          ('Gx2', 'Gx2', 'Gx2'), ('Gy', 'Gy'),
                                          ('Gi', )])
        self.assertEqual(list1, expected_list1)

        list2 = cc.translate_circuit_list(orig_list, {
            Label('Gi'): (Label('Gx'), Label('Gx'), Label('Gx'), Label('Gx'))
        })
        expected_list2 = cc.circuit_list([('Gx', 'Gx'), ('Gx', 'Gy'),
                                          ('Gx', 'Gx', 'Gx'), ('Gy', 'Gy'),
                                          ('Gx', 'Gx', 'Gx', 'Gx')])
        self.assertEqual(list2, expected_list2)
Exemplo n.º 23
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 def setUp(self):
     self.opLabels = [Label('Gx'), Label('Gy')]
     self.strs = cc.circuit_list([('Gx', ), ('Gy', ), ('Gx', 'Gx')])
     self.germs = cc.circuit_list([('Gx', 'Gy'), ('Gy', 'Gy')])
     self.testFidPairs = [(0, 1)]
     self.testFidPairsDict = {
         (Label('Gx'), Label('Gy')): [(0, 0), (0, 1)],
         (Label('Gy'), Label('Gy')): [(0, 0)]
     }
     self.ds = DataSet(outcomeLabels=['0',
                                      '1'])  # a dataset that is missing
     self.ds.add_count_dict(('Gx', ), {
         '0': 10,
         '1': 90
     })  # almost all our strings...
     self.ds.done_adding_data()
Exemplo n.º 24
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 def test_circuit_layer_of_oneQgates(self):
     self.skipTest("RB analysis is known to be broken.  Skip tests until it gets fixed.")
     layer = sample.circuit_layer_of_oneQgates(
         self.pspec_1, oneQgatenames='all', pdist='uniform',
         modelname='clifford'
     )
     self.assertEqual(len(layer), self.pspec_1.number_of_qubits)
     layer = sample.circuit_layer_of_oneQgates(
         self.pspec_1, subsetQs=['Q1', 'Q2'],
         oneQgatenames=['Gx', 'Gy'], pdist=[1., 0.],
         modelname='clifford'
     )
     self.assertEqual(len(layer), 2)
     self.assertEqual(layer[0].name, 'Gx')
     layer = sample.circuit_layer_of_oneQgates(
         self.pspec_1, subsetQs=['Q2'], oneQgatenames=['Gx'],
         pdist=[3.], modelname='clifford'
     )
     self.assertEqual(layer[0], Label('Gx', 'Q2'))
     self.assertEqual(len(layer), 1)
     layer = sample.circuit_layer_of_oneQgates(
         self.pspec_1, oneQgatenames=['Gx'], pdist='uniform',
         modelname='clifford'
     )
Exemplo n.º 25
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 def test_compress_depth(self):
     ls = [
         Label('H', 1),
         Label('P', 1),
         Label('P', 1),
         Label(()),
         Label('CNOT', (2, 3))
     ]
     ls += [Label('HP', 1), Label('PH', 1), Label('CNOT', (1, 2))]
     ls += [Label(()), Label(()), Label('CNOT', (1, 2))]
     labels = circuit.Circuit(ls)
     c = circuit.Circuit(layer_labels=labels, num_lines=4, editable=True)
     c.compress_depth(verbosity=0)
     self.assertEqual(c.depth(), 7)
     # Get a dictionary that relates H, P gates etc.
     oneQrelations = symplectic.oneQclifford_symplectic_group_relations()
     c.compress_depth(oneQgate_relations=oneQrelations)
     self.assertEqual(c.depth(), 3)
Exemplo n.º 26
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    def test_change_gate_library(self):
        # Change gate library using an ordinary dict with every gate as a key. (we test
        # changing gate library using a CompilationLibrary elsewhere in the tests).
        labels = circuit.Circuit(
            None, stringrep="[Gz:Q0Gy:Q1][Gy:Q0Gz:Q1]Gz:Q0Gi:Q1")
        c = circuit.Circuit(layer_labels=labels,
                            line_labels=['Q0', 'Q1'],
                            editable=True)
        comp = {}
        comp[Label('Gz',
                   'Q0')] = circuit.Circuit(layer_labels=[Label('Gx', 'Q0')],
                                            line_labels=['Q0'])
        comp[Label('Gy',
                   'Q0')] = circuit.Circuit(layer_labels=[Label('Gx', 'Q0')],
                                            line_labels=['Q0'])
        comp[Label('Gz',
                   'Q1')] = circuit.Circuit(layer_labels=[Label('Gx', 'Q1')],
                                            line_labels=['Q1'])
        comp[Label('Gy',
                   'Q1')] = circuit.Circuit(layer_labels=[Label('Gx', 'Q1')],
                                            line_labels=['Q1'])
        comp[Label('Gi',
                   'Q1')] = circuit.Circuit(layer_labels=[Label('Gi', 'Q1')],
                                            line_labels=['Q1'])

        c.change_gate_library(comp)
        self.assertTrue(Label('Gx', 'Q0') in c[0].components)
Exemplo n.º 27
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 def test_insert_circuit_label_collision(self):
     # Test inserting a circuit when they are over the same labels.
     c_copy = self.c.copy()
     self.c.insert_circuit(c_copy, 2)
     self.assertTrue(Label('Gx', 'Q0') in self.c[2].components)
Exemplo n.º 28
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 def test_empty_tuple_makes_idle_layer(self):
     c = circuit.Circuit(['Gi', Label(())])
     self.assertEqual(len(c), 2)
Exemplo n.º 29
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 def test_replace_layer_with_layer(self):
     # Test replacing a layer with a layer.
     newlayer = [Label('Gx', 'Q0')]
     self.c[1] = newlayer
     self.assertEqual(self.c.depth(), 5)
Exemplo n.º 30
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fixture_2Q = Namespace(
    n=2,
    qubit_labels=['Q0', 'Q1'],
    availability={'Gcnot': [('Q0', 'Q1')]},
    gate_names=['Gh', 'Gp', 'Gxpi', 'Gpdag', 'Gcnot'],
    # generated as before:
    clifford_sym=np.array([[0, 1, 1, 1], [1, 0, 1, 1], [1, 0, 1, 0],
                           [0, 1, 0, 1]]),
    clifford_phase=np.array([2, 0, 1, 3]))
fixture_2Q.pspec = ProcessorSpec(fixture_2Q.n,
                                 gate_names=fixture_2Q.gate_names,
                                 availability=fixture_2Q.availability,
                                 qubit_labels=fixture_2Q.qubit_labels)
# Totally arbitrary CNOT circuit
fixture_2Q.cnot_circuit = Circuit(layer_labels=[
    Label('CNOT', ('Q1', 'Q0')),
    Label('CNOT', ('Q1', 'Q0')),
    Label('CNOT', ('Q0', 'Q1')),
    Label('CNOT', ('Q1', 'Q0'))
],
                                  line_labels=fixture_2Q.qubit_labels)
fixture_2Q.cnot_circuit_sym, fixture_2Q.cnot_circuit_phase = \
    symplectic.symplectic_rep_of_clifford_circuit(fixture_2Q.cnot_circuit)

fixture_3Q = Namespace(
    n=3,
    qubit_labels=['Q0', 'Q1', 'Q2'],
    availability={'Gcnot': [('Q0', 'Q1'), ('Q1', 'Q2')]},
    gate_names=['Gh', 'Gp', 'Gxpi', 'Gpdag', 'Gcnot'],
    # generated as before:
    clifford_sym=np.array([[0, 0, 1, 1, 0, 1], [0, 0, 0, 0, 1, 0],