def test_object_deletion(self):
"""
Checks that Connectors do not inhibit clean object deletion.
"""
# deletion without explicit garbage collection
gc.collect()
rel = sumpf.modules.RelabelSignal()
rel.SetSignal(sumpf.Signal())
del rel
self.assertEqual(gc.collect(), 0)
# sumpf.collect_garbage
sumpf.connect(self.obj1.GetValue, self.obj2.SetValue)
sumpf.connect(self.obj2.GetText, self.obj1.SetText)
sumpf.disconnect_all(self.obj1)
gc.collect()
current_instance_count = ExampleClass.instance_count
sumpf.destroy_connectors(self.obj1)
del self.obj1
gc.collect()
if ExampleClass.instance_count != current_instance_count - 1:
for o in gc.garbage:
if isinstance(o, ExampleClass):
collected = sumpf.collect_garbage()
self.assertIsInstance(collected, int) # sumpf.collect_garbage shall return the integer number of collected items
self.assertEqual(gc.garbage, []) # garbage collection should have removed all garbage
return
self.fail("The object has neither been deleted, nor has it been marked as garbage")
def Destroy(self):
"""
An override of the Window's Destroy method.
This method also destroys the connectors, so that this dialog can be
easily garbage collected.
"""
sumpf.destroy_connectors(self)
Window.Destroy(self)
def destroy_connector_references():
"""
A garbage collector function that helps to delete objects with connectors.
Normally this is not needed, but when the object has a destructor method, the
garbage collector does not know in which order it shall delete the object and
the connector. This garbage collector function breaks this dependency cycle.
"""
for obj in gc.garbage:
sumpf.destroy_connectors(obj)
def Delete(self):
"""
Shuts down the jack connection and prepares the instance for garbage collection.
"""
if not self.__deleted:
jack.deactivate()
jack.detach()
sumpf.destroy_connectors(self)
BaseIO.Delete(self)
self.__deleted = True
def GetOutput(self):
# get lengths from durations
if self.__silence_duration != 0.0:
d2l = sumpf.modules.DurationToLength(duration=self.__fade_out, samplingrate=self.__sampling_rate)
fade_out_length = d2l.GetLength()
d2l.SetDuration(duration=self.__fade_in)
fade_in_length = d2l.GetLength()
d2l.SetDuration(self.__silence_duration)
silence_length = d2l.GetLength()
sumpf.destroy_connectors(d2l)
sweep_length = self.__length - silence_length
# get signals
slg = sumpf.modules.SilenceGenerator(samplingrate=self.__sampling_rate, length=silence_length)
silence = slg.GetSignal()
sumpf.destroy_connectors(slg)
if (fade_out_length == 0.0 and fade_in_length ==0.0):
interval = None
else:
interval = (fade_in_length, -fade_out_length)
swg = sumpf.modules.SweepGenerator(start_frequency=self.__start_frequency,
stop_frequency=self.__stop_frequency,
function=self.__function,
interval=interval,
samplingrate=self.__sampling_rate,
length=sweep_length)
sweep = swg.GetSignal()
sumpf.destroy_connectors(swg)
if fade_in_length == 0.0:
raise_interval = None
else:
raise_interval = (0,fade_in_length)
wng = sumpf.modules.WindowGenerator(raise_interval= raise_interval,
fall_interval=(-fade_out_length, -1),
function=sumpf.modules.WindowGenerator.Hanning(),
samplingrate=self.__sampling_rate,
length=sweep_length)
window = wng.GetSignal()
sumpf.destroy_connectors(wng)
# combine signals
windowed_sweep = sweep * window
cat = sumpf.modules.ConcatenateSignals(signal1=windowed_sweep, signal2=silence)
concatenated_sweep = cat.GetOutput()
sumpf.destroy_connectors(cat)
else:
print "normal sweep"
concatenated_sweep = sumpf.modules.SweepGenerator(self.__start_frequency,self.__stop_frequency,
samplingrate=self.__sampling_rate,
length=self.__length,function=self.__function).GetSignal()
self.__sweep_signal = sumpf.modules.AmplifySignal(concatenated_sweep)
return self.__sweep_signal.GetOutput()
def get_impulse_response(excitation, response, start_freq, stop_freq):
"""
Calculate the impulse response of the system
:param excitation: the input signal to the system
:param response: the output signal of the system
:param start_freq: the start frequency
:param stop_freq: the stop frequency
:return: the impulse response of the system
"""
transferfunction = get_transfer_function(excitation, response, start_freq,
stop_freq)
ifft = sumpf.modules.InverseFourierTransform(spectrum=transferfunction)
result = ifft.GetSignal()
sumpf.destroy_connectors(ifft)
return result
def get_transfer_function(excitation,
response,
start_freq=20.0,
stop_freq=20000.0):
"""
Calculate the transfer function of the system
:param excitation: the input signal to the system
:param response: the output signal of the system
:param start_freq: the start frequency of the input
:param stop_freq: the stop frequency of the input
:return: the transfer function of the system
"""
fft = sumpf.modules.FourierTransform(signal=excitation)
excitation_spectrum = fft.GetSpectrum()
fft.SetSignal(response)
response_spectrum = fft.GetSpectrum()
sumpf.destroy_connectors(fft)
rgi = sumpf.modules.RegularizedSpectrumInversion(
spectrum=excitation_spectrum,
start_frequency=start_freq,
stop_frequency=stop_freq)
regularized = rgi.GetOutput()
sumpf.destroy_connectors(rgi)
if len(regularized.GetChannels()) == 1 and len(
response_spectrum.GetChannels()) != 1:
cpy = sumpf.modules.CopySpectrumChannels(
input=regularized,
channelcount=len(response_spectrum.GetChannels()))
regularized = cpy.GetOutput()
sumpf.destroy_connectors(cpy)
cls = sumpf.modules.CopyLabelsToSpectrum(data_input=response_spectrum *
regularized,
label_input=response)
relabeled = cls.GetOutput()
sumpf.destroy_connectors(cls)
return relabeled
def Destroy(self):
"""
Destroys this ProgressIndicator instance, so it can be easily garbage
collected.
"""
sumpf.destroy_connectors(self)
