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@@ -29,21 +29,31 @@ def test_hadamard_only_multiqubit(n=6): |
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def test_all_multiqubit(n=4): |
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def test_all_multiqubit(n=4): |
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""" A multi qubit test with arbitrary local rotations """ |
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""" A multi qubit test with arbitrary local rotations """ |
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for qqq in range(REPEATS): |
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g = GraphState(range(n)) |
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c = CircuitModel(n) |
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for i in range(10): |
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qubit = np.random.randint(0, n - 1) |
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rotation = np.random.randint(0, 24 - 1) |
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g.act_local_rotation(qubit, rotation) |
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c.act_local_rotation(qubit, clifford.unitaries[rotation]) |
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assert g.to_state_vector() == c |
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for i in range(1): |
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a, b = np.random.randint(0, n-1, 2) |
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if a != b: |
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g.act_cz(a, b) |
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c.act_cz(a, b) |
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assert g.to_state_vector() == c |
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g = GraphState(range(n)) |
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c = CircuitModel(n) |
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for i in range(10): |
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qubit = np.random.randint(0, n - 1) |
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rotation = np.random.randint(0, 24 - 1) |
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g.act_local_rotation(qubit, rotation) |
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c.act_local_rotation(qubit, clifford.unitaries[rotation]) |
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assert g.to_state_vector() == c |
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for i in range(100): |
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a, b = np.random.randint(0, n-1, 2) |
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if a != b: |
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g.act_cz(a, b) |
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c.act_cz(a, b) |
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assert np.allclose(np.sum(np.abs(c.state)**2), 1) |
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assert np.allclose(np.sum(np.abs(g.to_state_vector().state)**2), 1) |
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if not g.to_state_vector() == c: |
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print g |
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print a, b |
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print "Circuit:" |
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print g.to_state_vector() |
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print "Graph:" |
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print c |
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raise ValueError |
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assert g.to_state_vector() == c |