/* -*- c++ -*- */ /* * Copyright 2008,2009 Free Software Foundation, Inc. * * This file is part of GNU Radio * * GNU Radio is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3, or (at your option) * any later version. * * GNU Radio is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GNU Radio; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, * Boston, MA 02110-1301, USA. */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include qtgui_sink_c_sptr qtgui_make_sink_c (int fftsize, int wintype, float fmin, float fmax, const std::string &name, bool plotfreq, bool plotwaterfall, bool plotwaterfall3d, bool plottime, bool plotconst, QWidget *parent) { return qtgui_sink_c_sptr (new qtgui_sink_c (fftsize, wintype, fmin, fmax, name, plotfreq, plotwaterfall, plotwaterfall3d, plottime, plotconst, parent)); } qtgui_sink_c::qtgui_sink_c (int fftsize, int wintype, float fmin, float fmax, const std::string &name, bool plotfreq, bool plotwaterfall, bool plotwaterfall3d, bool plottime, bool plotconst, QWidget *parent) : gr_block ("sink_c", gr_make_io_signature (1, -1, sizeof(gr_complex)), gr_make_io_signature (0, 0, 0)), d_fftsize(fftsize), d_wintype((gr_firdes::win_type)(wintype)), d_fmin(fmin), d_fmax(fmax), d_name(name), d_plotfreq(plotfreq), d_plotwaterfall(plotwaterfall), d_plotwaterfall3d(plotwaterfall3d), d_plottime(plottime), d_plotconst(plotconst), d_parent(parent) { d_main_gui = NULL; pthread_mutex_init(&d_pmutex, NULL); lock(); // Perform fftshift operation; // this is usually desired when plotting d_shift = true; d_fft = new gri_fft_complex (d_fftsize, true); d_fftdata = new gr_complex[d_fftsize]; d_index = 0; d_residbuf = new gr_complex[d_fftsize]; buildwindow(); initialize(); } qtgui_sink_c::~qtgui_sink_c() { delete d_object; delete [] d_fftdata; delete [] d_residbuf; delete d_fft; } void qtgui_sink_c::lock() { pthread_mutex_lock(&d_pmutex); } void qtgui_sink_c::unlock() { pthread_mutex_unlock(&d_pmutex); } void qtgui_sink_c::initialize() { if(qApp != NULL) { d_qApplication = qApp; } else { int argc; char **argv = NULL; d_qApplication = new QApplication(argc, argv); } uint64_t maxBufferSize = 32768; d_main_gui = new SpectrumGUIClass(maxBufferSize, d_fftsize, d_fmin, d_fmax); d_main_gui->SetDisplayTitle(d_name); d_main_gui->SetFFTSize(d_fftsize); d_main_gui->SetWindowType((int)d_wintype); d_main_gui->OpenSpectrumWindow(d_parent, d_plotfreq, d_plotwaterfall, d_plotwaterfall3d, d_plottime, d_plotconst); d_object = new qtgui_obj(d_qApplication); qApp->postEvent(d_object, new qtgui_event(&d_pmutex)); } void qtgui_sink_c::exec_() { d_qApplication->exec(); } QWidget* qtgui_sink_c::qwidget() { return d_main_gui->qwidget(); } PyObject* qtgui_sink_c::pyqwidget() { PyObject *w = PyLong_FromVoidPtr((void*)d_main_gui->qwidget()); PyObject *retarg = Py_BuildValue("N", w); return retarg; } void qtgui_sink_c::set_frequency_range(const double centerfreq, const double startfreq, const double stopfreq) { d_main_gui->SetFrequencyRange(centerfreq, startfreq, stopfreq); } void qtgui_sink_c::set_time_domain_axis(double min, double max) { d_main_gui->SetTimeDomainAxis(min, max); } void qtgui_sink_c::set_constellation_axis(double xmin, double xmax, double ymin, double ymax) { d_main_gui->SetConstellationAxis(xmin, xmax, ymin, ymax); } void qtgui_sink_c::set_frequency_axis(double min, double max) { d_main_gui->SetFrequencyAxis(min, max); } void qtgui_sink_c::fft(const gr_complex *data_in, int size, gr_complex *data_out) { if (d_window.size()) { gr_complex *dst = d_fft->get_inbuf(); int i; for (i = 0; i < size; i++) // apply window dst[i] = data_in[i] * d_window[i]; } else { memcpy (d_fft->get_inbuf(), data_in, sizeof(gr_complex)*size); } d_fft->execute (); // compute the fft for(int i=0; i < size; i++) { d_fft->get_outbuf()[i] /= size; } // copy result to our output if(d_shift) { // apply a fft shift on the data unsigned int len = (unsigned int)(ceil(size/2.0)); memcpy(&data_out[0], &d_fft->get_outbuf()[len], sizeof(gr_complex)*(size - len)); memcpy(&data_out[size - len], &d_fft->get_outbuf()[0], sizeof(gr_complex)*len); } else { memcpy(data_out, d_fft->get_outbuf(), sizeof(gr_complex)*size); } } void qtgui_sink_c::windowreset() { gr_firdes::win_type newwintype = (gr_firdes::win_type)d_main_gui->GetWindowType(); if(d_wintype != newwintype) { d_wintype = newwintype; buildwindow(); } } void qtgui_sink_c::buildwindow() { d_window.clear(); if(d_wintype != 0) { d_window = gr_firdes::window(d_wintype, d_fftsize, 6.76); } } void qtgui_sink_c::fftresize() { int newfftsize = d_main_gui->GetFFTSize(); if(newfftsize != d_fftsize) { // Resize the fftdata buffer; no need to preserve old data delete [] d_fftdata; d_fftdata = new gr_complex[newfftsize]; // Resize residbuf and replace data delete [] d_residbuf; d_residbuf = new gr_complex[newfftsize]; // Set new fft size and reset buffer index // (throws away any currently held data, but who cares?) d_fftsize = newfftsize; d_index = 0; // Reset window to reflect new size buildwindow(); // Reset FFTW plan for new size delete d_fft; d_fft = new gri_fft_complex (d_fftsize, true); } } int qtgui_sink_c::general_work (int noutput_items, gr_vector_int &ninput_items, gr_vector_const_void_star &input_items, gr_vector_void_star &output_items) { int i=0, j=0; const gr_complex *in = (const gr_complex*)input_items[0]; pthread_mutex_lock(&d_pmutex); // Update the FFT size from the application fftresize(); windowreset(); const timespec currentTime = get_highres_clock(); const timespec lastUpdateGUITime = d_main_gui->GetLastGUIUpdateTime(); if(diff_timespec(currentTime, lastUpdateGUITime) > 0.25) { if(d_index) { int filler = std::min(d_fftsize - d_index, noutput_items); memcpy(&d_residbuf[d_index], &in[0], sizeof(gr_complex)*filler); d_index += filler; i = filler; j = filler; } if(d_index == d_fftsize) { d_index = 0; fft(d_residbuf, d_fftsize, d_fftdata); d_main_gui->UpdateWindow(true, d_fftdata, d_fftsize, NULL, 0, (float*)d_residbuf, d_fftsize, 1.0/4.0, convert_to_timespec(0.0), true); } for(; i < noutput_items; i+=d_fftsize) { if(noutput_items - i > d_fftsize) { j += d_fftsize; fft(&in[i], d_fftsize, d_fftdata); d_main_gui->UpdateWindow(true, d_fftdata, d_fftsize, NULL, 0, (float*)&in[i], d_fftsize, 1.0/4.0, convert_to_timespec(0.0), true); } } if(noutput_items > j) { d_index = noutput_items - j; memcpy(d_residbuf, &in[j], sizeof(gr_complex)*d_index); } } pthread_mutex_unlock(&d_pmutex); consume_each(noutput_items); return noutput_items; }