class Fl


Class Hierarchy

Include Files

Description

The Fl class is the FLTK global (static) class containing state information and global methods for the current application.

Methods

void add_check(Fl_Timeout_Handler, void* = 0);

FLTK will call this callback just before it flushes the display and waits for events. This is different than an idle callback because it is only called once, then FLTK calls the system and tells it not to return until an event happens.

This can be used by code that wants to monitor the application's state, such as to keep a display up to date. The advantage of using a check callback is that it is called only when no events are pending. If events are coming in quickly, whole blocks of them will be processed before this is called once. This can save significant time and avoid the application falling behind the events.

Sample code:

void add_fd(int fd, int when, void (*cb)(int,void*),void* =0);
void add_fd(int fd, void (*cb)(int, void*), void* = 0);

Add file descriptor fd to listen to. When the fd becomes ready for reading Fl::wait() will call the callback and then return. The callback is passed the fd and the arbitrary void* argument.

The second version takes a when bitfield, with the bits FL_READ, FL_WRITE, and FL_EXCEPT defined, to indicate when the callback should be done.

There can only be one callback of each type for a file descriptor. Fl::remove_fd() gets rid of all the callbacks for a given file descriptor.

Under UNIX any file descriptor can be monitored (files, devices, pipes, sockets, etc.) Due to limitations in Microsoft Windows, WIN32 applications can only monitor sockets.

void add_handler(int (*h)(int));

Install a function to parse unrecognized events. If FLTK cannot figure out what to do with an event, it calls each of these functions (most recent first) until one of them returns non-zero. If none of them returns non zero then the event is ignored. Events that cause this to be called are:

void add_idle(void (*cb)(void*), void* = 0);

Adds a callback function that is called every time by Fl::wait() and also makes it act as though the timeout is zero (this makes Fl::wait() return immediately, so if it is in a loop it is called repeatedly, and thus the idle fucntion is called repeatedly). The idle function can be used to get background processing done.

You can have multiple idle callbacks. To remove an idle callback use Fl::remove_idle().

Fl::wait() and Fl::check() call idle callbacks, but Fl::ready() does not.

The idle callback can call any FLTK functions, including Fl::wait(), Fl::check(), and Fl::ready(). FLTK will not recursively call the idle callback.

void add_timeout(double t, Fl_Timeout_Handler,void* = 0);

Add a one-shot timeout callback. The function will be called by Fl::wait() at t seconds after this function is called. The optional void* argument is passed to the callback.

You can have multiple timeout callbacks. To remove an timeout callback use Fl::remove_timeout().

If you need more accurate, repeated timeouts, use Fl::repeat_timeout() to reschedule the subsequent timeouts.

The following code will print "TICK" each second on stdout with a fair degree of accuracy:

    void callback(void*) {
      puts("TICK");
      Fl::repeat_timeout(1.0, callback);
    }

    int main() {
      Fl::add_timeout(1.0, callback);
      return Fl::run();
    }

int arg(int, char**, int&);

Consume a single switch from argv, starting at word i. Returns the number of words eaten (1 or 2, or 0 if it is not recognized) and adds the same value to i. You can use this function if you prefer to control the incrementing through the arguments yourself.

int args(int, char**, int&, int (*)(int,char**,int&) = 0);

FLTK provides an entirely optional command-line switch parser. You don't have to call it if you don't like them! Everything it can do can be done with other calls to FLTK.

To use the switch parser, call Fl::args(...) near the start of your program. This does not open the display, instead switches that need the display open are stashed into static variables. Then you must display your first window by calling window->show(argc,argv), which will do anything stored in the static variables.

callback lets you define your own switches. It is called with the same argc and argv, and with i the index of each word. The callback should return zero if the switch is unrecognized, and not change i. It should return non-zero if the switch is recognized, and add at least 1 to i (it can add more to consume words after the switch). This function is called before any other tests, so you can override any FLTK switch (this is why FLTK can use very short switches instead of the long ones all other toolkits force you to use).

On return i is set to the index of the first non-switch. This is either:

The return value is i unless an unrecognized switch is found, in which case it is zero. If your program takes no arguments other than switches you should produce an error if the return value is less than argc.

All switches except -bg2 may be abbreviated one letter and case is ignored:

The second form of Fl::args() is useful if your program does not have command line switches of its own. It parses all the switches, and if any are not recognized it calls Fl::abort(Fl::help).

A usage string is displayed if Fl::args() detects an invalid argument on the command-line. You can change the message by setting the Fl::help pointer.

void (*atclose)(Fl_Window*,void*);

void awake(void *p);

The awake() method sends a message pointer to the main thread, causing any pending wait() call to terminate so that the main thread can retrieve the message and any pending redraws can be processed.

void background2(uchar, uchar, uchar);

Changes fl_color(FL_WHITE) and the same colors as Fl::foreground(). This color is used as a background by Fl_Input and other text widgets.

void background(uchar, uchar, uchar);

Changes fl_color(FL_GRAY) to the given color, and changes the gray ramp from 32 to 56 to black to white. These are the colors used as backgrounds by almost all widgets and used to draw the edges of all the boxtypes.

Fl_Widget* belowmouse();
void belowmouse(Fl_Widget*);

Get or set the widget that is below the mouse. This is for highlighting buttons. It is not used to send FL_PUSH or FL_MOVE directly, for several obscure reasons, but those events typically go to this widget. This is also the first widget tried for FL_SHORTCUT events.

If you change the belowmouse widget, the previous one and all parents (that don't contain the new widget) are sent FL_LEAVE events. Changing this does not send FL_ENTER to this or any widget, because sending FL_ENTER is supposed to test if the widget wants the mouse (by it returning non-zero from handle()).

int box_dh(Fl_Boxtype);

Returns the height offset for the given boxtype.

int box_dw(Fl_Boxtype);

Returns the width offset for the given boxtype.

int box_dx(Fl_Boxtype);

Returns the X offset for the given boxtype.

int box_dy(Fl_Boxtype);

Returns the Y offset for the given boxtype.

int check();

Same as Fl::wait(0). Calling this during a big calculation will keep the screen up to date and the interface responsive:

The returns non-zero if any windows are displayed, and 0 if no windows are displayed (this is likely to change in future versions of FLTK).

int compose(int &del);

Use of this function is very simple. Any text editing widget should call this for each FL_KEYBOARD event.

If true is returned, then it has modified the Fl::event_text() and Fl::event_length() to a set of bytes to insert (it may be of zero length!). In will also set the "del" parameter to the number of bytes to the left of the cursor to delete, this is used to delete the results of the previous call to Fl::compose().

If false is returned, the keys should be treated as function keys, and del is set to zero. You could insert the text anyways, if you don't know what else to do.

Though the current implementation returns immediately, future versions may take quite awhile, as they may pop up a window or do other user-interface things to allow characters to be selected.

void compose_reset();

If the user moves the cursor, be sure to call Fl::compose_reset(). The next call to Fl::compose() will start out in an initial state. In particular it will not set "del" to non-zero. This call is very fast so it is ok to call it many times and in many places.

void copy(const char *stuff, int len, int clipboard);

Copies the data pointed to by stuff to the selection (0) or primary (1) clipboard. The selection clipboard is used for middle-mouse pastes and for drag-and-drop selections. The primary clipboard is used for traditional copy/cut/paste operations.

int damage();
void damage(int x);

If true then flush() will do something.

void default_atclose(Fl_Window*,void*);

This is the default callback for window widgets. It hides the window and then calls the default widget callback.

void delete_widget(Fl_Widget*);

Schedules a widget for deletion when it is safe to do so. Use this method to delete a widget inside a callback function. When deleting groups or windows, you must only delete the group or window widget and not the individual child widgets.

void display(const char*);

Sets the X display to use for all windows. Actually this just sets the environment variable $DISPLAY to the passed string, so this only works before you show() the first window or otherwise open the display, and does nothing useful under WIN32.

int dnd();

Initiate a Drag And Drop operation. The clipboard should be filled with relevant data before calling this method. FLTK will then initiate the system wide drag and drop handling. Dropped data will be marked as text.

void dnd_text_ops(int d);
int dnd_text_ops();

Gets or sets whether drag and drop text operations are supported. This specifically affects whether selected text can be dragged from text fields or dragged within a text field as a cut/paste shortcut.

void (*error)(const char*, ...);

FLTK calls this to print a normal error message. You can override the behavior by setting the function pointer to your own routine.

Fl::error means there is a recoverable error such as the inability to read an image file. The default implementation prints the error message to stderr and returns.

int event_alt();

Returns non-zero if the Alt key is pressed.

int event_button1();

Returns non-zero if button 1 is pressed.

int event_button2();

Returns non-zero if button 2 is pressed.

int event_button3();

Returns non-zero if button 3 is pressed.

int event_button();

Returns which mouse button was pressed. This returns garbage if the most recent event was not a FL_PUSH or FL_RELEASE event.

int event_buttons();

Returns the button state bits; if non-zero, then at least one button is pressed.

int event_clicks();
void event_clicks(int i);

The first form returns non-zero if the most recent FL_PUSH or FL_KEYBOARD was a "double click". Returns N-1 for N clicks. A double click is counted if the same button is pressed again while event_is_click() is true.

The second form directly sets the number returned by Fl::event_clicks(). This can be used to set it to zero so that later code does not think an item was double-clicked.

int event_ctrl();

Returns non-zero if the Control key is pressed.

int event();

Returns the last event that was processed. This can be used to determine if a callback is being done in response to a keypress, mouse click, etc.

int event_inside(int,int,int,int);
int event_inside(const Fl_Widget*);

Returns non-zero if the current event_x and event_y put it inside the widget or inside an arbitrary bounding box. You should always call this rather than doing your own comparison so you are consistent about edge effects.

int event_is_click();
void event_is_click(0);

The first form returns non-zero if the mouse has not moved far enough and not enough time has passed since the last FL_PUSH or FL_KEYBOARD event for it to be considered a "drag" rather than a "click". You can test this on FL_DRAG, FL_RELEASE, and FL_MOVE events. The second form clears the value returned by Fl::event_is_click(). Useful to prevent the next click from being counted as a double-click or to make a popup menu pick an item with a single click. Don't pass non-zero to this.

int event_key();
int event_key(int s);

Fl::event_key() returns which key on the keyboard was last pushed. It returns zero if the last event was not a key press or release.

Fl::event_key(int) returns true if the given key was held down (or pressed) during the last event. This is constant until the next event is read from the server.

Fl::get_key(int) returns true if the given key is held down now. Under X this requires a round-trip to the server and is much slower than Fl::event_key(int).

Keys are identified by the unshifted values. FLTK defines a set of symbols that should work on most modern machines for every key on the keyboard:

On X Fl::get_key(FL_Button+n) does not work.

On WIN32 Fl::get_key(FL_KP_Enter) and Fl::event_key(FL_KP_Enter) do not work.

int event_length();

Returns the length of the text in Fl::event_text(). There will always be a nul at this position in the text. However there may be a nul before that if the keystroke translates to a nul character or you paste a nul character.

int event_shift();

Returns non-zero if the Shift key is pressed.

int event_state();
int event_state(int i);

This is a bitfield of what shift states were on and what mouse buttons were held down during the most recent event. The second version returns non-zero if any of the passed bits are turned on. The legal bits are:

X servers do not agree on shift states, and FL_NUM_LOCK, FL_META, and FL_SCROLL_LOCK may not work. The values were selected to match the XFree86 server on Linux. In addition there is a bug in the way X works so that the shift state is not correctly reported until the first event after the shift key is pressed or released.

int event_x();

Returns the mouse position of the event relative to the Fl_Window it was passed to.

int event_x_root();

Returns the mouse position on the screen of the event. To find the absolute position of an Fl_Window on the screen, use the difference between event_x_root(),event_y_root() and event_x(),event_y().

int event_y();

Returns the mouse position of the event relative to the Fl_Window it was passed to.

int event_y_root();

Returns the mouse position on the screen of the event. To find the absolute position of an Fl_Window on the screen, use the difference between event_x_root(),event_y_root() and event_x(),event_y().

void (*fatal)(const char*, ...);

FLTK calls this to print a fatal error message. You can override the behavior by setting the function pointer to your own routine.

Fl::fatal must not return, as FLTK is in an unusable state, however your version may be able to use longjmp or an exception to continue, as long as it does not call FLTK again. The default implementation prints the error message to stderr and exits with status 1.

Fl_Window* first_window();
void first_window(Fl_Window*);

Returns the first top-level window in the list of shown() windows. If a modal() window is shown this is the top-most modal window, otherwise it is the most recent window to get an event.

The second form sets the window that is returned by first_window. The window is removed from wherever it is in the list and inserted at the top. This is not done if Fl::modal() is on or if the window is not shown(). Because the first window is used to set the "parent" of modal windows, this is often useful.

void flush();

Causes all the windows that need it to be redrawn and graphics forced out through the pipes. This is what wait() does before looking for events.

Fl_Widget* focus();
void focus(Fl_Widget*);

Get or set the widget that will receive FL_KEYBOARD events.

If you change Fl::focus(), the previous widget and all parents (that don't contain the new widget) are sent FL_UNFOCUS events. Changing the focus does not send FL_FOCUS to this or any widget, because sending FL_FOCUS is supposed to test if the widget wants the focus (by it returning non-zero from handle()).

void foreground(uchar, uchar, uchar);

Changes fl_color(FL_BLACK). Also changes FL_INACTIVE_COLOR and FL_SELECTION_COLOR to be a ramp between this and FL_WHITE.

void free_color(Fl_Color c, int overlay = 0);

Frees the specified color from the colormap, if applicable. If overlay is non-zero then the color is freed from the overlay colormap.

Fl_Box_Draw_F *get_boxtype(Fl_Boxtype);

Gets the current box drawing function for the specified box type.

unsigned get_color(Fl_Color c);
void get_color(Fl_Color c, uchar&r, uchar&g, uchar&b);

Returns the RGB value(s) for the given FLTK color index. The first form returns the RGB values packed in a 32-bit unsigned integer with the red value in the upper 8 bits, the green value in the next 8 bits, and the blue value in bits 8-15. The lower 8 bits will always be 0.

The second form returns the red, green, and blue values separately in referenced variables.

const char* get_font(Fl_Font);

Get the string for this face. This string is different for each face. Under X this value is passed to XListFonts to get all the sizes of this face.

const char* get_font_name(Fl_Font, int* attributes = 0);

Get a human-readable string describing the family of this face. This is useful if you are presenting a choice to the user. There is no guarantee that each face has a different name. The return value points to a static buffer that is overwritten each call.

The integer pointed to by attributes (if the pointer is not zero) is set to zero, FL_BOLD or FL_ITALIC or FL_BOLD | FL_ITALIC. To locate a "family" of fonts, search forward and back for a set with non-zero attributes, these faces along with the face with a zero attribute before them constitute a family.

int get_font_sizes(Fl_Font, int*& sizep);

Return an array of sizes in sizep. The return value is the length of this array. The sizes are sorted from smallest to largest and indicate what sizes can be given to fl_font() that will be matched exactly (fl_font() will pick the closest size for other sizes). A zero in the first location of the array indicates a scalable font, where any size works, although the array may list sizes that work "better" than others. Warning: the returned array points at a static buffer that is overwritten each call. Under X this will open the display.

int get_key(int);

void get_mouse(int &x,int &y);

Return where the mouse is on the screen by doing a round-trip query to the server. You should use Fl::event_x_root() and Fl::event_y_root() if possible, but this is necessary if you are not sure if a mouse event has been processed recently (such as to position your first window). If the display is not open, this will open it.

void get_system_colors();

Read the user preference colors from the system and use them to call Fl::foreground(), Fl::background(), and Fl::background2(). This is done by Fl_Window::show(argc,argv) before applying the -fg and -bg switches.

On X this reads some common values from the Xdefaults database. KDE users can set these values by running the "krdb" program, and newer versions of KDE set this automatically if you check the "apply style to other X programs" switch in their control panel.

int gl_visual(int, int *alist=0);

This does the same thing as Fl::visual(int) but also requires OpenGL drawing to work. This must be done if you want to draw in normal windows with OpenGL with gl_start() and gl_end(). It may be useful to call this so your X windows use the same visual as an Fl_Gl_Window, which on some servers will reduce colormap flashing.

See Fl_Gl_Window for a list of additional values for the argument.

Fl_Window* grab();
void grab(Fl_Window&w) {grab(&w);}

This is used when pop-up menu systems are active. Send all events to the passed window no matter where the pointer or focus is (including in other programs). The window does not have to be shown() , this lets the handle() method of a "dummy" window override all event handling and allows you to map and unmap a complex set of windows (under both X and WIN32 some window must be mapped because the system interface needs a window id).

If grab() is on it will also affect show() of windows by doing system-specific operations (on X it turns on override-redirect). These are designed to make menus popup reliably and faster on the system.

To turn off grabbing do Fl::grab(0).

Be careful that your program does not enter an infinite loop while grab() is on. On X this will lock up your screen!

int h();

Returns the height of the screen in pixels.

int handle(int, Fl_Window*);

Sends the event to a window for processing. Returns non-zero if any widget uses the event.

int has_check(Fl_Timeout_Handler, void* = 0);

Returns true if the check exists and has not been called yet.

int has_idle(void (*cb)(void*), void* = 0);

Returns true if the specified idle callback is currently installed.

int has_timeout(Fl_Timeout_Handler, void* = 0);

Returns true if the timeout exists and has not been called yet.

void lock();

The lock() method blocks the current thread until it can safely access FLTK widgets and data. Child threads should call this method prior to updating any widgets or accessing data. The main thread must call lock() to initialize the threading support in FLTK.

Child threads must call unlock() when they are done accessing FLTK.

When the wait() method is waiting for input or timeouts, child threads are given access to FLTK. Similarly, when the main thread needs to do processing, it will wait until all child threads have called unlock() before processing additional data.

Fl_Window* modal();

Returns the top-most modal() window currently shown. This is the most recently shown() window with modal() true, or NULL if there are no modal() windows shown(). The modal() window has its handle() method called for all events, and no other windows will have handle() called (grab() overrides this).

Fl_Window* next_window(const Fl_Window*);

Returns the next top-level window in the list of shown() windows. You can use this call to iterate through all the windows that are shown().

void own_colormap();

Makes FLTK use its own colormap. This may make FLTK display better and will reduce conflicts with other programs that want lots of colors. However the colors may flash as you move the cursor between windows.

This does nothing if the current visual is not colormapped.

void paste(Fl_Widget &receiver);

Set things up so the receiver widget will be called with an FL_PASTE event some time in the future. The reciever should be prepared to be called directly by this, or for it to happen later, or possibly not at all. This allows the window system to take as long as necessary to retrieve the paste buffer (or even to screw up completely) without complex and error-prone synchronization code in FLTK.

Fl_Widget* pushed();
void pushed(Fl_Widget*);

Get or set the widget that is being pushed. FL_DRAG or FL_RELEASE (and any more FL_PUSH) events will be sent to this widget.

If you change the pushed widget, the previous one and all parents (that don't contain the new widget) are sent FL_RELEASE events. Changing this does not send FL_PUSH to this or any widget, because sending FL_PUSH is supposed to test if the widget wants the mouse (by it returning non-zero from handle()).

Fl_Widget* readqueue();

All Fl_Widgets that don't have a callback defined use a default callback that puts a pointer to the widget in this queue, and this method reads the oldest widget out of this queue.

int ready();

This is similar to Fl::check() except this does not call Fl::flush() or any callbacks, which is useful if your program is in a state where such callbacks are illegal. This returns true if Fl::check() would do anything (it will continue to return true until you call Fl::check() or Fl::wait()).

void redraw();

Redraws all widgets.

void release();

void remove_check(Fl_Timeout_Handler, void* = 0);

Removes a check callback. It is harmless to remove a check callback that no longer exists.

void remove_fd(int, int when);
void remove_fd(int);

Removes a file descriptor handler.

void remove_handler(int (*h)(int));

Removes a previously added event handler.

void remove_idle(void (*cb)(void*), void* = 0);

Removes the specified idle callback, if it is installed.

void remove_timeout(Fl_Timeout_Handler, void* = 0);

Removes a timeout callback. It is harmless to remove a timeout callback that no longer exists.

void repeat_timeout(double t, Fl_Timeout_Handler,void* = 0);

This method repeats a timeout callback from the expiration of the previous timeout, allowing for more accurate timing. You may only call this method inside a timeout callback.

The following code will print "TICK" each second on stdout with a fair degree of accuracy:

    void callback(void*) {
      puts("TICK");
      Fl::repeat_timeout(1.0, callback);
    }

    int main() {
      Fl::add_timeout(1.0, callback);
      return Fl::run();
    }

int run();

As long as any windows are displayed this calls Fl::wait() repeatedly. When all the windows are closed it returns zero (supposedly it would return non-zero on any errors, but FLTK calls exit directly for these). A normal program will end main() with return Fl::run();.

void scheme(const char *name);
const char *scheme();

Gets or sets the current widget scheme. Currently only "none" and "plastic" are recognized, and NULL will use the scheme defined in the FLTK_SCHEME environment variable or the scheme resource under X11.

void selection(Fl_Widget &owner, const char* stuff, int len);

Changes the current selection. The block of text is copied to an internal buffer by FLTK (be careful if doing this in response to an FL_PASTE as this may be the same buffer returned by event_text()). The selection_owner() widget is set to the passed owner.

Fl_Widget* selection_owner();
void selection_owner(Fl_Widget*);

The single-argument selection_owner(x) call can be used to move the selection to another widget or to set the owner to NULL, without changing the actual text of the selection. FL_SELECTIONCLEAR is sent to the previous selection owner, if any.

Copying the buffer every time the selection is changed is obviously wasteful, especially for large selections. An interface will probably be added in a future version to allow the selection to be made by a callback function. The current interface will be emulated on top of this.

void set_abort(void (*f)(const char*,...));

void set_atclose(void (*f)(Fl_Window*,void*));

void set_boxtype(Fl_Boxtype, Fl_Box_Draw_F*,uchar,uchar,uchar,uchar);
void set_boxtype(Fl_Boxtype, Fl_Boxtype from);

The first form sets the function to call to draw a specific boxtype.

The second form copies the from boxtype.

void set_color(Fl_Color, uchar, uchar, uchar);
void set_color(Fl_Color, unsigned);

Sets an entry in the fl_color index table. You can set it to any 8-bit RGB color. The color is not allocated until fl_color(i) is used.

void set_font(Fl_Font, const char*);
void set_font(Fl_Font, Fl_Font);

The first form changes a face. The string pointer is simply stored, the string is not copied, so the string must be in static memory.

The second form copies one face to another.

Fl_Font set_fonts(const char* = 0);

FLTK will open the display, and add every font on the server to the face table. It will attempt to put "families" of faces together, so that the normal one is first, followed by bold, italic, and bold italic.

The optional argument is a string to describe the set of fonts to add. Passing NULL will select only fonts that have the ISO8859-1 character set (and are thus usable by normal text). Passing "-*" will select all fonts with any encoding as long as they have normal X font names with dashes in them. Passing "*" will list every font that exists (on X this may produce some strange output). Other values may be useful but are system dependent. With WIN32 NULL selects fonts with ISO8859-1 encoding and non-NULL selects all fonts.

The return value is how many faces are in the table after this is done.

void set_idle(void (*cb)());

Sets an idle callback.

This method is obsolete - use the add_idle() method instead.

void set_labeltype(Fl_Labeltype,Fl_Label_Draw_F*,Fl_Label_Measure_F*);
void set_labeltype(Fl_Labeltype, Fl_Labeltype from);

The first form sets the functions to call to draw and measure a specific labeltype.

The second form copies the from labeltype.

int test_shortcut(int);

Test the current event, which must be an FL_KEYBOARD or FL_SHORTCUT, against a shortcut value (described in Fl_Button). Returns non-zero if there is a match. Not to be confused with Fl_Widget::test_shortcut().

void *thread_message();

The thread_message() method returns the last message that was sent from a child by the awake() method.

void unlock();

The unlock() method releases the lock that was set using the lock() method. Child threads should call this method as soon as they are finished accessing FLTK.

double version();

Returns the compiled-in value of the FL_VERSION constant. This is useful for checking the version of a shared library.

void visible_focus(int v);
int visible_focus();

Gets or sets the visible keyboard focus on buttons and other non-text widgets. The default mode is to enable keyboard focus for all widgets.

int visual(int);

Selects a visual so that your graphics are drawn correctly. This is only allowed before you call show() on any windows. This does nothing if the default visual satisfies the capabilities, or if no visual satisfies the capabilities, or on systems that don't have such brain-dead notions.

Only the following combinations do anything useful:

This returns true if the system has the capabilities by default or FLTK suceeded in turing them on. Your program will still work even if this returns false (it just won't look as good).

int w();

Returns the width of the screen in pixels.

int wait();
double wait(double time);

Waits until "something happens" and then returns. Call this repeatedly to "run" your program. You can also check what happened each time after this returns, which is quite useful for managing program state.

What this really does is call all idle callbacks, all elapsed timeouts, call Fl::flush() to get the screen to update, and then wait some time (zero if there are idle callbacks, the shortest of all pending timeouts, or infinity), for any events from the user or any Fl::add_fd() callbacks. It then handles the events and calls the callbacks and then returns.

The return value of the first form is non-zero if there are any visible windows - this may change in future versions of FLTK.

The second form waits a maximum of time seconds. It can return much sooner if something happens.

The return value is positive if an event or fd happens before the time elapsed. It is zero if nothing happens (on Win32 this will only return zero if time is zero). It is negative if an error occurs (this will happen on UNIX if a signal happens).

void (*warning)(const char*, ...);

FLTK calls this to print a warning message. You can override the behavior by setting the function pointer to your own routine.

Fl::warning means that there was a recoverable problem, the display may be messed up but the user can probably keep working - all X protocol errors call this, for example.

int x();

Returns the origin of the current screen, where 0 indicates the left side of the screen.

int y();

Returns the origin of the current screen, where 0 indicates the top edge of the screen.

int event_dx();

int event_dy();

const char* event_text();