class PlotImpz_UI(QWidget):
"""
Create the UI for the PlotImpz class
"""
# incoming: not implemented at the moment, update_N is triggered directly
# by plot_impz
# sig_rx = pyqtSignal(object)
# outgoing: from various UI elements to PlotImpz ('ui_changed':'xxx')
sig_tx = pyqtSignal(object)
# outgoing to local fft window
sig_tx_fft = pyqtSignal(object)
def __init__(self, parent):
"""
Pass instance `parent` of parent class (FilterCoeffs)
"""
super(PlotImpz_UI, self).__init__(parent)
"""
Intitialize the widget, consisting of:
- top chkbox row
- coefficient table
- two bottom rows with action buttons
"""
# initial settings
self.N_start = 0
self.N_user = 0
self.N = 0
# time
self.plt_time_resp = "Stem"
self.plt_time_stim = "None"
self.plt_time_stmq = "None"
self.plt_time_spgr = "None"
self.bottom_t = -80 # initial value for log. scale (time)
self.nfft_spgr_time = 256 # number of fft points per spectrogram segment
self.ovlp_spgr_time = 128 # number of overlap points between spectrogram segments
self.mode_spgr_time = "magnitude"
# stimuli
self.stim = "Impulse"
self.chirp_method = 'Linear'
self.noise = "None"
self.f1 = 0.02
self.f2 = 0.03
self.A1 = 1.0
self.A2 = 0.0
self.phi1 = self.phi2 = 0
self.noi = 0.1
self.noise = 'none'
self.DC = 0.0
self.stim_formula = "A1 * abs(sin(2 * pi * f1 * n))"
# frequency
self.plt_freq_resp = "Line"
self.plt_freq_stim = "None"
self.plt_freq_stmq = "None"
self.bottom_f = -120 # initial value for log. scale
self.param = None
# dictionary for fft window settings
self.win_dict = fb.fil[0]['win_fft']
self.fft_window = None # handle for FFT window pop-up widget
self.window_name = "Rectangular"
self._construct_UI()
self._enable_stim_widgets()
self.update_N(emit=False) # also updates window function
self._update_noi()
def _construct_UI(self):
# ----------- ---------------------------------------------------
# Run control widgets
# ---------------------------------------------------------------
self.chk_auto_run = QCheckBox("Auto", self)
self.chk_auto_run.setObjectName("chk_auto_run")
self.chk_auto_run.setToolTip("<span>Update response automatically when "
"parameters have been changed.</span>")
self.chk_auto_run.setChecked(True)
self.but_run = QPushButton(self)
self.but_run.setText("RUN")
self.but_run.setToolTip("Run simulation")
self.but_run.setEnabled(not self.chk_auto_run.isChecked())
self.cmb_sim_select = QComboBox(self)
self.cmb_sim_select.addItems(["Float","Fixpoint"])
qset_cmb_box(self.cmb_sim_select, "Float")
self.cmb_sim_select.setToolTip("<span>Simulate floating-point or fixpoint response."
"</span>")
self.lbl_N_points = QLabel(to_html("N", frmt='bi') + " =", self)
self.led_N_points = QLineEdit(self)
self.led_N_points.setText(str(self.N))
self.led_N_points.setToolTip("<span>Number of displayed data points. "
"<i>N</i> = 0 tries to choose for you.</span>")
self.lbl_N_start = QLabel(to_html("N_0", frmt='bi') + " =", self)
self.led_N_start = QLineEdit(self)
self.led_N_start.setText(str(self.N_start))
self.led_N_start.setToolTip("<span>First point to plot.</span>")
self.chk_fx_scale = QCheckBox("Int. scale", self)
self.chk_fx_scale.setObjectName("chk_fx_scale")
self.chk_fx_scale.setToolTip("<span>Display data with integer (fixpoint) scale.</span>")
self.chk_fx_scale.setChecked(False)
self.chk_stim_options = QCheckBox("Stim. Options", self)
self.chk_stim_options.setObjectName("chk_stim_options")
self.chk_stim_options.setToolTip("<span>Show stimulus options.</span>")
self.chk_stim_options.setChecked(True)
self.but_fft_win = QPushButton(self)
self.but_fft_win.setText("WIN FFT")
self.but_fft_win.setToolTip('<span> time and frequency response of FFT Window '
'(can be modified in the "Frequency" tab)</span>')
self.but_fft_win.setCheckable(True)
self.but_fft_win.setChecked(False)
layH_ctrl_run = QHBoxLayout()
layH_ctrl_run.addWidget(self.but_run)
#layH_ctrl_run.addWidget(self.lbl_sim_select)
layH_ctrl_run.addWidget(self.cmb_sim_select)
layH_ctrl_run.addWidget(self.chk_auto_run)
layH_ctrl_run.addStretch(1)
layH_ctrl_run.addWidget(self.lbl_N_start)
layH_ctrl_run.addWidget(self.led_N_start)
layH_ctrl_run.addStretch(1)
layH_ctrl_run.addWidget(self.lbl_N_points)
layH_ctrl_run.addWidget(self.led_N_points)
layH_ctrl_run.addStretch(2)
layH_ctrl_run.addWidget(self.chk_fx_scale)
layH_ctrl_run.addStretch(2)
layH_ctrl_run.addWidget(self.chk_stim_options)
layH_ctrl_run.addStretch(2)
layH_ctrl_run.addWidget(self.but_fft_win)
layH_ctrl_run.addStretch(10)
#layH_ctrl_run.setContentsMargins(*params['wdg_margins'])
self.wdg_ctrl_run = QWidget(self)
self.wdg_ctrl_run.setLayout(layH_ctrl_run)
# --- end of run control ----------------------------------------
# ----------- ---------------------------------------------------
# Controls for time domain
# ---------------------------------------------------------------
plot_styles_list = ["None","Dots","Line","Line*","Stem","Stem*","Step","Step*"]
lbl_plt_time_title = QLabel("<b>View:</b>", self)
self.lbl_plt_time_stim = QLabel(to_html("Stimulus x", frmt='bi'), self)
self.cmb_plt_time_stim = QComboBox(self)
self.cmb_plt_time_stim.addItems(plot_styles_list)
qset_cmb_box(self.cmb_plt_time_stim, self.plt_time_stim)
self.cmb_plt_time_stim.setToolTip("<span>Plot style for stimulus.</span>")
self.lbl_plt_time_stmq = QLabel(to_html(" Fixp. Stim. x_Q", frmt='bi'), self)
self.cmb_plt_time_stmq = QComboBox(self)
self.cmb_plt_time_stmq.addItems(plot_styles_list)
qset_cmb_box(self.cmb_plt_time_stmq, self.plt_time_stmq)
self.cmb_plt_time_stmq.setToolTip("<span>Plot style for <em>fixpoint</em> (quantized) stimulus.</span>")
lbl_plt_time_resp = QLabel(to_html(" Response y", frmt='bi'), self)
self.cmb_plt_time_resp = QComboBox(self)
self.cmb_plt_time_resp.addItems(plot_styles_list)
qset_cmb_box(self.cmb_plt_time_resp, self.plt_time_resp)
self.cmb_plt_time_resp.setToolTip("<span>Plot style for response.</span>")
lbl_win_time = QLabel(to_html(" FFT Window", frmt='bi'), self)
self.chk_win_time = QCheckBox(self)
self.chk_win_time.setObjectName("chk_win_time")
self.chk_win_time.setToolTip('<span>Show FFT windowing function (can be modified in the "Frequency" tab).</span>')
self.chk_win_time.setChecked(False)
lbl_log_time = QLabel(to_html("dB", frmt='b'), self)
self.chk_log_time = QCheckBox(self)
self.chk_log_time.setObjectName("chk_log_time")
self.chk_log_time.setToolTip("<span>Logarithmic scale for y-axis.</span>")
self.chk_log_time.setChecked(False)
self.lbl_log_bottom_time = QLabel(to_html("min =", frmt='bi'), self)
self.lbl_log_bottom_time.setVisible(True)
self.led_log_bottom_time = QLineEdit(self)
self.led_log_bottom_time.setText(str(self.bottom_t))
self.led_log_bottom_time.setToolTip("<span>Minimum display value for time "
"and spectrogram plots with log. scale.</span>")
self.led_log_bottom_time.setVisible(True)
lbl_plt_time_spgr = QLabel(to_html(" Spectrogram", frmt='bi'), self)
self.cmb_plt_time_spgr = QComboBox(self)
self.cmb_plt_time_spgr.addItems(["None", "x[n]", "x_q[n]", "y[n]"])
qset_cmb_box(self.cmb_plt_time_spgr, self.plt_time_spgr)
self.cmb_plt_time_spgr.setToolTip("<span>Show Spectrogram for selected signal.</span>")
spgr_en = self.plt_time_spgr != "None"
self.lbl_log_spgr_time = QLabel(to_html(" dB", frmt='b'), self)
self.lbl_log_spgr_time.setVisible(spgr_en)
self.chk_log_spgr_time = QCheckBox(self)
self.chk_log_spgr_time.setObjectName("chk_log_spgr")
self.chk_log_spgr_time.setToolTip("<span>Logarithmic scale for spectrogram.</span>")
self.chk_log_spgr_time.setChecked(True)
self.chk_log_spgr_time.setVisible(spgr_en)
self.lbl_nfft_spgr_time = QLabel(to_html(" N_FFT =", frmt='bi'), self)
self.lbl_nfft_spgr_time.setVisible(spgr_en)
self.led_nfft_spgr_time = QLineEdit(self)
self.led_nfft_spgr_time.setText(str(self.nfft_spgr_time))
self.led_nfft_spgr_time.setToolTip("<span>Number of FFT points per spectrogram segment.</span>")
self.led_nfft_spgr_time.setVisible(spgr_en)
self.lbl_ovlp_spgr_time = QLabel(to_html(" N_OVLP =", frmt='bi'), self)
self.lbl_ovlp_spgr_time.setVisible(spgr_en)
self.led_ovlp_spgr_time = QLineEdit(self)
self.led_ovlp_spgr_time.setText(str(self.ovlp_spgr_time))
self.led_ovlp_spgr_time.setToolTip("<span>Number of overlap data points between spectrogram segments.</span>")
self.led_ovlp_spgr_time.setVisible(spgr_en)
self.lbl_mode_spgr_time = QLabel(to_html(" Mode", frmt='bi'), self)
self.lbl_mode_spgr_time.setVisible(spgr_en)
self.cmb_mode_spgr_time = QComboBox(self)
spgr_modes = [("PSD","psd"), ("Mag.","magnitude"),\
("Angle","angle"), ("Phase","phase")]
for i in spgr_modes:
self.cmb_mode_spgr_time.addItem(*i)
qset_cmb_box(self.cmb_mode_spgr_time, self.mode_spgr_time, data=True)
self.cmb_mode_spgr_time.setToolTip("<span>Spectrogram display mode.</span>")
self.cmb_mode_spgr_time.setVisible(spgr_en)
self.lbl_byfs_spgr_time = QLabel(to_html(" per f_S", frmt='b'), self)
self.lbl_byfs_spgr_time.setVisible(spgr_en)
self.chk_byfs_spgr_time = QCheckBox(self)
self.chk_byfs_spgr_time.setObjectName("chk_log_spgr")
self.chk_byfs_spgr_time.setToolTip("<span>Display spectral density i.e. scale by f_S</span>")
self.chk_byfs_spgr_time.setChecked(True)
self.chk_byfs_spgr_time.setVisible(spgr_en)
# self.lbl_colorbar_time = QLabel(to_html(" Col.bar", frmt='b'), self)
# self.lbl_colorbar_time.setVisible(spgr_en)
# self.chk_colorbar_time = QCheckBox(self)
# self.chk_colorbar_time.setObjectName("chk_colorbar_time")
# self.chk_colorbar_time.setToolTip("<span>Enable colorbar</span>")
# self.chk_colorbar_time.setChecked(True)
# self.chk_colorbar_time.setVisible(spgr_en)
self.chk_fx_limits = QCheckBox("Min/max.", self)
self.chk_fx_limits.setObjectName("chk_fx_limits")
self.chk_fx_limits.setToolTip("<span>Display limits of fixpoint range.</span>")
self.chk_fx_limits.setChecked(False)
layH_ctrl_time = QHBoxLayout()
layH_ctrl_time.addWidget(lbl_plt_time_title)
layH_ctrl_time.addStretch(1)
layH_ctrl_time.addWidget(self.lbl_plt_time_stim)
layH_ctrl_time.addWidget(self.cmb_plt_time_stim)
#
layH_ctrl_time.addWidget(self.lbl_plt_time_stmq)
layH_ctrl_time.addWidget(self.cmb_plt_time_stmq)
#
layH_ctrl_time.addWidget(lbl_plt_time_resp)
layH_ctrl_time.addWidget(self.cmb_plt_time_resp)
#
layH_ctrl_time.addWidget(lbl_win_time)
layH_ctrl_time.addWidget(self.chk_win_time)
layH_ctrl_time.addStretch(1)
layH_ctrl_time.addWidget(lbl_log_time)
layH_ctrl_time.addWidget(self.chk_log_time)
layH_ctrl_time.addWidget(self.lbl_log_bottom_time)
layH_ctrl_time.addWidget(self.led_log_bottom_time)
#
layH_ctrl_time.addStretch(1)
#
layH_ctrl_time.addWidget(lbl_plt_time_spgr)
layH_ctrl_time.addWidget(self.cmb_plt_time_spgr)
layH_ctrl_time.addWidget(self.lbl_log_spgr_time)
layH_ctrl_time.addWidget(self.chk_log_spgr_time)
layH_ctrl_time.addWidget(self.lbl_nfft_spgr_time)
layH_ctrl_time.addWidget(self.led_nfft_spgr_time)
layH_ctrl_time.addWidget(self.lbl_ovlp_spgr_time)
layH_ctrl_time.addWidget(self.led_ovlp_spgr_time)
layH_ctrl_time.addWidget(self.lbl_mode_spgr_time)
layH_ctrl_time.addWidget(self.cmb_mode_spgr_time)
layH_ctrl_time.addWidget(self.lbl_byfs_spgr_time)
layH_ctrl_time.addWidget(self.chk_byfs_spgr_time)
layH_ctrl_time.addStretch(2)
layH_ctrl_time.addWidget(self.chk_fx_limits)
layH_ctrl_time.addStretch(10)
#layH_ctrl_time.setContentsMargins(*params['wdg_margins'])
self.wdg_ctrl_time = QWidget(self)
self.wdg_ctrl_time.setLayout(layH_ctrl_time)
# ---- end time domain ------------------
# ---------------------------------------------------------------
# Controls for frequency domain
# ---------------------------------------------------------------
lbl_plt_freq_title = QLabel("<b>View:</b>", self)
self.lbl_plt_freq_stim = QLabel(to_html("Stimulus X", frmt='bi'), self)
self.cmb_plt_freq_stim = QComboBox(self)
self.cmb_plt_freq_stim.addItems(plot_styles_list)
qset_cmb_box(self.cmb_plt_freq_stim, self.plt_freq_stim)
self.cmb_plt_freq_stim.setToolTip("<span>Plot style for stimulus.</span>")
self.lbl_plt_freq_stmq = QLabel(to_html(" Fixp. Stim. X_Q", frmt='bi'), self)
self.cmb_plt_freq_stmq = QComboBox(self)
self.cmb_plt_freq_stmq.addItems(plot_styles_list)
qset_cmb_box(self.cmb_plt_freq_stmq, self.plt_freq_stmq)
self.cmb_plt_freq_stmq.setToolTip("<span>Plot style for <em>fixpoint</em> (quantized) stimulus.</span>")
lbl_plt_freq_resp = QLabel(to_html(" Response Y", frmt='bi'), self)
self.cmb_plt_freq_resp = QComboBox(self)
self.cmb_plt_freq_resp.addItems(plot_styles_list)
qset_cmb_box(self.cmb_plt_freq_resp, self.plt_freq_resp)
self.cmb_plt_freq_resp.setToolTip("<span>Plot style for response.</span>")
lbl_log_freq = QLabel(to_html("dB", frmt='b'), self)
self.chk_log_freq = QCheckBox(self)
self.chk_log_freq.setObjectName("chk_log_freq")
self.chk_log_freq.setToolTip("<span>Logarithmic scale for y-axis.</span>")
self.chk_log_freq.setChecked(True)
self.lbl_log_bottom_freq = QLabel(to_html("min =", frmt='bi'), self)
self.lbl_log_bottom_freq.setVisible(self.chk_log_freq.isChecked())
self.led_log_bottom_freq = QLineEdit(self)
self.led_log_bottom_freq.setText(str(self.bottom_f))
self.led_log_bottom_freq.setToolTip("<span>Minimum display value for log. scale.</span>")
self.led_log_bottom_freq.setVisible(self.chk_log_freq.isChecked())
if not self.chk_log_freq.isChecked():
self.bottom_f = 0
lbl_re_im_freq = QLabel(to_html("Re / Im", frmt='b'), self)
self.chk_re_im_freq = QCheckBox(self)
self.chk_re_im_freq.setObjectName("chk_re_im_freq")
self.chk_re_im_freq.setToolTip("<span>Show real and imaginary part of spectrum</span>")
self.chk_re_im_freq.setChecked(False)
self.lbl_win_fft = QLabel(to_html("Window", frmt='bi'), self)
self.cmb_win_fft = QComboBox(self)
self.cmb_win_fft.addItems(get_window_names())
self.cmb_win_fft.setToolTip("FFT window type.")
qset_cmb_box(self.cmb_win_fft, self.window_name)
self.cmb_win_fft_variant = QComboBox(self)
self.cmb_win_fft_variant.setToolTip("FFT window variant.")
self.cmb_win_fft_variant.setVisible(False)
self.lblWinPar1 = QLabel("Param1")
self.ledWinPar1 = QLineEdit(self)
self.ledWinPar1.setText("1")
self.ledWinPar1.setObjectName("ledWinPar1")
self.lblWinPar2 = QLabel("Param2")
self.ledWinPar2 = QLineEdit(self)
self.ledWinPar2.setText("2")
self.ledWinPar2.setObjectName("ledWinPar2")
self.chk_Hf = QCheckBox(self)
self.chk_Hf.setObjectName("chk_Hf")
self.chk_Hf.setToolTip("<span>Show ideal frequency response, calculated "
"from the filter coefficients.</span>")
self.chk_Hf.setChecked(False)
self.chk_Hf_lbl = QLabel(to_html("H_id (f)", frmt="bi"), self)
lbl_show_info_freq = QLabel(to_html("Info", frmt='b'), self)
self.chk_show_info_freq = QCheckBox(self)
self.chk_show_info_freq.setObjectName("chk_show_info_freq")
self.chk_show_info_freq.setToolTip("<span>Show infos about signal power "
"and window properties.</span>")
self.chk_show_info_freq.setChecked(False)
layH_ctrl_freq = QHBoxLayout()
layH_ctrl_freq.addWidget(lbl_plt_freq_title)
layH_ctrl_freq.addStretch(1)
layH_ctrl_freq.addWidget(self.lbl_plt_freq_stim)
layH_ctrl_freq.addWidget(self.cmb_plt_freq_stim)
#
layH_ctrl_freq.addWidget(self.lbl_plt_freq_stmq)
layH_ctrl_freq.addWidget(self.cmb_plt_freq_stmq)
#
layH_ctrl_freq.addWidget(lbl_plt_freq_resp)
layH_ctrl_freq.addWidget(self.cmb_plt_freq_resp)
#
layH_ctrl_freq.addWidget(self.chk_Hf_lbl)
layH_ctrl_freq.addWidget(self.chk_Hf)
layH_ctrl_freq.addStretch(1)
layH_ctrl_freq.addWidget(lbl_log_freq)
layH_ctrl_freq.addWidget(self.chk_log_freq)
layH_ctrl_freq.addWidget(self.lbl_log_bottom_freq)
layH_ctrl_freq.addWidget(self.led_log_bottom_freq)
layH_ctrl_freq.addStretch(1)
layH_ctrl_freq.addWidget(lbl_re_im_freq)
layH_ctrl_freq.addWidget(self.chk_re_im_freq)
layH_ctrl_freq.addStretch(2)
layH_ctrl_freq.addWidget(self.lbl_win_fft)
layH_ctrl_freq.addWidget(self.cmb_win_fft)
layH_ctrl_freq.addWidget(self.cmb_win_fft_variant)
layH_ctrl_freq.addWidget(self.lblWinPar1)
layH_ctrl_freq.addWidget(self.ledWinPar1)
layH_ctrl_freq.addWidget(self.lblWinPar2)
layH_ctrl_freq.addWidget(self.ledWinPar2)
layH_ctrl_freq.addStretch(1)
layH_ctrl_freq.addWidget(lbl_show_info_freq)
layH_ctrl_freq.addWidget(self.chk_show_info_freq)
layH_ctrl_freq.addStretch(10)
#layH_ctrl_freq.setContentsMargins(*params['wdg_margins'])
self.wdg_ctrl_freq = QWidget(self)
self.wdg_ctrl_freq.setLayout(layH_ctrl_freq)
# ---- end Frequency Domain ------------------
# ---------------------------------------------------------------
# Controls for stimuli
# ---------------------------------------------------------------
lbl_title_stim = QLabel("<b>Stimulus:</b>", self)
self.lblStimulus = QLabel(to_html("Type", frmt='bi'), self)
self.cmbStimulus = QComboBox(self)
self.cmbStimulus.addItems(["None","Impulse","Step","StepErr","Cos","Sine", "Chirp",
"Triang","Saw","Rect","Comb","AM","PM / FM","Formula"])
self.cmbStimulus.setToolTip("Stimulus type.")
qset_cmb_box(self.cmbStimulus, self.stim)
self.chk_stim_bl = QCheckBox("BL", self)
self.chk_stim_bl.setToolTip("<span>The signal is bandlimited to the Nyquist frequency "
"to avoid aliasing. However, it is much slower to generate "
"than the regular version.</span>")
self.chk_stim_bl.setChecked(True)
self.chk_stim_bl.setObjectName("stim_bl")
self.cmbChirpMethod = QComboBox(self)
for t in [("Lin","Linear"),("Square","Quadratic"),("Log", "Logarithmic"), ("Hyper", "Hyperbolic")]:
self.cmbChirpMethod.addItem(*t)
qset_cmb_box(self.cmbChirpMethod, self.chirp_method, data=False)
self.chk_scale_impz_f = QCheckBox("Scale", self)
self.chk_scale_impz_f.setToolTip("<span>Scale the FFT of the impulse response with <i>N<sub>FFT</sub></i> "
"so that it has the same magnitude as |H(f)|. DC and Noise need to be "
"turned off.</span>")
self.chk_scale_impz_f.setChecked(True)
self.chk_scale_impz_f.setObjectName("scale_impz_f")
self.lblDC = QLabel(to_html("DC =", frmt='bi'), self)
self.ledDC = QLineEdit(self)
self.ledDC.setText(str(self.DC))
self.ledDC.setToolTip("DC Level")
self.ledDC.setObjectName("stimDC")
layHCmbStim = QHBoxLayout()
layHCmbStim.addWidget(self.cmbStimulus)
layHCmbStim.addWidget(self.chk_stim_bl)
layHCmbStim.addWidget(self.chk_scale_impz_f)
layHCmbStim.addWidget(self.cmbChirpMethod)
#----------------------------------------------
self.lblAmp1 = QLabel(to_html(" A_1", frmt='bi') + " =", self)
self.ledAmp1 = QLineEdit(self)
self.ledAmp1.setText(str(self.A1))
self.ledAmp1.setToolTip("Stimulus amplitude, complex values like 3j - 1 are allowed")
self.ledAmp1.setObjectName("stimAmp1")
self.lblAmp2 = QLabel(to_html(" A_2", frmt='bi') + " =", self)
self.ledAmp2 = QLineEdit(self)
self.ledAmp2.setText(str(self.A2))
self.ledAmp2.setToolTip("Stimulus amplitude 2, complex values like 3j - 1 are allowed")
self.ledAmp2.setObjectName("stimAmp2")
#----------------------------------------------
self.lblPhi1 = QLabel(to_html(" φ_1", frmt='bi') + " =", self)
self.ledPhi1 = QLineEdit(self)
self.ledPhi1.setText(str(self.phi1))
self.ledPhi1.setToolTip("Stimulus phase")
self.ledPhi1.setObjectName("stimPhi1")
self.lblPhU1 = QLabel(to_html("°", frmt='b'), self)
self.lblPhi2 = QLabel(to_html(" φ_2", frmt='bi') + " =", self)
self.ledPhi2 = QLineEdit(self)
self.ledPhi2.setText(str(self.phi2))
self.ledPhi2.setToolTip("Stimulus phase 2")
self.ledPhi2.setObjectName("stimPhi2")
self.lblPhU2 = QLabel(to_html("°", frmt='b'), self)
#----------------------------------------------
self.lblFreq1 = QLabel(to_html(" f_1", frmt='bi') + " =", self)
self.ledFreq1 = QLineEdit(self)
self.ledFreq1.setText(str(self.f1))
self.ledFreq1.setToolTip("Stimulus frequency 1")
self.ledFreq1.setObjectName("stimFreq1")
self.lblFreqUnit1 = QLabel("f_S", self)
self.lblFreq2 = QLabel(to_html(" f_2", frmt='bi') + " =", self)
self.ledFreq2 = QLineEdit(self)
self.ledFreq2.setText(str(self.f2))
self.ledFreq2.setToolTip("Stimulus frequency 2")
self.ledFreq2.setObjectName("stimFreq2")
self.lblFreqUnit2 = QLabel("f_S", self)
#----------------------------------------------
self.lblNoise = QLabel(to_html(" Noise", frmt='bi'), self)
self.cmbNoise = QComboBox(self)
self.cmbNoise.addItems(["None","Gauss","Uniform","PRBS"])
self.cmbNoise.setToolTip("Type of additive noise.")
qset_cmb_box(self.cmbNoise, self.noise)
self.lblNoi = QLabel("not initialized", self)
self.ledNoi = QLineEdit(self)
self.ledNoi.setText(str(self.noi))
self.ledNoi.setToolTip("not initialized")
self.ledNoi.setObjectName("stimNoi")
layGStim = QGridLayout()
layGStim.addWidget(self.lblStimulus, 0, 0)
layGStim.addWidget(self.lblDC, 1, 0)
layGStim.addLayout(layHCmbStim, 0, 1)
layGStim.addWidget(self.ledDC, 1, 1)
layGStim.addWidget(self.lblAmp1, 0, 2)
layGStim.addWidget(self.lblAmp2, 1, 2)
layGStim.addWidget(self.ledAmp1, 0, 3)
layGStim.addWidget(self.ledAmp2, 1, 3)
layGStim.addWidget(self.lblPhi1, 0, 4)
layGStim.addWidget(self.lblPhi2, 1, 4)
layGStim.addWidget(self.ledPhi1, 0, 5)
layGStim.addWidget(self.ledPhi2, 1, 5)
layGStim.addWidget(self.lblPhU1, 0, 6)
layGStim.addWidget(self.lblPhU2, 1, 6)
layGStim.addWidget(self.lblFreq1, 0, 7)
layGStim.addWidget(self.lblFreq2, 1, 7)
layGStim.addWidget(self.ledFreq1, 0, 8)
layGStim.addWidget(self.ledFreq2, 1, 8)
layGStim.addWidget(self.lblFreqUnit1, 0, 9)
layGStim.addWidget(self.lblFreqUnit2, 1, 9)
layGStim.addWidget(self.lblNoise, 0, 10)
layGStim.addWidget(self.lblNoi, 1, 10)
layGStim.addWidget(self.cmbNoise, 0, 11)
layGStim.addWidget(self.ledNoi, 1, 11)
#----------------------------------------------
self.lblStimFormula = QLabel(to_html("x =", frmt='bi'), self)
self.ledStimFormula = QLineEdit(self)
self.ledStimFormula.setText(str(self.stim_formula))
self.ledStimFormula.setToolTip("<span>Enter formula for stimulus in numexpr syntax"
"</span>")
self.ledStimFormula.setObjectName("stimFormula")
layH_ctrl_stim_formula = QHBoxLayout()
layH_ctrl_stim_formula.addWidget(self.lblStimFormula)
layH_ctrl_stim_formula.addWidget(self.ledStimFormula,10)
#----------------------------------------------
#layG_ctrl_stim = QGridLayout()
layH_ctrl_stim_par = QHBoxLayout()
layH_ctrl_stim_par.addLayout(layGStim)
layV_ctrl_stim = QVBoxLayout()
layV_ctrl_stim.addLayout(layH_ctrl_stim_par)
layV_ctrl_stim.addLayout(layH_ctrl_stim_formula)
layH_ctrl_stim = QHBoxLayout()
layH_ctrl_stim.addWidget(lbl_title_stim)
layH_ctrl_stim.addStretch(1)
layH_ctrl_stim.addLayout(layV_ctrl_stim)
layH_ctrl_stim.addStretch(10)
self.wdg_ctrl_stim = QWidget(self)
self.wdg_ctrl_stim.setLayout(layH_ctrl_stim)
# --------- end stimuli ---------------------------------
# frequency widgets require special handling as they are scaled with f_s
self.ledFreq1.installEventFilter(self)
self.ledFreq2.installEventFilter(self)
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
#----------------------------------------------------------------------
# --- run control ---
self.led_N_start.editingFinished.connect(self.update_N)
self.led_N_points.editingFinished.connect(self.update_N)
# --- frequency control ---
# careful! currentIndexChanged passes the current index to _update_win_fft
self.cmb_win_fft.currentIndexChanged.connect(self._update_win_fft)
self.ledWinPar1.editingFinished.connect(self._read_param1)
self.ledWinPar2.editingFinished.connect(self._read_param2)
# --- stimulus control ---
self.chk_stim_options.clicked.connect(self._show_stim_options)
self.chk_stim_bl.clicked.connect(self._enable_stim_widgets)
self.cmbStimulus.currentIndexChanged.connect(self._enable_stim_widgets)
self.cmbNoise.currentIndexChanged.connect(self._update_noi)
self.ledNoi.editingFinished.connect(self._update_noi)
self.ledAmp1.editingFinished.connect(self._update_amp1)
self.ledAmp2.editingFinished.connect(self._update_amp2)
self.ledPhi1.editingFinished.connect(self._update_phi1)
self.ledPhi2.editingFinished.connect(self._update_phi2)
self.cmbChirpMethod.currentIndexChanged.connect(self._update_chirp_method)
self.ledDC.editingFinished.connect(self._update_DC)
self.ledStimFormula.editingFinished.connect(self._update_stim_formula)
#------------------------------------------------------------------------------
def eventFilter(self, source, event):
"""
Filter all events generated by the monitored widgets. Source and type
of all events generated by monitored objects are passed to this eventFilter,
evaluated and passed on to the next hierarchy level.
- When a QLineEdit widget gains input focus (``QEvent.FocusIn``), display
the stored value from filter dict with full precision
- When a key is pressed inside the text field, set the `spec_edited` flag
to True.
- When a QLineEdit widget loses input focus (``QEvent.FocusOut``), store
current value normalized to f_S with full precision (only if
``spec_edited == True``) and display the stored value in selected format
"""
def _store_entry(source):
if self.spec_edited:
if source.objectName() == "stimFreq1":
self.f1 = safe_eval(source.text(), self.f1 * fb.fil[0]['f_S'],
return_type='float') / fb.fil[0]['f_S']
source.setText(str(params['FMT'].format(self.f1 * fb.fil[0]['f_S'])))
elif source.objectName() == "stimFreq2":
self.f2 = safe_eval(source.text(), self.f2 * fb.fil[0]['f_S'],
return_type='float') / fb.fil[0]['f_S']
source.setText(str(params['FMT'].format(self.f2 * fb.fil[0]['f_S'])))
self.spec_edited = False # reset flag
self.sig_tx.emit({'sender':__name__, 'ui_changed':'stim'})
# if isinstance(source, QLineEdit):
# if source.objectName() in {"stimFreq1","stimFreq2"}:
if event.type() in {QEvent.FocusIn,QEvent.KeyPress, QEvent.FocusOut}:
if event.type() == QEvent.FocusIn:
self.spec_edited = False
self.load_fs()
elif event.type() == QEvent.KeyPress:
self.spec_edited = True # entry has been changed
key = event.key()
if key in {Qt.Key_Return, Qt.Key_Enter}:
_store_entry(source)
elif key == Qt.Key_Escape: # revert changes
self.spec_edited = False
if source.objectName() == "stimFreq1":
source.setText(str(params['FMT'].format(self.f1 * fb.fil[0]['f_S'])))
elif source.objectName() == "stimFreq2":
source.setText(str(params['FMT'].format(self.f2 * fb.fil[0]['f_S'])))
elif event.type() == QEvent.FocusOut:
_store_entry(source)
# Call base class method to continue normal event processing:
return super(PlotImpz_UI, self).eventFilter(source, event)
#-------------------------------------------------------------
def _show_stim_options(self):
"""
Hide / show panel with stimulus options
"""
self.wdg_ctrl_stim.setVisible(self.chk_stim_options.isChecked())
def _enable_stim_widgets(self):
""" Enable / disable widgets depending on the selected stimulus"""
self.stim = qget_cmb_box(self.cmbStimulus, data=False)
f1_en = self.stim in {"Cos","Sine","Chirp","PM / FM","AM","Formula","Rect","Saw","Triang","Comb"}
f2_en = self.stim in {"Cos","Sine","Chirp","PM / FM","AM","Formula"}
dc_en = self.stim not in {"Step", "StepErr"}
self.chk_stim_bl.setVisible(self.stim in {"Triang", "Saw", "Rect"})
self.lblAmp1.setVisible(self.stim != "None")
self.ledAmp1.setVisible(self.stim != "None")
self.chk_scale_impz_f.setVisible(self.stim == 'Impulse')
self.chk_scale_impz_f.setEnabled((self.noi == 0 or self.cmbNoise.currentText() == 'None')\
and self.DC == 0)
self.cmbChirpMethod.setVisible(self.stim == 'Chirp')
self.lblPhi1.setVisible(f1_en)
self.ledPhi1.setVisible(f1_en)
self.lblPhU1.setVisible(f1_en)
self.lblFreq1.setVisible(f1_en)
self.ledFreq1.setVisible(f1_en)
self.lblFreqUnit1.setVisible(f1_en)
self.lblFreq2.setVisible(f2_en)
self.ledFreq2.setVisible(f2_en)
self.lblFreqUnit2.setVisible(f2_en)
self.lblAmp2.setVisible(f2_en and self.stim != "Chirp")
self.ledAmp2.setVisible(f2_en and self.stim != "Chirp")
self.lblPhi2.setVisible(f2_en and self.stim != "Chirp")
self.ledPhi2.setVisible(f2_en and self.stim != "Chirp")
self.lblPhU2.setVisible(f2_en and self.stim != "Chirp")
self.lblDC.setVisible(dc_en)
self.ledDC.setVisible(dc_en)
self.lblStimFormula.setVisible(self.stim == "Formula")
self.ledStimFormula.setVisible(self.stim == "Formula")
self.sig_tx.emit({'sender':__name__, 'ui_changed':'stim'})
#-------------------------------------------------------------
def load_fs(self):
"""
Reload sampling frequency from filter dictionary and transform
the displayed frequency spec input fields according to the units
setting (i.e. f_S). Spec entries are always stored normalized w.r.t. f_S
in the dictionary; when f_S or the unit are changed, only the displayed values
of the frequency entries are updated, not the dictionary!
load_fs() is called during init and when the frequency unit or the
sampling frequency have been changed.
It should be called when sigSpecsChanged or sigFilterDesigned is emitted
at another place, indicating that a reload is required.
"""
# recalculate displayed freq spec values for (maybe) changed f_S
if self.ledFreq1.hasFocus():
# widget has focus, show full precision
self.ledFreq1.setText(str(self.f1 * fb.fil[0]['f_S']))
elif self.ledFreq2.hasFocus():
# widget has focus, show full precision
self.ledFreq2.setText(str(self.f2 * fb.fil[0]['f_S']))
else:
# widgets have no focus, round the display
self.ledFreq1.setText(
str(params['FMT'].format(self.f1 * fb.fil[0]['f_S'])))
self.ledFreq2.setText(
str(params['FMT'].format(self.f2 * fb.fil[0]['f_S'])))
def _update_amp1(self):
""" Update value for self.A1 from QLineEditWidget"""
self.A1 = safe_eval(self.ledAmp1.text(), self.A1, return_type='cmplx')
self.ledAmp1.setText(str(self.A1))
self.sig_tx.emit({'sender':__name__, 'ui_changed':'a1'})
def _update_amp2(self):
""" Update value for self.A2 from the QLineEditWidget"""
self.A2 = safe_eval(self.ledAmp2.text(), self.A2, return_type='cmplx')
self.ledAmp2.setText(str(self.A2))
self.sig_tx.emit({'sender':__name__, 'ui_changed':'a2'})
def _update_phi1(self):
""" Update value for self.phi1 from QLineEditWidget"""
self.phi1 = safe_eval(self.ledPhi1.text(), self.phi1, return_type='float')
self.ledPhi1.setText(str(self.phi1))
self.sig_tx.emit({'sender':__name__, 'ui_changed':'phi1'})
def _update_phi2(self):
""" Update value for self.phi2 from the QLineEditWidget"""
self.phi2 = safe_eval(self.ledPhi2.text(), self.phi2, return_type='float')
self.ledPhi2.setText(str(self.phi2))
self.sig_tx.emit({'sender':__name__, 'ui_changed':'phi2'})
def _update_chirp_method(self):
""" Update value for self.chirp_method from the QLineEditWidget"""
self.chirp_method = qget_cmb_box(self.cmbChirpMethod) # read current data string
self.sig_tx.emit({'sender':__name__, 'ui_changed':'chirp_method'})
def _update_noi(self):
""" Update type + value + label for self.noi for noise"""
self.noise = qget_cmb_box(self.cmbNoise, data=False).lower()
self.lblNoi.setVisible(self.noise!='none')
self.ledNoi.setVisible(self.noise!='none')
if self.noise!='none':
self.noi = safe_eval(self.ledNoi.text(), 0, return_type='cmplx')
self.ledNoi.setText(str(self.noi))
if self.noise == 'gauss':
self.lblNoi.setText(to_html(" σ =", frmt='bi'))
self.ledNoi.setToolTip("<span>Standard deviation of statistical process,"
"noise power is <i>P</i> = σ<sup>2</sup></span>")
elif self.noise == 'uniform':
self.lblNoi.setText(to_html(" Δ =", frmt='bi'))
self.ledNoi.setToolTip("<span>Interval size for uniformly distributed process "
"(e.g. quantization step size for quantization noise), "
"centered around 0. Noise power is "
"<i>P</i> = Δ<sup>2</sup>/12.</span>")
elif self.noise == 'prbs':
self.lblNoi.setText(to_html(" A =", frmt='bi'))
self.ledNoi.setToolTip("<span>Amplitude of bipolar Pseudorandom Binary Sequence. "
"Noise power is <i>P</i> = A<sup>2</sup>.</span>")
self.sig_tx.emit({'sender':__name__, 'ui_changed':'noi'})
def _update_DC(self):
""" Update value for self.DC from the QLineEditWidget"""
self.DC = safe_eval(self.ledDC.text(), 0, return_type='cmplx')
self.ledDC.setText(str(self.DC))
self.sig_tx.emit({'sender':__name__, 'ui_changed':'dc'})
def _update_stim_formula(self):
"""Update string with formula to be evaluated by numexpr"""
self.stim_formula = self.ledStimFormula.text().strip()
self.ledStimFormula.setText(str(self.stim_formula))
self.sig_tx.emit({'sender':__name__, 'ui_changed':'stim_formula'})
# -------------------------------------------------------------------------
def update_N(self, emit=True):
# called directly from impz or locally
# between local triggering and updates upstream
"""
Update values for self.N and self.N_start from the QLineEditWidget,
update the window and fire "ui_changed"
"""
if not isinstance(emit, bool):
logger.error("update N: emit={0}".format(emit))
self.N_start = safe_eval(self.led_N_start.text(), self.N_start, return_type='int', sign='poszero')
self.led_N_start.setText(str(self.N_start)) # update widget
self.N_user = safe_eval(self.led_N_points.text(), self.N_user, return_type='int', sign='poszero')
if self.N_user == 0: # automatic calculation
self.N = self.calc_n_points(self.N_user) # widget remains set to 0
self.led_N_points.setText("0") # update widget
else:
self.N = self.N_user
self.led_N_points.setText(str(self.N)) # update widget
self.N_end = self.N + self.N_start # total number of points to be calculated: N + N_start
# FFT window needs to be updated due to changed number of data points
self._update_win_fft(emit=False) # don't emit anything here
if emit:
self.sig_tx.emit({'sender':__name__, 'ui_changed':'N'})
def _read_param1(self):
"""Read out textbox when editing is finished and update dict and fft window"""
param = safe_eval(self.ledWinPar1.text(), self.win_dict['par'][0]['val'],
return_type='float')
if param < self.win_dict['par'][0]['min']:
param = self.win_dict['par'][0]['min']
elif param > self.win_dict['par'][0]['max']:
param = self.win_dict['par'][0]['max']
self.ledWinPar1.setText(str(param))
self.win_dict['par'][0]['val'] = param
self._update_win_fft()
def _read_param2(self):
"""Read out textbox when editing is finished and update dict and fft window"""
param = safe_eval(self.ledWinPar2.text(), self.win_dict['par'][1]['val'],
return_type='float')
if param < self.win_dict['par'][1]['min']:
param = self.win_dict['par'][1]['min']
elif param > self.win_dict['par'][1]['max']:
param = self.win_dict['par'][1]['max']
self.ledWinPar2.setText(str(param))
self.win_dict['par'][1]['val'] = param
self._update_win_fft()
#------------------------------------------------------------------------------
def _update_win_fft(self, arg=None, emit=True):
"""
Update window type for FFT with different arguments:
- signal-slot connection to combo-box -> index (int), absorbed by `arg`
emit is not set -> emit=True
- called by _read_param() -> empty -> emit=True
- called by update_N(emit=False)
"""
if not isinstance(emit, bool):
logger.error("update win: emit={0}".format(emit))
self.window_name = qget_cmb_box(self.cmb_win_fft, data=False)
self.win = calc_window_function(self.win_dict, self.window_name,
N=self.N, sym=False)
n_par = self.win_dict['n_par']
self.lblWinPar1.setVisible(n_par > 0)
self.ledWinPar1.setVisible(n_par > 0)
self.lblWinPar2.setVisible(n_par > 1)
self.ledWinPar2.setVisible(n_par > 1)
if n_par > 0:
self.lblWinPar1.setText(to_html(self.win_dict['par'][0]['name'] + " =", frmt='bi'))
self.ledWinPar1.setText(str(self.win_dict['par'][0]['val']))
self.ledWinPar1.setToolTip(self.win_dict['par'][0]['tooltip'])
if n_par > 1:
self.lblWinPar2.setText(to_html(self.win_dict['par'][1]['name'] + " =", frmt='bi'))
self.ledWinPar2.setText(str(self.win_dict['par'][1]['val']))
self.ledWinPar2.setToolTip(self.win_dict['par'][1]['tooltip'])
self.nenbw = self.N * np.sum(np.square(self.win)) / (np.square(np.sum(self.win)))
self.cgain = np.sum(self.win) / self.N # coherent gain
self.win /= self.cgain # correct gain for periodic signals
# only emit a signal for local triggers to prevent infinite loop:
# - signal-slot connection passes a bool or an integer
# - local function calls don't pass anything
if emit is True:
self.sig_tx.emit({'sender':__name__, 'ui_changed':'win'})
# ... but always notify the FFT widget via sig_tx_fft
self.sig_tx_fft.emit({'sender':__name__, 'view_changed':'win'})
#------------------------------------------------------------------------------
def show_fft_win(self):
"""
Pop-up FFT window
"""
if self.but_fft_win.isChecked():
qstyle_widget(self.but_fft_win, "changed")
else:
qstyle_widget(self.but_fft_win, "normal")
if self.fft_window is None: # no handle to the window? Create a new instance
if self.but_fft_win.isChecked():
# Important: Handle to window must be class attribute otherwise it
# (and the attached window) is deleted immediately when it goes out of scope
self.fft_window = Plot_FFT_win(self, win_dict=self.win_dict, sym=False,
title="pyFDA Spectral Window Viewer")
self.sig_tx_fft.connect(self.fft_window.sig_rx)
self.fft_window.sig_tx.connect(self.close_fft_win)
self.fft_window.show() # modeless i.e. non-blocking popup window
else:
if not self.but_fft_win.isChecked():
if self.fft_window is None:
logger.warning("FFT window is already closed!")
else:
self.fft_window.close()
def close_fft_win(self):
self.fft_window = None
self.but_fft_win.setChecked(False)
qstyle_widget(self.but_fft_win, "normal")
#------------------------------------------------------------------------------
def calc_n_points(self, N_user = 0):
"""
Calculate number of points to be displayed, depending on type of filter
(FIR, IIR) and user input. If the user selects 0 points, the number is
calculated automatically.
An improvement would be to calculate the dominant pole and the corresponding
settling time.
"""
if N_user == 0: # set number of data points automatically
if fb.fil[0]['ft'] == 'IIR':
N = 100
else:
N = min(len(fb.fil[0]['ba'][0]),100) # FIR: N = number of coefficients (max. 100)
else:
N = N_user
return N
class FreqUnits(QWidget):
"""
Build and update widget for entering frequency unit, frequency range and
sampling frequency f_S
The following key-value pairs of the `fb.fil[0]` dict are modified:
- `'freq_specs_unit'` : The unit ('k', 'f_S', 'f_Ny', 'Hz' etc.) as a string
- `'freqSpecsRange'` : A list with two entries for minimum and maximum frequency
values for labelling the frequency axis
- `'f_S'` : The sampling frequency for referring frequency values to as a float
- `'f_max'` : maximum frequency for scaling frequency axis
- `'plt_fUnit'`: frequency unit as string
- `'plt_tUnit'`: time unit as string
- `'plt_fLabel'`: label for frequency axis
- `'plt_tLabel'`: label for time axis
"""
# class variables (shared between instances if more than one exists)
sig_tx = pyqtSignal(object) # outgoing
from pyfda.libs.pyfda_qt_lib import emit
def __init__(self, parent=None, title="Frequency Units"):
super(FreqUnits, self).__init__(parent)
self.title = title
self.spec_edited = False # flag whether QLineEdit field has been edited
self._construct_UI()
def _construct_UI(self):
"""
Construct the User Interface
"""
self.layVMain = QVBoxLayout() # Widget main layout
f_units = ['k', 'f_S', 'f_Ny', 'Hz', 'kHz', 'MHz', 'GHz']
self.t_units = ['', 'T_S', 'T_S', 's', 'ms', r'$\mu$s', 'ns']
bfont = QFont()
bfont.setBold(True)
self.lblUnits = QLabel(self)
self.lblUnits.setText("Freq. Unit")
self.lblUnits.setFont(bfont)
self.fs_old = fb.fil[0]['f_S'] # store current sampling frequency
self.lblF_S = QLabel(self)
self.lblF_S.setText(to_html("f_S =", frmt='bi'))
self.ledF_S = QLineEdit()
self.ledF_S.setText(str(fb.fil[0]["f_S"]))
self.ledF_S.setObjectName("f_S")
self.ledF_S.installEventFilter(self) # filter events
self.butLock = QToolButton(self)
self.butLock.setIcon(QIcon(':/lock-unlocked.svg'))
self.butLock.setCheckable(True)
self.butLock.setChecked(False)
self.butLock.setToolTip(
"<span><b>Unlocked:</b> When f_S is changed, all frequency related "
"widgets are updated, normalized frequencies stay the same.<br />"
"<b>Locked:</b> When f_S is changed, displayed absolute frequency "
"values don't change but normalized frequencies do.</span>")
# self.butLock.setStyleSheet("QToolButton:checked {font-weight:bold}")
layHF_S = QHBoxLayout()
layHF_S.addWidget(self.ledF_S)
layHF_S.addWidget(self.butLock)
self.cmbUnits = QComboBox(self)
self.cmbUnits.setObjectName("cmbUnits")
self.cmbUnits.addItems(f_units)
self.cmbUnits.setToolTip(
'Select whether frequencies are specified w.r.t. \n'
'the sampling frequency "f_S", to the Nyquist frequency \n'
'f_Ny = f_S/2 or as absolute values. "k" specifies frequencies w.r.t. f_S '
'but plots graphs over the frequency index k.')
self.cmbUnits.setCurrentIndex(1)
# self.cmbUnits.setItemData(0, (0,QColor("#FF333D"),Qt.BackgroundColorRole))#
# self.cmbUnits.setItemData(0, (QFont('Verdana', bold=True), Qt.FontRole)
fRanges = [("0...½", "half"), ("0...1", "whole"), ("-½...½", "sym")]
self.cmbFRange = QComboBox(self)
self.cmbFRange.setObjectName("cmbFRange")
for f in fRanges:
self.cmbFRange.addItem(f[0], f[1])
self.cmbFRange.setToolTip("Select frequency range (whole or half).")
self.cmbFRange.setCurrentIndex(0)
# Combobox resizes with longest entry
self.cmbUnits.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.cmbFRange.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.butSort = QToolButton(self)
self.butSort.setText("Sort")
self.butSort.setIcon(QIcon(':/sort-ascending.svg'))
#self.butDelCells.setIconSize(q_icon_size)
self.butSort.setCheckable(True)
self.butSort.setChecked(True)
self.butSort.setToolTip(
"Sort frequencies in ascending order when pushed.")
self.butSort.setStyleSheet("QToolButton:checked {font-weight:bold}")
self.layHUnits = QHBoxLayout()
self.layHUnits.addWidget(self.cmbUnits)
self.layHUnits.addWidget(self.cmbFRange)
self.layHUnits.addWidget(self.butSort)
# Create a gridLayout consisting of QLabel and QLineEdit fields
# for setting f_S, the units and the actual frequency specs:
self.layGSpecWdg = QGridLayout() # sublayout for spec fields
self.layGSpecWdg.addWidget(self.lblF_S, 1, 0)
# self.layGSpecWdg.addWidget(self.ledF_S,1,1)
self.layGSpecWdg.addLayout(layHF_S, 1, 1)
self.layGSpecWdg.addWidget(self.lblUnits, 0, 0)
self.layGSpecWdg.addLayout(self.layHUnits, 0, 1)
frmMain = QFrame(self)
frmMain.setLayout(self.layGSpecWdg)
self.layVMain.addWidget(frmMain)
self.layVMain.setContentsMargins(*params['wdg_margins'])
self.setLayout(self.layVMain)
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.cmbUnits.currentIndexChanged.connect(self.update_UI)
self.butLock.clicked.connect(self._lock_freqs)
self.cmbFRange.currentIndexChanged.connect(self._freq_range)
self.butSort.clicked.connect(self._store_sort_flag)
# ----------------------------------------------------------------------
self.update_UI() # first-time initialization
# -------------------------------------------------------------
def _lock_freqs(self):
"""
Lock / unlock frequency entries: The values of frequency related widgets
are stored in normalized form (w.r.t. sampling frequency)`fb.fil[0]['f_S']`.
When the sampling frequency changes, absolute frequencies displayed in the
widgets change their values. Most of the time, this is the desired behaviour,
the properties of discrete time systems or signals are usually defined
by the normalized frequencies.
When the effect of varying the sampling frequency is to be analyzed, the
displayed values in the widgets can be locked by pressing the Lock button.
After changing the sampling frequency, normalized frequencies have to be
rescaled like `f_a *= fb.fil[0]['f_S_prev'] / fb.fil[0]['f_S']` to maintain
the displayed value `f_a * f_S`.
This has to be accomplished by each frequency widget (currently, these are
freq_specs and freq_units).
The setting is stored as bool in the global dict entry `fb.fil[0]['freq_locked'`,
the signal 'view_changed':'f_S' is emitted.
"""
if self.butLock.isChecked():
# Lock has been activated, keep displayed frequencies locked
fb.fil[0]['freq_locked'] = True
self.butLock.setIcon(QIcon(':/lock-locked.svg'))
else:
# Lock has been unlocked, scale displayed frequencies with f_S
fb.fil[0]['freq_locked'] = False
self.butLock.setIcon(QIcon(':/lock-unlocked.svg'))
self.emit({'view_changed': 'f_S'})
# -------------------------------------------------------------
def update_UI(self):
"""
update_UI is called
- during init
- when the unit combobox is changed
Set various scale factors and labels depending on the setting of the unit
combobox.
Update the freqSpecsRange and finally, emit 'view_changed':'f_S' signal
"""
f_unit = str(self.cmbUnits.currentText()) # selected frequency unit
idx = self.cmbUnits.currentIndex() # and its index
is_normalized_freq = f_unit in {"f_S", "f_Ny", "k"}
self.ledF_S.setVisible(not is_normalized_freq) # only vis. when
self.lblF_S.setVisible(not is_normalized_freq) # not normalized
self.butLock.setVisible(not is_normalized_freq)
f_S_scale = 1 # default setting for f_S scale
if is_normalized_freq:
# store current sampling frequency to restore it when returning to
# unnormalized frequencies
self.fs_old = fb.fil[0]['f_S']
if f_unit == "f_S": # normalized to f_S
fb.fil[0]['f_S'] = fb.fil[0]['f_max'] = 1.
fb.fil[0]['T_S'] = 1.
f_label = r"$F = f\, /\, f_S = \Omega \, /\, 2 \mathrm{\pi} \; \rightarrow$"
t_label = r"$n = t\, /\, T_S \; \rightarrow$"
elif f_unit == "f_Ny": # normalized to f_nyq = f_S / 2
fb.fil[0]['f_S'] = fb.fil[0]['f_max'] = 2.
fb.fil[0]['T_S'] = 1.
f_label = r"$F = 2f \, / \, f_S = \Omega \, / \, \mathrm{\pi} \; \rightarrow$"
t_label = r"$n = t\, /\, T_S \; \rightarrow$"
else: # frequency index k,
fb.fil[0]['f_S'] = 1.
fb.fil[0]['T_S'] = 1.
fb.fil[0]['f_max'] = params['N_FFT']
f_label = r"$k \; \rightarrow$"
t_label = r"$n\; \rightarrow$"
self.ledF_S.setText(params['FMT'].format(fb.fil[0]['f_S']))
else: # Hz, kHz, ...
# Restore sampling frequency when returning from f_S / f_Ny / k
if fb.fil[0]['freq_specs_unit'] in {
"f_S", "f_Ny", "k"
}: # previous setting normalized?
fb.fil[0]['f_S'] = fb.fil[0][
'f_max'] = self.fs_old # yes, restore prev.
fb.fil[0][
'T_S'] = 1. / self.fs_old # settings for sampling frequency
self.ledF_S.setText(params['FMT'].format(fb.fil[0]['f_S']))
if f_unit == "Hz":
f_S_scale = 1.
elif f_unit == "kHz":
f_S_scale = 1.e3
elif f_unit == "MHz":
f_S_scale = 1.e6
elif f_unit == "GHz":
f_S_scale = 1.e9
else:
logger.warning("Unknown frequency unit {0}".format(f_unit))
f_label = r"$f$ in " + f_unit + r"$\; \rightarrow$"
t_label = r"$t$ in " + self.t_units[idx] + r"$\; \rightarrow$"
if f_unit == "k":
plt_f_unit = "f_S"
else:
plt_f_unit = f_unit
fb.fil[0].update({'f_S_scale':
f_S_scale}) # scale factor for f_S (Hz, kHz, ...)
fb.fil[0].update({'freq_specs_unit': f_unit}) # frequency unit
# time and frequency unit as string e.g. for plot axis labeling
fb.fil[0].update({"plt_fUnit": plt_f_unit})
fb.fil[0].update({"plt_tUnit": self.t_units[idx]})
# complete plot axis labels including unit and arrow
fb.fil[0].update({"plt_fLabel": f_label})
fb.fil[0].update({"plt_tLabel": t_label})
self._freq_range(
emit=False) # update f_lim setting without emitting signal
self.emit({'view_changed': 'f_S'})
# ------------------------------------------------------------------------------
def eventFilter(self, source, event):
"""
Filter all events generated by the QLineEdit `f_S` widget. Source and type
of all events generated by monitored objects are passed to this eventFilter,
evaluated and passed on to the next hierarchy level.
- When a QLineEdit widget gains input focus (QEvent.FocusIn`), display
the stored value from filter dict with full precision
- When a key is pressed inside the text field, set the `spec_edited` flag
to True.
- When a QLineEdit widget loses input focus (QEvent.FocusOut`), store
current value with full precision (only if `spec_edited`== True) and
display the stored value in selected format. Emit 'view_changed':'f_S'
"""
def _store_entry():
"""
Update filter dictionary, set line edit entry with reduced precision
again.
"""
if self.spec_edited:
fb.fil[0].update({'f_S_prev': fb.fil[0]['f_S']})
fb.fil[0].update({
'f_S':
safe_eval(source.text(), fb.fil[0]['f_S'], sign='pos')
})
fb.fil[0].update({'T_S': 1. / fb.fil[0]['f_S']})
fb.fil[0].update({'f_max': fb.fil[0]['f_S']})
self._freq_range(emit=False) # update plotting range
self.emit({'view_changed': 'f_S'})
self.spec_edited = False # reset flag, changed entry has been saved
if source.objectName() == 'f_S':
if event.type() == QEvent.FocusIn:
self.spec_edited = False
source.setText(str(fb.fil[0]['f_S'])) # full precision
elif event.type() == QEvent.KeyPress:
self.spec_edited = True # entry has been changed
key = event.key()
if key in {QtCore.Qt.Key_Return, QtCore.Qt.Key_Enter}:
_store_entry()
elif key == QtCore.Qt.Key_Escape: # revert changes
self.spec_edited = False
source.setText(str(fb.fil[0]['f_S'])) # full precision
elif event.type() == QEvent.FocusOut:
_store_entry()
source.setText(params['FMT'].format(
fb.fil[0]['f_S'])) # reduced prec.
# Call base class method to continue normal event processing:
return super(FreqUnits, self).eventFilter(source, event)
# -------------------------------------------------------------
def _freq_range(self, emit=True):
"""
Set frequency plotting range for single-sided spectrum up to f_S/2 or f_S
or for double-sided spectrum between -f_S/2 and f_S/2
Emit 'view_changed':'f_range' when `emit=True`
"""
if type(emit) == int: # signal was emitted by combobox
emit = True
rangeType = qget_cmb_box(self.cmbFRange)
fb.fil[0].update({'freqSpecsRangeType': rangeType})
f_max = fb.fil[0]["f_max"]
if rangeType == 'whole':
f_lim = [0, f_max]
elif rangeType == 'sym':
f_lim = [-f_max / 2., f_max / 2.]
else:
f_lim = [0, f_max / 2.]
fb.fil[0]['freqSpecsRange'] = f_lim # store settings in dict
if emit:
self.emit({'view_changed': 'f_range'})
# -------------------------------------------------------------
def load_dict(self):
"""
Reload comboBox settings and textfields from filter dictionary
Block signals during update of combobox / lineedit widgets
"""
self.ledF_S.setText(params['FMT'].format(fb.fil[0]['f_S']))
self.cmbUnits.blockSignals(True)
idx = self.cmbUnits.findText(
fb.fil[0]['freq_specs_unit']) # get and set
self.cmbUnits.setCurrentIndex(idx) # index for freq. unit combo box
self.cmbUnits.blockSignals(False)
self.cmbFRange.blockSignals(True)
idx = self.cmbFRange.findData(fb.fil[0]['freqSpecsRangeType'])
self.cmbFRange.setCurrentIndex(idx) # set frequency range
self.cmbFRange.blockSignals(False)
self.butSort.blockSignals(True)
self.butSort.setChecked(fb.fil[0]['freq_specs_sort'])
self.butSort.blockSignals(False)
# -------------------------------------------------------------
def _store_sort_flag(self):
"""
Store sort flag in filter dict and emit 'specs_changed':'f_sort'
when sort button is checked.
"""
fb.fil[0]['freq_specs_sort'] = self.butSort.isChecked()
if self.butSort.isChecked():
self.emit({'specs_changed': 'f_sort'})
class Plot_Phi(QWidget):
# incoming, connected in sender widget (locally connected to self.process_sig_rx() )
sig_rx = pyqtSignal(object)
# outgoing, distributed via plot_tab_widget
sig_tx = pyqtSignal(object)
def __init__(self, parent):
super(Plot_Phi, self).__init__(parent)
self.needs_calc = True # recalculation of filter function necessary
self.needs_draw = True # plotting neccessary (e.g. log instead of lin)
self.tool_tip = "Phase frequency response"
self.tab_label = "\u03C6(f)" # phi(f)
self._construct_UI()
#------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig=None):
"""
Process signals coming from the navigation toolbar and from sig_rx
"""
logger.debug("Processing {0} | needs_calc = {1}, visible = {2}"\
.format(dict_sig, self.needs_calc, self.isVisible()))
if dict_sig['sender'] == __name__:
logger.debug("Stopped infinite loop\n{0}".format(
pprint_log(dict_sig)))
return
if self.isVisible():
if 'data_changed' in dict_sig or 'home' in dict_sig or self.needs_calc:
self.draw()
self.needs_calc = False
self.needs_draw = False
elif 'view_changed' in dict_sig or self.needs_draw:
self.update_view()
self.needs_draw = False
# elif ('ui_changed' in dict_sig and dict_sig['ui_changed'] == 'resized')\
# or self.needs_redraw:
# self.redraw()
else:
if 'data_changed' in dict_sig:
self.needs_calc = True
elif 'view_changed' in dict_sig:
self.needs_draw = True
# elif 'ui_changed' in dict_sig and dict_sig['ui_changed'] == 'resized':
# self.needs_redraw = True
#------------------------------------------------------------------------------
def _construct_UI(self):
"""
Intitialize the widget, consisting of:
- Matplotlib widget with NavigationToolbar
- Frame with control elements
"""
self.cmbUnitsPhi = QComboBox(self)
units = ["rad", "rad/pi", "deg"]
scales = [1., 1. / np.pi, 180. / np.pi]
for unit, scale in zip(units, scales):
self.cmbUnitsPhi.addItem(unit, scale)
self.cmbUnitsPhi.setObjectName("cmbUnitsA")
self.cmbUnitsPhi.setToolTip("Set unit for phase.")
self.cmbUnitsPhi.setCurrentIndex(0)
self.cmbUnitsPhi.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.chkWrap = QCheckBox("Wrapped Phase", self)
self.chkWrap.setChecked(False)
self.chkWrap.setToolTip("Plot phase wrapped to +/- pi")
layHControls = QHBoxLayout()
layHControls.addWidget(self.cmbUnitsPhi)
layHControls.addWidget(self.chkWrap)
layHControls.addStretch(10)
#----------------------------------------------------------------------
# ### frmControls ###
#
# This widget encompasses all control subwidgets
#----------------------------------------------------------------------
self.frmControls = QFrame(self)
self.frmControls.setObjectName("frmControls")
self.frmControls.setLayout(layHControls)
#----------------------------------------------------------------------
# ### mplwidget ###
#
# main widget, encompassing the other widgets
#----------------------------------------------------------------------
self.mplwidget = MplWidget(self)
self.mplwidget.layVMainMpl.addWidget(self.frmControls)
self.mplwidget.layVMainMpl.setContentsMargins(*params['wdg_margins'])
self.setLayout(self.mplwidget.layVMainMpl)
self.init_axes()
self.draw() # initial drawing
#----------------------------------------------------------------------
# GLOBAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.sig_rx.connect(self.process_sig_rx)
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.chkWrap.clicked.connect(self.draw)
self.cmbUnitsPhi.currentIndexChanged.connect(self.unit_changed)
self.mplwidget.mplToolbar.sig_tx.connect(self.process_sig_rx)
#------------------------------------------------------------------------------
def init_axes(self):
"""
Initialize and clear the axes - this is only called once
"""
if len(self.mplwidget.fig.get_axes()) == 0: # empty figure, no axes
self.ax = self.mplwidget.fig.subplots()
self.ax.get_xaxis().tick_bottom() # remove axis ticks on top
self.ax.get_yaxis().tick_left() # remove axis ticks right
#------------------------------------------------------------------------------
def unit_changed(self):
"""
Unit for phase display has been changed, emit a 'view_changed' signal
and continue with drawing.
"""
self.sig_tx.emit({'sender': __name__, 'view_changed': 'plot_phi'})
self.draw()
#------------------------------------------------------------------------------
def calc_resp(self):
"""
(Re-)Calculate the complex frequency response H(f)
"""
# calculate H_cplx(W) (complex) for W = 0 ... 2 pi:
self.W, self.H_cmplx = calc_Hcomplex(fb.fil[0],
params['N_FFT'],
wholeF=True)
# replace nan and inf by finite values, otherwise np.unwrap yields
# an array full of nans
self.H_cmplx = np.nan_to_num(self.H_cmplx)
#------------------------------------------------------------------------------
def draw(self):
"""
Main entry point:
Re-calculate \|H(f)\| and draw the figure
"""
self.calc_resp()
self.update_view()
#------------------------------------------------------------------------------
def update_view(self):
"""
Draw the figure with new limits, scale etc without recalculating H(f)
"""
self.unitPhi = qget_cmb_box(self.cmbUnitsPhi, data=False)
f_S2 = fb.fil[0]['f_S'] / 2.
#========= select frequency range to be displayed =====================
#=== shift, scale and select: W -> F, H_cplx -> H_c
F = self.W * f_S2 / np.pi
if fb.fil[0]['freqSpecsRangeType'] == 'sym':
# shift H and F by f_S/2
H = np.fft.fftshift(self.H_cmplx)
F -= f_S2
elif fb.fil[0]['freqSpecsRangeType'] == 'half':
# only use the first half of H and F
H = self.H_cmplx[0:params['N_FFT'] // 2]
F = F[0:params['N_FFT'] // 2]
else: # fb.fil[0]['freqSpecsRangeType'] == 'whole'
# use H and F as calculated
H = self.H_cmplx
y_str = r'$\angle H(\mathrm{e}^{\mathrm{j} \Omega})$ in '
if self.unitPhi == 'rad':
y_str += 'rad ' + r'$\rightarrow $'
scale = 1.
elif self.unitPhi == 'rad/pi':
y_str += 'rad' + r'$ / \pi \;\rightarrow $'
scale = 1. / np.pi
else:
y_str += 'deg ' + r'$\rightarrow $'
scale = 180. / np.pi
fb.fil[0]['plt_phiLabel'] = y_str
fb.fil[0]['plt_phiUnit'] = self.unitPhi
if self.chkWrap.isChecked():
phi_plt = np.angle(H) * scale
else:
phi_plt = np.unwrap(np.angle(H)) * scale
#---------------------------------------------------------
self.ax.clear() # need to clear, doesn't overwrite
line_phi, = self.ax.plot(F, phi_plt)
#---------------------------------------------------------
self.ax.set_title(r'Phase Frequency Response')
self.ax.set_xlabel(fb.fil[0]['plt_fLabel'])
self.ax.set_ylabel(y_str)
self.ax.set_xlim(fb.fil[0]['freqSpecsRange'])
self.redraw()
#------------------------------------------------------------------------------
def redraw(self):
"""
Redraw the canvas when e.g. the canvas size has changed
"""
self.mplwidget.redraw()
class Input_Coeffs_UI(QWidget):
"""
Create the UI for the FilterCoeffs class
"""
sig_rx = pyqtSignal(dict) # incoming
sig_tx = pyqtSignal(dict) # outgoing
from pyfda.libs.pyfda_qt_lib import emit
def __init__(self, parent=None):
super(Input_Coeffs_UI, self).__init__(parent)
self.eps = 1.e-6 # initialize tolerance value
self._construct_UI()
# ------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig=None):
"""
Process signals coming from the CSV pop-up window
"""
# logger.debug("PROCESS_SIG_RX:\n{0}".format(pprint_log(dict_sig)))
if 'closeEvent' in dict_sig:
self._close_csv_win()
self.emit({'ui_changed': 'csv'})
return
elif 'ui_changed' in dict_sig:
self._set_load_save_icons() # update icons file <-> clipboard
# inform e.g. the p/z input widget about changes in CSV options
self.emit({'ui_changed': 'csv'})
# ------------------------------------------------------------------------------
def _construct_UI(self):
"""
Intitialize the widget, consisting of:
- top chkbox row
- coefficient table
- two bottom rows with action buttons
"""
self.bfont = QFont()
self.bfont.setBold(True)
self.bifont = QFont()
self.bifont.setBold(True)
self.bifont.setItalic(True)
# q_icon_size = QSize(20, 20) # optional, size is derived from butEnable
#######################################################################
# frmMain
#
# This frame contains all the buttons
#######################################################################
# ---------------------------------------------
# layHDisplay
#
# UI Elements for controlling the display
# ---------------------------------------------
self.butEnable = PushButton(self, icon=QIcon(':/circle-check.svg'), checked=True)
q_icon_size = self.butEnable.iconSize() # <- uncomment this for manual sizing
self.butEnable.setToolTip(
"<span>Show / hide filter coefficients in an editable table."
" For high order systems, table display might be slow.</span>")
fix_formats = ['Dec', 'Hex', 'Bin', 'CSD']
self.cmbFormat = QComboBox(self)
model = self.cmbFormat.model()
item = QtGui.QStandardItem('Float')
item.setData('child', Qt.AccessibleDescriptionRole)
model.appendRow(item)
item = QtGui.QStandardItem('Fixp.:')
item.setData('parent', Qt.AccessibleDescriptionRole)
item.setData(0, QtGui.QFont.Bold)
item.setFlags(item.flags() & ~Qt.ItemIsEnabled) # | Qt.ItemIsSelectable))
model.appendRow(item)
for idx in range(len(fix_formats)):
item = QtGui.QStandardItem(fix_formats[idx])
# item.setForeground(QtGui.QColor('red'))
model.appendRow(item)
self.cmbFormat.insertSeparator(1)
qset_cmb_box(self.cmbFormat, 'float')
self.cmbFormat.setToolTip('Set the display format.')
self.cmbFormat.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.spnDigits = QSpinBox(self)
self.spnDigits.setRange(0, 16)
self.spnDigits.setValue(params['FMT_ba'])
self.spnDigits.setToolTip("Number of digits to display.")
self.lblDigits = QLabel("Digits", self)
self.lblDigits.setFont(self.bifont)
self.cmbQFrmt = QComboBox(self)
q_formats = [('Norm. Frac.', 'qnfrac'), ('Integer', 'qint'),
('Fractional', 'qfrac')]
for q in q_formats:
self.cmbQFrmt.addItem(*q)
self.lbl_W = QLabel("W = ", self)
self.lbl_W.setFont(self.bifont)
self.ledW = QLineEdit(self)
self.ledW.setToolTip("Specify total wordlength.")
self.ledW.setText("16")
self.ledW.setMaxLength(2) # maximum of 2 digits
self.ledW.setFixedWidth(30) # width of lineedit in points(?)
layHDisplay = QHBoxLayout()
layHDisplay.setAlignment(Qt.AlignLeft)
layHDisplay.addWidget(self.butEnable)
layHDisplay.addWidget(self.cmbFormat)
layHDisplay.addWidget(self.spnDigits)
layHDisplay.addWidget(self.lblDigits)
layHDisplay.addWidget(self.cmbQFrmt)
layHDisplay.addWidget(self.lbl_W)
layHDisplay.addWidget(self.ledW)
layHDisplay.addStretch()
#######################################################################
# frmButtonsCoeffs
#
# This frame contains all buttons for manipulating coefficients
#######################################################################
# -----------------------------------------------------------------
# layHButtonsCoeffs1
#
# UI Elements for loading / storing / manipulating cells and rows
# -----------------------------------------------------------------
self.cmbFilterType = QComboBox(self)
self.cmbFilterType.setObjectName("comboFilterType")
self.cmbFilterType.setToolTip(
"<span>Select between IIR and FIR filter for manual entry."
"Changing the type reloads the filter from the filter dict.</span>")
self.cmbFilterType.addItems(["FIR", "IIR"])
self.cmbFilterType.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.butAddCells = QPushButton(self)
self.butAddCells.setIcon(QIcon(':/row_insert_above.svg'))
self.butAddCells.setIconSize(q_icon_size)
self.butAddCells.setToolTip(
"<span>Select cells to insert a new cell above each selected cell. "
"Use <SHIFT> or <CTRL> to select multiple cells. "
"When nothing is selected, add a row at the end.</span>")
self.butDelCells = QPushButton(self)
self.butDelCells.setIcon(QIcon(':/row_delete.svg'))
self.butDelCells.setIconSize(q_icon_size)
self.butDelCells.setToolTip(
"<span>Delete selected cell(s) from the table. "
"Use <SHIFT> or <CTRL> to select multiple cells. "
"When nothing is selected, delete the last row.</span>")
self.butSave = QPushButton(self)
self.butSave.setIcon(QIcon(':/upload.svg'))
self.butSave.setIconSize(q_icon_size)
self.butSave.setToolTip(
"<span>Copy coefficient table to filter dict and update all plots"
"and widgets.</span>")
self.butLoad = QPushButton(self)
self.butLoad.setIcon(QIcon(':/download.svg'))
self.butLoad.setIconSize(q_icon_size)
self.butLoad.setToolTip("Reload coefficient table from filter dict.")
self.butClear = QPushButton(self)
self.butClear.setIcon(QIcon(':/trash.svg'))
self.butClear.setIconSize(q_icon_size)
self.butClear.setToolTip("Clear all table entries.")
self.butFromTable = QPushButton(self)
self.butFromTable.setIconSize(q_icon_size)
self.butToTable = QPushButton(self)
self.butToTable.setIconSize(q_icon_size)
self.but_csv_options = PushButton(self, icon=QIcon(':/settings.svg'),
checked=False)
self.but_csv_options.setIconSize(q_icon_size)
self.but_csv_options.setToolTip(
"<span>Select CSV format and whether "
"to copy to/from clipboard or file.</span>")
self._set_load_save_icons() # initialize icon / button settings
layHButtonsCoeffs1 = QHBoxLayout()
layHButtonsCoeffs1.addWidget(self.cmbFilterType)
layHButtonsCoeffs1.addWidget(self.butAddCells)
layHButtonsCoeffs1.addWidget(self.butDelCells)
layHButtonsCoeffs1.addWidget(self.butClear)
layHButtonsCoeffs1.addWidget(self.butSave)
layHButtonsCoeffs1.addWidget(self.butLoad)
layHButtonsCoeffs1.addWidget(self.butFromTable)
layHButtonsCoeffs1.addWidget(self.butToTable)
layHButtonsCoeffs1.addWidget(self.but_csv_options)
layHButtonsCoeffs1.addStretch()
# ----------------------------------------------------------------------
# layHButtonsCoeffs2
#
# Eps / set zero settings
# ---------------------------------------------------------------------
self.butSetZero = QPushButton("= 0", self)
self.butSetZero.setToolTip(
"<span>Set selected coefficients = 0 with a magnitude < ε. "
"When nothing is selected, test the whole table.</span>")
self.butSetZero.setIconSize(q_icon_size)
lblEps = QLabel(self)
lblEps.setText("<b><i>for b, a</i> <</b>")
self.ledEps = QLineEdit(self)
self.ledEps.setToolTip("Specify tolerance value.")
layHButtonsCoeffs2 = QHBoxLayout()
layHButtonsCoeffs2.addWidget(self.butSetZero)
layHButtonsCoeffs2.addWidget(lblEps)
layHButtonsCoeffs2.addWidget(self.ledEps)
layHButtonsCoeffs2.addStretch()
# -------------------------------------------------------------------
# Now put the ButtonsCoeffs HBoxes into frmButtonsCoeffs
# ---------------------------------------------------------------------
layVButtonsCoeffs = QVBoxLayout()
layVButtonsCoeffs.addLayout(layHButtonsCoeffs1)
layVButtonsCoeffs.addLayout(layHButtonsCoeffs2)
layVButtonsCoeffs.setContentsMargins(0, 5, 0, 0)
# This frame encompasses all Quantization Settings
self.frmButtonsCoeffs = QFrame(self)
self.frmButtonsCoeffs.setLayout(layVButtonsCoeffs)
# ######################################################################
# frmQSettings
#
# This frame contains all quantization settings
# ######################################################################
# -------------------------------------------------------------------
# layHW_Scale
#
# QFormat and scale settings
# ---------------------------------------------------------------------
lbl_Q = QLabel("Q =", self)
lbl_Q.setFont(self.bifont)
self.ledWI = QLineEdit(self)
self.ledWI.setToolTip("Specify number of integer bits.")
self.ledWI.setText("0")
self.ledWI.setMaxLength(2) # maximum of 2 digits
self.ledWI.setFixedWidth(30) # width of lineedit in points(?)
self.lblDot = QLabel(".", self) # class attribute, visibility is toggled
self.lblDot.setFont(self.bfont)
self.ledWF = QLineEdit(self)
self.ledWF.setToolTip("Specify number of fractional bits.")
self.ledWF.setText("15")
self.ledWF.setMaxLength(2) # maximum of 2 digits
# self.ledWF.setFixedWidth(30) # width of lineedit in points(?)
self.ledWF.setMaximumWidth(30)
self.lblScale = QLabel("<b><i>Scale</i> =</b>", self)
self.ledScale = QLineEdit(self)
self.ledScale.setToolTip(
"Set the scale for converting float to fixpoint representation.")
self.ledScale.setText(str(1))
self.ledScale.setEnabled(False)
layHWI_WF = QHBoxLayout()
layHWI_WF.addWidget(lbl_Q)
layHWI_WF.addWidget(self.ledWI)
layHWI_WF.addWidget(self.lblDot)
layHWI_WF.addWidget(self.ledWF)
layHWI_WF.addStretch()
layHScale = QHBoxLayout()
layHScale.addWidget(self.lblScale)
layHScale.addWidget(self.ledScale)
layHScale.addStretch()
layHW_Scale = QHBoxLayout()
layHW_Scale.addLayout(layHWI_WF)
layHW_Scale.addLayout(layHScale)
# -------------------------------------------------------------------
# layGQOpt
#
# Quantization / Overflow / MSB / LSB settings
# ---------------------------------------------------------------------
lblQOvfl = QLabel("Ovfl.:", self)
lblQOvfl.setFont(self.bifont)
lblQuant = QLabel("Quant.:", self)
lblQuant.setFont(self.bifont)
self.cmbQOvfl = QComboBox(self)
qOvfl = ['wrap', 'sat']
self.cmbQOvfl.addItems(qOvfl)
qset_cmb_box(self.cmbQOvfl, 'sat')
self.cmbQOvfl.setToolTip("Select overflow behaviour.")
# ComboBox size is adjusted automatically to fit the longest element
self.cmbQOvfl.setSizeAdjustPolicy(QComboBox.AdjustToContents)
layHQOvflOpt = QHBoxLayout()
layHQOvflOpt.addWidget(lblQOvfl)
layHQOvflOpt.addWidget(self.cmbQOvfl)
layHQOvflOpt.addStretch()
self.cmbQuant = QComboBox(self)
qQuant = ['none', 'round', 'fix', 'floor']
self.cmbQuant.addItems(qQuant)
qset_cmb_box(self.cmbQuant, 'round')
self.cmbQuant.setToolTip("Select the kind of quantization.")
self.cmbQuant.setSizeAdjustPolicy(QComboBox.AdjustToContents)
layHQuantOpt = QHBoxLayout()
layHQuantOpt.addWidget(lblQuant)
layHQuantOpt.addWidget(self.cmbQuant)
layHQuantOpt.addStretch()
self.butQuant = QPushButton(self)
self.butQuant.setToolTip(
"<span>Quantize selected coefficients / "
"whole table with specified settings.</span>")
self.butQuant.setIcon(QIcon(':/quantize.svg'))
self.butQuant.setIconSize(q_icon_size)
self.butQuant.setSizePolicy(QSizePolicy.Fixed, QSizePolicy.Fixed)
lblMSBtxt = QLabel(self)
lblMSBtxt.setText("<b><i>MSB</i><sub>10</sub> =</b>")
self.lblMSB = QLabel(self)
layHMSB = QHBoxLayout()
layHMSB.addWidget(lblMSBtxt)
layHMSB.addWidget(self.lblMSB)
layHMSB.addStretch()
lblLSBtxt = QLabel(self)
lblLSBtxt.setText("<b><i>LSB</i><sub>10</sub> =</b>")
self.lblLSB = QLabel(self)
layHLSB = QHBoxLayout()
layHLSB.addWidget(lblLSBtxt)
layHLSB.addWidget(self.lblLSB)
layHLSB.addStretch()
layGQOpt = QGridLayout()
layGQOpt.addLayout(layHQOvflOpt, 0, 0)
layGQOpt.addLayout(layHQuantOpt, 0, 1)
layGQOpt.addWidget(self.butQuant, 0, 2, Qt.AlignCenter)
layGQOpt.addLayout(layHMSB, 1, 0)
layGQOpt.addLayout(layHLSB, 1, 1)
# -------------------------------------------------------------------
# Display MAX
# ---------------------------------------------------------------------
lblMAXtxt = QLabel(self)
lblMAXtxt.setText("<b><i>Max =</i></b>")
self.lblMAX = QLabel(self)
layHCoeffs_MAX = QHBoxLayout()
layHCoeffs_MAX.addWidget(lblMAXtxt)
layHCoeffs_MAX.addWidget(self.lblMAX)
layHCoeffs_MAX.addStretch()
#######################################################################
# Now put all the coefficient HBoxes into frmQSettings
# ---------------------------------------------------------------------
layVButtonsQ = QVBoxLayout()
layVButtonsQ.addLayout(layHW_Scale)
layVButtonsQ.addLayout(layGQOpt)
layVButtonsQ.addLayout(layHCoeffs_MAX)
layVButtonsQ.setContentsMargins(0, 0, 0, 0)
# This frame encompasses all Quantization Settings
self.frmQSettings = QFrame(self)
self.frmQSettings.setLayout(layVButtonsQ)
#######################################################################
# ######################## Main UI Layout ############################
#######################################################################
# layout for frame (UI widget)
layVMainF = QVBoxLayout()
layVMainF.addLayout(layHDisplay)
layVMainF.addWidget(self.frmQSettings)
layVMainF.addWidget(QHLine())
layVMainF.addWidget(self.frmButtonsCoeffs)
# This frame encompasses all UI elements
frmMain = QFrame(self)
frmMain.setLayout(layVMainF)
layVMain = QVBoxLayout()
# the following affects only the first widget (intended here)
layVMain.setAlignment(Qt.AlignTop)
layVMain.addWidget(frmMain)
layVMain.setContentsMargins(*params['wdg_margins'])
self.setLayout(layVMain)
#######################################################################
# --- set initial values from dict ------------
self.spnDigits.setValue(params['FMT_ba'])
self.ledEps.setText(str(self.eps))
# ----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
# ----------------------------------------------------------------------
self.but_csv_options.clicked.connect(self._open_csv_win)
# --------------------------------------------------------------------------
def _open_csv_win(self):
"""
Pop-up window for CSV options
"""
if self.but_csv_options.isChecked():
qstyle_widget(self.but_csv_options, "changed")
else:
qstyle_widget(self.but_csv_options, "normal")
if dirs.csv_options_handle is None:
# no handle to the window? Create a new instance
if self.but_csv_options.isChecked():
# Important: Handle to window must be class attribute, otherwise it
# (and the attached window) is deleted immediately when it goes
# out of scope
dirs.csv_options_handle = CSV_option_box(self)
dirs.csv_options_handle.sig_tx.connect(self.process_sig_rx)
dirs.csv_options_handle.show() # modeless i.e. non-blocking popup window
else:
if not self.but_csv_options.isChecked(): # this should not happen
if dirs.csv_options_handle is None:
logger.warning("CSV options window is already closed!")
else:
dirs.csv_options_handle.close()
self.emit({'ui_changed': 'csv'})
# ------------------------------------------------------------------------------
def _close_csv_win(self):
dirs.csv_options_handle = None
self.but_csv_options.setChecked(False)
qstyle_widget(self.but_csv_options, "normal")
# ------------------------------------------------------------------------------
def _set_load_save_icons(self):
"""
Set icons / tooltipps for loading and saving data to / from file or
clipboard depending on selected options.
"""
if params['CSV']['clipboard']:
self.butFromTable.setIcon(QIcon(':/to_clipboard.svg'))
self.butFromTable.setToolTip(
"<span>Copy table to clipboard, SELECTED items are copied as "
"displayed. When nothing is selected, the whole table "
"is copied with full precision in decimal format.</span>")
self.butToTable.setIcon(QIcon(':/from_clipboard.svg'))
self.butToTable.setToolTip("<span>Copy clipboard to table.</span>")
else:
self.butFromTable.setIcon(QIcon(':/save.svg'))
self.butFromTable.setToolTip(
"<span>"
"Save table to file, SELECTED items are copied as "
"displayed. When nothing is selected, the whole table "
"is copied with full precision in decimal format.</span>")
self.butToTable.setIcon(QIcon(':/file.svg'))
self.butToTable.setToolTip("<span>Load table from file.</span>")
if dirs.csv_options_handle is None:
qstyle_widget(self.but_csv_options, "normal")
self.but_csv_options.setChecked(False)
else:
qstyle_widget(self.but_csv_options, "changed")
self.but_csv_options.setChecked(True)
class FreqUnits(QWidget):
"""
Build and update widget for entering the frequency units
The following key-value pairs of the `fb.fil[0]` dict are modified:
- `'freq_specs_unit'` : The unit ('k', 'f_S', 'f_Ny', 'Hz' etc.) as a string
- `'freqSpecsRange'` : A list with two entries for minimum and maximum frequency
values for labelling the frequency axis
- `'f_S'` : The sampling frequency for referring frequency values to as a float
- `'f_max'` : maximum frequency for scaling frequency axis
- `'plt_fUnit'`: frequency unit as string
- `'plt_tUnit'`: time unit as string
- `'plt_fLabel'`: label for frequency axis
- `'plt_tLabel'`: label for time axis
"""
# class variables (shared between instances if more than one exists)
sig_tx = pyqtSignal(object) # outgoing
def __init__(self, parent, title="Frequency Units"):
super(FreqUnits, self).__init__(parent)
self.title = title
self.spec_edited = False # flag whether QLineEdit field has been edited
self._construct_UI()
def _construct_UI(self):
"""
Construct the User Interface
"""
self.layVMain = QVBoxLayout() # Widget main layout
f_units = ['k', 'f_S', 'f_Ny', 'Hz', 'kHz', 'MHz', 'GHz']
self.t_units = ['', '', '', 's', 'ms', r'$\mu$s', 'ns']
bfont = QFont()
bfont.setBold(True)
self.lblUnits = QLabel(self)
self.lblUnits.setText("Freq. Unit:")
self.lblUnits.setFont(bfont)
self.fs_old = fb.fil[0]['f_S'] # store current sampling frequency
self.ledF_S = QLineEdit()
self.ledF_S.setText(str(fb.fil[0]["f_S"]))
self.ledF_S.setObjectName("f_S")
self.ledF_S.installEventFilter(self) # filter events
self.lblF_S = QLabel(self)
self.lblF_S.setText(to_html("f_S", frmt='bi'))
self.cmbUnits = QComboBox(self)
self.cmbUnits.setObjectName("cmbUnits")
self.cmbUnits.addItems(f_units)
self.cmbUnits.setToolTip(
'Select whether frequencies are specified w.r.t. \n'
'the sampling frequency "f_S", to the Nyquist frequency \n'
'f_Ny = f_S/2 or as absolute values. "k" specifies frequencies w.r.t. f_S '
'but plots graphs over the frequency index k.')
self.cmbUnits.setCurrentIndex(1)
# self.cmbUnits.setItemData(0, (0,QColor("#FF333D"),Qt.BackgroundColorRole))#
# self.cmbUnits.setItemData(0, (QFont('Verdana', bold=True), Qt.FontRole)
fRanges = [("0...½", "half"), ("0...1", "whole"), ("-½...½", "sym")]
self.cmbFRange = QComboBox(self)
self.cmbFRange.setObjectName("cmbFRange")
for f in fRanges:
self.cmbFRange.addItem(f[0], f[1])
self.cmbFRange.setToolTip("Select frequency range (whole or half).")
self.cmbFRange.setCurrentIndex(0)
# Combobox resizes with longest entry
self.cmbUnits.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.cmbFRange.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.butSort = QToolButton(self)
self.butSort.setText("Sort")
self.butSort.setCheckable(True)
self.butSort.setChecked(True)
self.butSort.setToolTip(
"Sort frequencies in ascending order when pushed.")
self.butSort.setStyleSheet("QToolButton:checked {font-weight:bold}")
self.layHUnits = QHBoxLayout()
self.layHUnits.addWidget(self.cmbUnits)
self.layHUnits.addWidget(self.cmbFRange)
self.layHUnits.addWidget(self.butSort)
# Create a gridLayout consisting of QLabel and QLineEdit fields
# for setting f_S, the units and the actual frequency specs:
self.layGSpecWdg = QGridLayout() # sublayout for spec fields
self.layGSpecWdg.addWidget(self.lblF_S, 1, 0)
self.layGSpecWdg.addWidget(self.ledF_S, 1, 1)
self.layGSpecWdg.addWidget(self.lblUnits, 0, 0)
self.layGSpecWdg.addLayout(self.layHUnits, 0, 1)
frmMain = QFrame(self)
frmMain.setLayout(self.layGSpecWdg)
self.layVMain.addWidget(frmMain)
self.layVMain.setContentsMargins(*params['wdg_margins'])
self.setLayout(self.layVMain)
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.cmbUnits.currentIndexChanged.connect(self.update_UI)
self.cmbFRange.currentIndexChanged.connect(self._freq_range)
self.butSort.clicked.connect(self._store_sort_flag)
#----------------------------------------------------------------------
self.update_UI() # first-time initialization
#-------------------------------------------------------------
def update_UI(self):
"""
Transform the displayed frequency spec input fields according to the units
setting. Spec entries are always stored normalized w.r.t. f_S in the
dictionary; when f_S or the unit are changed, only the displayed values
of the frequency entries are updated, not the dictionary!
Signals are blocked before changing the value for f_S programmatically
update_UI is called
- during init
- when the unit combobox is changed
Finally, store freqSpecsRange and emit 'view_changed' signal via _freq_range
"""
idx = self.cmbUnits.currentIndex() # read index of units combobox
f_unit = str(self.cmbUnits.currentText()) # and the label
self.ledF_S.setVisible(f_unit not in {"f_S", "f_Ny",
"k"}) # only vis. when
self.lblF_S.setVisible(f_unit not in {"f_S", "f_Ny",
"k"}) # not normalized
f_S_scale = 1 # default setting for f_S scale
if f_unit in {"f_S", "f_Ny", "k"}: # normalized frequency
self.fs_old = fb.fil[0]['f_S'] # store current sampling frequency
if f_unit == "f_S": # normalized to f_S
fb.fil[0]['f_S'] = fb.fil[0]['f_max'] = 1.
f_label = r"$F = f\, /\, f_S = \Omega \, /\, 2 \mathrm{\pi} \; \rightarrow$"
elif f_unit == "f_Ny": # idx == 1: normalized to f_nyq = f_S / 2
fb.fil[0]['f_S'] = fb.fil[0]['f_max'] = 2.
f_label = r"$F = 2f \, / \, f_S = \Omega \, / \, \mathrm{\pi} \; \rightarrow$"
else:
fb.fil[0]['f_S'] = 1
fb.fil[0]['f_max'] = params['N_FFT']
f_label = r"$k \; \rightarrow$"
t_label = r"$n \; \rightarrow$"
self.ledF_S.setText(params['FMT'].format(fb.fil[0]['f_S']))
else: # Hz, kHz, ...
if fb.fil[0]['freq_specs_unit'] in {"f_S", "f_Ny",
"k"}: # previous setting
fb.fil[0]['f_S'] = fb.fil[0][
'f_max'] = self.fs_old # restore prev. sampling frequency
self.ledF_S.setText(params['FMT'].format(fb.fil[0]['f_S']))
if f_unit == "Hz":
f_S_scale = 1.
elif f_unit == "kHz":
f_S_scale = 1.e3
elif f_unit == "MHz":
f_S_scale = 1.e6
elif f_unit == "GHz":
f_S_scale = 1.e9
else:
logger.warning("Unknown frequency unit {0}".format(f_unit))
f_label = r"$f$ in " + f_unit + r"$\; \rightarrow$"
t_label = r"$t$ in " + self.t_units[idx] + r"$\; \rightarrow$"
if f_unit == "k":
plt_f_unit = "f_S"
else:
plt_f_unit = f_unit
fb.fil[0].update({'f_S_scale': f_S_scale}) # scale factor for f_S
fb.fil[0].update({'freq_specs_unit': f_unit}) # frequency unit
fb.fil[0].update({"plt_fLabel": f_label}) # label for freq. axis
fb.fil[0].update({"plt_tLabel": t_label}) # label for time axis
fb.fil[0].update({"plt_fUnit": plt_f_unit}) # frequency unit as string
fb.fil[0].update({"plt_tUnit":
self.t_units[idx]}) # time unit as string
self._freq_range(
) # update f_lim setting and emit sigUnitChanged signal
#------------------------------------------------------------------------------
def eventFilter(self, source, event):
"""
Filter all events generated by the QLineEdit widgets. Source and type
of all events generated by monitored objects are passed to this eventFilter,
evaluated and passed on to the next hierarchy level.
- When a QLineEdit widget gains input focus (QEvent.FocusIn`), display
the stored value from filter dict with full precision
- When a key is pressed inside the text field, set the `spec_edited` flag
to True.
- When a QLineEdit widget loses input focus (QEvent.FocusOut`), store
current value with full precision (only if `spec_edited`== True) and
display the stored value in selected format. Emit 'view_changed':'f_S'
"""
def _store_entry():
"""
Update filter dictionary, set line edit entry with reduced precision
again.
"""
if self.spec_edited:
fb.fil[0].update({
'f_S':
safe_eval(source.text(), fb.fil[0]['f_S'], sign='pos')
})
# TODO: ?!
self._freq_range(emit_sig_range=False) # update plotting range
self.sig_tx.emit({'sender': __name__, 'view_changed': 'f_S'})
self.spec_edited = False # reset flag, changed entry has been saved
if source.objectName() == 'f_S':
if event.type() == QEvent.FocusIn:
self.spec_edited = False
source.setText(str(fb.fil[0]['f_S'])) # full precision
elif event.type() == QEvent.KeyPress:
self.spec_edited = True # entry has been changed
key = event.key()
if key in {QtCore.Qt.Key_Return, QtCore.Qt.Key_Enter}:
_store_entry()
elif key == QtCore.Qt.Key_Escape: # revert changes
self.spec_edited = False
source.setText(str(fb.fil[0]['f_S'])) # full precision
elif event.type() == QEvent.FocusOut:
_store_entry()
source.setText(params['FMT'].format(
fb.fil[0]['f_S'])) # reduced precision
# Call base class method to continue normal event processing:
return super(FreqUnits, self).eventFilter(source, event)
#-------------------------------------------------------------
def _freq_range(self, emit_sig_range=True):
"""
Set frequency plotting range for single-sided spectrum up to f_S/2 or f_S
or for double-sided spectrum between -f_S/2 and f_S/2 and emit
'view_changed':'f_range'.
"""
rangeType = qget_cmb_box(self.cmbFRange)
fb.fil[0].update({'freqSpecsRangeType': rangeType})
f_max = fb.fil[0]["f_max"]
if rangeType == 'whole':
f_lim = [0, f_max]
elif rangeType == 'sym':
f_lim = [-f_max / 2., f_max / 2.]
else:
f_lim = [0, f_max / 2.]
fb.fil[0]['freqSpecsRange'] = f_lim # store settings in dict
self.sig_tx.emit({'sender': __name__, 'view_changed': 'f_range'})
#-------------------------------------------------------------
def load_dict(self):
"""
Reload comboBox settings and textfields from filter dictionary
Block signals during update of combobox / lineedit widgets
"""
self.ledF_S.setText(params['FMT'].format(fb.fil[0]['f_S']))
self.cmbUnits.blockSignals(True)
idx = self.cmbUnits.findText(
fb.fil[0]['freq_specs_unit']) # get and set
self.cmbUnits.setCurrentIndex(idx) # index for freq. unit combo box
self.cmbUnits.blockSignals(False)
self.cmbFRange.blockSignals(True)
idx = self.cmbFRange.findData(fb.fil[0]['freqSpecsRangeType'])
self.cmbFRange.setCurrentIndex(idx) # set frequency range
self.cmbFRange.blockSignals(False)
self.butSort.blockSignals(True)
self.butSort.setChecked(fb.fil[0]['freq_specs_sort'])
self.butSort.blockSignals(False)
#-------------------------------------------------------------
def _store_sort_flag(self):
"""
Store sort flag in filter dict and emit 'specs_changed':'f_sort'
when sort button is checked.
"""
fb.fil[0]['freq_specs_sort'] = self.butSort.isChecked()
if self.butSort.isChecked():
self.sig_tx.emit({'sender': __name__, 'specs_changed': 'f_sort'})
class Input_Fixpoint_Specs(QWidget):
"""
Create the widget that holds the dynamically loaded fixpoint filter ui
"""
# sig_resize = pyqtSignal() # emit a signal when the image has been resized
sig_rx_local = pyqtSignal(object) # incoming from subwidgets -> process_sig_rx_local
sig_rx = pyqtSignal(object) # incoming, connected to input_tab_widget.sig_rx
sig_tx = pyqtSignal(object) # outcgoing
from pyfda.libs.pyfda_qt_lib import emit
def __init__(self, parent=None):
super(Input_Fixpoint_Specs, self).__init__(parent)
self.tab_label = 'Fixpoint'
self.tool_tip = ("<span>Select a fixpoint implementation for the filter,"
" simulate it or generate a Verilog netlist.</span>")
self.parent = parent
self.fx_path = os.path.realpath(
os.path.join(dirs.INSTALL_DIR, 'fixpoint_widgets'))
self.no_fx_filter_img = os.path.join(self.fx_path, "no_fx_filter.png")
if not os.path.isfile(self.no_fx_filter_img):
logger.error("Image {0:s} not found!".format(self.no_fx_filter_img))
self.default_fx_img = os.path.join(self.fx_path, "default_fx_img.png")
if not os.path.isfile(self.default_fx_img):
logger.error("Image {0:s} not found!".format(self.default_fx_img))
self._construct_UI()
inst_wdg_list = self._update_filter_cmb()
if len(inst_wdg_list) == 0:
logger.warning("No fixpoint filter found for this type of filter!")
else:
logger.debug("Imported {0:d} fixpoint filters:\n{1}"
.format(len(inst_wdg_list.split("\n"))-1, inst_wdg_list))
self._update_fixp_widget()
# ------------------------------------------------------------------------------
def process_sig_rx_local(self, dict_sig: dict = None) -> None:
"""
Process signals coming in from input and output quantizer subwidget and the
dynamically instantiated subwidget and emit {'fx_sim': 'specs_changed'} in
the end.
"""
if dict_sig['id'] == id(self):
logger.warning(f'RX_LOCAL - Stopped infinite loop: "{first_item(dict_sig)}"')
return
elif 'fx_sim' in dict_sig and dict_sig['fx_sim'] == 'specs_changed':
self.wdg_dict2ui() # update wordlengths in UI and set RUN button to 'changed'
dict_sig.update({'id': id(self)}) # propagate 'specs_changed' with self 'id'
self.emit(dict_sig)
return
# ---- Process input and output quantizer settings ('ui' in dict_sig) --
elif 'ui' in dict_sig:
if 'wdg_name' not in dict_sig:
logger.warning(f"No key 'wdg_name' in dict_sig:\n{pprint_log(dict_sig)}")
return
elif dict_sig['wdg_name'] == 'w_input':
"""
Input fixpoint format has been changed or butLock has been clicked.
When I/O lock is active, copy input fixpoint word format to output
word format.
"""
if dict_sig['ui'] == 'butLock'\
and not self.wdg_w_input.butLock.isChecked():
# butLock was deactivitated, don't do anything
return
elif self.wdg_w_input.butLock.isChecked():
# but lock was activated or wordlength setting have been changed
fb.fil[0]['fxqc']['QO']['WI'] = fb.fil[0]['fxqc']['QI']['WI']
fb.fil[0]['fxqc']['QO']['WF'] = fb.fil[0]['fxqc']['QI']['WF']
fb.fil[0]['fxqc']['QO']['W'] = fb.fil[0]['fxqc']['QI']['W']
elif dict_sig['wdg_name'] == 'w_output':
"""
Output fixpoint format has been changed. When I/O lock is active, copy
output fixpoint word format to input word format.
"""
if self.wdg_w_input.butLock.isChecked():
fb.fil[0]['fxqc']['QI']['WI'] = fb.fil[0]['fxqc']['QO']['WI']
fb.fil[0]['fxqc']['QI']['WF'] = fb.fil[0]['fxqc']['QO']['WF']
fb.fil[0]['fxqc']['QI']['W'] = fb.fil[0]['fxqc']['QO']['W']
elif dict_sig['wdg_name'] in {'q_output', 'q_input'}:
pass
else:
logger.error("Unknown wdg_name '{0}' in dict_sig:\n{1}"
.format(dict_sig['wdg_name'], pprint_log(dict_sig)))
return
if dict_sig['ui'] not in {'WI', 'WF', 'ovfl', 'quant', 'cmbW', 'butLock'}:
logger.warning("Unknown value '{0}' for key 'ui'".format(dict_sig['ui']))
self.wdg_dict2ui() # update wordlengths in UI and set RUN button to 'changed'
self.emit({'fx_sim': 'specs_changed'}) # propagate 'specs_changed'
else:
logger.error(f"Unknown key/value in 'dict_sig':\n{pprint_log(dict_sig)}")
# ------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig: dict = None) -> None:
"""
Process signals coming in via `sig_rx` from other widgets.
Trigger fx simulation:
1. ``fx_sim': 'init'``: Start fixpoint simulation by sending
'fx_sim':'start_fx_response_calculation'
2. ``fx_sim_calc_response()``: Receive stimulus from widget in
'fx_sim':'calc_frame_fx_response' and pass it to fixpoint simulation method
3. Store fixpoint response in `fb.fx_result` and return to initiating routine
"""
# logger.info(
# "SIG_RX(): vis={0}\n{1}".format(self.isVisible(), pprint_log(dict_sig)))
# logger.debug(f'SIG_RX(): "{first_item(dict_sig)}"')
if dict_sig['id'] == id(self):
# logger.warning(f'Stopped infinite loop: "{first_item(dict_sig)}"')
return
elif 'data_changed' in dict_sig and dict_sig['data_changed'] == "filter_designed":
# New filter has been designed, update list of available filter topologies
self._update_filter_cmb()
return
elif 'data_changed' in dict_sig or\
('view_changed' in dict_sig and dict_sig['view_changed'] == 'q_coeff'):
# Filter data has changed (but not the filter type) or the coefficient
# format / wordlength have been changed in `input_coeffs`. The latter means
# the view / display has been changed (wordlength) but not the actual
# coefficients in the `input_coeffs` widget. However, the wordlength setting
# is copied to the fxqc dict and from there to the fixpoint widget.
# - update fields in the fixpoint filter widget - wordlength may have
# been changed.
# - Set RUN button to "changed" in wdg_dict2ui()
self.wdg_dict2ui()
# --------------- FX Simulation -------------------------------------------
elif 'fx_sim' in dict_sig:
if dict_sig['fx_sim'] == 'init':
# fixpoint simulation has been started externally, e.g. by
# `impz.impz_init()`, return a handle to the fixpoint filter function
# via signal-slot connection
if not self.fx_wdg_found:
logger.error("No fixpoint widget found!")
qstyle_widget(self.butSimFx, "error")
self.emit({'fx_sim': 'error'})
elif self.fx_sim_init() != 0: # returned an error
qstyle_widget(self.butSimFx, "error")
self.emit({'fx_sim': 'error'})
else:
self.emit({'fx_sim': 'start_fx_response_calculation',
'fxfilter_func': self.fx_filt_ui.fxfilter})
elif dict_sig['fx_sim'] == 'calc_frame_fx_response':
self.fx_sim_calc_response(dict_sig)
# return to the routine collecting the response frame by frame
return
elif dict_sig['fx_sim'] == 'specs_changed':
# fixpoint specification have been changed somewhere, update ui
# and set run button to "changed" in wdg_dict2ui()
self.wdg_dict2ui()
elif dict_sig['fx_sim'] == 'finish':
qstyle_widget(self.butSimFx, "normal")
else:
logger.error('Unknown "fx_sim" command option "{0}"\n'
'\treceived from "{1}".'
.format(dict_sig['fx_sim'], dict_sig['class']))
# ---- resize image when "Fixpoint" tab is selected or widget size is changed:
elif 'ui_changed' in dict_sig and dict_sig['ui_changed'] in {'resized', 'tab'}\
and self.isVisible():
self.resize_img()
# ------------------------------------------------------------------------------
def _construct_UI(self) -> None:
"""
Intitialize the main GUI, consisting of:
- A combo box to select the filter topology and an image of the topology
- The input quantizer
- The UI of the fixpoint filter widget
- Simulation and export buttons
"""
# ------------------------------------------------------------------------------
# Define frame and layout for the dynamically updated filter widget
# The actual filter widget is instantiated in self.set_fixp_widget() later on
self.layH_fx_wdg = QHBoxLayout()
# self.layH_fx_wdg.setContentsMargins(*params['wdg_margins'])
frmHDL_wdg = QFrame(self)
frmHDL_wdg.setLayout(self.layH_fx_wdg)
# frmHDL_wdg.setSizePolicy(QSizePolicy.Minimum, QSizePolicy.Minimum)
# ------------------------------------------------------------------------------
# Initialize fixpoint filter combobox, title and description
# ------------------------------------------------------------------------------
self.cmb_fx_wdg = QComboBox(self)
self.cmb_fx_wdg.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.lblTitle = QLabel("not set", self)
self.lblTitle.setWordWrap(True)
self.lblTitle.setSizePolicy(QSizePolicy.Expanding, QSizePolicy.Fixed)
layHTitle = QHBoxLayout()
layHTitle.addWidget(self.cmb_fx_wdg)
layHTitle.addWidget(self.lblTitle)
self.frmTitle = QFrame(self)
self.frmTitle.setLayout(layHTitle)
self.frmTitle.setContentsMargins(*params['wdg_margins'])
# ------------------------------------------------------------------------------
# Input and Output Quantizer
# ------------------------------------------------------------------------------
# - instantiate widgets for input and output quantizer
# - pass the quantization (sub-?) dictionary to the constructor
# ------------------------------------------------------------------------------
self.wdg_w_input = UI_W(self, q_dict=fb.fil[0]['fxqc']['QI'],
wdg_name='w_input', label='', lock_visible=True)
self.wdg_w_input.sig_tx.connect(self.process_sig_rx_local)
cmb_q = ['round', 'floor', 'fix']
self.wdg_w_output = UI_W(self, q_dict=fb.fil[0]['fxqc']['QO'],
wdg_name='w_output', label='')
self.wdg_w_output.sig_tx.connect(self.process_sig_rx_local)
self.wdg_q_output = UI_Q(self, q_dict=fb.fil[0]['fxqc']['QO'],
wdg_name='q_output',
label='Output Format <i>Q<sub>Y </sub></i>:',
cmb_q=cmb_q, cmb_ov=['wrap', 'sat'])
self.wdg_q_output.sig_tx.connect(self.sig_rx_local)
if HAS_DS:
cmb_q.append('dsm')
self.wdg_q_input = UI_Q(self, q_dict=fb.fil[0]['fxqc']['QI'],
wdg_name='q_input',
label='Input Format <i>Q<sub>X </sub></i>:',
cmb_q=cmb_q)
self.wdg_q_input.sig_tx.connect(self.sig_rx_local)
# Layout and frame for input quantization
layVQiWdg = QVBoxLayout()
layVQiWdg.addWidget(self.wdg_q_input)
layVQiWdg.addWidget(self.wdg_w_input)
frmQiWdg = QFrame(self)
# frmBtns.setFrameStyle(QFrame.StyledPanel|QFrame.Sunken)
frmQiWdg.setLayout(layVQiWdg)
frmQiWdg.setContentsMargins(*params['wdg_margins'])
# Layout and frame for output quantization
layVQoWdg = QVBoxLayout()
layVQoWdg.addWidget(self.wdg_q_output)
layVQoWdg.addWidget(self.wdg_w_output)
frmQoWdg = QFrame(self)
# frmBtns.setFrameStyle(QFrame.StyledPanel|QFrame.Sunken)
frmQoWdg.setLayout(layVQoWdg)
frmQoWdg.setContentsMargins(*params['wdg_margins'])
# ------------------------------------------------------------------------------
# Dynamically updated image of filter topology (label as placeholder)
# ------------------------------------------------------------------------------
# allow setting background color
# lbl_fixp_img_palette = QPalette()
# lbl_fixp_img_palette.setColor(QPalette(window, Qt: white))
# lbl_fixp_img_palette.setBrush(self.backgroundRole(), QColor(150, 0, 0))
# lbl_fixp_img_palette.setColor(QPalette: WindowText, Qt: blue)
self.lbl_fixp_img = QLabel("img not set", self)
self.lbl_fixp_img.setAutoFillBackground(True)
# self.lbl_fixp_img.setPalette(lbl_fixp_img_palette)
# self.lbl_fixp_img.setSizePolicy(QSizePolicy.Minimum, QSizePolicy.Minimum)
self.embed_fixp_img(self.no_fx_filter_img)
layHImg = QHBoxLayout()
layHImg.setContentsMargins(0, 0, 0, 0)
layHImg.addWidget(self.lbl_fixp_img) # , Qt.AlignCenter)
self.frmImg = QFrame(self)
self.frmImg.setLayout(layHImg)
self.frmImg.setContentsMargins(*params['wdg_margins'])
# ------------------------------------------------------------------------------
# Simulation and export Buttons
# ------------------------------------------------------------------------------
self.butExportHDL = QPushButton(self)
self.butExportHDL.setToolTip(
"Create Verilog or VHDL netlist for fixpoint filter.")
self.butExportHDL.setText("Create HDL")
self.butSimFx = QPushButton(self)
self.butSimFx.setToolTip("Start fixpoint simulation.")
self.butSimFx.setText("Sim. FX")
self.layHHdlBtns = QHBoxLayout()
self.layHHdlBtns.addWidget(self.butSimFx)
self.layHHdlBtns.addWidget(self.butExportHDL)
# This frame encompasses the HDL buttons sim and convert
frmHdlBtns = QFrame(self)
# frmBtns.setFrameStyle(QFrame.StyledPanel|QFrame.Sunken)
frmHdlBtns.setLayout(self.layHHdlBtns)
frmHdlBtns.setContentsMargins(*params['wdg_margins'])
# -------------------------------------------------------------------
# Top level layout
# -------------------------------------------------------------------
splitter = QSplitter(self)
splitter.setOrientation(Qt.Vertical)
splitter.addWidget(frmHDL_wdg)
splitter.addWidget(frmQoWdg)
splitter.addWidget(self.frmImg)
# setSizes uses absolute pixel values, but can be "misused" by specifying values
# that are way too large: in this case, the space is distributed according
# to the _ratio_ of the values:
splitter.setSizes([3000, 3000, 5000])
layVMain = QVBoxLayout()
layVMain.addWidget(self.frmTitle)
layVMain.addWidget(frmHdlBtns)
layVMain.addWidget(frmQiWdg)
layVMain.addWidget(splitter)
layVMain.addStretch()
layVMain.setContentsMargins(*params['wdg_margins'])
self.setLayout(layVMain)
# ----------------------------------------------------------------------
# GLOBAL SIGNALS & SLOTs
# ----------------------------------------------------------------------
self.sig_rx.connect(self.process_sig_rx)
self.sig_rx_local.connect(self.process_sig_rx_local)
# dynamic connection in `self._update_fixp_widget()`:
# -----
# if hasattr(self.fx_filt_ui, "sig_rx"):
# self.sig_rx.connect(self.fx_filt_ui.sig_rx)
# if hasattr(self.fx_filt_ui, "sig_tx"):
# self.fx_filt_ui.sig_tx.connect(self.sig_rx_local)
# ----
# ----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
# ----------------------------------------------------------------------
self.cmb_fx_wdg.currentIndexChanged.connect(self._update_fixp_widget)
self.butExportHDL.clicked.connect(self.exportHDL)
self.butSimFx.clicked.connect(lambda x: self.emit({'fx_sim': 'start'}))
# ----------------------------------------------------------------------
# EVENT FILTER
# ----------------------------------------------------------------------
# # monitor events and generate sig_resize event when resized
# self.lbl_fixp_img.installEventFilter(self)
# # ... then redraw image when resized
# self.sig_resize.connect(self.resize_img)
# ------------------------------------------------------------------------------
def _update_filter_cmb(self) -> str:
"""
(Re-)Read list of available fixpoint filters for a given filter design
every time a new filter design is selected.
Then try to import the fixpoint designs in the list and populate the
fixpoint implementation combo box `self.cmb_fx_wdg` when successfull.
Returns
-------
inst_wdg_str: str
string with all fixpoint widgets that could be instantiated successfully
"""
inst_wdg_str = "" # full names of successfully instantiated widgets for logging
# remember last fx widget setting:
last_fx_wdg = qget_cmb_box(self.cmb_fx_wdg, data=False)
self.cmb_fx_wdg.clear()
fc = fb.fil[0]['fc']
if 'fix' in fb.filter_classes[fc]:
self.cmb_fx_wdg.blockSignals(True)
for class_name in fb.filter_classes[fc]['fix']: # get class name
try: # construct module + class name ...
mod_class_name = fb.fixpoint_classes[class_name]['mod'] + '.'\
+ class_name
# ... and display name
disp_name = fb.fixpoint_classes[class_name]['name']
self.cmb_fx_wdg.addItem(disp_name, mod_class_name)
inst_wdg_str += '\t' + class_name + ' : ' + mod_class_name + '\n'
except AttributeError as e:
logger.warning('Widget "{0}":\n{1}'.format(class_name, e))
self.embed_fixp_img(self.no_fx_filter_img)
continue # with next `class_name` of for loop
except KeyError as e:
logger.warning("No fixpoint filter for filter type {0} available."
.format(e))
self.embed_fixp_img(self.no_fx_filter_img)
continue # with next `class_name` of for loop
# restore last fx widget if possible
idx = self.cmb_fx_wdg.findText(last_fx_wdg)
# set to idx 0 if not found (returned -1)
self.cmb_fx_wdg.setCurrentIndex(max(idx, 0))
self.cmb_fx_wdg.blockSignals(False)
else: # no fixpoint widget
self.embed_fixp_img(self.no_fx_filter_img)
self._update_fixp_widget()
return inst_wdg_str
# # ------------------------------------------------------------------------------
# def eventFilter(self, source, event):
# """
# Filter all events generated by monitored QLabel, only resize events are
# processed here, generating a `sig_resize` signal. All other events
# are passed on to the next hierarchy level.
# """
# if event.type() == QEvent.Resize:
# logger.warning("resize event!")
# self.sig_resize.emit()
# # Call base class method to continue normal event processing:
# return super(Input_Fixpoint_Specs, self).eventFilter(source, event)
# ------------------------------------------------------------------------------
def embed_fixp_img(self, img_file: str) -> QPixmap:
"""
Embed `img_file` in png format as `self.img_fixp`
Parameters
----------
img_file: str
path and file name to image file
Returns
-------
self.img_fixp: QPixmap object
pixmap containing the passed img_file
"""
if not os.path.isfile(img_file):
logger.warning("Image file {0} doesn't exist.".format(img_file))
img_file = self.default_fx_img
_, file_extension = os.path.splitext(img_file)
if file_extension != '.png':
logger.error('Unknown file extension "{0}"!'.format(file_extension))
img_file = self.default_fx_img
self.img_fixp = QPixmap(img_file)
# logger.warning(f"img_fixp = {img_file}")
# logger.warning(f"_embed_fixp_img(): {self.img_fixp.__class__.__name__}")
return self.img_fixp
# ------------------------------------------------------------------------------
def resize_img(self) -> None:
"""
Triggered when `self` (the widget) is selected or resized. The method resizes
the image inside QLabel to completely fill the label while keeping
the aspect ratio. An offset of some pixels is needed, otherwise the image
is clipped.
"""
# logger.warning(f"resize_img(): img_fixp = {self.img_fixp.__class__.__name__}")
if self.parent is None: # parent is QApplication, has no width or height
par_w, par_h = 300, 700 # fixed size for module level test
else: # widget parent is InputTabWidget()
par_w, par_h = self.parent.width(), self.parent.height()
img_w, img_h = self.img_fixp.width(), self.img_fixp.height()
if img_w > 10:
max_h = int(max(np.floor(img_h * par_w/img_w) - 5, 20))
else:
max_h = 200
logger.debug("img size: {0},{1}, frm size: {2},{3}, max_h: {4}"
.format(img_w, img_h, par_w, par_h, max_h))
# The following doesn't work because the width of the parent widget can grow
# with the image size
# img_scaled = self.img_fixp.scaled(self.lbl_fixp_img.size(),
# Qt.KeepAspectRatio, Qt.SmoothTransformation)
img_scaled = self.img_fixp.scaledToHeight(max_h, Qt.SmoothTransformation)
self.lbl_fixp_img.setPixmap(img_scaled)
# ------------------------------------------------------------------------------
def _update_fixp_widget(self):
"""
This method is called at the initialization of the widget and when
a new fixpoint filter implementation is selected from the combo box:
- Destruct old instance of fixpoint filter widget `self.fx_filt_ui`
- Import and instantiate new fixpoint filter widget e.g. after changing the
filter topology as
- Try to load image for filter topology
- Update the UI of the widget
- Try to instantiate HDL filter as `self.fx_filt_ui.fixp_filter` with
dummy data
- emit {'fx_sim': 'specs_changed'} when successful
"""
def _disable_fx_wdg(self) -> None:
if hasattr(self, "fx_filt_ui") and self.fx_filt_ui is not None:
# is a fixpoint widget loaded?
try:
# try to remove widget from layout
self.layH_fx_wdg.removeWidget(self.fx_filt_ui)
# delete QWidget when scope has been left
self.fx_filt_ui.deleteLater()
except AttributeError as e:
logger.error("Destructing UI failed!\n{0}".format(e))
self.fx_wdg_found = False
self.butSimFx.setEnabled(False)
self.butExportHDL.setVisible(False)
# self.layH_fx_wdg.setVisible(False)
self.img_fixp = self.embed_fixp_img(self.no_fx_filter_img)
self.resize_img()
self.lblTitle.setText("")
self.fx_filt_ui = None
# -----------------------------------------------------------
_disable_fx_wdg(self) # destruct old fixpoint widget instance:
# instantiate new fixpoint widget class as self.fx_filt_ui
cmb_wdg_fx_cur = qget_cmb_box(self.cmb_fx_wdg, data=False)
if cmb_wdg_fx_cur: # at least one valid fixpoint widget found
self.fx_wdg_found = True
# get list [module name and path, class name]
fx_mod_class_name = qget_cmb_box(self.cmb_fx_wdg, data=True).rsplit('.', 1)
fx_mod = importlib.import_module(fx_mod_class_name[0]) # get module
fx_filt_ui_class = getattr(fx_mod, fx_mod_class_name[1]) # get class
logger.info("Instantiating new FX widget\n\t"
f"{fx_mod.__name__}.{fx_filt_ui_class.__name__}")
# ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
self.fx_filt_ui = fx_filt_ui_class() # instantiate the fixpoint widget
# ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
# and add it to layout:
self.layH_fx_wdg.addWidget(self.fx_filt_ui, stretch=1)
self.fx_filt_ui.setVisible(True)
self.wdg_dict2ui() # initialize the fixpoint subwidgets from the fxqc_dict
# ---- connect signals to fx_filt_ui ----
if hasattr(self.fx_filt_ui, "sig_rx"):
self.sig_rx.connect(self.fx_filt_ui.sig_rx)
if hasattr(self.fx_filt_ui, "sig_tx"):
self.fx_filt_ui.sig_tx.connect(self.sig_rx_local)
# ---- get name of new fixpoint filter image ----
if not (hasattr(self.fx_filt_ui, "img_name") and self.fx_filt_ui.img_name):
# no image name defined, use default image
img_file = self.default_fx_img
else:
# get path of imported fixpoint widget ...
file_path = os.path.dirname(fx_mod.__file__)
# ... and construct full image name from it
img_file = os.path.join(file_path, self.fx_filt_ui.img_name)
# ---- instantiate and scale graphic of filter topology ----
self.embed_fixp_img(img_file)
self.resize_img()
# ---- set title and description for filter
self.lblTitle.setText(self.fx_filt_ui.title)
# Check which methods the fixpoint widget provides and enable
# corresponding buttons:
self.butExportHDL.setVisible(hasattr(self.fx_filt_ui, "to_hdl"))
self.butSimFx.setEnabled(hasattr(self.fx_filt_ui, "fxfilter"))
self.update_fxqc_dict()
self.emit({'fx_sim': 'specs_changed'})
# ------------------------------------------------------------------------------
def wdg_dict2ui(self):
"""
Trigger an update of the fixpoint widget UI when view (i.e. fixpoint
coefficient format) or data have been changed outside this class. Additionally,
pass the fixpoint quantization widget to update / restore other subwidget
settings.
Set the RUN button to "changed".
"""
# fb.fil[0]['fxqc']['QCB'].update({'scale':(1 << fb.fil[0]['fxqc']['QCB']['W'])})
self.wdg_q_input.dict2ui(fb.fil[0]['fxqc']['QI'])
self.wdg_q_output.dict2ui(fb.fil[0]['fxqc']['QO'])
self.wdg_w_input.dict2ui(fb.fil[0]['fxqc']['QI'])
self.wdg_w_output.dict2ui(fb.fil[0]['fxqc']['QO'])
if self.fx_wdg_found and hasattr(self.fx_filt_ui, "dict2ui"):
self.fx_filt_ui.dict2ui()
# dict_sig = {'fx_sim':'specs_changed'}
# self.emit(dict_sig)
qstyle_widget(self.butSimFx, "changed")
# ------------------------------------------------------------------------------
def update_fxqc_dict(self):
"""
Update the fxqc dictionary before simulation / HDL generation starts.
"""
if self.fx_wdg_found:
# get a dict with the coefficients and fixpoint settings from fixpoint widget
if hasattr(self.fx_filt_ui, "ui2dict"):
fb.fil[0]['fxqc'].update(self.fx_filt_ui.ui2dict())
logger.debug("update fxqc: \n{0}".format(pprint_log(fb.fil[0]['fxqc'])))
else:
logger.error("No fixpoint widget found!")
# ------------------------------------------------------------------------------
def exportHDL(self):
"""
Synthesize HDL description of filter
"""
dlg = QFD(self) # instantiate file dialog object
file_types = "Verilog (*.v)"
# needed for overwrite confirmation when name is entered without suffix:
dlg.setDefaultSuffix('v')
dlg.setWindowTitle('Export Verilog')
dlg.setNameFilter(file_types)
dlg.setDirectory(dirs.save_dir)
# set mode "save file" instead "open file":
dlg.setAcceptMode(QFD.AcceptSave)
dlg.setOption(QFD.DontConfirmOverwrite, False)
if dlg.exec_() == QFD.Accepted:
hdl_file = qstr(dlg.selectedFiles()[0])
# hdl_type = extract_file_ext(qstr(dlg.selectedNameFilter()))[0]
# =============================================================================
# # static method getSaveFileName_() is simple but unflexible
# hdl_file, hdl_filter = dlg.getSaveFileName_(
# caption="Save Verilog netlist as (this also defines the module name)",
# directory=dirs.save_dir, filter=file_types)
# hdl_file = qstr(hdl_file)
# if hdl_file != "": # "operation cancelled" returns an empty string
# # return '.v' or '.vhd' depending on filetype selection:
# # hdl_type = extract_file_ext(qstr(hdl_filter))[0]
# # sanitized dir + filename + suffix. The filename suffix is replaced
# # by `v` later.
# hdl_file = os.path.normpath(hdl_file) # complete path + file name
# =============================================================================
hdl_dir_name = os.path.dirname(hdl_file) # extract the directory path
if not os.path.isdir(hdl_dir_name): # create directory if it doesn't exist
os.mkdir(hdl_dir_name)
dirs.save_dir = hdl_dir_name # make this directory the new default / base dir
hdl_file_name = os.path.splitext(os.path.basename(hdl_file))[0]
hdl_full_name = os.path.join(hdl_dir_name, hdl_file_name + ".v")
# remove all non-alphanumeric chars:
vlog_mod_name = re.sub(r'\W+', '', hdl_file_name).lower()
logger.info('Creating hdl_file "{0}"\n\twith top level module "{1}"'
.format(hdl_full_name, vlog_mod_name))
try:
self.update_fxqc_dict()
self.fx_filt_ui.construct_fixp_filter()
code = self.fx_filt_ui.to_hdl(name=vlog_mod_name)
# logger.info(str(code)) # print verilog code to console
with io.open(hdl_full_name, 'w', encoding="utf8") as f:
f.write(str(code))
logger.info("HDL conversion finished!")
except (IOError, TypeError) as e:
logger.warning(e)
# --------------------------------------------------------------------------
def fx_sim_init(self):
"""
Initialize fix-point simulation:
- Update the `fxqc_dict` containing all quantization information
- Setup a filter instance for fixpoint simulation
- Request a stimulus signal
Returns
-------
error: int
0 for sucessful fx widget construction, -1 for error
"""
try:
self.update_fxqc_dict()
self.fx_filt_ui.init_filter() # setup filter instance
return 0
except ValueError as e:
logger.error('Fixpoint stimulus generation failed during "init"'
'\nwith "{0} "'.format(e))
return -1
# ------------------------------------------------------------------------------
def fx_sim_calc_response(self, dict_sig) -> None:
"""
- Read fixpoint stimulus from `dict_sig` in integer format
- Pass it to the fixpoint filter which calculates the fixpoint response
- Store the result in `fb.fx_results` and return. In case of an error,
`fb.fx_results == None`
Returns
-------
None
"""
try:
# logger.info(
# 'Simulate fixpoint frame with "{0}" stimulus:\n\t{1}'.format(
# dict_sig['class'],
# pprint_log(dict_sig['fx_stimulus'], tab=" "),
# ))
# Run fixpoint simulation and store the results as integer values:
fb.fx_results = self.fx_filt_ui.fxfilter(dict_sig['fx_stimulus'])
if len(fb.fx_results) == 0:
logger.error("Fixpoint simulation returned empty results!")
# else:
# # logger.debug("fx_results: {0}"\
# # .format(pprint_log(fb.fx_results, tab= " ")))
# logger.info(
# f'Fixpoint simulation successful for dict\n{pprint_log(dict_sig)}'
# f'\tStimuli: Shape {np.shape(dict_sig["fx_stimulus"])}'
# f' of type "{dict_sig["fx_stimulus"].dtype}"'
# f'\n\tResponse: Shape {np.shape(fb.fx_results)}'
# f' of type "{type(fb.fx_results).__name__} "'
# f' ("{type(fb.fx_results[0]).__name__}")'
# )
except ValueError as e:
logger.error("Simulator error {0}".format(e))
fb.fx_results = None
except AssertionError as e:
logger.error('Fixpoint simulation failed for dict\n{0}'
'\twith msg. "{1}"\n\tStimuli: Shape {2} of type "{3}"'
'\n\tResponse: Shape {4} of type "{5}"'.format(
pprint_log(dict_sig), e,
np.shape(dict_sig['fx_stimulus']),
dict_sig['fx_stimulus'].dtype,
np.shape(fb.fx_results),
type(fb.fx_results)
))
fb.fx_results = None
if fb.fx_results is None:
qstyle_widget(self.butSimFx, "error")
else:
pass # everything ok, return
# logger.debug("Sending fixpoint results")
return
class Plot_Tran_Stim_UI(QWidget):
"""
Create the UI for the PlotImpz class
"""
# incoming:
sig_rx = pyqtSignal(object)
# outgoing: from various UI elements to PlotImpz ('ui_changed':'xxx')
sig_tx = pyqtSignal(object)
# outgoing: to fft related widgets (FFT window widget, qfft_win_select)
sig_tx_fft = pyqtSignal(object)
from pyfda.libs.pyfda_qt_lib import emit
# ------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig=None):
"""
Process signals coming from
- FFT window widget
- qfft_win_select
"""
logger.warning("PROCESS_SIG_RX - vis: {0}\n{1}".format(
self.isVisible(), pprint_log(dict_sig)))
if 'id' in dict_sig and dict_sig['id'] == id(self):
logger.warning("Stopped infinite loop:\n{0}".format(
pprint_log(dict_sig)))
return
elif 'view_changed' in dict_sig:
if dict_sig['view_changed'] == 'f_S':
self.recalc_freqs()
# ------------------------------------------------------------------------------
def __init__(self):
super().__init__()
"""
Intitialize the widget, consisting of:
- top chkbox row
- coefficient table
- two bottom rows with action buttons
"""
# initial settings
self.N_FFT = 0 # TODO: FFT value needs to be passed here somehow?
# stimuli
self.cmb_stim_item = "impulse"
self.cmb_stim_periodic_item = 'square'
self.stim = "dirac"
self.impulse_type = 'dirac'
self.sinusoid_type = 'sine'
self.chirp_type = 'linear'
self.modulation_type = 'am'
self.noise = "None"
self.f1 = 0.02
self.f2 = 0.03
self.A1 = 1.0
self.A2 = 0.0
self.phi1 = self.phi2 = 0
self.T1 = self.T2 = 0
self.TW1 = self.TW2 = 1
self.BW1 = self.BW2 = 0.5
self.noi = 0.1
self.noise = 'none'
self.DC = 0.0
self.stim_formula = "A1 * abs(sin(2 * pi * f1 * n))"
self.stim_par1 = 0.5
self.scale_impz = 1 # optional energy scaling for impulses
# self.bottom_f = -120 # initial value for log. scale
# self.param = None
# dictionaries with widgets needed for the various stimuli
self.stim_wdg_dict = collections.OrderedDict()
self.stim_wdg_dict.update({
"none": {"dc", "noise"},
"dirac": {"dc", "a1", "T1", "norm", "noise"},
"sinc":
{"dc", "a1", "a2", "T1", "T2", "f1", "f2", "norm", "noise"},
"gauss": {
"dc", "a1", "a2", "T1", "T2", "f1", "f2", "BW1", "BW2", "norm",
"noise"
},
"rect": {"dc", "a1", "T1", "TW1", "norm", "noise"},
"step": {"a1", "T1", "noise"},
"cos": {"dc", "a1", "a2", "phi1", "phi2", "f1", "f2", "noise"},
"sine": {"dc", "a1", "a2", "phi1", "phi2", "f1", "f2", "noise"},
"exp": {"dc", "a1", "a2", "phi1", "phi2", "f1", "f2", "noise"},
"diric": {"dc", "a1", "phi1", "T1", "TW1", "f1", "noise"},
"chirp": {"dc", "a1", "phi1", "f1", "f2", "T2", "noise"},
"triang": {"dc", "a1", "phi1", "f1", "noise", "bl"},
"saw": {"dc", "a1", "phi1", "f1", "noise", "bl"},
"square": {"dc", "a1", "phi1", "f1", "noise", "bl", "par1"},
"comb": {"dc", "a1", "phi1", "f1", "noise"},
"am": {"dc", "a1", "a2", "phi1", "phi2", "f1", "f2", "noise"},
"pmfm": {"dc", "a1", "a2", "phi1", "phi2", "f1", "f2", "noise"},
"formula": {
"dc", "a1", "a2", "phi1", "phi2", "f1", "f2", "BW1", "BW2",
"noise"
}
})
# combobox tooltip + data / text / tooltip for stimulus category items
self.cmb_stim_items = [
("<span>Stimulus category.</span>"),
("none", "None",
"<span>Only noise and DC can be selected.</span>"),
("impulse", "Impulse", "<span>Different impulses</span>"),
("step", "Step",
"<span>Calculate step response and its error.</span>"),
("sinusoid", "Sinusoid", "<span>Sinusoidal waveforms</span>"),
("chirp", "Chirp", "<span>Different frequency sweeps.</span>"),
("periodic", "Periodic",
"<span>Periodic functions with discontinuities, "
"either band-limited or with aliasing.</span>"),
("modulation", "Modulat.", "<span>Modulated waveforms.</span>"),
("formula", "Formula", "<span>Formula defined stimulus.</span>")
]
# combobox tooltip + data / text / tooltip for periodic signals items
self.cmb_stim_periodic_items = [
"<span>Periodic functions with discontinuities.</span>",
("square", "Square",
"<span>Square signal with duty cycle α</span>"),
("saw", "Saw", "Sawtooth signal"),
("triang", "Triang", "Triangular signal"),
("comb", "Comb", "Comb signal")
]
# combobox tooltip + data / text / tooltip for chirp signals items
self.cmb_stim_chirp_items = [
"<span>Type of frequency sweep from <i>f</i><sub>1</sub> @ <i>t</i> = 0 to "
"<i>f</i><sub>2</sub> @ t = <i>T</i><sub>2</sub>.</span>",
("linear", "Lin", "Linear frequency sweep"),
("quadratic", "Square", "Quadratic frequency sweep"),
("logarithmic", "Log", "Logarithmic frequency sweep"),
("hyperbolic", "Hyper", "Hyperbolic frequency sweep")
]
self.cmb_stim_impulse_items = [
"<span>Different aperiodic impulse forms</span>",
("dirac", "Dirac",
"<span>Discrete-time dirac impulse for simulating impulse and "
"frequency response.</span>"),
("gauss", "Gauss",
"<span>Gaussian pulse with bandpass spectrum and controllable "
"relative -6 dB bandwidth.</span>"),
("sinc", "Sinc",
"<span>Sinc pulse with rectangular baseband spectrum</span>"),
("rect", "Rect",
"<span>Rectangular pulse with sinc-shaped spectrum</span>")
]
self.cmb_stim_sinusoid_items = [
"Sinusoidal or similar signals", ("sine", "Sine", "Sine signal"),
("cos", "Cos", "Cosine signal"),
("exp", "Exp", "Complex exponential"),
("diric", "Sinc",
"<span>Periodic Sinc (Dirichlet function)</span>")
]
# data / text / tooltip for noise stimulus combobox.
self.cmb_stim_noise_items = [
"Type of additive noise.", ("none", "None", ""),
("gauss", "Gauss",
"<span>Normal- or Gauss-distributed process with std. deviation σ."
"</span>"),
("uniform", "Uniform",
"<span>Uniformly distributed process in the range ± Δ/2."
"</span>"),
("prbs", "PRBS",
"<span>Pseudo-Random Binary Sequence with values ± A.</span>"
),
("mls", "MLS",
"<span>Maximum Length Sequence with values ± A. The sequence is "
"always the same as the state is not stored for the next sequence start."
"</span>"),
("brownian", "Brownian",
"<span>Brownian (cumulated sum) process based on Gaussian noise with"
" std. deviation σ.</span>")
]
self._construct_UI()
self._enable_stim_widgets()
self._update_noi()
def _construct_UI(self):
# =====================================================================
# Controls for stimuli
# =====================================================================
self.cmbStimulus = QComboBox(self)
qcmb_box_populate(self.cmbStimulus, self.cmb_stim_items,
self.cmb_stim_item)
self.lblStimPar1 = QLabel(to_html("α =", frmt='b'), self)
self.ledStimPar1 = QLineEdit(self)
self.ledStimPar1.setText("0.5")
self.ledStimPar1.setToolTip("Duty Cycle, 0 ... 1")
self.ledStimPar1.setObjectName("ledStimPar1")
self.but_stim_bl = QPushButton(self)
self.but_stim_bl.setText("BL")
self.but_stim_bl.setToolTip(
"<span>Bandlimit the signal to the Nyquist "
"frequency to avoid aliasing. However, this is much slower "
"to calculate especially for a large number of points.</span>")
self.but_stim_bl.setMaximumWidth(qtext_width(text="BL "))
self.but_stim_bl.setCheckable(True)
self.but_stim_bl.setChecked(True)
self.but_stim_bl.setObjectName("stim_bl")
# -------------------------------------
self.cmbChirpType = QComboBox(self)
qcmb_box_populate(self.cmbChirpType, self.cmb_stim_chirp_items,
self.chirp_type)
self.cmbImpulseType = QComboBox(self)
qcmb_box_populate(self.cmbImpulseType, self.cmb_stim_impulse_items,
self.impulse_type)
self.cmbSinusoidType = QComboBox(self)
qcmb_box_populate(self.cmbSinusoidType, self.cmb_stim_sinusoid_items,
self.sinusoid_type)
self.cmbPeriodicType = QComboBox(self)
qcmb_box_populate(self.cmbPeriodicType, self.cmb_stim_periodic_items,
self.cmb_stim_periodic_item)
self.cmbModulationType = QComboBox(self)
for t in [("AM", "am"), ("PM / FM", "pmfm")]: # text, data
self.cmbModulationType.addItem(*t)
qset_cmb_box(self.cmbModulationType, self.modulation_type, data=True)
# -------------------------------------
self.chk_step_err = QPushButton("Error", self)
self.chk_step_err.setToolTip(
"<span>Display the step response error.</span>")
self.chk_step_err.setMaximumWidth(qtext_width(text="Error "))
self.chk_step_err.setCheckable(True)
self.chk_step_err.setChecked(False)
self.chk_step_err.setObjectName("stim_step_err")
layHCmbStim = QHBoxLayout()
layHCmbStim.addWidget(self.cmbStimulus)
layHCmbStim.addWidget(self.cmbImpulseType)
layHCmbStim.addWidget(self.cmbSinusoidType)
layHCmbStim.addWidget(self.cmbChirpType)
layHCmbStim.addWidget(self.cmbPeriodicType)
layHCmbStim.addWidget(self.cmbModulationType)
layHCmbStim.addWidget(self.but_stim_bl)
layHCmbStim.addWidget(self.lblStimPar1)
layHCmbStim.addWidget(self.ledStimPar1)
layHCmbStim.addWidget(self.chk_step_err)
self.lblDC = QLabel(to_html("DC =", frmt='bi'), self)
self.ledDC = QLineEdit(self)
self.ledDC.setText(str(self.DC))
self.ledDC.setToolTip("DC Level")
self.ledDC.setObjectName("stimDC")
layHStimDC = QHBoxLayout()
layHStimDC.addWidget(self.lblDC)
layHStimDC.addWidget(self.ledDC)
# ======================================================================
self.lblAmp1 = QLabel(to_html(" A_1", frmt='bi') + " =", self)
self.ledAmp1 = QLineEdit(self)
self.ledAmp1.setText(str(self.A1))
self.ledAmp1.setToolTip(
"Stimulus amplitude, complex values like 3j - 1 are allowed")
self.ledAmp1.setObjectName("stimAmp1")
self.lblAmp2 = QLabel(to_html(" A_2", frmt='bi') + " =", self)
self.ledAmp2 = QLineEdit(self)
self.ledAmp2.setText(str(self.A2))
self.ledAmp2.setToolTip(
"Stimulus amplitude 2, complex values like 3j - 1 are allowed")
self.ledAmp2.setObjectName("stimAmp2")
# ----------------------------------------------
self.lblPhi1 = QLabel(to_html(" φ_1", frmt='bi') + " =", self)
self.ledPhi1 = QLineEdit(self)
self.ledPhi1.setText(str(self.phi1))
self.ledPhi1.setToolTip("Stimulus phase")
self.ledPhi1.setObjectName("stimPhi1")
self.lblPhU1 = QLabel(to_html("°", frmt='b'), self)
self.lblPhi2 = QLabel(to_html(" φ_2", frmt='bi') + " =", self)
self.ledPhi2 = QLineEdit(self)
self.ledPhi2.setText(str(self.phi2))
self.ledPhi2.setToolTip("Stimulus phase 2")
self.ledPhi2.setObjectName("stimPhi2")
self.lblPhU2 = QLabel(to_html("°", frmt='b'), self)
# ----------------------------------------------
self.lbl_T1 = QLabel(to_html(" T_1", frmt='bi') + " =", self)
self.led_T1 = QLineEdit(self)
self.led_T1.setText(str(self.T1))
self.led_T1.setToolTip("Time shift")
self.led_T1.setObjectName("stimT1")
self.lbl_TU1 = QLabel(to_html("T_S", frmt='b'), self)
self.lbl_T2 = QLabel(to_html(" T_2", frmt='bi') + " =", self)
self.led_T2 = QLineEdit(self)
self.led_T2.setText(str(self.T2))
self.led_T2.setToolTip("Time shift 2")
self.led_T2.setObjectName("stimT2")
self.lbl_TU2 = QLabel(to_html("T_S", frmt='b'), self)
# ---------------------------------------------
self.lbl_TW1 = QLabel(
to_html(" ΔT_1", frmt='bi') + " =", self)
self.led_TW1 = QLineEdit(self)
self.led_TW1.setText(str(self.TW1))
self.led_TW1.setToolTip("Time width")
self.led_TW1.setObjectName("stimTW1")
self.lbl_TWU1 = QLabel(to_html("T_S", frmt='b'), self)
self.lbl_TW2 = QLabel(
to_html(" ΔT_2", frmt='bi') + " =", self)
self.led_TW2 = QLineEdit(self)
self.led_TW2.setText(str(self.TW2))
self.led_TW2.setToolTip("Time width 2")
self.led_TW2.setObjectName("stimTW2")
self.lbl_TWU2 = QLabel(to_html("T_S", frmt='b'), self)
# ----------------------------------------------
self.txtFreq1_f = to_html(" f_1", frmt='bi') + " ="
self.txtFreq1_k = to_html(" k_1", frmt='bi') + " ="
self.lblFreq1 = QLabel(self.txtFreq1_f, self)
self.ledFreq1 = QLineEdit(self)
self.ledFreq1.setText(str(self.f1))
self.ledFreq1.setToolTip("Stimulus frequency")
self.ledFreq1.setObjectName("stimFreq1")
self.lblFreqUnit1 = QLabel("f_S", self)
self.txtFreq2_f = to_html(" f_2", frmt='bi') + " ="
self.txtFreq2_k = to_html(" k_2", frmt='bi') + " ="
self.lblFreq2 = QLabel(self.txtFreq2_f, self)
self.ledFreq2 = QLineEdit(self)
self.ledFreq2.setText(str(self.f2))
self.ledFreq2.setToolTip("Stimulus frequency 2")
self.ledFreq2.setObjectName("stimFreq2")
self.lblFreqUnit2 = QLabel("f_S", self)
# ----------------------------------------------
self.lbl_BW1 = QLabel(
to_html(self.tr(" BW_1"), frmt='bi') + " =", self)
self.led_BW1 = QLineEdit(self)
self.led_BW1.setText(str(self.BW1))
self.led_BW1.setToolTip(self.tr("Relative bandwidth"))
self.led_BW1.setObjectName("stimBW1")
self.lbl_BW2 = QLabel(
to_html(self.tr(" BW_2"), frmt='bi') + " =", self)
self.led_BW2 = QLineEdit(self)
self.led_BW2.setText(str(self.BW2))
self.led_BW2.setToolTip(self.tr("Relative bandwidth 2"))
self.led_BW2.setObjectName("stimBW2")
# ----------------------------------------------
self.lblNoise = QLabel(to_html(" Noise", frmt='bi'), self)
self.cmbNoise = QComboBox(self)
qcmb_box_populate(self.cmbNoise, self.cmb_stim_noise_items, self.noise)
self.lblNoi = QLabel("not initialized", self)
self.ledNoi = QLineEdit(self)
self.ledNoi.setText(str(self.noi))
self.ledNoi.setToolTip("not initialized")
self.ledNoi.setObjectName("stimNoi")
layGStim = QGridLayout()
layGStim.addLayout(layHCmbStim, 0, 1)
layGStim.addLayout(layHStimDC, 1, 1)
layGStim.addWidget(self.lblAmp1, 0, 2)
layGStim.addWidget(self.lblAmp2, 1, 2)
layGStim.addWidget(self.ledAmp1, 0, 3)
layGStim.addWidget(self.ledAmp2, 1, 3)
layGStim.addWidget(self.lblPhi1, 0, 4)
layGStim.addWidget(self.lblPhi2, 1, 4)
layGStim.addWidget(self.ledPhi1, 0, 5)
layGStim.addWidget(self.ledPhi2, 1, 5)
layGStim.addWidget(self.lblPhU1, 0, 6)
layGStim.addWidget(self.lblPhU2, 1, 6)
layGStim.addWidget(self.lbl_T1, 0, 7)
layGStim.addWidget(self.lbl_T2, 1, 7)
layGStim.addWidget(self.led_T1, 0, 8)
layGStim.addWidget(self.led_T2, 1, 8)
layGStim.addWidget(self.lbl_TU1, 0, 9)
layGStim.addWidget(self.lbl_TU2, 1, 9)
layGStim.addWidget(self.lbl_TW1, 0, 10)
layGStim.addWidget(self.lbl_TW2, 1, 10)
layGStim.addWidget(self.led_TW1, 0, 11)
layGStim.addWidget(self.led_TW2, 1, 11)
layGStim.addWidget(self.lbl_TWU1, 0, 12)
layGStim.addWidget(self.lbl_TWU2, 1, 12)
layGStim.addWidget(self.lblFreq1, 0, 13)
layGStim.addWidget(self.lblFreq2, 1, 13)
layGStim.addWidget(self.ledFreq1, 0, 14)
layGStim.addWidget(self.ledFreq2, 1, 14)
layGStim.addWidget(self.lblFreqUnit1, 0, 15)
layGStim.addWidget(self.lblFreqUnit2, 1, 15)
layGStim.addWidget(self.lbl_BW1, 0, 16)
layGStim.addWidget(self.lbl_BW2, 1, 16)
layGStim.addWidget(self.led_BW1, 0, 17)
layGStim.addWidget(self.led_BW2, 1, 17)
layGStim.addWidget(self.lblNoise, 0, 18)
layGStim.addWidget(self.lblNoi, 1, 18)
layGStim.addWidget(self.cmbNoise, 0, 19)
layGStim.addWidget(self.ledNoi, 1, 19)
# ----------------------------------------------
self.lblStimFormula = QLabel(to_html("x =", frmt='bi'), self)
self.ledStimFormula = QLineEdit(self)
self.ledStimFormula.setText(str(self.stim_formula))
self.ledStimFormula.setToolTip(
"<span>Enter formula for stimulus in numexpr syntax.</span>")
self.ledStimFormula.setObjectName("stimFormula")
layH_stim_formula = QHBoxLayout()
layH_stim_formula.addWidget(self.lblStimFormula)
layH_stim_formula.addWidget(self.ledStimFormula, 10)
# ----------------------------------------------------------------------
# Main Widget
# ----------------------------------------------------------------------
layH_stim_par = QHBoxLayout()
layH_stim_par.addLayout(layGStim)
layV_stim = QVBoxLayout()
layV_stim.addLayout(layH_stim_par)
layV_stim.addLayout(layH_stim_formula)
layH_stim = QHBoxLayout()
layH_stim.addLayout(layV_stim)
layH_stim.addStretch(10)
self.wdg_stim = QWidget(self)
self.wdg_stim.setLayout(layH_stim)
self.wdg_stim.setSizePolicy(QSizePolicy.Expanding, QSizePolicy.Minimum)
# ----------------------------------------------------------------------
# Event Filter
# ----------------------------------------------------------------------
# frequency related widgets are scaled with f_s, requiring special handling
self.ledFreq1.installEventFilter(self)
self.ledFreq2.installEventFilter(self)
self.led_T1.installEventFilter(self)
self.led_T2.installEventFilter(self)
self.led_TW1.installEventFilter(self)
self.led_TW2.installEventFilter(self)
# ----------------------------------------------------------------------
# GLOBAL SIGNALS & SLOTs
# ----------------------------------------------------------------------
self.sig_rx.connect(self.process_sig_rx)
# ----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
# ----------------------------------------------------------------------
# --- stimulus control ---
self.but_stim_bl.clicked.connect(self._enable_stim_widgets)
self.chk_step_err.clicked.connect(self._enable_stim_widgets)
self.cmbStimulus.currentIndexChanged.connect(self._enable_stim_widgets)
self.cmbNoise.currentIndexChanged.connect(self._update_noi)
self.ledNoi.editingFinished.connect(self._update_noi)
self.ledAmp1.editingFinished.connect(self._update_amp1)
self.ledAmp2.editingFinished.connect(self._update_amp2)
self.ledPhi1.editingFinished.connect(self._update_phi1)
self.ledPhi2.editingFinished.connect(self._update_phi2)
self.led_BW1.editingFinished.connect(self._update_BW1)
self.led_BW2.editingFinished.connect(self._update_BW2)
self.cmbImpulseType.currentIndexChanged.connect(
self._update_impulse_type)
self.cmbSinusoidType.currentIndexChanged.connect(
self._update_sinusoid_type)
self.cmbChirpType.currentIndexChanged.connect(self._update_chirp_type)
self.cmbPeriodicType.currentIndexChanged.connect(
self._update_periodic_type)
self.cmbModulationType.currentIndexChanged.connect(
self._update_modulation_type)
self.ledDC.editingFinished.connect(self._update_DC)
self.ledStimFormula.editingFinished.connect(self._update_stim_formula)
self.ledStimPar1.editingFinished.connect(self._update_stim_par1)
# ------------------------------------------------------------------------------
def update_freq_units(self):
"""
Update labels referrring to frequency specs
"""
if fb.fil[0]['freq_specs_unit'] == 'k':
f_unit = ''
t_unit = ''
self.lblFreq1.setText(self.txtFreq1_k)
self.lblFreq2.setText(self.txtFreq2_k)
else:
f_unit = fb.fil[0]['plt_fUnit']
t_unit = fb.fil[0]['plt_tUnit'].replace(r"$\mu$", "μ")
self.lblFreq1.setText(self.txtFreq1_f)
self.lblFreq2.setText(self.txtFreq2_f)
if f_unit in {"f_S", "f_Ny"}:
unit_frmt = "i" # italic
else:
unit_frmt = None # don't print units like kHz in italic
self.lblFreqUnit1.setText(to_html(f_unit, frmt=unit_frmt))
self.lblFreqUnit2.setText(to_html(f_unit, frmt=unit_frmt))
self.lbl_TU1.setText(to_html(t_unit, frmt=unit_frmt))
self.lbl_TU2.setText(to_html(t_unit, frmt=unit_frmt))
# ------------------------------------------------------------------------------
def eventFilter(self, source, event):
"""
Filter all events generated by the monitored widgets (ledFreq1 and 2 and T1 / T2).
Source and type of all events generated by monitored objects are passed
to this eventFilter, evaluated and passed on to the next hierarchy level.
- When a QLineEdit widget gains input focus (``QEvent.FocusIn``), display
the stored value from filter dict with full precision
- When a key is pressed inside the text field, set the `spec_edited` flag
to True.
- When a QLineEdit widget loses input focus (``QEvent.FocusOut``), store
current value normalized to f_S with full precision (only if
``spec_edited == True``) and display the stored value in selected format
Emit 'ui_changed':'stim'
"""
def _reload_entry(source):
""" Reload text entry for active line edit field in rounded format """
if source.objectName() == "stimFreq1":
source.setText(
str(params['FMT'].format(self.f1 * self.f_scale)))
elif source.objectName() == "stimFreq2":
source.setText(
str(params['FMT'].format(self.f2 * self.f_scale)))
elif source.objectName() == "stimT1":
source.setText(
str(params['FMT'].format(self.T1 * self.t_scale)))
elif source.objectName() == "stimT2":
source.setText(
str(params['FMT'].format(self.T2 * self.t_scale)))
elif source.objectName() == "stimTW1":
source.setText(
str(params['FMT'].format(self.TW1 * self.t_scale)))
elif source.objectName() == "stimTW2":
source.setText(
str(params['FMT'].format(self.TW2 * self.t_scale)))
def _store_entry(source):
if self.spec_edited:
if source.objectName() == "stimFreq1":
self.f1 = safe_eval(source.text(),
self.f1 * self.f_scale,
return_type='float') / self.f_scale
source.setText(
str(params['FMT'].format(self.f1 * self.f_scale)))
elif source.objectName() == "stimFreq2":
self.f2 = safe_eval(source.text(),
self.f2 * self.f_scale,
return_type='float') / self.f_scale
source.setText(
str(params['FMT'].format(self.f2 * self.f_scale)))
elif source.objectName() == "stimT1":
self.T1 = safe_eval(source.text(),
self.T1 * self.t_scale,
return_type='float') / self.t_scale
source.setText(
str(params['FMT'].format(self.T1 * self.t_scale)))
elif source.objectName() == "stimT2":
self.T2 = safe_eval(source.text(),
self.T2 * self.t_scale,
return_type='float') / self.t_scale
source.setText(
str(params['FMT'].format(self.T2 * self.t_scale)))
elif source.objectName() == "stimTW1":
self.TW1 = safe_eval(source.text(),
self.TW1 * self.t_scale,
sign='pos',
return_type='float') / self.t_scale
source.setText(
str(params['FMT'].format(self.TW1 * self.t_scale)))
elif source.objectName() == "stimTW2":
self.TW2 = safe_eval(source.text(),
self.TW2 * self.t_scale,
sign='pos',
return_type='float') / self.t_scale
source.setText(
str(params['FMT'].format(self.TW2 * self.t_scale)))
self.spec_edited = False # reset flag
self._update_scale_impz()
self.emit({'ui_changed': 'stim'})
# nothing has changed, but display frequencies in rounded format anyway
else:
_reload_entry(source)
# --------------------------------------------------------------------
# if isinstance(source, QLineEdit):
# if source.objectName() in {"stimFreq1","stimFreq2"}:
if event.type() in {QEvent.FocusIn, QEvent.KeyPress, QEvent.FocusOut}:
if event.type() == QEvent.FocusIn:
self.spec_edited = False
self.update_freqs()
elif event.type() == QEvent.KeyPress:
self.spec_edited = True # entry has been changed
key = event.key()
if key in {Qt.Key_Return, Qt.Key_Enter}:
_store_entry(source)
elif key == Qt.Key_Escape: # revert changes
self.spec_edited = False
_reload_entry(source)
elif event.type() == QEvent.FocusOut:
_store_entry(source)
# Call base class method to continue normal event processing:
return super(Plot_Tran_Stim_UI, self).eventFilter(source, event)
# -------------------------------------------------------------
def recalc_freqs(self):
"""
Update normalized frequencies if required. This is called by via signal
['ui_changed':'f_S'] from plot_impz.process_sig_rx
"""
if fb.fil[0]['freq_locked']:
self.f1 *= fb.fil[0]['f_S_prev'] / fb.fil[0]['f_S']
self.f2 *= fb.fil[0]['f_S_prev'] / fb.fil[0]['f_S']
self.T1 *= fb.fil[0]['f_S'] / fb.fil[0]['f_S_prev']
self.T2 *= fb.fil[0]['f_S'] / fb.fil[0]['f_S_prev']
self.TW1 *= fb.fil[0]['f_S'] / fb.fil[0]['f_S_prev']
self.TW2 *= fb.fil[0]['f_S'] / fb.fil[0]['f_S_prev']
self._update_scale_impz()
self.update_freqs()
self.emit({'ui_changed': 'f1_f2'})
# -------------------------------------------------------------
def update_freqs(self):
"""
`update_freqs()` is called:
- when one of the stimulus frequencies has changed via eventFilter()
- sampling frequency has been changed via signal ['ui_changed':'f_S']
from plot_impz.process_sig_rx -> self.recalc_freqs
The sampling frequency is loaded from filter dictionary and stored as
`self.f_scale` (except when the frequency unit is k when `f_scale = self.N_FFT`).
Frequency field entries are always stored normalized w.r.t. f_S in the
dictionary: When the `f_S` lock button is unlocked, only the displayed
values for frequency entries are updated with f_S, not the dictionary.
When the `f_S` lock button is pressed, the absolute frequency values in
the widget fields are kept constant, and the dictionary entries are updated.
"""
# recalculate displayed freq spec values for (maybe) changed f_S
if fb.fil[0]['freq_specs_unit'] == 'k':
self.f_scale = self.N_FFT
else:
self.f_scale = fb.fil[0]['f_S']
self.t_scale = fb.fil[0]['T_S']
if self.ledFreq1.hasFocus():
# widget has focus, show full precision
self.ledFreq1.setText(str(self.f1 * self.f_scale))
elif self.ledFreq2.hasFocus():
self.ledFreq2.setText(str(self.f2 * self.f_scale))
elif self.led_T1.hasFocus():
self.led_T1.setText(str(self.T1 * self.t_scale))
elif self.led_T2.hasFocus():
self.led_T2.setText(str(self.T2 * self.t_scale))
elif self.led_TW1.hasFocus():
self.led_TW1.setText(str(self.TW1 * self.t_scale))
elif self.led_TW2.hasFocus():
self.led_TW2.setText(str(self.TW2 * self.t_scale))
else:
# widgets have no focus, round the display
self.ledFreq1.setText(
str(params['FMT'].format(self.f1 * self.f_scale)))
self.ledFreq2.setText(
str(params['FMT'].format(self.f2 * self.f_scale)))
self.led_T1.setText(
str(params['FMT'].format(self.T1 * self.t_scale)))
self.led_T2.setText(
str(params['FMT'].format(self.T2 * self.t_scale)))
self.led_TW1.setText(
str(params['FMT'].format(self.TW1 * self.t_scale)))
self.led_TW2.setText(
str(params['FMT'].format(self.TW2 * self.t_scale)))
self.update_freq_units(
) # TODO: should only be called at f_S / unit update
# -------------------------------------------------------------
def _enable_stim_widgets(self):
""" Enable / disable widgets depending on the selected stimulus """
self.cmb_stim = qget_cmb_box(self.cmbStimulus)
if self.cmb_stim == "impulse":
self.stim = qget_cmb_box(self.cmbImpulseType)
# recalculate the energy scaling for impulse functions
self._update_scale_impz()
elif self.cmb_stim == "sinusoid":
self.stim = qget_cmb_box(self.cmbSinusoidType)
elif self.cmb_stim == "periodic":
self.stim = qget_cmb_box(self.cmbPeriodicType)
elif self.cmb_stim == "modulation":
self.stim = qget_cmb_box(self.cmbModulationType)
else:
self.stim = self.cmb_stim
# read out which stimulus widgets are enabled
stim_wdg = self.stim_wdg_dict[self.stim]
self.lblDC.setVisible("dc" in stim_wdg)
self.ledDC.setVisible("dc" in stim_wdg)
self.chk_step_err.setVisible(self.stim == "step")
self.lblStimPar1.setVisible("par1" in stim_wdg)
self.ledStimPar1.setVisible("par1" in stim_wdg)
self.but_stim_bl.setVisible("bl" in stim_wdg)
self.lblAmp1.setVisible("a1" in stim_wdg)
self.ledAmp1.setVisible("a1" in stim_wdg)
self.lblPhi1.setVisible("phi1" in stim_wdg)
self.ledPhi1.setVisible("phi1" in stim_wdg)
self.lblPhU1.setVisible("phi1" in stim_wdg)
self.lbl_T1.setVisible("T1" in stim_wdg)
self.led_T1.setVisible("T1" in stim_wdg)
self.lbl_TU1.setVisible("T1" in stim_wdg)
self.lbl_TW1.setVisible("TW1" in stim_wdg)
self.led_TW1.setVisible("TW1" in stim_wdg)
self.lbl_TWU1.setVisible("TW1" in stim_wdg)
self.lblFreq1.setVisible("f1" in stim_wdg)
self.ledFreq1.setVisible("f1" in stim_wdg)
self.lblFreqUnit1.setVisible("f1" in stim_wdg)
self.lbl_BW1.setVisible("BW1" in stim_wdg)
self.led_BW1.setVisible("BW1" in stim_wdg)
self.lblAmp2.setVisible("a2" in stim_wdg)
self.ledAmp2.setVisible("a2" in stim_wdg)
self.lblPhi2.setVisible("phi2" in stim_wdg)
self.ledPhi2.setVisible("phi2" in stim_wdg)
self.lblPhU2.setVisible("phi2" in stim_wdg)
self.lbl_T2.setVisible("T2" in stim_wdg)
self.led_T2.setVisible("T2" in stim_wdg)
self.lbl_TU2.setVisible("T2" in stim_wdg)
self.lbl_TW2.setVisible("TW2" in stim_wdg)
self.led_TW2.setVisible("TW2" in stim_wdg)
self.lbl_TWU2.setVisible("TW2" in stim_wdg)
self.lblFreq2.setVisible("f2" in stim_wdg)
self.ledFreq2.setVisible("f2" in stim_wdg)
self.lblFreqUnit2.setVisible("f2" in stim_wdg)
self.lbl_BW2.setVisible("BW2" in stim_wdg)
self.led_BW2.setVisible("BW2" in stim_wdg)
self.lblStimFormula.setVisible(self.stim == "formula")
self.ledStimFormula.setVisible(self.stim == "formula")
self.cmbImpulseType.setVisible(self.cmb_stim == 'impulse')
self.cmbSinusoidType.setVisible(self.cmb_stim == 'sinusoid')
self.cmbChirpType.setVisible(self.cmb_stim == 'chirp')
self.cmbPeriodicType.setVisible(self.cmb_stim == 'periodic')
self.cmbModulationType.setVisible(self.cmb_stim == 'modulation')
self.emit({'ui_changed': 'stim'})
# -------------------------------------------------------------
def _update_amp1(self):
""" Update value for self.A1 from QLineEditWidget"""
self.A1 = safe_eval(self.ledAmp1.text(), self.A1, return_type='cmplx')
self.ledAmp1.setText(str(self.A1))
self.emit({'ui_changed': 'a1'})
def _update_amp2(self):
""" Update value for self.A2 from the QLineEditWidget"""
self.A2 = safe_eval(self.ledAmp2.text(), self.A2, return_type='cmplx')
self.ledAmp2.setText(str(self.A2))
self.emit({'ui_changed': 'a2'})
def _update_phi1(self):
""" Update value for self.phi1 from QLineEditWidget"""
self.phi1 = safe_eval(self.ledPhi1.text(),
self.phi1,
return_type='float')
self.ledPhi1.setText(str(self.phi1))
self.emit({'ui_changed': 'phi1'})
def _update_BW1(self):
""" Update value for self.BW1 from QLineEditWidget"""
self.BW1 = safe_eval(self.led_BW1.text(),
self.BW1,
return_type='float',
sign='pos')
self.led_BW1.setText(str(self.BW1))
self._update_scale_impz()
self.emit({'ui_changed': 'BW1'})
def _update_BW2(self):
""" Update value for self.BW2 from QLineEditWidget"""
self.BW2 = safe_eval(self.led_BW2.text(),
self.BW2,
return_type='float',
sign='pos')
self.led_BW2.setText(str(self.BW2))
self.emit({'ui_changed': 'BW2'})
def _update_scale_impz(self):
"""
recalculate the energy scaling for impulse functions when impulse type or
relevant frequency / bandwidth parameter have been updated
"""
if self.stim == "dirac":
self.scale_impz = 1.
elif self.stim == "sinc":
self.scale_impz = self.f1 * 2
elif self.stim == "gauss":
self.scale_impz = self.f1 * 2 * self.BW1
elif self.stim == "rect":
self.scale_impz = 1. / self.TW1
def _update_phi2(self):
""" Update value for self.phi2 from the QLineEditWidget"""
self.phi2 = safe_eval(self.ledPhi2.text(),
self.phi2,
return_type='float')
self.ledPhi2.setText(str(self.phi2))
self.emit({'ui_changed': 'phi2'})
def _update_chirp_type(self):
""" Update value for self.chirp_type from data field of ComboBox"""
self.chirp_type = qget_cmb_box(self.cmbChirpType)
self.emit({'ui_changed': 'chirp_type'})
def _update_impulse_type(self):
""" Update value for self.impulse_type from data field of ComboBox"""
self.impulse_type = qget_cmb_box(self.cmbImpulseType)
self._enable_stim_widgets()
def _update_sinusoid_type(self):
""" Update value for self.sinusoid_type from data field of ComboBox"""
self.sinusoid_type = qget_cmb_box(self.cmbSinusoidType)
self._enable_stim_widgets()
def _update_periodic_type(self):
""" Update value for self.periodic_type from data field of ComboBox"""
self.periodic_type = qget_cmb_box(self.cmbPeriodicType)
self._enable_stim_widgets()
def _update_modulation_type(self):
""" Update value for self.modulation_type from from data field of ComboBox"""
self.modulation_type = qget_cmb_box(self.cmbModulationType)
self._enable_stim_widgets()
# -------------------------------------------------------------
def _update_noi(self):
""" Update type + value + label for self.noi for noise"""
self.noise = qget_cmb_box(self.cmbNoise)
self.lblNoi.setVisible(self.noise != 'none')
self.ledNoi.setVisible(self.noise != 'none')
if self.noise != 'none':
self.noi = safe_eval(self.ledNoi.text(), 0, return_type='cmplx')
self.ledNoi.setText(str(self.noi))
if self.noise == 'gauss':
self.lblNoi.setText(to_html(" σ =", frmt='bi'))
self.ledNoi.setToolTip(
"<span>Standard deviation of statistical process,"
"noise power is <i>P</i> = σ<sup>2</sup></span>")
elif self.noise == 'uniform':
self.lblNoi.setText(to_html(" Δ =", frmt='bi'))
self.ledNoi.setToolTip(
"<span>Interval size for uniformly distributed process (e.g. "
"quantization step size for quantization noise), centered around 0. "
"Noise power is <i>P</i> = Δ<sup>2</sup>/12.</span>")
elif self.noise == 'prbs':
self.lblNoi.setText(to_html(" A =", frmt='bi'))
self.ledNoi.setToolTip(
"<span>Amplitude of bipolar Pseudorandom Binary Sequence. "
"Noise power is <i>P</i> = A<sup>2</sup>.</span>")
elif self.noise == 'mls':
self.lblNoi.setText(to_html(" A =", frmt='bi'))
self.ledNoi.setToolTip(
"<span>Amplitude of Maximum Length Sequence. "
"Noise power is <i>P</i> = A<sup>2</sup>.</span>")
elif self.noise == 'brownian':
self.lblNoi.setText(to_html(" σ =", frmt='bi'))
self.ledNoi.setToolTip(
"<span>Standard deviation of the Gaussian process "
"that is cumulated.</span>")
self.emit({'ui_changed': 'noi'})
def _update_DC(self):
""" Update value for self.DC from the QLineEditWidget"""
self.DC = safe_eval(self.ledDC.text(), 0, return_type='cmplx')
self.ledDC.setText(str(self.DC))
self.emit({'ui_changed': 'dc'})
def _update_stim_formula(self):
"""Update string with formula to be evaluated by numexpr"""
self.stim_formula = self.ledStimFormula.text().strip()
self.ledStimFormula.setText(str(self.stim_formula))
self.emit({'ui_changed': 'stim_formula'})
def _update_stim_par1(self):
""" Update value for self.par1 from QLineEditWidget"""
self.stim_par1 = safe_eval(self.ledStimPar1.text(),
self.stim_par1,
sign='pos',
return_type='float')
self.ledStimPar1.setText(str(self.stim_par1))
self.emit({'ui_changed': 'stim_par1'})
class Input_PZ_UI(QWidget):
"""
Create the UI for the FilterPZ class
"""
sig_rx = pyqtSignal(object) # incoming
sig_tx = pyqtSignal(object) # outgoing
def __init__(self, parent):
"""
Pass instance `parent` of parent class (FilterCoeffs)
"""
super(Input_PZ_UI, self).__init__(parent)
# self.parent = parent # instance of the parent (not the base) class
self.eps = 1.e-4 # # tolerance value for e.g. setting P/Z to zero
self._construct_UI()
#------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig=None):
"""
Process signals coming from the CSV pop-up window
"""
logger.debug("PROCESS_SIG_RX\n{0}".format(pprint_log(dict_sig)))
if 'closeEvent' in dict_sig:
self._close_csv_win()
self.sig_tx.emit({'sender':__name__, 'ui_changed': 'csv'})
return # probably not needed
elif 'ui_changed' in dict_sig:
self._set_load_save_icons() # update icons file <-> clipboard
# inform e.g. the p/z input widget about changes in CSV options
self.sig_tx.emit({'sender':__name__, 'ui_changed': 'csv'})
#------------------------------------------------------------------------------
def _construct_UI(self):
"""
Intitialize the widget, consisting of:
- top chkbox row
- coefficient table
- two bottom rows with action buttons
"""
self.bfont = QFont()
self.bfont.setBold(True)
self.bifont = QFont()
self.bifont.setBold(True)
self.bifont.setItalic(True)
# q_icon_size = QSize(20, 20) # optional, size is derived from butEnable
# ---------------------------------------------
# UI Elements for controlling the display
# ---------------------------------------------
self.butEnable = QPushButton(self)
self.butEnable.setIcon(QIcon(':/circle-x.svg'))
q_icon_size = self.butEnable.iconSize() # <- set this for manual icon sizing
self.butEnable.setIconSize(q_icon_size)
self.butEnable.setCheckable(True)
self.butEnable.setChecked(True)
self.butEnable.setToolTip("<span>Show / hide poles and zeros in an editable table."
" For high order systems, the table display might be slow.</span>")
self.cmbPZFrmt = QComboBox(self)
pz_formats = [('Cartesian', 'cartesian'), ('Polar (rad)', 'polar_rad'),
('Polar (pi)', 'polar_pi'), ('Polar (°)', 'polar_deg')] # display text, data
# π: u'3C0, °: u'B0, ∠: u'2220
for pz in pz_formats:
self.cmbPZFrmt.addItem(*pz)
self.cmbPZFrmt.setSizeAdjustPolicy(QComboBox.AdjustToContents)
# self.cmbPZFrmt.setEnabled(False)
self.cmbPZFrmt.setToolTip("<span>Set display format for poles and zeros to"
" either cartesian (x + jy) or polar (r * ∠ Ω)."
" Type 'o' for '°', '<' for '∠' and 'pi' for 'π'.</span>")
self.spnDigits = QSpinBox(self)
self.spnDigits.setRange(0,16)
self.spnDigits.setToolTip("Number of digits to display.")
self.lblDigits = QLabel("Digits", self)
self.lblDigits.setFont(self.bifont)
self.cmbCausal = QComboBox(self)
causal_types = ['Causal', 'Acausal', 'Anticausal']
for cs in causal_types:
self.cmbCausal.addItem(cs)
qset_cmb_box(self.cmbCausal, 'Causal')
self.cmbCausal.setToolTip('<span>Set the system type. Not implemented yet.</span>')
self.cmbCausal.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.cmbCausal.setEnabled(False)
layHDisplay = QHBoxLayout()
layHDisplay.setAlignment(Qt.AlignLeft)
layHDisplay.addWidget(self.butEnable)
layHDisplay.addWidget(self.cmbPZFrmt)
layHDisplay.addWidget(self.spnDigits)
layHDisplay.addWidget(self.lblDigits)
layHDisplay.addWidget(self.cmbCausal)
layHDisplay.addStretch()
# ---------------------------------------------
# UI Elements for setting the gain
# ---------------------------------------------
self.lblNorm = QLabel(to_html("Normalize:", frmt='bi'), self)
self.cmbNorm = QComboBox(self)
self.cmbNorm.addItems(["None", "1", "Max"])
self.cmbNorm.setToolTip("<span>Set the gain <i>k</i> so that H(f)<sub>max</sub> is "
"either 1 or the max. of the previous system.</span>")
self.lblGain = QLabel(to_html("k =", frmt='bi'), self)
self.ledGain = QLineEdit(self)
self.ledGain.setToolTip("<span>Specify gain factor <i>k</i>"
" (only possible for Normalize = 'None').</span>")
self.ledGain.setText(str(1.))
self.ledGain.setObjectName("ledGain")
layHGain = QHBoxLayout()
layHGain.addWidget(self.lblNorm)
layHGain.addWidget(self.cmbNorm)
layHGain.addWidget(self.lblGain)
layHGain.addWidget(self.ledGain)
layHGain.addStretch()
# ---------------------------------------------
# UI Elements for loading / storing / manipulating cells and rows
# ---------------------------------------------
# self.cmbFilterType = QComboBox(self)
# self.cmbFilterType.setObjectName("comboFilterType")
# self.cmbFilterType.setToolTip("Select between IIR and FIR filte for manual entry.")
# self.cmbFilterType.addItems(["FIR","IIR"])
# self.cmbFilterType.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.butAddCells = QPushButton(self)
self.butAddCells.setIcon(QIcon(':/row_insert_above.svg'))
self.butAddCells.setIconSize(q_icon_size)
self.butAddCells.setToolTip("<SPAN>Select cells to insert a new cell above each selected cell. "
"Use <SHIFT> or <CTRL> to select multiple cells. "
"When nothing is selected, add a row at the end.</SPAN>")
self.butDelCells = QPushButton(self)
self.butDelCells.setIcon(QIcon(':/row_delete.svg'))
self.butDelCells.setIconSize(q_icon_size)
self.butDelCells.setToolTip("<SPAN>Delete selected cell(s) from the table. "
"Use <SHIFT> or <CTRL> to select multiple cells. "
"When nothing is selected, delete the last row.</SPAN>")
self.butSave = QPushButton(self)
self.butSave.setIcon(QIcon(':/upload.svg'))
self.butSave.setIconSize(q_icon_size)
self.butSave.setToolTip("<span>Copy P/Z table to filter dict and update all plots and widgets.</span>")
self.butLoad = QPushButton(self)
self.butLoad.setIcon(QIcon(':/download.svg'))
self.butLoad.setIconSize(q_icon_size)
self.butLoad.setToolTip("Reload P/Z table from filter dict.")
self.butClear = QPushButton(self)
self.butClear.setIcon(QIcon(':/trash.svg'))
self.butClear.setIconSize(q_icon_size)
self.butClear.setToolTip("Clear all table entries.")
self.butFromTable = QPushButton(self)
self.butFromTable.setIconSize(q_icon_size)
self.butToTable = QPushButton(self)
self.butToTable.setIconSize(q_icon_size)
self.but_csv_options = QPushButton(self)
self.but_csv_options.setIcon(QIcon(':/settings.svg'))
self.but_csv_options.setIconSize(q_icon_size)
self.but_csv_options.setToolTip("<span>Select CSV format and whether "
"to copy to/from clipboard or file.</span>")
self.but_csv_options.setCheckable(True)
self.but_csv_options.setChecked(False)
self._set_load_save_icons() # initialize icon / button settings
layHButtonsCoeffs1 = QHBoxLayout()
# layHButtonsCoeffs1.addWidget(self.cmbFilterType)
layHButtonsCoeffs1.addWidget(self.butAddCells)
layHButtonsCoeffs1.addWidget(self.butDelCells)
layHButtonsCoeffs1.addWidget(self.butClear)
layHButtonsCoeffs1.addWidget(self.butSave)
layHButtonsCoeffs1.addWidget(self.butLoad)
layHButtonsCoeffs1.addWidget(self.butFromTable)
layHButtonsCoeffs1.addWidget(self.butToTable)
layHButtonsCoeffs1.addWidget(self.but_csv_options)
layHButtonsCoeffs1.addStretch()
#-------------------------------------------------------------------
# Eps / set zero settings
# ---------------------------------------------------------------------
self.butSetZero = QPushButton("= 0", self)
self.butSetZero.setToolTip("<span>Set selected poles / zeros = 0 with a magnitude < ε. "
"When nothing is selected, test the whole table.</span>")
self.butSetZero.setIconSize(q_icon_size)
lblEps = QLabel(self)
lblEps.setText("<b><i>for ε</i> <</b>")
self.ledEps = QLineEdit(self)
self.ledEps.setToolTip("Specify tolerance value.")
layHButtonsCoeffs2 = QHBoxLayout()
layHButtonsCoeffs2.addWidget(self.butSetZero)
layHButtonsCoeffs2.addWidget(lblEps)
layHButtonsCoeffs2.addWidget(self.ledEps)
layHButtonsCoeffs2.addStretch()
# ######################## Main UI Layout ############################
# layout for frame (UI widget)
layVMainF = QVBoxLayout()
layVMainF.addLayout(layHDisplay)
layVMainF.addLayout(layHGain)
layVMainF.addLayout(layHButtonsCoeffs1)
layVMainF.addLayout(layHButtonsCoeffs2)
# This frame encompasses all UI elements
frmMain = QFrame(self)
frmMain.setLayout(layVMainF)
layVMain = QVBoxLayout()
layVMain.setAlignment(Qt.AlignTop) # this affects only the first widget (intended here)
layVMain.addWidget(frmMain)
layVMain.setContentsMargins(*params['wdg_margins'])
self.setLayout(layVMain)
#--- set initial values from dict ------------
self.spnDigits.setValue(params['FMT_pz'])
self.ledEps.setText(str(self.eps))
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.but_csv_options.clicked.connect(self._open_csv_win)
#------------------------------------------------------------------------------
def _open_csv_win(self):
"""
Pop-up window for CSV options
"""
if self.but_csv_options.isChecked():
qstyle_widget(self.but_csv_options, "changed")
else:
qstyle_widget(self.but_csv_options, "normal")
if dirs.csv_options_handle is None: # no handle to the window? Create a new instance
if self.but_csv_options.isChecked():
# Important: Handle to window must be class attribute otherwise it
# (and the attached window) is deleted immediately when it goes out of scope
dirs.csv_options_handle = CSV_option_box(self)
dirs.csv_options_handle.sig_tx.connect(self.process_sig_rx)
dirs.csv_options_handle.show() # modeless i.e. non-blocking popup window
else:
if not self.but_csv_options.isChecked(): # this should not happen
if dirs.csv_options_handle is None:
logger.warning("CSV options window is already closed!")
else:
dirs.csv_options_handle.close()
self.sig_tx.emit({'sender':__name__, 'ui_changed': 'csv'})
#------------------------------------------------------------------------------
def _close_csv_win(self):
dirs.csv_options_handle = None
self.but_csv_options.setChecked(False)
qstyle_widget(self.but_csv_options, "normal")
#------------------------------------------------------------------------------
def _set_load_save_icons(self):
"""
Set icons / tooltipps for loading and saving data to / from file or
clipboard depending on selected options.
"""
if params['CSV']['clipboard']:
self.butFromTable.setIcon(QIcon(':/to_clipboard.svg'))
self.butFromTable.setToolTip("<span>"
"Copy table to clipboard, SELECTED items are copied as "
"displayed. When nothing is selected, the whole table "
"is copied with full precision in decimal format.</span>")
self.butToTable.setIcon(QIcon(':/from_clipboard.svg'))
self.butToTable.setToolTip("<span>Copy clipboard to table.</span>")
else:
self.butFromTable.setIcon(QIcon(':/save.svg'))
self.butFromTable.setToolTip("<span>"
"Save table to file, SELECTED items are copied as "
"displayed. When nothing is selected, the whole table "
"is copied with full precision in decimal format.</span>")
self.butToTable.setIcon(QIcon(':/file.svg'))
self.butToTable.setToolTip("<span>Load table from file.</span>")
if dirs.csv_options_handle is None:
qstyle_widget(self.but_csv_options, "normal")
self.but_csv_options.setChecked(False)
else:
qstyle_widget(self.but_csv_options, "changed")
self.but_csv_options.setChecked(True)
class SelectFilter(QWidget):
"""
Construct and read combo boxes for selecting the filter, consisting of the
following hierarchy:
1. Response Type rt (LP, HP, Hilbert, ...)
2. Filter Type ft (IIR, FIR, CIC ...)
3. Filter Class (Butterworth, ...)
Every time a combo box is changed manually, the filter tree for the selected
response resp. filter type is read and the combo box(es) further down in
the hierarchy are populated according to the available combinations.
sig_tx({'filt_changed'}) is emitted and propagated to input_filter_specs.py
where it triggers the recreation of all subwidgets.
"""
sig_tx = pyqtSignal(object) # outgoing
from pyfda.libs.pyfda_qt_lib import emit
def __init__(self, parent=None):
super(SelectFilter, self).__init__(parent)
self.fc_last = '' # previous filter class
self._construct_UI()
self._set_response_type() # first time initialization
def _construct_UI(self):
"""
Construct UI with comboboxes for selecting filter:
- cmbResponseType for selecting response type rt (LP, HP, ...)
- cmbFilterType for selection of filter type (IIR, FIR, ...)
- cmbFilterClass for selection of design design class (Chebyshev, ...)
and populate them from the "filterTree" dict during the initial run.
Later, calling _set_response_type() updates the three combo boxes.
See filterbroker.py for structure and content of "filterTree" dict
"""
# ----------------------------------------------------------------------
# Combo boxes for filter selection
# ----------------------------------------------------------------------
self.cmbResponseType = QComboBox(self)
self.cmbResponseType.setObjectName("comboResponseType")
self.cmbResponseType.setToolTip("Select filter response type.")
self.cmbFilterType = QComboBox(self)
self.cmbFilterType.setObjectName("comboFilterType")
self.cmbFilterType.setToolTip(
"<span>Choose filter type, either recursive (Infinite Impulse Response) "
"or transversal (Finite Impulse Response).</span>")
self.cmbFilterClass = QComboBox(self)
self.cmbFilterClass.setObjectName("comboFilterClass")
self.cmbFilterClass.setToolTip("Select the filter design class.")
# Adapt comboboxes size dynamically to largest element
self.cmbResponseType.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.cmbFilterType.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.cmbFilterClass.setSizeAdjustPolicy(QComboBox.AdjustToContents)
# ----------------------------------------------------------------------
# Populate combo box with initial settings from fb.fil_tree
# ----------------------------------------------------------------------
# Translate short response type ("LP") to displayed names ("Lowpass")
# (correspondence is defined in pyfda_rc.py) and populate rt combo box
#
rt_list = sorted(list(fb.fil_tree.keys()))
for rt in rt_list:
try:
self.cmbResponseType.addItem(rc.rt_names[rt], rt)
except KeyError as e:
logger.warning(
f"KeyError: {e} has no corresponding full name in rc.rt_names."
)
idx = self.cmbResponseType.findData('LP') # find index for 'LP'
if idx == -1: # Key 'LP' does not exist, use first entry instead
idx = 0
self.cmbResponseType.setCurrentIndex(idx) # set initial index
rt = qget_cmb_box(self.cmbResponseType)
for ft in fb.fil_tree[rt]:
self.cmbFilterType.addItem(rc.ft_names[ft], ft)
self.cmbFilterType.setCurrentIndex(0) # set initial index
ft = qget_cmb_box(self.cmbFilterType)
for fc in fb.fil_tree[rt][ft]:
self.cmbFilterClass.addItem(fb.filter_classes[fc]['name'], fc)
self.cmbFilterClass.setCurrentIndex(0) # set initial index
# ----------------------------------------------------------------------
# Layout for Filter Type Subwidgets
# ----------------------------------------------------------------------
layHFilWdg = QHBoxLayout() # container for filter subwidgets
layHFilWdg.addWidget(self.cmbResponseType) # LP, HP, BP, etc.
layHFilWdg.addStretch()
layHFilWdg.addWidget(self.cmbFilterType) # FIR, IIR
layHFilWdg.addStretch()
layHFilWdg.addWidget(self.cmbFilterClass) # bessel, elliptic, etc.
# ----------------------------------------------------------------------
# Layout for dynamic filter subwidgets (empty frame)
# ----------------------------------------------------------------------
# see Summerfield p. 278
self.layHDynWdg = QHBoxLayout() # for additional dynamic subwidgets
# ----------------------------------------------------------------------
# Filter Order Subwidgets
# ----------------------------------------------------------------------
self.lblOrder = QLabel("<b>Order:</b>")
self.chkMinOrder = QCheckBox("Minimum", self)
self.chkMinOrder.setToolTip(
"<span>Minimum filter order / # of taps is determined automatically.</span>"
)
self.lblOrderN = QLabel("<b><i>N =</i></b>")
self.ledOrderN = QLineEdit(str(fb.fil[0]['N']), self)
self.ledOrderN.setToolTip("Filter order (# of taps - 1).")
# --------------------------------------------------
# Layout for filter order subwidgets
# --------------------------------------------------
layHOrdWdg = QHBoxLayout()
layHOrdWdg.addWidget(self.lblOrder)
layHOrdWdg.addWidget(self.chkMinOrder)
layHOrdWdg.addStretch()
layHOrdWdg.addWidget(self.lblOrderN)
layHOrdWdg.addWidget(self.ledOrderN)
# ----------------------------------------------------------------------
# OVERALL LAYOUT (stack standard + dynamic subwidgets vertically)
# ----------------------------------------------------------------------
self.layVAllWdg = QVBoxLayout()
self.layVAllWdg.addLayout(layHFilWdg)
self.layVAllWdg.addLayout(self.layHDynWdg)
self.layVAllWdg.addLayout(layHOrdWdg)
# ==============================================================================
frmMain = QFrame(self)
frmMain.setLayout(self.layVAllWdg)
layHMain = QHBoxLayout()
layHMain.addWidget(frmMain)
layHMain.setContentsMargins(*rc.params['wdg_margins'])
self.setLayout(layHMain)
# ==============================================================================
# ------------------------------------------------------------
# SIGNALS & SLOTS
# ------------------------------------------------------------
# Connect comboBoxes and setters, propgate change events hierarchically
# through all widget methods and emit 'filt_changed' in the end.
self.cmbResponseType.currentIndexChanged.connect(
lambda: self._set_response_type(enb_signal=True)) # 'LP'
self.cmbFilterType.currentIndexChanged.connect(
lambda: self._set_filter_type(enb_signal=True)) # 'IIR'
self.cmbFilterClass.currentIndexChanged.connect(
lambda: self._set_design_method(enb_signal=True)) # 'cheby1'
self.chkMinOrder.clicked.connect(
lambda: self._set_filter_order(enb_signal=True)) # Min. Order
self.ledOrderN.editingFinished.connect(
lambda: self._set_filter_order(enb_signal=True)) # Manual Order
# ------------------------------------------------------------
# ------------------------------------------------------------------------------
def load_dict(self):
"""
Reload comboboxes from filter dictionary to update changed settings
after loading a filter design from disk.
`load_dict` uses the automatism of _set_response_type etc.
of checking whether the previously selected filter design method is
also available for the new combination.
"""
# find index for response type:
rt_idx = self.cmbResponseType.findData(fb.fil[0]['rt'])
self.cmbResponseType.setCurrentIndex(rt_idx)
self._set_response_type()
# ------------------------------------------------------------------------------
def _set_response_type(self, enb_signal=False):
"""
Triggered when cmbResponseType (LP, HP, ...) is changed:
Copy selection to self.rt and fb.fil[0] and reconstruct filter type combo
If previous filter type (FIR, IIR, ...) exists for new rt, set the
filter type combo box to the old setting
"""
# Read current setting of comboBox as string and store it in the filter dict
fb.fil[0]['rt'] = self.rt = qget_cmb_box(self.cmbResponseType)
# Get list of available filter types for new rt
ft_list = list(
fb.fil_tree[self.rt].keys()) # explicit list() needed for Py3
# ---------------------------------------------------------------
# Rebuild filter type combobox entries for new rt setting
self.cmbFilterType.blockSignals(
True) # don't fire when changed programmatically
self.cmbFilterType.clear()
for ft in fb.fil_tree[self.rt]:
self.cmbFilterType.addItem(rc.ft_names[ft], ft)
# Is current filter type (e.g. IIR) in list for new rt?
if fb.fil[0]['ft'] in ft_list:
ft_idx = self.cmbFilterType.findText(fb.fil[0]['ft'])
self.cmbFilterType.setCurrentIndex(
ft_idx) # yes, set same ft as before
else:
self.cmbFilterType.setCurrentIndex(0) # no, set index 0
self.cmbFilterType.blockSignals(False)
# ---------------------------------------------------------------
self._set_filter_type(enb_signal)
# ------------------------------------------------------------------------------
def _set_filter_type(self, enb_signal=False):
""""
Triggered when cmbFilterType (IIR, FIR, ...) is changed:
- read filter type ft and copy it to fb.fil[0]['ft'] and self.ft
- (re)construct design method combo, adding
displayed text (e.g. "Chebyshev 1") and hidden data (e.g. "cheby1")
"""
# Read out current setting of comboBox and convert to string
fb.fil[0]['ft'] = self.ft = qget_cmb_box(self.cmbFilterType)
#
logger.debug("InputFilter.set_filter_type triggered: {0}".format(
self.ft))
# ---------------------------------------------------------------
# Get all available design methods for new ft from fil_tree and
# - Collect them in fc_list
# - Rebuild design method combobox entries for new ft setting:
# The combobox is populated with the "long name",
# the internal name is stored in comboBox.itemData
self.cmbFilterClass.blockSignals(True)
self.cmbFilterClass.clear()
fc_list = []
for fc in sorted(fb.fil_tree[self.rt][self.ft]):
self.cmbFilterClass.addItem(fb.filter_classes[fc]['name'], fc)
fc_list.append(fc)
logger.debug("fc_list: {0}\n{1}".format(fc_list, fb.fil[0]['fc']))
# Does new ft also provide the previous design method (e.g. ellip)?
# Has filter been instantiated?
if fb.fil[0]['fc'] in fc_list and ff.fil_inst:
# yes, set same fc as before
fc_idx = self.cmbFilterClass.findText(
fb.filter_classes[fb.fil[0]['fc']]['name'])
logger.debug("fc_idx : %s", fc_idx)
self.cmbFilterClass.setCurrentIndex(fc_idx)
else:
self.cmbFilterClass.setCurrentIndex(0) # no, set index 0
self.cmbFilterClass.blockSignals(False)
self._set_design_method(enb_signal)
# ------------------------------------------------------------------------------
def _set_design_method(self, enb_signal=False):
"""
Triggered when cmbFilterClass (cheby1, ...) is changed:
- read design method fc and copy it to fb.fil[0]
- create / update global filter instance fb.fil_inst of fc class
- update dynamic widgets (if fc has changed and if there are any)
- call load filter order
"""
fb.fil[0]['fc'] = fc = qget_cmb_box(self.cmbFilterClass)
if fc != self.fc_last: # fc has changed:
# when filter has been changed, try to destroy dynamic widgets of last fc:
if self.fc_last:
self._destruct_dyn_widgets()
# ==================================================================
"""
Create new instance of the selected filter class, accessible via
its handle fb.fil_inst
"""
err = ff.fil_factory.create_fil_inst(fc)
logger.debug(f"InputFilter.set_design_method triggered: {fc}\n"
f"Returned error code {err}")
# ==================================================================
# Check whether new design method also provides the old filter order
# method. If yes, don't change it, else set first available
# filter order method
if fb.fil[0]['fo'] not in fb.fil_tree[self.rt][self.ft][fc].keys():
fb.fil[0].update({'fo': {}})
# explicit list(dict.keys()) needed for Python 3
fb.fil[0]['fo'] = list(
fb.fil_tree[self.rt][self.ft][fc].keys())[0]
# =============================================================================
# logger.debug("selFilter = %s"
# "filterTree[fc] = %s"
# "filterTree[fc].keys() = %s"
# %(fb.fil[0], fb.fil_tree[self.rt][self.ft][fc],\
# fb.fil_tree[self.rt][self.ft][fc].keys()
# ))
#
# =============================================================================
# construct dyn. subwidgets if available
if hasattr(ff.fil_inst, 'construct_UI'):
self._construct_dyn_widgets()
self.fc_last = fb.fil[0]['fc']
self.load_filter_order(enb_signal)
# ------------------------------------------------------------------------------
def load_filter_order(self, enb_signal=False):
"""
Called by set_design_method or from InputSpecs (with enb_signal = False),
load filter order setting from fb.fil[0] and update widgets
"""
# collect dict_keys of available filter order [fo] methods for selected
# design method [fc] from fil_tree (explicit list() needed for Python 3)
fo_dict = fb.fil_tree[fb.fil[0]['rt']][fb.fil[0]['ft']][fb.fil[0]
['fc']]
fo_list = list(fo_dict.keys())
# is currently selected fo setting available for (new) fc ?
if fb.fil[0]['fo'] in fo_list:
self.fo = fb.fil[0]['fo'] # keep current setting
else:
self.fo = fo_list[0] # use first list entry from filterTree
fb.fil[0]['fo'] = self.fo # and update fo method
# check whether fo widget is active, disabled or invisible
if 'fo' in fo_dict[self.fo] and len(fo_dict[self.fo]['fo']) > 1:
status = fo_dict[self.fo]['fo'][0]
else:
status = 'i'
# Determine which subwidgets are __visible__
self.chkMinOrder.setVisible('min' in fo_list)
self.ledOrderN.setVisible(status in {'a', 'd'})
self.lblOrderN.setVisible(status in {'a', 'd'})
# Determine which subwidgets are __enabled__
self.chkMinOrder.setChecked(fb.fil[0]['fo'] == 'min')
self.ledOrderN.setText(str(fb.fil[0]['N']))
self.ledOrderN.setEnabled(not self.chkMinOrder.isChecked()
and status == 'a')
self.lblOrderN.setEnabled(not self.chkMinOrder.isChecked()
and status == 'a')
if enb_signal:
logger.debug("Emit 'filt_changed'")
self.emit({'filt_changed': 'filter_type'})
# ------------------------------------------------------------------------------
def _set_filter_order(self, enb_signal=False):
"""
Triggered when either ledOrderN or chkMinOrder are edited:
- copy settings to fb.fil[0]
- emit 'filt_changed' if enb_signal is True
"""
# Determine which subwidgets are _enabled_
if self.chkMinOrder.isVisible():
self.ledOrderN.setEnabled(not self.chkMinOrder.isChecked())
self.lblOrderN.setEnabled(not self.chkMinOrder.isChecked())
if self.chkMinOrder.isChecked() is True:
# update in case N has been changed outside this class
self.ledOrderN.setText(str(fb.fil[0]['N']))
fb.fil[0].update({'fo': 'min'})
else:
fb.fil[0].update({'fo': 'man'})
else:
self.lblOrderN.setEnabled(self.fo == 'man')
self.ledOrderN.setEnabled(self.fo == 'man')
# read manual filter order, convert to positive integer and store it
# in filter dictionary.
ordn = safe_eval(self.ledOrderN.text(),
fb.fil[0]['N'],
return_type='int',
sign='pos')
ordn = ordn if ordn > 0 else 1
self.ledOrderN.setText(str(ordn))
fb.fil[0].update({'N': ordn})
if enb_signal:
logger.debug("Emit 'filt_changed'")
self.emit({'filt_changed': 'filter_order_widget'})
# ------------------------------------------------------------------------------
def _destruct_dyn_widgets(self):
"""
Delete the dynamically created filter design subwidget (if there is one)
see http://stackoverflow.com/questions/13827798/proper-way-to-cleanup-
widgets-in-pyqt
This does NOT work when the subwidgets to be deleted and created are
identical, as the deletion is only performed when the current scope has
been left (?)! Hence, it is necessary to skip this method when the new
design method is the same as the old one.
"""
if hasattr(ff.fil_inst, 'wdg_fil'):
# not needed, connection is destroyed automatically
# ff.fil_inst.sig_tx.disconnect()
try:
# remove widget from layout
self.layHDynWdg.removeWidget(self.dyn_wdg_fil)
# delete UI widget when scope has been left
self.dyn_wdg_fil.deleteLater()
except AttributeError as e:
logger.error("Could not destruct_UI!\n{0}".format(e))
ff.fil_inst.deleteLater(
) # delete QWidget when scope has been left
# ------------------------------------------------------------------------------
def _construct_dyn_widgets(self):
"""
Create filter widget UI dynamically (if the filter routine has one) and
connect its sig_tx signal to sig_tx in this scope.
"""
ff.fil_inst.construct_UI()
if hasattr(ff.fil_inst, 'wdg_fil'):
try:
self.dyn_wdg_fil = getattr(ff.fil_inst, 'wdg_fil')
self.layHDynWdg.addWidget(self.dyn_wdg_fil, stretch=1)
except AttributeError as e:
logger.warning(e)
if hasattr(ff.fil_inst, 'sig_tx'):
ff.fil_inst.sig_tx.connect(self.sig_tx)
class Plot_tau_g(QWidget):
"""
Widget for plotting the group delay
"""
# incoming, connected in sender widget (locally connected to self.process_signals() )
sig_rx = pyqtSignal(object)
# sig_tx = pyqtSignal(object) # outgoing from process_signals
def __init__(self, parent):
super(Plot_tau_g, self).__init__(parent)
self.verbose = False # suppress warnings
self.algorithm = "diff"
self.needs_calc = True # flag whether plot needs to be recalculated
self.tool_tip = self.tr("Group delay")
self.tab_label = "\U0001D70F(f)"#"tau_g" \u03C4
self._construct_UI()
def _construct_UI(self):
"""
Intitialize the widget, consisting of:
- Matplotlib widget with NavigationToolbar
- Frame with control elements
"""
self.chkWarnings = QCheckBox(self.tr("Verbose"), self)
self.chkWarnings.setChecked(self.verbose)
self.chkWarnings.setToolTip(self.tr("<span>Print messages about singular group delay"
"and calculation times."))
self.cmbAlgorithm = QComboBox(self)
for t in [(self.tr("Auto"),"auto"),(self.tr("Scipy"),"scipy"), (self.tr("JOS"), "jos"),
(self.tr("Diff"), "diff"), (self.tr("Shpak"), "shpak")]: # text, data
self.cmbAlgorithm.addItem(*t)
qset_cmb_box(self.cmbAlgorithm, self.algorithm,data=True)
self.cmbAlgorithm.setToolTip(self.tr("<span>Select algorithm for calculating "
"the group delay.</span>"))
self.cmbAlgorithm.setItemData(0, self.tr("<span>Try to find best-suited algorithm."
"</span>"),Qt.ToolTipRole)
self.cmbAlgorithm.setItemData(1, self.tr("<span>Scipy algorithm.</span>"),Qt.ToolTipRole)
self.cmbAlgorithm.setItemData(2, self.tr("<span>J.O. Smith's algorithm.</span>"),Qt.ToolTipRole)
self.cmbAlgorithm.setItemData(3, self.tr("<span>Textbook-style, differentiate "
"the phase.</span>"),Qt.ToolTipRole)
self.cmbAlgorithm.setItemData(4, self.tr("<span>Shpak's algorithm for SOS and other "
"IIR filters.</span>"),Qt.ToolTipRole)
#self.chkScipy = QCheckBox("Scipy", self)
#self.chkScipy.setChecked(False)
#self.chkScipy.setToolTip("Use scipy group delay routine")
layHControls = QHBoxLayout()
layHControls.addStretch(10)
layHControls.addWidget(self.chkWarnings)
#layHControls.addWidget(self.chkScipy)
layHControls.addWidget(self.cmbAlgorithm)
# This widget encompasses all control subwidgets:
self.frmControls = QFrame(self)
self.frmControls.setObjectName("frmControls")
self.frmControls.setLayout(layHControls)
self.mplwidget = MplWidget(self)
self.mplwidget.layVMainMpl.addWidget(self.frmControls)
self.mplwidget.layVMainMpl.setContentsMargins(*params['wdg_margins'])
self.mplwidget.mplToolbar.a_he.setEnabled(True)
self.mplwidget.mplToolbar.a_he.info = "manual/plot_tau_g.html"
self.setLayout(self.mplwidget.layVMainMpl)
self.init_axes()
self.draw() # initial drawing of tau_g
#----------------------------------------------------------------------
# GLOBAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.sig_rx.connect(self.process_sig_rx)
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.mplwidget.mplToolbar.sig_tx.connect(self.process_sig_rx)
self.cmbAlgorithm.currentIndexChanged.connect(self.draw)
#------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig=None):
"""
Process signals coming from the navigation toolbar and from sig_rx
"""
logger.debug("Processing {0} | needs_calc = {1}, visible = {2}"\
.format(dict_sig, self.needs_calc, self.isVisible()))
if self.isVisible():
if 'data_changed' in dict_sig or 'home' in dict_sig or self.needs_calc:
self.draw()
self.needs_calc = False
elif 'view_changed' in dict_sig:
self.update_view()
else:
if 'data_changed' in dict_sig or 'view_changed' in dict_sig:
self.needs_calc = True
#------------------------------------------------------------------------------
def init_axes(self):
"""
Initialize the axes and set some stuff that is not cleared by
`ax.clear()` later on.
"""
self.ax = self.mplwidget.fig.subplots()
self.ax.xaxis.tick_bottom() # remove axis ticks on top
self.ax.yaxis.tick_left() # remove axis ticks right
#------------------------------------------------------------------------------
def calc_tau_g(self):
"""
(Re-)Calculate the complex frequency response H(f)
"""
bb = fb.fil[0]['ba'][0]
aa = fb.fil[0]['ba'][1]
# calculate H_cmplx(W) (complex) for W = 0 ... 2 pi:
# scipy: self.W, self.tau_g = group_delay((bb, aa), w=params['N_FFT'], whole = True)
if fb.fil[0]['creator'][0] == 'sos': # one of 'sos', 'zpk', 'ba'
self.W, self.tau_g = group_delay(fb.fil[0]['sos'], nfft=params['N_FFT'], sos=True,
whole=True, verbose=self.chkWarnings.isChecked(),
alg=self.cmbAlgorithm.currentData())
else:
self.W, self.tau_g = group_delay(bb, aa, nfft=params['N_FFT'], whole=True,
verbose=self.chkWarnings.isChecked(),
alg=self.cmbAlgorithm.currentData()) # self.chkWarnings.isChecked())
# Zero phase filters have no group delay (Causal+AntiCausal)
if 'baA' in fb.fil[0]:
self.tau_g = np.zeros(self.tau_g.size)
#------------------------------------------------------------------------------
def draw(self):
self.calc_tau_g()
self.update_view()
#------------------------------------------------------------------------------
def update_view(self):
"""
Draw the figure with new limits, scale etc without recalculating H(f)
"""
#========= select frequency range to be displayed =====================
#=== shift, scale and select: W -> F, H_cplx -> H_c
f_max_2 = fb.fil[0]['f_max'] / 2.
F = self.W * f_max_2 / np.pi
if fb.fil[0]['freqSpecsRangeType'] == 'sym':
# shift tau_g and F by f_S/2
tau_g = np.fft.fftshift(self.tau_g)
F -= f_max_2
elif fb.fil[0]['freqSpecsRangeType'] == 'half':
# only use the first half of H and F
tau_g = self.tau_g[0:params['N_FFT']//2]
F = F[0:params['N_FFT']//2]
else: # fb.fil[0]['freqSpecsRangeType'] == 'whole'
# use H and F as calculated
tau_g = self.tau_g
#================ Main Plotting Routine =========================
#=== clear the axes and (re)draw the plot
if fb.fil[0]['freq_specs_unit'] in {'f_S', 'f_Ny'}:
tau_str = r'$ \tau_g(\mathrm{e}^{\mathrm{j} \Omega}) / T_S \; \rightarrow $'
else:
tau_str = r'$ \tau_g(\mathrm{e}^{\mathrm{j} \Omega})$'\
+ ' in ' + fb.fil[0]['plt_tUnit'] + r' $ \rightarrow $'
tau_g = tau_g / fb.fil[0]['f_S']
#---------------------------------------------------------
self.ax.clear() # need to clear, doesn't overwrite
line_tau_g, = self.ax.plot(F, tau_g, label = "Group Delay")
#---------------------------------------------------------
self.ax.xaxis.set_minor_locator(AutoMinorLocator()) # enable minor ticks
self.ax.yaxis.set_minor_locator(AutoMinorLocator()) # enable minor ticks
self.ax.set_title(r'Group Delay $ \tau_g$')
self.ax.set_xlabel(fb.fil[0]['plt_fLabel'])
self.ax.set_ylabel(tau_str)
# widen y-limits to suppress numerical inaccuracies when tau_g = constant
self.ax.set_ylim([max(np.nanmin(tau_g)-0.5,0), np.nanmax(tau_g) + 0.5])
self.ax.set_xlim(fb.fil[0]['freqSpecsRange'])
self.redraw()
#------------------------------------------------------------------------------
def redraw(self):
"""
Redraw the canvas when e.g. the canvas size has changed
"""
self.mplwidget.redraw()
class Input_Fixpoint_Specs(QWidget):
"""
Create the widget that holds the dynamically loaded fixpoint filter ui
"""
# emit a signal when the image has been resized
sig_resize = pyqtSignal()
# incoming from subwidgets -> process_sig_rx_local
sig_rx_local = pyqtSignal(object)
# incoming, connected to input_tab_widget.sig_rx
sig_rx = pyqtSignal(object)
# outcgoing
sig_tx = pyqtSignal(object)
def __init__(self, parent):
super(Input_Fixpoint_Specs, self).__init__(parent)
self.tab_label = 'Fixpoint'
self.tool_tip = (
"<span>Select a fixpoint implementation for the filter,"
" simulate it or generate a Verilog netlist.</span>")
self.parent = parent
self.fx_path = os.path.realpath(
os.path.join(dirs.INSTALL_DIR, 'fixpoint_widgets'))
self.no_fx_filter_img = os.path.join(self.fx_path, "no_fx_filter.png")
if not os.path.isfile(self.no_fx_filter_img):
logger.error("Image {0:s} not found!".format(
self.no_fx_filter_img))
self.default_fx_img = os.path.join(self.fx_path, "default_fx_img.png")
if not os.path.isfile(self.default_fx_img):
logger.error("Image {0:s} not found!".format(self.default_fx_img))
if HAS_MIGEN:
self._construct_UI()
else:
self.state = "deactivated" # "invisible", "disabled"
#------------------------------------------------------------------------------
def process_sig_rx(self, dict_sig=None):
"""
Process signals coming in via subwidgets and sig_rx
Play PingPong with a stimulus & plot widget:
2. ``fx_sim_init()``: Request stimulus by sending 'fx_sim':'get_stimulus'
3. ``fx_sim_set_stimulus()``: Receive stimulus from widget in 'fx_sim':'send_stimulus'
and pass it to HDL object for simulation
4. Send back HDL response to widget via 'fx_sim':'set_response'
"""
logger.debug("process_sig_rx(): vis={0}\n{1}"\
.format(self.isVisible(), pprint_log(dict_sig)))
if dict_sig['sender'] == __name__:
logger.debug("Stopped infinite loop\n{0}".format(
pprint_log(dict_sig)))
return
elif 'data_changed' in dict_sig and dict_sig[
'data_changed'] == "filter_designed":
# New filter has been designed, update list of available filter topologies here
self._update_filter_cmb()
return
elif 'data_changed' in dict_sig or\
('view_changed' in dict_sig and dict_sig['view_changed'] == 'q_coeff'):
# update fields in the filter topology widget - wordlength may have
# been changed. Also set RUN button to "changed" in wdg_dict2ui()
self.wdg_dict2ui()
#self.sig_tx.emit({'sender':__name__, 'fx_sim':'specs_changed'})
elif 'fx_sim' in dict_sig:
if dict_sig['fx_sim'] == 'init':
if self.fx_wdg_found:
self.fx_sim_init()
else:
logger.error("No fixpoint widget found!")
qstyle_widget(self.butSimHDL, "error")
self.sig_tx.emit({'sender': __name__, 'fx_sim': 'error'})
elif dict_sig['fx_sim'] == 'send_stimulus':
self.fx_sim_set_stimulus(dict_sig)
elif dict_sig['fx_sim'] == 'specs_changed':
# fixpoint specification have been changed somewhere, update ui
# and set run button to "changed" in wdg_dict2ui()
self.wdg_dict2ui()
elif dict_sig['fx_sim'] == 'finish':
qstyle_widget(self.butSimHDL, "normal")
logger.info('Fixpoint simulation [{0:5.3g} ms]: Plotting finished'\
.format((time.process_time() - self.t_resp)*1000))
else:
logger.error('Unknown "fx_sim" command option "{0}"\n'
'\treceived from "{1}".'.format(
dict_sig['fx_sim'], dict_sig['sender']))
# ---- Process local widget signals
elif 'ui' in dict_sig:
if 'id' in dict_sig and dict_sig['id'] == 'w_input':
"""
Input fixpoint format has been changed or butLock has been clicked.
When I/O lock is active, copy input fixpoint word format to output
word format.
"""
if dict_sig[
'ui'] == 'butLock' and not self.wdg_w_input.butLock.isChecked(
):
# butLock was deactivitated, don't do anything
return
elif self.wdg_w_input.butLock.isChecked():
# but lock was activated or wordlength setting have been changed
fb.fil[0]['fxqc']['QO']['WI'] = fb.fil[0]['fxqc']['QI'][
'WI']
fb.fil[0]['fxqc']['QO']['WF'] = fb.fil[0]['fxqc']['QI'][
'WF']
fb.fil[0]['fxqc']['QO']['W'] = fb.fil[0]['fxqc']['QI']['W']
elif 'id' in dict_sig and dict_sig['id'] == 'w_output':
"""
Output fixpoint format has been changed. When I/O lock is active, copy
output fixpoint word format to input word format.
"""
if self.wdg_w_input.butLock.isChecked():
fb.fil[0]['fxqc']['QI']['WI'] = fb.fil[0]['fxqc']['QO'][
'WI']
fb.fil[0]['fxqc']['QI']['WF'] = fb.fil[0]['fxqc']['QO'][
'WF']
fb.fil[0]['fxqc']['QI']['W'] = fb.fil[0]['fxqc']['QO']['W']
elif 'id' in dict_sig and dict_sig['id'] in \
{'w_coeff', 'q_input', 'q_output', 'w_accu', 'q_accu'}:
pass # nothing to do for now
else:
if not "id" in dict_sig:
logger.warning("No id in dict_sig:\n{0}".format(
pprint_log(dict_sig)))
else:
logger.warning('Unknown id "{0}" in dict_sig:\n{1}'\
.format(dict_sig['id'], pprint_log(dict_sig)))
if not dict_sig['ui'] in {
'WI', 'WF', 'ovfl', 'quant', 'cmbW', 'butLock'
}:
logger.warning("Unknown value '{0}' for key 'ui'".format(
dict_sig['ui']))
self.wdg_dict2ui(
) # update wordlengths in UI and set RUN button to 'changed'
self.sig_tx.emit({'sender': __name__, 'fx_sim': 'specs_changed'})
return
#------------------------------------------------------------------------------
def _construct_UI(self):
"""
Intitialize the main GUI, consisting of:
- A combo box to select the filter topology and an image of the topology
- The input quantizer
- The UI of the fixpoint filter widget
- Simulation and export buttons
"""
#------------------------------------------------------------------------------
# Define frame and layout for the dynamically updated filter widget
# The actual filter widget is instantiated in self.set_fixp_widget() later on
self.layH_fx_wdg = QHBoxLayout()
#self.layH_fx_wdg.setContentsMargins(*params['wdg_margins'])
frmHDL_wdg = QFrame(self)
frmHDL_wdg.setLayout(self.layH_fx_wdg)
#frmHDL_wdg.setSizePolicy(QSizePolicy.Minimum, QSizePolicy.Minimum)
#------------------------------------------------------------------------------
# Initialize fixpoint filter combobox, title and description
#------------------------------------------------------------------------------
self.cmb_wdg_fixp = QComboBox(self)
self.cmb_wdg_fixp.setSizeAdjustPolicy(QComboBox.AdjustToContents)
self.lblTitle = QLabel("not set", self)
self.lblTitle.setWordWrap(True)
self.lblTitle.setSizePolicy(QSizePolicy.Expanding, QSizePolicy.Fixed)
layHTitle = QHBoxLayout()
layHTitle.addWidget(self.cmb_wdg_fixp)
layHTitle.addWidget(self.lblTitle)
self.frmTitle = QFrame(self)
self.frmTitle.setLayout(layHTitle)
self.frmTitle.setContentsMargins(*params['wdg_margins'])
#------------------------------------------------------------------------------
# Input and Output Quantizer
#------------------------------------------------------------------------------
# - instantiate widgets for input and output quantizer
# - pass the quantization (sub-?) dictionary to the constructor
#------------------------------------------------------------------------------
self.wdg_w_input = UI_W(self,
q_dict=fb.fil[0]['fxqc']['QI'],
id='w_input',
label='',
lock_visible=True)
self.wdg_w_input.sig_tx.connect(self.process_sig_rx)
cmb_q = ['round', 'floor', 'fix']
self.wdg_w_output = UI_W(self,
q_dict=fb.fil[0]['fxqc']['QO'],
id='w_output',
label='')
self.wdg_w_output.sig_tx.connect(self.process_sig_rx)
self.wdg_q_output = UI_Q(
self,
q_dict=fb.fil[0]['fxqc']['QO'],
id='q_output',
label='Output Format <i>Q<sub>Y </sub></i>:',
cmb_q=cmb_q,
cmb_ov=['wrap', 'sat'])
self.wdg_q_output.sig_tx.connect(self.sig_rx)
if HAS_DS:
cmb_q.append('dsm')
self.wdg_q_input = UI_Q(
self,
q_dict=fb.fil[0]['fxqc']['QI'],
id='q_input',
label='Input Format <i>Q<sub>X </sub></i>:',
cmb_q=cmb_q)
self.wdg_q_input.sig_tx.connect(self.sig_rx)
# Layout and frame for input quantization
layVQiWdg = QVBoxLayout()
layVQiWdg.addWidget(self.wdg_q_input)
layVQiWdg.addWidget(self.wdg_w_input)
frmQiWdg = QFrame(self)
#frmBtns.setFrameStyle(QFrame.StyledPanel|QFrame.Sunken)
frmQiWdg.setLayout(layVQiWdg)
frmQiWdg.setContentsMargins(*params['wdg_margins'])
# Layout and frame for output quantization
layVQoWdg = QVBoxLayout()
layVQoWdg.addWidget(self.wdg_q_output)
layVQoWdg.addWidget(self.wdg_w_output)
frmQoWdg = QFrame(self)
#frmBtns.setFrameStyle(QFrame.StyledPanel|QFrame.Sunken)
frmQoWdg.setLayout(layVQoWdg)
frmQoWdg.setContentsMargins(*params['wdg_margins'])
#------------------------------------------------------------------------------
# Dynamically updated image of filter topology
#------------------------------------------------------------------------------
# label is a placeholder for image
self.lbl_fixp_img = QLabel("img not set", self)
#self.lbl_fixp_img.setSizePolicy(QSizePolicy.Minimum, QSizePolicy.Minimum)
self.embed_fixp_img(self.no_fx_filter_img)
layHImg = QHBoxLayout()
layHImg.setContentsMargins(0, 0, 0, 0)
layHImg.addWidget(self.lbl_fixp_img) #, Qt.AlignCenter)
self.frmImg = QFrame(self)
self.frmImg.setLayout(layHImg)
self.frmImg.setContentsMargins(*params['wdg_margins'])
self.resize_img()
#------------------------------------------------------------------------------
# Simulation and export Buttons
#------------------------------------------------------------------------------
self.butExportHDL = QPushButton(self)
self.butExportHDL.setToolTip(
"Export fixpoint filter in Verilog format.")
self.butExportHDL.setText("Create HDL")
self.butSimHDL = QPushButton(self)
self.butSimHDL.setToolTip("Start migen fixpoint simulation.")
self.butSimHDL.setText("Sim. HDL")
self.butSimFxPy = QPushButton(self)
self.butSimFxPy.setToolTip("Simulate filter with fixpoint effects.")
self.butSimFxPy.setText("Sim. FixPy")
self.layHHdlBtns = QHBoxLayout()
self.layHHdlBtns.addWidget(self.butSimFxPy)
self.layHHdlBtns.addWidget(self.butSimHDL)
self.layHHdlBtns.addWidget(self.butExportHDL)
# This frame encompasses the HDL buttons sim and convert
frmHdlBtns = QFrame(self)
#frmBtns.setFrameStyle(QFrame.StyledPanel|QFrame.Sunken)
frmHdlBtns.setLayout(self.layHHdlBtns)
frmHdlBtns.setContentsMargins(*params['wdg_margins'])
# -------------------------------------------------------------------
# Top level layout
# -------------------------------------------------------------------
splitter = QSplitter(self)
splitter.setOrientation(Qt.Vertical)
splitter.addWidget(frmHDL_wdg)
splitter.addWidget(frmQoWdg)
splitter.addWidget(self.frmImg)
# setSizes uses absolute pixel values, but can be "misused" by specifying values
# that are way too large: in this case, the space is distributed according
# to the _ratio_ of the values:
splitter.setSizes([3000, 3000, 5000])
layVMain = QVBoxLayout()
layVMain.addWidget(self.frmTitle)
layVMain.addWidget(frmHdlBtns)
layVMain.addWidget(frmQiWdg)
layVMain.addWidget(splitter)
layVMain.addStretch()
layVMain.setContentsMargins(*params['wdg_margins'])
self.setLayout(layVMain)
#----------------------------------------------------------------------
# GLOBAL SIGNALS & SLOTs
#----------------------------------------------------------------------
self.sig_rx.connect(self.process_sig_rx)
#----------------------------------------------------------------------
# LOCAL SIGNALS & SLOTs & EVENTFILTERS
#----------------------------------------------------------------------
# monitor events and generate sig_resize event when resized
self.lbl_fixp_img.installEventFilter(self)
# ... then redraw image when resized
self.sig_resize.connect(self.resize_img)
self.cmb_wdg_fixp.currentIndexChanged.connect(self._update_fixp_widget)
self.butExportHDL.clicked.connect(self.exportHDL)
self.butSimHDL.clicked.connect(self.fx_sim_init)
#----------------------------------------------------------------------
inst_wdg_list = self._update_filter_cmb()
if len(inst_wdg_list) == 0:
logger.warning("No fixpoint filters found!")
else:
logger.debug("Imported {0:d} fixpoint filters:\n{1}".format(
len(inst_wdg_list.split("\n")) - 1, inst_wdg_list))
self._update_fixp_widget()
#------------------------------------------------------------------------------
def _update_filter_cmb(self):
"""
(Re-)Read list of available fixpoint filters for a given filter design
every time a new filter design is selected.
Then try to import the fixpoint designs in the list and populate the
fixpoint implementation combo box `self.cmb_wdg_fixp` when successfull.
"""
inst_wdg_str = "" # full names of successfully instantiated widgets for logging
last_fx_wdg = qget_cmb_box(
self.cmb_wdg_fixp, data=False) # remember last fx widget setting
self.cmb_wdg_fixp.clear()
fc = fb.fil[0]['fc']
if 'fix' in fb.filter_classes[fc]:
for class_name in fb.filter_classes[fc]['fix']: # get class name
try:
# construct module + class name
mod_class_name = fb.fixpoint_classes[class_name][
'mod'] + '.' + class_name
disp_name = fb.fixpoint_classes[class_name][
'name'] # # and display name
self.cmb_wdg_fixp.addItem(disp_name, mod_class_name)
inst_wdg_str += '\t' + class_name + ' : ' + mod_class_name + '\n'
except AttributeError as e:
logger.warning('Widget "{0}":\n{1}'.format(class_name, e))
self.embed_fixp_img(self.no_fx_filter_img)
continue
except KeyError as e:
logger.warning(
"No fixpoint filter for filter type {0} available.".
format(e))
self.embed_fixp_img(self.no_fx_filter_img)
continue
# restore last fxp widget if possible
idx = self.cmb_wdg_fixp.findText(last_fx_wdg)
# set to idx 0 if not found (returned -1)
self.cmb_wdg_fixp.setCurrentIndex(max(idx, 0))
else: # no fixpoint widget
self.embed_fixp_img(self.no_fx_filter_img)
return inst_wdg_str
#------------------------------------------------------------------------------
def eventFilter(self, source, event):
"""
Filter all events generated by monitored QLabel, only resize events are
processed here, generating a `sig_resize` signal. All other events
are passed on to the next hierarchy level.
"""
if event.type() == QEvent.Resize:
self.sig_resize.emit()
# Call base class method to continue normal event processing:
return super(Input_Fixpoint_Specs, self).eventFilter(source, event)
#------------------------------------------------------------------------------
def embed_fixp_img(self, img_file):
"""
Embed image as self.img_fixp, either in png or svg format
Parameters:
img_file: str
path and file name to image file
"""
if not os.path.isfile(img_file):
logger.warning("Image file {0} doesn't exist.".format(img_file))
img_file = self.default_fx_img
# _, file_extension = os.path.splitext(self.fx_wdg_inst.img_name)
_, file_extension = os.path.splitext(img_file)
if file_extension == '.png':
self.img_fixp = QPixmap(img_file)
#self.lbl_fixp_img.setPixmap(QPixmap(self.img_fixp)) # fixed size
# elif file_extension == '.svg':
# self.img_fixp = QtSvg.QSvgWidget(img_file)
else:
logger.error(
'Unknown file extension "{0}"!'.format(file_extension))
self.resize_img()
#------------------------------------------------------------------------------
def resize_img(self):
"""
Triggered when self (the widget) is resized, consequently the image
inside QLabel is resized to completely fill the label while keeping
the aspect ratio.
This doesn't really work at the moment.
"""
if hasattr(self.parent, "width"): # needed for module test
par_w, par_h = self.parent.width(), self.parent.height()
else:
par_w, par_h = 300, 700 # fixed size for module testself.lbl_img_fixp
lbl_w, lbl_h = self.lbl_fixp_img.width(), self.lbl_fixp_img.height()
img_w, img_h = self.img_fixp.width(), self.img_fixp.height()
if img_w > 10:
max_h = int(max(np.floor(img_h * par_w / img_w) - 15, 20))
else:
max_h = 200
logger.debug("img size: {0},{1}, frm size: {2},{3}, max_h: {4}".format(
img_w, img_h, par_w, par_h, max_h))
# The following doesn't work because the width of the parent widget can grow
# with the image size
# img_scaled = self.img_fixp.scaled(self.lbl_fixp_img.size(), Qt.KeepAspectRatio, Qt.SmoothTransformation)
img_scaled = self.img_fixp.scaledToHeight(max_h,
Qt.SmoothTransformation)
#img_scaled = self.img_fixp.scaledToHeight(max_h)
self.lbl_fixp_img.setPixmap(img_scaled)
#------------------------------------------------------------------------------
def _update_fixp_widget(self):
"""
This method is called at the initialization of the widget and when
a new fixpoint filter implementation is selected from the combo box:
- Destruct old instance of fixpoint filter widget `self.fx_wdg_inst`
- Import and instantiate new fixpoint filter widget e.g. after changing the
filter topology as
- Try to load image for filter topology
- Update the UI of the widget
- Try to instantiate HDL filter as `self.fx_wdg_inst.fixp_filter` with
dummy data
"""
def _disable_fx_wdg(self):
if hasattr(
self, "fx_wdg_inst"
) and self.fx_wdg_inst is not None: # is a fixpoint widget loaded?
try:
self.layH_fx_wdg.removeWidget(
self.fx_wdg_inst) # remove widget from layout
self.fx_wdg_inst.deleteLater(
) # delete QWidget when scope has been left
except AttributeError as e:
logger.error("Destructing UI failed!\n{0}".format(e))
self.fx_wdg_found = False
self.butSimFxPy.setVisible(False)
self.butSimHDL.setEnabled(False)
self.butExportHDL.setEnabled(False)
#self.layH_fx_wdg.setVisible(False)
self.img_fixp = self.embed_fixp_img(self.no_fx_filter_img)
self.lblTitle.setText("")
self.fx_wdg_inst = None
# destruct old fixpoint widget instance
_disable_fx_wdg(self)
# instantiate new fixpoint widget class as self.fx_wdg_inst
cmb_wdg_fx_cur = qget_cmb_box(self.cmb_wdg_fixp, data=False)
if cmb_wdg_fx_cur: # at least one valid fixpoint widget found
self.fx_wdg_found = True
# get list [module name and path, class name]
fx_mod_class_name = qget_cmb_box(self.cmb_wdg_fixp,
data=True).rsplit('.', 1)
fx_mod = importlib.import_module(
fx_mod_class_name[0]) # get module
fx_wdg_class = getattr(fx_mod, fx_mod_class_name[1]) # get class
#++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
self.fx_wdg_inst = fx_wdg_class(
self) # instantiate the fixpoint widget
#++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
self.layH_fx_wdg.addWidget(self.fx_wdg_inst,
stretch=1) # and add it to layout
self.fx_wdg_inst.setVisible(True)
# Doesn't work at the moment, combo box becomes inaccessible
# try:
# self.fx_wdg_inst = fx_wdg_class(self) # instantiate the widget
# self.layH_fx_wdg.addWidget(self.fx_wdg_inst, stretch=1) # and add it to layout
# except KeyError as e:
# logger.warning('Key Error {0} in fixpoint filter \n{1}'\
# .format(e, fx_mod_name + "." + cmb_wdg_fx_cur))
# _disable_fx_wdg(self)
# return
self.wdg_dict2ui(
) # initialize the fixpoint subwidgets from the fxqc_dict
#---- connect signals to fx_wdg_inst ----
if hasattr(self.fx_wdg_inst, "sig_rx"):
self.sig_rx.connect(self.fx_wdg_inst.sig_rx)
if hasattr(self.fx_wdg_inst, "sig_tx"):
self.fx_wdg_inst.sig_tx.connect(self.sig_rx)
#---- get name of new fixpoint filter image ----
if not (hasattr(self.fx_wdg_inst, "img_name") and
self.fx_wdg_inst.img_name): # is an image name defined?
img_file = self.default_fx_img
else:
file_path = os.path.dirname(
fx_mod.__file__
) # get path of imported fixpoint widget and
img_file = os.path.join(file_path, self.fx_wdg_inst.img_name
) # construct full image name from it
#---- instantiate and scale graphic of filter topology ----
self.embed_fixp_img(img_file)
#---- set title and description for filter
self.lblTitle.setText(self.fx_wdg_inst.title)
#--- try to reference Python fixpoint filter instance -----
# if hasattr(self.fx_wdg_inst,'fxpy_filter'):
# self.fxpy_filter_inst = self.fx_wdg_inst.fxpy_filter
# self.butSimFxPy.setEnabled(True)
# else:
# self.butSimFxPy.setVisible(False)
#--- Check whether fixpoint widget contains HDL filters -----
if hasattr(self.fx_wdg_inst, 'fixp_filter'):
self.butExportHDL.setEnabled(
hasattr(self.fx_wdg_inst, "to_verilog"))
self.butSimHDL.setEnabled(hasattr(self.fx_wdg_inst, "run_sim"))
self.update_fxqc_dict()
self.sig_tx.emit({
'sender': __name__,
'fx_sim': 'specs_changed'
})
else:
self.butSimHDL.setEnabled(False)
self.butExportHDL.setEnabled(False)
else:
_disable_fx_wdg(self)
#------------------------------------------------------------------------------
def wdg_dict2ui(self):
"""
Trigger an update of the fixpoint widget UI when view (i.e. fixpoint
coefficient format) or data have been changed outside this class. Additionally,
pass the fixpoint quantization widget to update / restore other subwidget
settings.
Set the RUN button to "changed".
"""
# fb.fil[0]['fxqc']['QCB'].update({'scale':(1 << fb.fil[0]['fxqc']['QCB']['W'])})
self.wdg_q_input.dict2ui(fb.fil[0]['fxqc']['QI'])
self.wdg_q_output.dict2ui(fb.fil[0]['fxqc']['QO'])
self.wdg_w_input.dict2ui(fb.fil[0]['fxqc']['QI'])
self.wdg_w_output.dict2ui(fb.fil[0]['fxqc']['QO'])
if self.fx_wdg_found and hasattr(self.fx_wdg_inst, "dict2ui"):
self.fx_wdg_inst.dict2ui()
# dict_sig = {'sender':__name__, 'fx_sim':'specs_changed'}
# self.sig_tx.emit(dict_sig)
qstyle_widget(self.butSimHDL, "changed")
#------------------------------------------------------------------------------
def update_fxqc_dict(self):
"""
Update the fxqc dictionary before simulation / HDL generation starts.
"""
if self.fx_wdg_found:
# get a dict with the coefficients and fixpoint settings from fixpoint widget
if hasattr(self.fx_wdg_inst, "ui2dict"):
fb.fil[0]['fxqc'].update(self.fx_wdg_inst.ui2dict())
logger.debug("update fxqc: \n{0}".format(
pprint_log(fb.fil[0]['fxqc'])))
else:
logger.error("No fixpoint widget found!")
#------------------------------------------------------------------------------
def exportHDL(self):
"""
Synthesize HDL description of filter
"""
if not hasattr(self.fx_wdg_inst, 'construct_fixp_filter'):
logger.warning(
'Fixpoint widget has no method "construct_fixp_filter", aborting.'
)
return
dlg = QFD(self) # instantiate file dialog object
file_types = "Verilog (*.v)"
dlg.setDefaultSuffix(
'v'
) # needed for overwrite confirmation when name is entered without suffix
dlg.setWindowTitle('Export Vlog')
dlg.setNameFilter(file_types)
dlg.setDirectory(dirs.save_dir)
dlg.setAcceptMode(
QFD.AcceptSave) # set mode "save file" instead "open file"
dlg.setOption(QFD.DontConfirmOverwrite, False)
if dlg.exec_() == QFD.Accepted:
hdl_file = qstr(dlg.selectedFiles()[0])
# hdl_type = extract_file_ext(qstr(dlg.selectedNameFilter()))[0]
# =============================================================================
# # static method getSaveFileName_() is simple but unflexible
# hdl_file, hdl_filter = dlg.getSaveFileName_(
# caption="Save Verilog netlist as (this also defines the module name)",
# directory=dirs.save_dir, filter=file_types)
# hdl_file = qstr(hdl_file)
# if hdl_file != "": # "operation cancelled" returns an empty string
# # return '.v' or '.vhd' depending on filetype selection:
# # hdl_type = extract_file_ext(qstr(hdl_filter))[0]
# # sanitized dir + filename + suffix. The filename suffix is replaced
# # by `v` later.
# hdl_file = os.path.normpath(hdl_file) # complete path + file name
# =============================================================================
hdl_dir_name = os.path.dirname(
hdl_file) # extract the directory path
if not os.path.isdir(
hdl_dir_name): # create directory if it doesn't exist
os.mkdir(hdl_dir_name)
dirs.save_dir = hdl_dir_name # make this directory the new default / base dir
hdl_file_name = os.path.splitext(os.path.basename(hdl_file))[0]
hdl_full_name = os.path.join(hdl_dir_name, hdl_file_name + ".v")
vlog_mod_name = re.sub(
r'\W+', '',
hdl_file_name).lower() # remove all non-alphanumeric chars
logger.info(
'Creating hdl_file "{0}"\n\twith top level module "{1}"'.
format(hdl_full_name, vlog_mod_name))
try:
self.update_fxqc_dict()
self.fx_wdg_inst.construct_fixp_filter()
code = self.fx_wdg_inst.to_verilog(name=vlog_mod_name)
#logger.info(str(code)) # print verilog code to console
with io.open(hdl_full_name, 'w', encoding="utf8") as f:
f.write(str(code))
logger.info("HDL conversion finished!")
except (IOError, TypeError) as e:
logger.warning(e)
##------------------------------------------------------------------------------
# def fx_sim_py(self):
# """
# Start fix-point simulation: Send the ``fxqc_dict``
# containing all quantization information and request a stimulus signal
# Not implemented yet
# """
# try:
# logger.info("Started python fixpoint simulation")
# self.update_fxqc_dict()
# self.fxpyfilter.setup(fb.fil[0]['fxqc']) # setup filter instance
# dict_sig = {'sender':__name__, 'fx_sim':'get_stimulus'}
# self.sig_tx.emit(dict_sig)
#
# except AttributeError as e:
# logger.warning("Fixpoint stimulus generation failed:\n{0}".format(e))
# return
#------------------------------------------------------------------------------
def fx_sim_init(self):
"""
Initialize fix-point simulation:
- Update the `fxqc_dict` containing all quantization information
- Setup a filter instance for migen simulation
- Request a stimulus signal
"""
if not hasattr(self.fx_wdg_inst, 'construct_fixp_filter'):
logger.error(
'Fixpoint widget has no method "construct_fixp_filter", aborting.'
)
self.sig_tx.emit({'sender': __name__, 'fx_sim': 'error'})
return
try:
logger.info("Fixpoint simulation started")
self.t_start = time.process_time()
self.update_fxqc_dict()
self.fx_wdg_inst.construct_fixp_filter() # setup filter instance
dict_sig = {'sender': __name__, 'fx_sim': 'get_stimulus'}
self.sig_tx.emit(dict_sig)
except ValueError as e: # exception
logger.error(
'Fixpoint stimulus generation failed during "init" for dict\n{0}'
'\nwith "{1} "'.format(pprint_log(dict_sig), e))
return
#------------------------------------------------------------------------------
def fx_sim_set_stimulus(self, dict_sig):
"""
- Get fixpoint stimulus from `dict_sig` in integer format
- Pass it to the fixpoint filter and calculate the fixpoint response
- Send the reponse to the plotting widget
"""
try:
logger.debug(
'Starting fixpoint simulation with stimulus from "{0}":\n\tfx_stimulus:{1}'
'\n\tStimuli: Shape {2} of type "{3}"'.format(
dict_sig['sender'],
pprint_log(dict_sig['fx_stimulus'], tab=" "),
np.shape(dict_sig['fx_stimulus']),
dict_sig['fx_stimulus'].dtype,
))
self.t_stim = time.process_time()
logger.info("Fixpoint simulation [{0:5.3g} ms]: Stimuli generated"\
.format((self.t_stim-self.t_start)*1000))
# Run fixpoint simulation and return the results as integer values:
self.fx_results = self.fx_wdg_inst.run_sim(
dict_sig['fx_stimulus']) # Run the simulation
self.t_resp = time.process_time()
if len(self.fx_results) == 0:
logger.warning("Fixpoint simulation returned empty results!")
else:
#logger.debug("fx_results: {0}"\
# .format(pprint_log(self.fx_results, tab= " ")))
logger.debug('Fixpoint simulation successful for dict\n{0}'
'\tStimuli: Shape {1} of type "{2}"'
'\n\tResponse: Shape {3} of type "{4}"'\
.format(pprint_log(dict_sig),
np.shape(dict_sig['fx_stimulus']),
dict_sig['fx_stimulus'].dtype,
np.shape(self.fx_results),
type(self.fx_results)
))
logger.info('Fixpoint simulation [{0:5.3g} ms]: Response calculated'\
.format((self.t_resp - self.t_stim)*1000))
#TODO: fixed point / integer to float conversion?
#TODO: color push-button to show state of simulation
#TODO: add QTimer single shot
# self.timer_id = QtCore.QTimer()
# self.timer_id.setSingleShot(True)
# # kill simulation after some idle time, also add a button for this
# self.timer_id.timeout.connect(self.kill_sim)
except ValueError as e:
logger.error("Simulator error {0}".format(e))
self.fx_results = None
qstyle_widget(self.butSimHDL, "error")
self.sig_tx.emit({'sender': __name__, 'fx_sim': 'error'})
return
except AssertionError as e:
logger.error('Fixpoint simulation failed for dict\n{0}'
'\twith msg. "{1}"\n\tStimuli: Shape {2} of type "{3}"'
'\n\tResponse: Shape {4} of type "{5}"'\
.format(pprint_log(dict_sig), e,
np.shape(dict_sig['fx_stimulus']),
dict_sig['fx_stimulus'].dtype,
np.shape(self.fx_results),
type(self.fx_results)
))
self.fx_results = None
qstyle_widget(self.butSimHDL, "error")
self.sig_tx.emit({'sender': __name__, 'fx_sim': 'error'})
return
logger.debug("Sending fixpoint results")
dict_sig = {
'sender': __name__,
'fx_sim': 'set_results',
'fx_results': self.fx_results
}
self.sig_tx.emit(dict_sig)
qstyle_widget(self.butSimHDL, "normal")
return
