#!/usr/bin/env python from gnuradio import gr, gru, modulation_utils from gnuradio import eng_notation from gnuradio.eng_option import eng_option from optparse import OptionParser import random, time, struct, sys, os, math from threading import Thread # from current dir from transmit_path import transmit_path from receive_path import receive_path try: from gnuradio.qtgui import qtgui from PyQt4 import QtGui, QtCore import sip except ImportError: print "Please install gr-qtgui." sys.exit(1) try: from qt_digital_window2 import Ui_DigitalWindow except ImportError: print "Error: could not find qt_digital_window2.py:" print "\t\"pyuic4 qt_digital_window2.ui -o qt_digital_window2.py\"" sys.exit(1) #print os.getpid() #raw_input() # //////////////////////////////////////////////////////////////////// # Define the QT Interface and Control Dialog # //////////////////////////////////////////////////////////////////// class dialog_box(QtGui.QMainWindow): def __init__(self, snkTx, snkRx, fg, parent=None): QtGui.QWidget.__init__(self, parent) self.gui = Ui_DigitalWindow() self.gui.setupUi(self) self.fg = fg self.set_sample_rate(self.fg.sample_rate()) self.set_snr(self.fg.snr()) self.set_frequency(self.fg.frequency_offset()) self.set_time_offset(self.fg.timing_offset()) self.set_alpha_time(self.fg.rx_timing_gain_alpha()) self.set_beta_time(self.fg.rx_timing_gain_beta()) self.set_alpha_freq(self.fg.rx_freq_gain_alpha()) # Add the qtsnk widgets to the hlayout box self.gui.sinkLayout.addWidget(snkTx) self.gui.sinkLayout.addWidget(snkRx) # Connect up some signals self.connect(self.gui.pauseButton, QtCore.SIGNAL("clicked()"), self.pauseFg) self.connect(self.gui.sampleRateEdit, QtCore.SIGNAL("editingFinished()"), self.sampleRateEditText) self.connect(self.gui.snrEdit, QtCore.SIGNAL("editingFinished()"), self.snrEditText) self.connect(self.gui.freqEdit, QtCore.SIGNAL("editingFinished()"), self.freqEditText) self.connect(self.gui.timeEdit, QtCore.SIGNAL("editingFinished()"), self.timeEditText) self.connect(self.gui.alphaTimeEdit, QtCore.SIGNAL("editingFinished()"), self.alphaTimeEditText) self.connect(self.gui.betaTimeEdit, QtCore.SIGNAL("editingFinished()"), self.betaTimeEditText) self.connect(self.gui.alphaFreqEdit, QtCore.SIGNAL("editingFinished()"), self.alphaFreqEditText) # Build a timer to update the packet number and PER fields self.update_delay = 250 # time between updating packet rate fields self.pkt_timer = QtCore.QTimer(self) self.connect(self.pkt_timer, QtCore.SIGNAL("timeout()"), self.updatePacketInfo) self.pkt_timer.start(self.update_delay) def pauseFg(self): if(self.gui.pauseButton.text() == "Pause"): self.fg.stop() self.fg.wait() self.gui.pauseButton.setText("Unpause") else: self.fg.start() self.gui.pauseButton.setText("Pause") # Accessor functions for Gui to manipulate system parameters def set_sample_rate(self, sr): ssr = eng_notation.num_to_str(sr) self.gui.sampleRateEdit.setText(QtCore.QString("%1").arg(ssr)) def sampleRateEditText(self): try: rate = self.gui.sampleRateEdit.text().toAscii() srate = eng_notation.str_to_num(rate) #self.fg.set_sample_rate(srate) except RuntimeError: pass # Accessor functions for Gui to manipulate channel model def set_snr(self, snr): self.gui.snrEdit.setText(QtCore.QString("%1").arg(snr)) def set_frequency(self, fo): self.gui.freqEdit.setText(QtCore.QString("%1").arg(fo)) def set_time_offset(self, to): self.gui.timeEdit.setText(QtCore.QString("%1").arg(to)) def snrEditText(self): try: snr = self.gui.snrEdit.text().toDouble()[0] self.fg.set_snr(snr) except RuntimeError: pass def freqEditText(self): try: freq = self.gui.freqEdit.text().toDouble()[0] self.fg.set_frequency_offset(freq) except RuntimeError: pass def timeEditText(self): try: to = self.gui.timeEdit.text().toDouble()[0] self.fg.set_timing_offset(to) except RuntimeError: pass # Accessor functions for Gui to manipulate receiver parameters def set_alpha_time(self, alpha): self.gui.alphaTimeEdit.setText(QtCore.QString("%1").arg(alpha)) def set_beta_time(self, beta): self.gui.betaTimeEdit.setText(QtCore.QString("%1").arg(beta)) def set_alpha_freq(self, alpha): self.gui.alphaFreqEdit.setText(QtCore.QString("%1").arg(alpha)) def alphaFreqEditText(self): try: alpha = self.gui.alphaFreqEdit.text().toDouble()[0] self.fg.set_rx_freq_gain_alpha(alpha) except RuntimeError: pass def alphaTimeEditText(self): try: alpha = self.gui.alphaTimeEdit.text().toDouble()[0] self.fg.set_rx_timing_gain_alpha(alpha) except RuntimeError: pass def betaTimeEditText(self): try: beta = self.gui.betaTimeEdit.text().toDouble()[0] self.fg.set_rx_timing_gain_beta(beta) except RuntimeError: pass # Accessor functions for packet error reporting def updatePacketInfo(self): # Pull these globals in from the main thread global n_rcvd, n_right, pktno if(pktno > 0): per = float(n_rcvd - n_right)/float(pktno) else: per = 0 self.gui.pktsRcvdEdit.setText(QtCore.QString("%1").arg(n_rcvd)) self.gui.pktsCorrectEdit.setText(QtCore.QString("%1").arg(n_right)) self.gui.perEdit.setText(QtCore.QString("%1").arg(per)) # //////////////////////////////////////////////////////////////////// # Define the GNU Radio Top Block # //////////////////////////////////////////////////////////////////// class my_top_block(gr.top_block): def __init__(self, mod_class, demod_class, rx_callback, options): gr.top_block.__init__(self) self._sample_rate = options.sample_rate channelon = True; self.gui_on = options.gui self._frequency_offset = options.frequency_offset self._timing_offset = options.timing_offset self._tx_amplitude = options.tx_amplitude self._snr_dB = options.snr self._noise_voltage = self.get_noise_voltage(self._snr_dB) self.txpath = transmit_path(mod_class, options) self.throttle = gr.throttle(gr.sizeof_gr_complex, self.sample_rate()) self.rxpath = receive_path(demod_class, rx_callback, options) # FIXME: do better exposure to lower issues for control self._timing_gain_alpha = self.rxpath.packet_receiver._demodulator._timing_alpha self._timing_gain_beta = self.rxpath.packet_receiver._demodulator._timing_beta self._freq_gain_alpha = self.rxpath.packet_receiver._demodulator._costas_alpha if channelon: self.channel = gr.channel_model(self._noise_voltage, self.frequency_offset(), self.timing_offset()) if options.discontinuous: z = 20000*[0,] self.zeros = gr.vector_source_c(z, True) packet_size = 5*((4+8+4+1500+4) * 8) self.mux = gr.stream_mux(gr.sizeof_gr_complex, [packet_size-0, int(9e5)]) # Connect components self.connect(self.txpath, self.throttle, (self.mux,0)) self.connect(self.zeros, (self.mux,1)) self.connect(self.mux, self.channel, self.rxpath) else: self.connect(self.txpath, self.throttle, self.channel, self.rxpath) if self.gui_on: self.qapp = QtGui.QApplication(sys.argv) fftsize = 2048 self.snk_tx = qtgui.sink_c(fftsize, gr.firdes.WIN_BLACKMAN_hARRIS, 0, 1, "Tx", True, True, False, True, True) self.snk_rx = qtgui.sink_c(fftsize, gr.firdes.WIN_BLACKMAN_hARRIS, 0, 1, "Rx", True, True, False, True, True) self.snk_tx.set_frequency_axis(-80, 0) self.snk_rx.set_frequency_axis(-60, 20) # Connect to the QT sinks # FIXME: make better exposure to receiver from rxpath self.freq_recov = self.rxpath.packet_receiver._demodulator.clock_recov self.time_recov = self.rxpath.packet_receiver._demodulator.time_recov self.freq_recov.set_alpha(self._freq_gain_alpha) self.freq_recov.set_beta(0.25*self._freq_gain_alpha*self._freq_gain_alpha) self.time_recov.set_alpha(self._timing_gain_alpha) self.time_recov.set_beta(self._timing_gain_beta) self.connect(self.channel, self.snk_tx) self.connect(self.time_recov, self.snk_rx) pyTxQt = self.snk_tx.pyqwidget() pyTx = sip.wrapinstance(pyTxQt, QtGui.QWidget) pyRxQt = self.snk_rx.pyqwidget() pyRx = sip.wrapinstance(pyRxQt, QtGui.QWidget) self.main_box = dialog_box(pyTx, pyRx, self) self.main_box.show() else: # Connect components self.connect(self.txpath, self.throttle, self.rxpath) # System Parameters def sample_rate(self): return self._sample_rate def set_sample_rate(self, sr): self._sample_rate = sr #self.throttle.set_samples_per_second(self._sample_rate) # Channel Model Parameters def snr(self): return self._snr_dB def set_snr(self, snr): self._snr_dB = snr self._noise_voltage = self.get_noise_voltage(self._snr_dB) self.channel.set_noise_voltage(self._noise_voltage) def get_noise_voltage(self, SNR): snr = 10.0**(SNR/10.0) power_in_signal = abs(self._tx_amplitude)**2 noise_power = power_in_signal/snr noise_voltage = math.sqrt(noise_power) return noise_voltage def frequency_offset(self): return self._frequency_offset * self.sample_rate() def set_frequency_offset(self, fo): self._frequency_offset = fo / self.sample_rate() self.channel.set_frequency_offset(self._frequency_offset) def timing_offset(self): return self._timing_offset def set_timing_offset(self, to): self._timing_offset = to self.channel.set_timing_offset(self._timing_offset) # Receiver Parameters def rx_timing_gain_alpha(self): return self._timing_gain_alpha def rx_timing_gain_beta(self): return self._timing_gain_beta def set_rx_timing_gain_alpha(self, gain): self._timing_gain_alpha = gain self.time_recov.set_alpha(self._timing_gain_alpha) def set_rx_timing_gain_beta(self, gain): self._timing_gain_beta = gain self.time_recov.set_beta(self._timing_gain_beta) def rx_freq_gain_alpha(self): return self._freq_gain_alpha def rx_freq_gain_beta(self): return self._freq_gain_beta def set_rx_freq_gain_alpha(self, alpha): self._freq_gain_alpha = alpha self._freq_gain_beta = .25 * self._freq_gain_alpha * self._freq_gain_alpha self.freq_recov.set_alpha(self._freq_gain_alpha) self.freq_recov.set_beta(self._freq_gain_beta) # ///////////////////////////////////////////////////////////////////////////// # Thread to handle the packet sending procedure # Operates in parallel with qApp.exec_() # ///////////////////////////////////////////////////////////////////////////// class th_send(Thread): def __init__(self, send_fnc, megs, sz): Thread.__init__(self) self.send = send_fnc self.nbytes = int(1e6 * megs) self.pkt_size = int(sz) def run(self): # generate and send packets n = 0 pktno = 0 while n < self.nbytes: self.send(struct.pack('!H', pktno & 0xffff) + (self.pkt_size - 2) * chr(pktno & 0xff)) n += self.pkt_size pktno += 1 self.send(eof=True) def stop(self): self.nbytes = 0 # ///////////////////////////////////////////////////////////////////////////// # main # ///////////////////////////////////////////////////////////////////////////// def main(): global n_rcvd, n_right, pktno n_rcvd = 0 n_right = 0 pktno = 0 def rx_callback(ok, payload): global n_rcvd, n_right, pktno (pktno,) = struct.unpack('!H', payload[0:2]) n_rcvd += 1 if ok: n_right += 1 if not options.gui: print "ok = %5s pktno = %4d n_rcvd = %4d n_right = %4d" % ( ok, pktno, n_rcvd, n_right) def send_pkt(payload='', eof=False): return tb.txpath.send_pkt(payload, eof) mods = modulation_utils.type_1_mods() demods = modulation_utils.type_1_demods() parser = OptionParser(option_class=eng_option, conflict_handler="resolve") expert_grp = parser.add_option_group("Expert") channel_grp = parser.add_option_group("Channel") parser.add_option("-m", "--modulation", type="choice", choices=mods.keys(), default='dbpsk', help="Select modulation from: %s [default=%%default]" % (', '.join(mods.keys()),)) parser.add_option("-s", "--size", type="eng_float", default=1500, help="set packet size [default=%default]") parser.add_option("-M", "--megabytes", type="eng_float", default=1.0, help="set megabytes to transmit [default=%default]") parser.add_option("","--discontinuous", action="store_true", default=False, help="enable discontinous transmission (bursts of 5 packets)") parser.add_option("-G", "--gui", action="store_true", default=False, help="Turn on the GUI [default=%default]") channel_grp.add_option("", "--sample-rate", type="eng_float", default=1e5, help="set speed of channel/simulation rate to RATE [default=%default]") channel_grp.add_option("", "--snr", type="eng_float", default=30, help="set the SNR of the channel in dB [default=%default]") channel_grp.add_option("", "--frequency-offset", type="eng_float", default=0, help="set frequency offset introduced by channel [default=%default]") channel_grp.add_option("", "--timing-offset", type="eng_float", default=1.0, help="set timing offset introduced by channel [default=%default]") channel_grp.add_option("", "--seed", action="store_true", default=False, help="use a random seed for AWGN noise [default=%default]") transmit_path.add_options(parser, expert_grp) receive_path.add_options(parser, expert_grp) for mod in mods.values(): mod.add_options(expert_grp) for demod in demods.values(): demod.add_options(expert_grp) (options, args) = parser.parse_args () if len(args) != 0: parser.print_help() sys.exit(1) r = gr.enable_realtime_scheduling() if r != gr.RT_OK: print "Warning: failed to enable realtime scheduling" # Create an instance of a hierarchical block tb = my_top_block(mods[options.modulation], demods[options.modulation], rx_callback, options) tb.start() packet_sender = th_send(send_pkt, options.megabytes, options.size) packet_sender.start() if(options.gui): tb.qapp.exec_() packet_sender.stop() else: # Process until done; hack in to the join to stop on an interrupt while(packet_sender.isAlive()): try: packet_sender.join(1) except KeyboardInterrupt: packet_sender.stop() if __name__ == '__main__': try: main() except KeyboardInterrupt: pass