Rename interpretor to interpreter.

[Faustine.git] / interpreter / preprocessor / faust-0.9.47mr3 / architecture / gui / faustgtk.h

#ifndef FAUST_GTKUI_H
#define FAUST_GTKUI_H

#include "GUI.h"

/******************************************************************************
*******************************************************************************

                                GRAPHIC USER INTERFACE
                                  gtk interface

*******************************************************************************
*******************************************************************************/
#include <string>
#include <set>

#include <math.h>
#include <stdlib.h>
#include <string.h>

#include <gtk/gtk.h>
#include <gdk/gdkkeysyms.h>
#include <assert.h>

using namespace std;

#define max(x,y) (((x)>(y)) ? (x) : (y))
#define min(x,y) (((x)<(y)) ? (x) : (y))

#define stackSize 256

// Insertion modes

#define kSingleMode 0
#define kBoxMode 1
#define kTabMode 2

//------------ calculate needed precision
static int precision(double n)
{
        if (n < 0.009999) return 3;
        else if (n < 0.099999) return 2;
        else if (n < 0.999999) return 1;
        else return 0;
}

namespace gtk_knob
{

class GtkKnob
{
private:
        double start_x, start_y, max_value;
public:
        GtkRange parent;
        int last_quadrant;
        GtkKnob();
        ~GtkKnob();
        GtkWidget *gtk_knob_new_with_adjustment(GtkAdjustment *_adjustment);
        
};

#define GTK_TYPE_KNOB          (gtk_knob_get_type())
#define GTK_KNOB(obj)          (G_TYPE_CHECK_INSTANCE_CAST ((obj), GTK_TYPE_KNOB, GtkKnob))
#define GTK_IS_KNOB(obj)       (G_TYPE_CHECK_INSTANCE_TYPE ((obj), GTK_TYPE_KNOB))
#define GTK_KNOB_CLASS(klass)  (G_TYPE_CHECK_CLASS_CAST ((klass),  GTK_TYPE_KNOB, GtkKnobClass))
#define GTK_IS_KNOB_CLASS(obj) (G_TYPE_CHECK_CLASS_TYPE ((klass),  GTK_TYPE_KNOB))

GtkKnob::GtkKnob()
// GtkKnob constructor
{

}

GtkKnob::~GtkKnob()
{
        // Nothing specific to do...
}

struct GtkKnobClass {
        GtkRangeClass parent_class;
        int knob_x;
        int knob_y;
        int knob_step;
        int button_is;

};

//------forward declaration
GType gtk_knob_get_type ();

/****************************************************************
 ** calculate the knop pointer with dead zone
 */

const double scale_zero = 20 * (M_PI/180); // defines "dead zone" for knobs

static void knob_expose(GtkWidget *widget, int knob_x, int knob_y, GdkEventExpose *event, int arc_offset)
{
        /** check resize **/
        int grow;
        if(widget->allocation.width > widget->allocation.height) {
                grow = widget->allocation.height;
        } else {
                grow =  widget->allocation.width;
        }
        knob_x = grow-4;
        knob_y = grow-4;
        /** get values for the knob **/
        GtkAdjustment *adj = gtk_range_get_adjustment(GTK_RANGE(widget));
        int knobx = (widget->allocation.x+2 + (widget->allocation.width-4 - knob_x) * 0.5);
        int knoby = (widget->allocation.y+2 + (widget->allocation.height-4 - knob_y) * 0.5);
        int knobx1 = (widget->allocation.x+2 + (widget->allocation.width-4)* 0.5);
        int knoby1 = (widget->allocation.y+2 + (widget->allocation.height-4) * 0.5);
        double knobstate = (adj->value - adj->lower) / (adj->upper - adj->lower);
        double angle = scale_zero + knobstate * 2 * (M_PI - scale_zero);
        double knobstate1 = (0. - adj->lower) / (adj->upper - adj->lower);
        double pointer_off = knob_x/6;
        double radius = min(knob_x-pointer_off, knob_y-pointer_off) / 2;
        double lengh_x = (knobx+radius+pointer_off/2) - radius * sin(angle);
        double lengh_y = (knoby+radius+pointer_off/2) + radius * cos(angle);
        double radius1 = min(knob_x, knob_y) / 2 ;

        /** get widget forground color convert to cairo **/
        GtkStyle *style = gtk_widget_get_style (widget);
        double r = min(0.6,style->fg[gtk_widget_get_state(widget)].red/65535.0),
                   g = min(0.6,style->fg[gtk_widget_get_state(widget)].green/65535.0),
                   b = min(0.6,style->fg[gtk_widget_get_state(widget)].blue/65535.0);

        /** paint focus **/
        if (GTK_WIDGET_HAS_FOCUS(widget)== TRUE) {
                gtk_paint_focus(widget->style, widget->window, GTK_STATE_NORMAL, NULL, widget, NULL,
                                knobx-2, knoby-2, knob_x+4, knob_y+4);
        }
        /** create clowing knobs with cairo **/
        cairo_t *cr = gdk_cairo_create(GDK_DRAWABLE(widget->window));
        GdkRegion *region;
        region = gdk_region_rectangle (&widget->allocation);
        gdk_region_intersect (region, event->region);
        gdk_cairo_region (cr, region);
        cairo_clip (cr);
        
        cairo_arc(cr,knobx1+arc_offset, knoby1+arc_offset, knob_x/2.1, 0, 2 * M_PI );
        cairo_pattern_t*pat =
                cairo_pattern_create_radial (knobx1+arc_offset-knob_x/6,knoby1+arc_offset-knob_x/6, 1,knobx1+arc_offset,knoby1+arc_offset,knob_x/2.1 );
        if(adj->lower<0 && adj->value>0.) {
                cairo_pattern_add_color_stop_rgb (pat, 0, r+0.4, g+0.4 + knobstate-knobstate1, b+0.4);
                cairo_pattern_add_color_stop_rgb (pat, 0.7, r+0.15, g+0.15 + (knobstate-knobstate1)*0.5, b+0.15);
                cairo_pattern_add_color_stop_rgb (pat, 1, r, g, b);
        } else if(adj->lower<0 && adj->value<=0.) {
                cairo_pattern_add_color_stop_rgb (pat, 0, r+0.4 +knobstate1- knobstate, g+0.4, b+0.4);
                cairo_pattern_add_color_stop_rgb (pat, 0.7, r+0.15 +(knobstate1- knobstate)*0.5, g+0.15, b+0.15);
                cairo_pattern_add_color_stop_rgb (pat, 1, r, g, b);
        } else {
                cairo_pattern_add_color_stop_rgb (pat, 0, r+0.4, g+0.4 +knobstate, b+0.4);
                cairo_pattern_add_color_stop_rgb (pat, 0.7, r+0.15, g+0.15 + knobstate*0.5, b+0.15);
                cairo_pattern_add_color_stop_rgb (pat, 1, r, g, b);
        }
        cairo_set_source (cr, pat);
        cairo_fill_preserve (cr);
        gdk_cairo_set_source_color(cr, gtk_widget_get_style (widget)->fg);
        cairo_set_line_width(cr, 2.0);
        cairo_stroke(cr);

        /** create a rotating pointer on the kob**/
        cairo_set_source_rgb(cr,  0.1, 0.1, 0.1);
        cairo_set_line_width(cr,max(3, min(7, knob_x/15)));
        cairo_set_line_cap(cr, CAIRO_LINE_CAP_ROUND); 
        cairo_set_line_join(cr, CAIRO_LINE_JOIN_BEVEL);
        cairo_move_to(cr, knobx+radius1, knoby+radius1);
        cairo_line_to(cr,lengh_x,lengh_y);
        cairo_stroke(cr);
        cairo_set_source_rgb(cr,  0.9, 0.9, 0.9);
        cairo_set_line_width(cr,min(5, max(1,knob_x/30)));
        cairo_move_to(cr, knobx+radius1, knoby+radius1);
        cairo_line_to(cr,lengh_x,lengh_y);
        cairo_stroke(cr);
        cairo_pattern_destroy (pat);
        gdk_region_destroy (region);
        cairo_destroy(cr);
}

/****************************************************************
 ** general expose events for all "knob" controllers
 */

//----------- draw the Knob when moved
static gboolean gtk_knob_expose (GtkWidget *widget, GdkEventExpose *event)
{
        g_assert(GTK_IS_KNOB(widget));
        GtkKnobClass *klass =  GTK_KNOB_CLASS(GTK_OBJECT_GET_CLASS(widget));
        knob_expose(widget, klass->knob_x, klass->knob_y, event, 0);
        return TRUE;
}

/****************************************************************
 ** set initial size for GdkDrawable per type
 */

static void gtk_knob_size_request (GtkWidget *widget, GtkRequisition *requisition)
{
        g_assert(GTK_IS_KNOB(widget));
        GtkKnobClass *klass =  GTK_KNOB_CLASS(GTK_OBJECT_GET_CLASS(widget));
        requisition->width = klass->knob_x;
        requisition->height = klass->knob_y;
}

/****************************************************************
 ** set value from key bindings
 */

static void gtk_knob_set_value (GtkWidget *widget, int dir_down)
{
        g_assert(GTK_IS_KNOB(widget));

        GtkAdjustment *adj = gtk_range_get_adjustment(GTK_RANGE(widget));

        int oldstep = (int)(0.5f + (adj->value - adj->lower) / adj->step_increment);
        int step;
        int nsteps = (int)(0.5f + (adj->upper - adj->lower) / adj->step_increment);
        if (dir_down)
                step = oldstep - 1;
        else
                step = oldstep + 1;
        float value = adj->lower + step * double(adj->upper - adj->lower) / nsteps;
        gtk_widget_grab_focus(widget);
        gtk_range_set_value(GTK_RANGE(widget), value);
}

/****************************************************************
 ** keyboard bindings
 */

static gboolean gtk_knob_key_press (GtkWidget *widget, GdkEventKey *event)
{
        g_assert(GTK_IS_KNOB(widget));

        GtkAdjustment *adj = gtk_range_get_adjustment(GTK_RANGE(widget));
        switch (event->keyval) {
        case GDK_Home:
                gtk_range_set_value(GTK_RANGE(widget), adj->lower);
                return TRUE;
        case GDK_End:
                gtk_range_set_value(GTK_RANGE(widget), adj->upper);
                return TRUE;
        case GDK_Up:
                gtk_knob_set_value(widget, 0);
                return TRUE;
        case GDK_Right:
                gtk_knob_set_value(widget, 0);
                return TRUE;
        case GDK_Down:
                gtk_knob_set_value(widget, 1);
                return TRUE;
        case GDK_Left:
                gtk_knob_set_value(widget, 1);
                return TRUE;
        }

        return FALSE;
}

/****************************************************************
 ** alternative (radial) knob motion mode (ctrl + mouse pressed)
 */

static void knob_pointer_event(GtkWidget *widget, gdouble x, gdouble y, int knob_x, int knob_y,
                               bool drag, int state)
{
        static double last_y = 2e20;
        GtkKnob *knob = GTK_KNOB(widget);
        GtkAdjustment *adj = gtk_range_get_adjustment(GTK_RANGE(widget));
        double radius =  min(knob_x, knob_y) / 2;
        int  knobx = (widget->allocation.width - knob_x) / 2;
        int  knoby = (widget->allocation.height - knob_y) / 2;
        double posx = (knobx + radius) - x; // x axis right -> left
        double posy = (knoby + radius) - y; // y axis top -> bottom
        double value;
        if (!drag) {
                if (state & GDK_CONTROL_MASK) {
                        last_y = 2e20;
                        return;
                } else {
                        last_y = posy;
                }
        }
        if (last_y < 1e20) { // in drag started with Control Key
                const double scaling = 0.005;
                double scal = (state & GDK_SHIFT_MASK ? scaling*0.1 : scaling);
                value = (last_y - posy) * scal;
                last_y = posy;
                gtk_range_set_value(GTK_RANGE(widget), adj->value - value * (adj->upper - adj->lower));
                return;
        }

        double angle = atan2(-posx, posy) + M_PI; // clockwise, zero at 6 o'clock, 0 .. 2*M_PI
        if (drag) {
                // block "forbidden zone" and direct moves between quadrant 1 and 4
                int quadrant = 1 + int(angle/M_PI_2);
                if (knob->last_quadrant == 1 && (quadrant == 3 || quadrant == 4)) {
                        angle = scale_zero;
                } else if (knob->last_quadrant == 4 && (quadrant == 1 || quadrant == 2)) {
                        angle = 2*M_PI - scale_zero;
                } else {
                        if (angle < scale_zero) {
                                angle = scale_zero;
                        } else if (angle > 2*M_PI - scale_zero) {
                                angle = 2*M_PI - scale_zero;
                        }
                        knob->last_quadrant = quadrant;
                }
        } else {
                if (angle < scale_zero) {
                        angle = scale_zero;
                } else if (angle > 2*M_PI - scale_zero) {
                        angle = 2*M_PI - scale_zero;
                }
                knob->last_quadrant = 0;
        }
        angle = (angle - scale_zero) / (2 * (M_PI-scale_zero)); // normalize to 0..1
        gtk_range_set_value(GTK_RANGE(widget), adj->lower + angle * (adj->upper - adj->lower));
}

/****************************************************************
 ** mouse button pressed set value
 */

static gboolean gtk_knob_button_press (GtkWidget *widget, GdkEventButton *event)
{
        g_assert(GTK_IS_KNOB(widget));
        
        GtkKnobClass *klass =  GTK_KNOB_CLASS(GTK_OBJECT_GET_CLASS(widget));
        

        switch (event->button) {
        case 1:  // left button
                gtk_widget_grab_focus(widget);
                gtk_widget_grab_default (widget);
                gtk_grab_add(widget);
                klass->button_is = 1;
                knob_pointer_event(widget, event->x, event->y, klass->knob_x, klass->knob_y,
                                                   false, event->state);
                break;
        case 2: //wheel
                klass->button_is = 2;
                break;
        case 3:  // right button 
                klass->button_is = 3;
                break;
        default: // do nothing
                break;
        }
        return TRUE;
}

/****************************************************************
 ** mouse button release
 */

static gboolean gtk_knob_button_release (GtkWidget *widget, GdkEventButton *event)
{
        g_assert(GTK_IS_KNOB(widget));
        GTK_KNOB_CLASS(GTK_OBJECT_GET_CLASS(widget))->button_is = 0;
        if (GTK_WIDGET_HAS_GRAB(widget))
                gtk_grab_remove(widget);
        return FALSE;
}

/****************************************************************
 ** set the value from mouse movement
 */

static gboolean gtk_knob_pointer_motion (GtkWidget *widget, GdkEventMotion *event)
{
        g_assert(GTK_IS_KNOB(widget));
        GtkKnobClass *klass =  GTK_KNOB_CLASS(GTK_OBJECT_GET_CLASS(widget));
        
        gdk_event_request_motions (event);
        
        if (GTK_WIDGET_HAS_GRAB(widget)) {
                knob_pointer_event(widget, event->x, event->y, klass->knob_x, klass->knob_y,
                                                   true, event->state);
        }
        return FALSE;
}

/****************************************************************
 ** set value from mouseweel
 */

static gboolean gtk_knob_scroll (GtkWidget *widget, GdkEventScroll *event)
{
        usleep(5000);
        gtk_knob_set_value(widget, event->direction);
        return FALSE;
}

/****************************************************************
 ** init the GtkKnobClass
 */

static void gtk_knob_class_init (GtkKnobClass *klass)
{
        GtkWidgetClass *widget_class = GTK_WIDGET_CLASS(klass);

        /** set here the sizes and steps for the used knob **/
//--------- small knob size and steps
        
        klass->knob_x = 30;
        klass->knob_y = 30;
        klass->knob_step = 86;

//--------- event button
        klass->button_is = 0;

//--------- connect the events with funktions
        widget_class->expose_event = gtk_knob_expose;
        widget_class->size_request = gtk_knob_size_request;
        widget_class->button_press_event = gtk_knob_button_press;
        widget_class->button_release_event = gtk_knob_button_release;
        widget_class->motion_notify_event = gtk_knob_pointer_motion;
        widget_class->key_press_event = gtk_knob_key_press;
        widget_class->scroll_event = gtk_knob_scroll;
}

/****************************************************************
 ** init the Knob type/size
 */

static void gtk_knob_init (GtkKnob *knob)
{
        GtkWidget *widget = GTK_WIDGET(knob);
        GtkKnobClass *klass =  GTK_KNOB_CLASS(GTK_OBJECT_GET_CLASS(widget));

        GTK_WIDGET_SET_FLAGS (GTK_WIDGET(knob), GTK_CAN_FOCUS);
        GTK_WIDGET_SET_FLAGS (GTK_WIDGET(knob), GTK_CAN_DEFAULT);

        widget->requisition.width = klass->knob_x;
        widget->requisition.height = klass->knob_y;

}

/****************************************************************
 ** redraw when value changed
 */

static gboolean gtk_knob_value_changed(gpointer obj)
{
        GtkWidget *widget = (GtkWidget *)obj;
        gtk_widget_queue_draw(widget);
        return FALSE;
}

/****************************************************************
 ** create small knob
 */

GtkWidget *GtkKnob::gtk_knob_new_with_adjustment(GtkAdjustment *_adjustment)
{
        GtkWidget *widget = GTK_WIDGET( g_object_new (GTK_TYPE_KNOB, NULL ));
        GtkKnob *knob = GTK_KNOB(widget);
        knob->last_quadrant = 0;
        if (widget) {
                gtk_range_set_adjustment(GTK_RANGE(widget), _adjustment);
                g_signal_connect(GTK_OBJECT(widget), "value-changed",
                                 G_CALLBACK(gtk_knob_value_changed), widget);
        }
        return widget;
}

/****************************************************************
 ** get the Knob type
 */

GType gtk_knob_get_type (void)
{
        static GType kn_type = 0;
        if (!kn_type) {
                static const GTypeInfo kn_info = {
                        sizeof(GtkKnobClass), NULL,  NULL, (GClassInitFunc)gtk_knob_class_init, NULL, NULL, sizeof (GtkKnob), 0, (GInstanceInitFunc)gtk_knob_init
                };
                kn_type = g_type_register_static(GTK_TYPE_RANGE,  "GtkKnob", &kn_info, (GTypeFlags)0);
        }
        return kn_type;
}
}/* end of gtk_knob namespace */

gtk_knob::GtkKnob myGtkKnob;

/**
 * rmWhiteSpaces(): Remove the leading and trailing white spaces of a string
 * (but not those in the middle of the string)
 */
static string rmWhiteSpaces(const string& s)
{
    size_t i = s.find_first_not_of(" \t");
    size_t j = s.find_last_not_of(" \t");

    if (i != string::npos & j != string::npos) {
        return s.substr(i, 1+j-i);
    } else {
        return "";
    }
}


/**
 * Extracts metdata from a label : 'vol [unit: dB]' -> 'vol' + metadata
 */
static void extractMetadata(const string& fulllabel, string& label, map<string, string>& metadata)
{
    enum {kLabel, kEscape1, kEscape2, kEscape3, kKey, kValue};
    int state = kLabel; int deep = 0;
    string key, value;

    for (unsigned int i=0; i < fulllabel.size(); i++) {
        char c = fulllabel[i];
        switch (state) {
            case kLabel :
                assert (deep == 0);
                switch (c) {
                    case '\\' : state = kEscape1; break;
                    case '[' : state = kKey; deep++; break;
                    default : label += c;
                }
                break;

            case kEscape1 :
                label += c;
                state = kLabel;
                break;

            case kEscape2 :
                key += c;
                state = kKey;
                break;

            case kEscape3 :
                value += c;
                state = kValue;
                break;

            case kKey :
                assert (deep > 0);
                switch (c) {
                    case '\\' :  state = kEscape2;
                                break;

                    case '[' :  deep++;
                                key += c;
                                break;

                    case ':' :  if (deep == 1) {
                                    state = kValue;
                                } else {
                                    key += c;
                                }
                                break;
                    case ']' :  deep--;
                                if (deep < 1) {
                                    metadata[rmWhiteSpaces(key)] = "";
                                    state = kLabel;
                                    key="";
                                    value="";
                                } else {
                                    key += c;
                                }
                                break;
                    default :   key += c;
                }
                break;

            case kValue :
                assert (deep > 0);
                switch (c) {
                    case '\\' : state = kEscape3;
                                break;

                    case '[' :  deep++;
                                value += c;
                                break;

                    case ']' :  deep--;
                                if (deep < 1) {
                                    metadata[rmWhiteSpaces(key)]=rmWhiteSpaces(value);
                                    state = kLabel;
                                    key="";
                                    value="";
                                } else {
                                    value += c;
                                }
                                break;
                    default :   value += c;
                }
                break;

            default :
                cerr << "ERROR unrecognized state " << state << endl;
        }
    }
    label = rmWhiteSpaces(label);
}


class GTKUI : public GUI
{
 private :
    static bool                         fInitialized;
    static map<float*, float>           fGuiSize;       // map widget zone with widget size coef
    static map<float*, string>          fTooltip;       // map widget zone with tooltip strings
    static set<float*>                  fKnobSet;       // set of widget zone to be knobs
        string                                                          gGroupTooltip;
    
    bool isKnob(float* zone){return fKnobSet.count(zone) > 0;}
    
 protected :
    GtkWidget*  fWindow;
    int         fTop;
    GtkWidget*  fBox[stackSize];
    int         fMode[stackSize];
    bool        fStopped;

    GtkWidget* addWidget(const char* label, GtkWidget* w);
    virtual void pushBox(int mode, GtkWidget* w);

        
 public :
    static const gboolean expand = TRUE;
    static const gboolean fill = TRUE;
    static const gboolean homogene = FALSE;
         
    GTKUI(char * name, int* pargc, char*** pargv);

    // -- Labels and metadata

    virtual void declare (float* zone, const char* key, const char* value);
    virtual int  checkLabelOptions (GtkWidget* widget, const string& fullLabel, string& simplifiedLabel);
    virtual void checkForTooltip (float* zone, GtkWidget* widget);
    
    // -- layout groups
    
    virtual void openFrameBox(const char* label);   
    virtual void openTabBox(const char* label = "");
    virtual void openHorizontalBox(const char* label = "");
    virtual void openVerticalBox(const char* label = "");

    // -- extra widget's layouts

    virtual void openDialogBox(const char* label, float* zone);
    virtual void openEventBox(const char* label = "");
    virtual void openHandleBox(const char* label = "");
    virtual void openExpanderBox(const char* label, float* zone);
    
    virtual void closeBox();
    virtual void adjustStack(int n);

    // -- active widgets
    
    virtual void addButton(const char* label, float* zone);
    virtual void addToggleButton(const char* label, float* zone);
    virtual void addCheckButton(const char* label, float* zone);
    virtual void addVerticalSlider(const char* label, float* zone, float init, float min, float max, float step);   
    virtual void addHorizontalSlider(const char* label, float* zone, float init, float min, float max, float step); 
    virtual void addKnob(const char* label, float* zone, float init, float min, float max, float step);
    virtual void addNumEntry(const char* label, float* zone, float init, float min, float max, float step);
    
    // -- passive display widgets
    
    virtual void addNumDisplay(const char* label, float* zone, int precision);
    virtual void addTextDisplay(const char* label, float* zone, const char* names[], float min, float max);
    virtual void addHorizontalBargraph(const char* label, float* zone, float min, float max);
    virtual void addVerticalBargraph(const char* label, float* zone, float min, float max);
    
    virtual void show();
    virtual void run();
    
};



/******************************************************************************
*******************************************************************************

                                GRAPHIC USER INTERFACE (v2)
                                  gtk implementation

*******************************************************************************
*******************************************************************************/

// global static fields

bool                        GTKUI::fInitialized = false;
map<float*, float>          GTKUI::fGuiSize;
map<float*, string>         GTKUI::fTooltip;
set<float*>                 GTKUI::fKnobSet;       // set of widget zone to be knobs

/**
* Format tooltip string by replacing some white spaces by 
* return characters so that line width doesn't exceed n.
* Limitation : long words exceeding n are not cut 
*/
static string formatTooltip(int n, const string& tt)
{
        string  ss = tt;        // ss string we are going to format
        int             lws = 0;        // last white space encountered
        int     lri = 0;        // last return inserted
        for (int i=0; i<tt.size(); i++) {
                if (tt[i] == ' ') lws = i;
                if (((i-lri) >= n) && (lws > lri)) {
                        // insert return here
                        ss[lws] = '\n';
                        lri = lws;
                }
        }
        cout << ss;
        return ss;
}



static gint delete_event( GtkWidget *widget, GdkEvent *event, gpointer data )
{
    return FALSE; 
}

static void destroy_event( GtkWidget *widget, gpointer data )
{
    gtk_main_quit ();
}

         
GTKUI::GTKUI(char * name, int* pargc, char*** pargv) 
{
    if (!fInitialized) {
        gtk_init(pargc, pargv);
        fInitialized = true;
    }
    
    fWindow = gtk_window_new (GTK_WINDOW_TOPLEVEL);
    //gtk_container_set_border_width (GTK_CONTAINER (fWindow), 10);
    gtk_window_set_title (GTK_WINDOW (fWindow), name);
    gtk_signal_connect (GTK_OBJECT (fWindow), "delete_event", GTK_SIGNAL_FUNC (delete_event), NULL);
    gtk_signal_connect (GTK_OBJECT (fWindow), "destroy", GTK_SIGNAL_FUNC (destroy_event), NULL);

    fTop = 0;
    fBox[fTop] = gtk_vbox_new (homogene, 4);
    fMode[fTop] = kBoxMode;
    gtk_container_add (GTK_CONTAINER (fWindow), fBox[fTop]);
    fStopped = false;
}

// empilement des boites

void GTKUI::pushBox(int mode, GtkWidget* w)
{
    ++fTop;
    assert(fTop < stackSize);
    fMode[fTop]     = mode;
    fBox[fTop]      = w;
}


/**
 * Remove n levels from the stack S before the top level
 * adjustStack(n): S -> S' with S' = S(0),S(n+1),S(n+2),...
 */
void GTKUI::adjustStack(int n)
{
    if (n > 0) {
        assert(fTop >= n);

        fTop -= n; 
        fMode[fTop] = fMode[fTop+n];
        fBox[fTop]  = fBox[fTop+n];
    }
}

void GTKUI::closeBox()
{
    --fTop;
    assert(fTop >= 0);
}


/**
 * Analyses the widget zone metadata declarations and takes
 * appropriate actions 
 */
void GTKUI::declare(float* zone, const char* key, const char* value)
{
        if (zone == 0) {
                // special zone 0 means group metadata
                if (strcmp(key,"tooltip")==0) {
                        // only group tooltip are currently implemented
                        gGroupTooltip = formatTooltip(30, value);
                }
        } else {
                if (strcmp(key,"size")==0) {
                        fGuiSize[zone]=atof(value);
                }
                else if (strcmp(key,"tooltip")==0) {
                        fTooltip[zone] = formatTooltip(30,value) ;
                }
                else if (strcmp(key,"style")==0) {
                        if (strcmp(value,"knob") == 0) {
                                fKnobSet.insert(zone);
                        }
                }
        }
}
        
        

/**
 * Analyses a full label and activates the relevant options. returns a simplified
 * label (without options) and an amount of stack adjustement (in case additional
 * containers were pushed on the stack). 
 */

int GTKUI::checkLabelOptions(GtkWidget* widget, const string& fullLabel, string& simplifiedLabel)
{   
    map<string, string> metadata;
    extractMetadata(fullLabel, simplifiedLabel, metadata);

    if (metadata.count("tooltip")) {
        gtk_tooltips_set_tip (gtk_tooltips_new (), widget, metadata["tooltip"].c_str(), NULL);
    }
    if (metadata["option"] == "detachable") {
        openHandleBox(simplifiedLabel.c_str());
        return 1;
    }

        //---------------------
        if (gGroupTooltip != string()) {
                gtk_tooltips_set_tip (gtk_tooltips_new (), widget, gGroupTooltip.c_str(), NULL);
                gGroupTooltip = string();
        }
        
        //----------------------
        
    // no adjustement of the stack needed
    return 0;
}

/**
 * Check if a tooltip is associated to a zone and add it to the corresponding widget
 */
void GTKUI::checkForTooltip(float* zone, GtkWidget* widget)
{
    if (fTooltip.count(zone)) {
        gtk_tooltips_set_tip (gtk_tooltips_new (), widget, fTooltip[zone].c_str(), NULL);
    }
}


// les differentes boites

void GTKUI::openFrameBox(const char* label)
{
    GtkWidget * box = gtk_frame_new (label);
    //gtk_container_set_border_width (GTK_CONTAINER (box), 10);
            
    pushBox(kSingleMode, addWidget(label, box));
}


void GTKUI::openTabBox(const char* fullLabel)
{
    string  label;
    GtkWidget* widget = gtk_notebook_new();

    int     adjust = checkLabelOptions(widget, fullLabel, label);

    pushBox(kTabMode, addWidget(label.c_str(), widget));

    // adjust stack because otherwise Handlebox will remain open
    adjustStack(adjust);
}


void GTKUI::openHorizontalBox(const char* fullLabel)
{   
    string   label;
    GtkWidget* box = gtk_hbox_new (homogene, 4);
    int     adjust = checkLabelOptions(box, fullLabel, label);

    gtk_container_set_border_width (GTK_CONTAINER (box), 10);
            
    if (fMode[fTop] != kTabMode && label[0] != 0) {
        GtkWidget * frame = addWidget(label.c_str(), gtk_frame_new (label.c_str()));
        gtk_container_add (GTK_CONTAINER(frame), box);
        gtk_widget_show(box);
        pushBox(kBoxMode, box);
    } else {
        pushBox(kBoxMode, addWidget(label.c_str(), box));
    }

    // adjust stack because otherwise Handlebox will remain open
    adjustStack(adjust);
}


void GTKUI::openVerticalBox(const char* fullLabel)
{
    string  label;
    GtkWidget * box = gtk_vbox_new (homogene, 4);
    int      adjust = checkLabelOptions(box, fullLabel, label);

    gtk_container_set_border_width (GTK_CONTAINER (box), 10);
            
    if (fMode[fTop] != kTabMode && label[0] != 0) {
        GtkWidget * frame = addWidget(label.c_str(), gtk_frame_new (label.c_str()));
        gtk_container_add (GTK_CONTAINER(frame), box);
        gtk_widget_show(box);
        pushBox(kBoxMode, box);
    } else {
        pushBox(kBoxMode, addWidget(label.c_str(), box));
    }

    // adjust stack because otherwise Handlebox will remain open
    adjustStack(adjust);
}


void GTKUI::openHandleBox(const char* label)
{
    GtkWidget * box = gtk_hbox_new (homogene, 4);
    gtk_container_set_border_width (GTK_CONTAINER (box), 2);
    if (fMode[fTop] != kTabMode && label[0] != 0)
    {
        GtkWidget * frame = addWidget(label, gtk_handle_box_new ());
        gtk_container_add (GTK_CONTAINER(frame), box);
        gtk_widget_show(box);
        pushBox(kBoxMode, box);
    }
    else
    {
        pushBox(kBoxMode, addWidget(label, box));
    }
}


void GTKUI::openEventBox(const char* label)
{
    GtkWidget * box = gtk_hbox_new (homogene, 4);
    gtk_container_set_border_width (GTK_CONTAINER (box), 2);
    if (fMode[fTop] != kTabMode && label[0] != 0)
    {
        GtkWidget * frame = addWidget(label, gtk_event_box_new ());
        gtk_container_add (GTK_CONTAINER(frame), box);
        gtk_widget_show(box);
        pushBox(kBoxMode, box);
    }
    else
    {
        pushBox(kBoxMode, addWidget(label, box));
    }
}


struct uiExpanderBox : public uiItem
{
    GtkExpander* fButton;
    uiExpanderBox(GUI* ui, float* zone, GtkExpander* b) : uiItem(ui, zone), fButton(b) {}
    static void expanded (GtkWidget *widget, gpointer data)
    {
        float   v = gtk_expander_get_expanded  (GTK_EXPANDER(widget));
        if (v == 1.000000)
        {
            v = 0;
        }
        else v = 1;
        ((uiItem*)data)->modifyZone(v);
    }

    virtual void reflectZone()
    {
        float   v = *fZone;
        fCache = v;
        gtk_expander_set_expanded(GTK_EXPANDER(fButton), v);
    }
};

void GTKUI::openExpanderBox(const char* label, float* zone)
{
    *zone = 0.0;
    GtkWidget * box = gtk_hbox_new (homogene, 4);
    gtk_container_set_border_width (GTK_CONTAINER (box), 2);
    if (fMode[fTop] != kTabMode && label[0] != 0)
    {
        GtkWidget * frame = addWidget(label, gtk_expander_new (label));
        gtk_container_add (GTK_CONTAINER(frame), box);
        uiExpanderBox* c = new uiExpanderBox(this, zone, GTK_EXPANDER(frame));
        gtk_signal_connect (GTK_OBJECT (frame), "activate", GTK_SIGNAL_FUNC (uiExpanderBox::expanded), (gpointer)c);
        gtk_widget_show(box);
        pushBox(kBoxMode, box);
    }
    else
    {
        pushBox(kBoxMode, addWidget(label, box));
    }
}



GtkWidget* GTKUI::addWidget(const char* label, GtkWidget* w)
{ 
    switch (fMode[fTop]) {
        case kSingleMode    : gtk_container_add (GTK_CONTAINER(fBox[fTop]), w);                             break;
        case kBoxMode       : gtk_box_pack_start (GTK_BOX(fBox[fTop]), w, expand, fill, 0);                 break;
        case kTabMode       : gtk_notebook_append_page (GTK_NOTEBOOK(fBox[fTop]), w, gtk_label_new(label)); break;
    }
    gtk_widget_show (w);
    return w;
}

// --------------------------- Press button ---------------------------

struct uiButton : public uiItem
{
    GtkButton*  fButton;
    
    uiButton (GUI* ui, float* zone, GtkButton* b) : uiItem(ui, zone), fButton(b) {}
    
    static void pressed( GtkWidget *widget, gpointer   data )
    {
        uiItem* c = (uiItem*) data;
        c->modifyZone(1.0);
    }

    static void released( GtkWidget *widget, gpointer   data )
    {
        uiItem* c = (uiItem*) data;
        c->modifyZone(0.0);
    }

    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v; 
        if (v > 0.0) gtk_button_pressed(fButton); else gtk_button_released(fButton);
    }
};

void GTKUI::addButton(const char* label, float* zone)
{
    *zone = 0.0;
    GtkWidget*  button = gtk_button_new_with_label (label);
    addWidget(label, button);
    
    uiButton* c = new uiButton(this, zone, GTK_BUTTON(button));
    
    gtk_signal_connect (GTK_OBJECT (button), "pressed", GTK_SIGNAL_FUNC (uiButton::pressed), (gpointer) c);
    gtk_signal_connect (GTK_OBJECT (button), "released", GTK_SIGNAL_FUNC (uiButton::released), (gpointer) c);

    checkForTooltip(zone, button);
}

// ---------------------------  Toggle Buttons ---------------------------

struct uiToggleButton : public uiItem
{
    GtkToggleButton* fButton;
    
    uiToggleButton(GUI* ui, float* zone, GtkToggleButton* b) : uiItem(ui, zone), fButton(b) {}
    
    static void toggled (GtkWidget *widget, gpointer data)
    {
        float   v = (GTK_TOGGLE_BUTTON (widget)->active) ? 1.0 : 0.0; 
        ((uiItem*)data)->modifyZone(v);
    }

    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v; 
        gtk_toggle_button_set_active(fButton, v > 0.0); 
    }
};

void GTKUI::addToggleButton(const char* label, float* zone)
{
    *zone = 0.0;
    GtkWidget*  button = gtk_toggle_button_new_with_label (label);
    addWidget(label, button);
    
    uiToggleButton* c = new uiToggleButton(this, zone, GTK_TOGGLE_BUTTON(button));
    gtk_signal_connect (GTK_OBJECT (button), "toggled", GTK_SIGNAL_FUNC (uiToggleButton::toggled), (gpointer) c);

    checkForTooltip(zone, button);
}



void show_dialog(GtkWidget *widget, gpointer data)
{
    if (gtk_toggle_button_get_active (GTK_TOGGLE_BUTTON(widget)) == TRUE)
    {
        gtk_widget_show(GTK_WIDGET(data));
        gint root_x, root_y;
        gtk_window_get_position (GTK_WINDOW(data), &root_x, &root_y);
        root_y -= 120;
        gtk_window_move(GTK_WINDOW(data), root_x, root_y);
    }
    else gtk_widget_hide(GTK_WIDGET(data));
}

static gboolean deleteevent( GtkWidget *widget, gpointer   data )
{
return TRUE;
} 

void GTKUI::openDialogBox(const char* label, float* zone)
{
    // create toplevel window and set properties
    GtkWidget * dialog = gtk_window_new (GTK_WINDOW_TOPLEVEL);
    gtk_window_set_decorated(GTK_WINDOW(dialog), TRUE);
    gtk_window_set_deletable(GTK_WINDOW(dialog), FALSE);
    gtk_window_set_resizable(GTK_WINDOW(dialog), FALSE);
    gtk_window_set_gravity(GTK_WINDOW(dialog), GDK_GRAVITY_SOUTH);
    gtk_window_set_transient_for (GTK_WINDOW(dialog), GTK_WINDOW(fWindow));
    gtk_window_set_position (GTK_WINDOW(dialog), GTK_WIN_POS_MOUSE);
    gtk_window_set_keep_below (GTK_WINDOW(dialog), FALSE);
    gtk_window_set_title (GTK_WINDOW (dialog), label);
    g_signal_connect (G_OBJECT (dialog), "delete_event", G_CALLBACK (deleteevent), NULL); 
    gtk_window_set_destroy_with_parent(GTK_WINDOW(dialog), TRUE);

    GtkWidget * box = gtk_hbox_new (homogene, 4);
 
    *zone = 0.0;
    GtkWidget*  button = gtk_toggle_button_new ();
    gtk_signal_connect (GTK_OBJECT (button), "toggled", GTK_SIGNAL_FUNC (show_dialog), (gpointer) dialog);
 
    gtk_container_add (GTK_CONTAINER(fBox[fTop]), button);
    gtk_container_add (GTK_CONTAINER(dialog), box);
    gtk_widget_show (button);
    gtk_widget_show(box);
    pushBox(kBoxMode, box);
}




// ---------------------------  Check Button ---------------------------

struct uiCheckButton : public uiItem
{
    GtkToggleButton* fButton;
    
    uiCheckButton(GUI* ui, float* zone, GtkToggleButton* b) : uiItem(ui, zone), fButton(b) {}
    
    static void toggled (GtkWidget *widget, gpointer data)
    {
        float   v = (GTK_TOGGLE_BUTTON (widget)->active) ? 1.0 : 0.0; 
        ((uiItem*)data)->modifyZone(v);
    }

    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v; 
        gtk_toggle_button_set_active(fButton, v > 0.0); 
    }
};

void GTKUI::addCheckButton(const char* label, float* zone)
{
    *zone = 0.0;
    GtkWidget*  button = gtk_check_button_new_with_label (label);
    addWidget(label, button);
    
    uiCheckButton* c = new uiCheckButton(this, zone, GTK_TOGGLE_BUTTON(button));
    gtk_signal_connect (GTK_OBJECT (button), "toggled", GTK_SIGNAL_FUNC(uiCheckButton::toggled), (gpointer) c);

    checkForTooltip(zone, button);
}


// ---------------------------  Adjustmenty based widgets ---------------------------

struct uiAdjustment : public uiItem
{
    GtkAdjustment* fAdj;
    
    uiAdjustment(GUI* ui, float* zone, GtkAdjustment* adj) : uiItem(ui, zone), fAdj(adj) {}
    
    static void changed (GtkWidget *widget, gpointer data)
    {
        float   v = GTK_ADJUSTMENT (widget)->value; 
        ((uiItem*)data)->modifyZone(v);
    }

    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v; 
        gtk_adjustment_set_value(fAdj, v);  
    }
};

// --------------------------- format knob value display ---------------------------

struct uiValueDisplay : public uiItem
{
        GtkLabel* fLabel;
        int     fPrecision ;

        uiValueDisplay(GUI* ui, float* zone, GtkLabel* label, int precision)
                : uiItem(ui, zone), fLabel(label), fPrecision(precision) {}

        virtual void reflectZone()
                {
                        float v = *fZone;
                        fCache = v;
                        char s[64];
                        if (fPrecision <= 0)
                                snprintf(s, 63, "%d", int(v));

                        else if (fPrecision > 3)
                                snprintf(s, 63, "%f", v);

                        else if (fPrecision == 1)
                        {
                                const char* format[] = {"%.1f", "%.2f", "%.3f"};
                                snprintf(s, 63, format[1-1], v);
                        }
                        else if (fPrecision == 2)
                        {
                                const char* format[] = {"%.1f", "%.2f", "%.3f"};
                                snprintf(s, 63, format[2-1], v);
                        }
                        else
                        {
                                const char* format[] = {"%.1f", "%.2f", "%.3f"};
                                snprintf(s, 63, format[3-1], v);
                        }
                        gtk_label_set_text(fLabel, s);
                }
};

// ------------------------------- Knob -----------------------------------------

void GTKUI::addKnob(const char* label, float* zone, float init, float min, float max, float step)
{
        *zone = init;
    GtkObject* adj = gtk_adjustment_new(init, min, max, step, 10*step, 0);
    
    uiAdjustment* c = new uiAdjustment(this, zone, GTK_ADJUSTMENT(adj));

    gtk_signal_connect (GTK_OBJECT (adj), "value-changed", GTK_SIGNAL_FUNC (uiAdjustment::changed), (gpointer) c);
    
        GtkWidget* slider = gtk_vbox_new (FALSE, 0);
        GtkWidget* fil = gtk_vbox_new (FALSE, 0);
        GtkWidget* rei = gtk_vbox_new (FALSE, 0);
        GtkWidget* re =myGtkKnob.gtk_knob_new_with_adjustment(GTK_ADJUSTMENT(adj));
        GtkWidget* lw = gtk_label_new("");
        new uiValueDisplay(this, zone, GTK_LABEL(lw),precision(step));
        gtk_container_add (GTK_CONTAINER(rei), re);
        if(fGuiSize[zone]) {
                float size = 30 * fGuiSize[zone];
                gtk_widget_set_size_request(rei, size, size );
                gtk_box_pack_start (GTK_BOX(slider), fil, TRUE, TRUE, 0);
                gtk_box_pack_start (GTK_BOX(slider), rei, FALSE, FALSE, 0);
        } else {
                gtk_container_add (GTK_CONTAINER(slider), fil);
                gtk_container_add (GTK_CONTAINER(slider), rei);
        }
        gtk_container_add (GTK_CONTAINER(slider), lw);
        gtk_widget_show_all(slider);
        
        if (label && label[0]!=0) {
        openFrameBox(label);
        addWidget(label, slider);
        closeBox();
    } else {
        addWidget(label, slider);
    }

    checkForTooltip(zone, slider);
}

// -------------------------- Vertical Slider -----------------------------------

void GTKUI::addVerticalSlider(const char* label, float* zone, float init, float min, float max, float step)
{
        if (isKnob(zone)) { 
                addKnob(label, zone, init, min, max, step);
                return;
        } 
    *zone = init;
    GtkObject* adj = gtk_adjustment_new(init, min, max, step, 10*step, 0);
    
    uiAdjustment* c = new uiAdjustment(this, zone, GTK_ADJUSTMENT(adj));

    gtk_signal_connect (GTK_OBJECT (adj), "value-changed", GTK_SIGNAL_FUNC (uiAdjustment::changed), (gpointer) c);
    
        GtkWidget* slider = gtk_vscale_new (GTK_ADJUSTMENT(adj));
        gtk_scale_set_digits(GTK_SCALE(slider), precision(step));
        float size = 160;
        if(fGuiSize[zone]) {
                size = 160 * fGuiSize[zone];
        }
        gtk_widget_set_size_request(slider, -1, size);
        
    gtk_range_set_inverted (GTK_RANGE(slider), TRUE);
    
    if (label && label[0]!=0) {
        openFrameBox(label);
        addWidget(label, slider);
        closeBox();
    } else {
        addWidget(label, slider);
    }

    checkForTooltip(zone, slider);
}

// -------------------------- Horizontal Slider -----------------------------------

void GTKUI::addHorizontalSlider(const char* label, float* zone, float init, float min, float max, float step)
{
        if (isKnob(zone)) { 
                addKnob(label, zone, init, min, max, step);
                return;
        } 
    *zone = init;
    GtkObject* adj = gtk_adjustment_new(init, min, max, step, 10*step, 0);
    
    uiAdjustment* c = new uiAdjustment(this, zone, GTK_ADJUSTMENT(adj));

    gtk_signal_connect (GTK_OBJECT (adj), "value-changed", GTK_SIGNAL_FUNC (uiAdjustment::changed), (gpointer) c);
    
    GtkWidget* slider = gtk_hscale_new (GTK_ADJUSTMENT(adj));
        gtk_scale_set_digits(GTK_SCALE(slider), precision(step));
        float size = 160;
        if(fGuiSize[zone]) {
                size = 160 * fGuiSize[zone];
        }
        gtk_widget_set_size_request(slider, size, -1);
    
    if (label && label[0]!=0) {
        openFrameBox(label);
        addWidget(label, slider);
        closeBox();
    } else {
        addWidget(label, slider);
    }             

    checkForTooltip(zone, slider);
}


// ------------------------------ Num Entry -----------------------------------

void GTKUI::addNumEntry(const char* label, float* zone, float init, float min, float max, float step)
{
        if (isKnob(zone)) { 
                addKnob(label, zone, init, min, max, step);
                return;
        } 
    *zone = init;
    GtkObject* adj = gtk_adjustment_new(init, min, max, step, 10*step, step);
    
    uiAdjustment* c = new uiAdjustment(this, zone, GTK_ADJUSTMENT(adj));

    gtk_signal_connect (GTK_OBJECT (adj), "value-changed", GTK_SIGNAL_FUNC (uiAdjustment::changed), (gpointer) c);
    
    GtkWidget* spinner = gtk_spin_button_new (GTK_ADJUSTMENT(adj), 0.005, precision(step));

    openFrameBox(label);
    addWidget(label, spinner);
    closeBox();

    checkForTooltip(zone, spinner);
}


// ==========================   passive widgets ===============================


// ------------------------------ Progress Bar -----------------------------------

struct uiBargraph : public uiItem
{
    GtkProgressBar*     fProgressBar;
    float               fMin;
    float               fMax;
    
    uiBargraph(GUI* ui, float* zone, GtkProgressBar* pbar, float lo, float hi) 
            : uiItem(ui, zone), fProgressBar(pbar), fMin(lo), fMax(hi) {}

    float scale(float v)        { return (v-fMin)/(fMax-fMin); }
    
    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v; 
        gtk_progress_bar_set_fraction(fProgressBar, scale(v));  
    }
};

    

void GTKUI::addVerticalBargraph(const char* label, float* zone, float lo, float hi)
{
    GtkWidget* pb = gtk_progress_bar_new();
    gtk_progress_bar_set_orientation(GTK_PROGRESS_BAR(pb), GTK_PROGRESS_BOTTOM_TO_TOP);
    gtk_widget_set_size_request(pb, 8, -1);
    new uiBargraph(this, zone, GTK_PROGRESS_BAR(pb), lo, hi);
    openFrameBox(label);
    addWidget(label, pb);
    closeBox();

    checkForTooltip(zone, pb);
}
    

void GTKUI::addHorizontalBargraph(const char* label, float* zone, float lo, float hi)
{
    GtkWidget* pb = gtk_progress_bar_new();
    gtk_progress_bar_set_orientation(GTK_PROGRESS_BAR(pb), GTK_PROGRESS_LEFT_TO_RIGHT);
    gtk_widget_set_size_request(pb, -1, 8);
    new uiBargraph(this, zone, GTK_PROGRESS_BAR(pb), lo, hi);
    openFrameBox(label);
    addWidget(label, pb);
    closeBox();

    checkForTooltip(zone, pb);
}


// ------------------------------ Num Display -----------------------------------

struct uiNumDisplay : public uiItem
{
    GtkLabel* fLabel;
    int fPrecision;
    
    uiNumDisplay(GUI* ui, float* zone, GtkLabel* label, int precision) 
            : uiItem(ui, zone), fLabel(label), fPrecision(precision) {}

    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v;
        char s[64]; 
        if (fPrecision <= 0) { 
            snprintf(s, 63, "%d", int(v)); 
        } else if (fPrecision>3) {
            snprintf(s, 63, "%f", v);
        } else {
            const char* format[] = {"%.1f", "%.2f", "%.3f"};
            snprintf(s, 63, format[fPrecision-1], v);
        }
        gtk_label_set_text(fLabel, s);
    }
};
    

void GTKUI::addNumDisplay(const char* label, float* zone, int precision )
{
    GtkWidget* lw = gtk_label_new("");
    new uiNumDisplay(this, zone, GTK_LABEL(lw), precision);
    openFrameBox(label);
    addWidget(label, lw);
    closeBox();

    checkForTooltip(zone, lw);
}


// ------------------------------ Text Display -----------------------------------

struct uiTextDisplay : public uiItem
{
        GtkLabel*           fLabel;
        const char**    fNames;
        float               fMin;
        float               fMax;
        int                         fNum;
        
        
        uiTextDisplay (GUI* ui, float* zone, GtkLabel* label, const char* names[], float lo, float hi)
                        : uiItem(ui, zone), fLabel(label), fNames(names), fMin(lo), fMax(hi)
        {
                fNum = 0;
                while (fNames[fNum] != 0) fNum++;
    }

    virtual void reflectZone()  
    { 
        float   v = *fZone;
        fCache = v;
        
        int idx = int(fNum*(v-fMin)/(fMax-fMin));
        
        if      (idx < 0)       idx = 0; 
        else if (idx >= fNum)   idx = fNum-1;
                
        gtk_label_set_text(fLabel, fNames[idx]); 
    }
};
    

void GTKUI::addTextDisplay(const char* label, float* zone, const char* names[], float lo, float hi )
{
    GtkWidget* lw = gtk_label_new("");
    new uiTextDisplay (this, zone, GTK_LABEL(lw), names, lo, hi);
    openFrameBox(label);
    addWidget(label, lw);
    closeBox();

    checkForTooltip(zone, lw);
}



void GTKUI::show() 
{
    assert(fTop == 0);
    gtk_widget_show  (fBox[0]);
    gtk_widget_show  (fWindow);
}


/**
 * Update all user items reflecting zone z
 */
    
static gboolean callUpdateAllGuis(gpointer)
{ 
    GUI::updateAllGuis(); 
    return TRUE;
}


void GTKUI::run() 
{
    assert(fTop == 0);
    gtk_widget_show  (fBox[0]);
    gtk_widget_show  (fWindow);
    gtk_timeout_add(40, callUpdateAllGuis, 0);
    gtk_main ();
    stop();
}



#endif