def test_render(self) -> None:
wf1 = DummyWaveform(duration=19)
wf2 = DummyWaveform(duration=21)
block = InstructionBlock()
block.add_instruction_exec(wf1)
block.add_instruction_exec(wf2)
plotter = Plotter(sample_rate=0.5)
times, voltages = plotter.render(block.compile_sequence())
wf1_expected = [([0, 2, 4, 6, 8, 10, 12, 14, 16, 18], 0)]
wf2_expected = [([20, 22, 24, 26, 28, 30, 32, 34, 36, 38, 40], 1)]
expected_result = list(range(0, 41, 2))
self.assertEqual(wf1_expected, wf1.sample_calls)
self.assertEqual(wf2_expected, wf2.sample_calls)
self.assertEqual(expected_result, list(times))
self.assertEqual(expected_result, list(voltages))
def test_render(self) -> None:
wf1 = DummyWaveform(duration=19)
wf2 = DummyWaveform(duration=21)
block = InstructionBlock()
block.add_instruction_exec(wf1)
block.add_instruction_exec(wf2)
plotter = Plotter(sample_rate=0.5)
times, voltages = plotter.render(block)
wf1_expected = [([0, 2, 4, 6, 8, 10, 12, 14, 16, 18], 0)]
wf2_expected = [([20, 22, 24, 26, 28, 30, 32, 34, 36, 38, 40], 1)]
expected_result = numpy.array([range(0, 41, 2)])
self.assertEqual(wf1_expected, wf1.sample_calls)
self.assertEqual(wf2_expected, wf2.sample_calls)
self.assertTrue(numpy.all(expected_result == times))
self.assertTrue(numpy.all(expected_result == voltages))
self.assertEqual(expected_result.shape, voltages.shape)
def integrated_test_with_sequencer_and_pulse_templates(self) -> None:
# Setup test data
square = TablePulseTemplate()
square.add_entry('up', 'v', 'hold')
square.add_entry('down', 0, 'hold')
square.add_entry('length', 0)
mapping1 = {
'up': 'uptime',
'down': 'uptime + length',
'v': 'voltage',
'length': '0.5 * pulse_length'
}
outer_parameters = ['uptime', 'length', 'pulse_length', 'voltage']
parameters = {}
parameters['uptime'] = 5
parameters['length'] = 10
parameters['pulse_length'] = 100
parameters['voltage'] = 10
sequence = SequencePulseTemplate([(square, mapping1),
(square, mapping1)],
outer_parameters)
# run the sequencer and render the plot
sample_rate = 20
plotter = Plotter(sample_rate=sample_rate)
sequencer = Sequencer(plotter)
sequencer.push(sequence, parameters)
block = sequencer.build()
times, voltages = plotter.render(block)
# compute expected values
expected_times = numpy.linspace(0, 100, sample_rate)
expected_voltages = numpy.zeros_like(expected_times)
expected_voltages[100:300] = numpy.ones(200) * parameters['voltage']
# compare
self.assertEqual(expected_times, times)
self.assertEqual(expected_voltages, voltages)
def integrated_test_with_sequencer_and_pulse_templates(self) -> None:
# Setup test data
square = TablePulseTemplate()
square.add_entry('up', 'v', 'hold')
square.add_entry('down', 0, 'hold')
square.add_entry('length', 0)
mapping1 = {
'up': 'uptime',
'down': 'uptime + length',
'v': 'voltage',
'length': '0.5 * pulse_length'
}
outer_parameters = ['uptime', 'length', 'pulse_length', 'voltage']
parameters = {}
parameters['uptime'] = 5
parameters['length'] = 10
parameters['pulse_length'] = 100
parameters['voltage'] = 10
sequence = SequencePulseTemplate([(square, mapping1), (square, mapping1)], outer_parameters)
# run the sequencer and render the plot
sample_rate = 20
plotter = Plotter(sample_rate=sample_rate)
sequencer = Sequencer(plotter)
sequencer.push(sequence, parameters)
block = sequencer.build()
times, voltages = plotter.render(block)
# compute expected values
expected_times = numpy.linspace(0, 100, sample_rate)
expected_voltages = numpy.zeros_like(expected_times)
expected_voltages[100:300] = numpy.ones(200) * parameters['voltage']
# compare
self.assertEqual(expected_times, times)
self.assertEqual(expected_voltages, voltages)
def test_render_no_waveforms(self) -> None:
self.assertEqual(([], []), Plotter().render(InstructionBlock()))
def test_render_unsupported_instructions(self) -> None:
block = InstructionBlock()
block.add_instruction(DummyInstruction())
plotter = Plotter()
with self.assertRaises(NotImplementedError):
plotter.render(block)
def test_render_unsupported_instructions(self) -> None:
block = InstructionBlock()
block.add_instruction(DummyInstruction())
plotter = Plotter()
with self.assertRaises(NotImplementedError):
plotter.render(block.compile_sequence())
