void NeoWindow::CheckForEvent() { FL_OBJECT *obj = fl_check_forms(); if ( obj != NULL && obj->form->fdui != NULL ) { if ( obj->form->fdui == mainWin ) HandleMainWinObject( obj ); else if ( obj->form->fdui == options_box ) HandleOptionsObject( obj ); else if ( obj->form->fdui == nnet_plot ) HandleNNetPlotObject( obj ); else if ( obj->form->fdui == chart_wind ) HandleChartWindowObject( obj ); } }
void show_otg_form() { int eNB_id; char title[255]; char *tArgv[] = { "OTG", "OTG" }; int tArgc = 2; int major_owd = 6; int minor_owd = 3; int major_thr = 5; int minor_thr = 2; fl_initialize(&tArgc,tArgv,"OTG",0,0); for (eNB_id = 0; eNB_id < NB_eNB_INST; eNB_id++) { //NB_eNB_INST form_dl= create_form_otg (); sprintf (title, "LTE eNB->UE (DL)"); fl_show_form (form_dl->otg, FL_PLACE_HOTSPOT, FL_FULLBORDER, title); fl_set_form_position(form_dl->otg, 200, 200); fl_set_xyplot_ytics(form_dl->owd,major_owd, minor_owd); if (g_otg->owd_radio_access==1) fl_set_xyplot_ybounds(form_dl->owd,0,200); else fl_set_xyplot_ybounds(form_dl->owd,0,400); fl_set_xyplot_ytics(form_dl->throughput,major_thr, minor_thr); fl_set_xyplot_ybounds(form_dl->throughput,0,1000); form_ul= create_form_otg (); sprintf (title, "LTE UE->eNB (UL)"); fl_show_form (form_ul->otg, FL_PLACE_HOTSPOT, FL_FULLBORDER, title); fl_set_form_position(form_ul->otg, 850, 200); fl_set_xyplot_ytics(form_ul->owd,major_owd, minor_owd); if (g_otg->owd_radio_access==1) fl_set_xyplot_ybounds(form_ul->owd,0,200); else fl_set_xyplot_ybounds(form_ul->owd,0,400); //fl_set_positioner_ystep (form_ul->throughput, 100); //fl_set_xyplot_xgrid (form_ul->throughput, FL_GRID_MAJOR); fl_set_xyplot_ytics(form_ul->throughput,major_thr, minor_thr); fl_set_xyplot_ybounds(form_ul->throughput,0,1000); } //create_form_clock(); //fl_show_form(fclock, FL_PLACE_CENTER,FL_TRANSIENT,"clocks"); //fl_do_forms(); fl_check_forms(); }
int main(int argc, char *argv[]) { void lmst_update (FL_OBJECT *, long); int i; void dismiss_psr(); void spectrum_hide(); void tp_hide (); void hide_waterfall(); void hide_interferometer(); void hide_info(); void receiver_leave(); int close_sub (); int close_main (); char *p; char fntstr[128]; char d[128]; int binwidth; /* * Init xforms library */ fl_initialize(&argc, argv, "Ira", 0, 0); fl_get_app_resources (NULL, 0); time (&started_at); /* * Create various windows, including the main one */ fd_receiver_main = create_form_receiver_main(); fl_set_form_atclose(fd_receiver_main->receiver_main, close_main, 0); fd_receiver_pulsar = create_form_receiver_pulsar(); fl_set_form_atclose (fd_receiver_pulsar->receiver_pulsar, close_sub, dismiss_psr); fd_receiver_spectrum = create_form_receiver_spectrum(); fl_set_form_atclose (fd_receiver_spectrum->receiver_spectrum, close_sub, spectrum_hide); fd_receiver_continuum = create_form_receiver_continuum(); fl_set_form_atclose (fd_receiver_continuum->receiver_continuum, close_sub, tp_hide); fd_receiver_waterfall = create_form_receiver_waterfall(); fl_set_form_atclose (fd_receiver_waterfall->receiver_waterfall, close_sub, hide_waterfall); fd_receiver_info = create_form_receiver_info(); fl_set_form_atclose (fd_receiver_info->receiver_info, close_sub, hide_info); fd_receiver_lproblem = create_form_receiver_lproblem (); fd_receiver_error = create_form_receiver_error (); fd_receiver_shutdown = create_form_receiver_shutdown (); flps_init(); fl_free_pixmap_pixmap(fd_receiver_main->ira_xpm_button); fl_set_pixmap_data(fd_receiver_main->ira_xpm_button, Ira_xpm); sprintf (version_info, "Ver: %s (BETA)", VERSION); /* * Stuff lines in info window */ for (i = 0; ; i++) { if (ira_info[i] == NULL) { break; } fl_add_browser_line (fd_receiver_info->info_browser, ira_info[i]); } fl_set_browser_fontsize(fd_receiver_info->info_browser, 14); /* fill-in form initialization code */ fl_set_object_label (fd_receiver_main->startup_text, "PLEASE WAIT........."); /* show the first form */ fl_show_form(fd_receiver_main->receiver_main,FL_PLACE_CENTER,FL_FULLBORDER,"IRA Control Panel"); fl_check_forms(); /* * Now we check a raft of environment variables, and use those to initialize * various settable values */ refmult = 1.0; if ((p = getenv ("RCVR_REF_MULT")) != NULL) { refmult = atof(p); } fl_set_slider_value (fd_receiver_main->refmult_slider, refmult); seti_integ = 15; if ((p = getenv ("RCVR_SETI_INTEG")) != NULL) { seti_integ = (int)atof(p); } fl_set_slider_value (fd_receiver_main->seti_integ_slider, (float)seti_integ); strcpy (datadir, "."); if ((p = getenv ("RCVR_DATA_DIR")) != NULL) { strcpy (datadir, p); } /* * Set the input field for freq, as well as the actual frequency */ if ((p = getenv ("RCVR_INITIAL_FREQ")) != NULL) { fl_set_input (fd_receiver_main->frequency_input, p); frequency = atof(p); sky_freq = frequency; sky_locked = 1; } /* * Start out with sky_freq unavailable for input */ fl_deactivate_object (fd_receiver_main->sky_freq_input); fl_set_input (fd_receiver_main->sky_freq_input, "--------"); /* If there's a sky_freq parameter, use it, and re-activate the * sky_freq_input control */ if ((p = getenv ("RCVR_SKY_FREQ")) != NULL) { if (abs(atof(p) - frequency) > 100.0) { sky_locked = 0; fl_set_input (fd_receiver_main->sky_freq_input, p); sky_freq = atof(p); fl_activate_object (fd_receiver_main->sky_freq_input); fl_set_button (fd_receiver_main->sky_lock_button, 0); } else { sky_freq = atof(p); fl_set_button (fd_receiver_main->sky_lock_button, 1); sky_locked = 1; } } PUSHVAR("ifreq", frequency); PUSHVAR("skyfreq", sky_freq); /* * * And again for RF gain */ if ((p = getenv ("RCVR_RF_GAIN")) != NULL) { rf_gain = atoi(p); } fl_set_slider_value (fd_receiver_main->rf_gain_slider, rf_gain); PUSHVAR("igain", rf_gain); /* * Gain correction values for A and B sides */ if ((p = getenv ("RCVR_COR_A")) != NULL) { gc_a = atof(p); } sprintf (d, "%f", gc_a); fl_set_input (fd_receiver_main->gc_a, d); if ((p = getenv ("RCVR_COR_B")) != NULL) { gc_b = atof(p); } sprintf (d, "%f", gc_b); fl_set_input (fd_receiver_main->gc_b, d); /* * Set bounds/values for DC gain */ if ((p = getenv ("RCVR_DC_GAIN")) != NULL) { dc_gain = atof(p); } fl_set_slider_value (fd_receiver_main->dc_gain_control, dc_gain); /* * And again for DC offset */ if ((p = getenv ("RCVR_DC_OFFSET")) != NULL) { dc_offset = atof(p); } fl_set_slider_value (fd_receiver_main->dc_offset_control, dc_offset); /* * Receiver DC Gain multiplier */ if ((p = getenv ("RCVR_DC_MULT")) != NULL) { int which; dc_mult = (double)atoi(p); which = 1; /* * It's a choice widget, so we need to set 'which' appropriately */ switch ((int)dc_mult) { case 1: which = 1; break; case 5: which = 2; break; case 10: which = 3; break; case 15: which = 4; break; case 20: which = 5; break; case 25: which = 6; break; case 30: which=7; break; case 35: which = 8; break; case 40: which = 9; break; } fl_set_choice (fd_receiver_main->mult_choice, which); } /* * Total power integration value */ tp_integration = 5; if ((p = getenv ("RCVR_TP_INTEG")) != NULL) { tp_integration = atoi(p); } fl_set_slider_value (fd_receiver_main->continuum_int, (double)atof(getenv("RCVR_TP_INTEG")) ); /* * Spectral integration */ spec_integration = 15; if ((p = getenv ("RCVR_SPEC_INTEG")) != NULL) { spec_integration = atoi(p); } fl_set_slider_value (fd_receiver_main->spec_int_slider, (double)atof(getenv("RCVR_SPEC_INTEG")) ); /* * Sigma_K for SETI analysis */ sigma_k = 2.5; if ((p = getenv ("RCVR_SIGMA_K")) != NULL) { sigma_k = atof(p); } fl_set_slider_value (fd_receiver_main->sigma_k_slider, sigma_k); /* * Check desired receiver mode */ if (getenv("RCVR_MODE") != NULL) { strcpy (rcvr_mode, getenv("RCVR_MODE")); } else { strcpy (rcvr_mode, "unknown"); } /* * Interferometer? Create the interferometer window */ if (strcmp (rcvr_mode, "interferometer") == 0) { fd_receiver_interferometer = create_form_receiver_interferometer(); fl_set_form_atclose (fd_receiver_interferometer->receiver_interferometer, close_sub, hide_interferometer); } /* * Otherwise, delete the "show interferograms" control */ else { fl_delete_object (fd_receiver_main->interferometer_button); } /* * Various values */ declination = -28.3; if ((p = getenv ("RCVR_DECLINATION")) != NULL) { declination = atof(p); } fl_set_input (fd_receiver_main->declination_input, getenv("RCVR_DECLINATION")); longitude = 0.0; if ((p = getenv ("RCVR_LONGITUDE")) != NULL) { longitude = atof(p); } seti_size = 500000; if ((p = getenv ("RCVR_SETI_SIZE")) != NULL) { seti_size = atoi (p); } bandwidth = 5000000; if ((p = getenv ("RCVR_BANDWIDTH")) != NULL) { bandwidth = atoi (p); } psr_rate = 10000; if ((p = getenv ("RCVR_PSR_RATE")) != NULL) { psr_rate = atoi (getenv ("RCVR_PSR_RATE")); } for (i = 0; i < NNOTCHES; i++) { notches[i] = -1.0; } if ((p = getenv ("RCVR_NOTCHES")) != NULL) { char *tp; char pcopy[128]; FILE *fp; strcpy (pcopy, p); tp = strtok (pcopy, ","); notches[0] = atof(tp); for (i = 1; i < NNOTCHES; i++) { tp = strtok (NULL, ","); if (tp == NULL) { break; } notches[i] = atof(tp); } } if ((p = getenv ("RCVR_NOTCH_SIZE")) != NULL) { notch_length = atoi(p); fl_set_slider_value (fd_receiver_spectrum->notch_slider, (double)notch_length); } if ((p = getenv ("RCVR_DM")) != NULL) { pulsar_dm = atof(p); fl_set_slider_value (fd_receiver_main->dm_input, (double)pulsar_dm); } PUSHVAR("idm", pulsar_dm); if ((p = getenv ("PULSAR_RATE")) != NULL) { pulsar_rate = atof(p); fl_set_input (fd_receiver_main->pulsar_rate_input, p); } if ((p = getenv ("PULSAR_FOLDING")) != NULL) { pulsar_folding = atoi(p); fl_set_choice (fd_receiver_main->pulsar_choice, pulsar_folding/5); } /* * Set spec_fft_size based on width of spectral plot display */ { FL_Coord x, y, w, h; fl_get_object_bbox (fd_receiver_spectrum->spectral_plot, &x, &y, &w, &h); spec_fft_size = w-130; } tp_maxval = 100000; tp_span = 20000; /* * Establish parameters for TP plot */ if ((p = getenv("RCVR_TP_MAXVAL")) != NULL) { tp_maxval = (double)atoi(p); } if ((p = getenv ("RCVR_TP_SPAN")) != NULL) { tp_span = (double)atoi(p); } tp_minval = tp_maxval - tp_span; fl_set_slider_value (fd_receiver_continuum->tp_max_slider, (double)tp_maxval); fl_set_slider_value (fd_receiver_continuum->tp_span_slider, (double)tp_span); fl_set_xyplot_ybounds(fd_receiver_continuum->tp_chart, (double)tp_minval, (double)tp_maxval); fl_set_xyplot_ytics(fd_receiver_continuum->tp_chart, 10, 1); fl_set_xyplot_xgrid (fd_receiver_continuum->tp_chart, FL_GRID_MINOR); fl_set_xyplot_ygrid (fd_receiver_continuum->tp_chart, FL_GRID_MINOR); fl_set_object_posthandler(fd_receiver_continuum->tp_chart, continuum_plot_post); /* * Set a post handler for inteferometer display */ if (strcmp (rcvr_mode, "interferometer") == 0) { fl_set_object_posthandler(fd_receiver_interferometer->interferometer_chart, continuum_plot_post); if ((p = getenv ("RCVR_INT_GAIN")) != NULL) { interferometer_gain = atof(p); } if ((p = getenv ("RCVR_INT_SPAN")) != NULL) { interferometer_span = atof(p); } if ((p = getenv ("RCVR_PHCORR")) != NULL) { interferometer_phase = atof(p); } if ((p = getenv ("RCVR_DELAY")) != NULL) { interferometer_delay = atof(p); } fl_set_xyplot_ytics (fd_receiver_interferometer->interferometer_chart, 10, 1); fl_set_xyplot_xgrid (fd_receiver_interferometer->interferometer_chart, FL_GRID_MINOR); fl_set_xyplot_ygrid (fd_receiver_interferometer->interferometer_chart, FL_GRID_MINOR); fl_set_slider_value (fd_receiver_interferometer->int_gain_slider, interferometer_gain); fl_set_slider_value (fd_receiver_interferometer->int_span_slider, interferometer_span); fl_set_slider_value (fd_receiver_interferometer->phase_adjust, interferometer_phase); fl_set_slider_value (fd_receiver_interferometer->delay_adjust, interferometer_delay); fl_set_xyplot_ybounds (fd_receiver_interferometer->interferometer_chart, -1*interferometer_span, interferometer_span); } fl_add_timeout (1000.0, (FL_TIMEOUT_CALLBACK)lmst_update, 0); /* * Setup parameters for spectral plot */ if ((p = getenv ("RCVR_SPEC_MAX")) != NULL) { current_smax = atoi(p); } if ((p = getenv ("RCVR_SPEC_SPAN")) != NULL) { current_span = atoi(p); } if ((p = getenv ("RCVR_SPEC_FLAT")) != NULL) { spec_flat_on = atoi(p); fl_set_button (fd_receiver_spectrum->flaten_button, spec_flat_on); } if ((p = getenv ("RCVR_SPEC_METHOD")) != NULL) { spec_method = atoi (p); } fl_set_xyplot_xgrid(fd_receiver_spectrum->spectral_plot, FL_GRID_MINOR); fl_set_xyplot_ygrid(fd_receiver_spectrum->spectral_plot, FL_GRID_MINOR); fl_set_xyplot_ybounds(fd_receiver_spectrum->spectral_plot, (double)(current_smax-current_span), (double) current_smax); fl_set_xyplot_ytics(fd_receiver_spectrum->spectral_plot, 10, 1); fl_set_xyplot_xtics(fd_receiver_spectrum->spectral_plot, 10, 1); fl_set_object_posthandler(fd_receiver_spectrum->spectral_plot, spectral_plot_post); fl_set_choice (fd_receiver_spectrum->spec_method_choice, spec_method); fl_set_choice_fontsize (fd_receiver_spectrum->spec_method_choice, 14); fl_set_slider_value (fd_receiver_spectrum->spec_max_slider, (double)current_smax); fl_set_slider_value (fd_receiver_spectrum->spec_span_slider, (double)current_span); /* * Set post handler for pulsar display */ fl_set_object_posthandler(fd_receiver_pulsar->pulsar_plot, pulsar_plot_post); /* * Set parameters for waterfall (SETI) display */ { FL_Coord x, y; FL_Coord w, h; fl_get_object_bbox(fd_receiver_waterfall->waterfall_display, &x, &y, &w, &h); fl_set_slider_bounds (fd_receiver_waterfall->wfall_seg_slider, 1.0, (float)seti_size/w); fl_set_object_dblbuffer(fd_receiver_waterfall->waterfall_display, 1); if ((p = getenv ("RCVR_WFALL_SEGMENT")) != NULL) { waterfall_segment = atoi(p); fl_set_slider_value (fd_receiver_waterfall->wfall_seg_slider, (double)waterfall_segment); } if ((p = getenv ("RCVR_WFALL_FINE")) != NULL) { waterfall_fine = atoi(p); fl_set_slider_value (fd_receiver_waterfall->fine_segment, waterfall_fine); } if ((p = getenv ("RCVR_WFALL_BRIGHTNESS")) != NULL) { double w; w = atof(p); if (fabsf(w-1.0) < 0.1) { fl_set_choice (fd_receiver_waterfall->wfall_brightness, 1); w = 1.0; } if (fabsf(w-0.75) < 0.1) { fl_set_choice (fd_receiver_waterfall->wfall_brightness, 2); w = 0.75; } if (fabsf(w-0.66) < 0.1) { fl_set_choice (fd_receiver_waterfall->wfall_brightness, 3); w = 0.66; } if (fabsf(w-0.50) < 0.1) { fl_set_choice (fd_receiver_waterfall->wfall_brightness, 4); w = 0.50; } waterfall_brightness = (float)w; } } if ((p = getenv ("RCVR_TRANS_THRESH")) != NULL) { transient_threshold = atof(p); fl_set_slider_value (fd_receiver_main->trans_thr_slider, transient_threshold); } if ((p = getenv ("RCVR_TRANS_DUR")) != NULL) { transient_duration = atof(p); fl_set_slider_value (fd_receiver_main->trans_dur_slider, transient_duration); } /* * Open various FIFOs--that's where we get our data from */ if ((seti_fd = open ("ra_seti_fifo", O_RDONLY|O_NONBLOCK)) > 0) { fcntl (seti_fd, F_SETFL, 0); fl_add_io_callback (seti_fd, FL_READ, (FL_IO_CALLBACK)handle_seti_io, fd_receiver_main); } if ((pulsar_fd = open ("ra_psr_fifo", O_RDONLY|O_NONBLOCK)) > 0) { fcntl (pulsar_fd, F_SETFL, 0); fl_add_io_callback (pulsar_fd, FL_READ, (FL_IO_CALLBACK)handle_pulsar_io, fd_receiver_main); } if ((dicke_fd = open ("ra_switching_fifo", O_RDONLY|O_NONBLOCK)) > 0) { fcntl (dicke_fd, F_SETFL, 0); fl_set_object_label (fd_receiver_main->dicke_mode, "DICKE: ON"); fl_add_io_callback (dicke_fd, FL_READ, (FL_IO_CALLBACK)handle_dicke_io, fd_receiver_main); } if (strcmp (rcvr_mode, "interferometer") == 0) { if ((inter_fd = open ("ra_inter_fifo", O_RDONLY|O_NONBLOCK)) > 0) { fcntl (inter_fd, F_SETFL, 0); fl_add_io_callback (inter_fd, FL_READ, (FL_IO_CALLBACK)handle_inter_io, fd_receiver_main); } } if (strcmp (rcvr_mode, "split") == 0) { if ((validation_fd = open ("ra_validation_fifo", O_RDONLY|O_NONBLOCK)) > 0) { fcntl (validation_fd, F_SETFL, 0); split_mode = 1; fl_add_io_callback (validation_fd, FL_READ, (FL_IO_CALLBACK)handle_validation_io, fd_receiver_main); } } fl_set_oneliner_font (FL_FIXEDBOLDITALIC_STYLE, FL_MEDIUM_FONT); fl_set_oneliner_color (FL_GREEN, FL_BLACK); while(fl_do_forms()) ; return 0; }
int main(int argc, char **argv) { // initialize the world with particle2 file? if (argc>1) { char *file = argv[1]; if (!strcmp(file, ".")) particle2_read_stream(stdin, "stdin"); else { FILE *fp; fp = fopen(file, "r"); if (fp==NULL) { fprintf(stderr, "Can't open particle file %s\n", file); exit(1); } particle2_read_stream(fp, file); fclose(fp); } } /* initialize Xforms */ fl_initialize(&argc, argv, "n-body", 0, 0); ui = create_form_nbody(); // draw the UI window fl_show_form(ui->nbody, /* form */ FL_PLACE_SIZE, /* pos & size flags */ FL_FULLBORDER, /* border flags */ argv[0] /* window name */ ); // set up so we can draw in the big window of "ui" using OpenGL // set bits-per-pixel and other attributes of window // attributes for RGBA, without z-buffer, single-buffered // int single_attrs[] = // {GLX_RGBA, GLX_DEPTH_SIZE, 0, GLX_RED_SIZE, 4, None}; // attributes for RGBA, without z-buffer, double-buffered int double_attrs[] = {GLX_RGBA, GLX_DEPTH_SIZE, 0, GLX_RED_SIZE, 4, GLX_DOUBLEBUFFER, None}; glxf_bind_pane(&pane, ui->pane, // window double_attrs, // requested attributes for window handle_event // event_handler for window ); // set viewport for OpenGL glMatrixMode(GL_PROJECTION); gluOrtho2D(0, 1, 0, 1); glMatrixMode(GL_MODELVIEW); // leave matrix mode at MODELVIEW so that later transformations // (glScale, glTranslate) go into that matrix // save info about current transformations view.update(); // disable z-buffer and lighting glDisable(GL_DEPTH_TEST); glDisable(GL_LIGHTING); dt_proc(ui->dt_slider, 0); // initialize world.timestep world.draw(); // draw the world (clear the screen) // Xforms handles events until exit button is pushed // the following loop repeats continuously when the world is "running", // otherwise it sleeps in fl_do_forms() waiting for mouse motion or other // Xwindows events, so as to not eat up unneeded CPU time // We have callback procedures set up for the sliders, but not for // the run and exit buttons. // fl_check_forms() and fl_do_forms() return only when an event occurs // (button, slider, mouse motion...) for which no callback procedure has // been set. // Therefore, control returns here when the run or exit buttons is hit. FL_OBJECT *obj; do { if (world.running) { // if running: world.step(world.timestep); // take a time step world.draw(); // redraw obj = fl_check_forms(); // do a (non-blocking) check for events } else // if not running: obj = fl_do_forms(); // sleep until next event comes if (obj == ui->run_button) { // user just hit the run button; toggle it world.running = !world.running; } } while (obj != ui->exit_button); // keep going until exit button is hit return 0; }
void plot_graphes_dl(int src, int dst, int ctime) //eNB -->UE { int i, dst_idx=1, curve_id=1; char loss_rate[100]; char curve_label[100]; char simu_time[100]; int x_key_position=27; int y_key_position=75; if (otg_forms_info->idx_dl[src][dst]==MAX_SAMPLES-1){ fl_update_display(1); //the function flushes the X buffer so the drawing requests are on their way to the server if (otg_forms_info->is_data_plot_dl == -1) otg_forms_info->is_data_plot_dl=dst; if (otg_forms_info->is_data_plot_dl == dst) { fl_set_xyplot_data (form_dl->owd, otg_forms_info->data_ctime_dl[src][dst], otg_forms_info->data_owd_dl[src][dst], otg_forms_info->idx_dl[src][dst], "", "time", "ms"); sprintf(curve_label, "%d%s%d", src,"-->", dst); fl_set_xyplot_key(form_dl->owd, 0, curve_label); fl_set_xyplot_key_position(form_dl->owd, x_key_position,y_key_position, FL_ALIGN_BOTTOM_LEFT); fl_set_xyplot_data (form_dl->throughput, otg_forms_info->data_ctime_dl[src][dst], otg_forms_info->data_throughput_dl[src][dst], otg_forms_info->idx_dl[src][dst], "", "time", "kbit/s"); sprintf(curve_label, "%d%s%d", src,"-->", dst); fl_set_xyplot_key(form_dl->throughput, 0, curve_label); fl_set_xyplot_key_position(form_dl->throughput, x_key_position,y_key_position, FL_ALIGN_BOTTOM_LEFT); otg_kpi_nb_loss_pkts(); sprintf(loss_rate, "%s%d","NB Loss pkts DL=",otg_info->total_loss_dl); fl_set_object_label(form_dl->loss_ratio, loss_rate); sprintf(simu_time, "%s%d","Simulation Time(ms)=", ctime); fl_set_object_label(form_dl->simu_time, simu_time); } else { fl_set_xyplot_data (form_dl->owd, otg_forms_info->data_ctime_dl[src][otg_forms_info->is_data_plot_dl], otg_forms_info->data_owd_dl[src][otg_forms_info->is_data_plot_dl], otg_forms_info->idx_dl[src][otg_forms_info->is_data_plot_dl], "", "time", "ms"); sprintf(curve_label, "%d%s%d", src,"-->", otg_forms_info->is_data_plot_dl); fl_set_xyplot_key(form_dl->owd, 0, curve_label); fl_set_xyplot_key_position(form_dl->owd, x_key_position,y_key_position, FL_ALIGN_BOTTOM_LEFT); fl_set_xyplot_data (form_dl->throughput, otg_forms_info->data_ctime_dl[src][otg_forms_info->is_data_plot_dl], otg_forms_info->data_throughput_dl[src][otg_forms_info->is_data_plot_dl], otg_forms_info->idx_dl[src][otg_forms_info->is_data_plot_dl], "", "time", "kB/s"); sprintf(curve_label, "%d%s%d", src,"-->",otg_forms_info->is_data_plot_dl); fl_set_xyplot_key(form_dl->throughput, 0, curve_label); fl_set_xyplot_key_position(form_dl->throughput,x_key_position,y_key_position, FL_ALIGN_BOTTOM_LEFT); otg_kpi_nb_loss_pkts(); sprintf(loss_rate, "%s%d","NB Loss pkts DL=",otg_info->total_loss_dl); fl_set_object_label(form_dl->loss_ratio, loss_rate); sprintf(simu_time, "%s%d","Simulation Time(ms)=", ctime); fl_set_object_label(form_dl->simu_time, simu_time); } for (dst_idx=1;dst_idx<=NB_UE_INST;dst_idx++){ if (dst_idx!=otg_forms_info->is_data_plot_dl){ fl_add_xyplot_overlay(form_dl->owd,curve_id++, otg_forms_info->data_ctime_dl[src][dst_idx], otg_forms_info->data_owd_dl[src][dst_idx], otg_forms_info->idx_dl[src][dst_idx],dst_idx+6); sprintf(curve_label, "%d%s%d", src,"-->", dst_idx); fl_set_xyplot_key(form_dl->owd, curve_id-1, curve_label); fl_set_xyplot_key_position(form_dl->owd, x_key_position,y_key_position, FL_ALIGN_BOTTOM_LEFT); fl_add_xyplot_overlay(form_dl->throughput,curve_id++, otg_forms_info->data_ctime_dl[src][dst_idx], otg_forms_info->data_throughput_dl[src][dst_idx], otg_forms_info->idx_dl[src][dst_idx],dst_idx+6); sprintf(curve_label, "%d%s%d", src,"-->", dst_idx); fl_set_xyplot_key(form_dl->throughput, curve_id-1, curve_label); fl_set_xyplot_key_position(form_dl->throughput, x_key_position,y_key_position, FL_ALIGN_BOTTOM_LEFT); } } for (i=0;i<otg_forms_info->idx_dl[src][dst];i++){ otg_forms_info->data_ctime_dl[src][dst][otg_forms_info->idx_dl[src][dst]]=i; otg_forms_info->data_owd_dl[src][dst][i]= otg_forms_info->data_owd_dl[src][dst][i+1]; otg_forms_info->data_throughput_dl[src][dst][i]= otg_forms_info->data_throughput_dl[src][dst][i+1]; } otg_forms_info->idx_dl[src][dst]--; } fl_check_forms(); }
void receiver_leave (FL_OBJECT *ob, long data) { FILE *fp; int pid; rcvr_runrun = 0; if (data > -1 && (fp = fopen ("receiver.pid", "r")) != NULL) { fl_hide_form (fd_receiver_main->receiver_main); hide_info(NULL, 0); hide_interferometer (NULL, 0); hide_waterfall (NULL, 0); tp_hide (NULL, 0); spectrum_hide (NULL, 0); dismiss_psr (NULL, 0); fl_show_form (fd_receiver_shutdown->receiver_shutdown, FL_PLACE_CENTER, FL_NOBORDER, "IRA Shutdown"); fl_check_forms (); fscanf (fp, "%d", &pid); kill (pid, SIGINT); sleep (1); kill (pid, SIGHUP); sleep (1); kill (pid, SIGKILL); fclose (fp); } if (data < -1) { char string[129]; if (before) { fprintf (stderr, "Leaving from: %s\n", __FUNCTION__); receiver_leave (ob, 0); } before++; fp = fopen ("receiver_py.err", "r"); fl_set_browser_fontsize(fd_receiver_error->error_browser, 14); fl_set_browser_fontstyle(fd_receiver_error->error_browser, FL_BOLD_STYLE); if (fp != NULL) { while (fgets (string, 128, fp) != NULL) { string[strlen(string)-1] = '\0'; fl_add_browser_line (fd_receiver_error->error_browser, string); } fclose (fp); if ((fp = fopen ("receiver_py.log", "r"))!= NULL) { while (fgets (string, 128, fp) != NULL) { string[strlen(string)-1] = '\0'; fl_add_browser_line (fd_receiver_error->error_browser, string); } } } else { fl_add_browser_line (fd_receiver_error->error_browser, "No Error Information Is Available"); } if (data == -10) { fl_add_browser_line (fd_receiver_error->error_browser, "I/O Timeout from Gnu Radio--no data for >30 seconds"); fprintf (stderr, "I/O timeout--exiting"); } fl_show_form (fd_receiver_error->receiver_error, FL_PLACE_CENTER, FL_FULLBORDER, "IRA Errors"); fl_check_forms (); no_more_input = 1; return; } exit (0); }