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- import numpy as np
- from abp import qi
- from abp import GraphState
-
-
- def test_init():
- """ Can you initialize some qubits """
- psi = qi.CircuitModel(5)
- assert psi.d == 32
-
-
- def test_single_qubit_stuff():
- """ Try some sensible single-qubit things """
- psi = qi.CircuitModel(2)
- psi.act_local_rotation(0, qi.px)
- assert np.allclose(psi.state[1], 1)
- psi.act_local_rotation(0, qi.px)
- assert np.allclose(psi.state[0], 1)
- psi.act_local_rotation(0, qi.px)
- psi.act_local_rotation(0, qi.pz)
- psi.act_local_rotation(0, qi.px)
- assert np.allclose(psi.state[0], -1)
-
-
- def test_further_single_qubit_stuff():
- """ Try some sensible single-qubit things """
- psi = qi.CircuitModel(2)
- psi.act_local_rotation(0, qi.py)
- psi.act_local_rotation(1, qi.py)
- psi.act_local_rotation(0, qi.pz)
- psi.act_local_rotation(1, qi.py)
- psi.act_local_rotation(0, qi.hadamard)
- psi.act_local_rotation(0, qi.pz)
- psi.act_local_rotation(0, qi.px)
-
-
- def test_more_single_qubit_stuff():
- """ Try some sensible single-qubit things """
- psi = qi.CircuitModel(2)
- psi.act_local_rotation(0, qi.px)
- psi.act_local_rotation(1, qi.px)
- psi.act_cz(0, 1)
-
-
- def test_equality():
- """ Test that equality succeeds / fails as desired """
- a = qi.CircuitModel(2)
- b = qi.CircuitModel(2)
- assert a == b
- a.act_local_rotation(0, qi.px)
- assert a != b
-
-
- def test_hadamard():
- """ What does CZ do ? """
- psi = qi.CircuitModel(3)
- psi.act_hadamard(0)
- psi.act_hadamard(1)
- assert np.allclose(psi.state, np.array([[1, 1, 1, 1, 0, 0, 0, 0]]).T / 2.)
- psi.act_hadamard(1)
- psi.act_hadamard(0)
- psi.act_hadamard(2)
- assert np.allclose(
- psi.state, qi.ir2 * np.array([[1, 0, 0, 0, 1, 0, 0, 0]]).T)
-
-
- def test_cz():
- """ What does CZ do ? """
- psi = qi.CircuitModel(2)
- psi.act_hadamard(0)
- psi.act_hadamard(1)
- psi.act_cz(0, 1)
- assert np.allclose(psi.state, qi.bond)
-
-
- def test_local_rotation():
- """ Do local rotations work okay? ? """
- psi = qi.CircuitModel(2)
- psi.act_local_rotation(0, qi.ha)
- psi.act_local_rotation(0, qi.ha)
- assert np.allclose(psi.state[0], 1)
-
- psi.act_local_rotation(0, qi.ha)
- psi.act_local_rotation(1, qi.ha)
- psi.act_local_rotation(0, qi.ha)
- psi.act_local_rotation(1, qi.ha)
- assert np.allclose(psi.state[0], 1)
-
-
- def test_dumbness():
- """ Check that I haven't done something really dumb """
- 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)
-
-
- def test_to_state_vector_single_qubit():
- """ Test some single-qubit stuff """
- g = GraphState()
- g.add_node(0)
- g.add_node(1)
- g.act_local_rotation(0, "hadamard")
- 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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