/*
If the control panel is on, reset the sliders. This is done
by asking the xyplot for it's current bounds.
Hence, if the use sets the bounds from Glish to values other
than what is set by default, the sliders will see the change.
*/
void ResetSliders()
{
if (CtrlPanelOn)
{
float max,min;
int i;
fl_get_xyplot_xbounds(CHART[0],&min,&max);
fl_set_slider_bounds(XMax_Slider,(double)min,(double)max);
fl_set_slider_bounds(XMin_Slider,(double)min,(double)max);
fl_set_slider_value(XMax_Slider,(double)max);
fl_set_slider_value(XMin_Slider,(double)min);
for (i=0;i<=GlobalNoOfOverlays;i++)
{
fl_get_xyplot_ybounds(CHART[i],&min,&max);
fl_set_slider_bounds(YMax_Slider[i],(double)max,(double)min);
fl_set_slider_bounds(YMin_Slider[i],(double)max,(double)min);
fl_set_slider_value(YMax_Slider[i],(double)max);
fl_set_slider_value(YMin_Slider[i],(double)min);
}
}
}
void anim_reactive_collision_interface(AnimProb * AnimProbPt) {
int NofCoef;
NofCoef = XYZ_ANIM.animation[0]->nof_coef;
ZANIM = AnimProbPt;
if (ARCI != NULL) {
fl_hide_form(ARCI);
fl_free_form(ARCI);
ARCI = NULL;
}
ARCI = fl_bgn_form(FL_UP_BOX, 200, 370);
ARCI_REAC_TIME = fl_add_valslider (FL_HOR_SLIDER, 10, 10, 180, 20, "Reaction Time");
fl_set_slider_bounds (ARCI_REAC_TIME, 0, 3);
fl_set_slider_value (ARCI_REAC_TIME, 1);
fl_set_slider_step (ARCI_REAC_TIME, 0.1);
ARCI_CONST_BLOCKS = fl_add_button(FL_NORMAL_BUTTON, 10, 50, 180, 20, "Constitute Blocks");
fl_set_object_callback(ARCI_CONST_BLOCKS, anim_arci_cb, 10);
ARCI_NOF_BLOCK = fl_add_text(FL_NORMAL_TEXT, 10, 80, 180, 20, "");
anim_udpate_nof_blocks();
ARCI_NOF_ATTEMPTS = fl_add_valslider (FL_HOR_SLIDER, 10, 110, 180, 20, "Number of Attempt for Solving Collisions");
fl_set_slider_bounds (ARCI_NOF_ATTEMPTS, 0, 1000);
fl_set_slider_value (ARCI_NOF_ATTEMPTS, 100);
fl_set_slider_step (ARCI_NOF_ATTEMPTS, 10);
ARCI_SOLVE_COL = fl_add_button(FL_NORMAL_BUTTON, 10, 150, 180, 20, "Solve Blocks");
fl_set_object_callback(ARCI_SOLVE_COL, anim_arci_cb, 11);
ARCI_SOLVED = fl_add_text(FL_NORMAL_TEXT, 10, 180, 180, 20, "");
anim_udpate_solved();
ARCI_SHOW_SOL = fl_add_button(FL_NORMAL_BUTTON, 10, 210, 180, 20, "Show Solution(s)");
fl_set_object_callback(ARCI_SHOW_SOL, anim_arci_cb, 12);
ARCI_OPTIM = fl_add_button(FL_NORMAL_BUTTON, 10, 240, 180, 20, "Optimize Solution(s)");
fl_set_object_callback(ARCI_OPTIM, anim_arci_cb, 13);
ARCI_OPTIMIZED = fl_add_text(FL_NORMAL_TEXT, 10, 270, 180, 20, "");
anim_udpate_optimized();
ARCI_SHOW_OPTIM = fl_add_button(FL_NORMAL_BUTTON, 10, 300, 180, 20, "Show Optimized Solution(s)");
fl_set_object_callback(ARCI_SHOW_OPTIM, anim_arci_cb, 14);
ARCI_CLOSE = fl_add_button(FL_NORMAL_BUTTON, 10, 330, 180, 20, "Close");
fl_set_object_callback(ARCI_CLOSE, anim_arci_cb, 15);
fl_end_form();
fl_show_form (ARCI, FL_PLACE_SIZE, FL_FULLBORDER, "Reactive collisions");
}
void FreezY_cb(FL_OBJECT *ob, long data)
{
if (CtrlPanelOn)
{
double max,min;
max = fl_get_slider_value(YMax_Slider);
min = fl_get_slider_value(YMin_Slider);
fl_set_slider_bounds(YMax_Slider,max,min);
fl_set_slider_bounds(YMin_Slider,max,min);
}
}
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;
}
FD_options *create_form_options(void)
{
FL_OBJECT *obj;
FD_options *fdui = (FD_options *) fl_calloc(1, sizeof(*fdui));
fdui->options = fl_bgn_form(FL_NO_BOX, 470, 530);
obj = fl_add_box(FL_UP_BOX,0,0,470,530,"Options");
fl_set_object_lsize(obj,FL_NORMAL_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP|FL_ALIGN_INSIDE);
fl_set_object_lstyle(obj,FL_BOLD_STYLE);
obj = fl_add_frame(FL_EMBOSSED_FRAME,20,370,210,130,"");
obj = fl_add_frame(FL_EMBOSSED_FRAME,240,370,220,110,"");
obj = fl_add_frame(FL_EMBOSSED_FRAME,20,190,440,170,"");
fdui->prob_mutation = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,35,250,200,20,"Probabiliy of Mutation:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 3);
fl_set_slider_value(obj, 0.008);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 0.001);
fl_set_slider_increment(obj, 0.001, 0.001);
fdui->prob_crossover = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,250,250,200,20,"Probabiliy of Crossover:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 3);
fl_set_slider_value(obj, 0.002);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 0.001);
fl_set_slider_increment(obj, 0.001, 0.001);
fdui->max_pop = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,250,210,200,20,"Maximum Population:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 10000);
fl_set_slider_value(obj, 2000);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 1);
fl_set_slider_increment(obj, 10, 10);
fdui->maintain_min_pop = obj = fl_add_checkbutton(FL_PUSH_BUTTON,260,380,20,20,"Maintain a Minimum Population?");
fdui->age_factor = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,35,290,200,20,"Age Factor:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 15);
fl_set_slider_value(obj, 9);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 1);
fl_set_slider_increment(obj, 1, 1);
fdui->carcass_decay_rate = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,250,290,200,20,"Carcass Decay Rate:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 100000);
fl_set_slider_value(obj, 10000);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 100);
fl_set_slider_increment(obj, 100, 100);
fdui->save_sim = obj = fl_add_checkbutton(FL_PUSH_BUTTON,45,380,20,20,"Save Simulation Every N Steps?");
fdui->save_every = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,40,420,170,20,"Save Every N Steps:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 100000);
fl_set_slider_value(obj, 50000);
fl_set_slider_size(obj, 0.12);
fl_set_slider_step(obj, 100);
fl_set_slider_increment(obj, 100, 100);
fdui->file_name = obj = fl_add_input(FL_NORMAL_INPUT,40,465,170,20,"Default File Name:");
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fdui->ok = obj = fl_add_button(FL_RETURN_BUTTON,360,490,80,30,"OK");
fdui->initial_params_frame = obj = fl_add_frame(FL_ENGRAVED_FRAME,20,20,440,160,"Initial Parameters");
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_object_lstyle(obj,FL_BOLD_STYLE);
fdui->scale = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,35,210,200,20,"Display Scale Factor:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 1, 32);
fl_set_slider_value(obj, 5);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 1);
fl_set_slider_increment(obj, 1, 1);
fdui->min_pop = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,265,420,170,20,"Minimum Population:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 100);
fl_set_slider_value(obj, 5);
fl_set_slider_size(obj, 0.12);
fl_set_slider_step(obj, 1);
fl_set_slider_increment(obj, 1, 1);
fdui->use_survivor = obj = fl_add_checkbutton(FL_PUSH_BUTTON,280,450,20,20,"Use Survivor for Minimum?");
fdui->initial_parameters_group = fl_bgn_group();
fdui->terrain_size = obj = fl_add_choice(FL_NORMAL_CHOICE2,340,135,100,30,"Terrain Size (cells):");
fl_set_choice_entries(obj, fdchoice_terrain_size_0);
fl_set_choice(obj,4);
fdui->initial_pop = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,35,60,200,20,"Initial Population:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 2000);
fl_set_slider_value(obj, 200);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 1);
fl_set_slider_increment(obj, 10, 10);
fdui->initial_plant = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,35,100,200,20,"Number of Initial Plant Locations:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 10000);
fl_set_slider_value(obj, 1000);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 100);
fl_set_slider_increment(obj, 100, 100);
fdui->initial_flesh = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,250,100,200,20,"Number of Initial Flesh Locations:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 10000);
fl_set_slider_value(obj, 1000);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 100);
fl_set_slider_increment(obj, 100, 100);
fdui->give_head_start = obj = fl_add_checkbutton(FL_PUSH_BUTTON,290,55,20,20,"Give A Head Start?");
fl_set_button(obj, 1);
fdui->allow_asex = obj = fl_add_checkbutton(FL_PUSH_BUTTON,70,150,20,20,"Allow Asexual Reproduction?");
fl_set_button(obj, 1);
fdui->allow_sex = obj = fl_add_checkbutton(FL_PUSH_BUTTON,70,130,20,20,"Allow Sexual Reproduction?");
fl_set_button(obj, 1);
fl_end_group();
fdui->waste_decay_rate = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,35,330,200,20,"Waste Decay Rate:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 10000);
fl_set_slider_value(obj, 20);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 5);
fl_set_slider_increment(obj, 10, 10);
fdui->poison_decay_rate = obj = fl_add_valslider(FL_HOR_BROWSER_SLIDER,250,330,200,20,"Poison Decay Rate:");
fl_set_object_lsize(obj,FL_DEFAULT_SIZE);
fl_set_object_lalign(obj,FL_ALIGN_TOP);
fl_set_slider_precision(obj, 0);
fl_set_slider_bounds(obj, 0, 10000);
fl_set_slider_value(obj, 20);
fl_set_slider_size(obj, 0.10);
fl_set_slider_step(obj, 5);
fl_set_slider_increment(obj, 10, 10);
fl_end_form();
fdui->options->fdui = fdui;
return fdui;
}
